237 38 67MB
English Pages [187] Year 1982
Penn State handbook for commercial mushroom growers : a compendium of scientific and technical information useful to mushroom farmers / science editor, Paul J. Wuest ; production editor, Glenn D. Bengtson. [University Park, PA] : Pennsylvania State University, College of Agriculture, c1982. https://hdl.handle.net/2027/uiug.30112020164825
Creative Commons Attribution-NonCommercial http://www.hathitrust.org/access_use#cc-by-nc-4.0 This work is protected by copyright law (which includes certain exceptions to the rights of the copyright holder that users may make, such as fair use where applicable under U.S. law), but made available under a Creative Commons Attribution-NonCommercial license. You must attribute this work in the manner specified by the author or licensor (but not in any way that suggests that they endorse you or your use of the work). This work may be copied, distributed, displayed, and performed - and derivative works based upon it - but for non-commercial purposes only (if you are unsure where a use is non-commercial, contact the rights holder for clarification). Please check the terms of the specific Creative Commons license as indicated at the item level. For details, see the full license deed http://creativecommons.org/licenses/by-nc/4.0.
TY .
Love
OF
LIBRARY
AT URBANA - CHAMPAIGN AGRICULTURE
1
III.
1
Library Materials! The MinimumFee
for
is $
NOTICE: Returnor renew each Lost Book 50.00.
for
all
AGRICULTURE
it is
to
for
.
or
on its
responsible The person charging this material return the library from which was withdrawn before the Latest Date stamped below of
.
ILLINOIS LIBRARY
URBANA CHAMPAIGN -
UNIVERSITY
AT
OF
,
To
in
,
,
discipli Theft mutilation and underlining books are reasons nary action and may result dismissal from the University renew call TelephoneCenter 333-8400
21 01
MAR
MAR
MAY
0
MAY
2011
1998
15
1 3
29
NOV
DEC
29 1936
0
MAY MAR
2008
1994
01 1995
MAR
8996
NOV 2.1
22
JUL
JUN
1994
01
2000
RRED
2000
229 L161-0-1096
1
1990
LIBRARY
1
1
1
1 1
1
p
Penn State Handbook for Commercial Mushroom Growers A compendium of
scientific and technical information useful to mushroom farmers
Scientific
Editor : Paul J. Wuest
Production Editor : Glenn D. Bengtson
All
Copyright © 1982 by The Pennsylvania State University .
Rights Reserved
ا
)6 : ) م
هت
.2 ...
Agrice
P38
PREFACE
vii
9
1986 ILLINOIS
Spawn and 14
ix
THE AUTHORS
Specific Nutrients Needed Mushrooms
by
UNIVERSITY
OF
MAY
Contents
0
AGRICULTURE LISRARÍ
Mesophilic Fungi Mushroom Compost and Their Metabolic Traits in
xi
FROM THE DEAN
,
I
,
,
DISEASES WEED MOLDS INDICATOR MOLDS AND ABNORMALITIES OF THE COMMERCIAL MUSHROOM
SECTION SCIENCE
Mushroom Diseases
23
Mummy Disease
24
Virus Disease
24
Nematodes
25
Truffle Disease
What Mushrooms Need
Mat and Confetti Diseases
Competitor
Bacterial Blotch Disease
II
I
3
22
3
22
5
21
Trichoderma Diseases
7
20
8
20
Hypomyces Mildew Disease
Indicator Fungi
of
Compost Chemistry and the Role Microorganisms
11
SOME BIOLOGICAL INDICATORS OF COMPOST QUALITY
11
25
Lipstick Mold
25
Cinnamon Brown Mold
26
Sepedonium Yellow Mold
26
12
Pythium Disease
27
12
Corticium Mold
27
-
Poor Quality Compost
Indicator Molds
Fungi and the Carbohydrate Component Compost
in
in
13
Fungi and Nitrogenous Components Compost
13
Improper Management Temperature
13
of
Anaerobiosis During Composting Compost
27
Ink Cap Fungi
27
Plaster Molds and Flour Molds
28
Olive Green Mold
30
Black Whisker Mold
30
Oedocephalum Mold
31
Ecological
iii
11
)
–
Composting Phase Succession II
Weed Molds
(M
, ;
,
I
Composting esophilic and Fungi Thermophilic Thermotolerant Fungi Actinomycetes and Bacteria Phase
13
or
/
Lignin Humus Complex
19 19
Mycogone Disease
Phase
19
Verticillium Disease
9
BIOCHEMICAL AND MYCOLOGICAL ASPECTS OF MUSHROOM COMPOSTING Phase
14
31
History
55
Stroma
31
Casing Materials
55
Weepers
32
Treatment
Flock , Hardcap , and Open Veil
32
Steam ,
Hollow Core and Brown Pith
33
Abnormalities
Purple Stem Color Plates
( to
follow page
34 )
SIGNIFICANT INSECT PESTS OF THE COMMERCIAL MUSHROOM
35
The Sciarid Fly
35
The Phorid Fly
38
The Cecid Fly
38
Pyemotid Mites
38
Heat Transfer, and Thermal Sensitivity
SPAWNING TO CASING IN COMMERCIAL MUSHROOM PRODUCTION
43
Spawn
43
Spawning
43
58
Soil Structure
59
Aerated
Steam
59
Using
Fumigant
60
a
60
Sanitation
INTEGRATED PEST MANAGEMENT MUSHROOM FARMING
FOR
Pest Management
61 61
Pest Management
61
Key Pests in the PSU Mushroom IPM Project
62
Monitoring for Key Pests
62
Monitoring Pest Populations
62
Excluding Key Pests From the Crop Modifications ; Cultural Modifications )
63
( Physical
44
Sanitation
65
45
Integrating Pesticides into IPM
65
Sanitation
45
Use of Pesticides
65
)
Spawning SASing (
at
884
Methods Rates
Supplementation Spawn Growth
45 46
Compost Factors
46
Sanitation
47 )
Casing SACing (
at
Mushroom Cultivar Used
46
Supplementation
-
INFLUENCE OF CULTURAL PRACTICES ON MUSHROOM YIELD RESPONSE TO DELAYED RELEASE NUTRIENTS
48
Determining Pesticide Needs and Assessing Effectiveness
LA FRANCE DISEASE OF THE CULTIVATED MUSHROOM
Disease Symptoms
70
Disease Epidemiology
72
49
Compost Density
TECHNOLOGY
-
II
SECTION
50
During Spawn
Run
52
of
Time
69 69
49
normal Temperatures
66
First Occurrence and Symptoms
Spawning Rate
Below
Casing
52
Spawn Strains
52
SEASONAL VARIATIONS AND MUSHROOM GROWING
79
Seasonal Influences
79
Composting Through Casing
79
Tradeoffs
80
,
1,
MANIPULATING AND TREATING MUSHROOM CASING SELECTING
iv
41
56
Soil Properties and Steam Treatment
Steps in Integrated
SUPPLEMENTATION WITH VEGETABLE OILS BEFORE PHASE II OF COMPOSTING
56
of Casing
55
80
83
Phase II
85
87
PASTEURIZATION DURING THE MUSHROOM - GROWING CYCLE Heat Conduction and Treatment
Effectiveness
91
and
Usage
91
Pasteurization After Cropping
92
Farm Practices
Measuring and Controlling Temperature
96
Practical Scenarios
97
Monitoring the Farm Environment
106
Monitoring the Climate
107
Disease Monitoring
107
Immature Insect Monitoring
108
Adult Insect Monitoring
109
Grower / Growing Practice Monitoring
109
Determination of Economic Levels of Damage
110
Techniques and Tools to Manipulate Pest Populations
110
Broad Considerations of the Mushroom Farm Community
111
eggs larvae Appendix : Extraction of pupae and nematodes from mushroom by
,
95
105
Decision -Making Based on
92
MANAGING COMPOST DURING SPAWN RUN AND CROPPING
Acquiring Pest Information
fly
Its
105
90
Pasteurization of Casing with Steam Aerated Steam
ORGANIZING AND USING THE PENN STATE IPM APPROACH TO MUSHROOM PEST MANAGEMENT
90
II Composting
Phase
101
103
89
When Pasteurization is Used
Water , Temperature, and Cropping
SOME THOUGHTS ON CO , CONTROL IN MUSHROOM CULTURE
89
Systems
100
83
Phase I
SUGGESTIONS FOR PHASE II IN A STANDARD MUSHROOM HOUSE
100
,
A GROWER'S GUIDE FOR COMMERCIAL MUSHROOM COMPOST PREPARATION
How to Apply Enough Water Watering During the Crop
,
Pest Strategies
centrifuged
compost and casing soil sugar flotation method
97
Pennsylvania Mushroom Fly Monitor Records
Before First Break
97
Mushroom
Later Breaks
98
Usage Record
99
Casing
99
Watering
99 99
Sealed Casing and Scratching
99
Water
Watering Different Cultivars
-
Two Week Pesticide 115
117
GLOSSARY OF TECHNICAL TERMS
119
BIBLIOGRAPHY
121
COMMENTS AND SUGGESTIONS
129
100 100
V
to
When
to
Apply Water
How
114
NEW INNOVATIONS FOR EFFICIENT MUSHROOM GROWING
"
HOW TO MANAGE THE WATERING OF MUSHROOM CROP
Farm
112
"
Pinning
A
At
During Spawn Run
a
97
1
1
Preface
by
of
By
is ,
.
lim
no
:
of
is
a
It is
.
of
by
in by
.
a
by
by
of
of
of
to
of
.
.
.
for
-
a
.
,
to
,
,
,
a
by
to
to
on
it
a
an
or
Its
.
in
.
-
,
to
is
to
.
or of
.
is a
to
,
a
or
,
in
be
.
be
,
,
be
evant
to
the scientific editor and topics that you consider rel
or by
be
to
It
.
a
You may notice that your handbook has some what unique paper was chosen with one thought provide guide mind used the farmer you have dirty hands spill some the farm a
of
an
.
of
of
a
of
is
1985. Please write
If
of at .
to
of
1984
provide information
.
,
be
.
to
.
,
.
as
or
,
an
.
culture
provide information commercial mushroom farmers Although the authors have covered subjects they consider important more comprehensive ref only erence will available when you the users tell what you think should added With your help additions the handbook could made available
to
,
,
,
supplied energy through compost Mushroom science has enabled farmers harvest least one pound mushrooms from each pound compost spawned This compares very favorably with the two pounds feed required for one pound chicken five pounds feed for one pound beef Such achievement supports the judgment that agri mushroom farming advanced form they must
to
re
a
of
.
,
,
chemical composition and favorable growing condi tions they derive their energy from the sun Whereas green plants are autotrophic mushrooms are hetero trophic are animals Because mushrooms cannot transform the sun's energy into energy for growth
and did Transferring knowledge was vital the evolution efficient mushroom farming No single reference textbook available farm practical questions ers who want answers swers those with far reaching consequences This step handbook that direction main purpose use force
.
of
,
,
a
be
to to
is
If
,
in
be
.
an
have made mushroom growing advanced form agriculture there harvest mushrooms green plants which manu must fed contrast facture their own food Although green plants quire fertilizers water soil certain texture and
producing favorable environment bountiful Progress was furthered crop those who had knowledge and passed those who wanted
:
a
of
phenom number six decades other contributions
vations along with pest control strategies provided .
art ,
an
is
science
it ,
In
.
the process
still
in
to
so
.
it
.
ena
in
Although making compost has quantified and explained
those who selected productive cul tures and supplied quality spawn and those who im plemented excellent management systems control watering and ventilation temperature These inno compost turners
to
.
it
in
of
differentiate from the standard compost made from horse manure
production systems that provided for highly efficient compost into mushrooms These sys conversions tems did not occur chance but choices made plateau farmers Mushroom farmers reached nurturing their crop when they understood how and why they could operate efficiently many dedicated peo The efforts and discoveries ple contributed the advancement mushroom farming There were the designers and builders
or
in
a
to
,
J.
to
The option use other materials was not available until 1946 when W. Sinden published paper which he described how make synthetic compost This compost was not truly synthetic that con sisted crushed corn cobs and hay blended with supplements Synthetic compost was named
Limiting Factors
.
to
).
a
of
.
is
is
of in
at
.
the prime compost many mushroom same material used 1982 farms an indication the cunning commercial mushroom farmers two centuries ago
manure
system governed
the matter how successful the harvest the crop sequence one aspect ited the most constraining factor the end the 1970s some mushroom farmers had devised balanced
Law
is
A. as
-
(
as
food base bisporus The bedded horse ingredient That the =
made Agaricus brunnescens first mushroom farmers used straw cultivate
involves more than making
biological
us
of
be
.
to
Early mushroom farmers
compost
at in
by
.
a
art
,
desired species appeared knew that compost had
farming
Mushroom
,
an a
its
beginnings few centuries ago mushroom From farming has been and science People ate mushrooms before that but they got them forag ing the countryside during times the year when the
vii
thing on a page , simply wipe it clean . You don't need to protect your book by keeping it on a bookshelf . Leave it at the farm and use it at the farm . That's what it was designed for.
Although the authors and editors will be recog nized as contributers , many other people who helped make the book possible deserve special recognition . If you ever meet Brenda Holcomb , Becky Peplinski , Jim McClure , Rae Chambers , Lesley Strother , Denise
Glen Goss , Paul Nel son , or John Skelly , convey to them your sentiments on the book . They , along with the Dean of the Col lege , Sam Smith , and a family farmer from West Grove , Charles C. Brosius , were instrumental in mak Hosterman
,
Evelyn Buckalew
ing this mushroom handbook
,
a
reality
.
Paul J. Wuest Professor
of Plant Pathology , Mushroom Specialist
1
1 1
1 1
July viii
1982
The Authors Cooperative Extension Service , Berks County Agricultural Center Herbert A. Wetzel
, Berks
Leesport,
,
PA 19533
County Extension Director
Department of Entomology , 106 Patterson Building , University Park ,1 PA 16802 Albert C. Napkil
, Graduate
Daniel L. Rinker ,
Graduate
Robert J. Snetsinger
Assistant Assistant
, Professor
of Entomology
Robert C. Tetrault, Associate Professor of Entomology Extension
Department of Plant Pathology , 211 Buckhout Laboratory , University Park , PA 16802 R. James Finley , Research Technologist
Cathy L. Harvey , Project Assistant ; on leave from Castle and Cooke , Inc. , Salem , Oregon C. Peter Romaine
,
Assistant Professor of Plant Pathology
Daniel J. Royse , Assistant
Professor
of Plant Pathology
Lee C. Schisler, Professor of Plant Pathology
Paul J. Wuest ,
Professor
of Plant Pathology
ix
From Dean Smith
at
Penn State .
tight budgets
.
I pledge to you that we will continue to serve the industry to the best of our abilities with the resources available to us . In turn , I would ask for your contin ued cooperation and support of industry these programs designed meet your needs Samuel H. Smith
xi
room Growers is one more example of this support and will be a helpful guide and resource for individ ual growers . Those of you who have been attending the Short Course , workshops , or Extension meetings and have worked with the faculty and staff members over the years are well aware of the contributions Penn State has made to the industry .
work
The close liaison between industry and the Univer sity is extremely important in times such as these when industry needs are great and research support for this university is threatened by inflated costs and
for
Mush
Extension
.
excellence . This Penn State Handbook for Commercial
At last count , we had twenty - two faculty and staff members from seven departments engaged in differ ent segments of mushroom research , education , and
to
Penn State has long recognized the importance of the mushroom industry in the agricultural economy of the Commonwealth . The University has provided substantial research and educational support through programs which are internationally recognized for
SECTION
I Science
Biochemical and Mycological Aspects
of Mushroom Composting Lee C. Schisler
4.0
0.24
Brewers Grains
2.50
2.50
4.0
0.10
Gypsum
1.25
1.25
0
Hay corn cob synthetic compost pile
.
NH NO
0.3
32.0
0.10
Potash
0.3
0.3
Gypsum
0.6
0.6
0
N
N
1.68
%
0.49
0.49 29.2
%
/
N
dry
=
wt
29.2
Hay corn cob hardwood bark synthetic
N
.
pile
content
15.0
12.8
2.0
0.26
Cobs
7.5
6.4
0.3
0.02
Hardwood bark
9.4
6.4
0.4
0.03
Chicken manure
3.8
2.4
4.0
0.09
NH.NO
0.2
0.2
32.0
0.06
Potash
0.3
0.3
Gypsum
0.6
0.6
3
1.58
N
0.46 29.1
%
N
%
=
ry
wt
/d
N
29.11
Ton
)
0
0
0
(
ton
0
)
(
(
ton
Hay
)
ton
( % )
·
Dry wt
Wet wt
Ingredients
46 /
of
in
as a
to
building the raw
compost
-
Table
,
in or
(
,
in
by
)
0.09
0.3
of
Phase
is
(
0.04
4.0
-
of or
a
in
,
,
.
blend
I
N 0.3
2.4
3.
a
or in
of
be
,
.
mixed
manure and synthetics are into what mushroom growers refer characterized
( % )
12.8
0
Chicken manure
3.8
0
15.0
.
" )
Various proportions
wt
0.26
).
,
as
organic fertilizers have been successfully introduced into the industry The following tables list four for mulas for typical composts used various parts North America today
.
(
(
Cobs
ton
2.0
0
,
(
12.8
content
covered
breakdown the raw ingredi drum done can also but commercial applications
a
is
.
device
I
here that
outside
such have been limited Horse manure has long been used the basic ingredient but substitutes called synthetics made from straw hay corn cobs other fibrous materials combined with organic and
"
ton
ton
15.0
I
;
performed
ents begins Phase composting
Dry
Hay
Ton
usually
it I is
area
Wet wt
Ingredients
)
Table
0.94
0.94 /59.75 = 1.57 % N
Ton N / dry wt = % N
PHASE Phase
0
59.75T
=
(
I
II
:
)
,
Chicken manure
6.00
0
a
pendent and interrelated processes Phase the out the cookout door composting process and Phase peak heat pasteurization process or
0.60
7.50
/
involving two interde
(ton )
(% ) 1.2
1 ,
no of .
organisms
(ton ) 50.00
2.
or
all
.
at
a
or
competitor
N content
80.00
compost
a
to
create
grow good crop provide time little
is
at
are
pile .
Dry wt
(ton )
Horse manure
At
.
its
composting
with sufficient nutrients mushrooms and the same nutrition for other fungi and procedure Composting
to to do
In
.
in
,
of
The objectives
Wet wt
Ingredients
compost
horse manure
)
Imbach , belongs to a group of plants called fungi the . These plants differ from green plants in they that lack chlorophyll and cannot use photosyn thesis in the manufacture of their own food . Conse quently , it becomes necessary to prepare a compost the same food to supply the mushroom with which upon compost foods contain must not time the compost grow fungi for mush suitable can other room growing other fungi either not grow comparison grow quite slowly the mushroom ( Lange )
Table 1. Straw -bedded
-
All commercial mushroom growing has depended on composted material. Although the time and nature of the composting has been modified , no one has been successful in eliminating this step from the prepara tion of a suitable medium for mushroom growing . Agaricus bisporus The cultivated mushroom ,
.
)
,
8.00
6.00
4.0
0.24
meal
2.00
2.00
6.7
0.13
Gypsum
0.65
0.65
0
,
,
be
to ( 50
as a
.
,
.
0.53
has been suggested that gypsum may also lower the pH and the NH3 content compost thereby bene fiting mushroom mycelial growth
1.52 % N
.
,
in
0.53 /34.9
is
to
Gypsum acts flocculating agent characteristics greasiness organic thereby preventing for colloids
0
34.9T %N
to
)
.
of
be
.
Cottonseed
Ton N /dry wt
,
Chicken manure
posts Inorganic sources may used with blends but the rate should calculated on only the syn thetic portion the blend Gypsum ton dry compost ingredients both manure added synthetic composts improve their physical and
It
0.04
lb /
0.6
of
6.25
75
7.00
to
Cottonseed hulls
to
0.12
be
22.00
be
( ton )
0.6
25
,
(% )
of
(ton ) 20.00
,
( ton )
Straw
lb /
N content
Dry wt
ni
age sludge dried blood are added Inorganic trogen sources such ammonium nitrate calcium cyanamide and urea may also used but their rate dry ton ingredi addition should not exceed only synthetic ents and should added com
pile .
as
Wet wt
Ingredients
compost
or
hulls synthetic
Table 4. Wheat straw -cottonseed
4
at
,
to
.
As
in
in
,
of
in °
45
at
C
to
of
As of
.
,
is
at
.
.
,
,
as
by
,
is
.
of
)
(
° F ).
in
to
C ,
of
°
80
up
to
,
,
a
.
is
It
.
it
C ,
°
in is
.
It
.
at at
.
,
,
,
of
of
-
by .
.
Another browning reaction
of at
)
(
,
the various compounds which have been iso lated These compounds exhibit increasing chemical complexity are degradation products either the tion
sugar
the
initial
carbohydrate
amine reaction
1
,
in
.
of
or
;
,
in
Maillard occurs this case the amino group proteins reacts with the amino acids peptides sugars Several stages hemiacetal hydroxyl group this reaction have been identified chiefly rela higher temperatures
of
,
from sugar anhydrides
-
,
,
,
,
,
,
as
(
% )
to
(
of
to
.
1
greater than percent raise the nitrogen content the compost the desired 1.5 1.7 level sup plements containing primarily organic nitrogen such poultry manure brewers grains cottonseed meal soybean meal cocoa bean hulls malt sprouts sew
one the reactions responsible for the darkening color the compost Dark colored polymerization dehydra products are formed consecutive steps tion and condensation with further loss water
or
. 2
To
is
of
,
a
of
nitrogen content Good quality hay may have percent but when mixed with corn cobs the total ni trogen content just slightly the bulk ingredients
proceeds most rapidly temperatures exceeding 100 will take place composting temperatures The higher the com posting temperature the more rapid the reaction
,
,
of
In
in
.
of
-
an
,
is
droppings and liquid waste which give the source average nitrogen con straw bedded horse manure percent synthetic compost tent 1.2 the case the protein the hay becomes the nitrogen source
Although caramelization
,
,
N
is
In
.
pH
of
is
at
be
am
.
substances later used the mushroom Gerrits sug gests nitrogen supplementation used until the filling monia content 0.4 percent and the com post 8.3 horse manure compost the
thereby concentrating the car from the carbohydrate saving bon and this valuable food for the mushroom
of
,
by
to
,
active fermentation and provide sufficient nitrogen shall discuss later carbohydrate combine with molecules form humic
Proteus
becomes
rise the temperature within the pile continues through the 60s 70s and the activities occurring within the pile change from largely biolog carbohydrates ical chemical Caramelization place process takes which eliminates water
or
to we to
as
of
to an
a
efficiently complete
leased this time urea bacteria such The and Aerobacter The pile Micrococcus alkaline
of
to
;
of
be
.
to
,
if
microorganisms supplements also need nitrogen grow and reproduce The nitrogen content they are the compost pile should 1.5 1.7 percent before the composting process begins this will assure that nitrogen the microbes have sufficient supply
the temperature increases the microbes reproduce and grow that love heat thermophiles and turn give off more heat Much the nitrogen present ammonified and much ammonia re 112
As
of
,
to
In
by .
ily
rect nutrient addition for consumption the mush carbohydrates supplied primar room addition the bulk compost ingredients and some the
sim
organic
acids Most the initial mesophilic organisms are growth capable temperatures exceeding
to
at
di a
by
,
in
is
of
.
of
the bulk compost ingredients and the supplements nutrients The addition this time directed therefore toward the feeding microbial population the compost rather than
are
of
supplied
compost
ucts the most easily attacked constituents ple carbohydrates which break down
to
by
.
is
,
iii )
oxygen and suitable temperature , ii ) moisture , available food Food for the microorganisms
iv )
i)
rises rapidly and the mass becomes slightly more acidic because the decomposition prod
temperature
.
croorganisms ( microbes ) . With the addition of water to the dry ingredients and the building of a pile , these microbes grow and reproduce . Their growth requires
Initially ingredients the compost pile are am bient temperature and are slightly acidic the multiply the digenous mesophilic organisms start
(
into piles . The piles are then periodically turned , watered , and formed . This mixing and water ing tends to equalize the environment so as to pro mote a uniform breakdown of the ingredients . Compost ingredients harbor a great number of mi
of
gredients
product . Dark - brown , insoluble polymeric com pounds are formed in the later stages . The first step ( which is usually colorless ?
;
of the glycosylamine The liberation of CO2 is a
in the reaction is the formation ).
characteristic of the sugar - amino acid reaction . The rate of reaction increases with increases in pH from 7 to 10 , the more marked browning occurring at pH 8 or above . The sugar -amine link is less susceptible to hydrolysis , thereby decreasing the availability of pro tein constituents , and the sugar residue becomes
cess , heat , excess ammonia , respired carbon dioxide , and respired and evaporated water are given off. The microbial thermogenesis follows a normal growth curve of thermophilic microflora as is shown in Fig ure 2 , borrowed from Tschierpe's paper published in Mushroom News . The similarity between the compost
more susceptible to dehydration . The total amount and extent of the specific browning reactions that occur is not known . Each time the pile is turned , bio logical activity is stimulated and the compost heats to levels higher than those of the preceding turn .
temperature curve and a typical bacterial growth curve is obvious . The rate of thermogenesis varies , depending on compost and environmental factors ,
Phase I is considered complete as soon as the raw ingredients have become pliable and are capable of holding water , the odor of ammonia is sharp , and the dark - brown color indicating caramelization and / or the browning reactions have occurred .
but peak rates can be 10 to 11 BTU per hour per lb dry matter ) of compost . The ammonia production curve from mushroom compost during Phase II , as shown in Figure 3 borrowed from Sager's data , was
PHASE
by the compost / temperature differ production during Phase ential and the ammonia can indicator the progress and termination Phase The activity the microflora generally clines after the first hours Phase Such
also similar in shape to the typical microbial popula tion curve . The heat generated by the microbial action air
i
control of Phase II composting . Available foods for microbes in the compost at filling , consisting of carbo hydrate and nitrogen foods , are utilized by the dy namic microbial populations , during Phase II , to pro duce microbial products at spawning which are ulti mately utilized by the mushroom . During the pro
a de of
ef
an
of
a
in
on
,
of
II .
of
60
to of
40
be
dominant
air
.
become
of
be
to
it
if
,
.
is
II
or
as
on in
.
of
be
normal population the thermophilic would have the particular flora The heating compost
surrounding causes cool drawn towards the heat and this action assures adequate air move oxygen content ment for microbial growth the adequate Pasteurization house Phase room
,
or
is at
,
.
which
trays are filled the compost be Once the house gins microbes Activi heat through the growth presented ties taking place this time can Figure borrowed from Sager's thesis which to
on
fect
expected
normal growth curve The temperature course the respiration rate and a
.
of
flora
be
can
of
be
II .
of of
to
is
.
of
following
temperature and
objectives
would
reduction
.
Through the proper manipulation ventilation these two primary realized
1 ,
at
Microbial foods filling
Microbial
1
{
Heat
{
{ {
products
spawning
1
by
the mushroom 1
range
1
temperature
Foods utilized
Microbial thermogenesis
microbial
Microbial
Respired
Respired and
carbon
evaporated
dioxide
water
nitrogen
Source
Sager
5
composting flow diagram
:
Phase
.
Figure
1.
foods II
of
composting in
|
The end products Phase
at
Microbial
Excess ammonia
{
1
carbohydrate foods Heat
I
į
)
(
it
so
:
II
Phase has two main purposes final conditioning compost becomes mushroom specific absence ammonia and readily available carbohydrates and necessary pasteurization free the Pasteurization insects compost and microbes undesirable
an
II
II
as evidenced
an
or
all
° F
of
be to
.
If
a
,
of
reproduce some harmful organisms may remain grow difficulty subsequently and These can cause the mushroom crop After hours 140 cool air introduced into the Phase room assure ade and quate oxygen cool compost below 140 produced help dissipate ammonia The ammonia from inorganic nitrogen sources from protein mol peptide linkages ecules amino acids united The .
Time
is in
to
culture
° F
to
° F,
iii )
i )
II
.
split into peptide fragments through individual amino acids providing im mediate liberation ammonia when another energy ,
of
of
)
a
If
.
is
of
.
an
,
an
as
,
is
of
4
Days
3
2
be
30
,
is
)
as
carbohydrate carbo available source such hydrate source acids and amino available not protein may produced part amides with the adequate being used energy source When carbohydrate present amount ammonia libera (
( 4
11
Phase days
during
hydrolysis
is
protein chain
Compost temperatures 40
).
(
50
by
or
.
is
,
ii )
° C 60
,
of
curve
bacteria
2
a
Growth
° F,
to
be
closed tightly allow the compost procedure heat the Either can produce the same result minimum 140 air and compost temper ature for hours the compost and other ex posed surfaces are not subjected temperature this completed and regime pasteurization will not 2
Lag phase
Logarithm
Exponential growth
to
air
of
house may
air .
cell count
Dying phase
to or to .
2
or of
a
° F
of
phase
be
Stationary
II .
Phase
of
be
accomplished toward the beginning Pasteurization requires air and compost hours temperature minimum for 140 introduced into the room house may Steam temperature raise the 140 the room
should
at
is
in
.
growth factor They include Actinomyces
Thermomon
.
),
,
Streptomyces encountered Fungi Humicola most fre (
10
-
to
,
.
be
of
or
If
.
-
a
PPM
Aspergillus and thermo tolerant mesophilic fungus fumigatus compost one were isolate from the on trays fungi and actinomycetes the surface beds would found Isolations from compost within the
1 )
(
by
.
)
.
or
mesophilic microflora Some spe the thermophilic cies especially certain Humicolas the most com monly encountered heat mold are especially adapted compost Humicola lanuginosa pro utilize starch
.
in
)
(
,
Phase
II
from compost during
to
:
.
3.
Ammonia production composting Source Sager FIGURE
of
,
.
),
as
(
,
,
80
hours
(
0
60
40
by
the thermophilic microflora Available and cel hemicellulose starches lipids fats energy foods for the microbial popula lulose serve tion Sugars are rather universally used most
used sugars
0
20
earlier and depicted the Phase that carbohydrate foods are also in
was mentioned schematic Fig
It
II
Pasteurization
.
is
to
is
.
or
tray would yield mostly actinomycetes bed The incorporated into microbial cells and ulti ammonia mately the mushroom available
Time
6
Mucor
,
Chaetomium
,
Torula
,
(
),
15
and Thermoactimomyces quently encountered
Ammonia
concentration
frequently
most
,
spora
a
in
as
is
of
(
microbial
)
to
best accomplished thermophilic heat loving organisms using organisms very efficient This group present compost the ammonia the nutrient
20
) (
ammonia
by
Conversion
of
is
protein
.
,
built into microbial protein
re
,
is
;
tion runs parallel with carbohydrate decomposition when carbohydrate excessive ammonia liberation protein nitrogen reduced since the once
is
:
.
II
peratures
Similarity bacterial growth activity and compost tem during Phase composting Source Tschierpe of
2.
FIGURE
substantial extracellular amylase Thermophilic well some mesophilic molds such pergillus fumigatus appear better utilize able .
,
,
re
.
It
20
60
40
of
10
80
100
120
Time hours (
is
and
during Phase
II
air
4.
compost
.
of
Typical temperatures FIGURE composting
C
°
)
-
(
45
55
Temperature
35
or be to is to
range
Air temperature
(
6
5
4
3
2
for
to
.
II
:
137
°
(
4
to
3
is
,
C )
°
60
reach
held for With sufficient compost differences .
by
to
(
to 58 °
F
air 6).
5.
of of
an
°
hours
temperatures
the temperature accomplish pasteurization
of
in
is
A
to
)
12
to
for
( 8
.
is
.
,
in
,
,
circulation the temperature and the air are minimal small amount fresh air introduced continuously The temperature then brought slowly hours the optimum
7
to
C )
25 °
(
F
77 °
to
be
,
10
.
5
. A
is
50 ° C )
to
2
(
of
°
F
conditioning level 122 CO concentra percent After maintained tion 1.5 days ammonia drops below ppm and the compost can cooled with fresh air for
Lignin Humus Complex Figure The right hand sector
in
.
'
of
7,
is
composting summarized adapted from one Gerrits papers
The discussion Figure
on
.
spawning
deals with the for lignin humus complexes
and
the total lignin remains 7
.
-
II,
Throughout Phases
7
rich
of
nitrogen
-
mation
I
.
controlling and programming devices composting Source Vedder
Phase
Vedder Fig When compost and
of -
on ,
.
to
system
/
is
.
,
a
in
The effects
automatic
.
be. or
in ,
,
.
-
,
-
,
heat the compost
II
FIGURE
is be
it
)
in
.
,
of
,
of
and steam intro the desired temperaure bulk system has been illu
closed fan switched
typical Phase
Days
in
,
of (
air
is
to is in
Compost temperature
be
.
in
of
.
° F ( 3 °
C )
-
aa
In
In
compost mass pasteurization filled uniformly and loosely into the tunnel Temperature probes are placed air and compost throughout the room The
A
86
140
with the standard bed system and higher dry weight potential filled into production beds
duced
95
strated
also good for mass pasteurization Apart from reduced wear buildings beds trays equipment pasteurization permits more and mass tensive use the growing rooms when compared
room
40
of
,
a
is
There
A
un
.
Tu
ta "
104
.
”
in
;
compost treatment oxygen can layer where reduced differential between in
side and surface temperatures the compost layer equipped need not differences bulkroom well more than 5.4 compost good for normal peak heating beds trays
72.5
113
30
,
a
in
and energy savings
II; .
needed
Pa
50
be
/
,
II
A
.
4.
II
“
or
Phase
During peak heating the required brought right into the compost IK
122
). in
**
Reported advantages include ease filling empty controlling and managing ing and spawning ease ,
ed IN
7
TUTE
131
5
net er
theory and principles can also applied pasteuriza pasteurization systems bulk Mass pasteurization tion bulk was first developed Italy and France and subsequently applied and fur ther refined the Netherlands Phase
bulk Peak heating mass pasteurization in
F
5 °
can
60
140
in
be of
,
temperature
by
like
dece
the compost
dropped
typical Phase pattern may for spawning Figure temperature pattern seen This time any pattern the grower chooses can now automat programmer and controller Fig ically controlled
in
DATE
75 ° F
si
.
z
,
temperature range giving the thermophiles time convert the ammonia Once the odor ammonia
gone
OF
per 24 faster than hours the desired
96
at
of
to
.
regulated
so
ventilation must no
135
cooling keep the rate hours This will assure least as
TA
and
115º
° F;
tween
be
at
.
II
in
an
.
of
II
Pasteurization
80
of
a
at
رمم
100
)
of
120
in
.
50
)F°(
temperature
Compost temperature
140
.
to
duced the raw materials The fatty acid composition also changes Linoleic acid content nearly doubles portion the linoleic least seems probable that biosyn remaining acid after Phase the result thermophiles thesis Oil supplementation com post before Phase results even higher level linoleic acid temperatures be The thermophiles grow best by
di ni
ei
fat
Quantitatively the content percent the original lipid
,
viridis about
in is
,
,
monospora
.
The test the Te 1 .
PETE
A Air
Temperature
as
As
.
(
to
be
to
cellulose than thermophilic actinomycetes Chaetom ium thermophile Humicola griseа Sporotrichum thermo phile and Torula thermophila show greater cellulolytic ability than do Micromonospora chalcea Streptomyces glaucus Thermoactinomyces violaceoruber and Thermo
,
TUH
,
nur che
)
molds
as
as
dcom
eginnie duces
COM FORTE TRATIE BLESSON
CONGO
SI
Compostrawmaterialsand supplements
Carbohydrates , incl Sugars Fats Hemicellulose Cellulose
Nitrogenouscompoundsincl. Proteins Aminoacids Urea Lignin
Microflora(thermophilic bacteriasuchas Bacillus, , Flavobacterium . Pseudomonas and Serratiasp., thermophilic fungisuchas Humicolaand Mucor sp., actinomycetes . mostlyStreptomyces sp.)
Microflora(plusurea , bacteriasuchas Proteus MicrococcusandAerobactersp.)
Lignin
N
N
CO но
Caramelization
Caramelized carbohydrates
P DO
by microflora C andN assimilation actinomycetes (thermophilic suchas Thermomonospora , Streptomyces , Thermoactinomyces sp., thermophilic fungisuchas Humicola , Torulasp., thermophile , Mucorpusillus, Chaetomonium , thermotolerant Stilbellathermophila mesophilessuchas Aspergillusfumigatus
Degradationproducts
0 0
N
Productsof intermediary NH + metabolism
Heat
Z
Microbes
D
N
O
N
N 21
N -richlignin humus complex
Compostfor mushroom
FIGURE 7. Schematic
summarization of mushroom composting .
6. Compost
and
during Phase
temperatures
com
.
posting
II
FIGURE
air
Source : Gerrits
.
of
Researchers have analyzed compost constituents dur ing various stages the mushroom crop cycle Ash content remains approximately the same throughout cropping The major part the lignin consumed is
of
of
its
What Mushrooms Need
.
of
a
-
,
to
.
of
be
.
,
portion essentially the same However the lignin disrupted via microbial degrada molecules may products tion Degradation various sizes are formed and these contribute the formation dark colored humic substances by reactions with ni
with length treatment Complex formation takes place more rapidly with increases temperature and ammonia concentration Some researchers have
summary enzymatic breakdown into the cell lignin and cellulose could follows Lignin and lignin complexes are broken down lignase phenolic compounds Further degradation laccase .
by
to
by
:
as
be
A
of
of
so
be
-
.
.
.
N
to
by
,
.
(
.
.
at
be
)
at
of
idly fruiting Cellulase which breaks the start down cellulose can detected throughout the same fruiting The changes period but increases sharply ,
to
to
,
if
to
us
Let now turn our attention what the mush room uses from the compost and see we can relate accomplish during this what we have attempted composting 8
yields quinones and aromatics which are more solu ble Cellulose broken down cellulases short chain oligosaccharides and disaccharides and eventu ally into glucose Extracellular laccase increases during spawn run and after casing but declines rap is
is
.
be
80 in
a
II
I
.
the lignin fraction
-
in
.
.
of in
of -
of
high proportion and compost the fixed the per humus lignin fraction the compost About cent the insoluble nitrogen could isolated from the total nitrogen
.
re
-
N
of
in
.
of
.
of
.
of
shown that during Phases
of
between spawning and the appearance the first pinheads Cellulose decreases rapidly when fruit bodies appear and enlarge The mushroom mycelium produces extra cellular enzymes which break down insoluble food particles that they can absorbed
N
trogenous compounds derived from protein and degradation Humic substances can react with con taining compounds low molecular weight The action with ammonia results the stable absorption nitrogen The content the complex increases
It
.
all
.
,
of
-
at
be
an
in
of
I
II
or
.
to
be
,
,
a
if
so
if
).
(
-s
;
as
.
a in
is
II .
In
as
an
or
I
in
II,
a
.sp
to
In
.
.
,
,
.
ar
to
as
to
,
.
I
of
,
as
.
of
II
or
of
,
,
-
fimicola was com composting mon years ago when the longer Phase rarely seen was routinely practiced today composting The farms following the short method .
white plaster mold seen most frequently today piluliferum
Bo
.
tryotrichum
is
;
it
of is
on
I
Scopulariopsis
II,
as
° F ).
at
of
).
(
The olivaceum Chaetomium Olive green mold presence sufficient oxy this mold indicates lack especially gen within the compost during Phase yet unknown higher temperatures The 145 (
lo
sugars and amino acids
in
.
,
,
to
,
the reaction between
are also cellulolytic
.
re
in
,
.
of
in
phenylalanine leucine isoleucine and valine most stimulating mushroom production Ear
,
lier
In
in
,
lial
are
rich
car
Sporobolomyces trichum piluliferum and Trichothecium these molds generally indi The presence mismanage cates over composting during Phase ment Phase such that the compost becomes alka line with residues amines Most these molds can carbohydrates utilize soluble carbon sources but roseum
of
As
.
is
is
have
can utilize cellulose
White plaster mold Several species are included lump growers tend under this general heading species This list these together without regard bitrarily will include Scopulariopsis Botryo fimicola
of
.
.
is of a
In
vitro studies
bohydrates Coprinus bon food source
-
be
to
,
.
protein
improper Phase tation Phase other words proper environmental conditions were not preventing maximum mi provided during Phase readily available car crobial utilization addition ,
,
by
-H
of
of
of
.
microbial
shown that the amino acids phenylalanine methio promoting myce nine and proline are most active growth the cultivated mushroom vivo sup plementation studies have suggested that proteins
present
..
a
of
to
by
an
of
,
80
,
-
in
cated
Coprinus fimetarius
-
of
a
1 : 1 .
of
,
)
in
of
.
ni
trogenous compounds become limiting discussed percent earlier about the total nitrogen the maining after composting apparently fixed probably humus lignin fractions The remainder
1 )
in
in of
.
as
.
.
It
tion between the nitrogen content the compost and yields increased both manure and synthetic com posts Supplementation studies during various stages mushroom cropping have shown that specific
Ink caps will grow compost free ammonia the This fungus nitrogen source usually utilizes free ammonia the ammonia comes from nitrogen over upplemen Ink caps
2 )
.
oil
it
by
is
(
lar
tiates this The remainder are probably complexed with humic substances lignin and protein positive correla has been shown that there
Indicator Fungi
Lets now briefly discuss some compost competitor they show up grower may indicator fungi that know why they are there and what must done avoid their showing up again
3 )
'
its
to
to
to
as
H
-
-6
from the compost appear intracellu thermophilic microflora within the cells lipids thermophilic fungi substan Fatty acid composition
or
A
.
to
)
In
the mushroom also provides necessary reducing power generate mannitol since synthesized mannitol the mushroom from fruc phosphate via mediated reduc NADP tose tion reaction The majority the lipids used the mushroom
.
Competitor
between the mushrooms lipid metabo fruiting mechanism has been established addition has been shown that the carbon units supplied supplementation the compost via are synthesize utilized structural lipids mushroom cell membranes biological The rapid production membrane material for expanding cells the devel oping sporophore requires generous supply lip proteins since the membranes have ids well lipid ratio protein compost Oxidation
NADP
-
,
a
.
relationship
(
room production
fatty acids
be
to
of
-
to
of
.
in
optimum environment Phase and that will enhance the ecological succession thermo philic microorganisms order for proper biological transformations occur during Phase are required produce selective medium for efficient mush supplemented
has been shown that lipids specifically the fatty acid linoleic are stimulatory mushroom production lism and
for the mush
conserved
a
to
os
of
19
is to
12
.
)
of
motic potential for increased water absorption the developing mushrooms expanding cells The mushroom utilizes lipids from the compost
therefore
room's later use may least part the reason for lower yielding anaerobic and low temperature Phase compost high temperature aerobic properly summary
In
to ,
.
in
(
at
provides substances for mannitol synthesis percent Mannitol comprises the dry weight thought the mushroom and provide the
cose
sugars and
I
,
ap
It
.
,
(
It
)
,
in
enzymes xylanase protease phosphatase laminarinase and have been detected has been suggested that the cellulase activity crease first flush breaking down cellulose into glu other
browning reactions , with subsequent formation of dark -colored humic substances , was discussed . It is of interest to note that valine is one of the most react ive with glucose under alkaline conditions and that leucine and phenylalanine react little or not at un der acidic conditions One could speculate that the failure these specific amino acids react with
to
changes
.
of
in
by
of
,
of
.
to
,
of
to
be
in
laccase and cellulase appear correlated with enlargement fruit bodies and not with their initia tion The enzyme switch appears occur only once i.e. during the maturation the first break pears that the breakdown products the lignins are utilized preference the mushroom mycelium carbohydrates before the start cropping No such
10
of
it
,
(
).
in
.
"
"
It 45 ° C )
in
54 ° ° C F
(
°
F is
,
,
at
its .
as
.
7 )
a
in
in
of
at
of
of
as
.
.
,
C )
40 °
° F (
to
,
to
,
,
as
,
is
in
.
of
of
to
in
of
in
of
of
do
,
of
to
.
in
of
to
in
increasing new
to
.
our quest increased yields Using nutritional criteria evaluate compost may provide valuable tool not only for tional supplementation but for predictability consistency yield potential ,
a
.
mension
di
,
for
could open
up
thereby
mass
a
mycelial
yield potential
,
increasing
mushroom
,
as
a
room mycelium the compost and expressing mush yield efficiency mycelial mass room relation investigating methods the compost The possibility
of
.
,
it
.
as
of
or
some other limiting factor arises residues ammonia and amines re nitrogen food source for this main and serve mold Since produces cellulase the cellulose acts the carbon source
II, II
during Phase during Phase
mushroom yield we shall the best job mushroom England composting Dr. David Wood the GCRI has recently done some interesting work on devel oping method predicting the dry weight mush room for maximization better position
.
If
of
.
in
of
ammonia and amines the compost insuf ficient available carbon sources remain for complete conversion above materials into microbial protein dues
As we continue learn more the exact changes taking place during mushroom composting and the specific vivo nutrient requirements the mush
in
this mold indicates resi
grow
organic materials the explanation for these black areas mushroom mycelium cannot grow elevated temperatures
of
II .
of
.
6 )
Presence
increase
growing
in of
available
can also
grisea fumigatus Penicillum Humicola Rhizopus stolonifer and Torula thermophila temperature when above 104
a
in
,
or
resulting
oxalicum
at
In
Generally indi during
supplementation
undercomposting Phase carbohydrate after Phase Oedocephalum
is
at
ignorum
.
compost ).
of
.
as
(l
5 )
Green mold Trichoderma cates inadequate nitrogen I
.
,
in
so
this type
pergillus
a
be
a
I.
of
or
.
of
,
to
compete
discussion
in
the compost the result
and
obviously therefore also the compost during the
indicator fungi requires least appearance mention the black areas the com post casing time These are areas which mush room mycelium apparently did not grow Recent studies suggest that the ability molds such As
be
carbohydrates condition may
spawning This undercomposting insufficient nitrogen supple mentation during Phase Excessive carbohydrate supplementation similar condition can produce compost mushroom mycelium will also this type Higher rapidly Doratomyces grow but not mixed spawning rates enable the mushroom myce lium
-
In
(
available
of at
residual
in
).
of
-
4 )
Sty Grey whisker mold Doratomyces microsporus this mold indicates The presence sanus stemonitis
112
indicates hot spots spawn growing period
ity
olivaceum
.
Chaetomium
can also result
ture for growth fairly well 130
of
in
room atmosphere
of II
.
the occurrence
or
for
in
much compaction , moisture , too thick a compost layer , or having the room or house air temperature above the compost temperature several hours sufficient oxygen the mushroom house Phase
Thielavia thermophila An indicator similar com post conditions Oedocephalum Thielavia thermophila optimum tempera different however that
A
compounds formed under these anaerobic conditions appear to be toxic to the mushroom but not so to C. olivaceum . Restriction of air flow and reduced oxy gen supply into the compost can occur because of too
qual nutri and
Some Biological Indicators of Compost Quality Cathy Harvey
and other essential nutrients becomes unavailable
nitrogen
,
AND BACTERIA by
,
the temperature climbs these mesophilic fungi populations and bacteria die out and are replaced thermophilic heat loving microorganisms Tem necessary for the thermo perature exceeding 112 .
,
to
grow and
as
philic bacteria actinomycetes and fungi Ammonifying bacteria such reproduce
Proteus
Micrococcus and Aerobacter utilize inorganic and or ganic nitrogen carbon and are accompanied 11
attack and a large portion of
THERMOPHILIC FUNGI ACTINOMYCETES
by
microbial
its
nitrogen compounds of low molecular weight into the lignin complex . The resultant product , the nitro gen -rich lignin - humus complex , is quite resistant to
and spore - producing bacteria metabolize available nutrients and contribute to the rise in compost tem perature .
)
coupled with the release of ammonia from urea and protein degradation along with heat released by mul tiple chemical reactions that occur at temperatures ex ceeding 140 ° F . This seems to favor the absorption of
Mucor, and even Doratomyces ( the Grey Whisker Mold fungus ) . Nonspore - producing
daria , Alternaria ,
,
nitrogen is bound to the lignin molecule are not com pletely known , but the reaction is favored by high temperatures ( above 140 ° F ) and high pH . More spe cifically , the incorporation of nitrogen may be favored by the partial breakdown ( by the microbes ) of lignin
form of heat . Fungi observed at this stage of com posting include species of Penicillium , Aspergillus , Sor
F is
As these substances form , reactions of great practical import occur . In Phase I , these reactions permit nitro gen to become an integral part of the lignin - humus complex . The mechanism or mechanisms by which
,
Composting
-
I
. Following the addition of water and in organic / organic supplements to the raw compost in gredients , storage fungi that survive long periods of drying start to grow rapidly and release energy in the
composting
°
Phase
,
(
bisporus nutrition .
high - quality compost is the result of an aerobic fermentation ( during Phase I ) involving the following organisms which precede the essential higher - temperature chemical reactions . First , the number of mesophilic and thermotolerant fungi and bacteria increase during the initial stages of outdoor
,
the
More specifically
.
two groups of compounds – one modified from original plant tissue and the other newly synthe sized by microorganisms - provide the basic frame work for the lignin - humus complex and for Agaricus these
MESOPHILIC AND THERMOTOLERANT FUNGI
,
The latter compounds are synthesized by thermo philic organisms and become a component of their cellular tissues . Although not clearly understood ,
ping cycle . A series of high temperature ( 140 ° F and higher ) reactions , which support growth of microor ganisms , reduces the reactivity of carbohydrates to enzymes of the compost microflora encountered later in cropping , and increases reactivity to specific en zymes produced by the mushroom mycelium .
As
pounds are rapidly depleted , yielding intermediate compounds at first , then simple products of microbial digestion . As decomposition occurs , two major or ganic substances of higher plant origin remain in the compost: resistant compounds ( such as oils , waxes , and lignin ) and newly synthesized compounds ( such as complex polysaccharides , proteins , and lipids ) .
Another reaction in Phase I composting is the for mation of carbohydrate compounds that are pro tected from microbial digestion and thus serve as a nutrient reserve for the mushroom during the crop
of
Good compost quality is the result of a biochemical process in which organic matter is consumed by gen erations of thermophilic bacteria , actinomycetes , and fungi . Easily decomposed carbon and nitrogen com
to
microbes .
competing
,
COMPOST CHEMISTRY AND THE ROLE OF MICROORGANISMS
or
to
at
° .F
.
of
is
of
° F .
°
;
in
-
at
.
at
of
of
of
.
of
,
in
of
F
-
,
-
as
°
,
.
to
is
in
,
of
of
in
is
-
of
a
,
in
of
)
a (
in
a
.
in
of
,
be
.
of
,
,
,
,
by
,
in
.
to
II
I
or
,
.
of "
("
to
,
)
in
,
,
,
of
in
.
Compost
imbalance in
.
I,
nutrient be
a
on the microbial During succession will discussed first Phase in organic nitrogen and nitrogen organic protein are utilizing carbohy compost microbes degraded products compost energy drates the sources degradation microbial include the ammonia re plus lated compounds amine amides ammonia compounds CO2 and H2O The ammonia evolved during Phase form major fraction the food base used the thermophilic microflora during Phase However when the nitrogen content Phase com of
The effect
-
.
By
,
as
-
)
,
,
of
II .
the Phase
I
of
carbohydrate
necessary
thermophiles
,
continued
growth
of
post exceeds the amount
II
.
,
degrade pure cellulose
Fungi and Nitrogenous Components
of
.
,
in
.
12
Streptomyces
.sp
of
,
post
during cropping
a
.
of
in ,
Malbranchea
sion tions favorable
(
a
)
of
and Talaromyces general show greater cellulo Thermophilic fungi lytic ability than actinomycetes However the most actinomycetes mushroom com common genera
,
thermophila
alters the sequence succes creating condi weed and indicator molds later on
.
to
-
.
(
thermophilic fungi that can util group complex only cellulose The second forms ize less ary cellulose degraders include the fungi Stilbella
particular
thermophilic microorganisms
I
assimilate carbon source substrates with de cellulase enzymes These fungi have the ability grade crystalline pure cellulose and must precede
Myriococcum
Phase
by
,
insolens
and
new nutrient substrates and consequently favor the growth different compost organisms Third recycling during improper temperature control
in
Torula
yield Second cultural practices that lead anaero biosis during Phase Phase cause the formation
,
ef
Thermophilic ,
.
H.
,
of
as
Humicola griseus
secondary
It
-
,
of
° F,
II .
of
60
populations occur
fungal
the compost for example alters sub and nitrogen thermophilic actinomycetes bac strate utilization creating surpluses that are utilized fungi teria and compost molds Such imbalances may reduce
II
of
in
.
,
is
,
As
number
or
that desired Many factors can cause shift the der succession but only three will discussed First an imbalance the relative amounts carbon
of
ni
of
as of a
A
.
;
of
H.
and Thermoascus The rate ammo rapid process nia conversion most and the most Phase hours ficient during the first the temperature falls below 128 the greatest Mucor
part
micro ecological the occurrence succession some regime other than
by
.
,
in
group trogen for use noncellu cell synthesis lolytic fungi assist the Actinomycetes the conver sion ammonia these include Humicola launginosa
and chemical
.
of
of
-
,
II
,
source
view poor compost
microbiologist's
consequence
,
am
in
,
in
be
no
.
actinomycetes
From
by
se
a
of
two genera
commonly found absorb ammonia
mi
lular structures members the thermophylic croflora form rich reserve for Agaricus
of
of
is
II
If
.
More specifically the micro ecological succession generations during Phase thermo consists philic actinomycetes and fungi Thermoactinomycetes
fungi such
pecially linoleic acid that stimulatory mushroom Polysaccharides and protein reproduction the cel
of
dur
completed
proper succession has occurred the compost monia and simple carbon compounds will have been longer present consumed and will the com post substrate
stellata
mi
POOR QUALITY COMPOST
and the result controlled ecological thermophilic microorganisms succession which lectively utilize the remaining unstable nitrogen com pounds and easily available carbohydrates the
and Thermomonospora
nutrient trans
below 112 and most the thermophilic perish leaving crobes residue their lipid protein membranes The membranes contain fatty acids es cools
for
is
-
good compost quality
of
Formation ing Phase
impor
Most
.
.
Ecological Succession
Composting
II
Phase
are the sites
a
mushroom growth
140
.
to
a
of
to
sential
and
port into the cell and the mechanism release Following depletion products toxic metabolism nutrient substrates the compost the compost by
,
of
.
° F,
and the other browning reactions es the formation substrate specific for
cell wall membranes
-
.
of
,
a
-
die out and the heat from chemical reactions causes caramelization
112
the cellular membranes tant fungi are most elastic high range temperature this they dissolve higher temperatures and become im permeable The cellular and cooler temperatures
to
to
of
is of
I
Phase time initial substrate conversions but the the succession and action more importantly pave the way for the microbes and thermophiles higher temperature chemical reactions When tem perature rises above 140 the thermophiles start
between
the lipid protein
,
,
S.
.
,
generate additional metabolic heat through aerobic respiration and nitrifying actinomycetes keep the other ammonia below levels toxic concentration members the compost microflora
temperatures
-
of
At in
.
