367 22 75MB
English Pages 922 Year 2003
THIRD EDITION
AN INTEGRATED APPROACH
Dee Unglaub Silverthorn
Word
Top Ten Ways to Succeed in Classes that Use Active Learning
Roots for Physiology
a- or an- without; absence
hypo- beneath or deficient
anti- against
inter-
ase signifies an
auto
By Marilla
Svinicki, Ph.D., Director
bi
University of Texas Center for Teaching Effectiveness
Make
the switch from an authority-based concep-
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and accept your own responsi-
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self
two
and go beyond what
cardio- heart
lipo- fat
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sented in class or the text.
-lysis
inside of a hollow tube split apart
macro-
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large
micro- small
mono- one multi- many myo- muscle
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potassium
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See errors as opportunities to learn rather than ures.
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o o fl
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erythro- red
Engage in active listening to what's happening in
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gastro- stomach
Trust the instructor's experience in designing class ac-
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in the spirit of learning rather
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as a person.
Prepare for class physically, mentally, and materially
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Human ^
Physiology AN INTEGRATED APPROACH THIRD EDITION
Dee Unglaub Silverihorn, Ph.D. University of Texas - Austin
WITH
William C. Ober, M.D. Illustration Coordinator
Claire
W. Garrison, R.N. Illustrator
Andrew C.
Silverthorn, M.D.
Clinical Consultant
WITH CONTRIBUTIONS BY
Bruce
R.
Johnson, Ph.D.
Cornell University
e PEARSON Ber\jamin
Cummings San Francisco Boston
New York
CapeTbwn HongKong London Madrid MexicoQty Montreal Munich
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Singapore Sydney Tokyo Toronto
Publisher: Daryl
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M.D.
Lucid,
Credits can be found on page 878.
ISBN 0-8053-5957-5 Copyright
© 2004
Pearson Education,
San Francisco,
CA
Manufactured
in the
94111.
Inc.,
publishing as Benjamin
Cummings, 1301 Sansome
St.,
All rights reserved.
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Library of Congress Cataloging-in-Publication Data
Silverthorn,
Human
Dee Unglaub, 1948-
Physiology: an integrated approach
/
Dee Unglaub Silverthorn; with William C.
Ober, illustration coordinator, Claire W. Garrison, illustrator, clinical consultant; p.
with contributions by Bruce
R.
Andrew
C. Silverthorn,
Johnson,
cm
Includes index
ISBN 0-8053-5957-5 1.
Human
(alk.
physiology.
paper)
1.
Title
QP34.5.S55 2004
612—dc21 2 3 4 5 6
7—VHC—07
e PEARSON Bor\jamin
Cummings
www. aw -Ik
.umii
2003052278
06 05 04
E.
Lake
Contents
in Brief
PREFACE
IX
mnammmm
i
Atoms,
w-
Cells
k-
Cellular Metabolism
Ions,
and
and Molecules
Tissues
*• Membrane Dynamn
^ ^T
Cardiovascular Physiology
J^
fi/oocf
Introduction to Physiology
^
Communication,
s
20
Blood
523
50
Mechanics of Breathing
546
84
Gas Exchange and Transport
574
124
The Kidneys
598
171
Flunl
Integrative Physiology II: and Electrolyte Balance
625
Introduction to the Endocrine System
^ ^y
4
2
Metabolism, Growth, and Aging
Homeostasis and Control
>
F/ow And the Control
490
UNIT UNIT
448
of Blooa Pressure
Integration,
and Homeostasis
3
Integration of Function
Basic Cell Processes: Integration and Coordination
»
UNIT
and Network
Properties
Digestion
659
^
Metabolism iind Energy Balance
695
208
Neurons: Cellular
T^
239 Endocrine Control of Growth
The Central Nervous System Sensory Physiology
284
and Metabolism
726
The Immune System
751
321 Integrative Physiology
Efferent Division: Autonomic anil Somatic Motor C ontrol
Muscles
^
Exercise
Reproduction and Development
782
796
389
Integrative Physiology
Control of Body
369
III:
I:
Movement
428
APPENDIX
A: Physics
APPENDIX
B:
APPENDIX
C: Anatomical Positions of the
and Math
835
Genetics
GLOSSARY [ND]
\
838
Body
842 843
CREDITS ill
About the
and
Art Coordinator as
Illustrators
an undergraduate
Illustrator at
DR. WILLIAM C.
OBER
studied
Washington and Lee University and ob-
tained an M.D. from the University of Virginia in Charlottesville. In addition to his medical school education, he studied in the
Department of Art
as Applied to
is
at
Johns Hopkins Uni-
Ober completed training
versity. After graduation, Dr.
dent in family practice. He
Medicine
now an
as a resi-
instructor in the Division of
Sports Medicine at the University of Virginia. During the sum-
About the Author
mer, he teaches biological illustration at Shoals Marine Laborato-
DEE UNGLAUB SILVERTHORN dergraduate in
at
Tulane University and went on to earn
marine science
search interest
is
at
a
Ph.D.
the University of South Carolina. Her
in her labora-
on transport properties
of the chick
membrane. She began her teaching
ry,
where he
career in the
is
part of the core faculty. Dr. Ober's professional
now focuses on
re-
and work
epithelial transport,
tory currently focuses allantoic
studied biology as an un-
medical and scientific
and
Mary Baldwin
College, she
1986. Ms. Garrison
Carolina but over the years has taught a wide range of stu-
The
from medical and college students to those
prepar-
still
ing for higher education. At the University of Texas she lectures
in
physiology, coordinates student laboratories in
physiology, and instructs graduate students in a course
veloping teaching
skills in
the
life
sciences.
on
de-
She has substantial
experience with active learning in the classroom and has given
workshops on
this subject at regional, national,
tional conferences. in
Dee
Physiology Education
of the
is
currently editor-in-chief of Advances
American Physiological
Union
improve physiology education ,i
member
of the
Society.
in
She works with
mem-
College Sc ience Teaching.
media
fiber art
Her
tree
is
Physiology Society,
time
and enjoying the Texas
is
and the
Societx fol
spent creating multi-
hill
by
Dr.
member
at Shoals.
Ober and Ms. Garrison have won following: Asso-
for Art
and Design); Printing Industries
of America (Award of Excellence); the Society of
Authors (Talbot
Prize)
Academic
and Bookbinders West. They have also
received the Art Director's Award.
About the ANDREW
C.
country with her
Clinical
Consultant
SILVERTHORN, M.D.
practice in Austin, Texas.
Academy (West
nam, and upon
husband, Andy, and their three dogs.
iv
Book Clinic (Award
developing countries. She
ciation for Biology laboratory Education,
also a core faculty
ciation of Medical Illustrators (Award of Excellence); Chicago
Military
Human Anatomy and
Dr. Ober's associate in
numerous awards from groups including the
of Physiological Sciences to
the Society for Comparative and Integrative Biology, the Asso-
(
texts illustrated
is
became
from
interna-
and past-chair of the Teaching Section
bers of the International
also
and
make med-
obstetric nurse. After receiving a degree in art
Physiology Department at the Medical University of South
dents,
to
her career after almost two decades as a pedi-
ical illustration
atric
illustration.
CLAIRE W. GARRISON chose
Illustrator
life
He
is
a
is
a physician in private
graduate of the United States
Point), served in the Infantry in Viet-
his return entered medical school at the
Medical
University Of South Carolina in Charleston, lie completed his
family practice residency
Branch, certified is
(
lalveston,
at
the University
where he was duet
by the American Board
ol
ol
Texas Medical
and he
resident,
Family Practice.
is
board-
When
\nd\
not busy sccmg patients he maj he found on the golt course,
playing golf or running witi his chocolate
lab.
l
>n\\
Godiva.
Owner's Manual: How to Use This Book Welcome
Human
to
Physiology!
As you begin your study of the pared to make
maximum
human body, you
should be pre-
use of the resources available to you,
including your instructor, the textbook.
library,
One
of
my
the Internet, and your goals in this
book
to
is
provide you not only with information about
how the human body functions but also with tips for studying and problem solving. Many of these study aids have been developed with
the input of find
them
On
my students,
so
I
think you
may
particularly helpful.
the following pages,
I
have put
to-
gether a brief tour of the special features of
the book, especially those that you
have encountered previously
may
not
in textbooks.
Please take a few minutes to read this sec-
you can make optimum use of the text as you study. If you take advantage of features such as the Concept Checks, the Figure and Graph Questions, and Running Problems, you will find that you begin to think about phystion so that
iology in a different way.
One
of your tasks as
you study
yourself a global view of the body,
will
its
be to construct for
systems,
and the many
processes that keep the systems working. This "big picture"
is
what physiologists call the integration of systems, and it is a key theme in the book. In order to integrate information, however, you must do more than simply memorize it. You need to truly understand it and be able to use it to solve problems that you have never encountered before. If you are headed for a career in the health professions, you will do this in the clinics. If you are headed for a career in biology, you will solve problems
in the laboratory,
field,
or classroom. Analyzing,
and evaluating information die skills that you develop while you are in school, and hope that the of this book will help you with this goal.
synthesizing,
need to features
Good
I
luck with your studies!
Warmest
regards,
Dr.
[email protected]
Dee
(as
my
students
call
me)
ANATOMY SUMMARIES
CHAPTER OUTLINE Each chapter begins with an outline for that chapter.
You
major headings
listing the
page reference next to each
will find a
heading. Use this outline to preview the chapter before you
Do you
start reading.
see
any connections between these topics
and concepts you have learned
in previous chapters or other
courses?
To understand physiology, you must also have
a
good under-
standing of basic anatomy. This book includes several
Anatomy
Summary
of a phys-
figures that help
from
iological system,
move all
a
way down
to see
all
visualize the
anatomy
to micro perspective. As
components
across the figure,
the
you
macro
you
of a structure are enlarged,
to the tissue level. These
summaries allow you
of the essential features of each system in a single
fig-
ure, either as a review or for the first time.
BACKGROUND This handy
list
BASICS
at
the beginning of each chapter shows you
FOCUS ON ORGAN FIGURES
which important concepts you should have mastered prior to beginning the chapter. If any of these topics seem unfamiliar, use the page references to revisit the subjects you need to review.
anatomy and physiology looked in physiology
of organs that are often over-
including skin, the
texts,
liver,
and the pineal gland.
FIGURE
CONCEPT LINKS
®
There are several large focus features highlighting the
AND GRAPH QUESTIONS In
These encircled "chain-links" with page references are an extension of the Background
Basics, linking
concepts discussed earlier in the find material that
you
new
help you inter-
and apply concepts,
FIGURE QUESTIONS
ber
you might have forgotten or that might be
helpful for understanding
effort to
pret quantitative information
to
They help you
text.
an
of
figures
a
num-
and graphs
throughout the book include
concepts.
questions that ask you to consider what you really
know about
the information you have just encountered. Answers to Figure
FIGURE REFERENCE LOCATORS The colored each figure ing
it
circles
in the text
easier for
and Graph Questions appear
found next to the
first
function as place markers, mak-
you to toggle between an
and the running narrative associated with that
at
the end of every chapter.
reference to
illustration
illustration.
FOCUS BOXES You
will find three
kinds of small boxes in this book. All of
these boxes were developed with the goal of helping you un-
derstand the role of physiology in science and medicine today:
CONCEPT CHECKS These breaks
in the text,
placed at intervals throughout each
chapter, act as stopping points
where you can check your un-
derstanding of what you have
just read.
Some
you to think about or apply
what you have learned. Answers
to the
REFLEX I
Concept Check ques-
end of each chapter.
he reflex pathways and concept maps organize material into a
their
format that links both physiological themes and
supporting
schematic or
accounts
oi
derstanding
details
a blueprint,
into
a
unified
reference.
I
ike
a
concept maps pto\ ide detailed visual
systems and processes and guide you to ot
moving world
coordinated physiological function.
r F
of biotechnology.
CLINICAL boxes
on
focus
clinical
and
applications
pathologies. In addition to being interesting, these
boxes
help you understand homeostasis and nor-
will
mal function.
PATHWAY AND CONCEPT MAPS
logical, visual
boxes discuss physiology-related
applications and laboratory techniques from the fast-
of these ques-
tions are factual, while others ask
tions appear at the
NKW- BIOTECHNOLOGY
a better (
olors
un-
and
EMERGING CONC1
IMS boxes give you
a
glimpse into
new and exciting developments In physiological research. Some topics, such as stem cells, that were high-
lighted in
Emerging Concepts boxes
become fundamental concepts of the main text.
In
in earlier editions
physiolog) and are
have
now
part
shapes are used to key different processes and properties inside the maps. Foi example, the stimulus 01 starting point a
yellow oval, while the Integrating center
is
always
Is
An additional
always
a red dia-
mond. Ybu will learn to create youi own maps by completing the mapping questions found in the end-of-chaptei exercises.
DIABE ol
MS
human
I
111 \ll
feature to .
Which
physiology.
Biotechnology box,
a
\ c
is
all
three ot these locus boxes
is
a
used to illustrate the comple\it\
diahetes linical
theme box
bears the icon ot a
box, or an Emerging Concepts
on the information presented. Because it makes a
box, depending
widespread effect on the body,
betes has such a
dia-
END OF CHAPTER QUESTIONS
per-
The end-of-chapter questions have been organized into four learning levels to allow you to develop your problem-solving
example of integrated physiology. Some boxes explain the effects of diabetes and then show how the body must compenfect
sate to cal
maintain homeostasis. Others describe biotechnologi-
advances or breakthroughs in the treatment of diabetes.
skills
through
a logical progression of exercises
to conceptual to real-world to quantitative.
—from factual
Answers to Level
One, Two, and Three questions can be found on the companion website. Answers to Level Four questions appear at the
end of the chapter. Level One questions review
RUNNING PROBLEMS
OEach
chapter includes a relevant,
real-life
problem that
appears in segments throughout the chapter. After the
opening scenario
established, segments
on
ly
Level
concepts.
prompt you
to utilize information
you have learned. Use
Two questions
test
your
Level Three exercises are real-world scenarios designed to de-
velop your problem-solving
segment of the problem.
dealing with Level Three questions
check your problem-solving strategy against the Problem Conclusion,
which
lists
the questions from each segment, the
steps that were required to successfully analyze
and analysis"
the running problem.
(or to
Facts:
this
a question
check your solution), examine the Facts and Integration
and Analysis columns
first
skills.
two
You
levels.
you can go
be more successful you have successfully
will
if
To check your answers or
to the book's website.
Level Four questions are quantitative
ing or
some mathematical manipulation. To
swer Level Four questions, you must
first
and the concepts and then be able
vant data to develop at
and require graph-
to
successfully an-
understand the
manipulate
a quantitative picture of
rele-
the physiology
hand.
to the right of each question.
As you study the chapter, identify relevant facts from
and from
earlier chapters.
Use the
check
facts listed here to
Integration
and
Analysis: As
you work through the chapter,
try to analyze the information you've learned to arrive
at
an an-
Using the explanation under Integration and Analysis,
check to see
if
your reasoning
is
sound.
that highlights the physiological
in the chapter.
a narrative
paragraph
themes encountered
in the
followed by enumerated points and page
ences, providing
you with
the end of each chapter following the chapter exercises,
ranging from print and sites.
media
sources,
online journals to magazines to Internet
Each Exploration examines topics relevant to the chapter ma/
s
Myelinated Vxons
260
.
Contents
^ •
Biotechnology:
Electrical Activity
Mutant Mouse Models
Can Be
jj^ Biotechnology:
Of Snakes,
Cell-to-Cell
•
Is
and Run
264
of Neurotransmitters
265
^
266
Clinical Focus: Myasthenia (iravis
267 268
Neurotransmitter Activity Is Rapidly Terminated
Long-Term Potentiation
•
•
The Cerebrum
268 271
Development of the Nervous System Depends on Chemical Signals
297 297
298
the Site of Higher
299
The Cerebrum Has Distinct Regions of Gray and White Matter Chemical Communication Influences
299
Neural Pathways
300
he
(
erebral Cortex
301
Organized
Is
into Functional Areas
302
274
Sensory Information Is Integrated in the Spinal Cord and Brain
302
Sensory Information
Is
Processed
304
into Perception
When
Chapter
296
273
274
Neurons Are Injured, Segments Separated from the Cell Body Die
295
Brain Functions
I
Diseases
Is
Brain Function
Alters Synaptic
Many
295
The Diencephalon Contains
Disorders of Synaptic Transmission
Are Responsible for
294
The Brain Has Six Major Divisions The Brain Stem Is the Transition Between Spinal Cord and Midbrain Anatomy Summary: The Brain The Brain Stem Consists of Medulla, Pons, and Midbrain The Cerebellum Coordinates Movement
Many
Communication •
293
268
Synaptic Activity Can Be Modulated at the Axon Terminal
292 293
268
Neural Pathways May Involve Neurons Simultaneously
292
the Brain
the Centers for Homeostasis
Integration of Neural Information Transfer
291
Barrier Protects the Brain
The Spinal Cord The Brain
264
Not All Postsynaptic Responses Are Rapid and of Short Duration
•
JT
Secretes a Variety
•
•
Fluid
290
Clinical Focus: Diabetes —Hypoglycemia
and
Neurocrines Convey Information
The Nervous System
Fluid
in the Blood Nervous Tissue Has Special Metabolic Requirements
Emerging Concepts:
Multiple Receptor Types Amplify the Effects of Neurotransmitters
•
•
263
•
•
•
The Blood-Brain
263
from Neurons to Other Cells •
•
the Signal for Neurotransmitter
Synaptic Vesicles Kiss •
Anatomy Summary: Cerebrospinal
288 289
from Harmful Substances
Release at the Synapse
^
•
263
Information Passes from Cell to Cell at the Synapse
Calcium
262
•
Anatomy Summary: The Central Nervous System The Brain Floats in Cerebrospinal
Communication
in the Nervous System •
261
•
Snails, Spiders,
and Sushi •
•
Altered by
Chemical Factors
a Variety of
Bone and Connective Tissue Support the Central Nervous System
261
The Motor System Governs Output
Summary
275
from the Central Nervous System
277
304 305
Questions Explorations
279 281
The Behavioral State System Modulates Motor Output The Reticular Activating System Influences
Answers
282
States of Arousal
-504
Physiological Functions Exhibit
The Central Nervous System £$ Running • •
Problem: Infantile Spasms
Emergent Properties of Neural Networks Evolution of Nervous Systems
^ •
284
•
The Central Nervous System Develops from a Hollow Tube The Central Nervous System Is Divided into Gray and White Matter
.
.
.
.
Why Do We Sleep?
307
f?
285
^ and That
286
.
306
284
Clinical Focus: Sleepwalking
Emerging
285
Biotechnology: Tracing Neurons in a Network
Anatomy of the Central Nervous System •
.
Orcadian Rhythms
•
287 •
(
'oncepts:
308
Adenosine
"Java jolt"
$08
Emotion and Motivation Are Complex Neural Pathways
$08
Moods
$09
Are Long-Lasting Emotional States
287
•
Learning and Memory Change Synaptic Connections in the Brain
287
•
Learning
Is
the Acquisition of Knowledge
309
Uo J47
• •
1
Efferent
Sympathetic and Parasympathetic Branches Exit the Spinal Cord in Different Regions
342
343
—A Powerful
•
Auditory Pathways Project to the Auditory
Running Problem: Nicotine
369
The Autonomic Division
343 first in
362
366
as Integrating
of
Inner Far
Sounds Are Processed
Summary
Addiction •
340
Ear
360
Autonomic and Somatic Motor Control
340
Ear:
357
Efferent Division:
Five
Basic Sensations
—A New Photosensitive Pigment ...