,
complex for reaction with nitrogen the same time cellulolytic Streptomyces thermovulgarius and rectus
that these microorganisms are bio adapted the relatively high temperature Spores propagules environment these organ Enzymes are stable isms germinate above 112 interesting
logically
of
in of
,
,
fat ,
consuming Bacillus , Flavobacterium , Pseudomonas , and Serrata species of bacteria . This latter group attacks cellulose starch and the waxy cuticle the straw Bacteria also degrade parts the lignin the the molecular straw possibly opening some sites
1
heat - loving fungi and actinomycetes may perish be fore the conversion of ammonia to microbial protein has been completed . The result is the presence of amines , amides , and ammonia in the compost sub
trient substrates can be formed , and these may favor the growth of unwanted organisms . Anaerobic com post in Phase I is caused by a lack of oxygen during the composting process . Without oxygen , the carbon
strate – these substrates support the prolific growth of mesophilic compost fungi when the compost is cooled for spawning . These fungi include the White Plaster Mold fungi, Coprinus sp . , Oedocephalum sp . ,
dioxide and hydrogen form by - products of anaerobic respiration . Formation of these compounds causes a drop in pH and temperature ; both effects are detri mental to compost quality . The anaerobic environ ment reduces efficiency and may even prevent chem ical reactions that are necessary to incorporate nitrogen into the lignin complex ; nutrient supply be comes limited and yields are reduced .
a
its
of
,
is
II )
;
Compost Temperature in
”
Improper temperature control particu recycling during Phase can lead alteration the micro ecological succession during cook out The up
in
is
.
Improper Management
an
to
of
II
to
of
is
,
degradation clothing during World War also among the soft rotters wood utilizes portions the lignin molecule for growth it
of of
,
In
the reverse situation the carbohydrate content constituents may exceed the amount the ther nitrogen necessary for continued growth mophiles and may cause the Phase die microflora carbohydrates before conversion cell substances completed The result CO2 and H2O the presence the compost
spawn . This fungus is stimulated by anaerobic condi tions in Phase II but it can , also , be a serious competi tor for nutrients in mushroom compost . Strongly cell ulolytic Chaetomium ( famous for troublesome
.
Compost
lation of the growth of Chaetomium species by anaero bic compounds during Phase II . Unknown anaerobic substances and the accumulation of CO2 in Phase II rooms with less than 16 percent oxygen support Chae growth and inhibit colonization by the tomium
, “
Fungi and the Carbohydrate Component
of
infested areas . However , cellulose has also been re moved during Coprinus metabolism , and yield poten tial of the mushroom crop has been reduced .
cores of compost ricks , but metabolites produced by the anaerobes may favor mold growth later in crop ping . The only analogy that can be made is the stimu
to
.
and on mushroom growth is not well understood . Fungal molds do not usually grow in anaerobic
of
The growth of this indicator mold removes ammonia compounds toxic to spawn growth , and the spawn often recolonizes multiple cellulase enzyme system
has not received the attention placed on aerobic spe cies , and their influence on the compost microflora
of
Coprinus sp . is a coprophilous ( dung - loving ) fun gus that benefits from unconverted nitrogenous com pounds remaining in the compost after Phase II . It is similar to S. fimicola , in that the optimum pH for growth is around 8. Coprinus utilizes the ammonium ion directly and vigorously degrades cellulose by a
The most notable of these
II
during Phase II .
.
are the sulphur - producing bacteria . Unfortunately , the role of anaerobic microbes in mushroom growing
of
growth requirements , the appearance of Scopular iopsis sp . has been associated with alkaline compost containing residual amines not converted into protein
the absence of competition
-
ions as nitrogen sources . An alkaline pH ( between 7 and 8 ) favors nitrogen assimilation . Due to these
The anaerobic substrate during Phase I is not with out life . Organisms that require no oxygen flourish in
lar ,
and Thielavia thermophila (Sporotrichum ). One of the fungi in the White Plaster Mold group is Scopulariopsis fimicola . Some fungi in the genus Scopu lariopsis degrade starch , lipid , hemicellulose , and cel lulose as energy sources , and use glucoseamine , demethylmamine , methylamine , and ammonium
of
-
in
of
.
in
60
of
a
of
of
at
is
by
At
is a
II,1
"
.
,
,
re
.
a
in
a 5 °
.
of
of
13
ac en
is
to
'
in
-
,
'
to
Due the step wise reduction the amount sim ple carbon sources these born again microbes break get carbon apart proteinaceous compounds ergy The nitrogen released about ten times that .
nu
.
to
temperature rise
the microflora has been consumed temperature can cause this time even rise surgence the thermophilic species that were domi during nant the beginning the pasteurization cycle -
a
in
.
to
to
bohydrate
,
in
of
of
II
consequence
of
on
in
.
a
Cultural practices that lead anaerobiosis during compost quality New Phase are harmful or
Recycling
.
, for
is ,
as
.
,
.
Anaerobiosis During Composting
I
“
,
by
be
.
Adsorption these compounds creates stronger foothold for the mold organisms the com greater ability compete with spawn for post and space and nutrients during cropping
ecule
.
especially after the end during Phase the first hours This near the point which most the car
-
sugars and become quite visible the compost under fungi these conditions These also use lipids var ious forms and will use components the lignin mol
,
set causes an imbalance the relative amounts carbon and nitrogen the finished compost This supports the growth imbalance consequently var ious weed and indicator fungi
of
partially digested cellulose and hemicellulose starch These may certain mesophilic utilized fungi when the compost temperature reduced Fungi such spawning Aspergillus Trichoderma simple Penicillium and Doratomyces flourish
, on the other hand , creates surpluses of certain nutrients that encourage compost molds .
quality compost
MESOPHILIC FUNGI IN MUSHROOM COMPOST AND THEIR METABOLIC TRAITS
1 ).
of
for
.
to
by
)
is
of
.
(
Chaetomium are notorious cellulose This mold fungus with the possible excep Coprinus tion the most cellulolytic the fungi found mushroom compost also utilizes xylan phenoloxi degrade lignin and has the ability dase enzymes The Olive Green Mold caused by this .
SPECIFIC NUTRIENTS NEEDED BY SPAWN AND MUSHROOMS
Poor
2 ).
(
as
,
is
to
(
),
.
is
as
;
of
an
is
,
fat
,
,
,
,
-
on
.
of
,
in
of
as
an
.sp
of
It
.
II .
,
is
.
.sp
by
re
,
in
,
or
as
a
As
is
to
3 ).
a
,
its in
,
.sp ,
.
.
for
it a
to
Its
,
4 )
(
,
,
lig
of
in
.sp
It
is
.
to
in
of
be
.
to
is
,
. 5 ).
.
,
,
)
(
-
(
It
between wood rotting Brown Plaster Mold
basidiomycetes
and
.
-
tion
is a
it is
of
Some Papulaspora species are imperfect states bas idiomycetes possible that there and connec
Penicillia
Fig
6 )
be
to
bisporus
.
A.
of
a
.
highly nutritious
cop Plaster Mold fungus Fig This mold fungus rophilous dung loving and prefers wet alkaline conditions will utilize cellulose starch and lignin .
;
.
-
to
in
-
High quality compost provides substrate specific for the growth
similar
,
the
mycelium and transported cell wall the sites construction the developing mushroom Some pro tein and lignin compounds are still used lipid and lipid related sterols that regulate reproduction are transported throughout the mycelial network assimilated
the Brown Mold fungus Fig Coprinus enzyme terms degrades cellulose fat and producing ability why the two molds are some nin and this may compost poor quality times observed together Papulaspora byssina the Brown the name given Oedocephalum
(
to
by
are absorbed
of
(
glucans
)
.
,
,
to
di
-
.
to
-
at
is
of
.
glucose building blocks
-
growth son with nitrogen content will stimulate ability vigorous utilize lignin may make competitor with Agaricus food and space is
,
of
of
major
the first break the crop occurs and the cellulose
metabolic switch fraction the compost becomes the preferred energy source The lignin fraction this point relegated secondary status Alpha cellulose and hemicellulose polysaccharides then shorter are reduced and mono saccharides As the mushrooms enlarge
a
mushroom compost environment mentioned compari high percentage simple carbohydrates
,
.
During the maturation
14
named Stysanus
formerly
microsporus
commonly known Grey Black Whisker Mold Fig The fungus has versatile enzyme producing system and the well adapted
,
growth
Doratomyces stemonitis
.
of
by
for
,
these residues are enzymatically broken down the energy and mushroom mycelium and absorbed
spe
Coprinus utilized for growth strong competitive ability mushroom
are also
vealing beds
(
,
II
,
of
thermophiles along membranes residues Phase the polysaccharide slime surrounding many
with
lignin
of
-
-
.
by
is
Lignin phenoloxidase reduced pounds and then further degraded soluble prod protein Lipid cellular and cell wall ucts laccase
connection
ammonia
cifically residual ammonia after Phase This group fungi vigorously breaks down cellulose and culti vated commercially for straw degradation Lipids and its
in
fraction
the compost phenolic com
.
the cellulose by
to
preference
to to of
-
of
by
,
,
A.
bisporus removes nitrogen spawn run however lignin lignin degradation products rich and
indicator
is
.
During the
has been mentioned
-
,
in
the
pres
Coprinus
with Ink Cap fungi
,
by
its
life cycle evidenced compost extracts enzymes
of
ence
as ,
,
,
throughout
,
.
of
these major nutrients during production the mushroom crop Mushroom mycelium absorbs xylan phosphate protein and laminarin starch
zation
-
.
on
)
a
.
of
(
,
of
of of A.
needs
gus shows positive cellulase amylase and lipase ac respec degrading cellulose starch and tively will rapidly recolonize overly pasteurized casing soil and possibly feeds heat killed cells other members the soil microflora tivity
of
.
in
,
at
somewhat the the nutritional each Studies bisporus have revealed differential utili
.
is
,
rot
-
,
-
lose from woody tissue but vary considerably the which they attack these substrates relative rates Some basidiomycetes remove lignin much more rap
depending
poor compost quality the indicator mold will compete for the same nutrients the mushroom mycelium and thus undesirable Chromelosporium for fulva Peziza ostrachoderma merly named Ostrachoderma peziza many known growers The fun Cinnamon Brown Mold Fig fungus
clas Agaricus bisporus the commercial mushroom basidiomycetes The sified among the white white rot basidiomycetes utilize both lignin and cellu
idly than cellulose original amounts
in
species All species their degradation (
and
globosum
in
.
on
is
.
C.
C.
-
of
clude
production
enzyme
Chaetomium Fig olivaceum
It
.
recycling
available
compost invading fungi
of
of
a
for
by
is
nium ions use when the temperature Cap fungi benefit from
,
straws ammo unwanted mesophilic fungi spawning Ink reduced
Some information
of
to
on
solution the compost supply provides and
,
a
rise
for in
monia causes
pH
goes into
.
of
-
in
,
-
for
tually consumed by the microbes ; the excess is liber ated into the environment in the form of ammonia . At this time , the compost temperature is well be ammonia loving thermophilic acti low optimum nomycetes and relatively little carbohydrate remains support certainly not enough the compost organisms high populations these The excess am
are opportunistic fungi known for
coa
I
10μ
10u
Inflated branches
Spherical spores on pegs
Lemon shaped
-
to
.
on
;
on
to
or
woodwork
straws
each
stalk
,
in
.
of
-
to
.
on
Hyphae
microsporus
form upright stalks
feather like head dark spores Col resembling bristles onies grey black bears
a
,
;
end
3.
interwoven compost
compost
.
.
FIGURE
compost
in
on
terminal
Doratomyces
Conidio-
forming longated spherical swollen branches spores borne Colonies minute pegs white when young turning yellow gold at
branched
of
2.
casing
fulva
surface
,
.
-
;
.
Tufts bristles spherical fruiting structures lemon shaped spores are produced inside
Chromelosporium
phores grow upright ;
post
FIGURE
or
in -
.
the surface
of
burrs form
-e
Olive green straw comprotrude from the
Chaetomium olivaceum
of on
FIGURE
1.
spores
.
-
cinnamon brown with age
Chains
of
|
10μ
Oval spores
10u
spores
504
I
Inflated cell
.sp
or
; ,
,
of
,
,
,
.
-g
be on
,
brown
15
.
yellow
or .
-
aa
of
-
,
.
of
in
6.
of of
on
tuft
become
be
young
,
when
Conidiophores arise Penicillium singly from straws the compost from spawn grains Upper portion conidio forming brush like head phore branches branches bear groups flask shaped cells long chain spores each supporting Spores may spherical oval smooth warty depending species Colonies usually green but can blue reen white FIGURE
,
white mycelium brown with age
straws
a
.
Masses
or
.
,
to
.
,
byssina
,
mi-
.
.
borne
5.
.sp
spores
Papulaspora
spherical fruiting structures form compost Structures arise from .
oval
nute pegs Colonies silvery white when young turn light coffee brown with age
FIGURE in
end
Conidiophores casing Enlarged cell on
terminal
compost
or
on
Oedocephalum
,
at
FIGURE upright
4.
Flask shaped cells
Roughened spherical spores
Spores
Boo Segmented hyphae
10μ 10μ Rod shaped spores
form tufts . Conidiophores have branched side branches ; whorls of usually three flask - shaped cells bear compact clus spherical green ters of spores . Spores and minutely roughened Colonies white when young turn dark green with age .
,
,
areas
,
tip
at
on
FIGURE 9.Trichoderma viride . White mycelium may grow on compost or casing . Fruiting
[
Smooth oval spores
10u
.
-
.
FIGURE 8. Sporendonema purpurescens . Grows on compost or casing . Mycelium irregularly segment branched , branches into rodshaped spores . Colonies , white when young , usually turn pink with age .
or of
and
or
short
.
fimicola . Conidioirregularly branched . Flask - shaped cells scattered along hyphae ; each supports a chain of white spores . Spores narrowed slightly at each end , but distinctly flattened at the base ; characteristic rings folds are present spore bearing cell Colonies compost casing are usually snow white 7.
phores
,
Scopulariopsis
FIGURE
are
Rings
Spore chains
1/4
"
Inflated
tip
Flask shaped cells
.
in
8
microsporus
.
12.
sac
in
,
spore
sac
of
,
a
oil
.
in
,
.
spherical spores Colonies velvety green dark green and become almost black with
Diehliomyces
-
is
swollen and bears series shaped cells which support long chains
FIGURE
spores
Cream white mycelium aggregate into cot tony brain shaped fruiting bodies com post casing Smooth golden brown droplet spores each containing central groups eight inside the are produced or
of
.
flask
ConidioUpright
,
.
11.
terminal end
age
16
fumigatus
.
.
,
.
at
.
,
of
in
five
Aspergillus
phores arise singly from compost
,
cells
Spores are oval and smooth Colonies white first turn light green but never become dark green whorls
FIGURE
-
Grows
Similar arranged
to of
-
viride except flask shaped
to T. on
woodwork
.
,
,
koningii
.
Trichoderma
compost casing
are
FIGURE
or
10.
8
I
10M
re
af
be
in
.
fungi that have caused this condition are microsporus and Aspergillus fumigatus Fig
11 ).
,
(
.
Doratomyces
growing this mold shows the most selective enzyme abilities Species this genera utilize only certain degrade starch cellulolytic very but fats are not
If
car
.
to
in
Examples
8 )
(
of
,
is
.sp ,
of
.
.
.
on
be
by
It
post Rapid growth rates some compost fungi may generate enough metabolic heat kill the spawn this occurs the saprophytic fungi will then utilize bohydrates the cells the dead spawn mycelium
has been discussed This fungus overly composted manure thrives Sporendomena purpurescens the current name for Geotrichum the Lipstick Mold fungus Fig Among the weed fungi associated with mushroom
,
Mold fungi
of
ter
room - growing substrates and their ability to compete for cellulose , starch , fat, and lignin . Scopulariopsis fimicola ( Fig 7 ) , one of the White Plas
.
by
of
utilizes secondary products cellulose hydrolysis leased upon cellulose degradation other fungi directly must added that spawn may compost molds fected the growth the com
of
6
utilization of simple carbohydrates . Diverse enzyme production characterizes their adaptability to mush
of
in
12 ),
(
is
.
.
of
a
.
as
,
but
.
a
,
of
of
Its
Disease complex disrupts spawn protoplasm activity brings about brown discoloration the rhizo yield morphs and loss marked Other compost molds such the yellow molds
,
,
,
ley
(
.
13 ),
of
cel
.sp
of
.
10 )
(
does not attack pure cellulose
/
of
.
as
as
to 9 )
Fig
be
.
of
that disrupts Agaricus metabolism The toxin diffuses into the compost and inhibits spawn growth Fig Oidiodendron member the Vern Ast
inhabitants acid soils Trichoderma pure degrades Fig and has two cellulose viride hydrolyze the more simple products enzymes cellulose breakdown On the other hand Trichoderma koningii
in
.
.
by to
by
-
and
(
lulose
of
a
ap
up
in
is
,
as
in
of
the
vigorous degraders
,
is
It
.
environments will produce toxins that will dissolve mushroom cell walls Trichoderma Spot and Tricho derma Stipe are symptoms this host pathogen Fig Diehliomyces microsporus teraction the causal agent Truffle disease another toxin producer
Trichoderma species are well adapted substrates their diverse evidenced mushroom compost enzyme producing abilities and the observations most mushroom growers They are known outside
mushroom industry
to
,
,
.
do
,
,
.
in
pathogens Certain mold fungi considered may the mushroom excrete extracellular metabolite inhibitors that diffuse into the compost and inhibit acidic spawn growth Strains Trichoderma viride
possible that specific substrate requirements are reason for the common belief that the mold often pears when chicken manure making used the compost
10μ
roughened
spores
5р
|
Large
Connecting spores
10μ Swollen cells
2
Warty
of
Short chains
spores
.sp
to
,
of
at
on
-
Illustrations
the author
.
,
,
tan with age
.
.
on
or
,
15.
.
on
are
of
.
14.
.
are
Loosely branched Figure Sepedonium mycelium bear large spherical distinctly sculptured yellow brown spores ends compost are branches Colonies grow white when young and turn dull yellow
by
age
-
.
,
-
Branches
or .
on
upper portion branched segment into rod shaped rounded spores with connectives between light spores The slow growing colonies grey when young and darken slightly with
irregularly
Figure Chrysosporium luteum Irregularly compost Small branched mycelium grow oval spores borne irregularly swollen cells short chains two three spores may produced Colonies white when young turn yellow with age .
are
;
,
the base
be
Tree like conidi-
.sp
Oidiodendron
brown and warty
at
,
FIGURE ophores
13.
Secondary spores
.
1
17
Chrysosporium
luteum
( Mat
disease )
( Fig
14 ) ,
C. mer
darian ( Confetti ) , and Sepedonium sp . ( Fig 15 ) , are sus
pected of producing metabolically antagonistic sub stances . However , these and many other fungi have not been investigated in terms of their ability to pro duce these substances .
organisms
occurring
during compost processing
de
termines in large part the value of the compost for mushroom production . An alteration in the optimal activity can ecological succession of microbiological be caused by many factors and usually will favor the
composting
growth of detrimental competitor molds during crop ping . Knowledge of the interactions between biolog ical and chemical agents can aid the mushroom grower in refining cultural practices for the end result the yield potential of a mushroom of maximizing
compost
crop .
SUMMARY activity associated with mushroom can be monitored for an evaluation of quality . The micro - ecological succession of
The biological
18
Diseases , Weed Molds , Indicator Molds , and Abnormalities of the Commercial Mushroom C.L. Harvey , P.J. Wuest
and L.C. Schisler
In
5 ).
,
of
is of
.
,
in V.
of
,
-b
is
(
or
.
be .
A of
a
or
a
.
-
-
.
of
V.
by of
a
is
;
-
to
,
,
of
as
.
be
on
.
in be on
If
.
is
.
to
do
a
is
by
of
to
,
or
,
of
.
a
of
.
contamination
on
,
,
concentration can accumulate dropped mushrooms infested cas floors because ing and the like Mites and mushroom flies with spores adhering their legs and abdomen are vec ,
a
as
, is
do
source
High inoculum
of
.
,
3 )
or
,
(
.
ten
from
.
of
of
peeling back
other
to
to
,
of
or
Splitting occurs Fig
the infected stem and lesions may not develop This stipe blowout symptom stem splitting one that many mushroom growers not recognize con tilts
house flies are present they spread the pathogen than any dispersal agent Unwashed picking baskets epidemic can also farm where Verticillium
side mushroom probably more
of
)
(
of
.
.
to 2 )
to
(
Infection the stem stipe causes stop growing The noninfected cells infected cells elongate and the stem thus bends continue wards the site infection and the mushroom cap
they move throughout cropping area Splash dis persal fungal spores while watering use inade quately treated infested casing and inoculum the hands and tools mushroom pickers seem spread common routes which the pathogen
a
greyish the fun
infection sites insects air currents and These materials act carriers inoculum transported which can soil particles and water droplets Workers can further distribute the pathogen
a
a
of
develop evidence
ported
dust
,
at
of
on
is
which
common sign the disease fungicola are trans
as
.
At to
be to .
lesions
-
,
most cast
or
a
-
gal
.
of
,
at
sporulates bloom spores Fig
this
Mycelium and spores
be
(
–
.
of
,
,
a
,
If
.
the
button stage depressed necrotic tissue often devel ops the cap When the Verticillium fun the edge color
by
.
– en
is
as
be
as
)
(
pileus will brown leading diagnosis times Verticillium bacterial blotch develop portions will cause brownish cast confused with bacterial the cap and this too can
gus
.
in
in
.
A
tire bubble
the mushroom cap possible incorrect
infection occurs when mushrooms are
6 )
.
is
of
-
-
most
by
.
of
,
V.
1 ).
coalesce
rooms should Yield losses occur Pennsylvania dry bubble Fig growers call this symptom bubble puffball Infected mushroom pins develop into shapeless cap like malformation with stunted
stem ten indistinguishable from the mushroom dull grey white bloom the spores covers the en
verticillium spot the most common symptom Fig Cinnamon brown spots necrotic lesions develop on the mushroom cap These spots may large and coalesce the mushroom cap enlarges
blotch
)
of
to
is
Two major symptom groups are associated with fungicola fection by and the disease named ac superfi cordance with the nature the symptom cap cial infection the maturing mushroom
When lesions
characterized The second major symptom group puffball like masses where the developing mush -
to a
is
it
of
or is
specific time not restricted any specific type restricted casing material mushroom strain Significant yield present losses occur when this disease
room cap tissues accompanied the appearance fungicola spores and spore earing structures sporophore common when infection occurs early development mushroom
(
Its
,
Verticillium disease is the most significant fungal induced disease on the mushroom farms of North severity
(
a
as
a
Not known
nor
of
at
a
.
hairlip Fig depressed lesion which looks like fected cap tissue becomes dry and leathery and de greyish cast velops the pathogen colonizes the internal tissues Discoloration the internal mush
OUTDATED NAMES : Verticillium malthousei, Acrostalagmus fungicola , Cephalosporium constantinii
America . the year
is
,
Brown spot ,
4 )
(
of
to
.
of
,
of
COMMON NAMES : Verticillium disease Fungus spot , Dry bubble , La môle THE PATHOGEN : Verticillium fungicola
of
Verticillium Disease
A
longitudinal sequence Verticilliium infection streak from cap base stem Fig another symptom Verticillium disease and indicates pres sence stem infection An infection the edge the mushroom cap usually produces nongrowing
MUSHROOM DISEASES
PERFECT STAGE :
,
19
Verticillium spores and mycelium on the beds , and promptly remove and dispose of infected mushrooms from the growing room . If disease symptoms appear on first -break mush
mon name for the disease wet bubble relates the liquid on the surface amber droplets the bubble golf ball Wet bubbles range from one half the size
,
(
).8
,
to
,
-
a
of
.
of
of
,
(
9 ).
of
to
by
.
be
so
,
)
,
.
a
;
in
(
.
a
so as
do
a
on
.
in
or
,
,
in
or
to
,
of
,
is a
M.
of
.
,
,
in
air
a
in
of
be
of
,
,
in
,
or
in
air
occurs via spore dispersal currents water drop hangers plus other lets flies dirty picking baskets disseminating agents mentioned connection with
Verticillium
The appearance
Mycogone disease
on
first break
indicates the casing contained the pathogen be during the casing operation came contaminated delayed until second When disease occurrence crop third break later the the inoculum has or
bed surfaces and mushrooms
the wooden
perniciosa consists spores and Inoculum transported house into which can contaminated casing dust currents mushroom flies workers and equipment Once infected mush the pathogen rooms appear subsequent spread
of
cover
crevices
mycelium
.
all
Infection and disease can be prevented . Routine dusting with 15 % Zineb is one approach to protection of the mushrooms ; to be effective , the dust must
and
,
rooms arises from infection at the time of first break so maintaining a Verticillium - free crop requires action well in advance of symptom appearance . Verticillium spot will develop within 7 days following inoculation by flies or water droplets .
,
debris cracks bedboards
.
mize pathogen spread . One key to Verticillium control is recognition that 10 to 14 days will pass from time of infection before symptoms appear . Verticillium on third - break mush
dormancy field soil other fungi room parasite wild mushrooms and M. The fungus perniciosa live on mushroom has been reported in
( 15 %
rather
mush dust ) to mini
.
rooms with sodium hypochlorite
,
,
mushrooms are removed by a trashing crew than the pickers , or by dusting the infected
as
of
occurred at pin
ning ; inoculum may have blown in , been carried in by flies , or have come with the casing . The losses dur ing later breaks can be reduced if infected first - break
,
sign that inoculation
, it is a
large not get
,
rooms
grapefruit Dry bubbles Verticillium large dry bubbles range size between large grape Unlike wet bubbles pea and that dry bubbles not change from white the brown felty exterior size and color can accurate differ entiators between dry and wet bubble Mycogone perniciosa survives apart from the mush do to
mushroom flies, neutralize
to
brown color and cause the infected mushroom become tan colored Fig As the disease progresses drops containing liquid amber bacteria and spores Fig appear on the infected mushroom The com in
tors for the pathogen . Nonharvested mushrooms or portions of mushroom remaining on the casing ( " trash " ) are also reservoirs of inoculum . To minimize fungus , destroy the distribution of the Verticillium
or
is
,
by
,
air
,
or
,
,
12
is
for wet bubble
about
is
(
,
,
,
-
)
.
.
of
.
bit
a
development
symptom
days Disease control best accomplished through hygenic work practices also true for Verticillium trashing beds pasteurizing disease the casing washing picking baskets and hangers etc.
-
be
is
it
,
,
reducing the numbers Mycogone disease har vestable mushrooms can cause significant yield loss The disease can occur wherever mushrooms are grown but more easily managed than Verticil may lium and thus less threatening mal Mycogone infected become mushrooms ,
in
or
perniciosa
.
Hypomyces
or
,
dirty usually been introduced flies currents picking baskets hangers workers contaminated watering hoses The time between inoculation and
Mycogone perniciosa by
STAGE
:
PERFECT
:
THE PATHOGEN
Wet bubble
,
:
,
COMMON NAMES Mycogone disease môle
La
.
Mycogone Disease
,
,
:
:
Dactylium
dendroides
Cladobotryium PERFECT
,
:
,
OUTDATED NAMES Nectria albertinii Nectria rosella dendroides
STAGE
Hypomyces
rosellus
,
it
all
,
at .
as
a
as
a
at
It
.
be
at
Hypomyces disease occasionally occurs mush can viewed minor disease usually occurs infrequently few farms However room farms
of
a
,
of
.
it
at
may occur about the farms small number overnight develop same time Mildew can and spread great number making mushrooms them a
-
-
;
THE PATHOGEN
to
–
of
of
.
-
mildew Cobweb Soft
,
)
(
a
.
at
,
20
COMMON NAMES Dactylium mildew Soft decay
:
, a
an
M.
by
,
of
perniciosa apparently Infection mushrooms occurs when the mushroom initials pins begin form ing the casing surface Following infection the pathogenic fungus grows into and over the mush visible white and sometimes cot room producing tony felt textured mycelium Mycogone perniciosa pro spores duces two kinds the first are small like those Verticillium and produce the white felt tex tured mycelium the second are thick walled and
Hypomyces Mildew Disease ,
tis
-
of
or
7 ).
,
(
,
,
or
formed with swollen stipes reduced deformed puffball like caps undifferentiated masses sue Fig These mycelial masses become necrotic wet soft rot may follow and offensive odor may develop
un
as a
,
–
of
T.
in
by
at
a
),
(
12 ).
,
a
in
.
-
develops
-
that
le
).
.
.
a
.
the discolored tissue koningii pathogen causes mildew which usually appears during the later stages the picking cycle between third break and the end Trichoderma
of
of
,
18
to
is
,
.
.
a
sporulates
a
,
all
( 8
of
.
)
in
in
its
rooms , it spreads over the casing and infects path Patches mushrooms mildew inches diameter often appear and mushrooms within this circle are infected and unsaleable Such patches may appear throughout the growing room lacking discernable pattern Mildew mycelium
,
all
stage
reddish brown
dry sunken cap sions form the mushroom The lesions are usually deep and penetrate into the mushroom The fungus pathogen then grows into the dead tissue and (
rather
on pins , or on mushrooms at any in the crop . Once the fungus infects mush
spontaneously
room tissue Tissue death results mahogany brown discoloration along the stem stipe Noncoalescing on
first break
or appear
,
on
before
-
casing
barren
a
mycelium which spreads over casing and mushrooms alike within 12 hours . The pathogen may grow over
to
Dactylium dendroides , the fungal pathogen , devel a conspicuous cottony growth of wefting
ops into
Fig The mold growth starts from dead mushroom tissue but spreads rapidly over and onto
the Trichoderma species more evident than that sage green spores can viride but clusters served the surface the mushrooms When pres
.
of of
14 ).
of
a
a
, .
-
to
to
14
by
.
be
of
of
a
,
it
,
-
as
.
growth
mildew can
ef
spot and Trichoderma
be
Trichoderma
.
,,
such wooden surfaces untreated ladders and interior doors High humid .
favors
be
of
on
be
is
T.
(
.
;
and casing there are two species that lig farming Trichoderma viride affect mushroom
pears
bedboards
,
be
of
–
,
-
in
to 2
1
,
.
preferred food spores are the red Pygmy these mite and the presence the harvested mush mites reduces the quality rooms red pepper mites are present one can sure Trichoderma also present even though may not obvious Trichoderma green mold also ap pepper
,
in
fungi are extremely common soils and encountered during mushroom pro isolated Trichoderma can duction Many forms frequently .
or
or
,
at
,
-
in
lignorum
Hypocrea
Trichoderma
from compost
days
Trichoderma
If
Trichoderma
in
)
of
meal
green mold appressed the casing surface appear and turn bright green several days Spawn may eventually colonize such infested casing and produce delayed mushrooms but production will
its
:
PERFECT STAGE
bed
propen
will grow from compost infested areas into the cas ing Large diameter circular colonies feet
.
:
OUTDATED NAME
no
-
,
(
or
as
a
,
seed
)
koningii
in
on
-
is
)
T.
of (
in
is
).
(
.
cotton
(
:
,
,
:
,
NAMES Trichoderma spot Trichoderma blotch Trichoderma mildew Green mold Trichoderma viride Trichoderma THE PATHOGENS COMMON
under sup
ground SpawnMate Super Spawn not uniformly distributed spawning Once Trichoderma mold has colonized the compost soybeans
21
Diseases
ob
be
.
-
of of
is
.
or
of
on
,
T.
in
(
These fungi quickly colonize areas with carbohydrates
compost Some Trichoderma isolates have sity for colonizing supplements clod
ity
Trichoderma
.
to
4
3
by
at a
of
,
(
on
.
in
of
all
.
Fig 15,16 plemented
-
;
it
if
of
mold
it
is
at
.
be
,
is
of air
.
90
F
65 °
appears benzimidazole fungicides are not used too frequently Maintaining high sanitation on the farm and farm opera mildew tions may prevent the occurrence effective levels
de
sporulating Fig evident viride and other Trichoderma species indicator weed molds flourish the compost molds when carbohydrates are available when nitrogen supplemented compost with sufficient not mycelium Strains
.
as
in
of
,
,
and tempera Dactyl development factors ium Mildew disease When the relative humidity percent and temperatures exceed greater than Dactylium Mildew after casing the spread favored Disease control should focused the mil
inches per day
compost early ent the casing the cropping sequence koningii causes superficial purple brown spots first break mushrooms but the caps
of
,
–
.
,
of
-
or
.
so
H.
by
as
of
High humidity water condensation
ture are significant
dew when
,
,
,
mycelium
of
in or
,
be
present
.
,
can
of
the fungus patho any mushroom the vicinity parasitized farm Wild mushrooms rosellus will harbor the pathogen will field soil both are primary inoculum Inadequately pasteur sources spent compost ized casing soil can also harbor propagules the mildew fungus which act reser voirs for this pathogen
Inoculum spores
rate
Mushrooms overgrown this mildew quickly velop soft wet rot The white downy mycelium a
(
).
,
of
;
.
descriptive gen
live mushrooms
T.
.
ap de
.
,
or
a
a
to
or
appropriately called cobweb mildew soft decay mildew the latter two terms are the most
soft
13 )
been
It
the crop
to
initially diffuse colored grey becomes white moderately dense with age and sometimes develops yellow hue Infected mushrooms rosy red velop soft wet rot and pins and buttons often Fig 10,11 This disease has pear like balls cotton
are
:
pathogen the casing
.
is not controlled .
may appear dark green any time during crop produc tion Mushrooms areas occupied viride die and show signs the sporulating fungus the dark green mold Fig The fungus purportedly secretes toxin into the casing which kills the living mush norum mold
on
within a few days . Significant yield losses will result if the spread of dactylium mildew disease saleable
21
mize its occurrence
in overheated compost , but Truffle can also appear in composts that have been maintained at the ideal tem 74 ° to 76 ° F. perature for spawn growth Soil is the major source of D. microsporus , yet not soils contain this mushroom pathogen Contamina compost with soil harboring microsporus tion
-
all
fectively controlled with dithiocarbamate and ben zimidazole fungicides, but careful preparation of compost plus thorough farm sanitation should mini .
to
in
-
.hr
8
.
of
,
a
.
,
-
-
,
:
:
,
:
,
,
,
:
.sp ,
of
)
(
de - of
.sp
, a
to
,
19 ). at
(
,
C. to
at
or
C.
-
its
.
is
,
at
,
C. is
of C.
,
a
in
)
(
in
of
.
a
of
(
),
A
,
3
C. to
as 2
as
of
in
as
a
of of
as
.
,
as
-
is
or
to
a at
it 83 ° F )
(
is
,
,
/
be
Presence
,
).
of
be cir in
or to of
.
an
D.
of -
no
is
Sepedonium
Chrysosporium luteum
yel gris Mat disease Vert which corky mycelial layer develops low brown the inter face between compost and casing Fig Texture growth habit and color very similar luteum that mushroom spawn making luteum difficult detect during spawn run and even times up usually noticed after first break Mat disease luteum develops stroma like morphology the compost casing interface luteum binds when compost straws together over large areas which early may occur weeks after spawning closely related fungus merdarian M. sulphurea few weeks causes Confetti disease After spawn growth Confetti appears small individual spore laden colonies with diameter about 1/16 inch or yellow yellow green flecks mold the compost appear initially fungi Fig tufts small Both results
20
,
on
a
,
.
disease found only when the compost has overheated during the spawn growing period but this not question that Truffle has appeared true There
group which also includes
and Sporotrichum -
.
in
.
af
by
is
.
by
A
.
affected warm compost temperature encour ages the growth microsporus but will grow maintained even when compost temperature lower Some farmers consider Truffle be
group
to
to a
-
a
or
,
,
yellowish cast and die before infested area have reaching harvestable size The amount compost limited isolated fested the pathogen may tray can cular patches although entire bed
Myceliopthora fungi are the most The Chrysosporium devastating mushroom pathogens the yellow mold
(
.
(
of
to 6
3
.
of
fected compost and the compost appears soggy production sunken and abnormally dark brown drops sharply Mushrooms that form the edge
or
Chrysosporium merdarian Myceliopthora OUTDATED NAMES Myceliopthora lutea sulphurea Sporotrichum pannorum and Chrysosporium sulphurea IMPERFECT STAGE Thielavia Gymnoascus Arthroderma others suggested ;
of
.
of is
-
to
,
in D.
,
) as . it
18
or
or
1
in
to
in up
to in
–
1/4
-
or
by
(
of
)
brown mass dissolves into reddish brown ooze Spawn growth markedly inhibited the pres ence the Truffle fungus Spawn disappears
an
COMMON NAMES Mat disease Vert de gris Confetti THE PATHOGEN Chrysosporium luteum and
,
,
of
D.
,
or
.
-
.
weeks following formation
and mature the fruit body Spores are liberated from the closed fruit powdery body when the truffle disintegrates
F
any debris from
.
in
-
or
In
brain like fruiting bodies characteristic Truffle They may appear singly inch diam eter several aggregates may coalesce form larger fruiting bodies diameter Fruit inch ing bodies are located the compost on the casing ready for surface the time first second break creamy the fruit white color The harvest Fig body changes ages rusty white Spores asco spores microsporus form inside the fruit body voluted
°
to
Mat and Confetti Diseases
of
one week the wefts aggregate without definite pattern from tangled knots microsporus form hyphae Gradually the aggregates develop into con
75
.
-
-
.
5
,
to
is
or
F
wharves with concrete during this era Once these areas were covered with concrete sanitization was
thorough washing off reduced concrete slabs
.
be of tol
,
F of
°
.
-
to °
2
of
the 1930s and 1940s paving composting
grey white color spawn found growing appressed compost on the
22
is
D.
of
of
this disease the emphasis
on in
a
in
of
of of
,
its
.
-
17 )
;
it
(
sanitized wood
.
was reflected
sideboards the surface bed this fun compost Fig The creamy white color wefting growth habit contrasts with the gus with ,
in
in a
air
on
will grow
inadequately
pathogen The severity
or
,
-
.
of
vive peak heat during Phase Two composting and germinate when the spawn starts growing Wefts creamy white nonsporulating mycelium can rapidly grow either through the spaces between compost space straws into the between the compost and
growing only way rooms Once the disease occurs the elim pasteurize the compost and inate from farm higher for woodwork 160 Air drying woodwork for months may also eradicate the harbored
at a
- in
,
,
in
.
of it
to
crop failure when occurs commercial mushroom crop Spores this soil habiting fungus when present compost can sur
it .
microsporus
,
,
caused by Diehliomyces
will usually lead
of
is
microspora
Truffle disease
unpaved composting wharves Such soil found bales straw muddied during harvest trans storage Spores port the fungus are heat erant and can survive 180 for hours Inoculum mycelium and spores this pathogen can also ,
Truffle disease
the occurrence on
the usual cause
:
:
:
THE PATHOGENS OUTDATED NAME Pseudobalsamia IMPERFECT STAGE Not known
3
Truffle disease
microsporus
or in
Diehliomyces
or
:
,
COMMON NAMES False truffle
of
.
Truffle Disease
–
a
of in ,
-
.
of
at
in
.
a
is
air is
)
.
;
aa
–
to air
.
a
as
so
.
is
air ,
.
air air
,
en
so
;
,
.
'
the
-
tem
it
aa
a
to
is
. If -
forced ventilation heating coil after must pass through a
° F )
many
system
,
found
is in to
°
(
pipes
it
the
heating
air
perimeter
a
.
,
b )
,
(
through
growing rooms
In
,
the spots
to air
.
in .
-
a
on
favor the disease
if
3
2
or
-
conditions
and coalesce sometimes covering the entire mushroom cap Fig 22a Mushroom stems can also
coming from transpiration air cooled perature lower than desired and then reheated few degrees can hold more moisture and mushroom surfaces will dry This heating operation accom plished circulating hot water 110 120
.
a
).
(
to 21
,
no
,
on ,
–
. or
If 1
moisture
enlarge
vironmental and surface moisture conditions disease reproduc pathogens control requires inhibiting tion the mushroom surface Air will dry the mush room surfaces can hold the additional moisture
.
,
,
G
,
of
be
,
of
to
yellow grey watersoaked and grey Blotches usually appear when the mushrooms are the early button stage but can appear mushrooms any age harvested refrigerated mush even rooms mushrooms over wrapped with water tight film pear
–-
as
a
,
of or
if
do
of
or
is
superficial discoloration more than mm deep and the underlying mushroom tissue may ap
in
,
a
is
of
of .
,
that are pale yellow initially but which later become golden yellow rich chocolate brown Fig This
active mushroom growth transpiration
cool surface Slight fluctuations few temperature during cropping can cause the air vascillate between the saturation point and not being saturated even though the abso lute water vapor content remains constant Warm holds more water vapor than cool the temperature increases the air becomes less saturated with water vapor the inverse also true With Bacte strongly influenced by rial blotch disease being
it
on
Bacterial blotch may endemic mushroom farms damaging mushroom quality and posing potential yield loss Presence probable the disease the surfaces the mushrooms not dry following wa tering irrespective the season Pseudomonas fluorescens biotype the pathogen causes the formation lesions on mushroom tissue
room due produces degrees
by
Phytomonas
tolaasi
on
G
tolaasii
dis
by
a
.
or
or
on
a
the outer surface any stage both growth development mushroom Bacteria splashed onto mushroom surface will reproduce moist conditions such occur when water con denses remains on the mushroom surface for
,
Bacterium
be
,
tolassi
),
on
by
at
62
to
of
Bacterial blotch can develop cap stem
mushroom
air
:
OUTDATED NAMES Pseudomonas
,
P.
:
biotype
fluorescens
,
in
.
,
by
and mushroom flies and nematodes Recent observations suggest compost with moisture percent spawning precondi content less than tions mushrooms blotch infection
(
Bacterial spot THE PATHOGEN
of
(
on
of .
is ,
of
cedes disease occurrence Once the disease occurs splash blotch causing bacteria are spread persal during watering upon tools used pickers
number hours Condensation forms when satura present and warmer than ted with water vapor the cap surface The cap surface cooler than the sur rounding when water transpires from the mush
Brown blotch
,
:
,
COMMON NAMES Bacterial blotch
as
a
is
even after pasteurization Oc associated with the size the bacterial population the mushroom cap pileus rather than the population the casing which ex plains why prolonged wet period the cap pre most casing material currence disease
,
.
, 2
–
air
4
to
Bacterial Blotch Disease
or
or
.
air -
borne dust are the primary means
of
from spores by filtering particles larger than 3 mi crons from the the spores are unusually small by microns free
in
,
6
to
,
of If 4 or
Casing and
and trashers
include preventing field soil from washing onto the composting wharf , using clean baled straw or hay , pasteurizing the compost before it is emptied , and keeping the spawning area Disease - control methods
at
,
operation .
the
introducing the blotch pathogen into mushroom probably present house The bacterial pathogen
on
horse manure is used , pathogen - infested soil is carried in on straw bales , or pathogen -contaminated runoff water flows over a composting slab . The path ogen produces copious spores , which can be carried by air currents to soil - storage and cropping areas . Great masses of spores are released when the com post is broken up during the emptying ( dumping )
caps may crack radially
infected
mushroom expands
compost
contaminate
.
developed
a
may
crevices clusters mush wherever mushroom caps remain wet for longer after water has been hours very dry conditions occur after blotch has
.
spores
rooms period applied
near the edge
the contact points between
-
Chrysosporium
not completely pasteurized during Phase II , or they may contaminate casing soil . Buildup of these molds at a mushroom farm can also occur when infested
2
observed
mushroom caps two mushroom caps
,
postcrop sanitation can lead to a farm - wide problem if these pathogens are not eradicated between crops .
to 5
Typically spotting of
As aa rule , growers become aware of either fungus only after production decreases occur in scattered areas . A grower is well -advised after cropping to search through the compost in each growing room to determine if either fungus is present. Inadequate i
similarly
be blemished
or on
then change to a yel
,
.
at at is .
white hyphae in the compost
low color
has 23
bit
of
is
.
in
,
to .
ap
it
at
all
Mummy Disease '
'
, '
X -
,
,
La
La
It
.
a
of
of
to
.
of
of
or
,
all
of
a
of
,
its
of
of
of
.
,
.
is
La
;
.
a
in
in
,
in
,
as
as
,
In
of
)
(
.
be
.
;
-
an
.
be
in
of
,
) .
(
: i )
.
a
is
by
of
ii )
);
or
(
a
of
iv )
(
);
iii )
);
to
in
-
a
wet soft rot which causes the decompose few days Fig 26b dwarfing Fig 260 premature early maturation opening development the veil Fig 26d an mushroom
(
of
to
;
vii )
;
a
;
v vi ) )
a
elongated spindly stem with small cap formation gills mal thickened stem with thin flat cap completely absent and sym formed absence metry during development from pins mushrooms ,
-
are often off white
Cutting
or
).
Infected mushrooms tan color Fig 26f (
Fig 26e
ashen
in
a
.
.
of
to
on
be it is
is
on
.
a
in
,
,
of
to
in
,
on
to
;
dying followed
of
ex
or
.
-
in
)25 . .
,
a
is
of
(
At
24
Fruiting below fected areas appear normal Fig 26a symptom the casing surface common rapid Symptoms diseased mushrooms include
or
,
in
,
;
-
Mummy disease seems endemic certain farms which suggests growers can nurture their crops develop manner that seems allow this disease the vast majority farms however the disease appears without prediction Mummy can appear growing room where the crop coming quite strongly when this occurs not uncommon for the good even though there harvest from the room producing patches are bare the surface the bed
my
occur producing well defined barren areas the en tire casing surface may bare Mushrooms growing the perimeter barren spots have abnormal appearance although mushrooms growing unaf
).
as
,
if
as
,
a
,
.
mushrooms the mushrooms produced die are tremely abnormal appearance and texture An Mummy delay other symptom first break picking except delay but for the the mushrooms appear normal Fig Typical Mummy symptoms appear by second break
vigor Infected mycelium may appear normal color and density before casing but growth into the casing may restricted time the mushroom celium disappears dieback from the casing well the compost Suppression mushroom fruiting may
or
-
).
.
,
in be
tom development localized area radial spread begins and the disease eventually affects the entire production surface moving much one foot per day Infected areas produce few any saleable
Only the most consistent symptoms are described Numerous false symptoms exist France disease forthcoming section described more detail ,
,
(
,
is
,
spongy dry and leathery mummified The myce although lium also infected but appears normal rhizomorphs can Following coarse initial symp
type symptom manifesting presence the disease depends upon the strain mushroom involved and development the stage environmental condi tions and the pathogen's virulence and abundance
,
tis
.
,
.
(
in
at
,
colored
24 )
Fig infected mushrooms are slightly dis firm and moist first but then become tilted
The tissues
mushroom progressive and
,
.
in
as
of
frequently
size total suppression rapid dying mushrooms degeneration mycelium The
mushroom
fruiting
on
or ,
,
.
,
23 )
a
at
(
of
as
-
,
water soaked longitudinal streaks These streaks of ten terminate dark spots the mushroom cap sue and turn brown the disease progresses The caps infected mushrooms are often dwarfed and
duction
a
.
are characterized by having curved stems surrounded the base with crown overgrowth Internally the mycelium Fig mushroom stems often have colorless translucent
is a
saleable
a
fected with mushrooms Diseased mushrooms
Virus disease has been reported most places where commercial mushrooms are grown serious dis ease that can completely destroy crop Symptoms virus disease vary from modest re in
in
producing
stops
goutte
.
of
.
,
mummy
,
can cause significant yield losses commercial mushroom crops The effects the dis ease are devastating since mushroom mycelium ,
another species
Brown disease
COMMON NAMES France disease Dieback Watery stipe disease THE PATHOGEN Virus particles :
aeruginosa
Pseudomonas
:
,
Mummy disease caused
smells fresh and permits slow but steady drying of the casing . These observations are based on the expe riences of one author ( PJW ). Perhaps confirmation by
Virus Disease in or
by
Pseudomonas
surfaces in the growing room are at present only the means of preventing spread of the pathogen crop from to crop . Mummy seems to appear with less frequency in growing rooms where the air always
research will become available at some future time .
goutte and
: .sp
:
, '
La
COMMON NAMES Mummy disease THE PATHOGEN Pseudomonas aeruginosa
influenced by
wooden
,
have no effect
.
at ,
pears
to
at
be
of
at a
effect since the bacterial population reproduces rate that neutralizes the effect the oxidizing agent This helps explain why sodium hypochlorite seems very effective times while other times
be
the season of the year , or any obvious component of the mushroom - production system . Trenching the compost 8 feet in advance of symptomatic mush rooms often stops disease spread . Strict sanitation at spawning and casing plus post - crop pasteurization of
of
.
if
,
be
kept trol blotch providing the mushrooms can dry But the mushroom stays wet chlorine has little
This disease does not appear to
(
to
.
at
,
is
be
been cooled , so the cooling coils may need a more capacity than might expected This system dry ing energy intensive but essential when drying Adding sodium hypochlorite needed 150 ppm irrigating the crop will con chlorine water used
handling
irregular appearance and take result com post decomposition Infested areas enlarge the ne matodes migrate new feeding sites Since 1964 by
.sp
.
to
( be
)
found with high popula
saprophytic nematodes even though mush tions good such locations Pro room production may good duction may range from very poor ,
.
to
.
in
be
as
Saprophytic nematodes sometimes form into moist glistening swarms appearing upright cylindrical the aggregates swaying the surface and fro casing Such swarms can seen without magnifi of
is an
of be
by
If
.
in
as
to
45
to
;
,
on
to
in
-
in
of
on
,
.
on
on
.
,
in
,
,
,
on a
is
of
or
in
in II .
.
is
.
of
on
(
28 )
of
of
up
as a
a
,
an
in
5
or
4
.
of
.
,
as
of
-
.
to
–
in
,
COMMON NAMES Lipstick Red lipstick SCIENTIFIC NAME Sporendonema purpurescens NAME Geotrichum
candidum
Oosporum
.sp
OUTDATED
,
:
is
Lipstick Mold :
in
-
a
of
it
the surface
,
at
as
.
is
de medicinal odor turns black and Surfaces nematode infested areas sink
,
.
cast
WEED MOLDS
:
2
the
;
tectable
whitish
area feet diam lacking mushrooms Bacterial blotch has been associated with parasitic and with free liv ing nematodes the bacterial both are vectors Killing the nematodes wherever blotch pathogen control they over rop the only means the casing usually eter
,
to
in
spawning nematodes are present the compost spawn's mycelium will grow slowly and degener ate mushrooms will not form Mycelium affected completely destroyed and areas the compost de composes
This mold appears
is
is
an
of
.
of
at
the time third break with the develop nonproductive areas feet diameter 1
ment
of
noticed
,
a
in
is
.
tation procedures The primary symptom associated with the parasitic nematodes Aphelenchoides composticola and Ditylenchus degeneration myceliophagus the mushroom mycelium the compost Normally infestation
,
.
so
,
a
in
-
in
of
a
is
keystone wood mushroom farm hygiene sani failure nematodes suggests the presence
via the falling droplets nematode infestation sometimes accompanied the superficial sparse growth the fungus Arth parasite robotrys superba the nematode Fig
-c
the woodwork compost and of
in
Pasteurization
or
of
-
,
-
.
or
over cropped
of II if be
to
is
is
of
,
.
in
room
.
at
do
.sp )
.
(
by
-
growing
the
compost inadequately pasteurized during vive Saprophytic nematodes can multiply Phase ceil ings made ceiling insula wood concrete and ceiling tion Once infested water droplets condensing the ceiling will contain the nematode larvae their eggs and the crop becomes infested
A
is
,
,
)
-
(
.
,
saprophytic nematodes may produce Rhabditis products affect mushroom which adversely still spawn growth this but the extent proven One fact regarding nematodes certain present the compost they either survived Phase
noninfested from infested occurs Transportation clothing and hands work tools areas occurs ers and flies The nematodes will over crop adequately pasteurized wooden boards and may sur
by
.
a
of
of
of
nematodes possess needlelike mouth parts capable drawing out the contents mushroom cell The mouth the saprophytic nematode built for chewing Saprophytic free living nematodes ingest bacteria protozoa and fungal spores but not Large populations tack the mushroom mycelium
-
.
of
of
Parasitic and saprophytic species nematodes asso ciated with commercial mushroom growing are rou tine inhabitants most agricultural soils Parasitic
°
at
,
;
of
a
directing light angle cation beam the casing the motion the swarms what makes them obvious Eggs larvae and adults can serve inoculum Nematodes are transported the crop through infested compost peat moss and soil trans port dust particles and mushroom flies also ,
.sp
,
-
.
a
(
27 )
,
be
by
,
of
.
-
spawn run compost may
.
.,
,
:
COMMON NAMES Eelworms Cephalothecium disease THE PATHOGEN Aphelenchoides composticola Ditylenchus myceliophagus Rhabditis
pasteurization
ef a
at
to
.
by
Rhabditis have been repeatedly collected the authors during this same time period These too may associated with the spawn Fig disappearance and the breakdown compost into black soggy mass Normal looking
.
Nematodes
:
,
.
to
of
the genus level
Saprophytic nematodes
on
substantiated
periodically assessing the nematodes pres
to
remains
.
be
to
but this contention
,
a
for
zation of wood after the compost has been removed is essential . Poor - quality compost is suggested by some significant virus epidemic to be a precondition
vigilant
ent with identification
of
primarily transmitted to healthy mushroom myce lium via infected mushroom spores , as well as by in fected mushroom tissue or mycelium . Mushrooms should be picked before the veil opens ; this practice prevents liberation of mushroom spores that may carry virus particles . Infected myce lium harbored in the woodwork can survive post crop steaming and act as a transmitting agent of the pathogen to subsequent crop ( s ). Thorough pasteuri
forts the authors collect parasitic nematodes number North American mushroom farms have been unsuccessful Growers are advised remain
of
Several different virus particles recovered from in fected mushrooms and spawn have been character ized . The relationship between these virus particles and symptoms has not been established . Viruses are
to
.
as
of
as a
an
brown
to turn
causes infected mushrooms
rapidly .
on
generally
25
,
,
is on
,
.
at
.
as a
It
.
.
at
on
air -
.
,
of
,
(
C.
of
a
a
.
a
,
in
,
or
of
.
,
of
indicate
the inadequacy
of
of
of .
pasteurized and overly pasteurized casing Widespread Cinnamon infestations
sanitation
,
Sepedonium Yellow Mold COMMON NAME Yellow mold :
this color
genus confirmed
yellow mold differs from other molds sparce white mold the appearance
in of
Sepedonium
Ascomycete
no
STAGE
aa
or
as
PERFECT
of
to
on
large circular the compost
Sepedonium
chrysosporium ,
,
(
to
.
mon brown The mold first appears patches white aerial mycelium
color
cinna
SCIENTIFIC NAMES Sepedonium
:
peziza
)
fulva Ostrachoderma has been called Cinnamon Brown mold golden brown ranges from yellow gold
,sp
:
Peziza ostrachoderma
Chromelosporium
of
in
(
.
by
C.
of
,
of
31 ).
or
on
lets from wooden ceilings The spores the fungus easily are borne which facilitates contamination casing material and makes contami stock piles
by
Plicaria
.sp
:
.sp , :
STAGE
,
in
.
.
of
.
) (
Cinnamon Brown mold reflects spores mushroom farm around through open doors splash Inoculum can blow from floors during cleaning fall moisture drop
build
air -
peziza
OUTDATED NAMES Ostrachoderma Phymatotrichum
a
,
is
Widespread
.
ollare
its
Chromelosporium
.