Signal Processing Begins in the Retina
335
337
a
•
333
Anatomy Summary: Is
Concepts:
367
336
Taste
357
Answers
Olfactory Cells Are Neurons Olfaction
Photoreceptors Transduce Light
364
333
One
356
Retina
Questions Explorations
Nociceptors Initiate Protective Responses
Is
353
the Retina
330
332
Olfaction
at
Chapter
Temperature Receptors Are Free Nerve Endings
^T" Clinical Focus: Pain Control
351
330
332
Chemoreception: Smell and Taste
350
Light Enters the Eye
JF Emerging
326
Different Stimuli
.
Protected by the Skull
Melanopsin
Many
Pain and Itching Are Mediated by Nociceptors
Is
into Electrical Signals
Information
to
Equilibrium Pathways Project Primarily
The Eye and Vision
into Graded Potentials
Touch Receptors Respond
349
•
Sensory Transduction Converts Stimuli
The Central Nervous System
Vestibular Apparatus
349
B21
Running Problem: Meniere's Disease
347
to the Cerebellum
319 •
347
The Adrenal Medulla Secretes Catecholamines
.
.
Most Sympathetic Pathwav s Sec icte Norepinephrine onto Adrenergic Receptors ....
376 377
Contents
•
•
•
Parasympathetic Pathways Secrete
378
Autonomic Agonists and Antagonists Are Important Tools in Research and Medicine Primary Disorders of the Autonomic Nervous
378
System Are Relatively
y Neuropathy Summary
•
Uncommon
Clinical Focus: Diabetes
•
•
Acetylcholine onto Muscarinic Receptors
379
of Sympathetic
•
381
A Somatic Motor Pathway of One Neuron
381
•
382
•
The Neuromuscular Junction Contains
Chapter
Summary
384
Quest ions
385
Explorations
387
Answers
•
389 390
Skeletal Muscles Are
Composed 391
Anatomy Summary: Organization of Skeletal Muscle
392
414
Smooth Muscles Are Much Smaller than Skeletal Muscle Fibers
414
Smooth Muscle Has Longer Actin and Myosin Smooth Muscle Contractile Filaments
415
Are Not Arranged in Sarcomeres
416
Phosphorylation of Proteins Plays a Key Role in Smooth Muscle Contraction
417
Relaxation in
Smooth Muscle 418
Calcium Entry Is the Signal for Smooth Muscle Contraction 2"
419
Muscle Stretch Opens Ca
Some Smooth Muscles Have Unstable Membrane Potentials Smooth Muscle Activity Is Regulated
419
by Chemical Signals
419
Channels
Cardiac Muscle
Chapter
of Muscle Fibers
Smooth Muscle
Atherosclerosis
•
•
•
Skeletal Muscle
Clinical Focus:
•
389
Running Problem: Periodic Paralysis
413
Has Several Steps
388
Muscles •
•
Consists
Nicotinic Receptors
412
and •
The Somatic Motor Division
Muscle Disorders Have Multiple Causes
f?
—Diabetic Autonomic 380
410
Smooth Muscle
379
and Parasympathetic Divisions
•
•
Bones and Muscles Around Joints Form Levers and Fulcrums
419
421
Summary
422
Questions Explorations
424
426 42~
Answers
Myofibrils Are the Contractile Structures
394
of a Muscle Fiber
Muscle Contraction Creates Force Muscles Shorten Contraction
When They
Contract
396
Integrative Physiology
396
Control of Body Movement
Regulated by Troponin
Is
and Tropomyosin
399 •
Biotechnology: The In Vitro Motility Assay
.
.
.
399
%# Running Problem: Neural Reflexes •
Acetylcholine Initiates Excitation-Contraction
400
Coupling
Muscle Fatigue
I
las
403
Tension Developed by Individual Muscle Fibers Is a Function of Fiber Length
.
.
A Motor Unit
Is
and the Muscle
It
Innervates
Contraction in Intact Muscles Depends on the Types and Numbers of Motor Units •
Mechanics of Body Movement Isotonic Contractions Move Loads,
430
430
Skeletal Muscle Reflexes
431
•
404
Muscle Spindles Respond to Muscle Stretch .... £7"
405
•
406
•
Clinical locus: Reflexes
•
Stretch Reflexes
and Reciprocal Inhibition
Movement Around
Flexion Reflexes Pull Limbs
a Joint
408
•
The Integrated Control of Body Movement •
408
•
Movement Can Be
436
Away
from Painful Stimuli
408
434 435
Muscle Tension
Control
407
and Muscle Tone
432
Golgi Tendon Organs Respond to
but Isometric Contractions Create Force
Without Movement
Visualization
Autonomic Reflexes
One Somatic Motor Neuron Fibers
429
•
Force of Contraction Increases
with Summation of Muscle Twitches
Classified
•
Skeletal
.
Can Be
.'
h\ hniques in Sports
401
Multiple Causes
Muscle libers Are Classified by Contraction Speed and Resistance to Fatigue
429
y* Emerging Concepts:
Muscle Contraction Requires Steady Supply of ATP
Skeletal a
Ways
428 42N
Tetanus
Neural Reflex Pathways Different
I:
436 438
Classified as Reflex
Voluntary, or Rhythmic
43S
The CNS
440
Integrates
Movement
XXV
CONTENTS Emerging Concepts: Central Pattern Generators and Spinal Cord Injuries
J??
•
Symptoms
The Heart Contracts and Relaxes Once
in Visceral Muscles
.
.
y
443 •
444
Questions Explorations
445
Answers
447
471
During a Cardiac Cycle
442
Summary
Chapter
•
Reflects the
Electrical Activity of the Heart
of Parkinson's Disease Reflect the
Movement
Control of
The Electrocardiogram
440
Functions of the Basal Nuclei •
•
Clinical Focus: Gallops, Clicks,
447
.
Cardiac Cycle
Volume Is the Volume of Blood Pumped by One Ventricle in One Contraction
.
•
Heart Rate
Is
•
448
448 £$ Running Problem: Myocardial Infarction Overview of the Cardiovascular System .... 449 The Cardiovascular System Transports Material Throughout the Body 449 The Cardiovascular System Consists of the Heart and Blood Vessels 450 Pressure, Volume, Flow,
The
Pressure of Fluid in
and Resistance
....
478
Compressing
Its
488
O Running Problem: The Blood •
Blood Vessels Contain Vascular Smooth Muscle
Resistance Opposes Flow
454
•
Arteries
Depends on the Flow Rate and the Cross-Sectional Area
455
•
Exchange Between the Blood and
Anatomy Summary: The Heart Cardiac Muscle and the Heart The Heart Has Four Chambers
458
Blood Flow Converges in the Venules and Veins
493
459
Cardiac Muscle Cells Contract Without Nervous Stimulation
460
•
•
461
When It
(
Cardiac Muscle
More
ontracts
Is
.
.
.
462
•
463
•
464
466
Heart Rate
Fleet rk I
i
Mechanics of Breathing
519 521
Answers
522
•
Q$ Running Problem: Emphysema The Respiratory System Anatomy Summary: The Respiratory System he Bones and Muscles of the Thorax Surround the Lungs
546 546 547 ...
548
I
>
Blood
O •
523
Running Problem: Von Willebrand'S Disease
.
.
.
Plasma and the Cellular Elements of Blood • Plasma Is Composed of Water, Ions, Organic
524
JT' Clinical Focus: Cell Count •
Blood • •
('ell
•
Differential
White
Hematopoiesis
Is
Factors,
Bone Marrow
Colony-Stimulating Factors Regulate Eeukopoiesis
Thrombopoietin Regulates
•
Biotechnology: Blood
Red Blood •
.
.
allure
Cells
Mature Red Blood Cells Lack
a
Nucleus
Is
Is a
Mixture
551
a High-Flow,
552
552 552
ol Ciases
Move from
Areas of Higher Pressure
553
to Areas of lower Pressure
Law Describes Pressure-Volume 553
Ventilation 528
554
The Airways Warm, Humidify, and Filter Inspired Air
554
During Ventilation, Air Flows Because 554
of Pressure Gradients
When
Inspiration Occurs
Alveolar
Pressure Decreases
529 (
Air
Relationships of Gases
Platelet
ell
Gas Exchange
he Pulmonary Circulation ow-Pressure System
Boyle's
529
t
tis-
•Ralph W. Gerard, Mlnoi to Physiology: Self Survey of Physiological Science (Washington, D.< \merlcan Physiology Society, 1958) \
Outside
coming from the sensor
sues controlled by Integrating centers are
.:
Within desired rar ige
an integrating center
integrating center
response thai
1-60).
desirable range, specialized
a signal to
variable back Into the desired range,
K
or motors.
filters,
the maintenance of a relatively stable internal environment.
stasis,
The body has
lated
pumps,
the body
activ ated
sends signal
X
to [
|4ntegrating
center
Physiological control n items keep regulated variables within n desired range timing homeostasis
Figure 1-6
Themes
Cotnpartmentation of the body and of branes separate
within a
fluid. Similarly,
membranes
cell,
Input
divide the cell into dis-
compartmentation, or the
crete units or organelles. This
Physiology
mem-
cells Cell
from each other and from the extracellular
cells
in
pres-
ence of separate compartments within the body, allows different To maintain constant level, output must equal input.
areas to specialize their functions.
Communication cells of
that the
and
Most
efficiently.
and homeostasis both require
Integration
the body communicate with one another rapidly
communication uses chemical
cell-to-cell
with the nervous system adding speed by sending
signals,
may
Information
cal signals.
pass from
one
communication) or from one part of the body
(local
(long distance communication).
Movement
latory system aids long distance chemical
Communication between the cells
and the
across the
enter the
the
cell to its
of blood in the circu-
internal
Output
environment of the
requires information transfer
extracellular fluid
message must be trans-
In these instances, the
membrane and translated into an intracelluprocess known as signal transduction. Chemical
ferred across the cell lar signal,
a
communication and detail in
Chapter
•
Mass balance
Figure 1-7
in the
body
are able to
but others are unable to cross the barrier created by
cell
membrane.
cell
to another
communication.
membrane. Some chemical messengers
cell
electri-
neighbors
signal transduction are discussed in
behavioral responses bring the body back into balance. The law of
mass balance Total
summarized by the following equation:
is
amount
(or load) of
substance x in the body
= intake + production - output
more
Substances whose concentrations are maintained through mass
6.
balance include oxygen and carbon dioxide, water,
Movement Movement
of Substances across
of water, gases, and other molecules between the
and
intracellular
extracellular
the barrier of the
evolved that allow terials
logical
Membranes
compartments requires crossing
membrane.
cell
they allow in or out. The details of
membranes
movement
be discussed in Chapter
will
to
input of energy. stored? As
the body
across bio-
this
energy
come
continuous
from, and
those questions, you will learn
range.
Mass Flow
Mass balance
We
function of time.
talk
in the
body
usually discussed as a
is
about sodium intake per day or carbon
how
how
flow,
is
an important consideration. This
is it
Mass Balance
membranes, and
to create
Another important concept
the law of mass balance. This law says that
substance in the body
(amount
(amount min)
vol)
by an equal
For example, a person
movement.
is
to
loss (Fig,
if
in
the
physiolog\
amount
remain constant, any gain must be
is
of a off-
given
is
given an intravenous infusion of glu-
at a rate of
liter.
(in
from the body are the urinary and digestive
the urine and
integumentary system internal
and external
mass balance.
When
is
50 g glucose 1000 ml. solution x 2
mL
solution
= In
physiology
we
min
0.1 g glucose
are also concerned with the
min
movement
of
substances within and between compartments of the body.
Most substances enter the body from the outside environment, although some, like heat, can be produced internally. The for loss
the infusion
2 milliliters per minute, the mass flow for glu-
l-7«). For example, to maintain con-
environment.
major routes
If
cose would be
body temperature, heal gain from the external environment and from metabolism must be offset by heat loss back to the ex-
systems
mini
(vol
stant
.
expressed as mass
concentration x volume flow
Mass flow
energy in
cose containing 50 grams ot glucose per
ternal
is
where
used for synthesis and breakdown of molecules, to trans-
port molecules across cell
set
and hy-
dioxide output per minute. Thus, the rate of intake, production, or
5.
.iving processes require the
Where does
we answer
is
I
salts,
our bodies have regulatory mechanisms
keep temperature and energy stores within an acceptable
output
Biological Energy
ions. In addition,
Specialized processes have
be somewhat selective about what ma-
cells to
drogen
feces),
(skin).
the respiratory system, and the
Sensors that detect changes in the
environments monitor some
mass balance
is
aspects of
disturbed, physiological
and
Blood flows in the circulatory system; the lungs; gases, nutrients, and wastes In each instance,
movement
air
flows into and out of
move
into
and out of
or flow of the substance
is
cells.
created by
a driving force such as a pressure or concentration difference (a
gradient). In
many
flow,
and
is opposed by friction or The concepts of gradients.
situations, flow
forces that create resistance to flow.
resistance will be reintroduced in Chapter
5.
8
1
CHAPTER
INTRODUCTION TO PHYSIOLOGY
1
The seven themes
appear over and over
just described will
again in the subsequent chapters of the book. Look for
the
summary
end of the chapters and
material at the
them
in
in the end-
of-chapter questions.
vestigator in the bird experiment
changed to
food intake increased, she could not determine
if
the increased
food intake was due to temperature or to more palatable food unless
she had a control group that was also fed the different food.
During an experiment, the investigator carefully
CHECK
Answers:
p.
collects in-
formation, or data Iplural; singular datum, a thing given], about
1
on the
the effect that the manipulated (independent) variable has 1
.
a
If
person eats
milligrams of
remaining
it
1
2 milligrams of
in
day and excretes
salt in a
1
observed (dependent) variable. Once the investigator
the urine, what happened to the
analyze the data. Analysis can take
many
cludes statistical analysis to determine statistically significant.
THE SCIENCE OF PHYSIOLOGY How
ments of
Observation and experimentation are the key
hypothesis
using
and,
The next
designing an experiment
knowledge,
aspect of the
step
generates
about
a
how by
to test the hypothesis
is
which the
in
ele-
investigator observes an event prior
[hypotithenai, to assume], or logical guess,
the event takes place.
some
An
scientific inquiry.
phenomenon
or
graph
do we know what we know about the physiology of the
human body?
feels that
she has sufficient information to draw a conclusion, she begins to
milligram?
1
and
a different food,
If
apparent differences are
A common format
1-8*, Focus on Graphs,
in-
for presenting data
is
p. 12).
one experiment supports the hypothesis that cold causes
sure that the results were not step
is
called replication.
an unusual one-time event. This
When
data support a hypothesis in
may become
multiple experiments, the hypothesis
a scientific
theory.
Most information presented
one
in textbooks like this
On
new
occasion,
ex-
Good Scientific Experiments Must Be
perimental evidence that does not support a current model
Carefully Designed
published. In that case, the model must be revised to
element, or variable, that the investigator thinks
phenomenon. That
independent variable. For example, at a feeder
seem to
She generates
some
of biological experiment removes or alters
part of the observed
eat
more
is
an essential is
which she
will
keep birds
than
in the
which
is
summer.
her experiment, tem-
hypothesized to be dependent on tempera-
becomes the dependent variable.
example,
For
membrane was
Answers:
the laboratory execute an experiment
in
p.
1
urine output
in
the hour following drinking.
independent and dependent variables
which globules of proteins
essential feature
spect except thai the
l
result,
the
that
cell
is
manipulated variable
normal value. For example,
a
In
a sel
is
What
ol
birds
are the
cold temperatures,
rhe purpose
hanges are due
changes
In
some
oi
re-
not changed from
like
the control
to the
at
warm
the birds held is
.it
to ensure thai
experimental manipulation
other variable
1
01
example,
11
in
cell
membranes, and students who had learned the butter sandwich
model had
to revise their
mental model of the membrane.
human physiolog) come from? We have learned much of what we know from experiments on animals ranging from squid to rats, in many instances, the scientific
models
for
nonhuman models
enough
humans.
that
we
is
impor-
because experiments using
human
to
It
subjects can be difticult to perform.
control. A control
maintained
model of the membrane, one
within a double layer of
can extrapolate from the animal model
the bird-feeding experiment,
temperatures but otherwise treated exact!)
c
sci-
textbook writers had to revise their descriptions of
float
the experiment?
in
any experiment
the control group would be
10
learned
As a
tant to use
usually a duplicate of the experimental group in ever)
to
in the inter-
fats.
hum. ins.
and not
students
entists presented a very different
However, not
an) observed
in-
sandwich," composed of two layers of
physiological processes are identical or similar
which
they drink different volumes of water and measure their
its
1970
in
a "butter
Where do our
CHECK in
temperatures
the independent variable.
ture,
is
at different
eat. In
intake,
is
have discovered
be
the val.
Food
An
scientists
may
proteins with a layer of fats sandwiched between. But in 1972
perature, the manipulated element,
group
learn a physiological
"fact" while using this textbook, in 10 years that fact
what
the avail-
hypothesis that cold temperatures cause birds to
a
in
Students
fit
is
a biologist notices that birds
in the winter
and monitor how much food they
2.
you may
able evidence. Thus, although
accurate because of
element
altered
increase their food intake. To test her hypothesis, she designs an
experiment
is
based on theoretical models that scientists have developed from the best available experimental evidence.
A common type
a
birds to eat more, then the experiment should be repeated to en-
investigator manipulates
phenomenon.
(see Fig.
if
forms and usually
the in-
l)
I
all
studies
done on animals can be applied
by Europeans
for years
was undergoing stringeni testing
quired b) the U.5. food and Drug Administration before be sold in this country. a
to
or example, an antidepressant that had been used safe-
When
it
re-
could
beagle dogs were given the drug for
period ol months, the dogs started dying from heart problems.
S< leiitists
were alarmed
until luithei research
showed
that beagles
unique genetic makeup thai causes them to break down the drug Into more toxic substance. he drug was perfot tl) satewas subsequent!) in other kinds ol dogs ,\t)i.\ In humans and have
a
.1
I
it
approved
fbl
human
use
The Science
The Results of Human Experiments Can Be Difficult to Interpret There are
many
periments
and
reasons
it is
difficult to carry
humans, including
in
up an experiment with human subjects, we must control the placebo effect. The simplest way to do this is
In setting
try to
out physiological ex-
variability, psychological factors,
ethical considerations.
with a blind study,
which the subject does not know whether
in
he or she
is
receiving the drug or the placebo. Even this can
however,
if
the researcher
who
Human
and environmental
populations have tremendous genetic
variability.
Although physiology books usufunctions such as blood
ally present average values for various
number
pressure, these average values simply represent a
somewhere near the middle
falls
to
show
significant differences
human
groups in a
that
of a wide range of values. Thus,
between experimental and control
experiment, an investigator would,
ideally,
have to include large numbers of identical subjects.
who
However, getting two groups of people every respect
recruit subjects
may have
who
The
researcher then
are similar in as
must attempt
to
seen advertisements in newspapers requesting volun-
body weight,
of ideal
ability inherent in
even
to participate in a study ..." The vari.
a select
measurements or
their
interpretations.