10
.
a
,
a
is
on
at
C.
of
leathery texture and are usually dark brown color although chartreuse Peziza species have been observed
bery
Brown mold practices
fulva
to
or
,
,
or
.
As
to
.
a
30 )
to
on ,
)
of
,
fulva Several weeks after first appearance the mold fruiting struc and after the mold has disappeared tures the size and shape raisins may appear on the casing these are the sexual phases the fulva Pe Fig ziza ostrachoderma The structures have rub
of
:
SCIENTIFIC NAMES Chromelosporium
26
growth
nation possible
Cinnamon Brown ,
:
,
COMMON NAMES Brown mold mold
Although
the growing room the same suggesting time thus that borne spores landed the casing about the same time The high humidity following casing are ideal for temperatures and warm
in
a
is
its
,
of
.
Cinnamon Brown Mold
PERFECT
throughout much
.
to
4
° F )
.
(
F
-
°
awareness
most commonly known recolon overly pasteurized casing The mold will rap izer idly grow from infested compost areas into casing the casing and can become obvious will grow
The mold
of
to .
pasteurization temperature the Phase elimi hours seems for rather than 140 nate the mold problem when coupled with thorough not post crop sanitation The Lipstick fungus presence proven pathogen but the mushroom for sanitation indicates increased need the 150
II
Raising
its
a
of by
.
.
of
infesta the Lipstick fungus Confirming this route tion has not been accomplished Lipstick mold often extends An infestation through number crops after initial appearance
will
,
re up
-
is
to
;
in
to
be
is of
.
a
of
.
a
pickers Heavy infestations usually reflect build spores around mushroom farm The mold ported chicken ma associated with the use carry said nure the compost formula the litter
erly conditioned compost containing green mold often contain Cinnamon Brown mold
;
-
,
or
or
,
by
in
be
.
be
If ,
.
to
.
tioned compost Significant yield losses are associa ted with extensive compost infestations prior cas ing the mold does not become obvious until third experienced break little yield loss will Spores spent compost contaminated casing spread via air currents during watering can
tunistic and under certain conditions can rapidly spawn Areas grow into casing not colonized compost that overheated during spawn run coloni fulva and Cinnamon zation may bear colonies Brown mold has been observed growing undis spawning Improp tributed supplements added
or
in . in
.
a
is
of
S.
of
it
;
of
its
tell -
to dull orange or buff . However , with a peat - moss and limestone casing , the Lipstick fungus sometimes remains white and tale color does not develop Lipstick mold slow and restricted Growth mildew The does not spread outward like area purpurescens eventually fills white mycelium casing and can colonize well condi loose areas
granular appearance This mold days but usually disappears within Although not experimentally documented dense infestation may retard the crop especially first break slight yield reduction and cause fungus extremely common soil and flour The damp wood Chromelosporium fulva oppor ishes
up
balls on straws or casing . This form of the mold , if de veloping after casing , is easily misidentified as mush room spawn knitting into pins. As the spores of the Lipstick fungus mature , the color of the mold changes from white to pink, to cherry red , and then
Fig
ony develops grows rapidly
in
Lipstick mold is a fungus ( Sporendonema purpurescens ) that appears during spawn run or during mushroom production and grows either on compost or on cas ing , or on both ( Fig 29 ) . The organism first appears in spawned compost as a white crystalline -like mold , rather nondiscernable from spawn . Colonies may re semble frost on a windshield or small white cotton
Within few days spores form and changes light yellow the color from white light golden brown spores the mature the color golden brown deepens and the col cinnamon (
casing
Not confirmed
STAGE :
PERFECT
.
,
com
the
Corticium Mold
on
on
)
(
-
:
or
,
on
;
-
.
,
-
to
be
to
or
.
-
,
in
a
in is
,
-c
it
--
.
)
or
–
.
in
of
-
(
65 in
,
up
to
in
-
be of
to
is
20
10
to
40
as
high
percent have
to
,
3
2
to
in
(
.
It
)
,
or
.
or
Im
or
is
it a
if is
is
,
,
:
,
.sp
:
,
of -
-
is
or
of
Ozonium
,
Coprinus The appearance the Ink Cap fungi production crop spawn evidence during run
:
in
Rhacophyllus
IMPERFECT STAGE
,
of
Wild
.
is
.
to
it
a
-
,
a
to
is
mushrooms ,
. ,
or
of
for
no
is
,
,
air
on
a
,
is
,
a
-
At
a
Ink Cap Fungi
SCIENTIFIC NAMES Coprinus fimetarius Coprinus radiatus Coprinus
,
)
ter .
INDICATOR MOLDS COMMON NAMES Ink caps Ink weed
the sparsely growing delicate white mold Spawn growth compost normal adjacent affected areas and noninfested areas sup healthy mushrooms port normal crop
P.hynosporum
:
.
in
by
in
to 2
1
of
of
is
to
is
.
,
di
football shaped with the greatest diameter the cen the compost's surface only small digging into the inches black spot seen but compost the characteristic shape becomes apparent signs pest The compost contains pathogen except
it is
to
,
be
may noticed when mush develop rooms fail circular areas feet spawn ameter and there absence these af compost infested fected areas The mass the mold neither spherical nor oval but rather lensan in
compost
Infested
dur mushroom house before currents into ing the spawning operation whenever the grow opened ing room the outside environment good substrate for this properly cured compost mold but not known the mold itself the responsible for significant yield poor compost that reductions ,
P.
hynosporum
.
in
.
a
is
antagonistic potentially pathogenic fungus infrequently isolated from mush potential room compost The fungus has cause yield loss because spawn will not grow areas colo
by
an
Pythium hynosporum
of
:
is
:
(
SCIENTIFIC NAME Pythium hynosporum OUTDATED NAME Pythium artotrogus
nized by
cellulose common rotter nature Corticium sporulates dead tree limbs stored straw etc and profusely when the weather damp would seem spores the Corticium like pathogen are carried that
In
Pythium Disease
of
.
,
common and reductions been reported
as
of .
its
.
of
The occurrence the Corticium like fungus compost tends associated with overly com posted straws although overly wet compost does not development When the mold seem favor yield reductions widespread percent are ,
air
-e
.
is
to
boards and the infested compost concurrently On peat casing the mold appears granular like salt and develops small 1.5 inch diameter circles covering percent the casing some areas
,
is
of
an
to
.
of
running period filters essential High fficiency introducing are required reduce the possibility the mold into clean areas
in
,
or to
a
.
threat infestation Preventing spores from entering mushroom houses during spawning and the spawn
it
of
.
to
is
.
other factors spore populations will build yellow farm following the appearance monitoring temperature mold Strict and control dur adequate post ing compost pasteurization and eliminate the crop pasteurization are essential
identity not certain
)
to
of
;
not known
Sepedonium
on
due
Sepedonium
whether this
like
compost casing Corticium Mold found growing room This grey white the woodwork the wood the straws mold grows appressed engrained Although not fre appears wood quently encountered this mold once present will appear consecutive crops until post rop pasteuri zation eliminates from infested wooden surfaces
to
.
affect spawn the mold colonizes compost considered ideal Sepedonium for spawn growth Heavy infestations yellow mold are associated with poor yields but growth
SCIENTIFIC NAME Corticium
(
,
.
by
.
,
in
mushroom compost specimens Sepedonium seems The growth
up
air -
,
-
,
in
.
,
,
,
a
.sp
from the other significant compost yellow mold Chrysosporium The latter causes Mat and Con fetti diseases Smaller oval spores are produced the Sepedonium fungus but these are rarely observed ium
believed that borne spores contaminate spawning time post :
.
.
-
or
of
.
or
to
fungus may survive peak heat The obvious spores are spherical golden brown large and distinctly distinguishes spiny Sepedon characteristic which
mushroom production is also caused by other diseases and improper cultural practices , so when the symptom appears , other causes are sus pected at first. The compost is rarely investigated for the presence of the Pythium fungus. Moreover , mi croscopic examination and laboratory study are nec essary to identify a white compost mold as P. hynos porum . Although little information is available on the life history of this fungus and the mechanisms by which it spreads throughout a mushroom farm , it is Spotty
at
32 )
to to (
be
to
or
or
,
to
!
.sp
air
spent compost sticking with unpasteurized trays wooden boards Sepedonium are thick walled The obvious spores high heat and and resistant this spore form the riod
or
i
by
the compost during the spawn run Fig The sparce white mold turns dull yellow tan with age spores can spread Sepedonium the compost during the filling operation currents prior during the spawning operation spawn running pe
27
sidual
tions in such crops are probably influenced by grow ing conditions . Nevertheless , proper management during composting should minimize problems with
areas contain compost packed nonuniformly and too tightly during the filling operation
to
be
.
at
Phase convert
.
of
.
is
,
so
the ammonia into microbial protein some ammo nia left and this fosters Ink Cap development Lo calized occurrences Ink Caps suggest that these
-
of
Water related phenomena can favor the growth Ink Cap fungi Overly wet compost reduces the space space within compost and this can inhibit air ex change restricting compost aeration Surface com
if
,
.
,
)
air
ex
a
of
or
fill a
,
65 II .
)
(
to
or
at
-
of
of
in
II
an
-
.sp
.sp
of
of
an
.
as
.
°
,
96
to
72
of
in
II .
of
of
of
Coprinus The growth can also occur the re improper temperature management during sult Phase Areas the compost which the compost temperature did not remain within the range 115 135 from hours after pasteurization may Oppositely some com contain residual ammonia F
°
5
F to
3 °
as
as
–
–
posts that reheat recycle little near the end Phase will have additional ammonia pro duced via microbial ammonification nitrogen com pounds temperature low cooler than
-
air
A
.
to
In
.
in
.
in
,
on
to
-
of in an
1
–
° F
A
ex .
of
-
to
at
,
.
in
of
-
of at
be corrected
Plaster Molds and Flour Molds
.
com
need
.
a
,
.
a
is
a
on
,
to a
.
nus species have been isolated from mushroom post and unnamed species have been observed
–
,
a
is
a
by
.
larger species room crop Coprinus fimetarius characterized greyish thick hollow stem and scaley cap Coprinus radiatus the other hand smaller species with shorter thinner stem and very fragile pale brown yellow brown cap Other Copri
Locating the origin deciding Ink Caps can aid why the compost supports Ink Cap growth few scattered Ink Caps are little cause for concern and filling time may indicate compost nitrogen content near the recommended level 1.7 1.9 percent However bountiful flush Ink Caps suggests cessive ammonia spawning more than 700 ppm and evidence that certain aspects composting , a
of
.
by
.;
of
Coprinus formerly infested ance colonization compost mycelium mushroom then occurs Coprinus occur with the mush Several species
manage the internal compost maintained temperature can result ammonia ladened layer depth compost the surface 0.5 inch such instances Ink Caps can flourish the ammo nia remaining this surface layer
100
to
of -
a
to
sp
in
of of
in
.
a
in
be
is
It
of
.
is
unusual more common for the appear Cap ance Ink mushrooms one time phe growing nomenon room Exhaustion ammonia compounds the compost and subsequent reduc compost pH results tion the gradual disappear
is
,
in
,
but this
,
is
of
Coprinus cyclical like The fruiting process Agaricus and Ink Cap fungi may reappear flushes
at
.
of
II
at
of
)
-
(
.
exist
Coprinus
of
a
).
rhizomorph root like structure which extends into the the base the compost Mycelial proliferation stem can occur certain environmental conditions
percent content less than excessive may ventilation throughout extended Phase terfere with conversion ammonia into microbial protein Each these conditions may limit the growth thermophilic organisms and cause am monia residue which will precede the development
° F
(
of
34
-
is
to
of
,
air .
it expands and exposes the radiating spore - bearing gills . The cap opens , umbrella - like , releasing spores into the Once open the cap immediately begins autodigest and the ink black liquid characteristic autodigestion Fig this genus the end product long fibrous Certain Coprinus species develop
consistency post supersaturated with water similar mud wet clay can interfere with gas Conversely change during Phase low moisture
to
Vegetatively , Coprinus sp . produces a luxurious growth of white fine mycelium in or on the compost before or after spawning ( Fig 33 ) . Spherical white pin initials ( 1/16 inch diameter ) of an Ink Cap develop on the compost or in the vegetative mycelium within 3 to 4 days . Each pin develops into a mushroom with a narrow white stem and a scaley white to grey conical cap . The stem elongates within 12 hours into a nar row cylindrical hollow stalk which supports a delicate white to greyish - brown scaley cap . The cap remains intact on the stem until nearly mature , at which time
(
.
Ink Cap fungi .
ammonia spawning time thermophilic microflora may unable
all II
free ammonia in the compost . Free ammonia seems to be a growth requirement of this fungus . Variations in the frequency of appearance from year to year may reflect the abundance of Ink Caps in the straw , cobs , or hay used in compost production . Ink Cap popula
28
,
:
, ,
byssina
Chaetomium
piluliforum
),
S.
fimicola
Corticium
Thielavia
roseum
,
),
Myriococcum praecox PERFECT STAGES Dichotomyces
(
:
,
Trichothecium OUTDATED NAMES Monilia fimicola Oosporo
.sp ,
Papulaspora
Sporotrichum
.sp ,
piluliferum
,
:
Botryotrichum thermophila
B. :
re
Brown Plaster
SCIENTIFIC NAMES Scopulariopsis fimicola
(
to of
;
or
in
an
.
–
too much water which affects resiliency compost inorganic nitrogen added the Too much compost causes imbalance which can result
COMMON NAMES White Plaster Mold
Mold Flour Mold ,
II,
a
.
of
tion
I
of
;
II
of
,
to
or
,
of
,
at
of
during Ink Caps appear the end Phase spawn run after casing just prior harvest pe Generally riod the commercial mushroom wide spread infestation Coprinus may reflect poorly managed Phase composting too much breakdown raw materials during Phase composting addi
ů
( Sporotrichum ),
Hypomyces ( T.
:
IMPERFECT STAGES : Acremonium , Chrysosporium Myceliopthora , Sepedonium , Sporotrichum = Thielavia
roseum )
,
to salmon pink , and then to beige . White fluffy growth of T. thermophila may again appear on the spawned compost surface a a few days after spawning , but the salmon pink- to beige - colored mold grows
Plaster Molds and Flour Molds develop in mushroom compost when nitrogen sources from Phase I are not completely utilized by the microbes during Phase II and , in particular, when the nitrogen is not converted into microbial protein . Fungi that cause Flour Mold are not the same as those causing Plaster Mold , and
densely and rapidly through the compost , colonizing an area that may become as large as 5 feet in diame ter . Powdery masses of spores become airborne when the infested area is disturbed . Near the end of the crop cycle , areas infested by this mold usually contain
distinguished by differences in appear ance and color . However , it is generally believed that the same nutritional factors favor the growth of the two mold groups , so they will be discussed together . Several fungi have been associated with the White Plaster Mold condition ( Fig 35 ) . Scopulariopsis fimicola
phalum
foot or two in diameter , on the Prior to spawning , spores in
compost surface ( Fig 37 ).
to of
.
if all
,
B.
of in .sp
in
of T.
ies
of
re T.
of
or
of
,
.
a
to
of
if
,
.
As
in
° F, a
to
of T.
°
of
.
to
in
,
,
be
of
,
in
an
.
by
“
”
of
of
in
.
of
,
,
or
of
.
T.
in
is
.
of
,
de ro
“
or
,
do
,
of
a
be
It
.
on
a
is
in
.”
hot
fluffy white molds which initially light peach color and light rose pink color velop respectively .
-
a
as
seum appear
,
The Brown Plaster Mold fungus
Papulaspora
bys
As
in
.
or
to ,
,
to
in
or of
-
15
6
.
to
on
sina first appears the compost surface during the spawn run Patches diameter show inches plaster dense like white mold the fungus colony matures the center the the mold changes yellow from white orange tan then brown
rust Brown Plaster Mold colonies are not fluffy but grow above the compost and are often outlined actively growing outer fringe white myce lium Several colonies can coalesce form continu ,
ous coating over the surface damp bedboards After casing
a
of
to
to oval - shaped patches of
Sporotrichum and Trichothecium
the compost and the mold grows
up on
mold , a
Species
of
white
as circular-
spots
Flour Molds
not cause
,
fluffy
Other fungi also termed Plaster occur mushroom compost but
.
first observed
mold
bit
philic ( heat - loving ) and for this reason is unique among indicator molds . The mold grows rapidly and abundantly during the last days of Phase II , and is
thermophila Presence this plaster most often noticed during visual inspection may spawn growth development detected farms where compost temperature monitored great number locations daily
caused
a
The development of B. piluliferum in the compost is similar to S. fimicola , except that B. piluliferum colonies have a pearly glisten and the mycelium is creamy white to buff instead of snow white . Thielavia thermophilia ( Sporotrichum sp .) is thermo
the
restricted and has not been observed infesting entire tray compost Consequently high compost bed temperatures are only encountered these spots and monitoring during compost temperatures routine spawn run may not reveal the presence hot spots spots
as
leaving a white mold appressed to the compost sur face . In some cases , the White Plaster Mold grows from the infested area of the compost up through the casing where it resembles flecks of plaster or flour on the casing surface .
ammonification
However these areas vigorous spawn growth
support either ten fail high yields This white mold develops
a
tous aerial growth on the compost surface . Within a few days , the aerial hyphae aggregates on the com post surface and resembles plaster of paris . After spawning , the aerial growth completely disappears ,
the infested areas
an
pagules of the fungi, are used in an improperly cured support widespread compost . Conditions that growth of Plaster or Flour Molds will not support maximum yields of mushrooms . White Plaster Mold first appears , near the end of Phase II , as small irregular patches of white filamen
colonizes
compost has not occurred
.
tations of Papulaspora byssina ( Fig 36 ) . Scopulariopsis fimicola and P. byssina were common in the days of long composting methods and overly composted ma nure , but have been infrequently observed since the advent of short ( time) composting techniques . Other Plaster or Flour Molds will suddenly appear on a farm if raw compost ingredients , contaminated with pro
of
have been called Plaster or Flour Molds . Brown Plaster Mold has been used to describe infes roseum
,
pilu
up
the most familiar and Botryotrichum
liferum is the most recently recognized . Species of Sporotrichum , Thielavia thermophila , and Trichothecium
these Indeed mold and Coprinus growing compost close proximity conditions are conducive their growth High compost temperatures 120 105 thermophila sult the rapid growth infested the growth areas prohibit spawn growth thermophila slows the compost cools and spawn often
molds may
.
is probably
numerous small black spherical fruiting structures in addition to the fluffy beige form . These fruiting bod thermophila are the sexual stage Growth compost occurs this mold conditions similar piluliferum those that favor the growth Oedoce
by
they can be
|
the colony center start to mature and the fluffy tex ture of T. thermophila colonies takes on a granular flour - like appearance . Mold color changes from white
29
pigmented spherical structures ( bulbils ) on the com post straws or casing . The sporeless structures , bead like in appearance , are called " bulbils " and they are
interwoven with a fine network of white hyphae . A sample of the Brown Plaster Mold fungus rubbed be tween thumb and index finger feels waxy . It is currently thought that growth of Flour Molds by the presence of
unconverted ammonical compounds and amines in the mushroom compost . These conditions can exist when compost is too broken down or overly wet dur ing Phase I composting , and / or inadequately or im
Modi
Mold may significantly reduce spawn growth with a coincident reduction in mushroom yields . Olive Green Mold can be avoided by filling com post that is resilient when compressed and not overly broken down during Phase I. An adequate air ex change throughout the entire Phase II period is es sential to prevent compost from becoming anaerobic
few hours of too little sometimes enough Phase become anaerobic cause compost ventilation system should deliver com a
of
II
in
to
to
.
,
air
air or
-
,
hi -
,
of
.
of
be
at
or
is
,
a
to
of
air
II .
to
,
in
II .
air
Manipulating
tem
,
of
to
air a
to
Ink Caps
,
,
White Chaetomium another Chaetomium species can appear dense white cottony casing surface shortly after the casing has been applied Typically within several weeks sparce number burs will de
,
.
of
compost below the white mold White Chae tomium occurrence rather rare .
velop
.
Black Whisker Mold COMMON NAMES Black
Whisker Mold
Grey Wisker Mold
,
is
.
intake fans can
temperature maintain provides for differential between the compost and gas exchange from the compost the air and should minimize the occurrence Olive Green Mold and
or
of
.
temperature during Phase perature and volume
a
,
in
39 )
is
it
is
of
so
.
,sp
compost
avoided Proper dampers lou
the compost These procedures also enhance aero bic thermogenesis the compost which enables compost temperatures remain hotter than the air
during Phase
is
10
on
-
,
in
so
of
.
a
(
in
by
is
steam valves fresh speed exhaust vers doors and enough insure the availability
:
an
in
,
By
.
--
in
-
to
30
the Olive Green black compost
manipulation
oversaturation
filling time should
as a
.
,
of
.
of
38 ). on
-
is
(
a
or
isolated spots the affected compost Fig The compost will have musty odor Compost capable supporting the growth Chaetomium often does not support mushroom spawn growth common see Olive Green Mold black compost that not Compost that colonized mushroom spawn black and not colonized by spawn can contain many
with water
.
16
of
° F,
to in
of
spicuous greyish white fine mycelium the compost growth compost days fine aerial the surface spawning spawn Fig Frequently after initial growth delayed and reduced late spawn run fruiting structures that look like grey green cockle develop burs 1/16 inch diameter straws
the compost temperature Excessive compaction
in
II
II,
–
of
II,/
in
-
-
.
is
compounds produced anaerobic conditions These spawn growth but favor compounds are toxic growth Olive Green Mold The earliest signs the fungus consist incon
be
II
15
per compost throughout Phase varies from may proportion greater needed since cent but exchange heat and control outside air also used
,
in
,
,
.
in
°
6
F
.
,
,
of
the Olive Green Mold fungus are present straw soil and spent compost Heat tolerant they usually will survive 140 for hours However the only improperly managed appears compost mold especially where Phase during Phase ventilation oxygen inadequate less than Lack especially when compost tem percent Phase permits formation peratures are greater than 142
70
to
a
Trichocladium
air
a
to
air
8
of
IMPERFECT STAGES : Botryotrichum , Humicola , Papulaspora , Scopulariopsis , Thermomyces ,
fungi other than Chaetomium Mold not the exclusive colonizer
of
percent out post surface with minimum during pasteurization for compost filled side depth inches The proportion outside intro duced into room insure aerobic conditions the
olivaceum
Spores
ft A
/
/
1
SCIENTIFIC NAMES : Chaetomium globosum , Chaetomium
to ft
COMMON NAMES : Olive Green Mold
to
to
a
15 hr .
even
Olive Green Mold
is
.
fication of composting practices to improve com post quality usually reduces the occurrence of Flour and Plaster molds .
burs persist throughout a crop . Spawn usually grows into areas occupied by Chaetomium , although full spawn growth is delayed . Compost conditions con ducive to a wide - spread infestation of Olive Green
10
properly managed during the Phase II process
in contrast to the blue - green spore masses of Penicil lium mold or the forest - green Trichoderma molds . Once formed in the compost , Olive Green Mold
of
and Plaster Molds is stimulated
However , the spiny burs characteristic of Olive Green Mold are tell - tale and obvious even on compost colo nized by mushroom spawn . Numerous Chaetomium species are found in mushroom compost , but most common are C. oliva ceum and C. globosum . Characteristically , burs of these two species are olive green in infested compost ,
air
the casing and soon appears on the surface .
Usually white at first , the color changes to the typical brown with a white fringe . The fungus , P. byssina , is easily recognized by hand lens as a mass of darkly
.
through
Oedocephalum Mold COMMON NAME Brown mold
,
purpureofuscus,
:
SCIENTIFIC NAMES Oedocephalum
OUTDATED NAMES : Stysanus stemonitis PERFECT STAGES : Periconia and Cephalotrichum
in
as
.
a
II,
as
-
,
on
is
.
of
or
as
,
,
,
to
.
to
,
a
to a
,
41 ).
(
of
,
its
-
of
to
on
.
as
morphology
,
of
lens
a
.
its
a
of
,
a
hand
of
this fungus discernible consists an erect spore bearing structure with spherical cluster large spores top end Rubbing Oedocephalum spores between the thumb and index finger gives sensa The
through
in of
-
in
to
rubbing fine sand that experienced separates spores characteristic Oedocephalum from other white brown molds mushroom compost casing Spores Oedocephalum are common some mushroom composts but they dormant unless germinate and grow the environmental and duced nutritional conditions that encourage growth are not tion similar gritty This
.
lie
in
in
.sp
or
on
-
.sp
;
fully understood Growth Oedocephalum does not inhibit spawn growth but conditions favoring growth are not optimal for mushroom production
its
.
.
.
in of
the fungus ages and the spores
of
.
, by of
40 )
(
be
silvery brown mature
,
,
its
to
of
from sites infestation up through the casing and pin forma may appear the casing surface prior Oedocephalum tion The pearly white mycelium grows loosely over the surface but color changes
,
of
is
growth Fig when conditions favor Growth Aspergillis and Penicillium molds are also favored conditions conducive Doratomyces the growth fungi may present and these also the compost Doratomyces and the closely related Other species Trichurus spiralus have been isolated from compost
sparce growth over the com post surface dense coating on the compost straws Fig After casing Oedocephalum grows slowly
.
.
-
in
.
is
mold also seen spawn run Whether spores Black Whisker Mold survive peak heat not known but the mold will develop
phalum varies from
of
of
carbohy that the proportion high cellulose was too The compost that overheated during
,
conversely particularly
spawning After spawning the mold light light brown grey but changes dark tan fawn the spores mature The growth habit Oedoce
at
by
I,
of
a
in
.
of
or
,
quate drates
prior
light silvery grey surface during cool down
the compost
to
a
to
Its
.
or
in
pletely caramelized Phase and underheated the carbohydrates are thus form easily utilized the Black Whisker organism Presence Black Whisker Mold may also indicate that nitrogen supple mentation fresh compost ingredients was inade
The mold forms irregularly patches
.
be
.'
of
usually indicates
compost indicates that ammonia
.
,
.
of
'
to
be
,
has not been shown presence mushroom spawn that the straw has been incom
microsporus
1
and amines were not completely eliminated during Phase and are serving food for this organism
to
of ily
infested areas appear darker than usual because black powdery spores When dis turbed these spores are liberated and the compost smoking appears Doratomyces
.sp ,
Oedocephalum
-
serious competitor
Oedocephalum
fimetarium
Black Whisker Mold fungus in compost indicates an unbalanced nutritional base specifically , presence of certain carbohydrates – in the compost at spawning time. When Chaetomium Green Mold is present , Whisker Mold will also be present, since both are celluolytic – fungi that feed on cellulose . Black Whisker Mold , Doratomyces microsporus, grows rapidly through the compost at the end of Phase II or at the beginning of the spawn run . Heav
the masses
,sp
Trichusus spiralus
of
Stroma
an
ABNORMALITIES COMMON NAMES Stroma
,
,
:
of
.
a
of
or
of
on
.
a
in
on
a
be
or
of
be
on
or on
.
,
42 )
,
.
in
-
,
.
31
of
a
casing above patch compost borne stroma casing where stroma does not exist the compost pinning but casing develops Stroma advance rapidly putrifies once crop watering begins Mush in
so
,
many farms
.
unknown
at
of
.
of
assigned
on
.
Sensitive
or
sensitized workers should tasks elsewhere away from compost dumping Proper preparation compost precludes the development these molds these molds are
more intense
peeled from the surface compost casing can much like beefsteak can removed from charcoal grill Stroma form the compost small localized patches areas and the smaller can coalesce into larger areas Fig After casing stroma may form the .
: i )
;
aа
is
,
to
.
or v )
;
iv )
;
alternating nose bleed response transitory per chills The but son sensitive these spores becomes more sensitive with each exposure and the discomfort may become fever and
Sectoring
,
,
ii )
-
;
or
breathing difficulty
Sectors
Stroma are noticeable aggregations mushroom my spawned compost celium the surface the cas ing Discrete aerial patches white mycelium form dense tissue layer on the substrate surface Stroma
(
',
characterized asthma like symptoms including nasal throat irritation chest congestion
iii )
by
.
-
in
'
,
.
,
,
and Penicillium are copious numbers mold spores Air heavily ladened with spores from these fungi often erroneously called gas can induce dumping crew person acute allergy type response nel Workers may report respiratory troubles often
of
Aspergillis fungi which produce
Doratomyces
be
1
microsporus
stemonitis, Doratomyces
:
SCIENTIFIC NAMES : Doratomyces Doratomyces
,
or
is
of
of
by
.
a
to
,
-
a
-
64
of
is
–
.
be to
for
.
in
or
,
18
to
In to
.
12
,
'
of
in
to
a
;
.
on
be is
.
to
'
'
.
of
12
to
-
.
,
,
-
-
,
-
.
(
,
'
'.
to
),
a
-
)
to
:
,
,
,
:
of
.
a
is
,
be
.
.
al
be
,
;
in
,
,
of
de
be
,
,
-
at
,
as
or in
recognized velop singles clusters and can abnormal the pre button button and mature stages Symptomatic mushrooms may appear during the first break and diminish number later in
in
,
genetic
be
to
that causes mushrooms greater and certain strains have a
The mechanism flocked
.
in
.
in
or
they can increase number throughout the cropping cycle Flocked mushrooms are harvest quality able but lower
breaks
is
re -
to
,
,
,
a
be a
'
lacking The cap tissue may abnormally firm most brittle when broken Flocked mushrooms
.
be
is
.
'
on
a
Hardcap Hardgill Open Veil
physiologically induced malformation the mushroom's cap and gill tissue The cap opens pre maturely and the gills affected mushrooms are ru poorly developed dimentary and have little pig completely ment some cases the gills may Flock
,
' (
'
in
,
or
a '
or
'
.
'
,
a '
weepers
COMMON NAMES Flock
,
'
,
be
to
as '
a '
it
on
A
.
a
(
of a
is
.
'
of
,
,
.
.
are usually noticed since they are quite weeping mushroom can dissolve into Water collects the casing surface
putrid odor neath weeper and the area develops becoming stinker Growers have learned move weeping mushrooms from the bed surface and 32
of
of or
8
-
.
of
so
,
to
,
:
as
typically
.
or
44 ).
Weepers
unusual white foam
-
of
,
of
it .
-
weepers
cover the mushroom The weeper leaker and that droplets droplets the water remain the leaker actually falls mushroom while flows from weeper numerous
distinction between
being very prone the condition The old fashioned brown strains smooth surfaced brown cap pileus hefty mushroom with white stem stipe and have not been observed with sufficient frequency
Flock Hardcap and Open Veil
Leakers
exude considerable amounts water from the mush cap droplets room When small water exude from the cap the mushrooms are called leakers Fig stem droplets may These water few number and relatively isolated from each other they may sufficiently
Smooth white mushrooms seem have some sort protection against leakers and weepers Other ma jor types off white cream golden white are sus ceptible this malady with some off white strains
assess occurrence
:
Stinkers
are not the rule usually the occurrence weeper oddity and such instances does not seem yield adverse influence ,
is
or
-
to
,
.
in
, -
43 )
(
"
be
12
in of be
stroma
within inches the sideboard these epidem ics the weepers became stinkers and were suffi ciently numerous adversely affect yield Epidemics
--
.
an
be
.
on
a
,
"
to
mushrooms these areas removal matter for each farmer decide
become moisture
Weeper epidemics crop after crop have been reported The weeping mush rooms were positioned mostly next the sideboard
not
months
to
,
of
shallow cas
ing and has wefty grey white cream white ap Fig pearance consist contrast Stroma meaty tissue although some wefting mycelium may Large patches associated with stroma inches are often removed from the compost casing surfaces with the hope that the next growth spawn will normal and bear mushrooms Remov ing patches stroma does not insure growth
being
/
.
of .
in
at
A
to of
conditions
low
fosters weeper mushrooms prior and during first break Weeping mushrooms can rare and widely higher numbers scattered concentrated Usu ally single mushrooms are affected and clumps are
'
all
to of
is
to
,
or
spawn making the initial step few sectors will not affect yield adversely but the presence excessive stroma may reduce yield Stroma should not overgrowth confused with spawn the casing Spawn overgrowth related
Mushrooms described
but
percent coupled with high less than moisture casing where weepers are frequently seen The combination these two conditions often
compost
.
of these abnormalities , but specific rela tionships have not been elucidated . Even though these factors affect the appearance stroma and sec produce stroma tors the basic capacity for spawn sectors related the genetic makeup the
COMMON NAMES Weepers
trig
bacteria produces the
induce mushroom not but known
that are
,
.
Factors weeper
a
farm
appearance
abnormal environmental
perhaps mannitol
.
or at the
,
Production practices during cropping also affect the
isolate used
sugars foam
or
storage , transit
,
mechanisms not known
affected mushrooms apparently draw extraordinary amounts water from the compost and exude dissolved sugars Fermentation these
,
during preparation
rhizomorphs
–
disap
and tend to
,
Stroma and sectors are related to the genetic char acter of the spawn , but are sometimes induced if spawn is mishandled or exposed to harmful petro leum - based fumes or chemicals , or certain detergents
Weepers
all
.
in the compost and on the casing pear as the crop ages .
The physiological mechanism gering the weeper leaker syndrome of
that is distinctive
–
of spawn
an an
portion
a
of
sector is
when compared to the general appearance of spawn . A sector may be extra white , extra dense , or extraor dinarily fluffy, but it is always different when com pared to normal spawn growth . Sectors appear on or
as
A
remove associated rhizomorphs from the casing and the compost
but this is somewhat
,
unusual .
to
rooms can develop on stroma
in
of
,
of
;
if
in
be
It
.
in
or it
be
.
of
a
,
is
46 ).
) (
of
an or
in ,
.
to
15
of or
80 on
a
is
.
to
to
be
is
)
.
(
so
it
, a
is
,
,
:
is in
all
.
,
occurs
in
36 ° F )
it At
of
or
a
of
a
to
(
and
strains of
to
.
,
-
,
,
crop are most susceptible and most mushrooms from particular growing room are similarly affected enzyme Polyphenoloxidase later increases
.
in
,
break mushrooms and this enzyme influences pig ment formation Conditions that predispose mush phenomenon are unknown but the fre this rooms quency and amount water applied before harvest seem affect its occurrence ,
of
.
to
black than purple
,
a
closer
-smooth white off white cream and brown Gener ally mushrooms from third break the the end
.
by a
Storage
deep purple Cut stems the mushrooms develop color within few hours harvest after being overnight times the color cold storage
to
of
a
a
in of
,
Black Leg
.
it is
Burn
to
12
to
,
,
.
,
to
is
or
3
–
to
on ,
as
,
-
,
.
of
to
,
,
,
Slack Mushrooms Ltd. and SpawnMate Inc. made preparation this manuscript and these illustrations ,
possible
33
-
of
,
.
of
the mushroom stem
our thanks out each them Financial support from American Mushroom Institute Ben Mar Mush room Farms Inc. Oxford Royal Mushroom Products ,
cream strains
although off white
the and
of
to
afflict
illustrations were taken many cooperative mushroom growers go
farms
,
portion
Photographs used of
,
,
Brown
.
1
if :
Brown Pith
much more than other strains strains can have hollow core Symptoms these dis orders are not noticeable when the mushrooms are growing tissues involves since the abnormality the central
Purple Stem
COMMON NAMES
ACKNOWLEDGMENTS
Hollow Core
These two disorders seem
within
,
.
as
to
,
La
of
be
a
. It of ,
Core
NAMES
Purple Stem
,
,
be
it
to
by
'
of
be '
its
.
Hollow Core and Brown Pith COMMON
physiological rather
.
.
of
or
,
If or
.
open veil appears room Overall safe con clude that the mushroom has been under stress dur development
mentation and tissue collapse pathological condition than
,
of on
.
a
in
to
.
is
a
gill
.
.
18
symptom veil can France disease but other justify such diag symptoms must also present period nosis Open veil sometimes occurs when days water stress gener followed ous watering also occurs when fumes certain or ganic chemicals drift into growing are released
ing
and water stress but specifics are unknown Isola tions from the pigmented central tissue Brown Pith microorganisms have yielded seems the pig
an
.
of
,
on
.
,
is
break
,
45 )
30
to to
at
up
(
to
usually ephemeral existing during first alone Areas showing hardcap mushrooms first break produce neither numbers nor weight mushrooms equivalent normal crop Hardcap harvestable mushrooms means loss Open Veil the premature opening the veil with development that may may not normal Generally mushrooms with open veils plus abnor mal immature gill formation are referred gills are developed and pigmented but the flock veil breaks from the stem sooner than should this mushroom has open veil rather than the flock condi watering within tion Most cream strains react hours harvest their caps popping open and the term open best describes this strain trait Open drome
Pennsylvania producers report the prime time for appear early Spring and during the hollow core watering Fall The condition seems related
no
rela
to
.
as
in ,
be
to
disproportionately small
Hardcap mushrooms stem diameter Fig are usually restricted limited areas the casing although percent times the producing surface may have hardcapped mushrooms This syn tion
tendency for such mushrooms nonsaleable There third break second occur unexpectedly percent both and usually the harvest affected room will have the disorder ,
.
of
a
is
,
the cap tends
and
described for flock
.
or ,
as
,
,
cap and gills are
Hardcap
,
La
–
in
,
oil -
oil ,
certain diseases such France Brown Plaster Mold and Truffle induce flock symptoms Hardcap variation the flock syndrome With
Fig stipe When the bottoms the stems are trimmed after harvesting circular gap seen the center the stem This hole may extend the length may may that affected shorter the stipe tissue remains the hollowed area brown color presence such tissue renders the mushroom
a
Environmental
exhaust , smoke from No based paint fumes and certain anticor rosive chemicals steam boilers the presence of
(
.
- including diesel
to
develop the abnormality
to
a
tendency conditions 2 fuel
Significant Insect Pests of the Commercial Mushroom
fly
H.A.
Wetzel
P.J. Wuest
,
,
D.L. Rinker , and R.J. Finley
"
.
fly fly
“
of
Big
to
little flies sciarid while
to
and
,
,
in
to
is
it
by
,
"
"
" mushroom and mosquito are com monly used alike for cecid sciarid and phorid flies Pennsylvania Also many mushroom growers big rather common hear growers speak
The terms
is
"
Sciarid
fly fly
,
of
95
to
75
,
in
.
of
,
of
.
as
"
." "
,
little
"
"
"
used refer the often means the Dung flies are frequently misidentified phorid phorid flies and the size the adult cecid approxi phorid mates that the Sciarid and phorid flies are found together but except late summer one spe percent cies usually constitutes the total flies
adult
of
)
(
.
flies monitored
mushroom
Sep
,
,
Chester County PA mushroom houses from tember 1979 December 1980
these arthropod prerequisite
Phorid
to
a
Understanding the life cycles pests and the damage they cause
is of
.
to
in
percent
all
than
of
95
.
is
pests
be 1
Wing veination Fig the primary used for identifica different and can easily tion Scarid and phorid flies together represent more
population
the the
)
,
,
so
(
,
.
-
an
Knowing effective pest management program emerge when eggs are laid when larvae worms from the eggs when adults appear and forth plus relationship between temperature and the time ,
an
equally
Cecid
.
speyeri
.
is
to
throughout the life cycle
is
rare No pest likely management program achieve maximum effectiveness without integrating management tactics with biological phenomena effective
M.
pesticide that
is
.
a
;
insect's life cycle
A
to
in
is for
a
an
of
ses
of
development insect spends each stage ena pesticide applicator appropriate bles choose particular material each developmental stage pesticide usually effective only during certain pha
THE SCIARID FLY ,
2 )
in
of
H.
of
pygmaea
and cecid flies
.
,
phorid
Two
.
,
Wing veination FIGURE sciarid different cecid flies are represented of
de
frass
1.
addition
depositing
to
In
or
maturing mushrooms mushroom tissue and
,
stroying
.
of
,
mushrooms caps
Cecid
developing mycelium destroy pins and burrow tunnel into the stems and ,
feed
on
vae
at
,
in
(
,
Sciarid flies Lycoriella mali Fig have been the most devastating insect the Pennsylvania mushroom dustry 1979. Sciarid lar least since September
35
larvae may introduce decay - causing organ isms which make it necessary to trim and discard sec tions or whole mushrooms . sciarid
Adult ( winged ) sciarids consume minute quantities of water and other liquids , but do not feed on mush rooms . They can transport pyemotid ( pigmy ) mites , spores , possibly nematodes , mold and other pathogens . Sciarid eggs are laid singly or in groups ; 15 eggs in group is the maximum . At 65 °F , the incubation pe a riod is about 6 days . As the larvae hatch , they move
away from the hatching site to feed , and usually feed on mycelium . The larvae have mouth parts with which they " chew " on the mycelium . Larvae prefer to feed in moist areas and tend to move away from dry areas . They feed for approximately 18 days at 65 ° F , growing to about 6 mm ( 0.25 inch ) in length . They then go into a resting /developmental period called pupation . In the pupation stage , the " worms " may appear to be dead , but in fact they are undergoing changes within the larval skin . When it breaks out of its
Male sciarid
is
It
of
by
by
.
65
,
.
it
a
to
its
° F .
at
of
the sciarid
fly
is a
only
.
Adult and larval stage
of
2.
FIGURE
.
of
,
it a
,
,
movement employed larvae The pupal stage lasts days tendency for pupae way up There work towards the surface the casing As moves the
larva
6
Sciarid
a a
old larval skin the organism still looks like called worm different sort but pupa and the convulsive movements moves abdomen rather than the typical wormlike rhythmic
worm
its
.
at
a
is
fly ,
-
the pupal case breaks and the adult stage emerges winged wings are folded adult and first and extend part way along the abdomen The adult
if
Mating occurs almost immediately are disturbed after adult emergence The life span male adult days about while the female lives about days Flies either sex feed water and other liq uids and tend live little longer moist a
.
Larva
on
,
in
a
to
of
.
to
38
a
of
is 65 ° 35 F,
generation's exist the average length days This period ence time varies con Fig siderably with temperature and sex differences The variation can have dramatic effect on the generations per crop Fig number and the length effectively used for either time pesticides may 4 )
.
5b )
of
.
prefer darkened areas which may
be
light ,
Larvae tend 36
7 .)
of
Larval and adult reactions
to
different stages
of
(
( ° F )
affect
the
sex
and
to
fly .
3.
How temperature
of
a
in
by6.
is in
75
,
70
65 Temperature
the developing sciarid
Fig
single generation are The sequential life stages development Figure illustrated The rate temperature As temperature each stage affected development requires less increases each stage Fig time for completion
Egg 55
the adult stages
5a ,
the larval
(
10
or
of
be
(
of
.
a
3 )
(
20
At
q
Days
h a
environments
.
,
300
65 ° F
at
of
7
.
Pupa
10 is
of
.
Adult
40
FIGURE
to its
60
.
to
,
female
fly ,
=
-
.
30
wings are runs about and within minutes fully expanded While the adults prefer run rather wings are expanded and they they will than
male
fly
50r
4
02 UI6
10 1
SPAWNING
18 1 1
PINS
CASING
30
1
34
38
1
46 50 LLLLL
42
PICKING BEGINS Adult
AIR CASING
PUPAE
LARVAE
COMPOST
IST BROOD ADULTS
INVADING ADULTS LARVAE
PUPAE
IST BROOD ADULTS
INVADING ADULTS LARVAE
H
PUPAE Larva
55 ° F
IST BROOD ADULTS
INVADING ADULTS LARVAE
fly
at
.
Pupa
FIGURE
25
6.
.
of
PUPAE
development different temperatures Num generations per crop varies with temperature differences
FIGURE 4. Sciarid ber
Egg
1.00 mm
Life stages
the sciarid
.fly
65 ° F
++
IST BROOD ADULTS
INVADING ADULTS
70 ° F
26
22 1
of
75 ° F
14
20
22
16
-
15
50 10
10
Days
12
Adult
0
:
5
40
65
55
Pupa
75
70
30
drench
can
effective
when
larval stage
Days
an the
of
the
of
length
days
insecticide
.
.fly
How temperature affects sciarid Number
the female
be
of
FIGURE
5a .
:
( ° F )
Temperature
20
Larva
15 10
5
5
7
.
9
10
.fly
75
( °
affects the different stages
in
How temperature veloping female sciarid FIGURE
7.
be of
the
adult stage insecticide can
70
65
55
Temperature an of
the
of
.fly
5b .
the
de
killing adult flies
.
for
the
length FIGURE How temperature affects days when female sciarid Number useful
75
F )
70
65 Temperature
(° F )
55
0
0
Egg
37
In
.
.
of
fly
)
of
(
in
,
,
)
In
,
to
.
.
of
of
2
A
.
.
7
F in
°
90
-
or
-
to
80 °
at
)
( 2
is
.
or
on
.
.
.sp )
on
on
be
.
be
of
to
,
air
.
,
of
of
,
.
is
.
of
;
in
of
.
21
.
In At At
.
.
be
,
in
be
,
.
77 ° F
68
favorable environments the mite genera completed and will 4.8 and 3.9 respectively
at
tion days
.
in
24
of
an
.
of
otherwise
,
.
or
a
or
as
is
(
.
a
50 ° F
.
of
pygmaea
Myco
70 °
at
.
6
.
an
to -
-
)
(
F
in
.
13
,
In
75 °
by
quadratus and The life cycles these two species are identical Adult female mites lay eggs average masses eggs per with hours The about mass Eggs hatch into adults length the life cycle varies with temperature generation will completed each 7.6 days higher temperatures generation length decreases mesembrinae
88
8
12 ).
of
with larvae
Heteropeza
two species
yellow orange larvae white with a
,
yellow and
consists
,
,
philla speyeri
38
Fig
(
The Cecid
13 )
fly
THE CECID FLY
little food
The two most common mite species found Penn sylvania mushroom houses Pygmephorus are P.
be re
,
.
a
of
(
Fig
They eat weed
weed molds without weed molds there for the mites
to
;
.
-
° F .
65
at
20
,
bly with temperature
mushrooms
molds such Trichoderma which develop when poorly prepared Mites can transported compost species various flies currents tools and equipment from mushroom house mushroom house Proper preparation and pasteurization com post usually prevent the development large popu lations mites Properly prepared compost has few
5
be
-
F,
65 °
be
.
inch
not feed
.
in
.
"
"
,
-
to 14 At to -
,
in an
;
in
the larvae cycle will com days The pupal stage follows the about pupae appears whitish initially but quickly comes dark yellowish brown The pupal stage quires days Adult flies may live for about generation varies considera days but the length
pleted
Mites
in
.
in
3
,
.
of
3
to
2
or in
compost the casing The eggs hatch days and newly emerged larvae are nearly transparent and taper towards the head end With maturity they become whitish and are about 4.5 mm length end end about five and one half larvae
inch
Pyemotid mites are commonly called pigmy mites red pepper mites The mites cluster mushroom caps and also can casing found the
so
)
-
(
to
.
length Adult female phorids are about mm They lay smooth elongated ovoid eggs beneath the
end will equal
PYEMOTID MITES
do
of
).
eight larvae end
of
11 ).
(
,
(
Heteropeza
to
is a
.
.
of
to
;
to
Unspawned
compost and fully grown mature composts are not ovipositing egg laying female phorid attractive flies
equal
,
It
,
If
.
,
to
in
of of
room workers notice adult phorid flies during the day Mating because their daily flight schedules Fig commonly phorids outside found are swarms mushroom houses once mated the females are at actively tracted mushroom houses by the odor compost
.
on
in
of
pygmaea adult females are 1.5 mm long compost the mother larvae produces about seven days The larvae are white and larvae every days About will attain full size 2.8 mm
are usually most common late early present the flies summer and fall cropping light and swarm near windows and are attracted growing doors rooms and packing sheds dead phorid flies see thousands common sight on the floor beneath windows and near doors Mush
spawned
vae bearing more larvae Under certain conditions these paedogenetically produced larvae may revert the sexual type cycle Mycophilla speyeri adult females are 1.5 mm long
orange yellow and attain full Larvae are yellow days length size mm mm about one twelfth inch
.
is
,
Adult phorids
surface
.
,
(
,
in
in
.
,
be
(
,
10 ),
Megasellia halterata Fig general phorid more numerous than sciarids but flies cause less mushroom damage than sciarid flies How phorid feeding ever the total economic effect mycelium not really known
Phorid flies
growing mycelium
development Cecid flies have two types the sexual type the adult mates and the female lavs eggs which hatch into larvae The larvae grow and molt shed the skin several times become pupae and then adults reproducing the paedogenetic the sexually immature stage type repro larval duction the mother larvae bear larvae which increase size and without fertilization become mother lar
THE PHORID FLY may
mycelium
or
.
the air
Either can reduce crop yields when larvae feed on the
.
.
shows when the adult sciarid flies are
in
ure
9
it
fly
why they are seldom spotted on the casing surface . Adults , both male and female , also prefer a darkened area to an illuminated area ( Fig 8 ) . This adult re sponse may explain why the kind of light in a moni tor affects the number of adults attracted . Mushroom be growers generally don't see the adult sciarid Fig during cause the hours which flies are limited
Illuminated
20
(32 to 52 ft- candles )
of 10
number
2x
1x
Number
6
PM
Midnight
Flight pattern phorid flies Adult phorid flies are com monly observed during the daylight hours .
FIGURE
of
,
,
dark
.
prefer
Noon
AM
11.
Adult sciarid flies both male and female an illuminated area
a
Midnight
.
Female
6
1
5 0
Male
8.
to
FIGURE ened
-
caught
3x
adults
15
Relative
Nonilluminated
70
68 Adult
50
Days
3x 7
Pupa
45
40 30
24 Larva
20 1x
FIGURE
How temperature veloping phorid
affects the different stages
of
FIGURE
.fly
of
in
of
9.
of
Flight pattern FIGURE sciarid flies showing the relationship be tween the number adult sciarid flies the air and the time
75
65 Temperature
( ° F )
Midnight 12.
PM
Egg
55
13.
Noon
AM
6
6
Midnight
VI
10 0
Relative
number
caught
60
the
de
the cecid
.fly
Adult and pupa stages
of
the phorid
fly .
Adult and larval stage
of
FIGURE
10.
.
day
39
Supplementation with Vegetable Oils Before Phase II of Composting
in
,
oil -
be
In
II .
in
to
in to
Its
F
by
9 °
5 °
). an
,
,
a
(
toxic
and compost
within the compost areas undergoing the mushroom .
anaerobic fermentation
1
,
or
-
between
air
differential
provides for better ventilation thus reducing the possibility
be
turner This method proved insuring thorough mixing
oil an
it
of
be
temperature
to of
to
,
of
II .
to
in oil -
in
of
oil
of
supplementing mushroom com study the effects just prior post with vegetable Phase Crude cottonseed was sprayed onto the compost just passed into the mixing beater fore the compost oil
in
ap Jr ,
,
,
to
oil
A
.
to
the biological activity other Enhanced was evidenced marked increase FIRE FANG white flecking on supplemented compost Fig the straws the The increased biological activity requiring greater .
.
at
,
A
feasible Penn State Thomas Patton few years later pursue and the author decided detail this supplementation vegetable proach mush tests were performed series room compost
both composts supplemented compost had maintained lower than air temperature tures
containing the
,
that the idea may
increased thermogenesis maintain similar tempera temperature the room
addition resulted during Phase order
a
be
A
in
at
II
by
to
or
its
ble oils
1 )
of mushroom compost with vegeta prior to being filled into trays beds un composting was first tried dergo Phase Dr. J.W. Sinden and the author the Butler County Mush room Farm 1964. few preliminary tests showed Supplementation
in air to an
Lee C. Schisler
of
TREATED
ft2
lb /
-
supplementing compost with cotton seed
before
Phase
oil
1 .)
(
of
Effects tray
II .
ml
)
(
500
ft
Table
/4 1. -
of
.
of
.
of
.
to
efficient way throughout the the compost The compost was filled immediately after turning Yield increases resulted from the 0.4 addition the oil Table
Yield
None
2.71
Cottonseed oil
3.11
FIGURE
oil -
In
as
,
to
rapid reduction
.
in
hours before the same condition was nonsupplemented compost The
the
oil -
as
72
2 )
of
achieved
by
its
II
of
.
is
to
in
of
supplemented ammonia compost probably due increased usage the increased populations The reduction duration Phase saves valua in
and addition conserves dry weight and nutrients for the mushroom
ble time
.
in
to
quickly
in
to
15
a
II,
grower
.
room
of
,
to
of
adding vegetable oils compost The advantages prior percent increase Phase other than yield are considerable importance the mush
supplemented compost disappearance the the free ammonia seemed have occurred
,
of
in
..
be
.
is
by
or
II
of
to
.
in
II
Increased biological activity during Phase was also noted Whether the increase mushroom yield was due the buildup microbial protein the compost during Phase direct stimulation mushroom mycelial growth and fructification the oils not known Evidence would suggest that both factors may involved
1 .
( lb / ft ")
Supplementation
41
in
5
to
provide
to
a
(
two drums 110 adequate level an
)
(
to
oil
ft
.
II
of
)
4000
addition
.
of
-
is
as
of
in
is
,
for spawn growth
in
,
20
II
to to
of
prior 15
ble oils yields
.
in in
in
mushroom compost with vegeta Phase will increase mushroom primarily through percent creased microbial activity and thermogenesis during mycelium growth Phase Rate accelerated supplemented compost reducing the time required Supplementation by
.
II
,
Summary
II .
to
In
.
of
.
of
an
house seem
as it
,
-
a
,
be
of
.
or
of
to
on
in
pointed out however that both the should creased biological activity during Phase and the creased activity the mushroom mycelium during heat increase the spawn growing period create -
oil
-
in
of
(
A
”
.
“ ,
pests during spawn growth Any eral important savings time during this stage the production cy cle reduces the disease hazard It
.
single mushroom gal vegetable
provides in the grower year round basis addi creased production tion the mushroom beds are most vulnerable sev
42
plementation
The effects of various levels of addition prior Phase have not been determined For standard
growth was noted compost the nonsupplemented This reduction the spawn growing period reduced the dead time when the trays beds are not actu ally producing mushrooms the mushroom pro significant reduction such ducing cycle this economic importance
production during these two phases of the produc tion cycle . The grower must be able to cope with the additional heat to obtain the benefits of this oil sup
)
3
a
of
.
oil -s
3 )
of
Mycelial growth the mushroom was enhanced upplemented compost The treated compost the dense growth was thoroughly impregnated with mycelium days before similar mushroom
Spawning to Casing in Commercial Mushroom Production D. J. Royse
L. C. Schisler
,
,
and P. J. Wuest
SPAWN understand spawn , spawning , and spawn growth , the mushroom itself must be understood . Mushrooms are fruits of the fungus Agaricus bisporus , and consist of two main parts – the cap and the stem
To
( Fig 1 ) .
As the mushroom matures the cap opens and ( Fig 2 ) . Mushroom spores are
the gills are exposed
produced in the gills . Spores are microscopic spheres roughly comparable to the seeds of higher plants ( Fig 3 ) . These spores are produced in large numbers in the
A 3 -inch mushroom produces as many as 40 million spores an hour . Since spores germinate and grow into mycelium rather unpredictably , they are not used to ' seed ' mushroom compost . Spores will germinate and grow into thread -like mycelium , which is used by laboratories that produce spawn gills .