To avoid
not involved in the experiment,
which group group
is
is
who knows and which
receiving the experimental treatment
is
The most sophisticated
experimental design for minimizing psychological effects
the
is
which the control group
in the
experiment becomes the experimental group in
half of the
first
in
re-
a third party,
the only one
receiving the control treatment.
color
outcome,
this
which
searchers often use double-blind studies, in
may
the second half, and vice versa.
many aspects as possible. You
"Healthy males between 18 and 25, nonsmokers, within
teers:
10%
impossible.
is
researchers'
expectations of what the treatment will or will not do
double-blind crossover study,
are identical in
The
receiving.
is
fail,
knows
assessing the subject
is
which type of treatment the subject Variability
of Physiology
group of humans must be taken
when doing experiments with human subjects, bevariability may affect the researcher's ability to accurately
Ethical Considerations
mans
Ethical questions arise
are used as experimental subjects, particularly
when when
subjects are people suffering from a disease or other illness. ethical to
withhold
a
new and promising treatment from
group? A noteworthy example occurred
huthe Is it
the con-
few years ago
when
into account
trol
cause
researchers were testing the efficacy of a treatment for dissolving
on
interpret the significance of data collected
One way to human
reduce
whether
or animal,
to
is
do
a
blood clots in heart attack victims. The survival rate
that group.
within a
variability
test
population,
crossover study. In a
control. Thus, the individual's response to the treatment can
be compared with
the
when
method
is
within
population. For example, in a
a
particularly effective
ication, subjects
own
individual's
control
there
is
value.
wide
blood pressure med-
test of
an inactive substance (placebo, from the Latin first
perimental drug, then changes
half,
(iroup B starts with the ex-
effecl
oi
scheme
the drug
al-
on each
individual. Statistically, the resulting data can be analyzed using
methods
different
that look at the
changes
in
each Individual
rather than at changes in the collective group data.
Placebo and Nocebo Effects Another in human studies is the psychological aspect treatment. will
you give someone
help them, there
effect,
This
If
even
is
a
if
the
is
pill
a
a pill
and
tell
significant variable
administering
ol
the person that
strong possibility that
it
will
a
if
you
have specific adverse side
people that effects,
a
have that
drug they are taking
those people will report
er incidence of the side effects than a similar
were not warned. This phenomenon from the Latin word
nocere, to
may
high-
who
nocebo effect, do harm. The placebo and nocebo is
effects show the ability of our minds to
functioning of our bodies.
a
group of people
on some anticancer agents have shown
the experimental treatments were
less effective in
that
stopping the
spread of cancer than were the standard treatments used by the controls.
Was
it
ethical to undertreat the experimental patients
by
depriving them of the more-effective current medical practice?
Most studies now are evaluated
as rhey progress to
possibility that participants will be
A
recent
women
that
trial
harmed by
taking a
halted early
pill
when
women on
placebo
in
post-
investigators realized
with two different hormones were de-
veloping cardiovascular disease and breast cancer
than
minimize the
their participation.
on hormone replacement therapy
women was
menopausal
pills.
On
at a
the other hand, the
ceh Ing hormones also had
a lower rate of
fractures, the investigators
decided that the
higher rate
women
re-
colon cancer and bone risks associated
with
hormones exceeded the potential benefits, and the study was stopped. To learn more about this clinical trial and the taking the
pros
contains only sugar or an inert substance,
tell
In contrast, tests
and
cons
of
hormone
replacement
therapy,
go
to
it
well-documented phenomenon called the placebo
effect. Similarly,
the
that control groups could also be given the experimental drug.
changes to the
to the placebo. This
lows the researcher to assess the
A takes
for "I shall be
half of the experiment, then
experimental drug for the second
his
variability
might be divided into two groups. Group
pleasing") for the
I
among
was so much higher that testing was halted so
treated patients
crossover study, each subject acts both as experimental animal
and
a
called a
alter the physiological
wwwMlmMih.govfynedlineplusAiormonereplacementtherapy.html, the website of the U.S. National
1
Unary of Medicine.
Human Studies Can Be Designed in
Many Formats
Almost daily the newspapers carry Studying the efficacy are
many
ol
articles
about clinical
trials
drugs or other medical treatments. There
different aspects of experimental design that can affect
the validity
and
ample, some
applicability of the results of these
trials are carried
trials.
For ex-
out for only a limited period of time 11
8
CHAPTER
INTRODUCTION TO PHYSIOLOGY
1
FOCUS ON Figure 1-8
»
Graphs Graphs are
two
more) different
(or
(Fig.
between
pictorial representations of the relationship
l-8a#).
variables, plotted in a rectangular region
We use graphs to
present a large
amount
KEY Key
of numeri-
y-axis
emphasize comparisons between
cal data in a small space,
The standard features of a graph include units and labels on the axes, a key, and a figure legend. (a)
vari"1
show trends over time. A viewer can extract information much more rapidly from a graph than from a table of numbers or
1
ables, or
from
A
a written description.
well-constructed graph should con-
its)
—
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3 ai
Elements and Atoms
commonly
en-
countered in biological systems. Those that are necessary for
life
Only about one-fourth of the elements
major
are called essential elements. Eleven are
found
human body
in the
hydrogen
common
oxygen
(H),
in fairly large
and nitrogen
(O),
are
essential elements
amounts. Carbon
by
(N) are
far
The major
make up most elements are shown
essential
Put the correct answers particles in the left
tial
elements (blue squares in the periodic table in
the er
list
has atomic mass of
3.
neutron
(b)
found
4.
proton
(c)
negatively charged
(d)
changing the number of these in an atom creates a new element
1
biologiin
pink
Fig. 2-2). All of
in
the nucleus
Use the periodic table of the elements
Figure 2-2 to an-
in
swer the following questions: 5.
Which element has 30 protons?
of such elements continues to change as scientists discov-
6.
How many
electrons does
one atom
of
7.
How many
electrons does
one atom
of calcium (Ca) have?
8.
What
9.
What element
more about how minor
tain
amu
(a)
and
the trace elements are essential in
to cell function,
Many modern
work.
cells
some way
vitamin
pills
con-
sodium (Na) have?
elements such as selenium, chromium,
essential
manganese, and molybdenum.
The need
48
than once.
2. electron
minor essen-
tions in living tissues are called trace elements, or
may be used more
(C),
elements that are found in very low concentra-
essential
p.
the right column with the subatomic
in
column. Answers
squares in the periodic table in Figure 2-2.
The
Answers:
the most
essential elements because they
cal molecules.
CONCEPT CHECK
for trace
elements
evident only
is
when they
are
the average atomic mass of nitrogen?
is
illustrated
is
by the atom
in
Figure 2-1 ?
absent from a person's diet or present in insufficient quantities. For example, a lack of iodine in the diet causes low thyroid hor-
mone
production, which
and symptoms such
physical signs
One
tolerate cold.
trace
tion in recent years
and
element that has received a
chromium
ican public as
as fatigue
chromium, usually marketed
is
A
picolinate.
inability to
What
lot of atten-
element that
to the
deficiency of
body has been postulated (but not proven)
in the
RUNNING PROBLEM
then reflected by development of
is
Amer-
diet,
some
The atoms protons in
its
fact that
um
The next element,
um
two protons, followed by lithium
in its nucleus.
protons,
and so on. The number
ement
called the
table
is
In
the
brewer's yeast, broccoli, mush-
chromium
chlo-
poorly absorbed from the digestive
tract,
food and
in
chromium uptake
at the intestine.
lowance (RDA)
chromium
is
in
compound chromi-
from amino
picolinate. Picolinate, derived
of
an essential
is
acids,
enhances
The recommended
daily al-
50 micrograms. As we've seen,
Stan takes several times this amount.
nucleus. For example, the lightest element, hydro-
one proton
is
from one
each element has a unique number of
gen, has only (He), has
in
Chromium
is
(Cr)
normal glucose metabolism.
so a scientist developed and patented the
people.
another by the
found
is
supplements
ride
to be associat-
of different elements are distinguished
linked to
is
chromium
Chromium
picolinate?
rooms, and apples.
chromium
ed with the metabolic disease diabetes mellitus ("sugar diabetes") in
chromium
is
of protons in
atomic number
1.
The
at
ments.
with three
one atom of an
of the element.
arranged by atomic number, starting
atomic number of
(Li)
Question
heli-
Locate chromium on the periodic table of the
1:
What
chromium's atomic number? Atomic mass?
is
How many electrons
does one atom of chromium have? Which
el-
elements close to chromium are also essential elements?
The periodic
oQooooo
hydrogen, with an
end point of the periodic table
is
ele-
con-
stantly shifting as scientists find evidence for additional very short-lived elements (see Explorations at the for the story of a scandal associated
end of the chapter
with this research).
The average atomic mass of an element is shown below the symbol of the element. Atomic mass is calculated by adding the mass of the protons and neutrons in one atom of the element. For example, one atom of carbon has
six
protons and
Because the mass of each proton or neutron unit, carbon's table,
box
not
all
atomic mass
12 amu. However, in the periodic
is
with is
1
7
protons in
periodic table
is
a
known
nucleus,
shows an
20.
The atomic mass
in the
weighted average of the different forms of the
element. In the next section are
its
The number of protons stant
the (Fig.
we
as isotopes.
will discuss these different forms,
in
and distinguishes
number
Atoms
2-3 •).
for
the upper
is,
as isotopes of the
is
con-
others. However,
element
is
variable
numbers of same +
[/so-,
the same place in the periodic table)]. The
of the chemical letter symbol.
left
For example, *H, hydrogen-1,
(Fig.
all
an isotope shows the atomic mass number written to
occurring isotope of hydrogen, us
from
of an element that have different
known
tupos, place (that
symbol
one atom of any given element
that element
of neutrons in the atoms of an element
neutrons are
because chlorine comes in two forms,
one with 18 neutrons and one with
which
six neutrons.
one atomic mass
atomic masses are whole numbers. For example, the
for chlorine (CI),
atomic mass of 35.5. This •
is
Isotopes of an Element Are Atoms with Different Numbers of Neutrons
2-4 •).
or deuterium
Hydrogen 2
(
H),
lc
also has
is
the most
common
has a single proton in
two other
and hydrogen-3, or
naturally its
nucle-
isotopes, hydrogen-2,
tritium
f
(
formed by the addition of one or two neutrons
H),
which
are
to the nucleus
23
CHAPTER
2
ATOMS, IONS, AND MOLECULES Adding one neutron to hydrogen's one proton
(Fig. 2-4b,c).
ATOMS
an atomic mass of 2
sults in
atomic mass of 3
3 (
2 (
two neutrons
H); adding
same chemical properties because these properties
number
consist of \
)
g% W
which
Neutrons
Protons
Elect rons
are
called
is
radiation. Every element has at least one radioisotope, most of
w
\
of neutrons.
and the energy they emit
radioisotopes,
by
are affected
and emit energy. These unstable isotopes
are unstable
called
have the
and medicine, because
Isotopes are important in biology
some
an
yields
H). All isotopes of a single element
the electron configuration and not by the
re-
produced
are
by using high-energy
artificially
particle ac-
A
celerators to "shoot" extra neutrons into a stable nucleus.
number
of elements, such as carbon
small
and uranium, have naturally
occurring radioisotopes. An
ate
m
An
that
ato m that
An atom
that
gains or loses
gains or loses
gains or loses
electrons
protons becor nes a
becomes an
becor nesan
neutrons
Both
artificial
and natural radioisotopes have medical
example, radioisotopes such as thallium-201
body
ages of the inside of the
201 (
uses. For
produce im-
T1)
for diagnostic procedures (those that
identify disease). Radioisotopes are also used to treat cancer, Ion of the
Different
Isotope of the
same element
element
same element
A map showing
Figure 2-3
elements, ions, isotopes,
the relationship between
and atoms
ample of
The use of radioisotopes
therapeutic use.
m
and treatment
of disease
is
a specialty
known
an ex-
in the diagnosis
as nuclear medicine.
mmuiiHs
Radioisotopes and Nuclear Medicine
Of the 2000 known isotopes
of the elements, unstable iso-
topes that emit radiation outnumber the stable isotopes
Some
four to one.
A
artificially,
including
naturally, all
but
those with
atomic numbers of 84 or higher. Radioisotopes emit three
hydrogen atom has one proton in the nucleus and one orbiting electron, but no neutrons.
t.
occur
of these isotopes
many have been made typical
gamma
types of radiation: alpha («), beta (p), and
(7).
Alpha and beta radiation are composed of fast-moving
(a)
Hydrogen-1, H
particles (protons
+
an unstable atom.
Gamma
radiation
energy waves rather than
particles.
neutrons, or electrons) ejected from
particles. X-rays are similar to
A
«o
Radioisotopes are widely used sis
and treatment.
used by (b)
127
Hydrogen-2, deuterium,
2
l,
useful for diagnosis
is
disorders. it
does
13,
little
damage, but
Two
radiation
13, l,
in
medicine
for
diagno-
of thyroid gland
radiation. In small doses
larger doses can
be administered
when
the gland
overactive. Another widely used radioisotope for diagnos-
to the nucleus, creating 3 H.
tic
procedures
bound
is
technetium-99, an element that can be
to carrier molecules that target
it
to specific tissues.
CHECK
Hydrogen-3, 10.
24
Figure 2-4
'
is
neutrons have been added
Anvwi
1
tritium.
•
is
a radioactive isotope of
and treatment (3
is
and are
instances, the radioisotope
emits both a and
l
radiation
interior.
to selectively destroy thyroid tissue
J, (c)
some
For example,
itself.
H
"
In
of high-
deeply than a or p
gamma
used to create images of the body's
neutron has been added to the nucleus,
creating the isotope 2 H.
Gamma
much more
able to penetrate matter
-
composed
is
Isotopt
hydrogen
What
are the atomic masses
isotopes
shown
in
(in
Figure 2-4?
amu)
of the three
hydrogen
1
.
Elements and Atoms
Electrons
Form Bonds Between Atoms
(a)
and Capture Energy Electrons, the third
subatomic
particle, play a significant role in
The arrangement of electrons around the nucleus
physiology.
de-
termines the ability of an atom to bind with other atoms and
form molecules. The gain or cal
loss of electrons
changes the
electri-
charge on an atom and plays an essential role in communica-
on
tion throughout the body. Finally, electrons
processes.
life
The
electrons in an
atom do not move around the nucleus
random. Instead, they are arranged
The lowest energy
shells.
to other
it
movement and
molecules, so that the energy can be used for
other
atoms can
certain
capture energy from their environment and transfer
level,
energy
in a series of
designated as level
1, is
at
levels, or
Nucleus closest to
the nucleus. As distance from the nucleus increases, energy levels increase.
Each energy
torical reasons,
s,
p,
level
|
Appendix A
1
brackets around the symbol for a solute are the shorthand nota-
Another way to write This equation states that
pH
]
and
between
pH
of a solution
pH
is
1
cause [H
pH
H
+
less
+ is
]
is
measured on
numeric
a
Chemical
--
Household ammonia
--
is
meaning
Soap
H
its
pH
scale
7.
H+
Baking soda
concentrations. Be-
Pancreatic secretions
Solutions that have lost
H+
to a base
have
Compatible with human
a lower
concentration than pure water; they are called alkaline. They
have
pH
a
value greater than
7.
Remember, because pH +
tional to the reciprocal of the [H tration increases, the
The pH value of
scale
pH number
],
as the
is
Saliva
hydrogen ion concenUrine (4.5-7)
meaning
change
that a
pH
in
unit indicates a 10-fold increase or decrease in the hy-
1
drogen ion concentration. For example,
if
the
pH
of a solution
4-
ible
from
with
a
pH
of 8 to a
life.
Vinegar, cola
Lemon
1
•
Buffers are a key factor in the body's ability to maintain nor-
mal pH. A buffer
is
any molecule that moderates changes
Many
buffers are anions that
cules.
When
buffers
f
free
bond
Fi
is
to the
H
have a strong
added to +
a solution
affinity for
a buffer
used
pH of swimming pools and spas. The following shows how sodium bicarbonate buffers a solution to
When
which hydrochloric acid (HC1) has been added.
HO dissociates into FT
solution,
If
and CI
some
is
of the
present,
H
to
some
of
form undis-
carbonic acid. The removal of free FT lowers the
+ CI
+
I
ICO.
'
40.
When
the
body becomes more
acidic,
does the pH increase
or decrease?
41
How
.
can urine, stomach acid, and
outside the
pH range
part of the living
that
is
saliva
have pH values
compatible with
1
1
con-
k BIOMOLECULES Most of the molecules three elements in
concern
ol
common: carbon
in
human
(C),
=^H
2
CO,
+ CI
molecules, because
+ Na'
Hydrochloric
Sodium
Carbonic
Sodium chloride
100 amino acids)
have
l_ 1
"
2'-
structure
3° structure
structure
4° structure
1
Sequence of amino acids
1
Globular proteins
Fibrous proteins
P-pleated sheet
a-helix
•::•:
Multiple subunits
I
\
•
v.
;
"V
*
Figure 2-16
Map
of levels of organization in protein molecules
held in place by hydrogen bonds. In other proteins, sulfur atoms in
two
different cysteine molecules
in a disulfide (S
—
S)
bond covalently
to each other
acids each.
The hemoglobin molecule
proteins based on their shape. Globular proteins have
amino
acid chains folded into ball-like shapes. Fibrous proteins are
found as pleated sheets or in long chains that
wind around
carrying pigment found in red blood
The
ble in water, are important structural tissues.
Examples include
a
fibrous proteins,
number which
collagen, a fibrous protein
found
and
nails.
The globular proteins
making them
soluble.
cells,
has a quaternary struc-
of 146
in
and
many
They may
They act them and
are soluble in water.
said to
two polypeptide alpha chains of
cells
types of connective tissue, and keratin, a fibrous protein found in
Hemoglobin, the oxygen-
is
of impor-
are insolu-
components of
insoluble lipids in the blood, binding to
composed 141 amino acids each and two polypeptide beta chains of four subunits:
illustrated in
as carriers for
A protein with more than one polypeptide chain (Fig. 2-16).
and amino acids serve
tant functions in the body.
hair
each other.
is
Figure 2-16 under the label "Multiple subunits." Proteins, peptides,
Proteins are often classified as either globular or fibrous
ture
amino
bond.
have quaternary structure
•
also serve as enzymes that increase
the rate of chemical reactions. Soluble proteins also act as cell-tocell
messengers in the form of hormones and neurotransmitters
and
as defense
molecules to help fight foreign invaders.
39
CHAPTER
ATOMS, IONS, AND MOLECULES
2
CHECK
Answers:
p.
another kind of biomolecule. Proteins combine with
49
form lipoproteins. Lipoproteins are found mostly in
What
44.
the chemical formula of an
is
amino group? Of
a
carboxyl group?
Why must we
45.
They
branes.
also carry
terol in the blood: the lipid section of the
include essential
amino
acids
in
our diet but
lipoprotein-cholesterol
What aspect of protein structure allows proteins more versatility than lipids or carbohydrates?
to have
complex soluble
combine
Proteins
with
is
mem-
as choles-
makes the
entire
in water.
carbohydrates
glycoproteins. A "glyco-" molecule
cell
molecule interacts with
insoluble cholesterol while the protein section
not the other amino acids? 46.
hydrophobic molecules such
lipids to
composed
to
form
of a carbohy-
bonded to either a protein or a lipid (glycolipid). Glycoproteins and glycolipids, like lipoproteins, are important components of cell membranes (Chapter 5). The carbohydrate drate
Some Molecules Combine Carbohydrates, Proteins, Not
all
lipid.