FIGURE
1. Cap and stem structure of the commercial
mushroom
.
commercially . In the spawn -production process , mycelium from the spores is placed onto steam - sterilized grain , and in time the mycelium completely grows through the grain . This grain /mycellium mixture is called spawn ,
and spawn is used to " seed " mushroom compost ( Fig Most spawn is made with mycelium from a stored culture , rather than mycelium whose parent was a spore . This is because each spore is likely to yield a performance would new cultivar ( strain ), and unpredictable The term cultivar describe used Spawn making cultivated variety asexual to
is
.
an
is
.
a be
its
4) .
so
is a
a
t
a
.
,
SPAWNING
a
cap
of
the
underside
of
Figure Gill structure open mushroom
the
If
.
II
of
be
,
a
a
to
it
at
-
is
in
)
is
by
1
(p
Phase the end after cool down ready for spawning the the compost spawn refrigerator time can gained stored moving warmer place the day before spawn eak heat
2.
Immediately
on
of
.
be
is
for
.
be
eye
"
"
an
to
of
propagation similar dicing potato planted Spawn making can rather complex task and not practicable the average purchased from mushroom grower Spawn may spawnmakers number commercial and most spawn mushroom farmers purchase from these sources
method
mature
43
,
a
5.
of
spawning machine showing tines that Underview through mix spawn broadcast the compost surface .
FIGURE
on
the commercial
.
or
of
-
to
of
of
to
,
at
is
of
in its
in
– --
.
is
,
a
,
(
a
6.
with one
two grains
,
per cubic inch
.
(
it
of
is
in
.
;
it
in
to
a
is
,
to
used
or
3
.
of
is
to
.
of
in
-
a -
a
in
-
as
is
-
in
-
b .
After the machine has passed through the compost tamped with device sim the beds the compost Figure ilar that shown There are several ad vantages mixed spawning reduces the spawn growing period and increases mushroom yield The spawn evenly distributed the compost impregnating depending on the amount spawn )
.
Spawn broadcast over the surface Ruffling being ma the bed and ruffled the compost nipulated into flat surfaced bed The depth ruf fling varies from fraction an inch inches of
.up
.
to
is
,
at
the mushroom industry
today
44
greater and greater extent the bed sys mixed throughout the compost usu specially designed machine Fig the tines
Spawn
of
-
of to
is
in
,
.
of
the bed the lower portion the grain lost the many farms broadcast
in
the compost
Also the nutritional value crop Although not used spawning still practiced
tem ally
is
re
, a
,
to
for
of
to
cess
panded by
in ,
Its
.
to
of
to
dry surface conditions and the time start due grow throughout the full quired mycelium compost and establish total colonization depth thereby allowing competitors more time gain ac
c .
.
to is
,
of
a .
broadcast over the surface grow into the compost Chief the beds and allowed advantages the broadcast method are convenience disadvantages labor saving and time saving drying conditions grains clude exposure slow
similar
This method eliminates most the disadvantages broadcast spawning except that the mushroom my celium must still grow down through the compost from wherever the deepest spawn grains happen end This method more widely used than broad cast spawning especially farms where mechanized spawning equipment not available Mixed spawning This method was first used growing and now the tray system use has ex .
of
Spawn
Used
5 ).
,
.
.
be
to
is
1.
Methods Broadcast
FIGURE material
ing done The mycelium will resume growing and time will be saved
Compost tamping device made aluminum tamp the compost after spawning
6.
grain
.
from sterilized
to
spawn prepared
in
Mushroom
seed mushroom compost
.
to
FIGURE used
rye
4.
.
structure
-
lining
spores borne on basidia mushroom
of
micrograph ( magnification 5000x ) of gill
3. Scanning electron
FIGURE
All
20 15 F
10
20 22 24 26 28 30 )
days
of
Relationship between the quantity spawn used and growth time required before casing .
the amount
of
7.
FIGURE
as
,
in
(
at
of
10 -
.
A
or
In /
-
,
at
to
,
,
at
in
of
or
of
-
.
-
oil
at
of
to
.
of
60
of
in
.
is in -
into
com
is
A
un
6
. In
,
to
4
.
be at -
-
a
,
be
-
at
,
to
or
,
of is
as )
to
( 5
4
a
applied should not inches 7.5 cm from the side boards this region normally not well through supplement exist mixed Where concentrations adjacent near the surface the sideboards ,
the most sanitary opera
)
.
the
,
at
.
,
,
by
supplement
as
bed system closer than
or
one
of
be
should
supplement
using delayed release sup plement successfully uniform through mixing per delayed release nutrient usually applied dry compost weight should not used cent performed less mechanical through mixing the
.
Sanitation
or
of
,
in
delayed release
The key factor
to
.
Incorporating post
-
to
to of
a
in in
2
,
ft ?
ft,
12
-
1
as
be
,
within
.
is
to
in
be
is 1
as
.
spawned compost can damage
encapsulating microdroplets vegetable protein coat that was denatured with formal dehyde Increases percent mushroom yields were obtained come
–-
of
to
of
of
by
is
.
Overheating
thereby reduc injure the mycelial fruiting capacity ing productivity delayed release nutrient supplementation 1976 developed was The disadvantages associated with noncomposted the supplementation nutrients spawning were largely over mushroom compost
of
of
ft
2
.
,
is
in
spawning However excessive heating and strong competitor molds stimulation the compost dras tically reduced the rate which supplements could used and concurrently their corresponding bene be fit .
of
as
at
.
is
7 );
-s
to
,
,
.
, is
Developing technique the early 1960s yield creases were observed when compost was supple lipid rich materials mented with protein and percent increase casing and later spawning crop yield was obtained when small amounts protein supplements were added the compost
In
is
of
,
of
as ft1 of
60
as
(
to
as
In
.
be
air is
con
SASing
SUPPLEMENTATION AT SPAWNING
-
in
a
in
.
for
is is
.
inants from less sanitary operations
3
in
is
of
.
-
in
a
at
.
as
of
If
when outside cool and readily available trol compost temperatures
,
to
of
be
a
of
,
be
.
in
,
mushroom growing Spawning tools bas thoroughly cleaned kets and equipment should water and disinfected before with strong stream the the first operation use Spawning should work day insure that the workers their outer gar ments and their shoes are free debris contam tions
.
.
,
,
-
.
.
a
with tendency towards excessive compost heating cooling equipment isn't available higher spawning year rates should used only during the time
Spawning
32
18
16
casing
(
.
Time
to 14
1
12
10
8
4
spawn
FT
6
5
spawned
25
,
as
,
.
,
-
is
its
35 30
.
its
-
80 ° F
at
is
to a
in
be
In
1
mushroom production and reduces the time needed especially true when this for spawn growth Fig mixed pawned The increased mush the spawn room yield due more efficient utilization com post nutrients which turn related more initial growing points and quicker colonization the com post well the nutrient value the spawn grain itself adding more spawn one effect adding more nutrient There are practical limits the spawn that may amount added and still get creased yields When spawn ruffled the maxi mum beneficial rate about unit per but high with mixed spawning rates unit per On the other hand have proven advantageous creased spawning rates are not without disadvan tages Increased heat generated during spawn growth and cooling equipment must cope able ,
?
40
2
to
.
a
,
by
.
its a
is
2.
Rates
practice spawning rates vary among commercial spawn mushroom farms The basic unit the quart since grain spawn was originally made quart sized milk bottles and bagged quart sized spawn units Though only small percentage quart sized units today spawning rates are made quarts per square feet still designated terms compost surface Some growers spawn rates low quart bed surface Others will each quart for each sur great spawn rate spawning Increasing face area the rate increases as
/ qt
Compost
.
an
,
.
In
a
of
be
of
;
so to is
,
supplemental themselves become nutrient Bed growers are using spawning machines more and more Growers without machines are encouraged hand using short handled pitch forks mix spawn disadvantages All Mixed spawning not without bed destined for mixed spawning the compost spawning time since must cooled below well mixed throughout the bed the spawn near cooler outer surface However mixed spawn ing recommended practice since the advantages disadvantages far outweigh
3.
1
,
is
to
.
of
grains become initial points growth The mycelium grow any great distance before the does not have compost completely colonized and this saves time Time not the only advantage uncased beds are open various kinds infestations during this pe spawn growth can riod shorter period important advantage addition the spawn grains
45
a
all
at
to
.
of
to
no
,
be
no
.
or
,
,
.
at
If
de
is
of
,
.
be
.
.
of be
.
.
in
;
of
of
an
by
by
no
.
(
N )
.
a
is
-
at
is
of
.
,
,
N
,
as
,
a
N
to
is
It
in
.
, ,
”
ei
.
of
to
In
.
is
,
,
“
,
a
in
be
.
as
or
of
II
to
20
to
15
a
of
at a is of a
of
oil
of
in
of
-
.
of
in
percent increase
by
II,
in
.
in
of
of
.
heat being given off the compost Increases mushroom yield associated with lipid additions are due combination more microbial protein pro direct stimulation and duced during Phase mushroom mycelial growth and fructification during a
II,
at
.
spawn run and production Supplementing compost with after the compost fully permeated has been with mushroom mycelium oil
,
no
or
of
,
be
to
pH There seems little correlation be tween compost pH subsequent mycelial growth and pH made ultimate yield Determinations the
–
a
to
.
,
,
–
2.
/ml lb
.
.
in
,
Compost Factors
.
can result
mushroom yield Oil addition also increases the bio more logical activity during Phase which results
a
a
is
.
A
and spawn makers can often pro vide helpful information this regard each cultivar used
posting
to
their inherent capacity
genetic charac slower growth This teristic associated with the particular mushroom grower must become familiar with cultivar used .
is
10
bisporus vary
in
or of A.
Mushroom Cultivar Used
the
Lipid content lipid compost The amount will affect both the rate and quantity spawn growth Data from supplementation mushroom stim compost experiments show that linoleic acid ulatory lipid Crude cottonseed oil added rate wet compost prior Phase com 4.
.
.
-
of
The length the spawn growing period can affect yield Many factors can determine the proper spawn growing period
1.
necessarily denote good compost summary spawn growth rate not necessarily related compost ther yield the nitrogen content a
a
as
SPAWN GROWTH
46
very slow spawn growth Generally speaking well composts with the spawn growth may slower high content but fills out becomes more dense grows Of course slow spawn growth does not .
.
C )
26 °
to
(
F
°
80
/
or
to
27 ° 78 ° C ) F (
74 °
of
Temperatures
may inhibit mycelial growth damage the fruiting capac
.
of
ity
hyphae
to
23 an °
.
,
in
to
.
,
higher than and cause injury and
greater the ammonia content provided there present the better the yield This correlation how ever does not necessarily hold true with rate spawn growth possible have very rapid compost with spawn growth content low
N
ad
be ,
In
.
of
,
of / or
in
spawn run Mushroom cultivars differ their response general spawn growth temperatures However growth tempera optimal rule most cultivars have
to
be
of
.
if
.
to
to
this way the that temperature increases will occur can air temperature volume the and air justed surge thereby advance the heat main taining optimum compost temperature levels during
Nitrogen content The nitrogen content should spawning There positive cor 2.0 2.5 percent relation between nitrogen content and yield The
of
be
nonsupplemented compost These events anticipated are controllable The grower must days after spawning able determine the number
termined modified Kjeldahl method Most peo ple can detect ammonia content about 0.1 per cent smell this level ammonia will severely excess restrict spawn growth Concentrations 0.2 percent usually kills the mycelium 3.
of be
by
.
48
air as
to as
The normal peak tem advanced perature during spawn run also may much hours and the response the compost delayed temperatures will when com lower
spawning time should less than 0.05 percent ammonia content exceeds this value mycelial growth compost retarded Ammonia content best
,
C )
5 °
above
Ammonia There appears direct correla tion between ammonia content subsequent mycelial growth and ultimate yield The ammonia content
as it
ad
-
.
( 2 °
F
8 °
to
3 °
to ,
on
in
to
,
a
of
.
may îise nonsupplemented compost temperatures
for rapid
a
a
is
-
a
at
to of
of
compost
mycelial activity releases more heat into the compost nonsupplemented com than mycelium growing the condition and post As result depending dissipate heat compost bed ability the compost
Cultivars
,
.
of
be
of
It
The spawning encour ages more vigorous mycelial growth This increased compost temperature
Anticipatory control supplement dition
ture range
6.0 after
.
be
It
.
a
.
in
supplement
the way
during
compost been un Composts have been found with rela successful tively high pH containing ammonia and sup porting good mycelial growth On the other hand composts with relatively low pH 6.7 containing considerable ammonia and supporting little spawn growth have been observed .
,
a
be
to
of
overemphasized bution the nutrients cannot that thorough and even mixing the supplement delayed release key factor successfully using
to
a
.
On tray lines with tipper mechanism the supple evenly applied after the compost has ment should applied dumped should from the tray been prior spawn This the application and mixing practice will assure more thorough and even distri
pared
time of spawning seem to be acceptable pH from 6.5 8.2 The compost pH spawning crop decreases from 7.5 cropping Attempts the correlate pH with spawn growth and ultimate yield have of
for airborne
source
nutrient
a
become
a
they may molds
an
=
:
.
ac
is
of
.
is
;
=
,
30
.
”
–
;
1.5
–
) -
pe
7.
Ventilation and environment humidity The venti lation requirements during the spawn growing riod are not fully understood No precise data exist
1.0
(
Growth
.
-
2.0
,
dry compost small mushrooms Also weepers mushrooms from which water ex udes occur with very dry compost
rooms
2.5
"
rate
mm day
40 3.5
=
) / (
an
effect but indirect one Example Too wet too little moisture for aerobic compost too dry thermophiles generally One direct effect which cepted that moisture can influence size mush
45
.
It is
of
on
the effect ventilation during spawn growth yield generally assumed that little mushroom oxygen required during spawn run Growers are
culti
.
no
growth rate
to is
on
compost temperature
30
25
keep the house shut tightly with advised venti except necessary lation that maintain desired Withholding compost temperature ventilation makes easier maintain high humidity and denies it
a
at
.
of is
to
of
re
)
(
.
up
.
to
,
on
,
,
95
as
at
be
is
possible
.
moisture
to
or
to
74 °
of
,
increased growth rate between 1000 and 5000 per ppm The humidity should maintained higher preserve compost cent R.H. much
to on
.
is
as
far
in
as
in
.
is
to
no
.
8.
in
Sanitation to
-
a
be
.
is
.
on
if
.
,
,
.
,
its
,
.
or
of
,
of
a
,
pe
.
,
,
in
,
.
be
of
ft
-
, a
.
In
of
the greater the total yield
course
,
and generally
Of
direct
and
given set summary conditions under spawn growth can affect both yield and pat yield general tern shorter spawn growing early breaks con riod means fewer pounds per sisting larger size However fewer mushrooms generally reduced The longer the total yield can period growing spawn the larger the early breaks
length
.
generally not
a
de
”
,
of
“
of in
spawn growth
is
on
.
sired range
the texture the compost may cooking out the com compost moisture outside the
surface provides ideal conditions for germination growth pathogens pests
,
or
.
on
properly
,
water depending
cause difficulty post This effect
be
,
,
.
,
do
a
.
or
percent for synthetic com nure compost post These ranges are generally accurate for opti mum spawn growth and assume resilient compost structure However exceptions occur where spawn growth and eventual yield will optimum too little outside the ranges given Too much water
of
at
of
70
to
75 65
65 be to at
–
6.
compost Moisture The moisture content spawning should percent for horse ma
-
.
of
°
F
to
compost temperatures rise above mycelial activity the rhythmic growth pattern
compost surfaces Covering beds with plastic not disadvantages without however Less evapora tive cooling occurs and keeping bed temperatures within the desired range during warmer weather may problem Also contaminants are present prior covering the moist environment the compost a
the during peak
In
of
this
of
78
i.e. the tendency
,
obvious considering
plastic film protect Beds may covered with compost surfaces from air borne contaminants and pests The film also prevents moisture losses from the
to be
of
of
.
,
rhythmic growth pattern
is
78
° F
°
to
a
or
rather than
76
76 ° F
4
of
so
be
a
85 ° F .
if
to
Salt concentration The concentration soluble salts the compost believed have effect spawn growth and eventual yield There appears be an adverse effect when salts are high the casing soil but not the compost known ,
° F,
is
of
.
to
.
°
F at
is 85
any time during spawn growth The mycelium not killed until temperatures reach 104 but growth severely restricted and permanent damage can done the fruiting mechanism the myce lium incubated above rhythmic pattern Mushroom mycelium exhibits compost temperatures should growth moni day tored more times One the merits maintaining compost temperatures between 74º and is be
levels about 10,000 ppm San laboratory mycelial Antonio studies growth suggests the optimum CO concentration for
doing
as
.
-
a
,
a
in
76 ° F
CO
increasing
,
for
on
is
8 )
(
in
taining bed temperatures within the range results more rapid growth rate and conse quently shorter spawn growing period Growers should not permit compost temperatures exceed
dicate certain levels carbon dioxide CO accumu lation enhance mycelial growth Long and Jacobs ported that mycelial growth rate increases with
.
by
II
.
–
of
of
to
74 °
is
the mycelium
of 78 ° F .
5.
The optimum temperature the the cultivated mushroom This finding based primarily the research Treschow Fig Practical experience compost shows that main with growing spawn Temperature
growth
mushroom pests the house time when the mycelium most vulnerable Some data in
access
an
a
in
be
,
.
of
oil
to
)
(
just before casing SACing results higher biolog partial utilization ical efficiency and more yield due during Phase the supplemented ther mophilic microbes However SACing poses practical problems which will presented later
to
.
a
to
.
8.
FIGURE Effect vated mushroom
of
Compost temperature
on
20 ( ° C )
5
10
of
15
.
0.5
47
48
or
A
or
a
.
If
,
be
in
be
in
to
,
,
.
is
)
it
is
,
an
.
be
.
of
in
.
air
in
in
far
,
-
27 ° , C )
)
(
to
°
F (
80
it is
as
as
to
by
,
”
set
,
.
,
,
.
to
air
a
in to
is
of
.
II
.
.
-
,
in
.
a
.
,
in
of
of
a
of
SACing yield obtainable the de border break nonfruiting my velopment thick overgrowth
.
by
in
be
,
of
.
is
which the the room spawned compost kept fruiting on casing atop Second the induction compost problem SAC'd can The casing layer limiting the increase plays an important role
production involves variety compost Production that selective for mushroom growth and which contains those nutritional substances necessary optimize yields step compost mushroom the first Care preparation during Phase will mini and Phase mize problems encountered during the spawn grow ing period from spawning time through casing Attention the environmental physical and nutri tional factors discussed will yield increased quantity harvested mushrooms and quality Successful mushroom interrelated factors
I
,
,
-
.
of
a
is
riod function mospheric conditions
SUMMARY
is
the time needed the spawn The spawn growing the compost the cultivar and
the compost
at peto
for
relationship
to
its
Certain problems, however , must be overcome at commercial operations before SACing can be rou tinely used . First , the mycelium must be grown through the compost thoroughly before it is dis turbed by the fragmentation which precedes SACing . The exact time for SACing cannot be specified due to
fully colonize
.
is
in
about the same level as that of nonsupplemented compost .
special back room designed espe handle the increased heat load generated the increased mycelial activity the SAC'd compost used some mushroom tray farms Most commer cial mushroom growing operations however are not handling facilities sufficient equipped with ex change the heat produced casing cially
to
,
rapidly changes the heat produced the tem high perature can rise rapidly above enough mycelial fruiting cause possible injury capacity Maximum thermogenesis heat production usually occurs between the third and fourth day after “
production ) of production falls rapidly to
pattern of mushroom
the supple compost produces mented heat amounts above that associated with mycelial activity undisturbed compost Unless the around the compost ex
Finally increased mycelial activity
of
( cyclic
fragmented and can then multiply
mushroom production Nematode infes especially troublesome problem tations can with this practice
A
occurs in the first 30 days of production ; this period roughly with the first three to four corresponds
post when advance
.
the compost for mushroom growing must be added when any of these supplements are used for SACing . The compost must be fragmented to insure a thor ough mixing of the supplement into the compost . supplemented Once the compost is at casing ( SAC'd ) , the compost is leveled , pressed , and cased . Most of the yield increase obtained by SACing
mushrooms . Thereafter
stroma casing
be
)
Increases in mushroom yields of 100 percent have been observed when soybean meal or cottonseed meal were added to fully colonized compost at the rate of 10 percent of the dry compost weight just prior to casing . One additional step to the preparation of
breaks
may occur when certain type used Third weed molds mites pathogens and nema present compost todes must not SAC'd present they will distributed throughout the com
celium depth
of (
re
to
SUPPLEMENTATION AT CASING ( SACing
a
,
can cause
at
period
of
too long a spawn - growing duction in yield .
Influence of Cultural Practices on Mushroom Yield Response to Delayed - Release Nutrients Lee C. Schisler
State University spawn strain 324 ( a light cream ) was used at a rate of 110 g per tray . After a 2 - week spawn - growing period with compost temperatures maintained between 74º and 78 ° F , the trays were cased with 1 to 1.25 inches of pas teurized top soil . Ambient air temperature was main
disadvantages microdroplets
level throughout the remainder cycle
for
or
.
1
of
F
at
61 °
to
18
to
15
in
of
cultural practice being investigated these general procedures were employed for each experiment
in
.
of
Weight and number and trimmed mushrooms harvested from each tray were recorded daily Except where the experimental design was modified for the .
.
.
was applied Seven flushes were harvested the day picking period All mushrooms were picked
,
60
by
be
days after the soil
.
at
by
of
of
Various researchers have shown that mushroom yields can increasing the amount increased spawn mixed into the compost Early experiments demonstrated that increasing the spawning rate
Mushrooms matured .
.
)
(
a
oil
of
of
percent stimulation increase mushroom yields yields during the first few flushes and beyond pro delayed nutrient release vides evidence
the production
.
by
.
of
,
:
at
,
encapsulating vegetable lipids within protein coat denatured with formaldehyde encapsulated microdroplets spawning can Use
approximately tained at 74 ° F week until the mycelium reached the casing's surface Air tempera ture was then reduced and maintained that
.
ad
in
at
.
are largely overcome
below , The Pennsylvania
56 -
,
at
.
,
at
-
or
of
Supplementation mushroom compost with protein lipid rich materials spawning casing and later has increased mushroom yields Biological and practical limitations often accompany supplement ditions these times commercial mushroom cul ture Disadvantages associated with adding noncom spawning include limited posted supplements nutrient addition and yield stimulation excessive heating and stimulation competitor molds These
.
of
12
g
,
,
at
2 -
48 -
at
.
48
,
of
50 ,1
of
a
at
,
.
of
in in
in
a
3.
in
on
ft
in at
ft ?
lb /
.
all
at
,
1
-
/
lb
-
A
1 ).
(
of
an
in in
.
no
ft '
lb /
in
,
specifically
yield with Table one can see slight increases creased spawning rates during the first three flushes approximately 0.6 with larger increases due supplementation the last four flushes In of
to
,
noted
month
supple increased spawning rates and mushroom yields are presented slight increase yield and There was
.
where
10
in
of
4
45
lb
to
40
.
ft
at
.
,
lb
1
of
at
,
lb
Except
approximately
with increased spawning rate Table five fold spawn caused approximate 0.25 crease yield Addition delayed release supple crease approximately ment however evoked yield spawning rates Looking increase in
of
in
-
a
commercial product Spawn Mate The nutrient was uniformly throughout the compost spawn per tray the rate area that con tained approximately wet compost 13
1
.
II,
-t
a 6 -
day low emperaure Phase were employed The delayed release nutrient this series tests was
dry weight
In
1 , 2,
.
I
7 -
to
6-
,
by
a
at
Normal composting procedures used the Mush day Phase followed room Research Center
mixed ing
Effects mentation Tables
,
of
investigate these factors
to
ments were designed
experi
2,
.
The following series
of
,
-
planted
Ag
,
or
of
-
to
of
aricus bisporus
three separate composts intervals of
delayed release nutrients include supple compost filled per mentation rate and dry weight tray area incubation temperature dur unit bed ing the spawn growing period and the strain
experiments dealing with spawning rate trays were spawned the rate 100 150 and 240 spawn per tray making trays per test total Half the trays spawned each rate were supple tray tests were performed on mented Three such .
of
-
.
-
at
spawning Other cultural delayed release nutrients practices which could affect mushroom yield re sponse
SPAWNING RATE
to
to
of
of
It
on at
of
creased the yield mushrooms from trays supple mented with readily available nutrients spawning compare the effects was interest mushroom yield increased spawning rates and the addition
49
increase resulted from increased spawning rates but increases of 0.3 to 0.4 lb / ft' occurred due to supple those of mentation . Results of this study confirm earlier workers who found that increased spawning rates increased yields of mushrooms. However , the increases are much greater from the addition of the delayed - release
nutrients
than
from
increased
spawning rates . Increased spawning rates do not in crease the yields of compost supplemented with de layed - release nutrients . This is in contrast to results reported
in the experiments of supplementation spawning with readily available nutrients .
1. Effects of spawning rate and supplementation with delayed - release nutrients on total mushroom yield . (lb ft of tray
Table
surface .)
Spawn rate ( g / 4- ft' tray )
Treatment
50
100
150
250
Nonsupplemented
3.034
( Ib / ft ) 3.06
(Ib / ft ) 3.08
(lb ft ) 3.23
Supplemented
4.00
4.04
4.09
4.18
( lb / ft )
Averages of three experiments .
at
2. Effects of spawning rate and supplementation with delayed - release nutrients on total mushroom yield (lb / ft of tray surface ) of the first three flushes . Table
COMPOST DENSITY preliminary test dealing with compost density trays each were supplementation rate , sets of and supplemented with 0.25 0.5 / 0.75 and 1.0 nutrient per tray approximately 2.5 1 percent 7.5 and compost respectively One the dry weight trays was spawned but not supplemented mak ing total trays the test the second third lb
5,
of
100
150
250
1.991
( lb /it ") 2.06
(Ib / ft ) 2.15
2.24
Supplemented
2.63
2.68
2.76
2.84
(lb / ft")
Spawn rate ( g /4-ft ? tray )
1.034
1.01
.93
Supplemented
1.37
1.35
1.34
supplementation
and approximately the nonsupplemented had returned As the supplementation level increased yields increased the largest was greater than 0.75
three experiments
)
1.00
1.34
Nonsupplemented
)
( lb / ft ?
-
.
-
Last
flushes
Total
,
es
ft )
lb /
1.65
1.00
2.65
1.69
1.07
2.76
1.73
1.18
2.91
1.98
1.20
3.18
(
( lb / ft ")
/
454
2.33
)g
341
nutrient tray 1.0
0.93
)g
lb (
/
nutrient tray 0.75
( lb / ft ) (
/
lb
227
(
0.5
1.40
)g
lb
114
nutrient tray
nutrient tray /
with the
the spawn growing room -
in
-
50
flushes
)g
to
10
,
-
day
0.25
lb (
is
It
.
of
In
.
overheated rather severely from day when mechanical difficulties occurred
air handling system
various
in
.
10 -
.
to
of
,
13 ,
but
response
Yield First
Treatments
4
,
ft
.
of
of
to
),
lb at
.
as
in
(
It
4 )
(
of
addition was the greatest level used not supplementation known whether additional levels would elicit additional yields the second experi ment temperatures during the spawn growing pe riod were kept under control during the first week
level
tray surface Mushroom yield release nutrient addition
delayed
to
Compost temperatures during the spawn growing percent period were relatively easy control The
levels
of 4.
Table
Yield increases were noted
in
the early appears that with supple well the later flushes mented compost filled into trays low compost den dry weight per sities the preliminary test 2.6 pro tray surface yield mushrooms increased supplement used portion the amount Table
3
;
as ft ?
lb /
,
1 °
C .
to
Averages
250
ft
( Ib / ft )
)
/ ft
( lb
150
.
a
)
of -
,
At
(
3 °
C
,
.
tial between the three rates
100
Nonsupplemented
of
,
5,
,
.
ing which began about the sixth day and reached peak about warmer than the check on the ninth day casing time compost temperature differen
50
Treatment
( lb
of
Table 3. Effects of spawning rate and supplementation with delayed - release nutrients on total mushroom yield ( lb/ ft of tray surface ) of the last four flushes .
( lb / ft )
7
of
ft
?,
lb
.
to
percent levels
ft )
Averages of three experiments .
-
and
However the 7.5 addition caused some heat
the check of
10
when compared
(lb
,
90
3,
,
60 ,
75 ,
–
at ,
of
50
Nonsupplemented
at
and fourth experiments trays were spawned three 1 compost densities per tray approx and dry weight per imately 4.5 5.5 and 6.5 and supplemented approximately percent 1 ! and compost the dry weight Observations during spawn growth the prelimi heating nary experiment showed that little occurred with the 2.5 percent delayed release nutrient addition ,
Spawn rate ( g/ 4-ft' tray ) Treatment
,
,
In
.
in
30
a
of
,
.
set
,
5,
,
,
,
of
six of
,
or
,
six
a
10 lb
In
tem
70
F
°
.
on
°
of
65
.
at
in
trays
7 .
as
as
all
at
casing showed good spawn growth Yield data are presented Table
Observations
,
in
,
.
,
on
.
at 7
percent Observations and supplemented cas ing showed better spawn growth the supple mented trays than on the checks However the deeper and more heavily supplemented trays which obviously overheated their centers did show
ments in the spawn - growing room , the compost perature and fell this treatment remained below day following spawning low the tenth in
per tray
lb
90
at .
at
trays filled
in
F
were recorded
°
of
95
in
pecially the trays the greater compost densities and the higher supplementation rates Temperatures
areas
.
of
)
ft
to
/
(
lb
on
).
( lb / ft )
5.27
5.79
5.39
5.01
5.68
5.93
6.31
6.49
5.38
6.96
7.01
7.15
7
( lb / ft )
wt )
3
( Ib / ft ? )
( 5 %
0
( lb )
4.66
90
dry
75
-4
. In
( lb / ft )
.
to
of
lb / ft
(
)
on
6.
-
of
els
90
6.55
6.35
F
61 °
wt ) 7
5.32
/ ft )
( lb / ft )
5.45
Ib
(
3
( lb / ft )
75
dry
( lb / ft ? )
0 ( lb / ft )
4.18
( 5 %
).
(
4.36
-4 ft
( )lb
Supplementation
ft )
Dry
60
5.05
5.95
6.35
6.35
6.47
7.03
7.60
8.25
.
experiment
in
to ;
as
of
)
tray surface three lev three compost densities
to
( lb / ft '
on
7.
-
of
els
Effect mushroom yield delayed release nutrient addition
Fourth experiment
).
( lb / ft )
( Ib / ft )
7
3 ( lb / ft )
wt )
0
60
4.35
3.55
4.23
4.63
4.46
75
5.44
4.64
4.94
5.42
5.86
90
6.53
5.73
6.07
6.48
6.72
-
( lb / ft ")
( 5 %
wt
dry
( Ib / ")ft
ft
Supplementation
( lb )
treatments
the rest
of
.
at in
,
-
lb
60
7
of
maintained
Dry
-
for
throughout the spawn growing period except trays containing wet compost supplemented percent level the nutrient addition While the am bient temperature
Wet wt per tray 4
to
all
and
79 ° F )
°
between
(
mum
72
in
.
of
in
in
.
Table (
.
,
in
of
of
a
3
a
of
a
of
a
at
.
Treatment not included
in
ft
/
compost density tion rate Trays filled 5.45 showed substantial increase the yield percent However result nutrient addition additional yield increases were not obtained with the supplementation and percent levels Yield from the nonsupplemented checks increased with proportion creased compost density increased dry weight compost Compost temperatures the spawn growing during experiment room the fourth were near opti 7
1 =
at
of
6 .
in
tray surface three lev three compost densities
5
at
in
as
(
-
is
in
lb
Wet wt per tray
wt
of
)
lb /
Effect mushroom yield delayed release nutrient addition
Third experiment
compost
at
.
experiment
in
to
-
in
,
90
(
as
.
Treatments not included
-
90
s =
of
1.
at
in
,
75
all
all
in
° F,
7 %
( lb / ft )"
of
7
,
at -
3
,
F
°
an 2.
81
in
lev
65
,
7
in
75
of
tray
produced increased yield with increased supplementation rates yield increases were approxi supplementa mately proportional the increase lb
three
three compost densities
Supplementation
ft-
Dry wt
corded the mid density trays 5.45 dry compost supplemented the higher supplementation rates and Yield data shown Table compost densities Trays spawned 4.36 and
ft ?
-
5.
(
3
of
?
5
.
°
1 ,
of
)
7 %
(
the greatest density
lb /
tray surface
,
of
Wet wt per tray
Table
compost temperatures trays filled below the lower densities were well below optimum for my celial growth Temperatures low were re
5
yield
mushroom
release nutrient addition
experiment
Second
.
,
5
70 2.
spawn between and treatments growing room No spawn growing However attempt was made keep the room No where temperatures rate the higher supplementation
6.55
Effect
delayed
a
a
at
in
in
.
ft
lb /
as of a
in
TABLE of
5.39
yield with per square foot showed increase creased supplementation rates The trays filled dry compost density showed substan 6.46 yield tial increase result the addition percent nutrient However additional yield increases percent levels were not obtained from the and supplementation Yield from the nonsupplemented checks increased with increased compost density the third experiment the two higher supplementa percent for each density tion rates and com spawn growing room No post were placed The nonsupplemented checks densities and the low percent est supplementation rate and compost per tray were placed spawn growing Compost temperatures were maintained room No
els
lb
of
5 .
an
a
at
is
in
in
spawn damage and molds the damaged presented Yield data Table dry compost density The trays filled
the treat 51
Trays spawned at dry -weight densities of 5.44 and lb / ft showed increased yields with increased supplementation rates . This was also true trays percent level filled the 4.35 rate except the
Table 8. Mushroom yield (lb /ft") from compost in trays placed at two temperatures during spawn growth .
7
at
,
-
at
lb
for
6.53
(
7 % )
At
in
5
at
of
of
level Yields the nonsupplemented checks proportion creased with increased compost density compost increased dry weight compost density- and supplementation rate experiments where the compost temperatures were
( lb /ft?)
( lb /ft )
Nonsupplemented
2.86
3.18
Supplemented
3.53
4.08 D. for
S.
L.
of
-
=
.
of
by
* =
-
(
)
growing period days
( lb / ft
6
13
( lb / ft )
on
-
half the trays containing supplemented and nonsupplemented compost were placed single spawn growing room with the ambient tempera ture controlled The remaining half the spawn growing room with trays were placed
( lb / ft)
.
9.
on
-
to
mushroom yield response
release nutrients
Nonsupplemented
2.37
3.11
Supplemented
3.42
4.03
in
to
-
to
time
delayed
)
-
of
casing
Treatment
experiments especially designed evaluate the fluence low spawn growing temperatures delayed release nutri mushroom yield response -
Effect
the addition
Spawn
BELOW NORMAL TEMPERATURES DURING SPAWN RUN In
Table
of of
or
-
.
.
to
at
all
to
°
F,
84 °
72
yield increases maintained between and were proportional increased supplementation rates densities used Compost temperatures above below this range during the spawn growth restrained delayed release nutrients yield response
Mushroom yields are averages two experiments Waller Duncan analysis variance procedure
0.05 0.19 the four values
.
-
In
all
.
of
to
in
.
during spawn growth 74°F
62°F
,
.
of
supple supplement addition the highest mentation level yield for these trays was slightly less trays supplemented percent than that the
Compost temperature Treatment
to
,
.
as
in
by
.
-
is
of
,
)
12
12
to
-
a
(
a
In
a a
(
(
),
–
of
.
)
-
(
in
of
an
(
),
a
-
of
of
.
.
a
,
,
12
.
of
in of
,
,
(
10 ).
of
),
11
in
(
-
of
as
as
the
light
in
a
of
,
no
by
on
.
?
ft
lb /
.
of
yield cream and white strains The increases brought supplementa from 0.57 0.73 signifi tion were significant However there was among any cant difference these increases for the significant strains tested So although there was ,
may shorten some other specific
post were significantly less than those to
13
-
approximately casing time
of
of
days
.
response
to
in
casing
as
of
of
.
obtained
yield irrespective
This suggests that growers
to
9 ).
?
ft
the time 52
were
days and after
in
,
of
spawn growth Increases lb /
1 (
trays were cased after
6
-
to
to
In
casing affected order test whether time delayed release nutri mushroom yield response
Table
the two strains the second experiment Table yields the brown and off white strains the nonsupplemented well the supplemented com .
.
TIME OF CASING
ents
the preliminary experiment the yield the brown strain mushrooms was lower than that the light cream Table However the increase yield supplementation result was similar for In of
be
),
it
of
in
in
supplemented
a
(
a
.
is
by
as
be by
It
.
)
of
(
at
the lower temperatures does suggest that per haps some biological phenomenon may also volved the release the nutrients
),
re at
of
,
at ,
74 ° F .
held the temperature range normal for mushroom mycelial growth has been suggested Carroll and Schisler 1976 that delayed release may effected developing the pH the compost lowered Although this test does not mushroom mycelium negate such hypothesis some stimulation did occur
study the influence preliminary experiment trays were strain and mushroom yield response spawned with The Pennsylvania State University's light cream and strain 345 were spawned with PSU 344 brown Half the compost spawned with each strain was supplemented second experi trays PSU 310 four strains each ment light cream snow white PSU 324 PSU 344 brown and PSU 348 off white were spawned Compost half the trays each strain was
as
a
° F,
62
at
?,
ft
lb /
,
supplementation when the compost was incubated The greater stimulation mushroom yield sulted therefore when compost temperatures were
SPAWN STRAINS
In
in
.
A
8 )
?,
ft F
,
(
lb / 62 °
Table substantial yield crease 0.67 resulted from supplementing the compost and subsequent incubation and greater yield increase 0.90 resulted from the
with
a
an
com
° C
at
74
?,
from
resulted
incubated
demand without adversely affecting yield response delayed release nutrient addition However total yield reduced supplemented the earlier casing nonsupplemented compost well
In
of
F .
0.3
lb / ft
,
A
in
of
temperature ambient yield slight increase nonsupplemented compost pared
a
74 ° -
a
air
in
F .
at
62 °
-
air in
,
ents
10.
increases
of
)
)
(
of
)
by
)
lb )
(
ft )
( lb / ft ) )
(
)
(
(
PSU 344
S.
Brown
348
(
-
Off white PSU
2.43
3.16
2.42
2.99
0.57
2.14
2.77
0.63
2.10
2.69
0.59
0.73
no
.
-
of
D. 0.19 Waller Duncan analysis variance procedure for yields for nonsupplemented and supplemented compost for
.
95
of
comparison significant differ means shows the yield increases resulting from supplementation percent confidence level various strains the
Scheffe's test ence between
at
.
,
PSU 324
PSU 310
Supplemented Increase ( lb /
Nonsupplemented
Light cream White
L.
1
of
to
by
.
Treatment Strain
of
re
or
.
of
-
of
of
( lb / ft ")
.
bisporus
A.
-
compost supplementation with delayed release yield various strains
mushroom
of
of
Effect
on
11.
nutrients
lb / ft ?
of to
in
.
13
or -
6
lb )
at , 1
in
in
of
Table
in
as
as
.
ft ?
lb /
cultivated mushroom tested responded the addi delayed release nutrients increasing yield tion Although yield level varied with the strain the mag response was constant nitude of
(
.95
)
of
at
,
of
.
of
as
-
,
84 ° F ;
great and increases 1.9 were ob tained Compost temperatures above below this range reduced yield responses the delayed yield approximately lease nutrients Increases were obtained from supplementation with delayed release nutrients whether trays were cased spawn growth All strains days after the 72º
.
.96
3.37
of
of
%
7
to .
up
3.97
early
The addition increased supple dry weight compost with mentation delayed release nutrients spawning resulted dry increased mushroom yield did increases compost The addition weight density increas ing amounts increased mush nutrients resulted room yields from both low and high dry weights composts provided compost temperatures during the spawn growing period were maintained between (
3.01 2.42
all
at
occurred
in
.
These
Supplemented Increase
of
in
(
)
of
Ib / ft ?
in
-
of
in
bisporus caused slight increases delayed release nutrients whereas the addition spawning resulted approximately substantial yield tray surface increases
spawning rates and late flushes
PSU 345
PSU 344
Agaricus mushroom yield
,
In
summary increasing the spawning rate
Brown
(
Light cream
SUMMARY
of A. on
-
a
a
of
( lb / ft ? )
Nonsupplemented
( lb / ft )
,
of
Treatment
Strain
( lb / ft )
-
in
.
in of
Preliminary experiment showing effect Table compost sup plementation with delayed release nutrients mushroom yield light cream and brown strain bisporus
.
a
en nu
in
,
of
a
as
in
yield among the various strains from difference nonsupplemented composts the increases yield supplementation with delayed release result trients were similar This was true both tests compassing Agaricus bisporus total five strains commonly used the commercial mushroom industry
53
1
Selecting , Manipulating , and Treating Mushroom Casing J. Wuest
Lee C. Schisler and Paul
be
is a
a
to
in
"
36
to
18 "
of
,
a
)
2
no
(
if
In
it
be
a
,
to
or
,
or
a
)
bit.
an
be
to
-
,
to
.
the extent required
and
,
as
-
its
.
Peat formed from sphag superior product for cas high water holding
of a
or
,
sphagnum hardwood num moss considered ing primarily because is
.
of
-
it
of
on
in
is
in
50
bogs and contains more than Peat moss found percent organic matter decayed plants the form Peat classified the basis the parent material from which reedsedge was derived such
capacity
.
gases between compost and
air ,
of
mushroom compost but not when peat moss used
is
,
.
or
is
-a
to
it
A
of
grouping granules soil particles into aggregates well ggregated soil desirable for casing because provide the physical condition optimum seems for
before the material becomes suffi ciently leached decomposed both useful casing Desirable weathered spent compost has dark rich loamy consistency and makes excellent casing material with good water holding capacity Depth the casing layer needs increased comparison with mineral soil when using spent
,
the arrangement
or
determined
by
is
Soil Structure and Field Management
exchange
usually required
Peat Moss
CASING MATERIALS Soil structure
Spent mushroom compost may converted cas ing material piled more than feet deep field where can decompose and weather for Pennsylvania period time months
,
a
,
of
as
-
well materials
.
to
as in
–
in
,
a
in
of
tering and ventilation during cropping treating and handling the alternative prior casing
1
Spent Compost
is
at or a in
or
.
of
has occurred less than decade and has required changes management procedures number wa
excessive
.
and
,
as
casing
so
,
As a rule , casing with mineral soil requires a layer to 1.5 inches in depth .
,
),
by a
of
to
use
today weathered spent compost used alone combination with peat moss soil for casing number farms The transition from clay loam soil
aggregates
soil
of
re
its
in
,
.
recycle spent compost
a is for
–
–-
of
(
to
-
to
began
destroys
discing should be avoided . Dry soil can also be dam aged by tillage , reducing aggregation . The optimum condition for working soil is when it is friable .
.
( field ) soil for casing . The soil had physical characteristics which allowed water to be ap plied lightly without causing the soil to seal . Good top soil became less available due to urbanization plus legislation making the decision to strip top soil beyond the authority of the owner of land . The con predictable venience of storing peat moss , sponse watering often resulting higher yields obtaining good top soil caused and the difficulty major shift from top soil peat moss field soil the mid 1970s During the 1970s number farmers
ers used mineral
chanically
as
selection and management of the casing material . A variety of materials may be used for casing . Until 10 years ago , most North American mushroom grow
Good soil structure is easily damaged and can be destroyed by mismanagement . Field soils to be used for casing should never be tilled or worked in any way when excessively wet . Discing , for example , me
,
rial cannot be overemphasized . The yield potential of any mushroom compost is largely dependent on the
to provide water - holding capacity . Casing soils from grass or legume sods are usually much more desira ble than soils that have been under intensive tillage . Highly tilled soils can be improved if sodded 2 years or longer prior to use for casing .
in
Casing to induce development of sporophores has been practiced since the 17th century . That mush room mycelium will not produce fruiting bodies in any quantity until cased with a suitable material is well known . The importance of obtaining a suitable casing mate
(
HISTORY
55
a
in
vault
introduced
.
is
is
2 )
into which steam
a
.
is
,
is
,
2 )
(
ro ce
Peat and ground limestone are placed into ment mixer Fig water added and the drum injected tated mix the peat and limestone Steam into this mixture tumbles or
3 )
(
.
is
or
as
.
Fig
(
storage bins
a
in
air
treated
is
of
of
,
At
-
on
.
,
,
in is
in
.
,
or
a
-
,
.
,
of
produces higher yields 212 diseases and can be done with other systems ° F
-
at a
of
have become popular because temperature below that
of
-
mushroom
-
the most efficient
pests from casing
means
of
eradicating
-
steam
-
Moist heat
is
,
Heat Transfer and Thermal Sensitivity
.
injected through the pipes
Steam
,
:
12
;
2
is
a
in
A
1 ).
The material
.
is
.
a
of
to
(
the floor Fig
,
re
on
If
five systems
,
,
.
.
of
using one
truck bed equipped with pipes piled atop the pipes depth inches feet steam outlets are about tarpaulin must cover the casing before steam apart
1 )
Steaming
by
treated
casing
vault some sort forced aerated steam system Additional information treatment systems included the section beginning on page 89 and the reference authored by Aldrich Wuest mixer
The three systems casing treatment flowing free steam reduces incidence more efficiency than
.
be
is
Casing
the majority
and McCurdy
,
,
,
a
is
bagged
at
is
to
pasteurize good reason the peat bags bog the however and the moss during pasteuriza transport storage main intact and necessary tion may not and this
present
.
ill
a
,
so
be
to is
,
to
trucks for movement
4 )
is
to
.
be
or
to
from areas far removed from mushroom farms but advised Soils from such areas can this practice expected contain pests which may damage the crop pasteurization becomes essential Sphagnum deep bog may contain nematodes peat moss from
Vapam Chloropicrin are Fumigants such added screened soil when the soil loaded into
5 )
for casing mushroom frequently and other pests harm contain insects beds pasteurized ful the mushroom and thus should peat pasteurize growers obtained soil do not Some
Materials otherwise suitable
a
Casing
with
is
placed into airtight room container through which aerated perforated floor Fig forced steam
4 )
TREATMENT OF CASING
an
.
.
as it
lime
of
40
pounds bale when mixed with water and stone will cover about 125 square feet
loaded into trays and stacked
to
at
ft3
6 -
.
1
is
to
so
;
is
of
to
,
peat preferred texture 2.5 inches this watering during the depth that amount shrinks pinning time 1.5 inches One compressed
Casing
3 )
1.5
its
In general , casing with peat requires a deeper layer than is needed with mineral soil . Depending upon
One com
Norgen
organa
Momen
.
56
for
the
on
,
in
the
casing was not uniformly loaded treatment and that this treatment system boiler the truck is
indication that The steam source
for
,
-
an
.
a
a
1.
Steam rising from this truck comes from blow out the soil was not covered with tarpaulin before steaming began right FIGURE
the
PA NORBANTOWN
61
.
for
top
I
,
of
di
the
FIGURE 2. A commercial concrete mixer converted to a soil - treat ment system . Truck -mounted , mixer delivers treated casing rectly the mushroom house reducing risk contamination to
#
it
be
as
used
transport auger
.
is
to
be
,
of .
a
to
in
.
the
or ,
the
is a
ing
4.
*
Stripping casing The process includes screen soil stripped soil adding fumigant and then moving into covering with tarp Soil storage building casing used normally stripped towards the end summer and enough brought last until the following summer
FIGURE
40
canvas tarp over truck bed also helps keep coming contaminated
An
to .
truck
without
clean plastic casing from
or
. theA
buckets
the
to
emptying fill
to
the
or
thein
a
on
the
.
,
is a
up
other unloading device permits casing workers standing
used
be
.
.
tractor
a
is
is
3.
of
perforated The floor this room metal plate through which aerated steam through forced soil Load readily accomplished with ing the room scoop mounted FIGURE
it is
to
5.
Thoroughly cleaned vehicles should FIGURE casing from the treatment site where
be
ME
57
system
Source Aldrich :
soil treatment
9
7. 8. 9.
of
.
on of
in
of
a
in
a
-
be
.
30
°
F
is
by
a
in
of
a
a
aa
,
is
-
be
If
.
aa
,
to
.
a
in
In or
a
of
.
Soil Properties and Steam Treatment at
.
,
in
or
to
.
as
be
.
at
be
.
to
of
casing requires careful The MOISTURE CONTENT of soil should the level considered optimum for casing when pasteurization occurs This means the moisture content should about the same that considered optimum for tillage Clay loam soil should crumbly the touch When friable and feel soft slightly compressed the hand the soil granules Efficient steam treatment tention several details
a
;
to
in
in
to
.
is
,
to
.
,
be it
.
to
plastic con should tend stick together Soil with allowing too moist Soil be molded for casing should moistened several days prior dry soils some pests will pasteurization When form resistant resting structures this state they are less susceptible heat than when they are actively growing addition dry soil particles are poor con ductors heat water improves conduction Thus
sistency
ficiency
,
,
.
water around soil particles will increase the steaming
ef a
film
.
so
,
A
.
soil becomes contaminated
;
pe
riod mushroom grower seldom encounters ideal temperatures conditions when treating casing 58
the pasteurized
In
of
)
minute
soil treatment box used the pasteurized emptied into clean truck for transport
mushroom house Placing pasteurized soil into dirty truck negates the effects pasteurization since
.
is
is
30 -
for
a
° F
at
.
to
-
Most mushroom pests are killed steam
140
soil must
of
or
.
(
;
to
on
to
of
The use heat eradicate pests from soil based usually their low tolerance heat this tolerance called the thermal death point killing temperature soil borne pests when exposed
depth
of
a
to
.
the mushroom
placing truck bed steam pipes nest box specifically constructed for soil treatment either case the soil should be filled uniform
of
of
ft ).?
/
lb
of
(
to
is
° F
These yield decreases occur because the steam ing releases harmful chemicals and the casing will post
contain factors toxic
plished
be
about
detrimental mushroom production Wuest between 0.2 and Schisler report yield decreases larger magnitude and 0.5 Yield decreases spent com have been observed with peat moss 212
recommendation for treating soils placed nest steam pipes 180 maintained for minutes Treating soil with free flowing steam can accom
.
of
sides
.
at or
,
of
-
-
and where the soil touches the truck bed Treating field soil with free flowing steam
floor
a
so
,
in
be
° F .
to
is
at is
steam and some heat lost during transport placed thermometer the coolest spot the mass and timing for pasteurization begins when this spot reaches 180 The coolest spots tend those most distant from the steam sources the top the soil
with perforated
times longer than the minimum required provide margin safety and used every cubic inch adequate kill soil The
a
a a ,
at
It is
° .F
at
,
,
of In
° F .
-
to
is
all
,
and the heat transfer process con tinues until the material 212 not possi flowing casing less than steam free with ble treat 212 actual practice however physical character istics the soil impede the routine movement
sure
Exhaust plenum
to
.
At
to
a
° F .
of
,
.
it
.
to
its ,
of
in
next cool particle
.
of
of
a
As
by
a
is to
steam diffuses through the material contacts cool particle the steam condenses and transfers portion any loca heat directly the particle tion the material heat transfer continues until the particle reaches 212 At this time temperature the condensation stops and the steam advances
Soil chamber
to
should
Supply plenum
be or
higher
treating mushroom casing with steam mon method perfo inject free flowing steam through nest given volume soil The rated pipes covered
an
of
Steam supply
)
(
air
Thermometer
-
4. 5.
mixing and condensate Steam trap bottom drain
6.
dust spot efficiency minimum with prefilter
injector
Steam
-
3.
(
atmospheric
)
%
—
Filter
95
1.
Motor and fan
2.
8
7
1
5
N
3
6
-
aerated steam
.
air ,
drawing of a forced -
FIGURE 6. Schematic
the
to
if
of
is
it
for
.
,
it
is
.
,
a
of
making
by
-
,
,
a
,
,
a
-
or
A
.
12
to
be 10
-
or
is
4
of
° F
of
° F .
at
to
to
.
a
be
Its
,
to
.
is
of
.
,
to
to
to
,
-
.
of
-
of
in
.
pasteurized
forcing
the pore spaces
Dis
out and
of it
replacing
it air
placing
push aerated steam
to by be
the desire
to
by
.
at aa
dictated
through the casing material
with aerated steam puts more the cas temperatures contact with pasteurizing much less time than would occur heat transfer and by
if
in
in
ing
(
an
in
.
to
steam movement occurred exclusively conduction particle The design factors which in from particle fluence this pasteurization system are numerous and Experiment Station bulletin are described Ald
1975 Rather than enumerating the specif forced aerated steam system realize that the system must balanced from the following per spectives steam flow pressure the forced uni formity casing both density and moisture characteristics the capacity and characteristics the ,
-
,
of
air ,
be
-
air
).
,
rich ics
of
in
the fan used
to
the air intake and
of
,
filter air
push the
its
facility will require
on
Every pasteurization
own
de
a
of
.
in
be
by is
in
,
to
,
casing and the sign predicated the choice amount treated one batch With vault sys tem fewer specifics are involved since the the casing sits room where the room temperature control at
-
-
.
of
led and heat transfer occurs exclusively conduc tion Use forced air aerated steam systems nu .
by a
a
merous mushroom farms verifies that benefits from system satisfy quite such few mushroom farmers
-
-
of
selection comments mushroom farmers who have installed and use forced air aerated steam sys
tems follows
.
the soil
,
resistance
in
residual
'
a
of
.
,
or
° F
at
is
.
of
of
vide
system assumes homogenous casing without lumps clods uniform moisture level Such uniformity
of
Ex
organic
ma
hours
move the casing into and out the vault The use forced air aerated steam treatment
:
.
iii )
;
is
i )
as
ii )
;
extended
for
disadvantages include treated one day before use the expenses incurred when constructing the trays and the vault the relatively long period time needed raise the soil the desired treatment tem perature and the labor and machines needed
of
a
,
in
60
° F
° F .
-
to
at
as is
,
of
.
is
treatment time
matter content the casing material increases An other consideration when weighing the advantages recognizing that many nonpatho aerated steam genic microorganisms remain and grow following treatment 160 lower and these bacteria and fungi compete with any pathogen accidentally intro duced into the casing after treatment Such residual pathogens and pro microflora hamper the growth
the casing
recommended for pasteurization when vault sys tem used This method assures uniform treatment with controlled conditions and permits soil
et
to of
° F
by ° F of
or is
of
.
be °
,
°,
.
°,
30
°
F
at
–
° F
no
higher The same 180 and true other steam air mixtures 170 160 150 140 for example Most mushroom pests will killed aerated steam 140 within minutes Lower treatment temper post steaming soil atures minimize the possibility experienced with treatment toxicity 212 temperatures above 160 posure for mineral soil significant dele more than minutes can result terious effect on soil chemistry and mushroom pro duction The likelihood toxic factors being present after treatment increases treatment temperature
raise and maintain the temperature terial 150 Maintenance 150
al .
air is of
is
or
at
-
.
,
the soil temperature reaches the temperature the mixture Thus steam air 180 will heat soil
formly heat these materials the desired tempera ture Live steam mixed with air enters the vault
a
-
to
.
be of
;
is
is
of
-
to
.