•
and Lipids
biomolecules are pure protein, pure carbohydrate, or pure
Conjugated proteins
Map
Figure 2-17
are protein molecules
portions of these molecules are usually found on the external
combined with
of nucleotide
surface of the
NUCLEOTIDE
structure
cell,
where they can form hydrogen bonds with
NH 2
N^
^
C
CH
II
1
HC^ ^C x / N N II
II
II
O^
-o-p- -0-P-0-POCH 2 o-
o-
\
-o
/
ATP
OH consists of
Purine
H
N
^
HOCH 2
/
HC^
(A)
II
I
0'
N
Guanine
(G)
Cytosine (C)
Thymine
OH
HO
(T)
HO
Uracil (U)
Bases Adenine Adenine Adenine Adenine
+
ADP CAMP NAD
= = = =
DNA RNA
= A.G.C.T - A.G.C.U
+ +
ATP
O
"0-P-OH
OH
NUCLEOTIDES
+ + +
Sugar
Phosphate groups
Ribose Ribose Ribose
+
3
+ + +
2
2 Ribose
Deoxyribose
Ribose
+ +
Other component
— — —
1
+
2
NUCLEIC ACIDS:
40
OH
O
1
I
Adenine
OH
O
II
I
N H
HOCH 2
Deoxyribose
N^ ^CH
CH
II
HC Nx
Ribose
Pyrimidine
H
I
Phosphates
Sugar
Base
1 1
per nucleotide per nucleotide
Nicotinamide
—
Biomolecules
water and other molecules in body
Glycolipids are be-
fluids.
lieved to contribute to the stability of the cell
and glycolipids
glycoproteins
tain
receptors
and
act
as
O
membrane. Cer-
Nucleotide chains
membrane
cell
£3
markers. Membrane receptors bind to mole-
cell
cules outside the
The
cell.
markers identify
cell
label, so that
the defense cells of the body can
ence between
"self"
cells,
like a
U
the differ-
tell
and foreign invaders.
Nucleotides Transmit
Bases
and Store Energy
and Information Nucleotides play an important role in cell,
including the storage and transmission of genetic informa-
tion
and the
molecule composed of five-carbon sugar,
base
(Fig. 2-1
and
(1)
(3) a
single nucleotide
is
one or more phosphate groups,
\tle-,
without;
bases: the purines
-oxy-,
two
There are
Thymine _ Guanine
(2) a
C
Cytosine
U
Uracil
oxygen]. There
and the pyrimidines. The
purines have a double ring structure; the pyrimidines have a gle ring.
are subjected to increased energy
may meet
the
demand
for
demands over
cells,
a period of
more ATP by increasing the num-
ber of mitochondria in their cytoplasm.
59
r
_
CHAPTER
3
CELLS
AND
TISSUES
^l^m\ Inner
membrane Outer membrane
Cytoplasm
Cristae
Matrix
is
the
compartment
•
Figure 3-9
of
membrane
Mitochondria
Mitochondria have
The Endoplasmic Reticulum Is the and Lipid Synthesis The endoplasmic a
Matrix
The intermembrane space forms a compartment.
Cytosolic side
innermost
a
double wall structure with
Site of Protein reticulum, or ER,
network of interconnected membrane tubes
(Figs.
3-6
is
and
as
smooth membrane
reticulum
comes from the Latin word
for net
and
refers
to the netlike appearance of the tubules. Electron micrographs reveal that there are
two forms of endoplasmic reticulum: rough
tubes. Both types of
The smooth endoplasmic reticulum pholipids for the terol
is
cell
membrane
liver
Smooth endoplasmic reticulum
rough appear-
cytoplasmic surface.
lacks the ribosomes
and appears
storage,
and kidney
muscle
cells, a
is
are
the main
[©
site for
p. 35].
produced here, and choles-
The smooth endoplasmic reticulum of
cells detoxifies or inactivates drugs. In skeletal
2+ )
to be used in muscle contraction.
are attached
to cytosolic side of
rough endoplasmic reticulum.
y% •
Smooth endoplasmic reticulum lacks ribosomes.
The hollow tubes
ER
60
The endoplasmlt reticulum
of the
are formed by a continuation
of the outer nuclear
Figure 3-10
Phos-
modified form of smooth endoplasmic reticulum
stores calcium ions (Ca
Ribosomes
•
and
modified into steroid hormones, such as the sex hormones
Rough endoplasmic reticulum has
its
(SER)
the synthesis of fatty acids, steroids, and lipids
estrogen and testosterone.
a granular or
endoplasmic reticulum
transport of biomolecules.
endoplasmic reticulum and smooth endoplasmic reticulum. ance from rows of ribosomes dotting
inner membrane.
have the same three major functions: synthesis,
3-10 •) that are a continuation of the outer nuclear membrane.
The name
a heavily folded
membrane.
•
Cellular
The rough endoplasmic reticulum (RhR)
is
the
main
at-
tached to the cytoplasmic surface of the rough endoplasmic
exported to other parts of the body. (Secretion
The Golgi Apparatus Packages Proteins into Membrane-Bound Vesicles The Golgi apparatus dig. 3-1 19) described by Camillo Golgi in 1898. For years,
vestigators thought that this organelle
was
some
just a result of
the
microscope. However,
we now know from
scope studies that the Golgi apparatus
nous organelle.
Its
function
is
to
is
fix-
electron micro-
indeed another membra-
modify proteins made by the
rough endoplasmic reticulum and package them into membranevesicles.
The Golgi apparatus consists of five or six hollow curved sacs stacked on top of each other like a series of hot water bottles and connected so that they share a single lumen. The convex side of the stack faces the
rough endoplasmic reticulum and
ceives the transport vesicles from
it.
which
re-
These transport vesicles fuse
with the membranes of the Golgi sac and discharge their con-
is
the process by
substance into the extracellular space.) The
contents of most storage vesicles, however, never leave the cytoplasm. Lysosomes are the major storage vesicles of the
cell.
Lysosomes Are the Intracellular Digestive System Lysosomes
[lysis,
dissolution + soma, body] are small, spherical
storage vesicles that appear as
cytoplasm
and
(Fig.
membrane-bound granules
in the
3-120). Lysosomes contain powerful enzymes
They take up bacteria or old organelles, such as mitochondria, and use the enzymes to break them down into their component molecules. Those act as the digestive
system of the
cell.
molecules that can be reused are reabsorbed into the cytosol, while the of
rest are
dumped
enzymes have been
out of the
identified
cell.
As
many
as
50 types
from lysosomes of different
cell types.
The
enzymes of lysosomes are not always kept isomembranes of the organelle. Occasionally, lysotheir enzymes to dissolve extracellular support
digestive
lated within the
somes
lumen.
a cell releases a
in-
ation process needed to prepare tissues for viewing under the
its
be attached to proteins to
storage vesicles. Secretory vesicles contain proteins that will be
tips of the
the Golgi apparatus.
tents into
be modified
be cleaved into
vesicles shuttle their contents across the cytosol to
pinch off from the
bound
may
may
Cytoplasmic vesicles are of two kinds: secretory vesicles and
membrane-bounded transport
der| that
light
smaller proteins or carbohydrates
may
vesicles [vesiada, blad-
spherical
first
the sac, they
endoplasmic reticulum.
where they undergo
chemical modification. Most of these proteins are packaged into
was
move through
by enzymes. For example, long proteins
make glycoproteins. Finally, the processed proteins are enclosed in membrane-bounded vesicles that pinch off from the concave face of the Golgi apparatus and move out into the cytosol.
reticulum, then inserted into the lumen,
The transport
As the proteins
site for
the synthesis of proteins. Proteins are assembled on ribosomes
Anatomy
release
Secretory vesicles leave filled with newly packaged proteins.
4
>**?
/» V Transport vesicles bring newly synthesized proteins from the endoplasmic reticulum to the
•
Figure 3-1
1
The Golgi apparatus
Golgi apparatus.
61
.
CHAPTER
CELLS
3
AND
TISSUES
One
of the best-known lysosomal storage diseases
known
herited condition
Sachs disease have defective lysosomes that glycolipids in nerve
symptoms
causes
cells.
is
the fatal in-
as Tay-Sachs disease. Infants
with Tay-
to break
fail
Accumulation of glycolipids
down
in the cells
nervous system dysfunction, including
of
blindness and loss of coordination. Most of the afflicted infants die in early childhood.
Lysosomes and peroxisomes are vesicles
filled
Peroxisomes Contain Enzymes That Neutralize
with enzymes.
Toxins
f;.y
:
\
Peroxisomes
1
-
tdur'l
some ,
***?,
now know
some, but we
Peroxii
1
.
.,/
kind of lyso-
a
that they contain a different set of en-
zymes. Their main function appears to be to degrade long-chain fatty acids
and potentially toxic foreign molecules.
name from
Peroxisomes get their inside
Lysospme
even smaller
are storage vesicles that are
than lysosomes. For years, they were thought to be
cule.
the fact that the reactions
them generate hydrogen peroxide (H 2
The peroxisomes
a toxic
2 ),
mole-
rapidly convert this peroxide to oxygen
and water using the enzyme
catalase.
Peroxisomal disorders
dis-
rupt the normal processing of lipids and can severely disrupt the
normal function of the nervous system by
altering the structure
membranes.
of nerve cell
CHECK 7.
•
Answers:
p.
83
What
is the anatomical difference between rough endoplasmic reticulum and smooth endoplasmic reticulum?
What
is
the functional difference?
Lysosomes and peroxisomes
Figure 3-12
How do
8.
material, such as the hard calcium carbonate portion of bone.
How
9.
lysosomes
release of lysosomal
enzymes has been impli-
from peroxisomes?
does the physiological theme of compartmentation
membranous
apply to
The inappropriate
differ
mitochondria
in
organelles
in
general and to
particular?
cated in certain disease states: for example, the inflammation and destruction of joint tissue in rheumatoid
10. Microscopic examination of a cell reveals arthritis.
mitochondria. In other instances, cells allow the
to
come
of
all
in
enzymes of
their lysosomes
or part of the
mass
is
this
many
observation imply about the
energy requirements?
contact with the cytoplasm, leading to self-digestion cell.
When
muscles atrophy (shrink) from lack
of use or the uterus diminishes in size after pregnancy, the loss of cell
cell's
What does
due to the action of lysosomes.
1 1
You are examining tissue from a previously unknown species of fish. You discover a tissue with large amounts of smooth endoplasmic reticulum in its cells. What is one possible function of these cells?
Because lysosomal enzymes are so powerful, one of the questions that puzzled researchers
mally destroy the
cell
was that these enzymes tions,
zymes
pH
is
first
If
will
it
The
pi
I
by very acid condi-
breaking
off
When
from the Golgi apparatus, their
in-
pH. Their inactivity serves as a form of
the lysosome breaks or accidentally releases the en-
not it
harm the
cell.
accumulates H
However, as the lysosome ions in
d
Once
down
this has oc( urred, the
sits in
conditions
known
Center
The nucleus
material thai
lysosomal storage diseases,
lysosomes are not effective because they lack
specific
enzymes,
processes.
How
the nucleus receives in-
in the cell or
elsewhere cell's
in
the body
protein synthe-
an active area of biological research, figure 3-13 • illustrates
sis is
the structure ol a typical nucleus, ["he boundary, or nuclear en-
velope,
a
is
(
j
is
membranes boles, oi
.is
all cell
and responds with line-tuned control of the
envelope
are capable ol
Cell's Control contains DNA, the genetic
formation about conditions
and the enzymes
enzymes
of the cell
ultimately controls
from the
various biomolecules.
in Inherited
The Nucleus Is the
process that uses ener-
inside the vesicle drops to 4.8-5.0,
are a< tivated.
62
they discovered
about the same as that of the cytosol, 7.0-7.3. The en-
the cytoplasm, gy.
are activated only
pinched
are inactive at this
insurance.
zyme,
What
100 times more acid than the normal cytoplasm.
lysosomes are terior
was why these enzymes do not nor-
that contains them.
i
two-membrane
structure that separates the nucleus
toplasmic compartment.
I
lie
outer
membrane
ol
the
connected with the endoplasmic reticulum, and both Ol
the envelope are pierced here ne
t
many
i
olumnai
polygonal
to
airways; female reproductive
Protein-secreting nils filled
I
witb membrane-bound secretory granules and extensive Rl R, Steroid se< reting cells contain lipid droplets
and extensive
open
em Ironmenl
Nose, trachea, and uppei
One side covered with cilia to move fluid across suifa< e
1 1
Sit irtory
the mouth, that
to the
SI
R
act
MX
line glands, in< hiding
p. liu reas,
swr.u glands,
salivar) glands,
endocrine
glands, sin
tin roid,
li
.is
gonads
68
.
'
Body
Tissues of the
Most
Cell organelles.
4.
Blood Capillary epithelium
merous
transport materials have nu-
cells that
mitochondria
provide
to
energy
processes (discussed further in Chapter
The
Pore
(a)
moved from
the extracellular
Leaky exchange epithelium allows movement through gaps between the cells.
5).
properties of transporting epithelia differ. For example,
glucose can be
Extracellular fluid
the lumen of the small intestine to
but cannot be
fluid,
um of the large intestine.
moved
Lumen
ous stimuli. Hormones, for example, of intestine or kidney •
Apical
membrane
by the epithelium of the kidney. You
•
Tight
—
more about
trans-
study the kidney and digestive
systems.
/wiAMTinMii Ciliated epithelia Ciliated epithelia are nontransporting
tis-
i
)
la
•J
parts of the female
lumen
tract.
covered with
cilia
that beat in a coordinated, rhythmic fashion,
moving
and
particles across the surface of the tissue. Injury
to the
surface of the tissue facing the
fluid
cilia
one
•
effect of
smoking.
It is
is
considered to contribute to the higher
incidence of respiratory infection in smokers, because the
Basolateral
is
movement.
or to their epithelial cells can stop ciliary
Paralysis of the ciliated epithelium lining the respiratory tract
•
•
•
The
reproductive
cell
•J[•
jj
and
sues found lining the respiratory system
epithelial
/
mucus
•
membrane
B
is no longer swept up out of the lungs by the 3-19# shows the ciliated columnar epithelium of the
that traps bacteria
Extracellular fluid _
cilia.
•
when you
porting epithelia
•
9
(Transporting
(b)
affect the transport of ions
will learn
•
•
junction
in response to vari-
• •
•
across the epitheli-
Furthermore, the transport properties of
an epithelium can be regulated and modified •
transport
for
a transporting epithelium prevent movement between the cells. To cross the epithelium, substances must go through two cell membranes. Tight junctions
Movement of substances
Figure 3-18
Figure
in
across tight
trachea.
and
leaky
Protective epithelia The protective epithelia are designed to prevent any exchange between the internal and external environ-
epithelia
ments. They are ers of cells.
environments. These epithelia are found lining the hollow tubes
and the kidney, where lumens open into
of the digestive system
the external environment [*
stratified tissues,
The epidermis
\epi,
composed x
upon
of
many
stacked lay-
derma, skin) and linings of
the mouth, pharynx, esophagus, urethra, and vagina are tective epithelia.
The multiple
cell layers
There are several characteristics of transporting epithelia
Some
of
these tissues are toughened further by the secretion of keratin [keras,
(Fig. 3- 18b):
pro-
of this tissue type pro-
tect areas subject to mechanical or chemical stresses.
p. 4|.
all
horn], the
same insoluble protein abundant
in hair
and
nails. 1.
Cell shape.
The
cells
much
of transporting epithelia are
thicker than those of exchange epithelia, so they act as a barrier as
well as
an
entry point. The cell layer
thick, but the cells are cuboidal or 2.
Membrane
columnar
modifications. The apical
is
only one
cell
the sur-
face of the cell that faces the lumen, has microvilli, fingerlike
projections that increase the surface area available
transport.
A
cell
with microvilli has
face area of a cell without
membrane,
may 3.
also
them.
at least
chemicals, bacteria, and other destructive forces, the cells in ha\ e a short
life
span. In the deeper layers,
20 times the
foi
sur-
In addition, the basolateral
cells are
them
produced
you wash your
face,
you scrub
As the skin ages, the rate of (Retin- A
).
a
off
dead
cell
cells
surface layer.
turnover declines, tretinoin
drug derived from vitamin
and surface shedding so
on the
A.
speeds up
cell
division
that the treated skin develops a
more
youthful appearance.
the side of the cell facing the extracellular fluid,
have folds that increase the
cell's
Secretory epithelia Secretory epithelia are composed
surface area.
Cell junctions. The cells of transporting epithelia are firmly
that produce a substance inside the cell
attached to adjacent cells by moderately tight to very tight
tracellular space in a process
junctions. This thelial cell
new
continually, displacing the older cells at the surface. Each time
in shape.
membrane,
Because the protective epithelia are subjected to irritating
means
on one
that material
side of the tissue
must move into an
and out of the
other in order to cross the epithelium.
cell
epi-
on the
may
be scattered
among
known
and
release
it
o\ cells
into the ex-
as secretion. Secretory cells
other epithelial
cells,
or the)
may group
together to form a multicellular gland. There are two types of cretory glands: exocrine glands
se-
and endocrine glands. 69
!
CHAPTER
3
AND
CELLS
TISSUES
Ciliated epithelium lining the airways.
(a)
(b)
Scanning electron micrograph showing
ciliated cells
mixed
with cells covered with shorter microvilli.
Cilia
Microvilli
Golgi
apparatus
Nucleus
Basement
membrane
l*3&&r
Mitochondria
Figure 3-19
Ciliated epithelia
Exocrine gland
RUNNING PROBLEM
cells
produce two types of secretions. Serous
many
secretions are watery solutions, and
Many kinds of cancer develop in epithelial cells that are subject to damage or trauma. The cervix consists of two types of epithelia.
the outside of the cervix. At the opening of the cervix, these
come
together. As Jan
lies
Mucous
exocrine secretions.
the inside of the cervix, while a protective epithelium covers
of epithelia
solutions containing glycoproteins
Goblet
cells,
shown
to take samples of cells from both inside
and outside her
cervix.
with
She then smears the
fixative.
Question
3:
cells
on
a slide
a
little
gested,
What kind of damage
or trauma are cervical ep-
and
acts as a lubricant for
epithelia
normally subjected to? Which of
more
is
its
food to be swallowed, in-
between the epithelium and the
and they produce both serous and mucous
secretory
cell,
tions. For
example, the salivary glands release mixed secretions. secretions, or
hormones,
are released
secre-
by ductless
two types of glands or single
likely to
and proteoglycans.
and microorganisms inhaled or
as a protective barrier
Endocrine ithelial cells
are
environment. Some exocrine glands contain more than one type of
and sprays them
sent to a lab for evaluation.
slides will
serous
brush
now be
The
en-
in Figure 3-20 •, are single exocrine cells that
produce mucus. Mucus
as a trap for foreign particles
and
all
mucus)
secretions (also called
sticky
on the exam-
ining table, her physician uses a small spatula
them contain
zymes. Tears, sweat, and digestive enzyme solutions are
Secretory epithelium with mucus-secreting glands lines
two types
of
be affected by trauma?
mones then
oooOoo
cells directly into
the extracellular space. Hor-
enter the blood for distribution to other portions of
the body, where they regulate or coordinate the activities
ous
tissues, organs,
ol vari-
and organ systems. Some of the best-known
endocrine glands are the pancreas, the thyroid gland, the gonads.
and the
pituitary gland. For years,
it
was thought
that
all
hor-
be onto
mones were produced by cells grouped together into endocrine glands. We now know that isolated endocrine cells occur scat-
the surface of the skin or onto an epithelium lining one of the in-
tered in the epithelial lining ol the digestive tract, in the tubules
Exocrine glands release their secretions into the external en-
vironment
\exo-,
outside + krinein, to secrete]. This
may
ternal passageways, such as the airways of the lung or the
lumen
of the kidney,
Of the intestine. In effect, an exocrine secretion leaves the body.
This
is
important to know,
cretions, like lite.
stomach
acid,
Most exocrine glands
tubes
known
as ducts.
70
you consider that some exocrine
have
a
pH
that
release theta
Sweat glands,
the breast, salivary glands, ocrine- glands.
if
tin- liver,
is
se-
incompatible with
products through open
mammary
glands found
and the pancreas
are
.ill
111
ex-
and
Figure 3-21
exocrine
•
glands.
downward
in
the walls ol the heart.
shows the
epithelial origin of
During development,
into the supporting tissms
link to the parenl epithelium in the
or
dud
glands lose the connec the bloodstream.
ting cells
and
epithelial
cells
grow
Exocrine glands retain
form of
that transports the se< ivtion to
endocrine and
its
a
a
hollow passageway
destination. Endocrine
se< rete theil
hormones
into
Tissues of the
Body
Goblet cells secrete mucus into the lumen of hollow organs such as the intestine.
Goblet
Figure 3-20
cells
CHECK
Epithelium 1
4. List
Connective tissue
Answers: p. 83
the five functional types of epithelia.
15. Define secretion.
During development, the region of epithelium destined to become glandular tissue divides downward into the underlying connective tissue.
1
Name two
6.
properties that distinguish endocrine glands from
exocrine glands. 1
7.
The
basal lamina of epithelium contains the protein fiber
laminin. Are the overlying cells attached by focal adhesions
or 18.
hemidesmosomes?
You look
at a tissue
under a microscope and see a simple it be a sample of the skin surface?
squamous epithelium. Can Explain. 1
9.
A
cell of
the intestinal epithelium secretes a substance into
the extracellular
Endocrine
Exocrine
fluid,
where
carried to the pancreas.
endocrine or an exocrine
Duct
I-i
Connecting disappear
tural
Exocrine secretory cells
picked up by the blood and cell
an
cell?
Connective Tissues Provide Support and Barriers Connective
cells
it is
the intestinal epithelium
Is
tissues, the
second major
support and sometimes
tissue type, provide struc-
a physical barrier that,
specialized cells, helps defend the
along with
body from foreign invaders
such as bacteria. The distinguishing characteristic of connective Endocrine
tissues
secretory cells
is
the presence of extensive extracellular matrix contain-
ing widely scattered Blood vessel
A
hollow center, or lumen, forms in exocrine glands, creating a duct that provides a passageway for secretions to move to the surface of the epithelium.
Figure 3-21
Development
front epithelium
The
cells secrete
and modify the matrix
of the tissue. Connective tissues range from blood, to the support Endocrine glands lose the connecting bridge of cells
them to the parent epithelium. Their secretions go directly into the bloodstream.
tissues for the skin
and
internal organs, to cartilage
and bone.
that links
Structure of Connective Tissue The matrix of connective tissue is a ground substance of proteoglycans and water in which insoluble
•
cells.
of endocrine
ami
exocrine glands
fibrous protein fibers are arranged,
much
like
The consistency of
suspended pieces of
fruit in a gelatin salad.
ground substance
highly variable, depending on the type of
is
71
CHAPTER
CELLS
3
connective
and
at the
AND TISSUES At one extreme
tissue.
other extreme
is
the watery matrix of blood,
the hardened matrix of bone. In be-
is
tween are solutions of proteoglycans that vary
in consistency
from syrupy to gelatinous. The term ground substance
some-
is
times used interchangeably with matrix.
The
Connective
if
tissue cells are described as fixed
they remain in one place, or mobile
Fixed
to place.
are responsible
and mobile found
The mobile
storage.
mainly
cells is
it
itself is
connective tissue
distinction at least
between fixed
one
cell
often indicates a
cell
that
on
either
is
down
a connective tissue cell
these suffixes should help
and
cells
name
example, are connective tissue
matrix are identified by the suffix
be given the suffix
-cyte,
-clast [klastos,
meaning
broken].
down ma-
you remember the functional difference found in bone.
ground substance, con-
In addition to secreting glycoprotein
found
gated into insoluble
duced]
in the matrix of connective tissue, aggre-
fibers.
Collagen
[kolla,
the most abundant protein in the
is
one-third of
its
dry weight.
It is
Three other protein
is
connective
fibers in
The amount and
steel.
one of the distinguishing chartissue.
connective tissue are
wavy
elastin, fib-
rillin,
and
to
original length after being stretched. This property
its
fibronectin. Elastin
as elastance. Elastin fibrillin to
sels,
and
is
a coiled,
combines with the very
form filaments and sheets of
important in skin.
elastic tissues
As mentioned
earlier,
protein that returns is
known
thin, straight fibers of
elastic fibers.
These two
such as the lungs, blood vesfibronectin connects
cells to
extracellular matrix at focal adhesions. Fibronectins also play
important role in
wound
healing and in blood clotting.
also the
Types of Connective Tissue
Table 3-4 describes in detail
the different types of connective tissue. The most
and dense connective
of connective tissue are loose
pose
tissue, cartilage,
types
tissue, adi-
bone, and blood.
Loose connective tissues that underlie skin
common
(Fig.
3-22 •) are the elastic tissues
and provide support
connective tissues are
tissues
for small glands.
whose primary function
is
Dense
strength
glue
+
human
-genes, pro-
body, almost
most diverse of the four
ligaments, and the sheaths that surround muscles and nerves. In
these tissues, collagen fibers are the
dominant
type.
Tendons (Fig. 3-23*) attach skeletal muscles to bones. Ligaments connect one bone to another. Because ligaments contain elastic fibers in addition to collagen fibers, they
have a
limit-
ed ability to stretch, whereas tendons cannot stretch.
Table 3-4: Types of Connective Tissue
TISSUE
NAME
GROUND SUBSTANCE more ground than and cells
Loose connective
Gel;
tissue
fibers
Dense, irregular connective tissue
ground
Dense, regular connective tissue
ground
Adipose
Very
More More
fibers
FIBER TYPE AND ARRANGEMENT
MAINC
Collagen,
elastic,
fibroblasts
reticular;
random
Mostly collagen; random
than
I
I
I
IVI'IN
WHERE FOUND around blood and organs, under epithelia
Skin,
vessels
Fibroblasts
Mus
>
P
1
E+F
c
C
G+H
0)
(1)
Net free energy
01 Ll_
change
Time
KEY
some
Time
Substrates
was trapped
of the activation energy
of the products. called
A
is
A
A
plot of
•. Note that the products
energy than the reactants A and
may
the bonds of glycogen during
out
energy
tion gradient.
An important
reaction
is
is
C
and
D
have
is
shown
a lower free
be given off as heat. In
is
tion is
when
(P,),
and
AIT and water Knergy
1
II
.
is
the high-energy phosphate
a
tew
to
form
metabolic reactions
energy
is
Where does the activation energy for come from? The simplest source of activation
to couple an exergonic reaction that produces energy to
an endergonic reaction that requires
of the
AH' molecule
reaction:
ADP
ATP
+
P,
—G * H
In this type of
A
plot of net free energy
G
E + F
+
H+ +
energy
+ H,
is
change
shown
is
retained by the products.
for
an endergonic reaction.
in Figure 4-4b.
Compare
this ender-
gonic reaction with the energy-producing reaction of figure 4-4a, in
which
coupled reaction, the two reactions take place
all
activation energy
added
to the reactants
was
released
during the reaction.
Some
of the energy added to an endergonic reaction remains
lizing reactions are often synthesis reactions in
made from
,ii
id I
to drive the
endergonic reaction of
F.
lowever,
coupled to trap
not always practical for reactions to be direct 1\
it is
like this.
Consequently, living
and save energy
common method
for
gy electrons carried on nucleotides molecules
NADU,
I
usually transfer
have developed waj
cells
released by exergonic reactions.
trapping energy-
is
most of
all
.
(Fig.
s
The most
form of high-ener-
in the
41].
|»» p.
\DH : and NADPH
electrons of their hydrogen atoms
trapped in the chemical bonds of the products. Thus, energy-uti-
molecules are
in
si-
the same location, so that the energy from
ATP can be used immediately
energy-Utilizing, reactions, part ol the acti-
vation energy added to the reactants
fa-
breaking the high-energy bond of ATP to drive an endergonic
I
During endergonic, or
of the most
released during this rea
vation energy, the
C +
less likely
A + B reaction shown *
D, the reverse reaction
is
it
main reasons
then so
many
A + B
is
shown
B. Reversible reactions are
that
that they are aided
is
possible,
^=^ C +
D.
biological reactions are re-
by the specialized proteins known
enzymes.
in
CHECK
Answers: p. 122
recall,
(Fig. 4-6)
What
5.
the difference between endergonic and exergonic
reactions?
the larger the acti-
that the reaction will proceed
is
6.
If
you mix baking soda and vinegar together
in
a bowl, the
reactions could be reversed with
mixture reacts and foams up, releasing carbon dioxide gas.
some
reactions have such large activa-
Name
your study of physiology, you
versible reactions.
is
in
tion energies that they are essentially irreversible. In
C + D
>
all
spontaneously. Theoretically input, but
C + D
A + B > A +
a large release of energy in the for-
has a large activation energy. As you will
enough energy
C + D
the reverse of the
was
Figure 4-4a. Because there
ward reaction A + B
is
the reaction
if
of the
activation energy of the reverse reaction. For example, look at
energy of the reaction
,
ATP
with arrows that point in both directions:
versible
activation
of
the reaction
the net free energy change of the forward reaction contributes to the
the
Energy released by exergonic reactions can be trapped in the high-energy electrons of NADH, FADH 2 or NADPH. Energy that is not trapped is given off as heat.
encounter a few
will
in this
reaction.
Do you think this reaction is endergonic or exergonic? Do you think it is reversible? Defend your answers.
7.
irre-
However, most biological reactions are
the reactant(s) and product(s)
re-
k ENZYMES Enzymes
GRAPH QUESTION
are biological catalysts, proteins that speed
Activation energy
this
rate
of chemical reactions without themselves being changed. With-
out enzymes, most chemical reactions in the an endergonic or exergonic reaction? Is
up the
slowly that the
cell
would be unable
to live. Because
not permanently changed or used up alyzes,
we might
write
it
in a reaction
A + B + enzyme This
way
-»
of writing the reaction
cell
would go so an enzyme
in the reaction that
it
is
cat-
equation this way:
C + D + enzyme
shows
thai the
enzyme
partici-
A and Bbui Is unchanged at the end ol thereA more common shorthand for enzymatic reactions shows
pates with reactants action.
the
name
of the
enzyme above
the reaction arrow, like
C+D
A + B in
this:
enzymatically catalyzed reactions, the reactants are called
substrates
Time
KEY Substrates Activation of reaction
Reaction process Products
Enzymes L€>wer the Activation Energy of Reactions How
does
.\\\
enzyme
Increase the rate ol a reaction? in thermo-
dynamic terms, H lowers the activation energy, making • Figure 4-6
90
Some rem
lions
have large
m tivation energies
likely thai the reaction
will stait
ii
Ig.
4-r»t.
I
n.
\
it
more
mes accomplish
Enzymes
of
Activation energy
without
enzyme
one million molecules of C0 2 and water to carbonic
absence of enzyme, Lower energy of
activation
presence
in
enzymes
enzyme
takes nearly 100 seconds for only
it
and water to be converted to carbonic
would go
in cells, biological reactions
would be unable
cell
3
C0 2
cule of
acid. In the
to obtain
enough energy
one moleWithout
acid.
so slowly that the
to live.
A+B
O
£
Enzymes Bind
a E
How
>.
to Their Substrates
does an enzyme bring the substrates into the best position
them
Most enzymes
to react?
are large protein molecules with
§
for
e
complex three-dimensional shapes [# p. 39]* On each enzyme molecule is a region known as the binding site, part of the protein
When
molecule that actually binds to the substrates.
en-
zyme-substrate binding takes place, the substrate molecules are
brought close to each other and to the enzyme's active
the
site,
region that promotes reaction of the substrates with each other.
Time
Activation of reaction
Reaction process Products
was thought that the binding
it
Enzymes lower the activation energy of
one another
fit
The binding
reactions
site
needs only to attract the substrates to that
region of the enzyme. Then, as the binding
ly
by binding to the reactant molecules and bringing them
to-
gether Into the best position for reacting with each other. With-
out enzymes, the reaction would depend on the random collision of the molecules to bring
them
into alignment. Notice in the
fig-
ure that neither the starting nor ending free energy content ot the substrates
The
and products has hanged.
rapid than the
same
by an enzyme
is
much more
reaction taking place in the absence of the en-
zyme. For example, consider the enzyme carbonu
which converts
C0 2 and
interaction
binding
one second
shown
is
site
to tatalyze the conversion
mally, lysosomes within cells contain
worn-out parts of the
enzyme
cell. In
enzymes
that digests specific glycolipids called gangliosides,
them
in
nerve
is
cells in
and function abnormally. Inwith Tay-Sachs disease slowly lose muscle control and
the brain, causing fants
that digest old,
Tay-Sachs, hexosaminidase A, an
absent. As a result, gangliosides accumulate
brain function.
Question
1:
They
to swell
usually die before
Hexosaminidase A
is
age
gliosides from the light-sensitive cells of the eye.
information,
what
is
more
close-
of enzyme-substrate
According to
this
model, the fit ei-
would en-
enzyme to bind to either reactants or products and thus
be able to catalyze i.
do
.in
a single
this.
Induced
fit
explains reversibility better than
model,
the older lock-and-kej
matched
reaction in both directions. In tact, en-
in
which the binding
site
was
to either the substrates or the products, but not to both.
Enzyme
Most enzymes
Specificity
react
with only one
of substrates or with a
group of similar substrates. The
ad enzyme to catalyze
a
is
certain reaction or a
called specificity,
ability of
group of closely
some enzymes
set
re-
are very spe-
about the reactions that they catalyze. For example, the sole
enzyme glucokinase is to attach a phosphate group onto glucose molecules when they enter a cell. Other enzymes act on whole groups ot molecules. The enzymes known as peptidases function of the
ad on peptide bonds of polypeptides without regard for which two amino acids are joined by those bonds. Peptidases therefore are not very specific in their action.
An Enzyme's Name
four.
also required to
in figure 4-8b.
model
fit
ther the substrate or the product molecules. This trait
able an
cific
a particularly devastating condition. Nor-
is
and the substrates
has an intermediate shape that can change to
lated reactions
RUNNING PROBLEM Tay-Sachs disease
site
changes shape to
ahhydrase,
water to carbonic add. A single molecule
of carbonic anhydrase takes
site
to the substrates. This induced-fit
zymes
(
rate of a reaction catalyzed
was
exactly.
begin to interact, the binding this
site
fit the substrates exactly, the way a key fits into a lock. A representation of this lock-and-key model of enzyme activity is shown in Figure 4-8a». In recent decades, however, scientists have discovered that the binding site and the substrates do not
need to Figure 4-7
years,
shaped to Substrates
•
many
For
KEY
remove ganBased on
this
Function function in
Gives Information About Its Most enzyme names are important clues to their a cell. The names of most enzymes are instantly
another symptom of Tay-Sachs disease
besides loss of muscle control
and brain function?
oCjo © ©®
•Recently, researchers discovered that
R\
\
can sometimes
act as a catalyst.
91
CHAPTER 4 CELLULAR METABOLISM
(a)
Lock-and-key model In this
Binding
older model, the
site
site
was an exact match
for the substrates.
/
\ ENZYME
(b)
enzyme binding
^^
\
model
Induced-fit
model, the enzyme binds most tightly to an intermediate form of substrate or product. This model compatible with reversible reactions that are catalyzed by one enzyme. In this
is
more
Intermediate form
•
Two models of enzyme binding sites
Figure 4-8
recognizable by the suffix
name
-ase.
The
first
of reaction, the substrate
upon which the enzyme
acts, or
both.
For example, glucokinase, mentioned previously, has glucose as
and
substrate
as a kinase
substrate. Addition of a
adds a phosphate group
phosphate group
is
called
[
$
its
p. 28] to the
phosphorylation.
The peptidases mentioned above break up peptides into smaller peptides or
amino
amino
Enzymes and
part of the enzyme's
(everything that precedes the suffix) usually refers to the type
acids by cleaving the peptide
bond
that links the
a
hours following a heart attack, damaged heart muscle
enzymes into the blood. One way son's chest pain
role in the
cells release
determine whether is
Some
a per-
to look for el-
diagnosticalh
important enzymes and the diseases of which they are suggestive are listed in Table 4-2.
CHECK
for
8.
different digestive
enzymes, are examples of older enzyme
names.
A few enzymes come
known
as
alyze the
isozymes
same
ut tissues.
I
[iso-,
10. in a variety oi related forms, these are
equal].
Isozymes
are
enzymes
several isozymes, Including
and
a se
8
"5
0)
a>
rr
DC
20
40
30
50
Temperature This
60
5
6
7
PH
f'C)
enzyme
Most enzymes humans have
denatures around 50° C.
in
optimal activity near the body's
GRAPH QUESTION
internal Is
the
at
30
pH
GRAPH QUESTION
of 7.4.
enzyme more active C or at 48" C?
If
Figure 4-12
Effect of
pH and
The
marinated
is
hydrogen ions that
acidic lime juice contains
bonds
rupt hydrogen
muscle proteins of the
in the
fish,
in
dis-
causing
the proteins to lose their configuration. As a result, the meat be-
comes more firm and opaque,
just as
it
would
if it
were cooked
pH and enzymes
crease the activity of
changes exceed some altered so
the
its
much
enzyme
restored
if
is
temperature can increase or de(Fig.
critical point,
that
its
activity
is
4-12 •). However, once the
the structure of the destroyed.
said to be denatured. In a
the modulator
original shape as
denaturation
way
is
a
if
few
When
enzyme
is
this occurs,
cases, activity
can be
removed. The protein then resumes
is
nothing had happened. Usually, however,
permanent
to unfry an egg or
loss of activity.
uncook
There
is
certainly
no
and pH on enzymes and other
one reason that these
factors are so closely regulated
is
falls
from 8 to
7.4,
to the activity
enzyme?
line to chat with his girlfriend, the cashier.
buying
a ticket, but
from getting
he prevents the people
in line
interest in
behind him
their tickets for the movie.
Allosteric
modulators
shape)) bind to the
[alio-,
other +
stereos,
(
1
)
site (Fig.
binding
activity. Allosteric
site for
gen-binding
ability
changes with
allosteric
in
of
a
and
increase the probability of enzyme-sub-
Chapter 18 you the
(2)
decrease the
the substrate and inhibit
modulation also occurs
enzymes. For example,
site
(as
4-14 •). This type of
binding and enhance enzyme activity or
affinity of the
solid
enzyme away from the binding
modulation can either strate
He has no
respiratory
enzyme
in proteins other will learn
protein
how
than
the oxy-
hemoglobin
modulation by carbon dioxide,
H\ and
several other factors.
a piece of fish. The potentially dis-
astrous influence of temperature
proteins
of the
change the shape of the binding
with heat. Small changes in
pH
temperature on enzyme activity
ceviche, the national dish of Ecuador, raw fish
lime juice.
the
what happens 1
•
9
8
A competitive inhibitor blocks substrate binding at the binding site.
by the body.