,
until
-
of
.
on
aa .
by
than steam alone When aerated steam introduced into cool soil condensation heat transfer occurs
vault
at
to
.
an
to
to
heat treating soil the use produced when aerated steam Aerated steam injected into free flowing steam line this causes the disperse steam vapor The dispersion steam vapor cooler air causes the steam air mixture
The newest method
years enclosure house for can filled with trays containing soil peat properly designed de spent compost and with livery and distribution system aerated steam can uni
growers
a
If
.
,
a
its
a
its
of
or
be
Aerated Steam
Techniques utilizing aerated steam treating cas ing have been used effectively some mushroom
is or
is
to
or
of
.
it
of
,
its
for
steaming . Clods or lumps of soil are usually com pressed ; porosity is reduced , and steam flows past them . The temperature within a clod may never reach that required to kill the pests within it , and the clod serves as a reservoir of pests . Steam - chemical combinations have been shown to be more effective than steam alone in destroying re sistant weed fungi and fungal pathogens . The injec tion of formaldehyde into free - flowing steam has been a practice used by a handful of growers three decades but routine use NOT RECOMMENDED be problems creates The procedure increases cause probability contamination after pasteurization the damage and soil structure soil chemistry cir grower cumstances otherwise warrant use should treat only small amount and assess the mag nitude detrimental effect The decision con procedure tinue switch alternative can thus based evidence rather than speculation
increased
possibility pathogen getting established much possible less likely Finally treat casing just before used this reduces the chance contami nation after pasteurization
.
Soil structure is significant in mushroom farming be cause movement of steam through casing is largely dependent on porosity . Any factor ( compaction , water ) that reduces porosity reduces the efficiency of
a
Structure
A
Soil
59
Fumigation has certain disadvantages and include :
of
to the pests
treatment and safety on the fumigant label . Chloro picrin ( tear gas ) and Vapam ( VPM ) ( sodium - methyl dithiocarbamate ) are the two fumigants registered for use with mushroom casing .
Fumigants should not
spent compost preferred
used
used with peat moss casing steam the
If
3 ) Fumigants require either a prolonged treatment or aeration time , or both , before treated soil may be safely applied to mushroom beds . Fumigant properties vary with each chemical and this underscores the need to follow the directions for
.
.
to
,
are highly toxic to man
is
fumigants
,
,
pest elimination
means
.
In general
.
2)
in regards
SANITATION Handling
casing and doing the casing job spawning second only far care as
are selective
as
Fumigants
traces
as
1)
killed .
the fumigant remain when the soil the compost raise the room temperature and withhold watering this will enhance the elimination general the higher the tempera the fumigant ture and the lighter the soil the shorter the period needed for aeration and the more critical the need cover the soil after treatment laid
is
ble salts , manganese , or ammonia to be released as can occur when casing is overexposed to steam .
The soil MUST BE THOROUGHLY AERATED following fumigation so traces the fumigant disappear be fore used for casing
c)
of
solu
should be in the range of 65 ° to .
be
Fumigation does not cause toxic amounts of
b ) Soil temperatures 75 ° F for best results
,
.
and at the
.
altered
be
not
,
are
,
3)
is
is
2 ) Soil structure
should be free of lumps or clods proper moisture content . a ) Soil
of to
quantities
are a practical means of treating large of soil in the field .
all
Fumigants
Soil conditions optimum for fumigating casing those judged optimum for use of soil as casing :
4)
.
1)
-
;
Soil fumigants are chemicals , usually liquids that va porize to a toxic gas which diffuses through soil and kills pests . Fumigants have advantages over steam in the treatment of casing . They include :
A
In
Fumigant
or two
week
of
a
hours
a
water seal or plastic cover placed over fumigated casing soil will prevent rapid dissipation of the fumi gant . Rapid diffusion of the fumigant often means an ineffective treatment because of the low concentra tion of toxic gas the fumigant . 3)
5 )
Using
11
I ."
in viable seeds germinating after the casing has been applied . results
of
can do the job in
a a
it is
When I steamed ground ( soil ) in
If
truck bed , it re quired one or two men and about 40 man hours , but with my aerated steam treatment bin one man "
on
can control the moisture content of my casing by
than are insects
more resistant to fumigants nematodes , and most weed seeds .
,
Growers sometimes assume that if weeds and nema todes are killed , the fungi will also have expired . This is not true . Proper treatment with aerated steam often
be
"' I
adjusting the length of the cool - down period . "
Fungi are generally
2)
d )
“ Bubble was a problem when I used tear gas ( chlo ropicrin ) for my ground ( soil ) , but now with aer ated steam my problem is about gone . "
should
pasteurization
60
,
,
be
.
is
to
,
.
of
.
,
of
of
a
of
.
as
,
,
or
casing
.
fumigation
of
.
or
a
1 ) Apply fumigants as the casing soil is being mixed or moved . This insures a uniform distribution of the
to
iphery of the diffusion pattern
In addition to the specific recommendations on a fumigant's label , there are a few general rules con cerning their use .
to
chemical to the soil . When a fumigant is injected into casing soil , the amount injected must be adequate to lethal at the concentraton per assure
avoid Casing contamination concerned tools soil tubs thoroughly buckets and equipment should washed with clean water then disinfested with steam chemicals before use Schedule casing the operation first work day and inspect the outer garments and shoes workers insure they are clean and free debris Clean hands including clean fingernails are also necessary Relaxing these strict effective rules can quickly neutralize the benefits
Integrated Pest Management for Mushroom Farming R. Snetsinger
Steps in Integrated
to
ef
iii )
,
,
v )
of
of
if
as
pest noth
manage the pests systematic Pest Management IPM predict and detection and analysis system used pest infestation while maxi minimize the extent mizing cultural practices known have negative a
to is
(
.
)
done Integrated
fluences
pest populations
Fig
.
in
Identification
,
monitored
-
a
А.
so
prediction loss and risk of
continuous system and evaluating the ,
and controlling pests
de re
IPM
for
cycle
is a
1.
,
IPM
Effective
identifying
sults
.
quality mushrooms
tecting .
,
of
to
be
,
all
in
to
a
.
a
duce the highest
FIGURE
.
,
of
in -
must be made
to
,
An Integrated
it is
as
population must be
decision
-
a
.
Pest Management sys these farmer's efforts identify how time money areas scheme pro and equipment can most efficiently used room quality
tem may complement ,
Pest
An action
for contaminant free foods and legislation which cleaner environment has resulted includes regulations governing the disposal farm waste Some waste may harbor crop pests farmers manage refuse from pest threat and environmental vantage while nurturing crops maximize mush concern
,
public's
.
in
of
,
a
in
is
.
or on
,
follow
Preventive cultural practices
up
for
,
of
Evaluation and
pesticides even though total reliance pests complete control not the final answer Pesticide costs have increased sharply the past signifi several years and pest control has become growing mushrooms The the cost cant expense ticides
of
key pest
-
as
of
as
-
in
.
of
to
produce measures are utilized mushrooms for processing well fresh market sales Production commercial mushrooms now pes and the foreseeable future requires the use
crop protection
( s )
,
,
.
,
)
determine the cost the crop value
of
:
(
20
in
mushrooms
an
by
$
duced
ing
compared
to
Pennsylvania was percent estimated value estimated large numbers mushroom 29.5 million due pests Mushroom pests include insects disease path ogens weed molds Numerous and nematodes commercial
management
of
to
re of
of
,
)
.
(
50
.
$
147.5
manipulating the data to
,
.
in
to
million Pennsylvania continues production percent dominate with the nation's total During this 1980-1981 crop year production was
1981
determining the most equates to yield losses , identifying techniques fective control strategy measuring the size useful the pest population in
11
3
,
to
,
by
/
lb
in
.
in
,
percent price for Pennsylvania had reached mushrooms produced during the 1977-1978 production year 72.3 cents but declined 1.2 7.3 and 6.4 percent for succes sive years 62.1 cents for the 1980-1981 crop year Pennsylvania growers Total sales value 1980
on
of
,
a
tion harvested mushrooms during the 1980-1981 season more than the preceding year Average
Pest Management
The steps in Integrated Pest Management may be outlined as follows : i ) identifying key pests , ii ) de termining the threshold where pest occurrence
is
mushroom produc record 237.5 million pounds
the leading state
in
Pennsylvania
,
MANAGEMENT
PEST
D.J. Royse , and R.C. Tetrault
,
1 ).
,
(
P.J. Wuest
iv )
,
to
Wetzel
to
H.A.
61
to
,
,
a
of
,
,
,
.
of
.
or
to
,
of
.
on
be
of
fre
be
of
so
to
its
be
.
,
a
of
if
be
.
,
or
is
fly
?
be
.
to a
in
-
.
3
or
1 ,
2,
.
a
in
,
of
on
to
on
.
to
-w
is
is
),
,
,
a
to
,
.
(
to
a
on
in
-
,
is a
2 )
its
) (
to .
in
be
.
an
.
is
at
a
the effective systems of
can make meaningful comparisons ness various insect management
.
.
to
-
(
G )
Pseudomonas fluorescens biotype bacteria induced disease which develops when dry after being mushroom caps are not induced watered On very rare occasions the disease can
change the insect management program Management strategies different farms can evaluated only common monitor used Growers using identical monitoring systems within area
if
.
of
in
of
is
.
Brown blotch
in
or is
de
of
,
a
if
.
of
70
,
as
a
to
.
of
of
quality Verti formed and thus penalized terms cillium fungicola the most frequently occurring and the commercial mush serious fungal pathogen room
of
in
on the clothing workers When present the sever yield loss trace disease may range from yield percent much the crop Even not reduced infected mushrooms are spotted as ity
of
.
on
,
in
by
,
be
it
;
in
on
a
(
is
is
.
)
or
;
so
(
);
or
spots form the spots coalesce the cap spot the entire cap discolored the stipe growing stem shatters The fungus usually enters room via casing that not adequately treated fested tools and picking instruments and dust particles flies and carried can also the air
,
on
,
.
of
ways
bubbles
a
light devices are used trap flies Sticky attract light bulb has been used for paper hung next years Mushroom Fly Monitor The Pennsylvania Fig simple PMFM low cost monitor wide use since introduction 1979. Insect control rec ommendations from The Pennsylvania State Univer sity are based data gathered using PMFM An ad hesive hold insects pressurized Tangle Trap Tanglefoot Co. Grand Rapids MI sprayed onto strips white freezer rap paper after the paper attached monitor Flies are attracted the black light and stick the adhesive contact Monitoring flies specific cropping days provides population size estimates and identification the growing room This information species present may aid estimating the population weeks hence and the potential damage from these insects evaluating the need These data may also assist
(
afflicts the crop
in
)
V.
(
fungicola
This fungal pathogen can infect young pins which then grow into blobs called dry
is
increasing decreasing the insect population and monitor can provide such data Monitoring also es tablishes for management which insects are present and when they appear used Various What monitoring system should
of
an
Verticillium disease
62
monitoring use flies The effectiveness insect manage ment measures can assessed when one knows
system
or
to
,
a
fly ,
.
DISEASES
array
Why should mushroom growers
.
of
fly
of
a
in
,
,
has not been extensive for
MUSHROOM FLIES
to
.
of
by
.
or
in
,
as fly
known the cecid few years
of
,
,
,
if
be
;
Mycophilla speyeri flies and Heteropeza way similar the afflict the crop but the occurrence these flies both
the
Monitoring Pest Populations
?
,
.
of
of
and causes internal browning the stem Crop loss can total infestations the sciarid are very high lesser infestations are costly because reduc yield quality tions
sciarid
in
a
.
Larvae
this insect feed the spawn and young pins and maturing mushrooms bore into the stems Their damage reduces yields stops mushroom growth
practices will combination most beneficial crop the consumer and the farmer of
(
composting
those elements the environment influencing their multiply and survive must ability monitored population size and quently routine estimates impact With such determined the crop can information managers can decide from the spectrum possible courses action what one practice
for
Lycoriella mali
),
fly
.
II
Phase
manage
pest
comparable rate Weather availability decrease feeding sites stage crop growth the pest life cycle natural enemies and other factors affect the growth pest populations Pest populations and and decline
,
to
a
a
of
the sciarid
on
is
A
),
to is
mushroom compost after the
it
,
(
,
it
in
is
.
,
is
at
a
,
is
to
a
as
more serious insect which attracted pasteurization stage
integrated
a
fly
fly ,
INSECTS
Cecid
essential
ment Pest populations are dynamic sometimes day and they may more than doubling less than
,
IPM Project
Megaselia halterata nuisance The phorid planted tracted mushroom houses when spawn important and thereafter This insect that acts fungal bac vector for mushroom pathogens terial and nematode and may cause brown spot develop where touches mushroom cap much
pygmaea
Monitoring
at
as a
to
all
farming
maintain
the PSU Mushroom
in
Key Pests
resources
.
greater use of viable business
Monitoring for Key Pests is
-
their specialty areas , leaving the farmer to integrate pest - control into a production system . Today , agri cultural scientists and educators must focus on the to tal situation with the farmer , and strive towards
cause the stipe of the mushroom to turn black and shatter , and the cap may also blacken . Most often , the mushroom cap becomes discolored with a non discrete brown - colored area .
.
Pest problems change with time . As they change , also change . Professional must IPM programs agriculturalists – entomologists , plant pathologists , and horticulturalists can no longer work within
Determining where to locate the monitor within a species room affects the proportion of different tracted the PMFM Sciarid flies can be numerous
B
at
to
A
.
to
fly
A
.
fly
,,
in
to
to
CE
fly
is
of
.
18
24
D
F
"
the center aisle facing the room One situation assesses the adult pinpoint where monitor will not provide data growing room Up eight moni flies are entering tors are needed when the source the flies ques a
"
BI
upstairs accurately
,
at
.
a
,
ward the wharf end while both sciarids and phorid flies enter room from the breezeway end PMFM located on the back wall the wharf end
or
at 2
1
be
,
to
,
.
.
fly
6 "
on
5
-
II
.
tioned Daily counts must made starting days before Phase cool down and continue for pin least days after spawning and preferably up formation Pesticide choice and application are based counts during this period
counting mushrooms Disease assessment consists affected Verticillium dry bubble spot bacterial blotch and calculating the percentage mush rooms infected selected locations Choosing the they represent what occurring choice cations easy sampling sites since neither disease not or
lo of oc of
all
of
(
is
is
)
.
is
a
at
curs randomly this time visual assessment suggested harvested mushrooms
The Pennsylvania Mushroom Fly Monitor
.
2.
.
,
WATT BLACKLIGHT TUBE FLUORESCENT LIGHT FIXTURE WIDE STRIP OF WHITE PAPER SPRAYED WITH TANGLEFOOT
;
15
"
F F D = = = 4 " 18 ",
6 " " X X 1 18 " " X X " " " 18 " X
BOTTOM BOARD 24 1/2 SIDE FLAPS 1/4 SPACERS 1/2 3/4 X1 5
C B A = ==
so
.
in
-E
FIGURE
)
,
AED
(
D
B
by
of
18 "
MUSHROOM DISEASES
The density
an
in
en
mushroom farms area may hance the pest population but building isolated mushroom farm will not insure the absence pests Some common sense ideas are quite effective for excluding pests
.
'
.
a
a
in
to
,
at
to
'
numerous Chester County PA mush room farms determined when monitor during the growing crop cycle and where locate PMFM Experiments
of
,
SYSTEM
of
A
FLY POPULATION MONITORING
an
Excluding Key Pests from the Crop IMPLEMENTING
air -
a
if
or
an
-
to
hr
to
hr
to to
8
no
at
° F
-
6
an
° F
will cause 1.5 inch urethane empty room get 150 for pasteurization and damage the
,
is
to
is
is
to
spawn growth The only caulking that nontoxic and known remain stable after repeated expo high temperature sures Vulkem Sealant Poly to
.
-
Adults initially invade mushroom grow cool down
II .
3.
entry Sciarid rooms during Phase
FIGURE ing
fly
.
the same level urethane
of
Larvae
for
treat
A
to
it .
a
-v
,
buckle
so
–
Invading Adults
a
by
.
in
-
.
use
to
160
Exterior
of
tion
used
be
Casing
Spawning
ure
urethane requires additional ultraviolet resistant coating minimize growing room deterioration Urethane used vapor barrier prevent steam should covered and water apor from penetrating further cau post crop pasteuriza tion with urethane relates thane
is
14
1
10
if
be
thane complies with underwriter's regulations higher insurance premium will required
,.
if
,
to
.
or
.
(
a
(
),
Growing rooms are not tight completely sealed and flies will enter room through the smallest crack crevice Seal the cracks with spray insulation ure caulking compound thane using ure Before using urethane check see )
,
a
air
F
tem
.
6 1
2
o
certainly before the
° F
to
°
is
-4
–
be
temperature about 112 perature cools 110
Physical Modifications
or
on
,
.
to
,
a
in to
.
° F (
3 )
-
II
,
Adult sciarid flies enter growing rooms during cool down when the air temperature drops Fig below 110 Adult phorid flies the other hand are attracted mushroom house when the spawn starts monitor the compost Thus run placed into growing rooms when the should Phase
I.
.
room
63
to 6
at
3
(
4
to be
be 3
-
;
-
at
to
'
fly
-
so
,
no
leaves
room
.
exclusion
to
)
,
in
by
compost not
cov
2
( 1
closed
to
60
building
,
clean
,
a
stored
in
.
° F
(
.
to
be
to
° F
,
at
soil must
.
dust free area may not require pasteurization before use However ASSESS peat moss for the PRESENCE nematodes before deciding that pasteurization not necessary Moisten the peat moss hold room tem ,
.
a
and level surface Mix spawning reduces the time days full spawn growth and increases yields Compacted compost makes temperature manage
,
.
;
,
18
to
14
a
in
)
(
to
an
as
be
.
)
(
be
,
'
CROPPING fly
if to
.
of
be
,
,
to
cease
remove diseased are trained pickers mushrooms before the touch them removal spreading the pathogen At reduces the likelihood two people
com
at
.
in
to
-
II
to
the
Inade or
be
fly
of
,
64
must
tention control must focus early pinning crop from Phase cool down quate control this time will severely reduce stroy the crop .
: i)
at
ii )
,
is
)
-
be ,
added weed mold free the supplement uniformly mixed throughout the compost must
protein
compost
–
supplement
spawning
(
exist before
be
both
iii )
lipid
or
or
Three constraints
a
ADDING SUPPLEMENTS AT SPAWNING
in .
;
to
one
or
.
all
a
(
),
ment more feasible during spawn run colonization and level compost surface makes uniformly distrib uted mushrooms on breaks more likely
and disease infestations will cause the production after third break Verticil lium infestations for example will cause this occur The effects Verticillium can minimized
Certain crop .
.
to
.
its
"
at
)
°
(
,
-
is
8
of
ft2
12
to
6
less one compost inches deep After unit per spawn mixing machine used compact the compost
.
F or
80
Mix spawn into cooled compost
at
is
.
moss
.
.
treating soil but should never used with peat Manipulating and Treating Selecting See Mushroom Casing for more details regarding the casing process ,
)
37 %
(
gal
or of
.
a
gal
of
;
of .
of
be
;
100
is
5
per
,
,
.
be
all
be
-p
or
spawning formaldehyde water the registered usage
days and assay for nematodes perature for dry bagged peat may only contain eggs and the pres eggs without larvae worms may result ence faulty conclusion Vapam VPM can steam used alternative for
be
during the sanitation must maintained operation their clothes and Workers shoes must clean and free debris spawning job day should the first the Tools and equip strong ment should cleaned with stream water spray with high ressure steam before use Dip day formaldehyde equipment before the with clean Strict
spawning
of
-
SPAWNING
a
in
in
.
in
of of
.
a
,
° F,
)
-
do
a
con
.
II,
ing Phase and the two disease pests are not casing time cern until
kill
covered with clean polyethylene film peat moss The number and kind nematodes varies with the location the peat bog Some peat sealed plastic bags and stored moss packaged or
in
II
,
is
.
a
PMFM since adult sciarid flies will enter the room Adult phorid flies generally not enter room dur
fumigated
the mushroom crop Most insects 140 for but higher temperatures 130 kill some pathogens After treat are required
pests harmful die min ment
pasteurized
or
Casing soil should
,
and
be
.
if
A
.
at
be
,
as
pesticide plastic such ered that the edges drench the edges may needed monitors indi cate flies are present CASING
by
air .
in
°
,
F
of
protects compost
film mil but eggs are laid
i.e.
room Exclude flies from the Phase room stalling 100 mesh screening and enter the room only when necessary During compost cool down when install between 112 and 110 the air temperature -
from infestation to
a
TEMPERATURES
temperatures and higher pasteurize 140 they destroy unwanted pests the compost
Air
.
do
I
II
CONTROL OF PHASE
)
scarid
Clear polyethylene
not become The pests discussed here generally problem during Phase composting operations
(
be ,
by
on
sciarid adults for mistakes
PLASTIC ON MUSHROOM BEDS
COMPOSTING
I
II .
or
in be
air
volume may
Cultural Modifications
PHASE
a
II
on
of
.
some adjustment
.
the fan required
in
by
, of so a
or
,
posting and fasten the screen with batten strips held tight with short nails staples Screening the take side fan will reduce the volume air moved
thoroughly the side boards this area cannot mixed with most present day equipment and be compost borne comes food for various airspawn molds Adding supplements into compost ing may enhance the composts attractiveness .
, etc.
all
,
-
A
takes ,
pin
controlled through
delayed release nutrient added percent any other material see the dry compost weight chapters authored distrib L.C. Schisler must inches uted the compost but not closer than of
nylon screen placed over fan in vents doors will keep flies out of a room if installed so flies cannot crawl under or around it . In screening before beginning Phase stall com 100 - mesh or finer
must
of
SCREENING
A
post temperature
ning
)
growing - room environments .
to
or
urethane No. 116. This caulking remains pliable after years of exposure
de
FOGGERS
Before removing the spent compost from rooms , wet the surface , walls , and woodwork and raise the air temperature to 140 ° F for at least 4 hours . Then pas
Fog applicators
teurize the emptied
both remain
in
),
(
a
.
in
or
a
to
or
.
)
(
-
.
in
pesticides into Dusters dispense dust formulations both fungicides and insecticides of
the steam
growing rooms
.
of
a
or
to .
is
A
for
are
.
-
or
-
a
or
-
be
.
be
or
air
,
in
A
is
is
.
-
a
a
To
(
or
at (
.
.
is
air
is
)
-
units must operate the sprayers rated PTO speed and yet constant ground speed
,
a
to
.
'
USE OF PESTICIDES tection Agency
by
to
by
.
of
.
on
,
,
is
in
of
and enforces state pesticide regulations
,
,
in
as
), a
of
(
itors
A
the
1976. Also the Depart Pennsyl Commonwealth Pesticide Control Act and pesticide pesticide inspector administers mon
amended
Agriculture
vania has spectors .
disperse
FIFRA
ment ,
,
a
.
-
,
used
to
the higher pressures
EPA
.
.
pesticide
to
'
to
'
relates
Act
,
.
-
.
)
to
,
as
(
of
water and concentrated insecticide The term low volume refers less water and air blast
wise indicated ister pesticides in
Air
air -
or
sprayers also known low volume concentrate sprayers spray exterior blast are also used walls and vegetation The air blast sprayer uses
the Environmental Pro
for nationwide use unless other reg the label States are allowed special The use needs local for provisions pesticides governed and monitored the Federal Insecticide Fungicide and Rodenticide (
dilute spray
AIR SPRAYERS
mixture
are registered
Pesticides
)
a
mixture
produce
a
to
.
ical the
,
Hydraulic sprayers spraying exterior used walls and attics and the soil and vegetation around farm Hydraulic sprayers use water and chem
,
of
.
.
in in
is
sprayer maintain
SPRAYERS
,
,
-
of
,
tractor equipped with pro powered enough available horsepower
have
a at
-
.
,
,
air
,
,
in
of
power spraying and dusting There are five types hydraulic equipment use on mushroom farms sprayers sprayers fog applicators aerosol gener ators and dusters HYDRAULIC
operating take shaft the correct speed generate the droplet size needed for uniform distribu velocity tion the correct essential -
Application Equipment
droplet distribution stream Calibration the part replacement nozzle the job whenever in stalled Another concern with air shear nozzles on mist sprayer that the fan engine Pto power .
on
.
.
A
of
equipment formulations and application different from that used outdoors equipment brief review characteristics follows
off )
do
To
.
.
for
and may lead hazardous and illegal pesticide purposes specified usage Use pesticides only the label Interior pesticide application may require
resistant nozzles those with ceramic hardened stainless steel orifices are preferred even though they are more expensive worn orifice yields an correct droplet both size and shape and this affects
A
ers ,
to to
.
on
to
user follow directions the pesticide container oth erwise risks injury the mushroom crop and work label
or
the
pesticides requires
a
in
.
.
of
Legal use
the
INTEGRATING PESTICIDES INTO IPM
usually favor low volume
Economic considerations
over dilute sprayers low volume sprayer will cover given time than sprayer designed more area compat calibrated for dilute sprays Nozzles must able with the air volume and speed the air stream anticipated dosages will not applied Wear
A
. ,
or
,
,
,
by
salting paving
sprayer calibra effective only when the details tion and maintenance are attended The operator's manual dealer will provide the necessary instruc tions Apply the recommended dosages for effective control insect pests disease causing organisms of
),
(
and garbage
Minimize dust around oiling driveways and directing vehicles away from growing rooms rubbish
the farm
Equipment
.
or
.
of
Good sanitation practices eliminate breeding and roosting sites neutralize de insects Remove caying organic matter stumps and trash stagnant
of
Calibration and Operation
SANITATION
water
no
.
a
to in
,
DUSTERS
-
killed
so keep Flies the
.
by
room will
,
.
be ,
the temperature reaches 100 ° F and higher cracks sealed and doors and vents closed
all
This practice eliminates pests harbored in crevices and woodwork , and is vital to effective pest manage ment . Flies in an infested room try to escape when
the air for considerable time allow adult insects make contact with the particles Pes ticides applied with such equipment have little residual action and are effective only when sus pended the air Ultra low volume Ulv equipment also included this category in
the boards laid out )
and aerosol generators are used for growing rooms This equipment thermal fog fine mist aerosol and
flies
is
( with
house
at 160 ° F for 6 hours . Inject formaldehyde ( 37 % ) into the steam line 30 minutes before the end of steaming .
control produces
of
CLEAN -UP FOLLOWING CROPPING
65
Before purchasing a pesticide for use at a mush room farm , be sure the product is approved for such usage . All formulations, even though chemically sim ilar , are not registered for use on mushrooms and
DETERMINING PESTICIDE NEEDS AND ASSESSING EFFECTIVENESS
without a mushroom - approved label , not legally be used .
the ECO NOMIC THRESHOLD varies with the stage the crop The ECONOMIC THRESHOLD also involves the crop loss anticipated when contrasted with the cost pesticide usage With many factors affecting the little wonder that ECONOMIC THRESHOLD there not constant and will vary from one season
in is a
of
of
of
an
at
.
to
an
to
,
is
it is
so
.
,
a
,
fly
)
on
an
4
to
.
or
4
to
of
to
a
in
or
)
in
if
to
.
( =
-
or
-
to or
,
or
of
a
be ,
,
a
.
in
on
.
be
-
flyat
,
4.
do
.
not
yet
.
Spawning
11
-11
9
-3
7
o
5
of
13
15
17
19
21
Pins
Casing Days
Pennsylvania Mushroom Fly Monitor action levels fly
.
4.
FIGURE
.
Adult sciarid counts determine the need growing room tions in a
a
.
a
.
rela
20
a
,
a
so
harvest time should damage
Action levels for phorid and cecid flies have been determined
,
,
is
first day after spawning
for
routine pesticide
in
.
in
the mushroom crop tively free sciarid
ap
,
is
a
to
be
-
PMFM through the twenty
will require more infor plus management skills
the immediate future data must collected and analyzed then placed into deci strat farmer can use such sion making system pest management The Penn State Mushroom egy developing such system IPM program
66
should used the room every day until casing These adult sciarid fly numbers are based on daily counts enumerated from the catch on PMFM and are not cumulative Action levels are graphically pres Figure ented When sciarid flies not appear
3
-
an .
pest management
mation than now available system not based effect
on
to
,
of
if
to
a
ity
pests needed before control measures are initiated ). The ECONOMIC THRESHOLD LEVEL usually occurs early in the crop , and is the point in time when preventive chemical controls should be applied . Both levels as sume that a mushroom grower is able to predict crop yields at any particular stage of production . This abil income from addi determine allows grower additional tional crop yields will offset the costs pesticide applications Unquestionably economic based integrated ap
after spawning when ten more flies are counted twenty first days after on any one the fifteenth fogspawning aerosol applied insecticide
of
rior walls at sun - up and sun -down so this is when to apply exterior insecticides for maximum effective ness . From another vantage , applying preventive sprays , fogs, or dusts before cropping begins can limit the increase in disease and insect populations during harvest . Both of these timing considerations have profound economic implications, but more spe cifics are not currently available . Additional economic data are needed before pesti cide - usage decisions can be made on a cost -benefit basis . These include i ) identifying an ECONOMIC IN JURY LEVEL ( the number of pests which , if not control led , will result in economic loss ) and , ii ) the ECO NOMIC THRESHOLD LEVEL ( the minimum number of
another
pesticide application Adult sciarid counts are the apply basis for determining and when insecti = growing room cide ACTION LEVEL order sustain increase the effect routine preventive days after sprays applied from days before spawning When eight more flies are counted from the fourth day after spawning the fifteenth day
in
may call for either smaller pesticide quantities or fewer applications, both of which will reduce the cost of pest management . Correct timing of applications is critical to pesticide performance . Flies alight on exte
and from one grower
Current data provide some definite information biology concerning the best time for based
(
Monitoring to estimate pest levels is one step in the direction of maximizing the return on pest -manage ment dollars . An integrated pest management system
other
a
1980 survey of 94 mushroom growers in Chester and Berks counties revealed an average cost for rou tine chemicals of $ 432.67 per double per crop . Costs reported by growers ranged from $ 23.85 to $ 1300.50 per double per crop .
Number insects per strip
A
plications Thus
growing
of
Economics of Pest Control
proach
The point which the number flies room justifies the use insecticide It
can
.
pesticide
.
a
insecticide applica
progress with this sort of cooperation , and the au thors thank generously those who have given themselves Thanks are also extended the Ameri can Mushroom
of
so
Institute
room Growers Association mitments this project
and the Canadian
Mush
for their continuing
com
*
A.
to
rent pest management practices .
their farms and reported their pest - control practices and costs , along with crop culture information and crop yields . The ipm program can continue to make
to
itoring the frequency and density of pest populations and the effects they cause are means by which a farmer can evaluate the effectiveness of his or her cur
The Penn State Mushroom IPM Program was devel oped through the cooperative efforts of Experiment Station scientists , Extension specialists , growers , and fieldmen . Mushroom growers provided access to
.
Effectiveness of insect management programs can be assessed via monitoring . Counts of adult insects from a PMFM provide a measure of a pest management pro gram's effectiveness . Inspecting , growing and har vested mushrooms also provides a basis for assessing the effectiveness of a pest management system . Mon
ACKNOWLEDGMENTS
all
Assessing Effective Insecticide Usage Via Monitoring
.
D
1
67
|
1
La France Disease of the Cultivated Mushroom
on
.
La
its
La
by
It
La
it
a
.
.
to
,
be
in
of
if
to
–
an
a
of
of
A
.
on
of
,
a
1 .)
is
no of
,
–
.
La
the vigorous growth
cul
healthy
ture When such isolates were inoculated into spawn fruiting made from healthy cultures there was
on
no
,
a
by
,
In
.
.
.
a
by2 ).
(
of
an
is
;
in
-
)
(
of
of
chlorophyll production the plant loss certain portions the leaf tobacco mosaic example There are virus diseases the bacteria of
40 ;
mottling
or
.
as
as
on
.
of
in to
3 -
beds planted with the spawn Fig This implies that being the disease was caused virus Viruses animals and man The com cause many diseases green plants mon cold and polio are examples many diseases often characterized viruses cause of
,
a
.
It
.
in
comparable roughly the tomato These seeds huge numbers the gills spores are produced many one inch mushroom may produce hour Under natural conditions million spores grow into mycelium very spores germinate these poorly For this reason using spores seeds for planting mushroom beds directly not successful However we can stimulate spores the laboratory germinate and produce mycelium This mycel an
compared
.
)
,
(
–
).
(
such bacteria molds will grow out from the diseased mushroom tissue However when pieces tissue infected with France disease are plated weak when organisms are present Fig Growth
.
.
of
-
as
and spread
place some mycelium from the compost agar plates fected area see other organisms
in
,
of
just
opens and the previously hidden gills are exposed the gills that mushroom spores are produced function These are tiny microscopic spheres with
is
France disease was very infectious
of
"
, "
,
.
this fungus plant
tomatoes are fruits the tomato plant The mush parts room has two main the cap pileus and the stipe stem As the mushroom matures the cap
on
placed
.
a
is
DISEASED
.
in is
"
,
to
ium from the spores completely allowed
HEALTHY
as
,
.
“
Dr. James W. Sinden the France broth name France disease
rapidly through the beds and from house house organism isolated from infected tissue could No but isolates mushroom mycelium from infected agar beds grew very weakly standard proce a finding mushrooms disease the cause dure for
(
in -
,
a
of
is
.
mushrooms Mushrooms are the fruits
received
or
.
of
be
to
applied After casing soil the mycelium grows through this layer and then forms fruits i.e. stance
Hence
on
,
its
-
cottony like growth and feeds the compost energy thus obtains from the compost Mycelium can considered the vegetative part the fungus plant similar the roots and vine tomato for
ers
to
,
on
a
to
is to
,
.
in its
.
its
a
-
its
phyll in plant without chlorophyll tissues and energy cannot utilize from the sun manufacture supply own food Consequently compost made the mushroom with food The fungal mycelium
was first observed
mushroom farm operated
as
fungi . Fungi are similar in some respects to the higher green plants , but differ in many other respects . Per haps the biggest difference is the absence of chloro
1948.
is to
To understand La France disease , one should know a bit about what kind of creature the host mushroom is . The mushroom belongs to a group of plants called
by
Lee C. Schisler and C. Peter Romaine
sterilized grain and It in is
.
is
it is
start the crop cycle again
SPOROPHORE TISSUE CULTURES
.
to
then the beds
,
to
grow through the grain spawn spawn that planted called and
of
diseased
and healthy
.
1.
Cultures developing from tissue agar plates mushrooms FIGURE
on
in
in
,
ia's
of
Pennsylvan mushrooms appeared growing mushroom center Chester County
disease
,
)
A
FIRST OCCURRENCE AND SYMPTOMS
69
1
.
NORMAL SPAWN
DISEASED SPAWN
production from trays planted with healthy and diseased
FIGURE 2. Mushroom
spawn .
coast to coast and in Canada under the name of
X dis
ease . Confirmation of the infectious nature of the dis ease came from Beltsville and Penn State . Meanwhile workers at the Glasshouse Crops Research Institute in England reported finding three types of virus particles associated with diseased tissue . English
a new name , die -back , for the dis ease . Despite the diversity of names , die -back and La France are the same disease .
workers supplied
mushroom bed showing bare area with
no
3.
Portion mushrooms
Butler , PA by Dr. Dr. L.C. Schisler .
J.W. Sinden , Miss E.M. Sigel , and A technical presentation of the re
is published
in the journal Phytopathology The disease was first observed on occasional beds at the Butler County Mushroom Farm in May 1962 , but was given little concern as the sanitation measures used were thought adequate to keep known diseases under control search
.
FIGURE
of
The research discussed in this paper was con ducted at the Butler County Mushroom Farm , Inc. at
of
in
at
in
a
.
,
air
of
strike the fall 1962 the beds were covered with mature mushrooms shed ding spores and the the mine was reddish brown color The beds spawned this time were very poor broke deep and were severely infected ,
since then from
During the week
in
it
re
1960 and has been reported
in
It
.
to
DISEASE SYMPTOMS
).
on
.
,
,
or
,
,
,
,
(
a
in
70
in
States
.
to
or or
a
by
plant through the insects nematodes man plant parts for example spores After season two the disease disappeared from Chester County Meanwhile had been ob England many mushroom farms and served reappeared mains there this day the United
all
a
is
,
a
.
of
infecting case France disease virus fun gus The virus particles are submicroscopic but can multiply and spread within plant from plant
,
La
( 57 : 519-526 , 1967 ) .
FIGURE 4. Large bare area on bed from early inoculation .
At
.
in
.
of
.
a
to
with the virus Yield was reduced small fraction the normal amount The disease remained wide spread the mine that time the disease investiga .
tion began
or
The symptoms
.
on
.
fruit bodies
of
,
,
at
of of
of
.
of
or
it
,
FIGURE 5. Wet , brown
of
in or
infected when the virus got into the tray got spawning during spawn growth whether the new mushrooms after picking after casing began The amount virus particles and perhaps the relative abundance the several kinds virus came
rot
be of
is
.
at
.
,
to
-
,
is
of
.
is
at of
to
of
to
responses the mushroom vary according the variety mush Butler used rooms The golden white variety very much different The effect the disease the snow white variety which most mushroom growers the stage use Also symptoms vary according development when the tray inoculation That the disease
in
a
for
as
.
ex
is
to
of
an
of
of
.
.
or
in
be
symp particles present also may affect the type toms exhibited There may variation the viru activity lence the virus Such diversity the kind and intensity the symptoms one reason the failure associate several symptoms pression the same disease
,
or
71
virus infection
.
Distorted mushrooms due
to
FIGURE
6.
of
).
(
on
,
to
.
at
of
The figures illustrate some the symptom com plex Very early inoculation shortly after spawning causes complete failure fruit producing Fig 3,4 large bare areas the beds Later inocula the fruit tion can cause dying and wet brown rot
(
,
a
of
at
).
or
5 ),
in
or
(
all
stages Fig . bodies at the mushrooms may grow various distorted stunted shapes Fig 6,7 may appear The mushrooms normal one stage growth but within may change few hours and ap
.
is
).
(
of
,
,
ca
.
pear diseased Affected sporophores develop more rapidly than healthy ones mature earlier and are discharging spores even when they appear pable Fig 8,9 dead and discolored symptom constantly present Mycelium iso One .
is
to
of
in
a
.
of
as
,
is
in
on
lated from infected beds grows slowly and weakly generally brownish agar and color This weak growth serves help confirming doubtful cases the disease All we need do take some the
7. Stunted , distorted mushrooms as a result of virus
FIGURE
in
by
.
fection .
by
or
,
.
of
-
a
of
in
be
it
on
mycelium and put agar and observe the growth Diagnosis can actually taken one step further looking for the virus particles the mushroom with high powered microscope the aid other standard methods virus detection
in
of
.
the snow white varieties -
infection
;
their reaction
to
in
(
10 of )
in
to
of
Losses from the disease vary from total failure the yield and pro some reduction the crop nounced deterioration the keeping quality fected mushrooms Fig Varieties differ very much
all
,
.
.
virus infected mushrooms -
Premature opening
of
8.
FIGURE
.
of
be
,
,
it
.
show the most deterioration Immunity has not been although Thus has been reported observed known varieties can become diseased and La France overcome by planting another kind cannot spawn
DISEASE EPIDEMIOLOGY
,
to
pickers
.
flies
by ,
or
byof
, in
.
in
it
is
Determining how the disease spread and how gets into the mushroom mycelium have been major problems Most people the mushroom industry thought had that the disease was carried the form mycelium from infected beds the healthy beds
ii )
1 ),
of
9.
Apparently dead and discolored mushrooms capable FIGURE discharging spores
in a
or
a
,
14
1
to
of
.
a
in
of
.
appearance was present Spawn was made from each these three diseased cultures Each spawn was mixed throughout tray proportion with healthy spawn few
.
the weak appressed
,
all
In
(
12 ).
-g
iii )
of
(
11 ),
in
(
i)
:
-
Pure culture isolates were made by three methods Fig mycelial tissue cultures from sporophores rhizomorphs growing cultures from the compost Fig spore ermination cultures from and spores diseased mushrooms Fig cases
this diseased spawn were planted one tray the rest which was the center spawned with healthy spawn Regardless method of
.
of
,
a
in
of
of
grains spot
the particular diseased spawn used infection was evident and healthy mushrooms did not grow Fig Healthy trays were always planted for com parison ,
.
.
13 )
(
and
72
).
mushrooms
top
row
),
Diseased
(
10.
FIGURE
rooms bottom row (
.
of
was established
,
it
that cultures from spores compost which could transmit the disease trays had been planted with healthy spawn were inocu lated directly with diseased and healthy spores The Since
and
healthy mush
by
al a
,
or
by
by
,
CULTURES FROM HEALTHY RHIZOMORPHS
CULTURES FROM DISEASED RHIZOMORPHS
of
.
a
to
on
a
on
at
of
spores were inoculated into the trays mixing them compost spawning pouring into the time suspension onto single spot tray the lowing dry spores the tray surface fall directly from diseased mushroom Mixing spores with the spawned compost pro most severe infection and rarely did even diseased one appear such Trays inoculated with healthy spores produced healthy mushrooms Spot inoculation pro
duced
on
,
Mycelium cultures from rhizomorphs
.
11.
ap
FIGURE
of
development
of of
the stage
of
,
on
pended
de
of
.
in
.
in
;
area infection around the spot mush appeared this area Mushrooms that rooms peared the periphery were diseased Inoculation the spawned tray with spores from diseased mushrooms always produced diseased mushrooms but the severity the symptoms duced
the healthy .
)
8
to
,
.
on
6
(
of
at
in
mycelium inoculation the time the compost symptoms suppression fruiting The most severe days after occurred when inoculation was done spawning Spores deposited the casing layer after the trays were cased also caused infection with the
on
DISEASED SPORE GERMINATION
A
HEALTHY SPORE GERMINATION
.
by
9
England did
occurring when inoculation was days after casing research group suspending mush experiment
an
done
severity to 6 to
upof
peak in
en by
on
.
at
at
screening above the trays rooms various times after casing The experiments Butler were done an
.
in
suspending mushrooms wire hooks closed chamber above the bed surface An interesting
,
12.
to
in
in
of
to
be
.
in
,
to
,
.
,
as
he of
,
of
on in
.
of of
.
,
in
its
.
to
he
6
as
is
in
be
of
by
La
to
is
importance disease development yet Infected spores are the only method found for transmitting France disease from one va riety another Any control the disease gained changing from one variety tempo another will
virus but unclear
.
be
or
of
mush
his mushrooms the young closed condi bring the disease tion months was able completely under control Recent evidence suggests mycelium may carry In
of
,
)
in
(
ing
.
or
of
8
to
of
to
.
England and Australia are the only mushroom growing countries which the mushrooms are regu larly picked open mature with spores already being shed This practice explains why the disease more
the United States and Canada where
rooms are regularly picked when closed i.e. before the gills are exposed England had the One large mushroom grower disease severely and constantly two his three isolated farms When the importance spores the agent dissemination was learned started pick all
of
,
or
to
6
.
,
on
9
to
days after casing coincides with the time hyphal tips would when the maximum numbers growing the surface the compost the casing layer
ease
.
of
on
a
be
.
,
strains and between healthy hyphae and germ tubes infected spores The best time for inoculation the spores days after spawning and up the trays of
Spore germinations from healthy and diseased mush
frequently and constantly encountered these coun tries The tendency for diseased mushrooms ma ture earlier than healthy ones thereby making them unsalable causes them left on the beds dis charge spores This can result the spread the dis
,
ex
,
.
of
on
.
grow together tubes could seen anastomose always with the growing tips the healthy myce lium Such anastomoses were observed between germ tubes and hyphae different the same
6
rooms
.
spores into the healthy mycelium the following periment was performed Diseased spores were de posited agar plates the surface which healthy grain mushroom mycelium was growing from rye spawn These spores germinated and the germ
to
FIGURE
to
In
to be
or
to
,
so
.
,
mal Apparently mushrooms even though they pear normal can carry enough virus that open and shed spores the disease will allowed spread carried through the spores order find out how the virus moved from the
.
if ap
be
to
in
in
sidelight both locations was that some cases dis ease appeared under mushrooms thought nor
.
di
no
of
an
.
.
(
14 )
,
a
a
the
mushroom trays Fig
73
dé of thanthe rary may speras fan by ) The s
insted spores
.
longe
#ears makes thorough
a
varietyi made
SPOT INOCULATION
SUMMARY
2 sects ar was
s a
I la
Francei
WHITE
l
previously
kwasfoundthat
it
.
pickers
MIXED INOCULATION
CHECK
virus
al
.
get
they
mushroom spores
into
ng La
,
spawn growth bar
mushrooms
.
white strain
of
spawn
a
Trays planted with healthy and diseased
of
74
compost
spawning
.
the
healthy spores mixed
in
with diseased
or
Trays planted with healthy spawn
DISEASED SPORES
but
FIGURE
14.
HEALTHY SPORES
at
FIGURE
13.
they
get
b } If
France sym
onto
rary if
the disease
b)
If
they get onto the beds sometime after casing ,
as -
be
La
in
at at )
/
10
of
ft ?
in
4
).
.
in
controlling the disease formaldehyde also may aid will destroy virus infected mycelium persisting the bed boards well within the house
in
spores
cracks
or
-
break .
Steam the house before dumping the beds for hours and the empty house 160 for hours Using formaldehyde the steam steaming gal 8000 line during the last part 145
as
If
spawn
through spores 2
it is spread primarily by diseased
they get into beds at spawning or during growth , bare areas and mushrooms show ing La France symptoms will appear on the first
a)
have
°
It was found that mushroom spores .
Control : Keep
experiments
F F in
It was previously thought to have been spread by insects or pickers .
2)
3)
open mushrooms off the beds shown that normal appearing just dangerous obviously mushrooms can spreading diseased mushrooms France disease
5)
(
.
;
is a virus disease
°
La France
(
1)
.
in
SUMMARY
as
change to
.
The effects of the disease on the crop may vary from severe loss in yield to a slight reduction in yield , but it always brings a pronounced loss in the keeping quality of mushrooms . A reduction in mushroom size and an increase in number of culls are also effects of all
a
appear in the later breaks
4)
as
of spores by thorough disinfection when a new variety is made .
La France symptoms
crevices
.
infected spores remain within the environment of the farm . The longevity of mushroom spores ( more than 40 years ) makes it essential that the farm be free
75
SECTION
1
II Technology
1
Seasonal Variations and Mushroom Growing Paul J. Wuest
to
."
is
of to
is
;
,
or
fill
at to
9
a
11
of .
to
to
16
of
to
14
of
in
25
by of At air -
.
re
to
to
so
.
of
or
as
as
,
be
.
to
off -
or
a
-
.
,
higher during production yet fresh market quality
mushrooms
of
or
a
)
to
,
(
of
1800 ppm
solid
fre
Growers who provide mushrooms for processing display the same tendencies strain selec tion An alternative suggestion for either kind grower cooling ventilation system de install signed handle the hot humid air summer and provide cool air the growing mushrooms This can
of
in
quently
79
.
of
/
a
to
to
per
in
it
.
a
)
at
.
A
.
period
,
-
to
extended
level yield
to is
,
is
)
(
or
.
F
°
it is in
compost materials for
an
the
,
it
to
.
In
either instance the compost turned after preferably higher and this has heated 150 can take longer winter Besides the interval be pre condition tween turning common practice
winter
be at a
be
,
In
.
to
(
or
-
a
to
of
of
fresh market grow either white white strain year round However they may choose from availa heat ble spawn cultivars strains one more tolerant during spawn run and one which can tolerate CO2
.
in
5
to ,
3
of
2
1
or
to
is
-
a
in
.
,
at
to
is
It
-
common encounter least two different composting schedules during the year one for summer and one for winter The interval between days contrasted turns summer reduced turning schedule interval days with
Composting
is
-
.
14
to
"
bit :
of
a
of
compost was tightly packed since the compost tem perature more easily controlled during spawn run tightly packed when the compost spawn strain can Spawn influenced Selection year growers time Mushroom who sell the a
, ,
.
to
COMPOSTING THROUGH CASING
percent months was reduced much conditioning duce the demand for have bet the compost while the ter temperature control colonizing the compost The spawn was running spawning operation was often modified that the
of is
is
,
50
to -
30
to
.
-
so
,
,
a
control pests
farms where deep filling was compost filled warmer
post surface tamped routine the volume
.
to
,
,
.
a
and usually not quite wide ranging The seasons modify com then cause mushroom farmer posting practices watering and ventilating patterns
trend during the 1970s was com depth the out inches into beds composting set the second phase This original depth depth compost shrank inches the time spawning was completed and the com post
is
° .F
no
as
so
,
alike available for use during the same 24 hour period Spring February through mid April per time when the humidity ranges from cent and the temperature changes are less sudden
tioning
-
Filling
of
65
to
40 ° F
,
cent and the temperatures usually will vary from cooler than warmer than challenge Such conditions are mushroom growing long mushroom houses are sturdily built well insulated and have heating and air condi
chines
,
85
is
to
40
.
in
,
Between these extremes fall and spring have their unique characteristics Fall the Northeast often per muggy with humidities ranging from
problem Some composters have ma turners for each composting season turn specific times during the composting pro ers used both cess
usually not
-
.
3
or
2
25
a
of
air ,
.
or
higher during this time Winter miles per hour dry also time and the relative humidity may percent for remain below consecutive weeks
tween winter and summer composting the amount water that must added during the composting process challenge get summer can enough water into the compost the outset the process keep composting going winter this
,
to
is 20
10
at
to
all
cent . At the opposite end of the year , mid - winter , there are usually 6 weeks during which the thermom eter stays below the freezing mark and , further, it is gust not at uncommon for the winds
days Pre conditioning another way allowing the materials start heating and significant moist Another difference be
by
Summer is characterized by hot and humid days when temperatures equal or exceed 82 ° to 85 ° F with accompanying humidities ranging from 70 to 90 per
get
by
The weather of the North American continent is a challenge to anyone wishing to grow mushrooms .
and even the strategy used
haps saying 10
SEASONAL INFLUENCES
of
,
.
to )
,
-
only
usually
is (
most mushroom farmers used topsoil clay loam for casing Today such casing 60s
used
at a
to
.
in
15
,
-
of
.
,
be
an
expensive alternative considering the cost energy and equipment maintenance Casing The next phase the crop casing and crop management following casing has changed years During the middrastically late the last
.
of
a
in
,
-
of
-
is
15
10
percent the farms Now the coinmon peat moss mixed with low magnes casing material ium ground limestone although nearly one third the farms North America use third casing mater
of the drying should be changed , but farmers often solve the problem by using a greater depth of casing this practice may alleviate the symptom but it does not solve the problem . A clay -loam soil is the slowest
of the three materials in terms of drying rate , so it is not particularly prone to rapid drying . However , soil and the other two materials act as insulators when they are on top of the compost , and may cause a problem in controlling compost temperature , espe cially as casing depth is increased and the upper ore . half of the casing dries excessively , or both . Because
Weeds are kept down during the warm roto tilling few times and roto tilling manipulation physical only this material The the spent compost collected from the field pasteur ized and used for casing
system
-
a
of
"
.
"
is
A air
in
of
,
, a
by re
to air
of
to a
is or
it
,
is
by
in
to
be
,
of
b )
or
a )
:
–
to
is
,
be
to
.
at
,
-
of in
by
to
.
of
a
,
or -
to
of
.
or
,
,
of
of
.
a
,
.
in
,
,
an at
so
,
a
in
routinely followed until the first freezes
of
is
-
of
in
in
,
in
to of
winter
arrive
The changing seasons require modifications
all
SUMMARY in
.
or
vegetation doors and attics roofs lofts and pesticides Use these nonproducing areas seems growing room protecting the crop vital the first sign mild weather the early spring initiated and expanded pest management system .
in
to
is
-d
,
.
as
of
if
pests
concern extends beyond the walls since the milder weather the growing rooms means alternate breeding grounds are available out weather the area of
in
,
or
75
is
as
of
F .
to
a
of or ,
,
.
80
the weather
present irre composted selected Do that none not affect severity because pathogen and disease occurrence problem under any combi insect alike may become growing conditions This fact makes grow nation pest incidence year round and ers alert most preventing their becom farms pests are controlled ing established growing rooms During milder
of -
of
on
.
or
,
;
to
.
-
55 °
50 °
lower than casing top ressing the deeper layer applying spawning less compost Spent compost has casing peat during muggy some the same traits spent compost dries more quickly than weather but drying peat Thus the rate too great the cause
less tied
do
to .
is if
,
by
is
a
F
°
70
percent and the humidity night temperature goes no the time Such situation may require
the
PEST STRATEGIES
or
or
,
-
or
,
.
and
CO
sustained concentration practice increase While neither desirable many growers common situation faced Northeast today the
2,
at
.
is
or
is
by
a
,
higher
causing
.
.
of
is
.
-
is if
is
-
a
of
In
or in .
reaches concentration too high for pinning occur Such conditions occur rather commonly from late spring through fall when outside daytime tempera tures exceed
grower must choose between one two incomplete introducing solutions more fresh and not ducing the growing temperature due inadequate cooling capacity reducing the temperature decreasing the amount outside air introduced thus
are constant threat Pests seem spective year the material the time the casing the spawn cultivar planted mean not misinterpret this statement the listed mushroom farming elements
the room air
North
the incessant need for America conditioning during the summer the tradeoff
The pest situation
twice daily foggings with water gentle waterings using fog nozzle that produces mist The myce the surface fuzz lium certain spawns tends usually peat pins the rather than form This occurs when air conditioners are undersized unavailable muggy weather when air conditioners are not either situation the CO2 level
mushroom growing
consequence
.
as
,
.
,
,
a
,
ial
commonplace during the warmer months being forced into the room too much air creating too much turbulence the dew point tem excessively perature the the cooled when lowered air becomes reheated This situation should be modifying the ventilation system but remedied daily most often the symptom corrected
Another aspect
of
is
.
of
this ing are too numerous for detailed attention key point but are listed considerations few Sphagnum peat the most common casing mater today sphagnum peat very prone used Fine sealing watered too frequently over watered
use
TRADEOFFS
.
,
is
,
Each these casing materials has unique charac teristics and thus requires different management the seasons change Casing depths differ watering patterns change and each material requires distinc tive ventilation procedures With three materials and variables that affect cas four seasons the number
Drying
.
at
at 36 a
18
to
:
of
-
,
a
-
by
ft
,
to is
be
as
.
-
of
of a .
months months
the
of compost - temperature control and ease in manag ing the water content of the casing , only the winter months provide an ideal opportunity to manage casing without the addition forced air ventilation
ial
weathered spent compost Weathered spent the compost can follows described briefly placed compost spent fields crop into end depth weather for 2.5 and allowed
fac
. ů
ets of mushroom culture . How extensive the changes must be is somewhat dependent upon the ability of a mushroom grower to keep the number of variables to a minimum . Imposing greater crop - management con trol through the use of different machines , environ
mental - control systems , or understanding the biol ogy of mushroom - growing and supplying what is needed by using more or less air , heat , water , or pesticides can neutralize the potential impact of each
new season
.
81
A Grower's Guide for Commercial
Mushroom Compost Preparation Lee C. Schisler
All commercial mushroom growing
has depended on
composted material . The time and nature of the composting process has been modified , but no one has been successful in eliminating it from the prepa ration of a suitable medium for the mushroom bed . Our mushroom belongs to a group of plants called a
(% )
(ton )
80.00
50.00
1.2
0.60
Chicken manure
7.50
6.00
4.0
0.24
Brewers Grains
2.50
2.50
4.0
0.10
Gypsum
1.25
1.25
0
(ton )
Horse manure
(ton )
0
59.75T
Ton N /dry wt
%N
0.94 1.57 % N
0.94 /59.75
Wet wt
Dry wt (ton )
(% )
(ton )
15.0
12.8
2.0
0.26
Cobs
15.0
12.8
0.3
0.04
Chicken manure
3.8
2.4
4.0
0.09
NH.NO
0.3
0.3
32.0
0.10
Potash
0.3
0.3
Gypsum
0.6
0.6
0 0
,
it .
or
I,
II,
pasteurization
(ton )
Hay
0
.
no of
or
a
to
at
and Phase the cookout some growers call
N content
0
(
or
all
a
to
create
a
is
:
/
N
%
%
/d
a
1.68
Hay corn cob hardwood bark synthetic compost pile Dry
N
Wet wt
Ingredients
wt
.
-
-
Table
3.
of or
a
.
in
in
in
or
0.49
0.49 29.2
content
0.3
0.02
6.4
0.4
0.03
Chicken manure
3.8
2.4
4.0
0.09
NH.NO
0.2
0.2
32.0
0.06
Potash
0.3
0.3
Gypsum
0.6
0.6
0
0
0 0
N
1.58
%
N
%
Ton
wt
periodically
0.46
0.46 29.1 /
to 4 .
(
29.11
.
a
as
to
piles which are then
)
6.4
9.4
dry
ton
(
( % )
7.5
Hardwood bark
)
Cobs
)
0.26
(
2.0
/
is
by
of
1
in
North America today are enumerated Tables Various proportions manure and synthetics are mixed into what growers refer blend building the raw Phase characterized 1
12.8
N
in
of
.
ganic and inorganic fertilizers have been successfully introduced into the industry around the world Some typical formulae used various parts
into
ton
15.0
,
,
,
)
,
synthetic composts hay corn made from straw cobs and other fibrous materials combined with or
ingredients
ton
Hay
(
,
as
.
,
It
is
to
.
Ton
N
I is
I
usually conducted outside covered area This the activity which the raw ingredients begin break down can also occur drum composting device but commercial applications such have been limited Horse manure has long been used the basic ingredient but substitutes called
ry wt
=
29.2
PHASE
N
, ,
Ingredients
.
to
at
do
)
in
are therefore
as
process process
Table 2. Hay -corn cob synthetic compost pile .
compost
containing sufficient nutrients grow good crop mushrooms and the same time provide little nutrition for other fungi and competitor organisms Composting procedure involving two interde pendent processes Phase the outdoor composting
Phase
N content
In
,
.
.
composting
of
tives
-
Dry wt
,
compost that will supply our mushroom with food At the same time the compost must not contain compost foods upon which other fungi can grow suitable for mushroom growing other fungi with only few exceptions either not grow slowly objec comparison the mushroom The
Wet wt
Ingredients
its
the jungi . These plants differ from green plants in that they lack chlorophyll and cannot manufacture their own food . We consequently have to prepare a
Table 1. Straw -bedded horse manure compost pile .
83
N content
Wet wt
Dry wt
(ton )
(ton )
(% )
(ton )
22.00
20.00
0.6
0.12
Cottonseed hulls
7.00
6.25
0.6
0.04
Chicken manure
8.00
6.00
4.0
0.24
meal
2.00
2.00
6.7
0.13
Gypsum
0.65
0.65
0
and reducing pH and ammonia content . Growth of the microbes causes the temper the pile to increase . Microbes vary in their ada
heat , so their temperature requirements ar what specific . As the temperature increase that love heat ( thermophiles ) reproduce ar and in turn give off more heat . Much of the in the compost is ammonified , i.e. , much am
Cottonseed 0 0.53
34.9T 1.52 % N
0.53 /34.9
-
turned , watered , and formed . This mixing and water ing tends to equalize the environment so as to pro mote a uniform transformation of the ingredients . Compost ingredients harbor a great number of mi
With the addition of water to the dry ingredients and the building of a pile , these microbes grow and reproduce . Their growth requires (microbes ).
ii ) adequate moisture , suf available food The food supplied the bulk compost ingredients and the compost supplements nutrients The addition this time directed therefore toward the feeding microbial population the compost rather than direct nutrient addition for the mushroom addi .
of at
,
a
In
by
.
.
,
ni
,
Horse manure – Synthetic
1 . 1
be
-
NITROGEN CONTENT GUIDELINES
pe
to
be
b )
.
.
by to
.
up
or
.
at
,
as
as
During composting add much water without runoff first two turns Add only water during next turn turns wet dry Bring adequate desired water content ing just before filling MOISTURE CONTENT GUIDELINES in 75
to
or
70
the greener
the more moisture
it
thumb
is :
good rule the compost
be
at
filling should Moisture content Water should drip from compost squeezed
A
be is
WATERING PROCEDURES
-
-
;
or
blends with calculated only the syn on
be
III
,
of
of
,
addition but their rate ingredients and should composts
raw ingredient
spawning
IV .
as
,
,
,
,
.
be
to lb /
25
to
used
dry ton
synthetic added only blends the rate should ,
.
to
(
,
)
Inorganic nitrogen sources are added ammonium nitrate calcium cyanamide and
may also
limited
5.68 yd /ton
ingredient
.
,
To
of
1
of
% ),
to
,
as
-
urea
3.25 yd / ton raw
fr
content will increase throughout com and cookout and should 2.2 2.3
,
2
of
is
(
,
,
try
nitrogen
–
filling,
at
pile should Starting content percent before composting See Tables
.
aa is
just slightly greater than percent nitrogen compost raise the content the the de poul supplements sired level 1.5 1.7 such manure brewers grains cottonseed meal soy bean meal cocoa bean hulls malt sprouts sewage sludge and dried blood containing primarily organic
84
Calculating volume of compost weight of raw ingredients :
.
in
,
of
of
an
it
,
In
the nitrogen source Good quality hay may percent but when mixed have nitrogen content nitrogen with corn cobs the total content the bulk ingredients
an
I. WET - WEIGHT / VOLUME RELATIONSHIPS
of
the straw contains droppings and liquid waste giving average nitrogen content 1.2 percent synthetic compost the protein the case the
such
A few practical tips on Phase I compost composting process :
N
com
horse manure
post
hay
,
a
to
to
active fermentation
In
plete
.
an
of
to
be
of
content the compost pile before the composting be gins should 1.5 1.7 percent assure sufficient supply nitrogen for the microbes efficiently com
of each of these is present
Phase I composting is complete as soon as ingredients have become pliable , are capable ing water , and have become dark brown in co odor of ammonia is sharp .
of
to
supplied primarily carbohydrates tion the bulk microorganisms compost ingredients also need trogen for growth and reproduction The nitrogen
long as enough
will continue to heat .
to
a
in
,
is
.
of
by
,
is
iii )
,
iv )
i ) suitable temperature ficient oxygen and
color of the the compost . The microbes use readily available carbon , nitrogen , and oxy
,
croorganisms
-
N
%N
Ton N /dry wt
released by a group of bacteria at this time . temperature within the pile increases , a direc ical change caramelization takes place . It cess which eliminates water from carboh thereby concentrating this valuable food mushroom . It is responsible for the darke
II .
Straw
a )
Ingredients
thetic portion of the blend . Gypsum ( at the r to 75 lb / dry ton of compost ingredients ) is a manure and synthetic composts alike to their physical characteristics by preventing gr
compost pile .
hulls synthetic
Table 4. Wheat straw -cottonseed
more
can
.sp );
Thermoactinomyces
and
fungi
.sp );
Streptomyces
).
is
be
at
° F .
,
°
,
at be in a
24 to ,
as
F
°
5
tem
In
at
.
96
of
no
of
so
° F
to
to
is
to
.
.
be
.
72
to
a
,
.
:
in
be
II
At
is
°
F
75
to
be
° F .
to
°
of
,
of
of
it
.
depth
and
.
in
fill
,
it
be
.
or
,
or
be
to
both
in
II .
.
.
II
,
),
in or
in
houses without forced air ventilation
.
the range where
to
as
so
Phase avoid
.
of
)
4
(
)
Heat for pasteurization insect kill early perhaps days after filling second heating cycle the compost
4 )
micro
a
115
° F ).
135
°
grow best
(
3 )
Keep compost temperatures
organisms
to in
-
systems
in
as
(
is
.
of
at
to
an
open flame The higher times sustain filling time the compost the nitrogen content greater the ventilation required When the outside high temperature early fall more summer required for Phase ventilation standard double gen
(
in
,
uniformly
Insure adequate ventilation during Phase When doubt ventilate The air should have sufficient oxy
II
by
of
.
to
Attempt
compactness
to
,
° F
wetter the compost the more loosely filled into the beds The longer greener can firmed into the beds the compost the more The shorter
should
of
.
(
compost can allowed this point few practical order
is
i)
.
in
gone ammonia spawning for may Phase
1
in
air is
,
to
.
is
)
as a :
-
smell cool tips
all
,
in
,
,
be
to
to
is
II
to
ii )
is (
greater than per least hours within the de
this 135 115 sired temperature range able perature range the thermophiles should convert all the ammonia within hours Once the
up
to
all
°
F
of
If
,
.
,
to iii )
cooling
hours This will assure
on to
2
of
or ,
to
be
–
air . 2
in
accomplished Once pasteurization cool troduced into the Phase room assure adequate and attempt oxygen hold compost below 140 help dissipate ammonia Conversion ammonia microbial protein best accomplished thermo philic heat loving organisms This group organ using the ammonia present very efficient isms growth factor The thermophilic the compost group includes actinomycetes Thermomonospora
keep the rate
,
be
in
air
a
be
.air
to or
or
air
°
, to F
to
.
° F
of
.
II
be
.
II
or is
in
air
,
air to
heat through the growth of the microbes . The heating compost causes the surrounding cool drawn towards the heat and this action assures ade quate air movement for microbial growth provided within the the available sufficient oxygen mushroom house Phase room accomplished early Pasteurization should the operation requires Phase Pasteurization and compost temperatures minimum for 140 compost temperature hours Once the has.increased 140 steam may introduced into the room temperature house raise the the same point the room house may closed tightly allow the compost heat the Either procedure can pro temperature duce the same result hours 140 compost compost both and the and other exposed surfaces are not subjected this tempera complete ture regime pasteurization will not leaving some harmful organisms grow reproduce and subsequently cause difficulty the mushroom crop
converted Air introduced into the house room rate sufficient cool the compost this range Once the compost has cooled below 140 the amount ventilation must be regulated nia will
at
gins to
temperatures be These organisms grow best longer tween 115 and 135 The the compost can held within this range providing other factors are available sufficient quantities the faster the ammo or
has two main purposes – elimination of am pasteurization . Pasteurization is necessary to free the compost of undesirable microbes and in sects . Through the proper manipulation of tempera ture and ventilation , these two primary objectives can be realized . Once the house or trays are filled , the compost be
monia and
1 )
II
Phase
2 )
PHASE II
,
As
(
(
,
Humicola Torula Chaetomium Mucor and ther motolerant mesophilic fungi Aspergillus fumigatus incorporated this group grows the ammonia into microbial cells and ultimately becomes available the mushroom ,
the less water it
,
,
or more dense the compost
should have .
,
| shorter
85
II
Suggestions for Phase
in a Standard Mushroom House
in
or
1 °
in
(
of
on
,
4
up
I'd
,
in
I'd
ventilation
.
-
–
.
4 .
°
at
to
of
),
to
or
I'd 2
6 )
2 ° F ) (
–
sufficient
° F .
°
,
24
,
a
°
in
each hours and this will insure temperature range suitable for
microbes
compost
spawn
moisture
necessary
,
adjust
re -
,
cool
if
I'd
When ammonia has disappeared from compost
,
.
the growth
5
hours of
of
about
96
a
rate least
to
During the next several days gradually bring Cool 115 compost temperature down from 140
and
.
an
4
in
.
.
temperature through use ately 7 )
)
,
or
in
on )
steam immedi
a
in
II
a
.
to is
I
.
I
to
I
uncertain and varies from house house how would can give only general guidelines manage as
that
"
"
I'd
,
the procedure would follow for Phase standard mushroom house Ventilation one area
This
it .
to
° F .
,
° F
to
begin gen After compost reaches 1250 130 keep compost tempera erous ventilation enough ture cooler than 140
5 )
Summary is
in
air
so
I'd
flame
.
the house will support
a
-
.
as
as
to
ately after filling temperature and get com raise quickly post started possible have some ven enough tilation from the very beginning
is
so
in
12
.
fans Turn
for insect kill Turn live steam cool hours Then 140 for pre heatup level immedi back
heat
hold air temperature
air
4 )
,
be
(
to
both depth and compactness Compost should not stepped loosen where it's deep place inches one and inches forth other and
Turn on recirculation
post
at at
,
the more
greener the The longer into the beds I'd attempt .
. it it
fill
to to
firm
compost shows the first violent heat breaking compost temperature drops the first violent ammonia release has subsided usually days after filling depending com
8 )
as
)
oil
of
or
fill
I'd
3 )
the compost
wetter
to is ( 55 -
of
as
at
ft
(
of
.
The shorter loosely attempt more I'd attempt uniformly
.
oil
Add cottonseed the rate four compost drums per double 8,000 filled Method addition should be such throughout compost uniform distribution
2)
gal being insure
As soon
signs
air
Check compost as it is ready for filling . Moisture content should be between 70 and 75 percent . If less , adjust by watering . Water should drip from compost squeezed in the fist . Good rule of thumb : greener and coarser more H2O , shorter or denser – less H2O .
1)
as
Lee C. Schisler
87
Pasteurization During the Mushroom - growing Cycle
a
to
.
,
no
,
a
a
,
In
.
is
is a
.
a
of
.
es ,
of
,
is
in
a
,
no
an
.
is all
in
an of
a
a
-
to
.
is
of
to
,
to a
a
is
of
–
is
)
is
to
to
the temperature the exchanged steam latent heat from steam ob ject contacts this phenomenon called CONDEN SATION CONDUCTION the transfer heat through temperature difference with heat mov solid due ing from higher temperature region one lower temperature CONVECTION heat transfer through fluid due temperature difference heat a
).
for
. °
C if
of
all
in
.
to
a
preferred object
a
se or a
– .
(
is
to
,
),
(
as
or
-
,
,
of
,
is
-
,
room
pasteurization Steam heats
.
,
,
,
.
be
.
POSTCROP PASTEURIZATION When steamed off and the empty room trays beds walls and floors are pasteurized this practices quence steam referred sanitation ing before and after dumping EMPTYING OFF COOK OUT
with the things succumb long exposed
biological vacuum ence precludes the possibility The biological vacuum which exists after sterilization an unnatural condition and life forms luxuriate competition when they encounter substrate making mushroom spawn sterilized grain sential but other aspects mushroom farming
; (
,
,
-
a
is
sanitation
.
to
be
lethal When picking ceases postcrop implemented Compost casing and the pasteurized before removing spent room should materials This practice has different names STEAM proves
along
All living
temperature 100 enough time Once life forms are dead the me dium which they lived sterile contrast pasteurized medium sterile medium pas for pathogenic organisms but teurized medium has does contain innocuous microorganisms Their pres
it
-
be is
-
,
by
to
or
,
,
of
to
.
-
,
-
-
,
This process also called peak heat pasteurizing more than pasteurization since ammonia must eliminated from the compost before spawning Casing treatment refers the elimination undesirable insects fungi bacteria nematodes and viruses either via fumiga subjecting undesirable microflora and mic tion temperature time combination rofauna that
microorganisms
beneficial
harmful target organisms
is
or
.
cook out
or
is
supplemental heating
tral
In
is
II
by
.
iii )
There are three periods in the mushroom - production cycle when steam may or should be used to pasteur ize : i ) Phase II composting , ii ) treatment of casing , postcrop sanitation composting and Phase the managed composting process which ammonia dissipated and pests eliminated through natural
or
Paul J. Wuest
.
is
-
,
,
;
1
of
of
is
to
or
to
af
.
(
),
a
in
or of
to
a
is
/ b /
of
a
.
)
so
-
.
F of
°
it
is
,
or
, in
.
in
a
, of
or
be
to
,
is
.
neu
VAULT TREATMENT system consists room which containerized compost casing trays placed pasteurized beds buckets The or
in
by
.
be
to to
an
is
thus destroying
com
post peat moss any other material significantly fects how quickly heat accumulated and trans ferred ,
,
C )
°
of
(
°
F
as
as
is a
living organisms
,
eliminates
all
;
on be
depending much 120 48.0 the volume and temperature air used the mixture such mixture called AERATED STEAM pasteurization allowing Aerated steam aid temperature Sterilization controlled the steam lowered
gas
.
is
of
.
,
by
the mixture can
gas liquid dia involved liquid solid called SENSIBLE HEAT The moisture content
,
to
is
mixed with steam the temperature
(
at
– en
at
/
-
)kg
to
be
)
of
(
kg
? (
/
in
lb /
/ lb
).
° C
is
to
(
°
F
100
The specific heats and dry wood make both poor rather conductors heat dry soil dry peat and dry spent compost are also relatively poor conductors high specific heat heat Water has Btu good conductor contains heat and temperature sensible heat Heat transferred due change differences without the nature the me
A
vaporized
water and water vaporizes Heat must transferred convert water steam 970 Btu 244.42 cal 14.696 pressure 1.0332 cm² and this heat ergy released when the steam reverts water which occurs with condensation When cool air 212
of air
to
HEAT CONDUCTION AND TREATMENT SYSTEMS Steam
its
or
.
to
moves from warmer cooler areas Heat transfer occurs via conduction convection when the con ductor has heat transfer high SPECIFIC HEAT
89
to
,
in
,
,
as
as
,
.
in
or
or
a
or
.
be
-
by
a
-
in
or
a
in
60 °
,
of
air
is
of
a
.
ef at
C )
-
,
is
(
°
F
to
If
fly
-
a
30
,
45
,
a
in
?
F
°
45
!
?
to
,
.
,
°
F
at
of
° F
,
at
.
.
to
90
.
at
in
,
In
.
.
If
–
-
of
,
at
or
-
by
is
2
of
30
at of ,
to
be
-
an
-
is .
a
.
3
4
to at
or
do
on ,
be
be
at
80 or
to
,
an
-
.
,
,
hours figuring
to 3 ,
2 In
.
to
boiler for
5
ers rented
hours
to
to
all
at
.
of
3
to
2
°
to
were needed raise the compost from 130 up holding time Pas resulting 140 hours teurized compost was obtained with this system farms where fans were used mix the steam and room air in
of
a
of
prime tar
Consider
truck mounted steam boiler pasteurize the com post Truck mounted boilers are usually rated approximate steam output 100 horsepower with 2400 3000 pounds per hour respectively Farm ers who rent boilers tend monitor compost and air temperatures with milk thermometers 1981 farm a
is
fa .
a
by
a
,
.
the truffle fungus was
was not thorough
or
.
to
to
,
.
be
?
to
90
,
posting wharves
pasteurization
.
,
,
is
,
-
of
pasteurization cycle that vorable environment plus eliminates mushroom pests but not the number beneficial microorganisms What needs eliminated from the compost dur ing pasteurization Before the days concrete com
present
ing that most commercial sized rooms provide oppor tunities for the temperature lower than needed judicious safeguard additional minutes holding time Thus the recommendation hr thorough and 140 when temperature monitoring reliable Many farms not have monitoring systems depended that can and such farms the hold ing time should extended hours Many Pennsylvania mushroom farmers rent F
is
.
to
all
a
of
In
a
most efficiently accomplished when large popula deammonifying microorganisms are present tions High populations are encouraged providing
pasteurization can be assessed The effectiveness monitoring free living saprophytic nematodes spawning time before cool down any are
.
re
Reconditioning
the summa chemical and physical changes which compost that soft nongreasy with de sired odor and color and with heat molds present the low temperature system compost tempera tures are critically monitored and controlled insure efficient temperature range most conducive deammonification The deammonification process tion produce
occur
todes had disappeared
-
in
a
to
,
is
.
C )
63 °
(
°
F
of
at a
mini and compost temperatures are maintained Following pasteurization mum 145 this few de system compost temperature reduced permit deammonification grees each day and
minutes 140 were maintained and temperature control was totally reliable has demonstrated that pasteurization may not take place these instances large nematode populations re spawning time When the mained the compost holding time was extended minutes 140 pasteurization was accomplished The live nema
.
is
.
-
6 -
a
is by
In
to
by
,
to
a
to
the compost allowed move through normal heating and cooling cycle interrupted allow pas teurization occur heat from the compost contrast the high temperature system which characterized hour period during which air
holding times
a
,
In
.
is air
cess in this process , as practices vary among farmers . Notwithstanding the many variations , the conduct of the process normally falls into one of three general ized schemes : natural , low- , or high - temperature . These designations reflect the management of the compost and temperatures the natural system
°
write or speak of the Phase II process recog nize at least two steps : deammonification and pas teurization . No single technique is required for suc
of
All who
conditioning
search indicates that flies larvae most fungal pathogens and nematodes will die during min minutes be ade Shouldn't 140 ute exposure quate NO Experience few situations where ,
II Composting
° F,
Phase
2
WHEN PASTEURIZATION IS USED
re
.
,
to
air
et al . ( 1975 ) .
,
.
in
in ,
-
in
aerated - steam treatment system is covered in depth
by Aldrich
must be raised 140 and maintained for pasteurization least hours this done will be fective Remote temperature sensing probes posi verify tioned the and compost are needed temperatures have been maintained that desired showing that pasteurization has occurred Why does pasteurization require hours when .
density , total porosity , compression index , and par ticle - size distribution plus a few other physical char acteristics . How each affects treatment in a forced - air ,
directly duct installed ventilation pipe which fans circulate the room from into introduced how the steam room air Regardless compost and distributed temperature and alike permanently a
-
sible heat , or specific heat . Heat transfer occurs via condensation , conduction , or convection , and these processes are affected by the specific gravity , bulk
2
Heat energy involved in any of these processes falls the following categories latent heat , sen
into one of
viruses the compost the air Pasteurizing with added heat steam gener introducing free flowing begins ator aerated steam into room The steam can distributed via bacteria
.
and aerated steam is forced through the mass , the bulk compost or casing is being treated by a FORCED AIR , AERATED - STEAM system .
but today truffle disease tends prime pests rare The for elimination are insect lar vae the compost adult insects the room nema todes the compost well undesirable fungi get for elimination be
containers are then surrounded by free - flowing or aerated steam for treatment . When bulk quantities of compost or casing are placed in a treatment facility
infestation , and when treatment with free - flowing steam is compared with aerated steam , the free
ers used weathered spent compost for casing . Weathered spent compost and top soil alike will harbor mushroom pests , and peat moss is suspect . If the treatment (pasteurization ) temperature is too
that will germinate ( Table 3 ) . Percent germination of V. fungicola ( syn . malthousei) spores is influenced by the casing material and the length of treatment at 140 ° F ( Table 4 ) . Generally , as treatment time is in creased , the percentage of Verticillium spores that germinate also increases ( Table 4 ) . Germination dif
mushrooms ( Table 2 ) . However , the temperature at which soil is treated affects the percentage of spores
fers with each type of casing ( Table 4 ) 1, and the amount of disease appears to be related to the type of casing material used ( Table 5 ) .
The conclusion from these data is : TREATING CASING
a
,
or iv )
)
(
do
.
A
of
if
as
+12
)
12 (
at
or
2 (
)
(
)
° F
or
°
at
1.
of
Casing treated
with
infested
+2
.
3
was
and
° F
° F
209
casing
surface
.
0 of
ft
1.9
for
104
each
12
35
(
= 5 x
G. to ,
),
3
its
,
treatment temperature inocu diseased mushrooms when days before treated soil
to of
,
2.
casing 209
° F
temperature 180
of
Treatment 140
the time
2
( % )
( % ) 5
( % ) 4
) 0
/ 4
5,000
17
44
92
50,000
65
92
100
500,000
81
96
98
of
-
related
to
is
on
of
aerated steam treat disease are presented
(
or as
.
soil following
Spores
ft
G ,
.
Inoculum density
° F
at
.
casing
° F
,
of
of
.sp
30 ;
° F
were used
85
to
8
0
12
+
( to to % )
1 0 ( to to to % ) 10 7 3
)
(
),
(
15
T.
),
T.
,
at
to
F
mineral soil casing Verticillium incidence -
spores
The relationship between lum density and the percentage spores Verticillium were added use
, °
at
45
(
(
(
),
-
.
Data showing the influence 1.
+2
),
-
(
by
,
.sp
,
F
°
pathogen were eliminated from peat treatment 131 for 30 minutes of
-3
140
days
Table
aerated steam 140 the hardiness the two exceptions was such that minutes exposure destroy them The bacterial 130 was required blotch pathogen Pseudomonas flourescens biotype and the Pseudomonas species known the Mummy
in
,
minutes
perniciosa Chromelosporium Ostra Cinnamon brown mold viride and viride and Chromelo All fungi except were eliminated after minutes expo
to
.sp
V. 1 1 :
Time
infestation
-3
30
° C )
,
A.
),
A
).
(
M.
fungicola
ment Table
days before
percent mushrooms
.
(
° F
at
of
for
bisporus Geotrichum candidum Lipstick eliminated Mycogone perniciosa viride Trichoderma Wet bubble Green mold and Verticillium fungicola Spot and Dry bubble different aerated steam treatment system designed Aldrich and Nelson 1969 was used treat soil containing Dactylium dendroides mildew
sure
the pathogen days after casing of
,
-
in
on
fluence the crop assessed Treatment soil 130 54.5
spores
Occurrence Verticillium disease when soil treated 140 209
of
flowing an
by
of ,
° F
free
of se at
the use
infected
steam conducting 212 was evaluated extensive experiments ries which the thermal sensitivity the important pathogens was determined and its
sporium
steam at a lower temperature is effective in accom plishing the desired result.
in
to
An alternative
choderma
farms span the spectrum of casing materials and their treatment systems are quite varied ; this suggests
Table
Effectiveness and Usage of
Its
-
Aerated Steam
candidum
have treated their casing at 135 ° F for 2 hours have a decade . These
grown pest - free crops for almost
.
of
is
a
is
,
at
a
a
of
of
..
is
-
of
it .
peat moss not pasteurize experience peat decade indicates moss from some bogs free mushroom pathogens and saprophytic saprophytic nematodes When severe infestation appears peat pasteurized nematodes farm nematode assessment indicates that the peat moss the source the nematodes
General users
AT 140 ° F FOR 30 MINUTES IS ADVANTAGEOUS WHEN COMPARED TO TREATMENT AT HIGHER TEMPERATURES OR FOR LONGER PERIODS . Mushroom farmers who
a
in
a
in
or
iii )
high or if the treatment period is too long , harvest de lays and yield reductions occur . Today most casing is treated via one of the following methods : i ) steam dis tributed through pipes in a truck bed , ii ) aerated steam that surrounds trays of casing in special rooms ( vaults ) used exclusively for this purpose , aerated steam forced through the casing mixed with the fumigant casing rotating cement mixer field soil
a higher percentage of in fected mushrooms . Treating soil at 140 ° F is not a panacea for Verticillium control , since the amount of inoculum influences the percentage of diseased
flowing treatment permits
as
2.
Pasteurization of Casing with Steam Casing is any material used to top - dress the compost , and it is on casing that mushrooms form . Soil , usually a clay loam , was the principal casing material used until urbanization and soil conservation caused farm ers to look for some other material . About 1970 , a few mushroom growers started to use sphagnum peat mixed with limestone , and a small number of grow
91
is
is
an
-
,
is
is
,
it
a
and after dumping Why Steam heats compost more rapidly than heats wood the compost acts heat sink Thus steaming before dumping pasteur izes the compost but not the wood as
a
.
.
,
,
it
so
64.5
?
57.9
Control
.
209
If
.
23.1
be , or
180
eliminates pests harbored the wood farm plagued with Mummy LaFrance nematodes imperative that pasteurization done both before in
11.3
,
( % )
.
( ° F ) 140
of
this practice minimize chances contaminating younger crops other growing rooms pest infested growing room when compost from being removed empty room Also pasteurizing a
Germination
temperatures
The goal
in to
Treatment
Pasteurization After Cropping of
for
.
° F
or
°
°,
at
in
24
TABLE 3. Germination of Verticillium fungicola spores incubated hours soil treated 140 180 209 with aerated steam
material
30
90
240
( % ) 93
52
86
73
70
95
87
compost
a
of
.
,
-
to
.
or
,
II,
of
?
.
Spent
has replaced the low temperature system for Phase pasteur many farms Those farmers who failed ize empty growing rooms between crops often had severe nematode infestations appearing when first break pins were forming Where did the nematodes come from From inadequate pasteurization during casing Phase from inadequate pasteurization
II
72
-
29
at
Peat moss
( % )
Loam soil
( % )
oil
of
)
minutes
of
Treatment
(
Most mushroom growers use some form low system which maximizes the temperature Phase nutritional value the compost Since the cost fuel sky rocketed late the 1970s the natural system II
.
Casing
time
FARM PRACTICES
in
,
or
or
90 ,
30 ,
treated
° F
at
,
contact
in
of
Germination percentage Verticillium fungicola spores spent compost previously with loam soil peat moss 140 for 240 minutes
4.
Table
to
38 12
enough
is
of to or
it
. ° F
to
or
,
,
a
6
° F
at
150
or
,
is
,
If
.
for
,
to
,
In
.
.
a
air
to
of
-
,
3
or
2
dry thoroughly months many the pests were naturally eliminated Today's year around drying from being growing cycle prevents feasi ble alternative steam pasteurization .
0.89
4
air
6
Casing spent compost
:
0.64
thor
hold
for hours LaFrance Mummy nematodes are necessary between each problem this practice bygone years when boards were allowed crop
a 34
farm hygiene least once year for hours 160 at of
-
in
is
It
ing the air temperature 10
/
)
0.54
30
out
and the boards laid
the best interest oughly pasteurize the wood
minutes
(
new
)
liter 0.38
( g -
old
Casing soil :
92
,
,
is
to
.
all of
,
6 ).
is
(
II
Time
Density
-
3/4 ",
3/4 ",
Cypress wood unfinished
six
to
to
or
–
It
has been well moistened Material
Cypress wood unfinished
is
,
to
.
to
is
touch
takes much longer about five times longer spent compost for cypress heat than for soil heat Table For this reason the likelihood pasteurizing the internal portion the wood during Phase remote Considering factors seems pasteurize wood the best time when the beds trays are not filled with compost and the woodwork
– ° F,
145
° F .
steam
at
to
of
to
)
(
6.
Table Time minutes necessary increase the temperature using aerated four materials from room temperature 145
II
a
compost
?
moss
is
soil
,
Spent
.
Peat
to
14
29
21
,
II
to
,
26
209
temperatures
Loam
( % )
140
woodwork where the nematodes were able over crop How possible precise that The reason not Phase known but anyone who has entered room immediately after pasteurization knows that the com post cool handle yet the woodwork too hot
Treatment
( % )
( % )
.
° F
°
minutes
casing
?
in
from the infested bed boards the growing room Some cases were traced ineffective casing treat poor steam distribution during ment and some pasteurization but most came from infested Phase
( 0 ° F )
3
or
-
at
5.
Verticillium infected Table from three casing materials treated 140 209 days prior then infested with Verticillium spores
30
mushrooms harvested to for
of
Percentage
be is
60
to
45
,
° F .
4
° F
.
a
.
6
at
° F
almost anyone can pasteurization a
,
so
)
–
of
or
,
at
,
is
to
of
° F
.
,
-
is 2 or
a
in
if
,
a
in be
to
to
.
of
3
to
,
a
As
to
is of .
at
,
monitoring for pests axioms evaluate the effectiveness procedure
i
,
(
proce
By
for
.
temperature
compost
be ,
is a desired
woodwork Accurate dures except pasteurization monitoring temperatures during each pasteuriza pasteurization tion period the only way know guideline has occurred however shelf tray system the minimum time maintain 140 necessary With hours and times hours may casing when the coolest location forced air aer
growing room Wooden from shelves wooden trays and other wooden fixtures exposed least hours for steam 160 must unique and for this reason Each mushroom farm may necessitate modifying these temperatures the exposure holding time length the times and temperatures suggested are guidelines rather than spent
.
( 60 ° C )
all
Eliminating unwanted pests is called pasteurization , and it is a necessary part of compost preparation , cas ing treatment, and postcrop farm hygiene . Generally , 140 ° F
ated steam system reaches 140 minutes accomplish the goal Compost should adequate raised 140 and held for hours before removing -
SUMMARY
93
Managing Compost During Spawn Run and Cropping
so
-
80 ° F
of .
air
to
or
° F,
to
50
80 °
F .
to be
cool the com
If
the available compost maintain the .
in
or
60 °,
.
to
,
,
or
-
to
for
is
a
If
2
,
,
.
in
of
,
is
to
of
inches when pushed downward with the heel unlikely that compost tempera the hand then ture will maintained within the desired range packed tightly dur essential that the compost bed ing the spawning operation for the tighter the bed attempts adjust tempera the more effective will ture the compost This potential for greater control
of
.
.
to
be
,
be
It is
it
be
,
is
4
of
is
of
.
or
is
at
a
in
is
at
.
to
of
so
63
air ,
is
.
a
a
to
heat transfer through more dense material less dense material Another aspect heat that heat more easily transferred via compost with water than the temperature spawning unlikely percent less than water Temperatures compost controllable bed spawning can be controlled when the moisture higher Within this moisture percent cooling capacity for each 12.3 cubic range ton relates versus transfer
of
compost filled should handle the heat gener during spawn run supplements are added ated spawning more cooling capacity needed perhaps
at
,
is
If
yards
.
be
° F,
85
if
the cool air needed
68
ul to
.
-
as
optimum range
the
75º and
the proper range may not
1
If
.
a
in
a
as
° F .
83
is
it
air temperature may keep the
even
of
,
36 air
to
24
,
be
,
of
,
between
in
of
,
12
12
as
in
a
.
-
1
cooling necessary amount temperature available the second most important factors are the density and moisture content the compost mushroom bed the mushroom bed packed loosely i.e. the compost easily compresses
to
.
its
of
6
It
.
as
F in
°
is
a
be
8
to
in
a
of
or
even withstand these temperatures and are damaged the Thus for the compost temperature reaches important that com safety the mushroom crop
temperature
Sometimes post
,
a
at
air is at a
,
a a
If
.
°
5
for
withstanding temperatures high spawn higher cannot cultivars Other bit
rises no
.
, ,
.
in 8
,
is
,
its
,
on
to
to
.
of
capable
be
,
to
for
in
its
by
as
a
to
.
,
high compost temperature during the spawn grow ing period For example one strain spawn may
lowered
spawn growth
,
in
is
its
is
to
ex ,
In
.
of
If
be . ,
by
be
if
to
-
hr
maximum spawn growth and may timately result decrease mushroom quality Some mushroom cultivars will show tolerance
these factors Therefore
compost
growers know that each spawn has own rate growth and also own unique appearance during growth Further each spawn will cause the compost temperature increase certain time after spawn ing the time varies between days and de spawn used spawn strain the amount pending grower knows from experience and the compost growth spawn rate will increase the when the temperature should few degrees lowered rapid spawn growth prior not unusual dur ing the accelerated growth phase for compost tem peratures this hours little rise suit occurs the compost temperature will not able range
both have
the compost tem perature because the spawn grows much quicker rate and releases heat causing the compost tempera ture rise the room not cooled Experienced marked increase
temperature
that its
throughout the entire spawn grow
Some experienced mushroom growers seem per tempera plexed about the relationship between compost during temperature spawn growth ture and nothing temperature do with rate has little Air spawn growth mushroom quality but the compost temperature during spawn run can adversely affect to of
pe
in ,
° .F
of
At
75
° F .
at
,
.
will
there
managed
higher than ing period
to
80
between 75º and the com approximately post this the outset riod spawn grows slowly from each grain rather dependently other grains nutritious compost grow slowly spawn and texture seems the tremely fine not nutritious the the compost spawn will grow much more obvious and seem rapidly more reflected whiteness the com post The most common sequence compost colo spawn steady and perhaps slow nization days Thereafter spawn growth during the first
post
be
temperature
Spawn runs best
66
its
is usually spawned when
is
Compost
be
P.J. Wuest and D. J. Royse
95
air
is
it
of
of
ex
of an
of
by
.
is
a
is
.
,
,
,
,
–
is
in
a
.
In
a
air
of
or .air is
de
so
air
of
on
.
are
,
of
,
air
air .
to
be
as
as
air ;
on
)
(
.
is
is
at
,
as
is .
a
to
is
so
.
a
a
air
it,
pressure against the door when closing are simple adjustments which reduce the back pressure and per .
to
,
,
a
a
to
of
mit greater volumes move through room moving through room the greater the The more heat exchange and the more evaporation both phe nomena causing the compost temperatures de
frequency higher temperatures distribution spots are the majority warm then the tem perature should degree lowered two Con
dioxide CO2 content the room Carbon oxide enhances spawn growth and the use outside air will reduce the CO2 concentration Once the CO2 level lowered below 0.15 percent 1500 ppm
in
di
be ),
(
to
.
of
)
of
air .
a
.
(
of
.
a
.
.
to
Cooling ,
a
by
.
a
air
.
,
.
be
of
is
.
to
in
of
be
and
cooling compost moisture results surface drying The grower must de acceptable when adjusting cide how much drying through room The deci passing the volume tempered considering the conse sion should drying Before reviewing quences few conse drying realize that some water lost quences through evaporational cooling can replaced Re Evaporation but also leads
of of
).
,
occurs
Evaporation Relates
.
as
of
evaporation
,
,
dry
,
is
air
If
.
96
the
be
to
-
air
or
,
a
(
,
(
as
)
(
in
in
of
)
the compost
slowed The relationship spawn growth tween CO2 concentration and rate another consideration when planning strategy for compost temperature control during spawn run
spawn growth may
air
by
air
temperature causes the compost decrease when air exchanges the heat produced the compost latent heat well some the heat the compost materials specific heat Further the more air cooler drier than the room air moved through room the greater the amount heat removed from the room air and indirectly from to
Reducing the temperature
temperature
temperature
to
,
be a
new idea even though routinely used control compost
is
(
a
be
in
an
of
ume may
is
If
.
air
.
or 68 °
bit or
,
a
of
73 ° F ),
air
if
,
of
spots are cool the majority may the temperature increased the being volume air exhausted decreased either should cause increase the compost temperature adjusting compost temperature Control vol versely
is
.
bit of
be
a
of
or
on
to
or in
ture should sions on whether cool warm the air should based the average compost temperature and the
a
crease Flushing room with outside for compost temperature control will cause carbon reduction
be
be
air
of
,
for
-
be
of
to .
is
,
is
in
of
spawn growing different parts why tempera not the same and this measured numerous spots Deci
maximum output Opening exhaust cracking no there door few inches its
, a
in
on so
hr ,
6
to
F
2 °
1 °
or
4
,
a
or
in
is
work
dampers
rhythmic sequence with growth periods and rest periods each lasting the depending compost will heat cool the point the cycle when the temperature measured The rhythm the compost
air
8 -
to
Cooling
is
Spawn growing
volumes are needed control the compost temperature reducing the back pressure allows fan
greater
air
is
Related
the fan moves The output volume from other types fans reduced back pressure increases moving even though the fan the same speed and unchanged the electric consumption Thus when ,
.
a
be
to
a
to
to
.
is
a
-
to
of
a
at
be
a
6-
tronic thermometer équipped with inch probe should used monitor spawn run tempera day Such tures number sites twice device routinely monitored allows numerous spots preferable using which milk thermometer single location
or at
of
of
-
A
.
to
to 12
a
at
30
manager should spend every least minutes hours moving dairy thermometers from one spot another determine the range temperatures portable quick response elec within the compost
physical barriers that resist the they can force the considered act coun terforces that push against the These forces against the constitute back pressure and back pressure affects the output fans differently pending designed fan design Some fans air the volume that back pressure has little effect
floor which serve
of
,
.
in
, a
is
.
-
of
in
,
room houses two dairy thermometers the compost and left the same location throughout the duration the spawn running period When the grower can compost temperature rather uniform leave these thermometers one location However
,
In
?
-
measured
most mush are placed into
,
be
should compost temperature during the spawn growing period
Air
exhaust fan time the amount exiting The actual amount room can measured using anemometeric methods ventilation system equipped with fan that displaces energy air the air driven there the air Air pushed against the ducts walls doors ceiling and
dampers hausting
Where
air
-
to
through the managers move too little compost spawn running rooms good control temperature The relative amount air being moved noting the position exhaust can estimated be
MEASURING AND CONTROLLING TEMPERATURE
.
of
a
is
is ,
.
a
is
of
.
the brittleness
the compost compost the
cooling The greater another form the air volume moving through room and the drier the greater the total cooling effect on the com post With forced ventilation rather common
it
.
,
since the density
of
,
by
a
in
of
.
range
restricted
A
at
64
a
for
,
to
is
temperature
evaporation
for
yd
8.5
for
filling as much as 1 ton of cooling dry compost one below percent moisture will heat longer period than will more more rapidly and Dry compost packed tightly moist compost very manage maintaining desired difficult terms
–
to
If
76 F .
76 °
is
at
6
be
80 ° F .
1 °
F to
air
.
is
air
,
to or
F .
air
,
60 ° F
at
76 °
to
2 °
is
if
,
af
-
to
.
as
is to
°
° F
, 61
in
is
of
.
At
,
of
is
air
-
to
to
be
to
."
“
to
,
as
to
to
18
12
F
°
°
to
be
64
58
."
"
a
be
air in
a
is at
of
as
air .
,
air
in
in
be
on
,
.
at
or
a
,
or
to
to
62 ° F
68 °
or
in
air
is
.
air
to
to
of
,
to
.
of is
,
the strain form when the CO2 content between 750 and 1200 ppm The normal outdoor air ranges from 300 650 ppm bring room the amount outside air needed crop the desired CO2 level may vary from crop Determination the CO2 level best accomplished temper any event the with CO2 detector but ature when picking begins will approximate lower with the compost temperature the CO2 level
F .
at
re
.
is
depending
,
of
-
higher 2800 7500 ppm and may rooms that are tightly constructed where supplement was spawning casing Pins added the compost
,
a
between hours concurrently with induce pinning and they shocking events With
of
to
of
.
,
down sharply
refer these concurrent either procedure the growing room should smelling Carbon dioxide CO2 outdoor fresh during the later stages spawn levels the growing into the casing ususally concentration
air
is
It
,
be
.
to
of
is
,
brought perature must and for reducing the CO2 level
a
( 1
.
a
,
to
.
-
,
Once the spawn uniformly covers the casing surface fresh air must used reduce the CO2 content called form this induce pins the room air flushing There are people who think that tem
,
)
(
is
is
)
,
,
an
;
covering stricted from the compost when used The fundamental ideas for maintaining compost temperature have been described and these ideas are
Pinning
as
by
a
so
to
in
or
is
. "
"
in
in
use plastic sheets includes consideration factors other than water loss since virus infected mushroom spores egg laying insects and other pests are
fect and predict change
of
on
is
a
or ,
). ,
2
to
mils thickness inhibits evaporation and mini quite common mizes drying and this practice not unusual though find the plastic must re moved when the compost temperature starts rise often impossible with the since temperature control plastic place This practice removing the plastic provides insight into the amount heat dissipa Deciding whether ted via evaporational cooling
Two conditions apply
respectively then post temperatures are and manip control and has the ability the grower the goal desired This ulate compost temperature being able managed mushroom growing
of
.
by
of
to
to
is
Water moist travel into the cells the straw the pore spaces openings separated Several light waterings few hours will condition the compost water from heavier applications bound the compost rather than being free Unbound water free water undesirable hinders spawn growth and thus Covering spawned compost with plastic sheet
(
3
is
keep in mind that once compost dries , significantly reduced absorb water compost that sufficiently absorbed provide newly added water path which to
its
plying water ability
but the compost temperature has cooled either too much being introduced temperature the too low temperature The grower decides raise the keep the compost temperature between 75º and Temperatures should see hours checked after holding the air and com the compost still
to so
placement of water in the casing is easily done , but compost moisture can only be replaced at the com r . post surface , so there will be a net water loss when compost water evaporates . Adding water to compost may slow the crop and restrict mushroom improperly yields or reduce mushroom quality – the same result anticipated with overheating of compost during spawn run . Thus the advantage of maintaining desir able compost temperatures during spawn run can be lost if watering of the compost before casing is done improperly . Returning water to compost prior to casing requires one or two daily waterings using a misting nozzle . Compost drying can be minimized by thoroughly wetting floors and walls two or more times a day when the spawn is running . When ap *
a
to
or
It
to
at a to
quality mushroom Some strains
F
at
be
68 at 64 ° ° F .
to
is
The goal during the cooling period prior first break reduce the compost temperature rate as sure first break mushrooms are picked when the compost was once believed the com about high post had harvest cooler to
for
°
58
as
.
air
is
or on 66 ° F as
or
° F
64
the amount
;
of
related
to
in
.
,
(
of
)
-
F
66 °
at
is
the compost
is
is
on
12
to
air is
° F .
with the compost temperature Twelve hours later the air temperature
compost and first break picking begins this depends metabolic heat generated the amount the compost As explained earlier the heat left by
temperature about
60 ° F 9
in
Let assume that the heat has surged the com post between days after spawning and the 78
Iū
us
be
During Spawn Run
at
,
PRACTICAL SCENARIOS
68 °
at
to
do
.
is
not true first break but this produce higher quality tend mushrooms one compost temperature versus an quite adequate other but overall tem good quality mushrooms first break The when the low perature may ,
,
and
high
Before First Break
is -
air
,
temperature
ideal environment for
.
to
air so
compost
,
-
all
or
,
manage
provide moisture quality mushrooms
an
comes
to
,
is
by
air .
of
,
6
-
of
12
,
to
all
periods true for maximum heat production days after spawning the first few days after cas ing and the onset picking Compost temperature adjusting tempera controlled volume ture humidity three the challenge be
heat removed 97
,
air temperature but some composts are nutritionally spawn growth slows and little heat inadequate
is
so
via evaporation plus the heat exchanged between the compost and the air . Thus a grower concerned with rapid crop development while conserving energy , whether the energy is used to heat or to cool , must
air
,
.
of
As
is
.
air
in
an
,
.
in
to
.
air
is
or
,
air
.
in
a
,
,
volume and the air's moisture air temperature predictable content affect compost temperature all
-
for
.
or
they can calculate the average before deciding how ventilate and nurture the compost the crop
to so
.
of
as
An experienced
air
tempera grower may use during making gauge ture the decision stages the crop Knowledgable growers routinely spot throughout move thermometers from spot cropping temperatures measure the ranges way
of to
of
to
It or is
.
air
as
N
2 °
F
is
as
to
continue decline the crop ages unless the rate heat exchange reduced desirable maintain temperature compost the room more above the
,
.
,
hr )
to
24 -
(
12
may important but during harvest compost tem perature affects the crop much more than does temperature With experience growers learn that
to
.
)
to
,
temperature after first break since the crease the reduced compost temperature will decline due activity The compost temperature will metabolic
In
.
is
Compost temperature rather than temperature During the during spawn growing key the concern pin formation time temperature air
.
de
to
no ,
is
64 ° F .
air
be
is
By
.
,
a
is
crop managed properly compost tempera ture declines slowly between first and second break picked the compost the time the second break temperature may need There
(
SUMMARY
,
Later Breaks
98
there more evaporational cooling time the com predict post temperature will increase but the key compost temperature able growing insure that temperature throughout the crop remains above
be of
to
dur
.
-
the temperature desired
temperature increases the water the air can hold increases and
,
or
of
/
by
to
compost cools slowly ing first break picking
When
to air
-
F
°
a
-
)
,
air -
of
,
,
of
.
in
ble trait mushroom growing Experience with the the the bed moisture content strain compaction exchange phenomena and compost and casing other peculiarities each growing room allow practices management which the grower select
the amount is
68
to
°
66
(
"
"
,
,
at
during With the compost temperature providing picking factors and other ventilation first grow rapidly adequate are the mushroom will and push subsequent breaks keep coming desira
air to
the air
.
in
to
of
what self inhibiting
in
dioxide
air ,
monitor and control temperatures of the compost and addition the amount moisture and carbon
generated Excessive heat exchange may cause the same phenomenon identical temperature the temperature and the compost Increasing the induce the compost temperature upwards some
.
How to Manage the Watering of
Mushroom Crop
a
for
to
in
.
is
A
;
of
by
on
to
.
of
a
,
to
2
",
.
“ 1
, a
of
.
a
", 3 de "
,
of
to
4
,
of
is a
a of a
to
a
.
" 1 "
of
at
to
.
is
of
is
" 3 "
" 2 "
to
,
,
is
.
.
to
or
is on
is
at
in
to
at
it
,
it
so
.
of
or if if
for
by
.
ii is )
.
,
iii )
,
.
),
reduced
delayed
;
drastically
or
A
i )
of
production will
be
a
in
moved quickly enough over the casing surface the there not rhythmic and uniform and movement too much overlapping the watered area Once casing sealed becomes nonporous mushroom (
is
it
.
to
is
of
is
It
)
.
-
(
of
to
be
,
to
impor apply water Before discussing when applied and the mention how water should work habits the person applying water roseface water mush needed water break spray head desirable that the roseface produce room casing very fine stream water rather long high arc
tant
be
an
Water
is
Apply
is
to
How
dure dissipates the energy behind the water cing the water through arc like trajectory before the water falls gently onto the casing The most com mon failures during watering are the roseface not -
all
falls with too applied one time combination the two occurs The person doing the watering must invert the roseface that points and away from the casing rather than pointing directly the casing surface This proce at
than
be
.
to
an
as
rather
.
,
considered about watering inclusive watering schedule
Sealed Casing and Scratching Casing will seal the water falling much force too much water a
is i)
in
,
an
ii )
to
,
iii )
,
to
is
Watering the casing art that growers must judge when decide how much water water apply the water The needed and know how following comments are suggested factors
the left and
the final swipe made even closer the sideboard and Directing the water from the opposite direction the center the sideboard means that the person wa tering must move the spray head out assure that the water aimed the target area
up
be
is
WATERING
to
in
so
,
to
.
.
satisfactory crops
the rose moved from the right closer the sideboard and between
or
2
to
as
is
.
no
is
,
on
bring
cadence during watering tech manager can direct how much water
applied This means that during the count right starting water directed from left the center the bed Between the counts and
should " 1 , "
is
of
as
be
.
is
a
,
.
to
quate
gests that use nique whereby of
(
to
1
of
)
is
,
much use need there Further the deeper the casing the longer the interval between casing and picking More could said about casing but this general guideline ade
casing
a
f
a
depth measured after initial water has Normally casing adequate been applied 1.25 inches for most mushroom crops There are growers and much 1.75 farms where casing depth will usually found only where inches but such depth nothing peat moss the casing medium There layer casing deep herently wrong with but with
",
CASING
good management
a
be
.
2
about the casing layer are in order
,
statements
"
e
right and right face constantly from left left perhaps three passes per feet bed watering one person has half the width the surface Once veloped cadence movement pattern can followed for applying water Experience sug
in
1
quite acceptable for the task person applies water depends initial training and level supervision Some successful growers train watering personnel move the rose
How
is
* E
sealing the the initial waterings the potential casing thus minimized the water the force roseface with 750 1000 holes 0.01 inch diameter is
quality and speed of production are af fected by casing depth , moisture , and watering . The initial moisture content of casing , as well as how and when water is applied , affects the number of pins that form and the size and quality of the mushroom . Water and watering are frequently THE FACTORS that separate excellent growers from average growers , and ( as might be implied ) , can seem confusing if the overall goals of watering are not fully understood or implemented . Before getting into the watering , a few
Mushroom
for
Paul J. Wuest
99
different
Watering Different Cultivars a
of
of
withstanding heavy White mushrooms are capable pencil waterings when the pins are about the size a
at
of
.
in
)
(
Watering eraser approx 0.25 inch diameter cream cultivar the same rate will destroy most the pins Cream mushrooms must have pins that are
to
or
is
.
It
to
.
-
(
to to
is of
be
)
least twice that size about 0.5 inch before large quantities applied The rough white water can mushroom closer cream than white cultivars ap watering possible terms tolerance of
Scratching casing that contains spawn damages the mycelium , and this restricts the size of the devel oping mushrooms and may cause mushrooms to
.
.
belt - fed casing machine . Scratching is recommended by some growers ; others avoid the practice . A rule of thumb when scratching the casing is to restrict scratching to the depth where spawn has not grown .
for each cultivar
at
.
Some growers find it necessary to scratch the cas ing surface following initial applications of water be cause the casing is sealed . Sealing is common when peat is used , especially when the peat is applied by a
in
neither is desirable
When
How
.
a
ca
be at
of
.
of
as
a
is
to ,
,
is
to
;
of
it,
.
5
to
3
a
of
, to a
(
a
.
,
is
,
so
of
.
be
)
of
to
coarser
ap in
,
by
,
as ,
on
is
a
If
be
.
is
of to
to
,
a
,
a
at
The speed which crop grows i.e. the time inter val between breaks becomes decisive factor deciding when water and how much water ply The speed compost and the crop affected quickly temperatures coming break applied quickly and early perhaps water must early the last two picking days the previous of
it
a
.
no
a
to
,
a
be
may When break develops slowly then apply the water more slowly and over desirable longer period Under circumstances should cas break
by
is
an
it
re -
to
,
.
If
to
.
to
,
If
dry out completely ing allowed the casing be very comes dry the only way moisten casing with light repetitive waterings active spawn growth dries out the mycelium seems sur peat particles way that prevents water adsorption The casing has the appearance harboring grey mold but actually spawn Mushrooms growing on dry casing tend show
of
a
in
round the soil
to
.
is
it
,
They are light and pithy water stress symptoms spongy and the veils tend stretched The cap perpendicular appear bottoms stem since cap not fully rounded Mushrooms harvested from
the
to
.
be
to
.
.
is
with
even
Watering During the Crop
be
to
occur
or
" 1
, ",
2 “ 3
"
, "
“ 1
the initial buttons
.
"
,
-
of
on
-
likely
much less roseface
to
a
.
or
to
be
to
Once
thereafter during cropping
a
is
It
to
be
of
.
to
100
develop and roseface that provides 0.02 inch 1300 holes coarser water stream 1000 diameter can used The mushrooms and buttons break part the force the water and the extensive rhizomorph formation holds the casing sealing hours
)
is
is
.
be
it
of
be
to
be
is
" 1 " " 2 " " 3 "
at
of
.
an
apply when bringing much water first break something that has learned and it's usually
and thus becomes physically conditioned accept more water binding water usually requires
binds
as
.
to
is
;
.
it
,
of or
to
" 2 " _ " 3 "
applied the cadence increased from perhaps even the rose face does not but the movement pattern give change These numbers and dashes are used idea the speed which the arm the watering person moves Precisely when water and how
essential when applying more than one watering per day for the casing absorbs the first water and
.