Chemical Modulators that bind to
enzymes and
Chemical modulators are molecules alter their catalytic ability.
There are
three types of chemical modulators: competitive Inhibitors,
al-
Binding site
losteric
modulators, and covalent modulators.
Competitive inhibitors bind to the enzyme site,
blocking the
site
at its
and thus preventing the substrate from
binding with the enzyme
(Fig.
4-13 •).
hibitors are alternative substrates that
Some
competitive
and block the binding are like the
guy
site
who
without being acted upon slips into
in-
can also be acted upon by
the enzyme. Others are simply molecules that bind to the
They
binding
enzyme
themselves.
the front of the movie ticket
Figure 4-13
Competitive inhibition 95
w
CHAPTER 4 CELLULAR METABOLISM
(a)
Allosteric activation
Binding site
Allosteric activator
Modulator binds to enzyme away from active site.
Enzyme without modulator inactive.
is
(b)
Enzyme
with
modulator
is
bound active.
Allosteric inhibition
Binding site
Allosteric inhibitor
Modulator binds to enzyme away from binding site and decreases enzyme-substrate binding.
Enzyme without modulator active.
is
Figure 4-14
Allosteric
modulation
CHECK
Covalent modulators are atoms or functional groups that use covalent bonds to bind to enzymes and alter the enzymes' 1 1
properties. Like allosteric modulators, covalent
either increase or decrease the activity of the
most
common
Many enzymes when
covalent modulators
.
may
on and
off or
processes
the phosphate group.
1
2.
Match the modulator
penicillin.
Allosteric
1.
Bind by covalent bonds
Competitive
2.
Bind away from the binding
(c)
Covalent
up and down allows the
3.
Bind to the binding
and
4.
Inhibit activity only
5.
Inhibit or
noticed that Penicillium mold inhibited bacterial growth.
from the mold and used
it
a< ttve
ingredient penicillin
to treat infections in
humans. Yet
until 1965 that researchers figured out exactly
antibiotic works. Penicillin
to a key bacterial so,
it
unable to make
is
a
tli.it
how
it
the
competitive inhibitor that binds
enzyme by mimicking
forms bonds
verslbly Inhibits the
the normal substrate, in
are unbreakable
and thereby
irre-
enzyme. Without the enzyme, the bacterium
a rigid tell wall.
terium swells, ruptures, and dies
96
action(s).
its
site
enhance
site
activity
known chemical modulators is the antibiotic Alexander Fleming discovered this compound in 1928,
By 1938, researchers had extracted the
is
to
of the best
when he
doing
enzymatic reactions that an enzyme
(b)
energy-producing pathways.
was not
22
affect.
(a)
regulate the flow of biomolecules through synthetic
One
in
1
enzyme. One of the
phosphate group forms a covalent bond with them. The
a
Name two
modulator can
can be either activated or inactivated
in the cell
ability to turn reactions cell to
is
modulators
Answers: p.
Without the
rigid wall, the bat
Enzyme anil Substrate Concentration Affect Reaction Rate We ther
measure the
how
fast
strates are fa< tois,
rate ot
an enzymatic reaction
the products are synthesized or
consumed. Reaction
rate
can
how
fast
a
ei-
the sub-
number
ol
amount ot enzj me mammals we consider
including changes In temperature, the
he
temperature
to
amount and
substrate concentration as the
.it
monitoring
w altered in
present, or the substrate concentration. In
th.it
In
iii
t
essentially
reaction rate.
constant,
[his
two
leaves
mam
enzyme variables
,
Enzymes
Reaction Rate Is Directly Related to the Amount of Enzyme Present Enzyme amount is a major determinant of the rate of an enzymatic reaction.
there
is
no enzyme, most
enzyme is present, the rate be proportional to the amount of enzyme.
metabolic reactions go very slowly. of the reaction will
If
If
The graph in Figure 4-1 5 • shows the results of a typical experiment in which the amount of substrate remains constant while the crease in
GRAPH QUESTION
amount of enzyme is varied. As the graph shows, an inthe amount of enzyme present causes an increase in the
rate of the reaction.
As an analogy, think of the checkout lines in a supermarket.
Imagine that each cashier are substrates,
there are in
means
an enzyme, the waiting customers
and those leaving the
store with their purchases are
25
a
that
reaction, the presence of
more binding
In this
At the
more enzyme molecules
sites are available to interact
with the
75
50
100
125
150
175
*
Substrate concentration (mg/ml_)
One hundred people will get checked out faster when 25 lines open than when there are only 10 lines. Like-
products.
wise,
is
•
experiment, the amount of rate the enzyme
maximum
Figure 4-16
substrate molecules. As a result, reactants are converted into
enzyme was
constant.
said to be saturated.
is
Effect of changing substrate concentration
on
rate
products more rapidly.
Regulating
enzyme concentration
an important strategy
is
that cells use to control their physiological processes. Cells
amount
enzyme by influencing both its synthesis and its breakdown. If enzyme synthesis exceeds breakdown, enzyme accumulates and the reaction catalyzed by the enzyme speeds up. If enzyme breakdown exceeds synthesis, the amount of enzyme decreases, as does the reaction rate. Even when laamount of enzyme is constant, there is still a steady turnover of enzyme molecules. alter the
of an
tional to the substrate concentration. But
once the concentration
beyond
a certain level, the en-
of substrate molecules increases
zyme molecules have no more binding sites free molecules. The enzyme is catalyzing reactions and the
tration of
enzyme
is
If
cording to the concentration of substrate, figure
tration
is
the concen-
constant, then the reaction rate will vary ac-
the results of a typical experiment In which the
4- 16
• shows
enzyme concen-
constant, but the concentration ol substrate varies. At
low substrate concentrations, the reaction
rate
is
sion
directly propor-
Q.
3
belt In
Initially,
GRAPH QUESTION
the belt
Q. O!
What is the rate when the enzyme concentration is equal to A?
g C o o «
When
*-•
the rate
enzyme
what
the concentration?
was bringing canch
mouth
i
DC
i
i
r
A B C Enzyme concentration In this
rapidly,
to he a so fast that she couldn't
pack
it
maximum
rate.
That
was working
she'
at
her
point. (Her solution
was to
all
canch
stuff the
as well as into the box!)
Answers: p.
What happens to the rate of an enzymatic enzyme has reached saturation?
reaction
Reversible Reactions he stud]
into
when
1
22
the
Obey the Law of Mass Action
ol reaction rates in cells
is
complicated by the
fact that
is
o
Ba
more
14.
is
little
to increase her packing speed to keep up. Finally, the
reaction as the
I
2.5 mg/sec,
televi-
it
What happens to the rate of an enzymatic amount of enzyme present decreases?
Ei
can,
on the con-
3.
1
-
days of
removing the candy and putting
difficulty
the boxes because
E
oo
it
was moving slowly,
CONCEPT CHECK
-
some reactions tion A + B
are reversible. This *
C
+
D
In the reverse reaction,
—*
means
that the forward reac-
can reverse, so that the products
become the products.* What then determines in which
C + D
become
A
*
B.
the reactants and
the reactants
direction the reaction
is
to
experiment, the substrate amount remains constant.
go? The answer Figure 4-15 rate
in the early
ucy show. Lucille Ball was working
was Lucy's saturation
0)
•
/
the box. Gradually, the belt brought candy to her
and she had
T3
o 2
(Mr
and she had no
(0 k_
/ /
as fast as
value. This condition
veyor belt of a candy factory, loading chocolates into the
Into her
o r2 (Some of the added substrate is converted into product.)
A+B
two
have
lower-than-normal
enough
(c)
who
um
D
the substrate and product concentrations until the equilibri-
ratio
is
restored.
The law
of mass action
is
important
in
phys-
iology because as the concentration of substrates changes, the r,
The
change
substrates to products
ratio of
always the same
is
•
=r2
is
reflected in the concentrations of the products.
Enzymatic Reactions Can Be
at equilibrium.
Categorized Law
of mass action Although this figure shows the amount of A + B equal to C + D at equilibrium, the actual ratio can vary, depending on the reaction. Figure 4-17
Most reactions catalyzed by enzymes can be
classified into
four categories: oxidation-reduction, hydrolysis-dehydration, ex-
change-addition-subtraction, and ligation reactions.
equilibrium, where the rate of the reaction in the forward direction (A + B
*
reaction (C
+ D
C + >
equilibrium, there
product. As
fast as
tion takes place:
D)
A +
in the
B),
as
shown
no net change A and B convert
is
C and D
amount
in the
to
C and
turn back into
4-17a#. At
in Figure
of reactant or
D, the reverse reac-
A and B
an equal
at
rate.
some factor disturbs this equilibrium by the amount of A and B within the system? You learned
But what happens increasing
exactly equal to the rate of the reverse
is
strate concentration.
If
is
proportional to sub-
A and
the concentration of
tem goes up, so does the
rate of the
B in the sys-
forward reaction
Oxidation-Reduction Reactions
are converted into products
the reaction
reversible, as the
is
so does the rate
and
l
and
it
rea
anhydrase
the abbrevia-
(c)
(b) -*
Some,
P, is
If
Many enzymes cell.
(= ATP)
bond and
tions transfer that energy to the high-energy
Cell
reac-
phosphate bond and
ADP^P
indicates a high-energy
more important
bond energy
Enzymes Within the
third phosphate
pounds) of ATP to support one day's worth of metabolic
versible (Fig. 4-20c).
Isolation of
molecule con-
broken during removal of the phosis
+ energy
ergy storage molecule.
forward and one for the reverse reaction,
can regulate the reaction more closely dig. 4-20b).
a nucleotide
range from 7 to 12 kcal per mole of ATP.
cannot be closely regulated except by modulators and by control enzymes, one
is
bond
of free energy released by breaking a
termined by the law of mass action. These reactions therefore
of the
often
tion for an inorganic phosphate group. Estimates of the
and direction of metabo-
reaction in either direction
will
The squiggle
Cells can use re-
enzyme can run the
4-20a#), the reaction
when
ADP +
called end-product inhibition.
Enzymes and Reversible Reactions
ATP
stored in this high-energy
is
phate group. This relationship
sometimes
is
terms of the net amount of adenosine triphosphate, or
in
taining three phosphate groups |tf p. 40).
proceeds and Z accumulates, the enzyme catalyzing the conversion of
of metabolic pathways as suppliers of energy
ATP, that the pathways can yield.
an inhibitory modulator of the pathway. As the pathway
acts as
Transfers Energy Between Reactions
1
t
Reversi
reaction
enzymes
1
rreversible in
r
Most
ami
irreversible
cells of
meta-
the body can
f
Glucose 6-phosphate
Glucose 6-phosphate
requiring rwi 3
Reversible
bolic reactions
eaction goes
only on g direction
phosphorylate glucose to glucose 6-phosphate make glucose by dephosphorylation, because they lack the enzyme glucose 6-phosphatase to. The liver ami kidney are the primarj but cannot
sites for
glucose synthesis
(b).
101
CHAPTER 4 CELLULAR METABOLISM
Glucose
• • 4 N A V
GATOR
!
G L
Y C
Glycerol
ADP
O
ATP
L
Y S
Amino acids
This icon represents the
I
s
different steps in the
r
metabolic
Look
for
it
summary in
that follow to help
Amino
navigate your
Pyruvate
Acetyl
Fatty acids
you
way through
metabolism.
Cytosol
acids
figure.
the figures
Mitochondrion
CoA
CHECK 1
6.
Name
five
ways that
Answers: pp. 122-123
regulate the
cells
movement
of
substrates through metabolic pathways. 1
7.
what
In
Amino
ATP
part of the molecule does
energy?
In
what
and
trap
part of the molecule does
store
NADH
store
energy?
acids 1
8.
What
the difference between aerobic and anaerobic
is
pathways?
k ATP PRODUCTION High-energy electrons
andH+
The
catabolic pathways that extract energy from biomolecules
and
transfer
it
ATP
to
are
summarized
production of ATP follows two the
citric
small
in Figure 4-21
common
•. Aerobic
pathways: glycolysis and
acid (tricarboxylic acid) cycle. Both pathways produce
amounts
of
ATP
directly,
but their most important contri-
butions to ATP synthesis are high-energy electrons carried by
NADH
FADH 2
and
to the electron transport system in the mito-
chondria. The electron transport system, in turn, transfers energy
from the electrons to the high-energy phosphate bond of ATP. At various points, the process produces carbon dioxide and water.
Overview of aerobic pathways for ATP production ATP can be made through aerobic pathways using the chemical bond energy from glucose, amino acids, or glycerol Figure 4-21
and
fatty acids.
The water can be used by the cell, but carbon dioxide product and must be removed from the body. All three types of
drates, proteins, citric
and
is
a waste
biomolecules used for energy (carbohy-
lipids) use the
enzymes of
glycolysis, the
acid cycle, and the electron transport system to produce
ATP. Carbohydrates enter the pathways in the form of glucose. Lipids are broken
The metabolic pathways
that yield the most
ATP molecules
are those that require oxygen, the aerobic, or oxidative, pathways.
Anaerobic
[an-,
without +
tier,
air]
pathways that can proceed
without oxygen also produce ATP molecules, but er quantities.
that
The lower ATP
yield of anaerobic
we
will
consider
how
small-
to survive for
In the tiexl se
UAA Stop UAG
e
Leu
CULT)
c o "D O O
CUA cugJ
auaJ AUG
Stop
UGG
Trp
[
AUlTl AUC y He
TO
UGA
CGC Urg y CGA cggJ
Pro
f
-O
CyS
mRNA
CGlT|
CUCUeu
If)
UGU\ UGC/
3;
Met
DNA template
How does the cell know which of the thousands of base pairs DNA to use to make a strand of mRNA? turns out that the inIt
needs to make
Q. cr
formation a
a>
segment of
DNA known
contains
the information needed to
o o Q. O 3
Thr
of
+
Star!
all
mRNA. We
cell
a
as a gene.
protein
is
contained within
a
A gene is a region of DNA that make a functional piece of
used to believe that a gene coded for only one protein
one gene-one protein theorx gene can create main proteins. (the
i,
but
we now know
that
one
GUlTl
GUcUal GUA GUGj
Alternative Splicing Creates Multiple Proteins from One Sequence of DNA
Ala
[
ihe gene
Thegenetii code rhis table shows the genetic appears in the codons ol mRNA. he three-lettei
Figure 4-31
code
as
it
I
112
tor the
is
,1
nucleotide string that Includes the codon
polypeptide to be synthesized,
.is
well as
se-
some
1
abbreviations to the right ol the brackets Indicate the amino a< ids thai these codons represent. he starl and stop codons arc also marked.
quence
itseit
noncoding
segments,
cleotides as
i
I
his allows
.i
oiling or
i
he
designation
noncoding
single piece ol
I
>N
\
is
ol
sequences
not fixed
to create
foi
a
ol
nu-
given gene.
more than one protein
Synthetic Pathways
RNA
polymerase binds
The section of DNA the gene unwinds.
RNA
A\£\d\0\d\0X0\0%.
DNA.
to
A^Xf^Xf
that contains
nucleotides bind to DNA,
creating a single strand of
^W yn
mRNA.
#%#%#%#%,
Post-translational
continues
Lf
p, Proteins that
packaged
I.?
in
modification
the Golgi.
in
will leave the cell are secretory vesicles.
Proteins that remain
f
packaged
in
in
the
cell
are
Golgi apparatus
lysosomes or storage
vesicles.
Proteins secreted
Cell
•
into extracellular
Figure 4-35
mul
space
Post-translational modification the secretory puth\su\
RUNNING PROBLEM CONCLUSION Tay-Sachs Disease In this
down
running problem you learned that Tay-Sachs disease gangliosides
also learned that a
in cells
blood
is
missing.
test
in
27 Americans
is
an incurable, recessive genetic disorder
of Eastern
European Jewish descent
in
in
which the enzyme that breaks
gene
carries the
can detect the presence of the deadly gene. Check your understanding of
summary table. more on Tay Sachs disease, go to the website
paring your answers to those
To read
One
this
You have
for this disorder.
running problem by com-
the
of the National Tay Sachs
&
Allied Diseases Association (www.ntsad.org) or see
"Tay-Sachs Disease Carrier screening, prenatal diagnosis, and the molecular era. An international perspective, 1970 to 1993" journal of the American Medical Association
QUESTION What
is
another
(1
9):2307-231
5,
Nov.
1
7,
1
symptom
of
muscle control and brain
INTEGRATION
function?
Hexosaminidase A breaks down
Damage
could cause vision problems and even
enzyme
blindness.
absent and gangliosides
accumulate cells of
in cells,
JAMA,
AND ANALYSIS
gangliosides. In Tay-Sachs disease, the is
in
993.
FACTS
Tay-Sachs disease besides loss of
270
to light-sensitive cells of the eye
including light-sensitive
the eye, and cause
them
to function
abnormally.
How
could you test whether
Sarah and David are carriers of the Tay-Sachs gene?
Carriers of the levels of
gene have lower-than-normal
hexosaminidase
A.
Run
tests to
levels in
people
who
disease)
determine the average enzyme
known and
carriers of the disease
have had in
people
of being carriers.
(i.e.,
children with Tay-Sachs
who
Compare
have the
little
likelihood
enzyme
levels of
suspected carriers to the averages for the
known
carriers
and
noncarriers.
(continues on next page)
117
CHAPTER 4 CELLULAR METABOLISM
QUESTION
FACTS
INTEGRATION The new
Tay-Sachs disease more
The new test detects the defective gene. The old test analyzed levels of the enzyme
accurate than the old test?
produced by the gene.
Why
is
the
new
test for the
test
is
AND
ANALYSIS
a direct
The old
way
to test
was an
if
a person
indirect way.
is
a carrier.
is
possible for factors other than a defective
gene to think of
test
It
enzyme level. Can you some? (See answers at end of alter a person's
chapter.)
The Tay-Sachs gene recessive
gene
carrier
and
Tt
a
What
(t).
chance that any
is
is
the
x TT
Each child has
a
50%
chance of being
a carrier
(Tt).
I
TTTtTTTt
child of a
a noncarrier will
be a carrier?
O © O © ® d) CHAPTER SUMMARY The major theme
of this chapter
acquired, transferred,
and used
biological energy
is
to
do
and how
it is
biological work. Energy
and glycogen and
stored in large biomolecules such as fats
is
is
ex-
from them through the processes of metabolism. Reacand processes that require energy often extract it from the high-energy bond of ATP, a pattern you will see repeated as you learn more about the organ systems of the body. Two other themes in the chapter involve different kinds of structure-function relationships: molecular interactions and com-
tracted tions
which
depend heavily on molecular shapes. two models of enzymesubstrate interaction, the older lock-and-key model and the newer induced-fit model. (Note that as new models are presented, they may either displace an older model or become an alternative their substrates,
also
For example, this chapter presented
model.)
The final theme presented is compartmentation of enzymes, which is essential for organizing and separating metabolic processes. Glycolysis takes place in the cytosol of the
cell, for
partmentation. Molecular interactions are important in proteins,
ample, as does the anaerobic metabolism of pyruvate to
where the function of a protein often depends on its folding into the proper shape, and in the interactions between enzymes and
The
citric
ex-
lactate.
and the electron located on the inner mitochondrial membrane.
acid cycle occurs in the mitochondria,
transport chain
is
Energy in Biological Systems 1
.
Energy is the capacity to do work. Chemical work enables and organisms to grow, reproduce, and carry out normal
2.
activities.