–
or
or
up
so
to
a
or
In
a
in
,
,
light amount water during watering should
applied the day fast applied watering heavier can sealing the casing Delay much chance
be
be
a
.
to
as
it .
be
,
to
.
to
,
diately after casing and not during cropping watering suggested that this method tried and using throughout evaluated small area before an entire growing room may necessary After initial waterings water fog until pins appear Where such lightly mist
without
Water
second
-
to
is
If
.
its
no
it
,
it
bit ,
a
,
,
is in
A
to
day flood the casing after the water ab sorbed scratch the peat break the crust and re used imme the casing this method store texture
dence
is
.
up
.
it
so
to
,
,
will absorb water As the spawn enters the casing through the compost grows spawn from the The rapidly initially casing casing closer more dries the casing allowed the compost than elsewhere dry good ability will lose absorb water longer When this occurs will act water res ervoir mushrooms borne upon will soft and pithy and yields will reduced When too much stops water the casing spawn growth slows production spawn delays with resultant death apply initial water peat casing radical way
When the first water
.
at
as for as
as
to
,
to
,
at
is
It of is
it
is ,
its
to be it
all
.
-
.
it a
as
of
frequently the structure the casing permits days casing few until the contains much water can hold This volume water referred the holding capacity casing water essential that the receive the water can hold this time for the casing must always top that moist from bottom from surface where contacts the compost
Apply Enough
air
.
– –
as
of
,
or
,
or
is
applied immediately after casing Initial water least during the first second day after casing and applications additional water are continued
pins
(
to
Water
-
ply too much water too early with either the cream the rough white cultivar and thereby destroy the
all
form under the casing . Scratching works for some farmers and not for others , so scratching is not a prac tice recommended for mushroom operations
be
of
to
be
an
or
to a
.
at
all
,
in
a
at
no ,
of
be
.
at
or
.
At
far
on
off -
in
hr
24 -
,
or
be be
.
is
,
a
of
be a
to
of it
,
.
,
no
by
,
.
of
or
in
-
,
,
of
,
to
for
a
.
as
substitute
keen
a
,
is
.
to
in
be
,
a
.
If
.
here cannot
will record the changes along with information about how the mushrooms look before and after the water was applied Such reference can useful mak ing decisions about future crops .
to
re ,
as
-
,
-
a
If
at
so be
to
.
a
-
,
presented
sense observation and experience with how differ ent cultivars respond different watering patterns changed When watering pattern wise grower
F
t
of
many times
lines
of
A of
is
,
of
2
of
,
at or its as
.
“ 1 ” -“ 2 ” -" 3 "
.
in
is
to
;
a
i 11
needed the casing holding capacity mains moisture while the pins the first break mushrooms develop into buttons three
Overwatering can result pins and the death poorly mushrooms and underwatering poor waterings produce quality timed soft mush rooms Most growers learn through experience how water which roseface use and the frequency applications crop water the matures The guide small
a
to
“ 1 ", 2 ", “ 3 ”
its
.
a
in
aa
first break
waterings begins Morning and afternoon waterings are applied the cadence cream being grown water cultivar not applied this delay days will give the pins time time about pea After the initial first grow twice the size watering applied two break water will have
and the casing must moist but not wet This requirement can usually met watering fourth and subsequent breaks more fre quently than twice weekly preferably waiting until buttons have developed each successive break
.
air ;
60 ° 8 F
,
,
a
series
of
pencil eraser the first ,
a
size
of
,
:
to
,
is
;
is
to
.
to
,
If is
to
.
in
is
to
to
10
days and The compost has been cased for compost tem the air temperature has cooled going into the perature the lower 70s Fresh smell fresh the myce room causes the room air knitting together and pins are starting lium dry quick form the casing tends watering cadence prevent becoming needed overdry fogging the casing surface every second day and floors and walls should be an alternative soaked routinely minimize drying few days later when the pins white cultivar are about the
to
.
of
total picture
aa
make
dying pins especially with dead white and cream cultivars Many growers notice the abundance dead pins after second break and erroneously symptom think virus condition rather than water damage Less water needed with .
a
of
a
grower will see and what should developing will bring number
of to
bit
-
a
of –
55
4
–
or
or
a
a
,
a
crop factors together
to is
what
as
of
,
be A
scenario done
*
,
Temperature and Cropping
Water
If
.
in
of
of
.
to
-
-
.
;
.
be
up
to
,
is
a
a
by ),
by
8
it
.
heavier applications water can com mence These should continued until the casing again reaches good moisture level Repeated water ings during single day are better for the crop than single waterings successive days the same time too much water applied one time too period can result much water applied over buttons
a
;
in
-
of
of
10
if
-
by
or
)
Too much water applied cream off great number white cultivar this time will cause third break and dead pins depressed yields during fourth break production practically Once second break pins have matured into small vest
,
A .
10
of
to
of
,
8
.
as
bit
/ ft ?
lb
( : ·
(
break air temperatures cause the crop days quite short interval water must be added before the end the first break har
compost
.
to
.
for
bit
a
,
a
I
be
pected on second break , then water has replaced plus evaporation more This quan tity needed only for second break since subse quent breaks normally are not heavy gallon pounds the Im water weighs just more than pounds After cal perial gallon will weigh close culating the total pounds mushrooms harvested square feet times the total harvested area you can calculate the volume replacement water taking nine tenths this figure and dividing you're using Imperial gallons US gal is
&
0.9
-
lb of
*
.
may be used to determine this . are about 90 percent water , so a pound of harvested mushrooms per square foot of bed means that 0.9 lb of water has been removed from that same square foot. If an additional pound is ex
Mushrooms
on
A quasi -analytical rule
developing additional water may heavy break applied from the button stage the onset har vesting Watering should avoided during the har quality usually suffers vest period Second break pins form before first break mush applied rooms are harvested Water needs wards the end first break since the harvested mushrooms absorb much the water the casing
of
casing too dry during one stage of their development will have a good bit of casing attached to them ; this is especially true of first-break mushrooms . How much water should be added after first break ?
101
Some Thoughts on
CO , Control 2
in Mushroom Culture Lee C. Schisler
;
of
by
let
.
be
,
it
to
is
It
.
-
air
a
2
,
of
,
of
all
a
in
to
..
to
be
in
,
,
of
,
for
In
.
to
.
by
,
In
. A
)
(
air
ac
for
(
.
of
air
of
to
be
in -
an
re in
,
at
to
)
,
in
to
slightly ventilation can approximate 500 ppm increase ”
“
sizing mush levels which should assist rooms and facilitate picking This CO level should maintained throughout the remainder the pick ing period
CO
of
to
fresh
allowing
,
). .
.
to
be
adjusting
duced
.
of
in
an
to
of
be
(
CO
white strains this would
enlargement
,
.
.
be
,
of
This level CO should held constant until the enlargement mushrooms enter the rapid stage when caps reach 0.5 0.75 inch diameter The should then raised additional 500 ppm enhance enlargement the mushrooms For most
crease fresh introduction should follow thereby optimum pin reducing the CO level allow ning The proper CO level this point will vary cording the strain mushroom being grown After mushrooms begin enter their rapid stage
,
or
at
, I
I
-
.
or
2,
,
-
sup give you good figures for these Spawnmakers plying these strains generally have this information
higher CO2 levels 5000-15,000 ppm during spawn growth and immediately after casing sharp in
.
is
.
reducing the CO2 level with fresh White strains generally require 1000 ppm CO2 less whereas light cream strains will fruit 1500 ppm CO less As have had little experience with off white and old fashioned brown strains cannot
summary CO levels can mush controlled regulating ventilation room houses Ventilation procedures will vary from farm general farm however regulation ventilation should provide
.
in
air ,
.
or
,
,
,
of
the material used for casing depth the casing layer moisture content and temperature the mushroom house The house room then flushed
the stated levels will vary according the peculiar cultural properties you provide the crop
,
to
,
10
to for
on
6
is
of
CO2 levels should be maintained at between 5000 or 15,000 ppm during spawn growing , or that portion of the production cycle between casing and the ap pearance of mushroom mycelium on the casing layer . spawn The time normally required reach the days depending surface the casing from
the crop
After having said this me qualify stating that these levels especially those CO point inches above given for after casing are for the casing layer forced ventilation system important with good air distribution add that ,
ex
,
be based on their research and some practical periences of my own .
be
will
and maintaining that level until the end for light cream would 2000 ppm it
Many researchers have done extensive experiments with the effects of CO , ( carbon dioxide ) on mush room growth . The following generalities and remarks
1500 ppm
103
Organizing and Using the Penn State IPM Approach to Mushroom Pest Management
potential
on
.
of ,
,
to
is
of
of
a
to -
-
,
(
-
.
.
1
.
.
'
-
.
in
of
fly
on
,
.
-
–
or
.
on
.
A
. (
to
of
3, 4 ).
-
phorids move while sciarid movement
identification
with quick jerky movements
,
clue
to
,
:
also
a
ment
size alone Sciarid males are about the same adult phorid Fig Form adult move
less erratic
.
,
tion size
as by an
:
or
fly
of
G ,
,
,
,
"
."
or
,
have antennae that are easily seen Antennae the phorids are difficult caution identifica see
is
.
,
"
",
fly
or :
Wood the phorid little fly The disease pathogens are Verticillium fungicola Gams commonly speck and called Verticillium spot dry bubble Pseudomonas flourescens biotype the cause bacte rial blotch
in
two have been restricted pests and two disease pathogens The insect Lycoriella mali Fetch commonly pests are Sciaridae big called the sciarid and Phoridae Megaselia
is
to
Initially investigations
.
of to
.
a
;
ance
.
5 )
,
.
phorid pupae have cocoon like appear Both species pupate the compost stage The adult the two species differs several respects Female sciarid flies are larger and more rotund than the humpbacked adult phorid and
loosely
Consider the mushroom farm community
'
pest
control
to
tools
insect
|
As
.
-
on
to -
stem while phorid larvae remain the compost the two flies differ considerably The pupae Sciarid pupae have barely visible legs which hang of
.
and
.
4 )
Use IPM techniques populations
halterata
be
is
-
,
do
.
1
of
,
ture phorid larvae laid end end measure inch Sciarid larvae are often found inside the mushroom in
the actual
.
is
, (
.
-
span inch Phorid larvae are also whitish cover not have the black head Fig and segmental but Phorid larvae resemble the house fly maggot blunt one end and pointed the other Six ma a
or
on
.
/
,
,
,
3 )
based
the sciarid larvae becomes visible Phorid eggs are also whitish but oblong and concave Eggs either compost Fig are laid Sciarid larvae are whitish segmental and have black headed capsule Four larvae laid end end
on
include cli
to
-
Monitor the farm environment
mate disease immature insect and adult insect pop ulations and grower growing practices Make decisions damage levels
see the eggs time for hatch Sciarid eggs are whitish and oval approaches the distinctive black headed capsule
1 ).
an in
be
.
1 )
Acquire pest information
2 )
described
:
of
.
developed around this theme The Mushroom IPM program can terms the five steps involved
essential disease pathogens The two insect pests considered pass through four stages during their life cycles - egg larvae pupae and adult The latter three stages are easily recog required nized without lens but magnification
in
.
is
in
economically tolerable level ecologically accept able way The Penn State Mushroom IPM program
insects and the conditions which favor colonization and spread
a
as
an
to .
-
,
to
-e
,
agro
as
an
up
(
accurate managed
.
IPM ) ,
significant factors that make considers well cosystem acknowledges harmful manipu beneficial factors and determines how including pesticides An late the beneficial factors pest infestations program reduce should IPM
ment
based
knowledge about the organisms Knowing the biology and behavior
.
This concept, called Integrated Pest Manage
.
all
peared
management
pest
Effective
.
was accepted . Such a dependence on chemicals led to undesired side effects , and alternatives were sought . About 1970 , a new concept of pest control ap
ACQUIRING PEST INFORMATION
,
community initiated called the " Pesticide Age , " a time upon pesticides to produce crops agricultural
,
subsequent use of DDT and other
2 )
The discovery and pesticides by the what is commonly when dependence
I.
P.J. Wuest , R.J. Finley , D.L. Rinker , A. Napkil , D.J. Royse , R. Tetrault , and R.J. Snetsinger
105
to
an
a
few
is
;
;
-
;
-
time
longer for the phorid
the sciarid
longer
the phorid
.
Total generation
for
time
-d
);
.
Pupae development
longer
for
time
is
evelopment
longer for the sciarid is
2 )
Larvae
time
is
1 )
Egg development
3 ) mushroom
are repeated here
4 )
on
)
right
page 35
.
and phonial egg
(
left )
1. Sciarid egg (
mycelium
(
the Commercial Mushroom
generalizations
FIGURE
in
is
of
.
cant Insects
in
;
to
an
,
Besides knowing what flies are present growers should know something about the development time needed for insect evolve from one stage greatly other this varies with temperature for each Signifi Development insect described detail
patterns significant program Sciarids
Both species exhibit behavioral management
.
a
when devising
° F
,
to
.
on
as
as
air
II
enter the mushroom house during Phase cooldown temperature drops soon the below 110 and lay their eggs the unspawned compost
4
,
of es .
a
on to
to
,
of
.
lay
5
or
,
or
Phorids infest the house only after the beds trays have been spawned the greatest numbers entering days after spawning and lesser extent after casing Phorids eggs only spawned compost Lastly adults light both species are attracted
.
is
,
Verticillium disease has several recognizable dry An often encountered symptom pin the disrupted growth button into
-
"
blow out -
"
is
stem shatters
the
and
a
bit
a
or
grape
)
stipe stem the cap tilts (
is
a
.
-
,
of
a
bubble ball like mass generally the size larger Another common symptom ,
or
symptoms
of
mush
-
below
.
larva
)
and sciarid
(
)
(
above
.
2.
Phorid larva room mycelium FIGURE
on
.
teristics
by
,
pecially fluorescent black light with the exception light the sciarid adult male which not attracted Disease pathogens likewise have distinctive charac
.
or
a
in
.
.
.
of
be
,
a
.
and requirements designing and in
,
to
program
.
,
is
in
a
important
re
a
of
.
)
(
is
of
but one phase successful pest management control program Information garding when colonization occurs the size the ini ,
.fly
4.
behavior
THE FARM ENVIRONMENT
MONITORING -
106
on a
,
a
hr
.
or
.
12
to of
6
II .
management
Identifying pests Adult female phorid
a
on
It
of
Keeping the biology the pests mind
executing
FIGURE
,
by by
or
on
or
,
picker Usually the water hands tools spores are spread flies particularly the phorid Blotch caused bacteria on the mushroom cap often appears the sides and lower edges the mushrooms Typically blotch has bronze color but yellowish cast cap splitting the cap may signs the disease The pathogen needs wet cap for for disease occur is
.
right sciarid flies )
and female
(
left
)
Adult male
(
FIGURE
3.
.
of on
,
on
.
a
is
fly
A
it
of
in
of
a
as
be
on
(
5 ).
Many times the fungus pathogen can Fig seen fruiting infected tissue the cap where greyish hue appears less the infected area speck recognized form the disease called spot Spots develop when the pathogen infects single site the cap which develops into discrete splashed spot The pathogen arrives the cap slightly
hl. db
7
b
db
for
thermograph used
temperature
to
monitor compost
temperature
day period
.
continuously
.
of
,
to
in
of
understanding the rhythms aids insect and dis and pest movement from farm ease development farm Disease Monitoring of
or
as
.
-
a
in
a
of
beds
).
24
locations per standard growing room
(
at
is
of
Counting
total
all
.
,
The eight locations are equally divided between the four lower and four upper beds Occasionally growing room are assessed for dis mushrooms ease occurrence Such extensive assessments provide data the pattern disease spread throughout growing room a
areas
of
more prevalent
in
a
of
tends
be
Verticillium
to
at
of for
,
.
-d
,
dom
the
.
7 .)
(
to
DE
.
,
at
.
the
die E
counted
blotch are recorded mushrooms number eight somewhat ran done
Verticillium
of
.
6 )
to
(
a
.
,
In
addition outdoor climatological data are availa many ble from U.S.Weather Service offices located airports The Philadelphia International Airport and provide such data airport Dover south signifi eastern Pennsylvania Weather information cance includes wind direction and speed precipita tion and degree ay values Climate information
symptoms percentage
in
rela
.
and
growing room Fig tive humidity Thermo graphs are also used regularly record compost Thermograph devices are equipped temperature with remote sensors measure bed temperature continually throughout every day Fig
Disease monitoring begins with sampling the mush picking for rooms the beds on the heaviest day strip each flush Mushrooms foot wide across the bed are counted and inspected Those showing on
hygro
.
air
in to
is
monitored continuous use thermographs temperature measure
on
Climate
of
Monitoring the Climate by
hy
.
.
of
an
,
the future size and predictions tial population integral part any man the pest population are agement program Monitoring pest populations pro vides this information
.
on
is
as a
as
-
on a
( m )
or
on
( ov )
5b . .
FIGURE
for a 7 -
m
mating Sciarid flies ovipositing mush Verticillium infested mush room cap When these flies are vectors for the Verticillium fungus and the result rooms they act usually the symptom known spot FIGURE
in use in a mushroom house to and relative humidity continuously
air
OV
A hygrothermograph
.
a
monitor week
the
FIGURE 6.
A
The various symptoms of Verticillium disease : dry bubble ( db ) , spot (s), hairlip (hl ) , bubble (b ) .
FIGURE 5a .
107
dry
dry within watering hours cer tain beds areas beds repeatedly show high probably change blotch incidence there need circulation patterns within the room
Determine the potential threat very early the crop before
rou
As
in at ,
.
in
at
i)
iv )
;
at
;
iii )
:
.
of
;
ii )
.
is
or
,
in
"
or
at a
one
time
the crop
.
of
of
pest control
in at
.
at to
:
1 )
"
Evaluate the efficacy agement practices
pest
man
,
by , a
.
If
,
of
),
,
.
is
in
be
,
(
of
or
,
a
in to
a
of
fill
of
by
–-
,
in
.
a
or
and endboard
--
,
a
in
.
-
in -
of
,
5
percent areas represents about exposed compost yet the majority room generation the first emerges from house hatch these areas all
).
it
.
in
;
.
to
is
ft )
8
spawning machine compacted ing conveyors compost plus the compost This compacted layer side-
to
in
III
(
was
Raising endboards sideboard close door often layer compacted compost reveals contact with compost falling from the bedboards the result of
an
lating the Economic Threshold and Action Thresh maturing old when correlated with insect damage mushrooms See heading later this section
program
compost along the track alley exposed by the cracks between the sideboards and the bottom .
is
by
by
.
of
.
in
listed the Appendix Insects are counted micro scope and the number recorded species and stage development This information then permits calcu
tight
a
. – is
of
,
Fordyce and Cantello very more detailed account the procedure
of
At is
–
A
.
developed
by ,
.
,
process useful
or
is
sugar solution centrifuged added and the sample again The immature insects pupae larvae float on the sugar solution while the residue sinks This
IPM
few open cracks etc most the flies will enter through open doors and the greatest num eggs will ber laid the first and second sections the beds Egg laying most frequent house
or of
.
8 )
;
(
a
,
of
doors inward towards the center the room then placed into plastic bag and thoroughly mixed Fig Fifty grams are washed and centrifuged then
the mushroom
initial sampling locations for larvae were chosen random draw Intensive sampling several rooms proved the initial assumption invalid instead most lay eggs immediately upon entering flies begin
4
to
8
or
casing adjacent feet within the
to
4
it .
of
cessing Samples compost aisles are collected from beds
(
a
of
,
,
of
eggs larvae and pupae consists collecting the sample and pro process
--
-
step
of
Monitoring
the onset
assumed that flies entered the growing room and laid their eggs randomly throughout the room As such
in
Immature Insect Monitoring two
from
.
the crop
Relate the number larvae monitored adults future time
with the number
of
-
of
at
or
(
of )
to
dence loss
crop
the
casing time
.
in
or
at
,
least reduce the inci can eliminate the disease and prevent serious economic
treating
worms
2 )
.
Locating areas within each room where disease routinely occurs and treating removing the spot fected mushrooms the first sign disease
to
)
re
If
to
a
is
,
of
air -
,
.
4
to
or
,
of
be
by
.
.
in an
of
to
mushrooms
Forecasting
3
to
.
to
;
be
as
,
.
Stress can result from excessive
af pe
ing around the sideboards such occurs with rimeter steam pipes mushrooms most likely fected are those closest the steam pipes Another form moisture stress occurs when the casing mains wet over extended period Verticillium this condition flourish seems effectively controlled encouraging Blotch can
insect damage is another way to explain why intermittent counts of immature insects and tine counts adult insects are recommended sessment for immature insects should occur spawning pin set and before casing second break The monitoring schedule for adult sects outlined the next section To summarize monitoring for immature insect numbers allows one
moisture stress
in
an
)
(
.
be
Knowing where the first eggs are laid identifies tar get areas for pesticide usage Treatment might wa tering drenching insecticide into the compost .
of
contact with the endboards and the first two sections sideboard for each bed The insecticides malathion
,
at
to
.
12
to
or
be
a
or
if
at
label rates are most effective applied these areas day two before spawning applied spawning while Apex can these areas days later up to
and diazinon used
108
to
if
is
in
If
,
that
holes and cracks
be
for
is
.
be
requires
.
for
a
be
board drench
all
.
sampling
sample Collecting The sideboard has extraction the compost most likely infested available to
been raised
so
FIGURE
8.
,
.
is a
be
A
cautionary note needed this limited area procedural change from drenching drenched the entire bed surface there are open cracks walls and roof flies enter through these openings and the sideboard and lay eggs almost everywhere inadequate drench will Success with the side
open doors
the
If
entry
.
to restrict
to
fly
,
of
the flies enter through the doors
as
be
deposition sites and patterns can identified sessing larva and pupa numbers Once the locations where eggs have been laid are known insecticides can be targeted these areas important that each room assessed for tightness Egg laying patterns are quite likely vary from room room the same farm and cer tainly between farms This means that patterns need be
.
-
at
to for
If
.
,
fly
Adult
and periodically veri larva and pupa populations treatment sites must change
each room
,
to
identified fied by assessing the pattern changes
down , and remain operative at least through spawn run , and preferably through the entire cropping pe riod . Monitors positioned outside where flies normally roost and in the breezeway provide num of the " background " – naturally oc population level , and may measure the ef
bers reflective
-
curring
fectiveness of an outside control program . Accurate records of daily catches ( Fig 10 ) are needed to evalu ate present control programs and future strategies . Wetzel devised a logbook form for this purpose , and another for logging pesticide 115 ) . These can be duplicated
usage
( pages
if desired
114 and
.
.
be
.
,
."
"
to
is
It
to
,
i
.
-
ma
egg
by
plugged
jority
Monitoring
Insect
the paper
on
.
fly -
a
(
oper Pennsylvania Mushroom Fly Monitor PMFM infested house The black specks flies
one day within
.
,
ation
.
,
at
.
of
a
,1
of
FIGURE
A
.
,
be
;
in
of
1 )
Determination invasion sites Generally the wharf end room the upper level has consider ably more flies than does the breezeway end How
2 )
I
are
to
or
a
.
the species present Identification the room when species are known control measures can de signed more effectively
for 9.
at
is
an
.
as is
;
a
by
it
as
to
.
I
TIN
sticky surface tractant and water retain the several serves Monitoring flies insects adult purposes
) in
of
of
monitoring involves assessing The fourth type population levels the adult female sciarid and adult male and female phorid the adult male sciarid less easy rarely flies Monitoring monitor accom using plished fluorescent black light
,
an
13
breezeways often weather movement between rooms .
a
fly
severely cold bridge for
as in
,
of
,
.
if
of
fly
Grower Growing Practice Monitoring of
of
monitoring involves the grower and The final type growing practices This monitoring takes the form all
an
of
,
.
be
to
9 )
,
(
).
,
on
phases crop extensive questionnaire covering from composting through harvest and cleanup Questions address cultural and pesticide practices plus yield information Once significant
production .
in
for
,
al .
et
a
tion entitled Integrated Pest Management Mushroom page 61 The monitor Fig Farming should placed the wharf wall upper level prior cool
(
é
by
Currently the Penn State Mushroom IPM project monitor illustrated Wetzel the sec
uses
1
fly
are
it
.
the
in
fly
a
”
.
low during
hr
on
specks
daily count and recording essential management black The absence population was sticky paper suggests that period before the count was made aid
.
.
on
a
to
of
.
5 ) 1
Making
of
organisms with the poten Reveals the presence tial for biological control Phorids are being investi gated naturally occurring determine the effect population levels endoparasitic nematode
FIGURE
monitoring
the is the" to 24 -
.
be
,
aa
be
from management strategies and determine pesticide effectiveness and may tool through which indi vidual worker effectiveness can measured
10.
or
,
to -
in
,
- be to -
.
to -
,
to -
.
4 )
Evaluates present management programs Com parisons can made control strategies from room crop grower crop grower room season season Monitoring can eliminate the guesswork
/
1
,
.
1
.
it
)
Provides accurate schedule insect activity making easier select the optimum time for cor rective action Growers often say they have no flies until they apply casing Actually these flies are the first generation emerging and usually are not invad ing adults to
m
,
ever serve
cropping factors affecting pest management are iden 109
.
a
Fly fly
.
,
of
fly
,
in
it
is
.
to
Fly Exclusion The most effective way handle problem avoid the problem from the start proofing against invading adults solves the problem begins Cracks before walls around air condi tioners and pipes are usual routes initial inva (
11 )
sion Putting netting over doors Fig and limiting the amount traffic into room critical times can greatly reduce the possibility infestation Moni toring helps determine the tightness room and at
management
.
a
of
"
"
doorway
.
of
a
"
"
of
the effectiveness
:
of
on
.
Even if Economic Threshold levels cannot be com puted , Action Levels can be decided upon by pre vious experiences with pests . Action Levels refer to " doing something " when pest levels reach a prede termined size or incidence known to be deleterious to the crop Suggested Action Threshold levels adult flies the Penn State Mushroom Fly Monitor are
growers
of
pest population , the dollar return will not equal or ex ceed the dollar invested in pesticides or other man agement activity , and would not be cost effective .
available
.
Once monitoring techniques have been initiated and a farmer has confidence in the accuracy of the daily readings plus the compiled records , the next step is to make management decisions after considering the ec onomic feasibility of one or more management prac tices that are available . In other words , an Economic Threshold level must be determined . Below a certain
to
ily
The fourth procedure involved in the execution of Mushroom IPM is not actually a step , but rather the selection , integration , and implementation of several individual control techniques into a whole system . Some tools and techniques are well known and read
to
BASED
ON THE DETERMINATION OF ECONOMIC LEVELS OF DAMAGE
TO MANIPULATE PEST POPULATIONS
1 )
III . DECISION - MAKING
IV . TECHNIQUES AND TOOLS
.
tified , excerpts from the questionnaire will be pub lished as a checklist for a quality assurance system in crop and pest management .
on
or
,
is
cooler than day each before spawning
.
spawn run
.
-
of
the remainder
per day after casing
.
40
to
Thirty
for
4
2 )
Fifteen per day
3 )
to
one two flies days after spawning
° F
1 )
When growing room temperature
110
,
.
of
to
as
wide problem
a
in
at
flyas
in
as
.
fly
to
of
at
Threshold levels different stages the crop vary determine their own and growers are encouraged populations Economic Threshold levels Greater potentially dam later the cropping cycle are not production However aging earlier periods large populations one room may pose farm
,
-
;
-
is a
,
to
.
to
.
,
flies are mobile and can move other rooms Flies can also carry disease causing pathogens and mites from place place Both flies and especially the phorid are attracted Verticil fly lands on an infected lium infected mushrooms )
of
(
a
.
,
mushroom and thereafter vector transporter the pathogen Economic Thresholds for Verticillium and bacterial
110
11.
in
.
to
A
.
the
to
be
it
so
is
to
a
it
a
;
to
,
be theis the
a
A
-
is
the
.
of
stage
of
the harvesting
.
.
either disease early crop
in
of
to
olds for both diseases are known farmers who rec ognize the gravity even the slightest occurrence
door standard double mushroom house screened with fine mesh cloth prevents flies from entering Note also procedure used netting install narrow furring strip wrapped with the netting then and the screen are stapled doorway filled with door jamb How can fixed netting entered can't and this what directs the traffic one doorway hung pushed away provide where netting that can entry the room FIGURE
? It
to
.
,
be
defining the sessed then attention will directed Economic Threshold for each disease Action Thresh
to
.
be
as
a
in
to
.
is
partially due blotch have not been established This difficulty establishing routine representative sampling procedure Once disease can reliably
.
.
,
fly
of
is
at
of
.
of
-
in
.
to
of
or
be
.
off -
.
. ,
by
.
to
be
.
,
an
to
of
a
,
,
of
.
to
"
,
.
of
at
'
,
,
.
of
C.
of
A
,
be
used
.
is
warm
mush
.
"
from each extended permitted room farmers who their rooms research and development IPM
to
.
acknowledged us
gratefully of
thank you
is
PA
,
Square
of
.
,
fly
,
committee individuals from the industry provided direction for the project The assistance Dr. For Longwood Biological Laboratory dyce Kennett
Jr. ,
in
is
of
a
and
Funds for this project originated from the USDA IPM Project the American Mushroom Institute the Cana dian Mushroom Growers Association and the Agriculture College Penn State An advisory
,
of to
of
at
fly
of
.
to
.
be
,
“
4
-
be
to
air
,
,
be
,
more enlightened
Acknowledgments
" 1 /
.
F
°
as
by
a
.
a
of
day when peak restricted the time movement occurs inside growing room when adult flies are the target For maximum effectiveness larva applied when larvae are susceptible cides must Outside sprays are most effective when flies are rest ing swarming and roosting
Age
age more effective pest control Pesticide
for
of
at (
as
,
.
Insecticides have value when used the end crop þefore pasteurizing prevent move temperature ment between rooms when creased for pasteurization Application insecticides
should
to
of
in
to
be
-
.
.
as -
.
at
all by
of
hr )
Pesticide Use Pesticide usage might restricted level suggesting Threshold Economic the events damage will occur moni the use determined
6 )
V. BROAD CONSIDERATIONS OF THE MUSHROOM FARM COMMUNITY .
-
,
is
an
of
an
as
,
Finally consider the entire mushroom farm commu agro ecosystem nity An isolated farm has the quickly controlling pest problems but best chance mushroom farming not always isolated busi ness and some isolated farms have continuing pest .
a
,
,
at
-
.
,
Far too often the pest management prac another farm tices one farm affect pest problems probably has certain farm Each room block and problems of
|
is
as
.
)
5
Crop Termination Fly control the end the crop equally important that during cropping Treat steaming off 140 compost for ment houses stages kills flies well disease causing fungi and bacteria
tors
.
,
of
with precise record keeping can greatly improve present pest management programs Knowledge not eventually lost and then needs redis shared willingness covered Foresight cooperation and integrated accept new ideas will permit the use progression the management from pest and is
be
of
.
lot of
a
.
is is
if of
.
a
should
better management practices The sharing and con knowledge gained experience mostly years observation and experience coupled
solidation
of
.
of
,
be
or
fly damage Floors and breezeways regular basis cleaned on
The success IPM depends effective monitoring grower cooperation can only aid Second grower ,
con
else
somewhere
to
.
in fly
is
for
trol and for disease control Flies can breed the Re discarded mushrooms butts and fragments desirable Beds trash moval and prompt disposal especially should trashed there disease
occurring
phenomena
In Conclusion on
at
of
of
its
to
important
negated
to -
to
of
by
by
Good sanitation
.
4 )
Sanitation
the downwind the size increase background populations The wise pest management manager should aware his neighbor's practices anticipate and problems and adjust his programs expected problems from farm sources The most amplified effective management program can ,
.
a
.
temperatures reduces the possibility eco damage increasing the number days re complete one generation life cycle
2
warm nomic quired
producing
of
,
to
in
of
new generation Higher temperatures occur the compost during spawn run and after casing when compared the days harvest period Reducing the number
the direction peak periods the wind Wind carry some the flies downwind
-
.
(
°
F
into mature
evolve
of
fly
.
in
)
more time larvae need capable producing
adults
-
·
:
#
the
The fewer days lar optimum spawn running tem comparison with cooler temperatures run and casing 75
spawn
at -
3 )
Short
vae are kept perature
populations may vary
background and speed activity will
in
air
and
ade
insure
pests called the background population number These populations are specific for each farm and will crop and season vary from crop season Breeze way and outdoor monitors aid establishing the background levels insect populations One reason
an
.
for
monitored
Phase
to
Rooms should
bed temperatures throughout quate pasteurization
II
.
*
.
mold fungi
be
°
F
of
all
of
by
of Phase II . Compost temperatures in excess stages Temper 130 ° F for a few hours kill flies at teatures about 140 kill most disease and weed
2 ) Control
111
so
to
the the
cups
getting
,
in
.
lot for of
a
sample includes samples
two
25 g
into
If
.
50 g
a
sample
is
of
,
3
5 )
of
processing
break
it
moss
,
1 )
Sample preparation
Weigh out
avoid
Balance the centrifuge tubes contain the same minutes until volume then centrifuge for about the bottom concentrated most the particulate the tube
PROCEDURES
peat
to
.
.up
samples mixed
plastic
as
of
be
,
transferred Label the cups
short term storage -
for
stream water from two samples are being
If
.
,
Extraction of Fly Eggs , Larvae , Pupae , and from Mushroom Compost and Casing Soil by a Centrifuged - Sugar Flotation Method . Nematodes
into
more than 80 ml )
a
4 ) Tease the residue ( no centrifuge tubes using wash bottle more than sessed the residue can
all
APPENDIX
in
it .
.
,
mesh sieve Gently stir the sample while rinsing that nematodes and larvae will flush from
so
.
,
-
2 )
or
casing sample the kitchen Place the compost strainer and the 400 mesh sieve atop the plastic bucket Gently rinse the sample with water taking care that the rinse water passes through the 400
off
PIC
the side
.
the tube
.
of
sticking
to
6 )
Carefully pour water from each tube Rotating while pouring prevents floating particulate from
so
1
,
liquid
112
off
(
it
.
(
of
aa
to
a
-
on
)
or
sugar Pour the upper inch inch and half thoroughly clean reverse water onto one spot rinsed and washed 400 mesh sieve Top rinse the residue thoroughly with tap water and transfer it
into one location
.
,
to
-
to
a
3 )
Use slow stream water from the hose the wash bottle reverse flush the residue on the 400 push the residue mesh sieve and use the stream
9 )
of
.
tain the same amount minute
they all con then centrifuge for
their retainers of
Balance the tubes
in
8 )
.
it
so
.
to
g
to )
of
1
to
in
(
7 )
granulated Add the sugar solution 375 400 sugar dissolved liter water the tubes Use gently stir the residue the spatula that mixes throughout the sugar solution
common screen wire kitchen type -
Strainer
,
EQUIPMENT AND MATERIALS REQUIRED
-
or oz ,
(
mesh
,
3 -
to
ft
to 6-
length
with faucet attachment
plastic
or
8 -
inch )
)
-
)
)
-t
g
-
50
400
granular
)
/
(
Sugar water solution 375 sugar liter
g
or
ml ,
binocular ype weighing samples to
balance
for
or
Scale
for nematodes
microscope
,
400 mesh
Dissecting
for centrifuge
(
,
plastic 40-
(
Tubes
simple table top model 80 -
Centrifuge machine
,
,
5 -
(
,
or
(
, 1 -
,
liter need one two plastic squeeze type one two mm grid etched on bottom Petri dishes Bottles
Sieve
.
on
.
for
metal
-
.
to
a
2 )
Select black stage and 40x 60x magnification the microscope Set the petri dish the stage
Bottles
,
or
,
,
to
-
or
.)
,
its
1)
,
Take a clean etched petri dish . ( If the dish is not etched , scratch a 5 -mm grid on outside bottom sur sharp face using dissecting needle razor blade pen knife Transfer the residue material from the plastic cup 400 mesh sieve the petri dish
Spatula
hose
,
Garden
,
Counting
2
)
400
-
same diameter
,
5 -
,
gal plastic Bucket nematode sieve
as
to
-
,
,
Timer kitchen type Cups disposable plastic Crayon felt tip marker label cups 8 -
contains larvae , eggs , pupae , nematodes ) into labeled plastic cups or a counting ( petri ) dish by reverse z 2 washing with the plastic squeeze bottle . 2
).
of
;
(
3 )
,
of
Using top lighting count the larvae and pupae each species sciarid larvae have distinguishing black phorid larvae are opaque Move the heads heads .
.
in
,
4 )
After counting clean the petri dish thoroughly avoid contamination future counts
to
.
petri dish under the lens until the entire sample has been counted Record counts for future reference
113
THEPENNSYL
STATE LVANIA
-
UNIVERSITY
(
Room No.
8
-
-6 -5
9
Number and Name of Flies
+
Date
+
Day
Day
PENNSYLVANIA MUSHROOM FLY MONITOR RECORDS
1886
Date
Number and Name of Flies
4
+10
-
-
Block No.
The Pennsylvania State University
+11
-2
+12
-1
+13
Spawning
+14
+1
+15
+2
+16
+3
+17
+4
+18
+5
+19
+6
+20
+7
+21
-
-3
SCIARID FLY WING
Record daily counts from the monitor for days thru +21 from spawning Note whether the flies are Cecid Phorid Sciarid
114
,
C )
=
.
=
S )
(
or
,
P )
helpful
insect identification
.
10X hand lens will
in
:
Note
A
(
be =
(
.
6
–
-
:
Instructions For Use
fly
PHORID FLY WING
CECID FLY WING
The Pennsylvania
STATE TE
—
Room No ..
MUSHROOM FARM Week Pesticide Usage Record Week
of
Week
of
-
2
1855
RSITY
-
THE
UNE
Block No.
State University
Sunday
Monday
Tuesday
Wednesday
Thursday
Friday
,
.
(
s )
.
of
(
s )
Record pesticide used formulation application and rate Also record any unusual situation (s )
:
Instructions For Use
( s ),
Saturday
115
Glossary of Technical Terms
in
is
by
;
–
a
of on
,
a
–
is
on
.
.
to
air
.
,
in
,
in
of
to
'
is '
be
a
to
is
is
be ex
;
be
.
an
to
.
,
is
to of
is
if
of
.
to
.
-
as
in a
i.e. ,
by
;
of
–
of
do
,
to
.
,
.
-
of
a
a
of
sul
calcium
for
of
)
. (
,
,
in is a is
-
naturally occurring mineral consisting
,
is
its
a
–
of
or
black organic constituent
of
mycelium the basic unit ;
singular strand
nutrients
.
a
dark brown containing valuable
the
fun
.
gal thallus
pest
to
infesta basic
.
and cultural methods
for
procedure is
systematic
the effect
of
–
)
(
,
,
tions Emphasis upon sanitation the IPM concept .
a a
INTEGRATED PEST MANAGEMENT IPM evaluating and minimizing detecting
a
to
6-
,
, a
of or
as a
on a
for
in a
SUBSTANCE compost
of
soil
a
HUMIC
-
shelves
of
.
to
.
be a '
to
.
is a
flocculating agent fate Gypsum mushroom compost and conditioningʻ agent Gypsum such considered used compost becoming greasy reduce the tendency very undesirable condition
HYPHAE
is
:
.
of
–
in
to ,
.
GYPSUM
or
for
-
from out
or
,
is
,
to
beds
of
.
by
moved
.
,
which compost composting trays
Each peak harvest known break bloom the time when the first mushrooms
crop are harvested
network
, is
.
;
growing room
the standard
rhythmic pulse with peak mushrooms develop mature mushrooms available harvest
and first break
mycelium from the initial strand propagule and the germ tube develops turn develops and branches out into interconnected mycelial strands see THALLUS germ tube
fungal spore The spore into mycelium which .
to
in
is
used
cropping but be
is
of .
9 -
day cycle
flush
GERM TUBE
–
as of it
of
often
.
II
FIRST BREAK numbers
I
procedure
other
green plants Green plants are referred than that required autotrophic organisms since they can convert elemental material array into nutritious life sustaining substances a
-
of
for
at
is
ft ?
the
on
of
growing surface 8000 Pennsylvania mushroom farms
doors following Phase Phase composting
plants that lack chlorophyll the sub plants green Because the absence chlorophyll fungi convert elemental not have the capacity Fungi are thus called heter chemicals into complex life substances otrophic plants they must obtain food more complex form group
of
of
a
In
.
--
-
the pasteurization process the end fore the compost removed from the room
describe
FILLING
that makes
important since gases must develop into mushrooms
casing
a
.
its
by
is
a
.
compost prep North used
a
secular word for the second phase aration deammonification and pasteurization America Great Britain and on the continent
DOUBLE
large
stance
an
of
a
-
a
to
COOK OUT
FUNGI
-
in a
small particles
suspension and often ,
solution and
a
of
extremely
pos organic and inorganic substances mixture sessing nutrient quality unique from constituents Mushroom compost managing the degradation plant materials made plus nitrogenous substances and conditioning agent gypsum produce food selectively favorable the growth the com mercial mushroom
COMPOST
The friability spawn
change
exchanged
in as
of a
state intermediate between gelatinous consistency
a
composed
.
a
substance
gener easily crumbled Clay loam soil when very wet FRIABLE plowed otherwise the soil parti ally not friable and should not impervious clay that inhibits gas cles stick together form
.
to
an
)
to a
by
(
a
to
of
microorgranism degrade the ability break down cellulose less complex compound usually achieved organism's capacity produce the necessary enzyme COLLOID
many times higher than that occurring nature while pins will high concentration not form such CO2 Thus the room grown which the crop flushed with fresh reduce the CO2 concentration and induce pin formation
a
.
-
CELLULOLYTIC
exclusively vegetative green celium which like leaves plant rhizomorphs which are binding together mycelial strands and which pins form and the mushroom itself the fruit body Mycelial growth stimulated CO2 concentrations
-
to ,
18
to
,
–
in a
:
,
.
mushrooms develop The most commonly used materials ing are loamy top soil sphagnum peat mixed with limestone compost that has been placed field weather for months weathered spent compost
36 or
for
which cas
- are spawn growth when pins minute mushrooms form The mushroom consists three growth stages my
in
.
top dressing atop compost
on
used
-
as a
material
–
CASING
of
in
are
AGAR PLATE - a petri dish containing a substrate composed of nutri routinely ents plus a solidifying substance - agar . Such plates microorganisms used laboratories for the cultivation
time duced
;
ADSORPTION - a physical phenomenon in which a liquid is bound to a substance by electrical bonding . In soil , water can be adsorbed by each particle of soil .
reserved
for that
organic substance which complements the cellulosic Lignin breaks down during composting very
nutritious lignin humus -
form
a
of
.
to
an
.
mushroom growing this term
is
– in
.
a
a
of
1 FLUSHING
LIGNIN
components plant cells combine with humus complex to
the process whereby small particles are enjoined into larger masses chemical precipitant and cloud are exam ples flocculated particles FLOCCULATING
119
is
.
.
to a .
is
of
10
or
a
,
is
a
is
of
is
of
.
, to
of in
is
to
,
an of
a
to
of
of
on
a
the
at
.
at
in a
in
theis
if
)
. (
to
.
–
.
By
to a
is
17
to
10
.
is
to
for
.
is
,
,
,
of
,
on
in
.
.
.
,
of ,
be on
,
it
fungus Mushrooms are quite vis the gills spores produced via sex a
.
a
the fruit body ible sporophores and contain SPOROPHORE
soil conditioner
.
as a
material
in of
casing
or
used
, It is
.
,
of
compost which after harvesting SPENT COMPOST the crop has usually spread been removed from the growing house fields and left weather for some months after which can to
in ,
,
during
ual process
to
grow
at
organism
° an F .
of
–
ability
high tempera
(
see
tis
heat
.
production
of
generation
of
the
or
°
110 and 150
)
;
. (
or
cells
sue apart from the host organism the process artificial substrate see AGAR PLATE
small masses
is
of
cloning cultivation ;
–
TISSUE CULTURE an
,
. (
.
,
of ,
a )
,
or
THERMOGENESIS PEAK HEAT
on
an ,
care
is
If
not exercised the casing surface will seal and interfere with gas exchange
120
THERMOPHILIC tures between
–
of a
improve the tex applying water
-
some growers
in to
by
practice used extreme
MYCELLIUM
simple plant body not differentiated into roots fungi and algae see GERM TUBE Characteristic
leaves
.
to
a
casing
.
ture
of
SCRATCHING
if
be
a
is
of
is
in
way that the area filled with narrow streams tooled such experienced water much wider than would the face was the water outlet flat and perpendicular face
stems
)
is
A
so
.
,
-
a
.
a
to
the end the water into many small streams rather than one large gush roseface also water break but handcrafted and drilled the water must pass through extremely narrow holes Further the head rose scribe the device
THALLUS
,
de
use
-
of
on
term greenhouse operators fragment hose used
to
-
' is a
water break
'
ROSEFACE
–
.
,
in
.
on
is
is
the time beginning shortly after spawning which the mycelium the fungus colonizes the compost SPAWN RUN
.
,
cord
of
strand
an
a
visible
or
compacted mycelium which intermediate stage between mycelium and mushrooms and the structure which pins form Mycelium rhizomorphs shape and size and differ and mushrooms are distinctive their physiological characteristics RHIZOMORPH
of
Il .
of
)
. (
to
as
lead
collectively
.
,
,
–
immature mushrooms initially the diameter pencil arising from rhizomorphs Pins are sometimes pinheads see FLUSHING referred PINS
in a
)
-
(
see PEAK HEAT
-
;
in
making compost the second stage Phase encouraged and pasteurization must occur
deammonification
applying and mixing spawn with compost after Phase composting Mycelium completed and the grain spawn grows into and through the compost SPAWNING
is
° F .
as
as
,
sup
.
is '
aerated and
of
II
PROCESS
becomes
composting process
is
II,
PHASE
to
are
,
at
this time the compost turned plements added enhance
Sealed
grain sorghum rye wheat millet cooked with Mycelium water and chalk and sterilized added container grow days this concoction and allowed this time the fungal mycelium has totally impregnated the grain and this new product called spawn SPAWN
-
the ' so it
to
of
by
,
during which the materials are moistened alkaline conditions are stimulating the production ammonia and tem high peratures within the compost pile increase 180 Also
encouraged
few days before flushing
–
the composting process
surface
surface pore space the small spaces between soil particles casing rarely gives rise mushrooms see SCRATCHING
for
of
the component
COMPOSTING
ing
to
is
2
5,
,
.
,
.
to
18
I
PHASE
casing
applied casing will seal too much water one time particles such excessive watering permits the cas realign themselves pattern that drastically reduces the
reality
–
°F .
SEALING
II
is
–
-
a
after compost
spawn
see FLUSHING
or
110
composting there filled Phase time when the maximum amount microbial growth occurs and growth activity releases heat Thus compost will achieve peak heat after filling and this occurs between days and and lasts for 36 hr PEAK HEAT
growth
).
meso
(
be a
to
to
range of for
temperature
45 °
of a
,
at
a
it
in
.
to
thrives
if
phile
organ
especially
In
the ability
grow and thrive average and not high ranges ism fungus temperature Some mycologists consider
of
term referring
an
ecological
of
an
MESOPHILIC
to
.
.
all
tion of heat . When something is pasteurized there is always a microflora of neutral or beneficial organisms remaining , in contrast to sterilization , which destroys life forms
capacity within depth 0.5 0.75 inches effort restore texture the cas ing There scratching called finger scratching another form Finger scratching the gentle ruffling the casing surface em ployed there evidence sealed casing when the spawn very close days follow the surface and this done a week ing deep scratching Finger scratching and repositioning casing top over spawn growing the casing encourages uniform
if
– nem applica
commcr
I
some farms
to
PASTEURIZATION – selective elimination of unwanted pests atodes , insects , fungi , bacteria , and viruses – usually by
-
devastating condition
raise the moisture content the casing casing then scratch the casing few days to
at
practice
of It
undesirable and potentially its
the body (thallus ) of a fungus comprised of numerous hyphal strands , making the fungus a biological
.
MYCELIUM interconnected unit .
usually performed
“ New
Innovations For Efficient Mushroom Growing
"”
Lee C. Schisler
90 fill
(
.
a
to
US
at
ft-
)/
rebe
a
of a
7 -
.
A
a
2
to
1
in
air
for
.
a
for
(
° F .
II .
is
to
is
it .
to
is
II
II .
in
is
,
Mushroom
Science
).
,
described
1976
at
of
to 7
.
5
-
in
is
of
8 ft '
of
).
at
growing
°,
75
to to
times the closer ;
all
and
at
73
°
Maintain compost temperatures
79 . ° F
Spawn
the
Never allow compost temperatures exceed adequate Co level between 6000 Maintain during the spawn growing period and 12,000 ppm fully grown and ready for cas The compost should an
ing
days
.
.
14
to
12
in
be
)
-
(
2,
82
.
better ° F .
;
of
,
.
4 )
Casing Use the proper depth casing layer this depending upon casing varies the material being a
.
to
of
.
1
to
,
a
,
.
a
peat might require casing layer used For instance depth heavy clay soil might 1.75 inches whereas require only 0.75 inch inch depth Insure proper treatment the casing material eliminate pests
of
.
a
,
-
all
be
I
.
5 )
Watering single watering cannot describe method which will best for mushroom growing operations environmental conditions cultural prac -
by
I
75 % )
to
70
.
(
;
to
or
turns wet dry spots and bring the desired moisture content adequate watering just before filling Phase to
for
;
as
as
at
:
as
I
,
in
at
any time thus eliminating anaerobic areas the pile Insure proper moisture regulation during Phase possible without follows Add much water run off first two turns add only enough during the next turn
filled
required
duration
.
2 ) 3 )
"
° F ).
to
°
175
and
of
.
"
of
a
to as to
(
in
the compost piles 160 no leaching from the piles
be
obtained There should
so
I.
. of
be
level posting
7
6
to °
)
F
°
)
2
? '
at to
:
Use proper raw materials and supple nitrogen schedules achieve prior percent 1.5 the initiation com Proper composting temperatures should
Phase mentation
to
of
II .
b )
(
if
–
,
a
a
by
I
at
,
a
method
.
compost preparation
gallons
Spawning Use mixed spawning the proper rate adequate for area one unit spawn for each delayed release most operations Thoroughly mix supplement percent the rate the dry weight compost
.
Composting Follow the short composting
up
(
,
any
system
269-278
between
a )
of
a
=
.
of
to
'
,
,
a
methods
such
a
a
mush
IX :
of or
whether
in
does
the maximum
(
lb
=
/
/
Ib lb lb
/
let
is
'
How
110
compost
proper Phase The easiest and best way accom plish proper phase The Penn automate Facility State Mushroom Test Demonstration
excellent
and What new innovations should you adopt achieve desired rank These only you grower questions are the can answer reach few ways least To begin may suggest taking high rating primarily old new look
1 )
o
:
tions ratings
opinions
period
opinion However regard me ask the following two ques your farm rank the above
matter
,
of
less
dry compost
rate
proper temperature sequence Phase Follow during Phase Keep compost temperatures tween 140 and 115 Never allow recycling heating proper pasteuriza occur Provide tion 140 the and compost minimum days after filling day hours generally
poor
=
5
of
oil
add vegetable Imperial gallons 4000 depth inches
,
ing
average good
not you agree with my ratings even valid for evaluation
? '
I
room farm
yield
=
dry compost dry compost dry compost
is
this criterion
a
Whether
yield lb
more
yield yield
/
lb lb lb
0.5 0.7 0.9
or
or to to to
1.0
0.3 0.5 0.7
to 7 days , depending used . At tray or bed
should be completed in upon the raw ingredients
of
have been asked from time to time to rate commer mushroom growing , based on present - day knowledge , in terms of biological efficiency . In other words , how many pounds of mushrooms per pound dry weight of compost should a commercial farm ex pect to produce in a 35 - day pick with the knowledge and innovations available to us today ? My ratings in terms of lb yield per lb dry weight of compost are as follows : I
icial
117
-
fly
by
.
,
,
,
,
,
of
.
-
a
e )
in
of
on
in
.
I
a
on
-
on
in
:
of
/
or
.
and
materials
.
short term economic expediency -
3 )
be
better suited
mechanization
.
of
of
au
To accommodate handling
(
at
feasible and may
To accommodate the labor force
a
)
is
is
1976
)
,
269-278
the Penn State Mushroom Facility Mushroom Science
novations mushroom culture were based solely the following three reasons rather than the needs the mushroom 1 )
for
on
(
of
as to
.
IX :
described tomation Test Demonstration
immediately
Let me close with little philosophy have observed that severe difficulties are encountered mushroom growing when decisions the adoption new
2 )
of
to
.
,
to )
ppm depending again
strain en crop first break and the remainder ping Manual CO2 sampling and adjustment satisfactory but dampers control CO2 levels 1500-2000
largement
15 %
to
)
of
.
to
after 600-1200 ppm depending upon the strain spawn being used for proper pinning After pins are adjust CO2 level enlarge set and begin
,
.
by
to
.
(
,
to
Co
HTH powder
good Maintain control program follow ing current legal and recommended practices
.
of
in
of
.
,
-
Provide for relatively high 10,000 ppm levels 5000 until the mushroom mycelium reaches the surface the cas ing layer Reduce the CO2 level immediately there
6 )
with
Ventilation after casing
initial
a
d )
Employ good general sanitation and spot treat ment program Keep picking utensils clean always pick newest rooms first etc. Spot treat infection Mycogone Trichoderma etc. centers Verticilium
mediately its
after casing . Bring casing layer back up to water holding capacity just prior first break adequate waterings insure ade Between breaks quate buildup meet the the casing layer water the next flush water requirements
.
to
However , the following general procedures should be followed : insure adequate initial water buildup im
ac
a
c )
good zineb dusting program Maintain approved label instructions cording
As
tices , and other things vary from operation to opera tion , requiring modifications of the watering regime .
118
in
by
by
be
to
.
"
"
to
.
.
according
of
-
Maintain good benomyl program approved label instructions a
to b )
.
a )
never allow open
Efficient mushroom production can achieved taking new look old methods Steady progress has been and will continue be made mushroom production due the intelligent and practical appli cation sound research findings dedicated mush room growers at
Pick mushrooms closed mushrooms around the plant
Summary
a
fol
:
a
.
7 )
Cropping Practice good disease prevention lowing few simple rules
by
.
for some operations
.
,
et
,
,
26 .
.
p
In :
.
.
)
(
11 .
.
.
on
J.,
of
,
.
,
ed .
.
.pp
,
. )
la
a
mushroom
cul
des Revue
.
,
37 :
of
52
du
.
. (
of de
.pp of
to
,
of
.
,
an
of
.pp.
on
:
,
.
.pp
.
of
-
D.
A.
at
nutrient
.
,A
A.D. and L.C. SCHISLER 1976. Delayed release supplement for mushroom culture Applied and En .
:
CARROLL
,
Hyphomycetes from Soil 262 pp
.
Genera
.
The
of
1968.
MD William Wilkins Co.
destine compost
1973. Improving post composting mush spawning Master supplements Science for use room Thesis The Pennsylvania State University
CARROLL ,
.
,
G.L.
,
Baltimore
compost
Mycoflora
tined for the culture the commerical Mycologie 1-2 14-35 ,
of
Co.
pp 99-106 BARRON
1972. Mycoflora CALLEUX champignon ture couche
de
&
Freeman
Soils 8th
1970. The design development and con adiabatic calorimetric system measure the compost Science Thesis The Master
D.E.
Pennsylvania State University
de
,
.
London
Biological control
H.
CA
struction thermogenesis
R.
'
,
Growing
.pp
1974.
W. In :
.
R.J. Cook
San Francisco
:
to
.
.
Mushroom 122
,
,
Peter
.
,
,
.
,
and
Yaxley
,
.
Mushroom Growers
BUFFINGTON
,
,
.
.
,
.
&
White Plaster Mold
:
,
K.F.
,
N.C. 1974. The Nature and Properties New York NY Macmillan Publ Co. 639
BRADY
of
Annals
Sons
ATKINS F.C. 1974. Guide England Farber and Farber BAKER
A
.
BOTTRELL D.R. 1979 Integrated Pest Management Publication No 041-011-00049-1 Council Environmental Quality Washington DC Government Printing Office 120 ,
161-166
Association Midlands Group Publications borough England Stamford
plant pathogens
major sporocar mushroom Agaricus bisporus Agriculture paper The Pennsyl
96
Aphelenchoides
on
1946.
compendium
, .US
mushroom
the
mush
.pp
of
.
)
Lange Imbach Master vania State University
:
and
the cultivated
,
F.C.
,
:
ATKINS
Potter
Chap
The
1937.
the commercial
,
myceliophagous
,
J.E.C.
Chroncle
S.F. 1980.
,
BONIFACINO pic diseases
'
of
.
Gardeners
Oospora fimicola
mold
,
of
.
Some effects
1968.
ATKINS F.C. 1945. Verticillium Mushrooms Midlands Eng Group Publications Yaxley Peterborough Stamford land
P.H. Williams
1 and
86 of
in
181-182
.
33 :
of
.
12 ( 3 ):
(
of
.
Cali
.
Applied Biology
of
on
yield 61 :
of
and C.D. BLAKE
Ditylenchus
nematodes composticola
Plant Disease Reporter
.
N.P.
,
,
ARNOLD
de
.) (
on
). ]
,
fornia and their control
mushrooms
cultivated
white plaster
room beds
(
du
,
(
Diseases
1949.
,
,
in
les
C.
control
myceliopthora champignon ALLARD 1961. Sur couche Psalliota hortensis Cooke Facts concerning Myceli opthera found the mushroom commerce Psalliota hortensis Cooke Annals des Epiphytes 263-291
ARK P.A.
W.F. HARNETT
Soil ACS Monograph 126
.
3 :
BEWLEY
,
Mush
.pp
,
du . )
C.
,
. [
111-118
of
.
,
.
,
F.E. 1955. Chemistry Waverly Press Inc. 373 BEAR
cham
jaunes ALLARD 1956. Les moisissures pignon The yellow molds mushroom culture room Science
in
,
,
44 :
An
16 .
p
.
.
32
.
.
and
15 .
14 ,
News
11 ,
Mushroom
design
soil treatment
25 ( 7 ): 3, 6,
.
use
Aerated
1977.
9,
R.A.
,
ALDRICH
336
BEACH W.S. 1937b Control mushroom diseases and weed fungi Bulletin 351 Pennsylvania Agricultural Experiment pp Station
.
Pennsylvania Agricultural Experi
.
.
800
W.S. 1937a Mushroom diseases Bulletin Pennsylvania Agricultural Experiment Station BEACH
,
pp
36
air .
Bulletin
ment Station
dis
mushroom
certain
Pennsylvania Agricultural Experi
.
with
ex
of
1975. Heating soils , soil mixes , and soil substitutes
ment Station
investigation
204
the
G.H.
eases
of
, and
saturated
The relation
1971.
.
M.E. SCHROEDER , R.A. KEPPLER
,
,
R.A.
,
W.S. 1926 Bulletin
BEACH
,
ALDRICH , R.A. , P.J. Wuest , and J.A. McCurdy . 1974 . Treating soils , soil mixes or soil substitutes with aerated steam . Special Circular 187 , Pennsylvania Cooperative Extension Service . 14 pp . ALDRICH DIENER .
and C.L. FERGUS
mycelium tracellular amylase and time some therm ophilic and mesophilic Humicola species Mycopathologia Mycologia Applicata 131-141 .
53 :784-788 .
E.A.
BARNETT
In :
ated steam treatment mixes . Plant Disease Reporter
,
Equipment for aer of soil and soil
1969.
of small quantities
.
P.E. Nelson .
, and
,
ALDRICH , R.A.
of
Bibliography
121
vironmental Microbiology 31 :499-503 . CHANG , S.T. , and W.R. HAYES (EDS ) . 1978. The Biology and of Edible Mushrooms . New York , NY : Academic Press . 819 pp . Cultivation
CHARLES , V.K. , and C.H. POPONOE . 1928. diseases and their carriers .
riculture.
Circular
pp .
12
Some
mushroom
US Department of Ag
27 ,
mannitol formation and hexosemonophosphate bisporus . ) Phytochemistry 11 : 2677-2681 .
in
ELLIS , G.P. 1959. The Maillard reaction . Advances hydrate Chemistry 14 :63-134 .
Agaricus
in Carbo
FERGUS , C.L. 1964. Thermophilic and thermotolerant molds and actinomycetes of mushroom compost during peak heating . Mycologia 56 :267-284 .
CHARLES , V.K. 1, and E.B. LAMBERT . 1933. Plaster molds oc curring in beds of the cultivated mushroom . Journal of Agri cultural Research 46 : 1089-1098 .
FERGUS , C.L. 1969. The cellulolytic activity of thermophyilic fungi and actinomycetes . Mycologia 61 : 120-129 .
CONROY , R.J. 1961. Mat disease of cultivated mushrooms . Agricultural Gazette of New South Wales 72 :487-488 .
celium
Cross
, J. , and L. Jacobs . 1969. Verticillium and mycogone diseases of the mushroom . Mushroom Growers ' Association Bulletin 238 : 440-442,44
A new thermophilic fungus from mushroom compost : Thielavia thermophila , sp . nov . Canadian Journal of Botany 47 : 1635-1637 .
Cross , M.J. , and L. Jacobs . 1969. Some observations on the biology of spores of Verticillium malthousei . Mushroom Science
FLEGG , P.B. 1959. The function of the compost and casing layer in relation to fruiting of the cultivated mushroom ( Psalliota ( Agaricus ) hortensis ). Mushroom Science 4 : 205-210 .
7 :239-244 .
DELMAS , J. , and J. LABORDE . 1968. Influence de la forme d'azote utilisee au cours de la fermentation des composts
sur l'effect d'une supplementation proteinique apportee au moment de gobetage , et sur le rendement . (Supplementa tion at casing with soya bean by - products and total mush room yield as influenced by different forms of nitrogen used during composting .) Mushroom Science 7 : 309-328 .
A new truffle dis mushrooms . Mycologia 22 :223
A.
(
1
,
.:
.
,
of ,
Bacteria and mushrooms
Mushroom
451-457
.
Economic Entomology
253-254
.
Journal
74 :
.
growing media
and W. W. CANTELO 1981. Techniques stages Lycoriella mali from mushroom
of
extract immature
of
C.L.
,
FORDYCE
.
of
.
58 :
.
in
of
,.
,
,
L.B. P.J. Wuest and V.R. WAGGER 1974. Occur fungal diseases rence and economic impact mush Pennsylvania Plant Disease Reporter rooms 987-991
FORER
303-310
to
a
in
in
.
1 ,
of
R.R. and E.L. PASSMORE 1978. Concentration airborne mushroom basidiospores and their deposition and around mushroom farm relation mushroom virus disease Mycological Transactions Society British FROST
.
)
Abstr
1979.
.
J.R.
FLETCHER Journal
to
.pp
mush Transac
,
of
pp
,
de
di de
en
Lawnswook U.K Agricultural Division Ad Ministry Agriculture Fisheries and Food
tors and pests
visory Service
,
.
D.
.
,
in
FLETCHER , J.T. , and K. ATKINSON . 1976. Mushrooms . A guide recognition and control competi to diseases weed moulds
.
. )
Society
DUTCH G.A. and Rast 1972. Biochemische beziehung zwischen mannitbildung und herosemonophosphatzykus relationship between Agaricus bisporus Biochemical 122
moulds , and manage
FLETCHER , J.T. , DRAKES , G. , and C.J.W. TALENT. 1975. The control of wet bubble disease of mushrooms caused by My cogone perniciosa . Annals of Applied Biology 79 : 35-41.
.
.
.pp )
,
290
presence
the commercial
disease
. (
216-217
,
FLETCHER , J.T. 1975. Experience on the control of bubble disease (Mycogone perniciosa ). Mushroom Journal 25 :4-5 .
,
of
7 :
in
Agricultural
Comparisons
couche
confetti
Mushrooms
.
au
-
of de
1972.
1977.
ment . Mushroom Journal 56 :252-256 .
(S
by
by
. .
of of
de
in
the presence tions Phythopathologia
room
Fungi
:
J.M. OLIVIER
12 :
(C
.
J.
,
R. ,
,
(
confetti
and
champignon omparison strains
verse varieties
1972.
England Longman Group Limited Wiley and Sons Inc. 290 NY
also New York
DURAND
GAMS
:
,
London
W.
.]
as
,
and
FLETCHER , J.T.
.
le
et
,
de
at
,
.
Soils
K.H.
7 : 221-237 .
room Science
Jr.
la
forme des composts
fermentation
sur l'effect d'une supplementation proteinique apportee upplementa gobetage moment sur rendement products and total mush casing with soya bean tion nitrogen room yield influenced different forms 309-328 Mushroom Science used during composting DOMSCH
J.T. , and G.W. GANNLEY . 1968. Experiments on the biology and control of Mycogone perniciosa Magn . Mush
FLETCHER ,
.
Influence
1968.
P.B. 1980. Temperature induced synchronization of sporophore production in the mushroom Agaricus bisporus . Scientific Horticulture 13 (4 ) :307-314 . FLEGG ,
,
.
de
LABORDE cours
de . la
au J.
J.,
,
DELMAS and d'azote utilisee
tute , 1960 ( 1961 ): 125-234 .
82 , :
,
.
of
:
.
:
,
,
-
the Netherlands ,
in
A.
VAN ZAAYEN
,
1972. Mushroom virus dis symptoms eitology electron mi Philosophy Thesis croscopy spread and control Doctor Wageningen Netherlands Center for Agricultural Publica tions and Documents
ease
1961.
the
.
:
Association Bulletin 244 158-178
DIEHLEMAN
Mushroom composts and composting : a review of literature . Report , Glasshouse Crops Research Insti FLEGG , P.B.
.
is
in
'
disease Growers
,
VAN ZAAYEN 1970. Means which virus spread cultivated mushrooms Mushroom
-
DIEHLEMAN
by
226 .
, Agaricus
70 :636-644 .
.
ease in beds of cultivated
. 1930.
. Mycologia
during my
mushroom
FERGUS , C.L. and J.W. SINDEN . 1969.
58
and E.B. LAMBERT
,
colonization by the cultivated
brunnescens
73 :
DEIHL , W.W.
FERGUS , C.L. 1978. The fungus flora of compost
HAYES , W. A. 1969. Microbial changes occurring when dif ferently treated mixtures of wheat straw and horse - manure
95 : 362-365 .
are composted . Mushroom Science 7 : 173-186 .
GANDY , D.G. 1972. Observations on the development of Verticillium malthousei in mushroom crops and the role ( of ] cultural practices in control Mushroom Science 171-181
Hayes , W.A.
.
.
8 :
GANDY , D.G. 1957. Diseases and disorders - that mush room questionnaire . Mushroom Growers ' Association Bulletin
its
*
(
.
35 :
.
.
)
of
.
,
,
GAZE R.H. and J.T. FLETCHER 1975. ADAS Agricultural Division Advisory Service survey mushroom diseases and fungicide usage 1974/5 Mushroom Journal 370-376
,1 and P.E. RANDLE . 1968. The use of water sol uble carbohydrates and methyl bromide in the preparation of mushroom composts . Mushroom Growers ' Association Bul letin . 218 :81-102 .
Last .
1969. The na sporophore forma
tion in Agaricus bisporus . Annals of Applied Biology
64 : 177-187 .
.
.
of
by
.
in
.
of
.
of in
ostracho
.
T.
,
of
of .
11.
.
of
48 :
7 (
.
.
,
of
.
26
of
.
In
.
8 :
complexes
Westport
,
-
.
153-165
258
cul
of
1979. Care and handling
Pennsylvania
Ef
.
lignin
An
.
9 :
1971.
nual Review
.
on
microorganisms Effects Phytopathology 185-210
KIRK T.K.
1981.
.
Journal
SCHISLER
after casing mush Botany 735-741 59 :
Canadian
C.
L.
and
temperature
on
.
room production
Royse
of
high compost
,
J.
D.
M.
of
fects
of
of
of
JODON
H. ,
.
,
.
and D.J. Royse
months
35-42
.
carbohydrate
Protein
:
,
.
.
1964.
Foods Proteins and their reactions
.
of
.
T.
.
of
the cultivated mushroom after refrigeration Mushroom Science
cultivated mushroom Bulletin Agricultural Experiment Station tures
Stability
1972.
.
pp
352-370
and J.P. SAN ANTONIO
,
,
the
,
Jodon M.H.
J.
,
11 ,
Ltd. Chpt
pp
Symposium
REED
7,
F.
JEVONS
of H.
,
of ,
,
,
spawn stocks liquid nitrogen
.
5 :
,
of
N.
.
S.W.
HWANG
,
.
:
.
.
.
.
.
71-75
Pezziza
361-366
,
,
Pests
The
Edward Arnold
:
.
.
'
1959.
:
Edinburg
38
,
Diehliomyces of
The development the fruit body microsporus Gilkey Transactions Botanical Society
L.E.
Botany
Ultrastructure
1970.
ontogeny
:
Sci
-
.
.
.
SINDEN 1959a Industrial research into some factors affecting yield Mush
342-348
lip
HESLING 1969. The and glasshouse and mushroom pests Protected Cultivation London England
W. W. biology and control
HUSSEY
.
.
of
.
J.W.
E. ,
,
es here to 19
non structural carbo Agaricus bisporus Mushroom
HAUSER and J.W. SINDEN 1959b Mixed spawning Mushroom Growers Association Bulletin 110 39-40 HAWKER
BISALPUTRA
Conidium
CN AVI Publ Co Inc. Chpt
4 :
,
and and investigations room Science
The role
of
.
Hauser
E. ,
391-400
sporophore
the HUGHES D.H. 1962. Preliminary characterization lipid constituents the cultivated mushroom Agaricus campestris 540-546 Mushroom Science
In :
in
by
as
its
of
in ,
10 ( 1 ):
ence
1978.
and
on R.
.]
.
,
10 of ( 2 ):
303-310
J.B.W.
Biosynthesis
251-255
.
(
.
of
.
8 :
HAPP A.C. and P.J. WUEST 1980. Mushroom yield and cidence Verticillium disease influenced the choice casing and treatment with steam Mushroom Science
the life cycle
176-180
1972
HUGHES S.J. hyphomycetes
of ,
K.
,
1972.
533-552
HAMMOND hydrates
I.
.
lipids Lipids ids Lipids
derma Canadian Journal
Versleichende untersuchungen zur spezi kompostiertem und nicht kompostiertem champignonkultursubstrat Understanding the compara composting and not composting the tive specifications substrate for culturing mushrooms Mushroom Science
GRABBE fitat von
19 :
R.B. and L.C.SCHISLER 1971. Lipid metabolism Analysis sporophore and mycelial bisporus ,
Holtz
1271-1273
.
25 .
.
-
,
-
for .
,
,
,
,
R.E. HEPP P.O. MOHN and D.L. VOGELSANG Establishing and operating grower owned organizations integrated pest management Federal Extension Service Pam phlet PA 1180 USDA pp 1977.
1971.
carbohydrates
and Food Chemistry
.
Good J.M.
B.
,
R.
Qualitative and quantitative analyses gas mushroom tissue liquid chromatography and mass spectrometry Agricultural
,
on
263-264
.
.
Botanical Gazette
disease of a deavour 22 : 112-117 .
Agaricus
.
28 :
Soil fungi
1913.
A virus mushroom . En
fungus : die - back of cultivated
free neutral
micro
. Special Circular Service . 20 pp .
safely
Extension
HOLLINGS , M. , D.G. GANDY , and F.T. LAST . 1963.
Holtz
.
6 :
.
Investigations
56 :
O.
,
1941.
mushroom beds Pseudobalsamia Applied Biology 85-90
.
the invasion spora Annals GODDARD
and W.M. WARE
by
1 ,
H.H.
of of
GLASSOCK
,
.
1967.
Using pesticides
1976.
HOELLER , K. 1980. An Integrated Pest Management Primer . Science and Education Administration , USDA . 16 pp .
,
,
-
,
in
3
,
J.P.G. H.C. Bels KONING and F.M. MULLER Changes compost constituents during composting pasteurization and cropping Mushroom Science 225-243
GERRITS
Hock , W.K.
217 , Pennsylvania Cooperative
):
.
288-302
Mycology . London , England : Edward Arnold , Ltd. 340 pp .
6 :
to
in
for
,
in
.
25 :
to
of
gypsum applied J.P.G. 1977. The significance particular mushroom compost relation the ammo Agricultural nia content Netherlands Journal Science ,
E
GERRITS ,
.
9 ( 2 ):
1976.
.
,
J.P.G.
of
The supplementation horse ma nure compost and synthetic compost with chicken manure and other nitrogen sources Mushroom Science 77-98
GERRITS
HAYES , W.A. ,, and N.G. NAIR . 1975. The cultivation of Ag aricus bisporus and other edible mushrooms . In : J.E. Smith and D.R. Berry , eds . , The Filamentous Fungi , Vol 1 : Industrial
.
.
mushroom
43-57
8 :
.
water
in
The influence
1972.
Mushroom Science
.
J.P.G.
,
GERRITS
compost
of
.
7 :
by
,
GERRITS J.P.G. 1968. Organic compost constituents and water utilized the cultivated mushroom during spawn 111-126 run and cropping Mushroom Science
HAYES , W.A. , P.E. RANDLE , and F.T. ture of the microbial stimulus affecting
123
Murphy, W.S. 1976. Some factors affecting Mushroom News 24 ( 12 ) : 10 .
2nd
NAIR , N.G.
.
.pp
O'DONOGHUE 1968. Relationship between some com post factors and their effects Agaricus Mush the yield room Science
245-254
.
Ag
.
.
. .
(
of
.)
en
.
P.
of
. )
of
in
:
:
.
C.
S. .
at
for
83 :
:
.
.
,
.
for as
a
K.
.
.
in
ef
.
.
-
up
.
4 :
R.
l'etude du
a
.pp
.
.
du
R.
Contribution la
A
36-47
.
Mycologie
38 in :
. (
Review
de
mushroom
destine
a
culture couche contribution concerning the mi culturing the compost destined for use .]
cultivated
1973.
compost
of
of
40 ° C .
at
CALLEUX
by
.
.
Y. ,
,
and in de
.
and cypress wood
)
Royse
.pp
6
Washington
.
of
.
in
Entomological Society
,
455-457
.
.
.
,
,
D.J. and P.J. WUEST 1980a Identification and ther mal sensitivity two bacterial pathogens Plant Disease of
)
Lange
64 :
basidiospores
chemo (
and
,
virus disease
thermal
Agaricus bisporus
(
,
ROBINSON W.H. 1979. Phoridae Diptera associated with cultivated mushrooms eastern North America Proceed
.
on
.
transmission
of
Influence of
on
1979.
via
Imbach
champignon
ings
.
F.C.
therapeutans
RENARD
100
.
of
)
,
MORGAN
cellulase mi Philos Doctor
ophy Thesis Pennsylvania State College
croorganisms
1-65
.
.
)
,
. (
de
.
in , ,
of
problems
6 :
research
to
of
Food Research
in
Advances
1 ,
,
(
ity of :
63 1368-1374
124
Application
473-474
spawning Mushroom Sci
REESE 1946. Aerobic decomposition temperatures above croorganisms
des microorganismes
R.K. and P.J. WUEST 1973. Occurrence and sever Verticillium disease mushrooms produced cas Phytopathology soil treated with aerated steam
MOORE
ing
.
F.
L.
1955.
candy manufacture
Leeds
RAPER 1972. Life cycle and prospects Agaricus bisporus Mushroom Sci
RASMUSSEN C.R. 1959. Shake 21-29
ence
,
.
of
.
417-418
:
,
MARTIN
.
in
-
,
porter
31
ris disease T.F. 1947. The vert the cultivated mushroom occurring the United States Plant Disease Re MANNS
and
the identification
Mushroom Journal
T.
mushroom
the cultivated
Mor
RASMUSSEN 1959. Controlled air movement and its 222-234 fect on cropping yields Mushroom Science
4 :
of
CO2
1979.
proteins
1-9
E.
in
.
8 :
373-384
de -g
Mushroom Science
1968. Some observations
.
,
,
L.
P.E. and Jacobs and sporophore initiation LONG
D.
,
les
. (
S. ,
P.
the
of
,
C.A.
and
for interstrain breeding C.
of
by
two tests
the laboratory
.
5 :
room Science
.
,
,
and L.R. KNEEBONE 1962. Investigation gases produced Agaricus bisporus Mush 281-299
.
J.D.
the metabolic
T.
,
RAPER J.R. ence
LOCKARD
,
of
,
of Bulletin
JONG
.
'
.
Papulospora
Association
Growers
tolaasi
8 :
.
Brown plaster mould
Mushroom
and
Bacterial blotch disease research
1979.
University makes progress
.
111-113
1947.
,
C. )
Hots
CHEN
Agaricus bisporus Changes enzyme activity Mycologia 469-478 PREECE
cultivated
.
4 :
,
.
,
LATOUCHE byssina
M.
phogenesis
P.
of
E.B. 1959. Improving spawn culture mushrooms Mushroom Science 33-51
LAMBERT
Three Phyto
Mycological Medicine 4-5 65-67
71 :
.
Re
.
. of
.
:
348-353
PARANJPE
French Society
of
.
, 1
,
41
porter
Trois nouvelles
la
de
Bulletin
261-268
E.B. and T.T. AYERS 1957. Thermal death times cultivated mushroom Plant Disease for some pests LAMBERT
8 :
in
,
:
.
of
.
,
36 :
of
,
Reporter
Disease
1975.
1980
OLIVIER J.M. E.P. PICHOT and HACQUET 1975. Etude microflora fongiques des Champignonnieres Study fonction des postes travel the fungal micro flora mushroom culture function work practices ,
33
.
E.B. and T.T. AYERS 1952. An improved system mushroom culture for better control diseases Plant
LAMBERT
GUILLIAMES
Jan
champignonnieres francaises maladies dams new diseases French mushroom farms Annals pathology 357-358 Abstr 7 :
.
by
252
253
and
Angers France ,
,
ricultural Research
,
C.
,
The
1949.
Reporter
Plant Disease
.
of
fungi
DRECHLER
and MARTIN 1980. Study mushroom caps National Institute for
GUILLAUMES of
,
disease
J.
of
of
bacterial
OLIVIER J.M.
mushrooms caused surface devel evidenced
.sp )
"
cultivated
(
nematode predaceous opment
of
G.
,
,
"
by a
disease Ditylenchus
and
J.
,
OLIVIER J.M.
,
.
20 :
,
,
,
deaths and control 75-83 .
,
to
parasitism thermal the growth Phytopathology Mycogone perniciosa
temperature
of
E.B. 1930. Studies on the relation
STEINER
of
on
.
,
Aston . pp 27-47 .
.
8 :
,
.
N. G. , and W. H. HAYES . 1974. Suggested role of car bon dioxide and oxygen in casing soil . In : W. A. Hayes , ed : The Casing Layer. Birmingham , England : University of
C.
.
:
at
.
6 :
,
,
development and KNEEBONE L.R. 1968. Strain selection 531-541 maintenance Mushroom Science
LAMBERT E.B. Cephalothecium
Agricul
.
.
'
,
:
116 252-256
KNEEBONE L.R. 1965. Spawn research The Pennsylvania 265-281 State University Mushroom Science
LAMBERT
.
Nair ,
,
,
,
115 226-228
,
:
,
.
or
:
114 190-194
Mushroom diseases in Australia
1979.
D.
and
controls mushroom pathogens indicator molds and competitors Mushroom Growers Association weed molds Bulletin 113 146-152
size and yield
tural Gazette of New South Wales 90 (2 ) : 14-17 .
of
.
B.
of
outline
1959. Brief
.
,
L.R. 1 and E.L. MEREK
for
,
KNEEBONE
:
).
,
J.
,
KLIGMAN 1950. Handbook mushroom culture Swaye 356 Kennett Square PA
edition
the
(
A.
M.
.
34 :
of
,
beds the truffle 1944. Control mushroom Phytopathology 376-384
cultivated
Fr.
,
of
in
KLIGMAN A.M.
Taxidium destichum ( L. ) Rich . suspected of harboring inocu lum . Master of Science Thesis , The Pennsylvania State Uni versity . 59 pp .
6 :
30 :
,
of
in cultivation American Journal
of
the
and genetic problems Agaricus campestris the mushroom Botany 745-762 Some cultural
1943.
.
A.M.
KLIGMAN ,
Royse , D.J. , and P.J. WUEST . 1980b . Mushroom brown blotch : effect of chlorinated water on disease intensity and bacterial populations in the casing soil and on the pilei . Phy topathology 70 : 902-905 .
SCHISLER , L.C. 1980. Composting . Mushroom News , 28 (1):5 13 .
J. C. 1973. A system analysis of environmental vari tables for control of phase II ofmushroom composting . Doc tor of Philosophy Thesis , The Pennsylvania State Univer SAGER ,
SCHNITZER , M. and S. U. KHAN . 1972. Humic Substances the Environment .
New York , NY : Marcel Dekker .
Barr , L. C.
SCHROEDER , M. E. , W.
SAN ANTONIO , J.P. , and R.L. THOMAS . 1972. Carbon
SNETSINGER . 1973. Automatic Phase Il system of composting at the MTDF . Progress Report 331 , Pennsylvania State Univer
SCHISLER , L.C. , and J.W. SINDEN . 1962. Nutrient supple
.
.
Crowley .
summary . Mushroom Science 11 ( 1) :387-396 . SINDEN , J. W. 1938. Synthetic compost growing mushroom Bulletin 365 Pennsylvania State University Agricultural
HAUSER
.
relation
of
.
in
.
of
F.E.V.
Transactions British Mycologoical Society
Three
diseases
ad of
.pp
RINKER
.
and
D.
.
KIELBASA
,
,
CHUNG
R.
L.
S.
SNETSINGER
College 16
Agriculture The Pennsylvania State University of
Ethoprop and malathion for control mushroom infesting larval sciarids Progress Report 369 Pennsylvania Agricultural Experiment Station ,
1979.
.pp
12
.
.
Re
. .
.
arthropod pests
Special Publication
,
mushroom
of
1972. Biology and recognition
commercial
.
,
SNETSINGER
,
Progress
8 :
:
'
production
.
mushroom
81-97
SMITH R.C. 1970. Some experiences with Verticillium Mushroom Growers Association Bulletin 250 445-449
R. ,
in
.
Utilization
com
1976.
6-15
of
.
and M. GRABLE
posted municipal refuse
for corn cobs
22 ( 5 ):
.
C.
L.C.
News
mush
cultivated
.
.
1924.
125-130
10 :
in
.
.
)
.
Science
,
substitutes
technologically
Mushroom
rooms
the
.
Possible Mushroom for
,
SCHISLER
1974.
composts .,
mushroom
L.
,
SCHISLER
of
of
.
of
In
W.
J.
,
problems
SMITH
of
8 :
to
oil
,
,
of
.
1972. Disease
vanced mushroom nurseries ,
,
Jr. .pp
12
.
L.C. and T.G. PATTON 1972. Yield response selected mushroom strains vegetable supplementa tion Mushroom Science 707-712 ,
f *
SINDEN
,
com
.
.
,
1 ,
and P.J. Wuest 1970. Harvesting the crop Special Circular 141 Pennsylvania mercial mushroom Cooperative Extension Service
2
.
spawn Fruit Trade Journal SINDEN J.W. 1971. search pp 15-16 Mushroom Supplement 27Aug1971
R.
,
.
12
Pennsylvania Cooperative
140
L.C.
SCHISLER
and Phyto
.
E.
,
177-181
( cropping
Circular pp
.
Service
Review
.
9 :
room Science ,
pp
in
.
,1
,
.
21
through
Special
SCHISLER
of
.
.
in
,
of
139
.
.
Circular
1970. Watering and ventilat pro commercial mushroom
L.C. and P.J. Wuest
casing
pathogens
,
Service
in
Pennsylvania Cooperative Extension
duction Extension
Sci
.
C.
L.
Nutrient supple casing Mushroom
1962.
SINDEN J.W. and HAUSER 1953. Nature and control three mildew diseases mushrooms America Mush 2 :
Casing soil treatment
Special
production
12
1970.
.
J.
P.
,
Wuest
.
C.
L.
and commercial mushroom
ing from
Mush
.
W.
SCHISLER compost
SINDEN J.W. 1971. Ecological control weed molds mushroom culture Annual pathology 411-432 ,
.
:
ticultural Science 95 595-597
SCHISLER
the com
short composting
.
II
of
by
.
,
,
of
L.C. and T.G. PATTON 1970. Stimulation supplementation with vegetable oils mushroom yield composting Journal American Society Hor before phase SCHISLER
SCHISLER
.pp
.
The nature
.
its
.
E.
1953.
123-131
of
,
5 :
.
Hauser
SINDEN and mentation mushroom 267-280 ence
J.
of
.
,
.
The short method
1950.
.
18 :
by JR
,
in
of
sterols and ethyl linoleate Chemistry 1102-1103
Stimulation
1970.
vegetable oils Effects Journal Agricultural and Food
2 :
.
room Science
SCHISLER L.C. and T.G. PATTON vield the cultivated mushroom ,
W. and posting process and SINDEN
,
Etiol
Phytopa
J.
.
.
of
1968.
cultivated mushrooms
944-948
:
thology
and E.M. SIGEL
,
,
,
mummy disease 58
of
ogy
Station
1 :
.
.
L.C. J.W. SINDEN
SCHISLER
for mushroom Pennsylvania State
52-59
Science
to
W. and
composting Mushroom
482
28
.
E.
,
SINDEN
J.
:
850
compost
.
Synthetic
1946.
at
SINDEN
growing Further studies Bulletin University Agricultural Experiment
,
Station
.pp
periment
.
.
in
15
oils
R. SNETSINGER , and V.
1981.
28
.
yield the cultivated Applied Microbiology 844
Stimulation
1967.
vegetable
.
mushroom
of
C. by
,
L.
SCHISLER
Schisler ,
Yield and casing experiments in the Penn State Mushroom Test Demonstration Facility - 10 year E.
.
at
.
,
,
ogy
57 of : a
,
,
,
L.C. J.W. SINDEN and E.M. Sigel 1967. Etiol symptomatology and epidemiology virus disease cultivated mushrooms Phytopathology 519-526
SCHISLER of
1063-1069
SCHROEDER , M. E. , L. C.
,
Botany
Nutrient supple Vegetable oils
casing .
Canadian Journal
1966.
.
J.
and W. SINDEN mushroom compost 44 :
mentation
of
,
SCHISLER
C.
5 : 150-164 .
of L.
Science
spawning . Mushroom
at
CROWLEY , and W. L. Barr . 1974. Automatic control of mushroom ventilation after casing and through production by sampling carbon dioxide . Mushroom Science 9 :269-278 .
W.
mentation of mushroom compost
SCHROEDER , M. E. ,1 L. C. SCHISLER , R. SNETSINGER , V. E.
Ex .
phore initiation in the cultivated mushroom . Doctor of Phi losophy Thesis . The Pennsylvania State University .
Station . 8 pp .
of
of sporo
SCHISLER , and R.
for
investigation
sity Agricultural Experiment
,
A physiological
SCHISLER , L.C. 1957.
diox mush
L.
!
ide stimulation of hyphal growth of the cultivated Science 8 :623-629 . room , Agaricus bisporus. Mushroom
721
in
pp .
327
sity . 132 pp .
J.
z
port 352 , Pennsylvania State University Agricultural Exper
iment Station . 16 pp .
125
62 :
STOLLER
of H. J.
as
to
of
.
J.
,
.
.
.
.
,
)
for
(
.
in
in
. (
.
. )
M.
:
,
in
to
in
E.
in
.
.
,
J.
,
and
during
and laccase activities
of
mushroom Agaricus bisporus
the Jour
.
91 :
167-176
, in
of
D.
.:
ed
,
T.
of
OSBORNE
and other volatiles
.
M.
.
of
,
In
M. ,
pp
M.
E. E.
WARD
ethylene
.
.
in
of
.
-
B.
.
.
.
of
.pp
.
of
My
.
nov Annals
of
of
mushrooms
cultivated
.sp
A
.
of
.
,
Botany
.
in
Gar
United
for estimating ,
biomass composted wheat
of
method
solid substrate
Biotechnology Letters
the
.
82 :
183-190
Observation
in
.
1971.
255-260
.
A
SNETSINGER
1 :
,
R.
.
97 :
JR .
1979.
bisporus
in a
,
A.
D.
Wood
Agaricus
mushroom beds
Pyemotid mites
Entomological News
States
.
and infesting
-
.,
,
mushroom
of
:
.
of
in
.
P.
.
A.
A. 1 ,
,
Wood and W. GoodENOUGH 1977. Fruiting Agaricus bisporus Changes enzyme extracellular activities during growth and fruiting Archives Microbiology 114 161 165
of
Nutrition
63-72
.
1981.
Mushroom Science
11 ( 2 ):
FERMOR
.
T.
R.
and compost
.
,
H. J.
Wood
.
disease
malthousei
Plaster mold 444,445,463-465
1933.
WICHT M.C.
bisporus
1974. Environmental factors and mush room growing Mushroom News 2-24 22 ( 8 ):
vari
Agaricus bisporus
.
,
di
of
of
(
.
The effects
1969.
The
.
W.M.
Chronicle
.
.
. )
on
,
61 :
WARE
D.
.
.
,
of
1933.
deners
straw
H.J. 1958. Die bedentung des kohlendioxyds den kulturchampignon The significance carbon Philosophy Thesis oxide for mushroom culture Doctor University Berlin ,
W.M.
WARE
caused Verticillium 47 763-788
in D.
en
with mushroom culture
TSCHIERPE
fur
,
305-314
'
se
.ppof
.
72
.
.
,
71 ( 5 ):
of
Extracellular
1979.
420
cologia
.
studies
,
and C.L. FERGUS
zymes some fungi associated Mycologia 908-17
B.V.
K.S. and L.C. SCHISLER growth mycelium
WARDLE
Growing
Modern Mushroom
ous lipids
on
of
N.
R.
enzymatic
1977. Extracellular
lected fungi associated with mushroom culture Master Science Thesis The Pennsylvania State University ,
of
:
Netherlands Educaboek
,
1
]
.
180
R.N.
A. ,
83 :
1978.
J.
VEDDER
P.
221-240
C.
in
Plant Pathology
.
mushroom
):
the cultivated
Danish Botanical Archives
11 ( 6
of
Nutrition (
1944.
Dansk Botanical Arkives
4 :
,
of
VAN ZAAYEN and VAN DER POL LUITEN 1977. Heat biology and prevention Diehliomyces micro resistance Agaricus species Netherlands Journal sporus crops
,
Ar
.
C.
,
TRESCHOW
,
Birmingham
21-24
VAN DER VUET M. 1959. Some observations about diseases mushroom farms Holland Mushroom Science 484-487
by
cultivated
Danish Botanical
(
11 ( 1 ): .
of
The Verticillium diseases
1941.
Dansk Botanical Arkives
1-31
TSCHIERPE
cellulase
the cultivated nal General Microbiology
,
(
:
,
.
.
.
C.
,
mushrooms
TRIGIANO
of
to
)
:
,
life cycle
WRIGHT
Production
Agaricus bisporus
Composting
,
:
H.
G.
1950. Eelworms nema MITCHELL and Square PA Mushroom mushrooms Kennett
of
pests
TRESCHOW
)
SELF 1975. and changes
,
.
. 2
,
.
C.A.
,
as
)
,
.
(
their biology and con
insects
Pennsylvania Agricultural Experiment
Growers Cooperative Association
126
TURNER
.
(
for
.
fur
).
.
to
Pennsylvania Coopera
.
,
,
1942. Mushroom
trol Bulletin 419 Station .
Grow
Pennsylvania
1979.
pp
Service
C.A.
,
and P.J. WUEst
Mushroom Pest Control
tive Extension
TRIGIANO
Enzyme activity
1977.
W.A. Hayes England University Aston compost
:
:
.
R.C.
TETRAULT
er's Guide
THOMAS
TURNER
,
,
.
[
als
Aceton acceptor
II .
)
.
a
CO2
1.
.
in I.
.
57 :
. ]
Archives Micro ein CO2 acceptor Ace Mikrobiologie Archives
58 339-356
THOMAS
TURNER 1974. Phenoloxidase activity relation Agari substrate and development stage the mushroom cus bisporus Transactions British Mycologoical Society 63 541
R.
.
Carboxylierungsreaktion
1967.
Der endogene CO2 acceptor Car Agaricus bisporus The endogenous
obxylation reaction CO2 acceptor Archives fur Mikrobiologie as
Bulletin
Association
.
BACHOFEN
392-405
553-592
.
.
,
R.
D. ,
:
in
and
Agaricus bisporus
chives
Mushroom Science
.
.
Plicaria fulva growing '
,
,
in
227 553-561
todes
room culture
547
.
40 :
192-199
B.B. 1968. The brown mold mushroom beds Mushroom Growers
tone
1972. Ueber umweltfaktoren der cham Concerning environmental factors mush
.
of
.
,
,
,
Reporter
STOLLER
biology
.(
of
of
and for
R.E. West and J.F. BAILEY 1956. Control ling the mildew disease the cultivated mushroom Plant B.B.
STOLLER
TAST
H.J.
,
making composts Method U.S. Patent 2,723,493
1955.
.
,
B.
STOLLER
growing mushrooms
Disease
pignonkultur
TSCHIERPE B.
,
36
.
35
8 :
.
'
,
of
B.B. 1952. Studies the function the casing mushroom beds Mushroom Growers Association Bulletin
STOLLER
var bisporus Further investigations concerning the signifi cance carbon dioxide the fruiting cultured mush Microbiology rooms Arkives fur Mikrobiologie Archives 49 405-425 .
for 34 , for
on
18 :
composts
397-414
:
synthetic
Plant Physiology
.
of
Preparation
1943.
mushroom culture
.
,
B.
,
.
46-48
H.J. and J.W. SINDEN 1964. Weitere unter uber die bedeutung von kohlendioxyd fur die fruktifikation des kulturchampignons Agaricus campestris
TSCHIERPE suchungen
,
.
room Journal
B.
,
Trichoderma and mushrooms Mush
1978.
5 :
R.G.
II
STEANE
8 :
1972. Microorganisms inhabiting mushroom during fermentation Mushroom Science 797-811
,
STANEK compost
and W. SINDEN 1962. Studies on the composition horse manure compost from beginning through mushroom cropping Phase related CO2 evaluation Mushroom Science 61-80 TSCHIERPE
.
of
.pp the
12 for
,
:
use
M.
.
,
SPAWN MATE , INC . 1979. Recommendations Spawn Mate San Jose CA Spawn Mate Inc.
Agaricus
1949. Red Geotrichum , a new invader of mush room beds . Darlington's Mushroom News 2 ( 1) :12-13 ; 2 (2) :20 * 21 .
Wood , F.C.
WOOD , F.C. 1957. Diseases 3
of cultivated
mushrooms . Na
ture ( London ) 179 (4554 ) :328 .
WUEST , P. J.
1970.
The use of steam for phase II . Mushroom
WUEST , P.J. , K.F. BAKER , and W.S. CONWAY . 1970. Sensitiv
mushroom pathogens
to aerated steam . Phy
topathology 60 : 1274-1275 .
i
WUEST , P.J. , and R.K. MOORE . 1972. Additional data on the
R.C. TETRAULT . 1974. Growers ' guide to Pennsylvania Cooperative Extension
P.J. , H. Cole , JR . , and P.L. SANDERS
. 1974.
Toler
malthousei to benomyl . Phytopathology
64 : 331-334 .
WUEST , P.J. 1976. Facts and fables concerning spent post for casing , Mushroom News 24 ( 10 ) :8 , 16 , 18 .
com
WUEST , P.J. 1977. Managing air during phase II composting nemesis . Mushroom News 25 ( 1) :7 , 8 , 16 ,
20 .
thermal sensitivity of selected fungi associated with Agari
WUEST , P.J. , and C.L. HARVEY . 1980. The nature of disease
cus bisporus . Phytopathology 62 : 1470-1472 .
resistance
P.J. and L.C. SCHISLER . 1968. Effect of aerated and selected fumigant treatments of casing soil on mushroom production and microbial populations of the soil . Phytopathology 58 : 1073 . ( Abstr )
brunnescens
Wuest
,
.
system
YOUNG , W. L. 1971. Biochemical aspects of aerobic composting . Hercules Industrial Systems Department Report . Cumber land , MD : Allegany Ballistics Lab . 60 pp .
growing
mushroom
.
,
Progress Report 302 Pennsylvania Agricultural Experiment Station ,
,
.
22 ( 11 ):
.
,
Wuest P.J. 1974. Knowing more about peat moss soil 6-14 spent compost for casing Mushroom News
Yoder , J. B. and J. W. SINDEN . 1953. Synthetic compost in America . Mushroom Science 2 : 133-139 .
or
ventilation
for
forced -
air
unitized
in strains of the cultivated mushroom , Agaricus Peck . Mushroom Science 10 ( 1) : 741-746 .
YODER , J. B. , J.W. SINDEN , and E. HAUSER . 1950. Experience with zinc ethylene bisdithiocarbamate as a fungicide in mushroom cultivation . Mushroom Science 1 :100-108 .
WUEST , P.J. , L.C. SCHISLER , and M.E. SCHROEDER . 1970. A
:
,
and the nematode
& steam
·
Wuest
, and
pest control .
ance of Verticillium
News 18 ( 9) :6-15 .
tity of selected
Wuest , P.J. mushroom Service .
127
1
1
Comments and Suggestions
The authors are interested in the value of this hand book to you . Further , the scientific editor solicits your help in identifying topics you would like included when additional material is published . Please send this information to Dr. Paul J. Wuest , 211 Buckhout Laboratory , The Pennsylvania State University , Uni versity Park
, PA 16802 .
129
or , be , to or as by
in
,
.
.
-
;
,
,
or or
,
as
,
.
by or
as sex , to
,
as ,
or
indirectly expressing any limitation specification discrimination race religion color national origin handicap age Vietnam era veteran status disabled provided except law Inquiries concerning this policy may directed the Affirmative Action Officer to
directly
be as
its
The Pennsylvania State University , in compliance with federal and state laws and regulations governing affirmative action and non discrimination , does not discriminate in the recruitment , admis sion , and employment of students , faculty , and staff in the opera tion of any of educational programs and activities defined law Accordingly nothing this publication should viewed
Color Plates
The spores
a are
to
cap
.
the
the
on
of caps
.
or
"
on
,
as a "
surface
infected
the
.
,
2.
FIGURE Verticillium fungicola sporulating grev and often appear haze bloom
of
noninfected mushroom
the
spot occurs when flies or water droplets carrying spores of fungicola cap move from infected mushroom an
1. Verticillium pathogen Verticillium
FIGURE
1
be
b
a>
is
( a )
.
by
Infected mushroom discol stipe Some developing but
and shattered
.
.
the
curved
has
the
.
db )
fungicola
Verticillium
has
a
,
to
.
)
(
split shattered stipe extends cap where slight indention line with the splitting stipe Verticillium fungicela infection caused this
in A
4.
(
as
red
FIGURE
developed splitting
( b )
Stipe splitting ( blowout ) or stipe curvature induced with grey spores forming toward base Infected mushroom dry bubbles uns appear IGURE 3.
a
be
can
db
dry
.
on
the
FIGURE 5. Infection at the cap edge often results in formation of a sunken lesion , pathogen Verticillium which in time becomes brown (necrotic ) . Grey spores of fungicola form the necrotic tissue
a
of
.
,
6.
137.37 When Verticillium fungicela intes pins they develop into bubbles maturing muistroms have ruiter than mushrooms Caps brownish cast caused
wb
wb
That
appearance
of
Wet bubble
.
a
is
called
.
;
-
develop normally this ball like tissue infection was restricted
develop after
the
( a )
brown spores
,
-
grapefruit Usually thick walled
.
large
as
as
be
can (b ).
,
-
Wet bubbles thin walled spores
FIGURE grey
8.
b
(
to
wb )
7. Mushrooms infected by Mycogone perniciosa indicates wet bubbles normal mushrooms are next FIGURE
to
fail
wb
Dactylium dendroides
.
,
the pathogen
by
.
M.
,
the cottony growth habit
of
characterized
by
.
Mildew disease
is
FIGURE
fungicola
10.
Verticillium
-
,
the
FIGURE 9. Amber droplets may appear randomly on tissue infected by Mycogone perniciosa , thus name Wet bubble Tissue morphology and spore color especially thick walled brown spores distinguish perniciosa infection from that caused
enzymes
ex
by
are
digested
can
that inhibit mushroom develop fungus pathogen
toxin
.
excretes spores
the
.
and
Infected mushrooms
of a
casing
is
the
as
the
,
rot .
an
-
,
,
casing
in
,
Trichoderma viride grows through significant crop losses The green tinge
Green mold
ment resulting
grows radially from infected mushroom becoming soft and wet looking they
mildew
.
11.
Dactylium
the pathogen
in
FIGURE
by
creted
12.
FIGURE
on
the
13.
'.
of
of
. .
a
-
or
.
first break mushrooms
mushroom
caps are
in
.
-
of
Symptoms Trichoderma koningii may appear without mildew appearing Superficial purple brown spots Jicative the pathogen's presenet FIGURE
on on
14.
,
on
,
,
,
,
usually appears after FIGURE Trichoderma mildew Trichoderma koningii second break The pathogen first grows stumps and dead mushrooms then onto healthy mushrooms killing them with secreted toxin Tissue infected mushrooms turns brown and the discoloration occurs randomly either the cap the stipe
not
on
to
d
slowed
,
crop will
be
evde
the
breaking
of
The
;
is
probabiy below pł16 Trichoderma viride colonizing casing casing but this pathogen causes minor damage compart other green molds FIGURE
5.
16.
.
.
luxuriating during spawn run compost properly caused mainly inferior compost rather than green by
.sp
Trichoderma
be
15.
FIGURE
composted Crop loss will mold
.
area
barren cas
of
by
mycelium
characteristic
of
of
surrounded
area contains wefted clumps
an
of
.
-
bed ,
of
of
the
is a
it
the
are
,
this in
.
,
of
on
pathogen
.
Trufie
center
Truffle disease The pathogen Diehliomyces fine strand mycelium mushroom spawn
the
the
in
;
its
,
is
17.
compost sign dense mycelium forming knots apart from whiter than mushroom spawn dense texture sets
A
.ing
Fluffy
number Truffle fruit bodies ascocarps seen casing Compost below Truffle's ascocarp rarely forms
FIGURE the
18.
FIGURE microsporus
the
19.
descans
content
.
but the Confetti disease
pathogen
,
Vlat
',
in
,
as
is
production
,
a
its
full
for
be
the cessation
of
results
forms dense yellow masses scattered throughout
the
merdarian
in
a
.
Confetti disease
Chrysosporium
,
20.
Figure
so
is
pathogen Chrysosporium luteum forms dense almost corky mass between FIGURE Mat disease named because compost and casing Rarely can crop present harvested duration when Mat disease
.”
as "
cap
,
the
large portion
of
a
.
discoloration Bacterial blotch affects spot referred
blotch
to
and Bacterial
is
cap
or
dark brown
restricted
,
blotch causes golden times infection
is
it .
At
Bacterial
of
all 21.
not
but
FIGURE
).
P.
Bacterial
of
the cap appear blotch .
;
caused
by
of
mushroom caps indentations
the stem can also
be
.
.
the edges
of to
Bacterial blotch may restricted the small button stage Discoloration
22b at
FIGURE
occurs
be
syn :
FIGURE 22a. These blotched mushrooms exhibit an additional symptom — splitting of the cap . Mushrooms next to infected mushrooms are free of blotch . The pathogen is Pseudomonas flourescens biotype G ( tolaassi
when infection
CS og
stem
( og ). of
the
base
of
the
.
background The classic symptoms
overgrowth
at
mycelial
the
in
be
and
seen
a
a
basal overgrowth
can
of
,
( as tc )
die
in
( cs )
dwarfed and have
a
Mushrooms that
are
a
24.
FIGURE disease
to
Mummy disease causes mushrooms prematurely slightly resulting disease include curved stem tilted cap
FIGURE the
23.
tc
mycelium exhibit symptoms associated with Mummy
.
.
of
is a
A
a delayed first break Mummy disease characteristic the lower bed are delayed and may never reach harvestable size
FIGURE
on
25.
---
Mushrooms
for
;
,
.
soft
rot
with subsequent
-
mustasnonis
,
death
of
.
.
is a
cause premature
spindly with elongated stems some caps are disproportionately small the barren area the foreground Few mushrooms will develop after these first in
,
France
characteristic
can
.
FIGURE 26b
La
break mushrooms
Also there picked
are
.
the stem
are
26a . LaFrance -diseased mushrooms
diameter
of
FIGURE
LaFrance
with prematurely
opened
veils
( ov ).
mushrooms affected
by
strain
)
cultivar
(
Cream
-
26d
.
FIGURE
and
the
stems
,
the
for
,
-
dwarfed their caps disproportionately sized
.
are
26c .
These LaFrance diseased mushrooms prematurely stretched FIGURE
veils
dp
)
are
area are characteristic
symmetry
symptoms
of
of
dp
barren
and lack
),
pin
(
the
LaFrance
of
a
edge
of
-
(
-
an
,
These prematurely open ashen colored mushrooms occurs off white cultivar sirain in
at
duck
dis
.
a
of
(m ),
)
-
proportions Marshmallow like bases cultivar strain mushrooms (
.
as it
FIGURE ease
cream
26f .
in
FIGURE ease
-
26e
m
LaFrance dis
27.
of
is
.
of
a
.
of
saprophytic nematodes The presence associated with spawn disap pearing from the casing downward through the compost This divot compost was compost infested with saprophytic nematodes taken from bed FIGURE
paion
und
he
texiure
of
is a
on
.
texture
of
the
,
compost Initially .
or
on
casing color grows becomes granului ,
buff
in
to
hin
.
I
Lipstick mod
.
20.
!!!!!! Un
,
Pack
reú
.
the
FIGURE 28. Once a nematode population is quite large , a white mold , Arthrobotrys pathogen superba , may appear on casing This fungus feeds and nematodes
Lipstick may resemble
too
for
30.
.
stage
is
A
,
is a
,
.
It
leathery
of
,
size
-
, is is a
,
.
raisin
the name
as
.
the
)
of
stage Cinnamon Brown mold fungus Chromelosporium fulva days after the Cinnamon Brown mold disappears Pezziza ostrachoderma
sexual 14
31. The perfect that appears 7
FIGURE cocarp
to (
of
.
a
too
or
at
pasteurized Cinnamon Brown mold Chromelosporium fulva weed mold that develops when casing high temperature appears soon after casing and disappears before picking begins strong spawn growth this mold into casing limits the growth FIGURE
long
the perfect
32.
.
.
its
,
,
).
(
.
-
be
is
to
or
in
Sepedonium Yellow mold occurs rather randomly compost and color develops during after third break harvest When young pin point This mold quite restricted white and growth tends sporulates profusely Digging into compost infested with yellow mold releases huge spore clouds FIGURE
characteristic Sepedonium
,
.
compost containing ammonia Upon aggregation mold appears grey and sparse
this delicate mycelium
.
,
of
.
34.
thein
the
33.
Mycelium FIGURE Ink Cap fungi grows appears fluffy and dense Without aggregation
.
or
an
,
to
,
on
.
on
.
is
the
inky liquefy into Ink Cap mushrooms develop pins that grow quickly into mushrooms Then they begin casing before first break colored liquid from which common name taken Ink caps appear uncased compost later FIGURE
veriliud
distinguished from other indi
brown spores rubbed between
,
(
S );
( )B ;
.
) is
,
, is
Papuinspuna bussina
on
time harvest increases and Scopulariopsis fimicola and to
is
.
(
.
fingers feel waxy
identity
be
.
color
Its
,
Brown Plaster Mold by
36.
cator molds
(
T ).
O )
:
of
.
is
(
FICURE
,
on
35.
inadequately prepared compost Spawn growth FIGURE Plaster Molds develop slowed mushroom yield lowered The collection Plaster Molds includes Botryotrichum piluliferum present Trichotechium roseum The indicator mold Oedocephalum Brown Mold
the
37.
.
in
.
-
as a
F
°
to
,
is
)
com
the bottom
of
in
rough dense
the bed boairt
at
most obvious close
;
, in is
,
delicate and grey when grotin
ti
38.
FIGURE Olive Green Mold post The fungus Chutorum the compost .
)
1
,
(
A
unique Flour Plaster Mold FIGURE Thielavia thermophila shown surface borne mold This thermophilic fungus generates heat while growing and the compost temperature increases 115 localized spots
.
vigorous
are
grey Olive Green Mold fruit bodies look like cockleburs and usually healthy and spawn beneath the area infested Olive Green Mold is
.
The
by
39.
FIGURE green
.
It
, a
is
granular and feels like gritts
und nhen the spores
are
Oedocephalum Brown molt appears
thumb and forefinger
.
is
.
.
is
41.
FIGURE
if on
40.
growing from spawn grains Black Whisker Mold usually grows incompletely composted straw When growth spore cloud forms abundant compost distributed FIGURE
iubbed between
the
to
.
,
be
to
peeled mushroom mycelium dense enough casing Stroma may yield few mushrooms but or
in
one piece from the compost this general there are exceptions
rule
.
growth
of
Stroma
is a
42.
FIGURE away
are
for
or not
43.
to ,
of ,
.
;
be
.
of
a
Spawn overgrowth should unique mistaken stroma both Overgrowth indicates vegetative growth rather than continuation reversion rhizomorphs and mushrooms the development FIGURE
as
(
the
rudi
of
firm
cap tissue partial has abnormally disrroportionately small cap size for ,
,
of
This Hardcap mushroom development gills and
a
45. )
FIGURE mentary sten
,
in
,
,
the
.
as
the
in
be
,
,
.
are
well whole mushrooms condition occurs early the
.
or
remaining stems 44. This clump of mushrooms has been partially picked . Some of leaking water These mushrooms called leakers can Generally single clusters crop FIGURE
the
46. Hollow Core is normally found in cream and off - white cultivars , when the seasons change or watering patterns are modified . Affected mushrooms look nor
FIGURE
when growing . Absence of tissue trimmed . mal
is
not
seen
until mushroom stems
are
1
|
1
1
No
у
UNIVERSITY OF ILLINOIS -URBANA Q.635.8P38 C001 PENNSTATEHANDBOOK FOR COMMERCIALMUSHR
TUNATE
3 0112 020164825