Transport work enables
create concentration gradients.
movement,
cells to
Kinetic energy stored energy,
cells
is
the energy of motion. Potential energy
is
(p. 86; Fig. 4-2)
move molecules to
Mechanical work
is
used for
(pp. 85-86)
Clientical Reactions 5.
4.
A chemical reaction begins with one or more reactants and ends with one or more products. Reaction rate is measured as the change in concentration of products with time. (p. 88)
7.
bonds of a molecule and the free energy of the molecule.
8.
The energy
stored in the chemical
available to perform (p.
work
is
gonic reactions,
88)
Activation energy
is
the
input ol energy required to
initial
hc-^in a reaction, (p. K8; Fig. 4-3) 6.
Exergonic reactions arc energy producing. Endergonic actions are energy utilizing,
118
(p.
K
l
;
»;
I
ig.
4-4)
re-
Energy (p.
9. 5.
Metabolic pathways couple exergonic reactions to ender-
A
(p.
89)
for driving
endergonic reactions
is
stored In ATP.
89) reaction that can proceed in both directions
is
called a
one direction hut not the other, it is an irreversible reaction. The net hange oi a rea< don determines whether that retree energj reversible reaction.
It
a reaction
i
action tan be reversed, (pp. 89
l
>0)
can proceed
in
1
1
Chapter Summary
Enzytnes 10.
Enzymes
are biological catalysts that speed
up the
rate of
15.
chemical reactions without themselves being changed. Enzymes bind to reactant molecules, bringing them together into the best position for reacting with each other. In reac-
by
catalyzed
tions
enzymes,
the
reactants
are
decrease the activation energy of the reaction, (pp. 95-96; Figs. 4-13 and 4-14)
called
substrates, (p. 90) 11.
enzyme that binds to the substrates is called the binding site. The induced-fit model of enzyme-sub-
The
part of the
binding site has an intermedishape that can change to fit either the substrate or the product molecules, (p. 91; Fig. 4-8)
16. Factors that affect the rate of
1
2.
Specificity
is
the ability of an
enzyme
to catalyze a certain re-
action or a group of closely related reactions,
(p.
17.
When an enzyme is saturated with maximum possible rate. (p. 97)
Some enzymes
are
be activated. This
91)
14.
Enzyme
Fig.
the reaction,
(p.
is
when
a reaction
the ratio of substrates to products
4-10)
by temperature, pH, and modulamodulator changes the ability of the entor molecules. A zyme to (1) bind the substrate or (2) alter activation energy of activity
works
at its
go to a state of equilibrium, where the forward direction is exactly equal of the reverse reaction. Reversible reactions obey
the law of mass action:
require the presence of a cofactor. Or-
ganic cofactors are called coenzymes, (pp. 93-94;
it
rate of the reaction in the
produced as inactive precursors and must
may
substrate,
18. Reversible reactions
to the rate 13.
enzymatic reactions include
modulation, the enzyme concentration, and the ratio of the concentrations of substrates and products, (p. 96)
strate interaction says that the
ate
Competitive inhibitors block the binding site of the enzyme directly. Allosteric modulators bind to the enzyme away from the binding site and change the shape of the binding site. Covalent modulators affect the ability of an enzyme to
is
is
at equilibrium,
always the same.
If
the
concentration of a substrate or product changes, the equilib-
rium
altered
19.
will
be disturbed,
(p.
Most reactions can be hydrolysis-dehydration,
98; Fig. 4-17)
classified
as oxidation-reduction,
addition-subtraction-exchange,
or ligation reactions, (pp. 98-99; Tbl. 4-4
94)
Metabolism 20. All the chemical reactions in the
body
are
known
enzymes to catalyze reversible reactions, (4) isolating enzymes within intracellular organelles, or (5) maintaining an optimum ratio of ATP to ADP. (p. 100) ferent
collectively
metabolism. Catabolic reactions release energy and down large biomolecules. Anabolic reactions require a net input of energy and synthesize large biomolecules. (p. 99)
as
break
22.
through their metabolic pathways by (1) controlling the enzyme concentration, (2) producing allosteric and covalent modulators, (3) using dif-
21. Cells regulate the flow of molecules
Aerobic pathways require oxygen and yield the most ATP. Anaerobic pathways can proceed without oxygen, but produce ATP in much smaller quantities, (p. 102
ATP Production interactive
//'
Phonology
25. Aerobic
Muscular: Muscle Metabolism
metabolism
of pyruvate
through the
citric
acid
cycle yields ATP, carbon dioxide, water, and high-energy electrons captured bj 23.
Through glycolysis, one molecule of glucose is converted into two pyruvate molecules, two ATP, two NADH, and two H*.
Glycolysis does not require the presence of oxygen,
(p. 103; Fig.
4-22)
metabolism, pyruvate is converted into lactate with a net yield of two ATP for each glucose molecule,
(p.
105; Fig. 4-24)
106; Fig. 4-25)
Glycogen and
lipids are the
primary energy storage moledown for ATP production
cules in animals. Lipids are broken in the process of
104; Fig. 4-23)
Synthetic
27.
and FAHH-
High-energy electrons from NADH and FADHi give up their energy as they pass through the electron transport system. Their energy is trapped in the high-energy bonds of ATP (p.
24. In anaerobic
(p.
26.
NADH
beta-oxidation,
(p.
109; Fig. 4-28)
Pathways
28. In gluconeogenesis,
verted to glucose,
(p.
amino 1
acids
and
10; Fig. 4-29)
glycerol can be con-
29. Fat Fig.
and cholesterol synthesis requires
acetyl
CoA.
(p.
Ill:
4-30)
119
.
CHAPTER 4 CELLULAR METABOLISM is controlled by nuclear genes made of DNA. The nucleotide code from a gene is transcribed into a matching code on messenger RNA (mRNA). Alternative
30. Protein synthesis
splicing of
mRNA in
The
mRNA goes
vert the (p.
may
33. Proteins
4-33)
Fig.
to the cytoplasm and, with the assistance of
RNA
and ribosomal RNA, assembles amino acids into the sequence designated by the gene. This process is
transfer
116)
the nucleus allows one gene to code for
multiple proteins, (pp. 112-114; 31.
and protein folding connewly synthesized protein to its finished form,
32. Post-translational modification
be modified in the rough endoplasmic reticu-
lum
or the Golgi apparatus. In the Golgi, they are packaged
into
membrane-bound
vesicles that
age vesicles, or secretory vesicles,
become lysosomes,
(p.
stor-
116; Fig. 4-35)
called translation, (pp. 112-114; Fig. 4-34)
QUESTIONS iMawMifc.-ftiir^i.nfjg 1
List
the three basic forms of work and give a physiological ex-
10
ample of each. 2.
protein
tivity
Explain the difference between potential and kinetic energy.
3. State
A
own
the two laws of thermodynamics in your
whose
structure
destroyed
is
altered to the point that
is
said to be
is
its
ac-
.
words.
an oxidation-reduction reaction, where electrons are molecules, the molecule that gains an electron is said to be and the one that loses an elec-
obtain
tron
11. In
moved between
,
4.
The sum of all chemical processes through which and store energy is called
cells
is
.
.
5.
In the reaction
12.
C0 2 + H 2
dioxide are the
,
cause this reaction
H2CO3. water and carbon
»
and
H 2 CO s
propriate to call water
the product. Be-
is
The
up chemical
all
re-
terms are
(b)
(c)
(d)
14. In
in the
2.
endergonic
of large biomolecules. In
the part of a protein
3.
activation energy
gy of metabolism?
molecule that actually binds the substrates
4.
reversible
5.
irreversible
a reaction that releases
6.
energy
7.
induced binding
the ability of an
enzyme
one reaction
fit
product of a metabolic
(the
.
site
8.
specificity
9.
free
10
saturation
how H + movement
16. Explain
energy
membrane
boost of energy needed
17. List the
results in
two
carrier
ATP
across the inner mitochondrial
synthesis.
molecules that deliver high-energy elec-
trons to the election transport system.
the ability of a protein 18.
its
Since 1972, fix
enzymes have been designated by adding the to their name.
sufi i
2+
thai must be presenl in order for an enzyme to work is called a _ Organic mole cules thai must be presenl for an enzyme to function are called rhe precursors of these organic molecules in our diet. come from ion,
such as Ca
or
Mg'
.The termed _ fatt) acids are broken Into two-carbon acetyl CoA molecules In a pathwaj called _. Which pathway do these acetyl CoA molecules join in order to produce ATP?
The breakdown
of lipids for energy
is
long chains of
of the substrate
>.
1
low
many
proteins,
,
.
120
last
end product) accumulates and slows or stops reactions earlier in the pathway is called
shape to fit more closely with that
An
Metabolic regulation where the
pathway
result
and reacand result in the synthesis what units do we measure the ener-
in either direction
15.
and
large biomolecules,
tions require a net input of energy
to alter
9.
breakdown of
exergonic
to get a reaction started
8.
reactions release energy
metabolism,
1.
but not another
(f)
.
a reaction that can run
to catalyze
(e)
)
.
used): (a)
called
amino group (NH 2 from a molecule (such an amino acid) is called Transfer of an amino group from one molecule to the carbon skeleton of another molecule (to form a different amino acid) is called What happens to the amino group removed from an amino acid?
of the reaction. their definitions (not
is
polymers, such as
.
as
often expressed as molarity/second.
Match these terms with
called
down
13 The removal of an
called the reaction
actions by (increasing or decreasing?) the activation energy
7.
is
to break
also ap.
are protein molecules that speed
6.
starch, it is
and carbon dioxide
speed at which this reaction occurs ,
is
from reacting molecules
H2
Using
.
catalyzed by an enzyme,
is
The removal of H 2
20.
Which
kilocalories per
and
gram
are stored In carbohydrates,
.'
t.its.
respectively
cellular organelles are Involved In lipid synthesis?
S
Chapter Summary
LEVEL TWO Reviewh maps using the following
21. Create
Map acetyl
Map
Metabolism
1:
CoA
amino ATP
gen ion concentration
terms. 2:
gradient.
Protein synthesis
Proteins are modified in the endoplasmic reticulum. Metabolic reactions are often coupled to the reaction
(c)
alternative splicing
base pairing
acids
(d)
DNA exon gene
citric acid cycle
co2 cytosol
initiation factors
ADP +
>
Pj.
proteins have S
—
bonds between nonadjacent
electron transport system
intron
FADH2
mRNA mRNA
fatty acids
ATP Some
(e)
amino acids. Enzymes catalyze
processing (f)
gluconeogenesis
nucleotides (A, C, G,
glucose glycerol
promoter RNA polymerase
glycogen
sense strand
glycolysis
start
high-energy electrons
codon stop codon
lactate
transcription
T, A,
biological
reactions.
U)
modulators change the binding site of enzymes. Allosteric
(g)
24. Define, compare,
and contrast the following terms: competi-
tive inhibition, allosteric
modulation, covalent modulation.
why
25. Explain
enzyme
in
it is advantageous an inactive form.
for a cell to store or secrete
an
mitochondria
NADH
26.
pyruvate water 22.
When bonds are
broken during
a
chemical reaction, what are
27.
those bonds?
ic
processes.
tion.
29.
Glycolysis takes place in the
1.
Biological energy
is
yields
and H 2
the advantage of converting glycogen to glucose 6-
cytoplasm; oxidative phos-
2.
Compartmentation
phorylation takes place in the
3.
Molecular interactions
Which
On what
and
transla-
organelles are involved in these processes?
molecule does the anticodon appear? Explain the molecule in protein synthesis.
role of this
mitochondria. (b)
What
CO z
28. Briefly describe the processes of transcription
Match the following theme(s) with the appropriate metabol(a)
from the aerobic breakdown of to the yield from one glucose going through anaerobic glycolysis ending with lactate. What are the advantages each pathway offers? to
phosphate rather than to glucose?
the three possible fates for the potential energy found in
23.
Compare the energy
one glucose
oxygen
The electron transport system traps energy in a hydro-
50.
Is
31.
If
\
1' 1
ATP
,in
example of potential or
releases
kinetic energ\
'
energy to drive a chemical reaction, would
you suspect the activation energy of that reaction
to be large
or small? Explain.
LEVEL THREE P 32. Transporting epithelial cells in the intestine
cose as their primary energy source.
do not use
glu-
What molecules might
they use instead? 33.
34.
t
in the right
for the reaction
A
list
+ B
column shows the *
D.
Is
this
free
mRNA codon
and
the appropriate anticodon.
DNA:
Given the following strand of DNA, list he sequence of bases that would appear in the matching mRNA. For the under-
The graph
lined triplets, underline the corresponding
CGC TACAAGTCAGGTACCGTAACG
mRNA: \nticodons:
energy change
an endergonic or exer-
gonic reaction? 3.S.
II
the protein-coding portion of a piece of edited
mRNA
is
450 nucleotides long, how many amino acids will he in the corresponding polypeptide? (Hint: The start codon is translated into an amino acid but the stop codon is not.)
E> CD
c
CD CD CD
Time 121
CHAPTER
CELLULAR METABOLISM
4
Explorations Exploration 1: Animations of Metabolism Dynamic processes such as enzyme action or movement substrate through metabolic
from the
static
pathways
Explorations are
Christine Schmidt and her tissue engineering research, go to www.bme.utexas.edu/faculty/schmidt.
of
are difficult to visualize
when they show
drawings in a textbook, even
Exploration
you can find many animations on some of them created by students. An excellent animated primer on DNA and genetics that includes the details of DNA replication, transcription, and translation can be found
no
tion in Fig. 4-32). However,
still
the web,
American for
is
Google search
a
One
site
News
the educated layperson.
Physiological
in
by the American Physiological NIPS
Sciences
Society,
pub-
over a year old can be ac-
articles
Some
articles related to topics in this
that contains these
"Death to sperm mitochondria
NetBioChem {www.mcphu.edu/ netbiochem/NetWelco.htm). Under the TOPICS button, select GRAPHICS to look at the animations on enzymology and more
and
or article. Scientific
cessed free at www.nips.org.
(www.google.com) using the search terms activation energy ani-
mation or enzyme animation.
book
is
a periodical that publishes scientific review articles
lishes review articles.
some animations on enzymes, do
animations
Readings on Metabolism
substitute for a well-written
(NIPS), published
at www.dnaftb.org.
see
3:
Although you can find information on the Internet, there
the steps in sequence (for example, the drawings of transcrip-
To
also available at www.physiologyplace.com
is
mitochondrial
DNA
chapter include:
—A ubiquitin clue to why
comes only from Mom,"
Scientific
American, March 1999.
"The
bioenergetics.
the deep, the long/designer
tall,
genomes
—extreme
engineering," Scientific American, Winter 1999.
Exploration
2:
Biomedical Engineering
Biomedical engineering (BME)
is
a rapidly
"The
growing
field
with
cellular
Scientific
chamber
doom — A
of
look at proteasomes,"
American, January 2001.
researchers in almost every level of physiology, from tiny
nanomachines
home
to
artificial
hearts
(nano =
1
"A nonconventional role of molecular chaperones:
x 10~ 9 ). The
volvement
page for the Whitaker Foundation (www.whitaker.org)
has more information about the
"BME
ing (see
(®
A
field of
Sciences 16:123-126,
biomedical engineer-
"The
Glance") as well as a news archive that
presents exciting developments. To learn
more about
human
in Physiological
June 2001.
proteomics
nology 19(5):178-181,
Dr.
News
in the cytoarchitecture,"
In-
initiative (HPI)," Trends in Biotech-
May
2001.
ANSWERS Page 85 1.
7.
Amino
indicates that energy
being released, so this
ami nucleotides always con-
acids
The foaming-up
is
tion. The relatively large
tain nitrogen.
an exergonk
amount
oi
ised indicates that the reaction
Page 88
is
Page 96
reac11.
energy is
Modulators ma\
not
body
in the
is
energy
in
motion: sunn
is
Page 92 h.
ntropy
the substMtes air (peptidase),
state
ol
randomness
9.
in
Page 90 Uons
peptides
and
sucrose
["he rea< tants are is
i
baking soda and
arbon dioxide.
model, both reactants products
site.
Ill
can
4(c)
1,
5
es,
14.
amount
ot
enzyme
present decreas-
the reaction rate de< teases
an enzyme has reached saturation, the
li
prodw
Page
the loik-andkc\
15.
iic is at its
maximum.
Inegar;
in.
Bj
«>«>
(a)
.'>.
is
dephos-
membrane
Three types of post-translational modifica-
and
cross-linking.
sepa-
intermembrane
34.
Hemoglobin
with
four
subunits
is
a
to Figttr action rate ol 2.5
Fig. 4-c>:
tration
The graph shows an endergonk
rea»
is
s.
/ spanning protein
/
-S|EJf Cytoskeleton
"
protein
Intracellular fluid
128
Peripheral protein anchors the cytoskeleton to the cell
membrane.
>
\\
^k \s
^
Figure 5-4
«m hored
I
In
to the
Fig. 1-4, p. 7|.
and
(1)
we think
we can
together as a single unit,
compartments:
If
of
the cells of the body
all
body into two main
divide the
the intracellular fluid (ICF) within the cells
the extracellular fluid (ECF) outside the
(2)
partments are separated by the barrier of the
The
cells.
These com-
membrane.
cell
extracellular fluid can be further subdivided. The di-
viding "wall" in this case
is
the tissue wall of the circulatory
system. Plasma, the fluid portion of the blood,
lies
within the
circulatory system and forms one extracellular compartment.
The
system and directly
fluid that lies outside the circulatory
bathes the
cells
stare, to stand].
is
known
as interstitial fluid [inter-,
Figure 5-13
•
between +
shows the relationships between
Intracellular fluid
Interstitial fluid
these compartments. In
many
parts of the circulatory system,
tween the plasma and the
interstitial fluid
is
no exchange
possible
be-
Leaky epithelium
due to the ECF
thick walls of the blood vessels. However, in the smallest blood
made
vessels, called capillaries, the walls are
of leaky exchange ep-
Cell
The ithelium. The capillary walls act like a sieve, retaining blood cells
and
large proteins but allowing the
cross freely through spaces
remainder of the plasma to
between the
Although many materials move
and the
interstitial fluid,
extracellular
cells
freely
[
B
compartments
is
restricted
by the
compartment (ECF) is subdivided into plasma and interstitial fluid. Material moving between cells and ECF must cross the cell membrane. extracellular fluid
membrane
Fig. 3- 18a, p. 69].
between the blood
exchange between the
ICF
intracellular cell
and
membrane.
Figure 5-1 3
tom
Body
fluid
compartments
The box
half schematically illustrates the relationships
in the bot-
between
the compartments.
133
MEMBRANE DYNAMICS
CHAPTER
5
Whether
or not a substance enters a cell
ties
of the
stand
cell
how
membrane and
depends on the proper-
of the substance
classifies
can be selective about the materials that enter
cells
them, we must look in
the high-energy phosphate ine
of
^ MOVEMENT ACROSS MEMBRANES Some
molecules, such as water, oxygen, carbon dioxide, and
lipids,
move
easily across cell
ions, larger polar molecules,
Membrane
permeability
and very
more
proteins, enter cells with
is
membranes: the
bility or polarity
not enter
and can be changed by
[
p. 28].
I
size of
the molecule and
cell
membrane
move
off other
molecules
we examand out
move from one
mem-
place to another,
molecules or off the sides of a container. out concentrated in one area of an en-
start
them
to spread out gradually
throughout the available space.
known as diffusion. Diffusion may be defined as
This process
is
the
movement
of molecules
from an area of higher concentration of the molecule to an area
proteins are the mediators that
of lower concentration of the molecule.*
If
you leave
a bottle of
use to transport molecules across their membranes.
There are two ways to categorize
how
molecules
move
term diffusion to mean any random movement of They call molecular movement along a concentration gradient diffusion. To simplify matters, we will use the term diffiision to mean
*Some
across
texts use the
molecules.
membranes. One scheme describes movement according whether
it
to
net
movement
takes place through the phospholipid bilayer or with
down
of molecules
a concentration gradient.
1
'
i
Requires no energy other than that of molecular motion
Requires energy
ATP
from J
Diffusion
Endocytosis i
1
Simple
Facilitated
diffusion
diffusion
creates
Secondary
concentration
active
Exocytosis
Primary active
Phagocytosis
gradient
transport
for
transport
1 ,
.
Molecule
Mediated transport
goes through
requires a
membrane
lipid bilayer
.
Uses a membrane-bound vesicle
protein
I
PHYSICAL REQUIREMENTS
Figure 5-14
Map
of the
ways molecules nunc
at
mw
cell
membranes
Movement
ol
substances across
be lassifled bj the energj requirements ol transport (top part ol map) oi according to whether transport uses diffusion, a membrane protein, oi a vesl< le (bottom part ol map).
cell
154
into
molecules are constantly in motion. Gas molecules and mole-
until they are evenly distributed
has a specific mechanism for transporting
across. Usually,
requirements.
of ATP. In this section
closed space, their motion causes
lipid-solu-
cell
scheme
cells.
When
bilayer. Larger or less
from crossing the
bond
cules in solution constantly
alter-
Very small or lipid-soluble substances
lipid-soluble molecules are excluded
brane unless a
All
at all.
movement
its
energy
its
the different ways that substances
all
bouncing its
different
of Molecular Movement
membrane.
can cross directly through the phospholipid
cells
may
A
Diffusion Uses Only the Energy
the other hand,
properties of a molecule will influence
across cell
them
On
large molecules, such as
difficulty or
variable
ing the proteins or lipids of the
Two
membranes.
).
port requires the input of energy from another source, such as
membranes.
cules cross
5-14
Passive transport does not require input of energy. Active trans-
mechanisms by which mole-
detail at the
membrane protein (Fig. movement according to
the aid of a
To under-
itself.
membranes an i
i
Movement cologne open and
room,
later notice its fragrance across the
from where they are more concentrated
Diffusion has the following seven properties:
1.
Diffusion
creases
a passive process. Diffusion does not require the
is
input of energy from another source, such as the energy
sessed by
all
Molecules
move from an
10.
A
called a
is
say that molecules diffuse
rate of diffusion
centration gradient.
concentration gra-
down
ammonia, the
5-15 •).
(Fig.
depends on the magnitude
The
from
the gradient,
rate of diffusion
is
is
3.
a
evenly
libra,
ual molecules are
still
the
dynamic \dynamis,
system,
balance]
moving
molecule that exits one
how
power]
and
and the
equilibrium
state
much
slower
distances. Albert F.instein studied the' diffusion of
mechanisms
long
molecules
that
is
100 u.m for
Diffusion
is
To overcome the lim-
organisms have developed
that speed
up the movement
oxygen and nutrients rapidly
at
which they enter the body
directly related to temperature.
molecules
move
to the cells.
At higher tempera-
Because diffusion
faster.
significantly affect diffusion in
ova
it
starve to death.
occurs
diffusion
rate,
Most multicellular organisms have some form
is
a result of
changes
temperature do not
in
humans because we maintain
a relatively constant body temperature. 6.
Diffusion
ecule
is,
showed
is
inversely related to
the
more slowly
molecukn it
will
size.
The
larger a
Albert
diffuse.
that friction between the surface of a particle
medium through which movement. He
rapid over short distances hut
would
rate of diffusion. Generally,
but for each
in
At that
molecular movement, as temperature increases so does the
is
another one enters. The
equilibrium
cells
from the point 5.
diffusion stops. Individ-
at equilibrium,
area,
cell
would take years
capillary.
them-
distributed
system. Diffusion
to 2, diffusion takes
of circulatory system to bring
the
that the concentration has equalized throughout the
is
1
from the nearest
tures,
Once the molecules have
through
[aequus, equal +
4.
for diffusion in-
seconds to diffuse from the blood to a
of molecules.
air.
There will be net movement of molecules until the concentration
means
needed
.
times as long?
various transport
concentration gradient.
equal everywhere. selves
to 2, the time
1
the dis-
2
itations of diffusion over distance,
as the
dropped to zero because there
rate of diffusion has
no longer
to 2
the distance doubles from
toe,
when you open
most rapid
ammonia molecules first escape from the bottle into the Later, when the ammonia has spread evenly throughout room, the
l
if
nutrients to diffuse from the small intestine to cells in the big
of the con-
larger the concentration difference,
the faster diffusion takes place. For example, a bottle of
2
from
to B. In other words,
What does the slow rate of diffusion over long distances mean for biological systems? In humans, nutrients take five
difference in the concentration of a
higher concentration to lower concentration
The
If
many
area of higher concentration to an area of
substance between two places
We
A
proportional to the
is
molecules.
lower concentration.
dient.
to point B
CONCEPT CHECK
stored in ATP. Diffusion uses only the kinetic energy pos-
2.
A
square of the distance from
tance doubles from
they are less concentrated (across the room).
Membranes
that the time required for a molecule
from point
to diffuse
where
(in the bottle) to
and found
in solution
it is
because the aromatic molecules in the cologne have diffused
Across
it
diffuses
is
mol-
Einstein
and the
a source of resistance to
calculated that diffusion
is
inversely propor-
tional to the radius of the molecule: the larger the molecule,
the slower
its
diffusion through a given
medium.
A crystal of dye, such as potassium permanDiffusion placed in a beaker of water. \s tin crystal dissolves, dye mole-
Figure 5-15 ganate,
is
cules spread
outward by diffusion.
c Diffusion of dye molecules their
down
concentration gradient
Equilibrium occurs when is uniform
the concentration
135
CHAPTER
7.
MEMBRANE DYNAMICS
5
an open system or
Diffusion can take place in
that separates two systems. Diffusion of
within a room
across a partition
ammonia
or cologne
an example of diffusion taking place in an
is
open system. There
no
are
barriers to
and the molecules spread out
to
sion can take place between
two
fill
molecular movement,
the entire system. Diffu-
different systems, such as
the intracellular and extracellular compartments, but only the partition dividing the two compartments allows the
if
summary, diffusion
In
down
movement of molecules due to random molecular
the passive
their concentration gradient
movement. Diffusion large molecules.
cule
is
is
slower over long distances and slower for
is
When
the concentration of the diffusing mole-
come to equirandom movement of
equal throughout the system, the system has
librium and diffusion stops, although the
molecules continues.
dif-
fusing molecules to cross.
For example,
if
you
close the top of
an open bottle of am-
monia, diffusion cannot spread molecules into the room because the bottle
is
not permeable to the ammonia. However,
you cover the open mouth
keeper" plastic bag with tiny holes in smell the to the
ammonia
ammonia.
a molecule, that sion.
If
the
in the
Similarly,
it,
you
is
begin to
will
room because the bag is permeable if a cell membrane is permeable to
molecule can enter or leave the
membrane
cross. Table 5-2
if
of the bottle with a "vegetable-
cell
by
diffu-
not permeable, the molecule cannot
summarizes these points.
Lipophilic Molecules Can Diffuse Through the Phospholipid Bilayer The
membranes
ability of cell
hydrophobic
their
body, and solve in
and
to act as barriers
Water
is
a direct result of
the primary solvent of the
is
vital nutrients, ions,
because of
it
drophilic
many
lipid core.
and other molecules
dis-
polar nature. But substances that are hy-
its
dissolve in water are lipophobic as a rule: they
not readily dissolve in
do
For this reason, the lipid layer be-
lipids.
tween the cytoplasm and the
cell's
exterior acts as a
boundary
that prevents hydrophilic molecules from crossing.
Substances that can pass through the lipid center of the
membrane move by
diffusion. Diffusion directly across the phos-
pholipid bilayer of a
Table 5-2: Rules for Simple Diffusion
cell
membrane
is
called
simple diffusion and
has the following properties in addition to the properties of diffu1.
Diffusion
is
an uses only the kinetic energy of
a passive process that does not require
outside energy source.
It
molecular movement. 2.
3.
4.
sion listed
1.
The
molecules that are lipid-soluble (lipophilic) can traverse the
Diffusion
is
rapid over short distances but
much
central lipid core of the steroids,
Diffusion
is
Diffusion
is
molecule
is,
membrane by
slower over
move
faster
and diffusion
is
more
inversely related to molecular size.
the slower
across the
it
The
years,
it
was thought it
from
moving through the lipid center of the bilayer, but experiments done with artificial membranes have shown that the
larger a
will diffuse.
small size of the water molecule allows
through the
tent are less
to slip
between the
readily water passes
depends on the composition of the Membranes with high cholesterol con-
lipid layer
phospholipid
membrane
it
many membranes. How
lipid tails in
that separates two systems.
bilayer.
permeable to water than those with low choles-
rate of diffusion
The rate of diffusion through a the suri.K e area, the
membrane
.irc.i
more mole(
ol the
is
terol content, till
I
he
the spaces between the Eatty acid
the kidncv are essentially cells insert special
largei
ules can diffuse across per
.i
I
membrane, the slower
diffusion will take pla
.
a
membrane
membrane,
Ibis
is
in othei
more molecules can
e
time
136
move
lipids,
simple diffusion.
that the polar nature of the water molecule prevented
through a cell membrane depends on the ability oi the molecule to dissolve in the lipid layer of the membrane. Only lipid-soluble (lipophilic) molecules can (lilluse across the membrane by simple diffusion.
the
only
a rule,
lipophilic molecules can
some phospholipid membranes. For
directly related to temperature. At higher
Diffusion can take place in an open system or across a
The
and small
membrane. As
Water, although a polar molecule, can diffuse across
proportional to the surface
io.
so-
There will be net movement of molecules until the concentration is equal. Molecular movement continues, however, so this is called a dynamic equilibrium.
Diffusion across a
9.
to dis-
the membrane's phospholipid bilayer, but only nonpolar
partition
8.
of the molecule
ability
of the membrane. Most molecules in
lution can mingle with the polar phosphate-glycerol heads of
rapid.
7.
of diffusion depends on the
difference, the faster diffusion takes place.
temperatures, molecules
6.
rate
solve in the lipid layer
Molecules diffuse from an area of higher concentration to an area of lower concentration. The larger the concentration
long distances. 5.
earlier.
max seem obvious, but
it
directly proportional to
words, the larger the
diffuse across per unit
has Important imphca-
.
Movement tions in physiology.
One
striking
surface area affects diffusion
As lung tissue fusion of
move
oxygen decreases. Consequently,
is
rate
change
in
oxygen can
less
oxygen that reaches
not enough to sustain any muscular activity and
the patient
The
a
emphysema.
destroyed, the surface area available for dif-
into the body. In severe cases, the
the cells
3.
is
example of how
the lung disease
is
is
how
in the lipid
of diffusion across a membrane
is
alter
membranes tails and
pack themselves into the spaces between the fatty acids retard passage of molecules illustrates
through those spaces
Lipophobic molecules cannot enter a sion, therefore cells
(see Fig. 5-2).
the principles of Fick's law.
must make
cell
by simple
diffu-
special provisions for their trans-
the slower diffusion will take place. This factor comes into
port.
play in certain lung conditions in which the exchange ep-
membranes through protein carriers. Ions also cross membranes through open water-filled channels. However, the movement of
ithelium of the lung
thickened with scar
is
diffusion so that the
This slows
tissue.
oxygen entering the body
is
not ade-
quate to meet metabolic needs.
Smaller
lipophobic
ions through channels
and
molecules
ions
as concentration gradients. This
rules for simple diffusion across
rized in Table 5-2.
equation
known
membranes
are
summa-
They can be combined mathematically into an law of diffusion.
as Fick's
In
an abbreviated
form, Fick's law says that: Rate of diffusion
is
it
meansjhat ion
iTi
oygjnenljjjiot
particles
by way of membrane
Fick's law.
We
in the last sections of this chapter.
such as bacteria are too large to be
transported by protein carriers. They must
move
into
and out of
vesicles.
CHECK
x concentration gradient
membrane x membrane thickness
membrane
is
1 1
the most complex of the four
has several factors that influence
it:
(
1 )
1
(2)
2.
Where does Which
is
Answers:
the energy for diffusion
more
likely
to cross a
cell
p.
169
come from?
membrane by
simple
diffusion: a fatty acid or glucose?
the size of 1
the diffusing molecule,
cell
proportional to
resistance of
terms because
movement
Macromolecules and
cells
available surface area
resistance of the
will discuss ion
cross
influenced by electric gradients as well
is
simple diffusion and cannot be predicted by using
The
The
may
between the individual
slip
phospholipids. For example, cholesterol molecules in
inversely proportional
of the membrane. The thicker the membrane,
can
Membranes
to diffusion decreases.
composition of the membrane
easily diffusing molecules
Figure 5-16
confined to bed.
to the thickness
Changes
membrane
resistance of the
increases,
Across
the lipid-solubility of the molecule,
3.
What happens
to the rate of diffusion
in
each of the
following cases?
and
(3)
the composition of the lipid layer across which
it
is
dif-
(a)
membrane
to
(b)
concentration gradient increases
diffusion increases. As lipid solubility of the diffusing molecule
(c)
surface area decreases
fusing. As molecular size increases, resistance of the
membrane
thickness increases
(continues
on next page)
Extracellular fluid
Membrane
Concentration outside cell
Molecular
Lipid
surface area
^size
solubility
i
Factors affecting rate of diffusion through a cell membrane: • Lipid solubility •
Membrane
Molecular size
• Cell
thickness
Composition
Concentration
of lipid layer
gradient
membrane
thickness
•
Concentration gradient Membrane surface area
•
Composition
•
of lipid layer
Concentration
Intracellular fluid
inside cell
Fick's
Law
Membrane
of Diffusion says:
available surface area • concentration gradient
Rate of diffusion
membrane
resistance
•
thickness of
membrane
resistance
lipid solubility
Membrane
resistance
•
molecular size
Changing the composition of the lipid layer can increase or decrease membrane resistance.
Figure 5-16
law of diffusion simple diffusion across a membMiie. Fick's
Fick's
law of diffusion mathematically relates factors that influence the rate of
137
CHAPTER 14.
MEMBRANE DYNAMICS
5
Two compartments
are separated by a
membrane
that
Both passive and active forms of mediated transport demon-
is
permeable only to water and yellow dye molecules.
strate three properties: specificity, competition,
Compartment A is filled with a solution of yellow compartment B is filled with a solution of equal
These concepts were introduced in the discussion on enzymes
concentration of blue dye.
the system
If
what color will compartment A (Remember, yellow + blue makes
for a long period of time,
yellow, blue, or green?
[i* p. 97].
undisturbed
left
is
dye,
and
saturation.
Mediated transport shares these properties with en-
zymes because both processes depend on the interaction of a sub-
be:
strate
with a protein.
green.)
Specificity 15.
What keeps atmospheric oxygen from diffusing into our bodies across our skin? (Hint: What kind of epithelium is
Specificity refers to the ability of a carrier to
move only one molecule or a group of closely related molecules. One example of specificity is the family of transporters known as the GLUT transporters. These membrane proteins move six-
skin?)
carbon sugars
Carrier-Mediated Transport Exhibits Saturation, Specificity, and Competition Movement
membranes with the aid of a mediated transport. Some mediated
of substances across cell
transport
known as carriers move only one
known
uniport
carrier protein
as
carriers that
is
move two
protein that
is
called a cotransporter.
direction,
symport
moves more than one kind If
together +
of molecule at
the molecules are
whether into or out of the [sym-,
cell,
moving
shown If
+
portare, to carry].
If
is
and
if
concentrations are equal inside the
substance against
known
called
the molecules are is
called antiport
are
and moves molecules down
passive
as facilitated diffusion.
ATP its
If
p. 35],
across cell
membranes. But
will
not transport the disaccharide maltose or
that
is
net transport stops
cell
and
when
out, the process
protein-mediated transport
or another outside source
concentration
gradient,
is
re-
and moves
the
process
a is
Competition specificity.
A
Competition
Uniport carriers
transport only
GLUT
a property closely related to
is
may move
transporter
several
group of substrates, but those substrates other for the binding the
GLUT
sites
move
transporters
members
will
on the transport
of a related
compete with each
proteins. For example,
the family of hexose sugars, but
GLUT transporter has a "preference" for one or more hexoses, based on its binding affinity. The results of an experiment demonstrating competition are
each different
in Figure 5-18
transporters are
moving
the arrow, glucose transporters have
is
.
In the initial part of this graph,
added to the extracellular
galactose
is
fluid.
Because the
a higher binding affinity for glucose than for
galactose, glucose replaces galactose
When
one
displaced from
rate of galactose transport into the
kind of substrate.
Symport carriers move two or more substrates in the same (b)
direction across the
membrane. Types of carrier-mediated transport
GLUT
galactose into a cell at a constant rate. At
on some of the binding
some cell
of the transporters, the
Antiport carriers substrates in opposite directions.
(c)
move
sites.
decreases. In this example,
Glucose
138
form of glucose
monosaccharides.
Cotransporters
Figure 5-17
a
not normally found in nature. Thus we can say that
glucose and galactose are competing for the transporter.
as active transport.
(a)
GLUT transporters
transporters are specific for the naturally occurring six-carbon
shown
their concentration gradient,
quires energy from
is
same
c.
mediated transport
known
one time
Symport and antiport
to carry].
portare,
in Figure 5-1 7b,
to find
in the
the process
being carried in different directions, the process [and, opposite
common
it is
or even three different kinds of molecules.
A
[
such as glucose, mannose, galactose, and
kind of molecule, a process
5-17aO). However,
(Fig.
fructose
(hexoses),
Movement
M
E
*r,The
GRAPH QUESTIONS Why does
•
Draw a
galactose transport decrease when glucose is added? line that
GLUT Transporter
found
diffusion
glucose transport.
o a w c
some yet
Glucose added T
CO
in
every
of the body. For
cell
It
a> co
was
o
other
was not
cells,
until
identified.
O)
cells,
many
years, scientists
different variants of the carrier. In
was independent
it
the
1
980s that the
To date,
isolated.
o
hexose sugars are
for the
glucose transport was regulated by hormones,
cells,
in
Family
carriers
assumed that there were
represents
Membranes
C
E R
Facilitated •
Across
The
first
six
hormonal
of
first
glucose transporters have been
from red blood
transporter, isolated
was named GLUT1
.
action.
glucose transporter
This protein
the facilitated
is
dif-
"o
moves glucose and other hexoses
fusion carrier that
a>
most
DC
Time
cells of
the body. The
the hepatocytes of the
brane of transporting
Glucose and galactose use the same membrane transporter. The transporter has a higher affinity for glucose than for galactose.
testine.
CLUT3
and muscle.
hormone Sometimes the competing molecule merely blot
ks the transport
i
not transported but
is
another substrate
,
in this case,
and
is
It
is
insulin.
transporter
is
a competitive inhibi tor
[
»* p.
cose transport system, the disaccharide maltose (Fig.
5-19
).
once bound,
competes with glucose
It
too large to be
is
moved
95] is
across the
in
medicine. For example, gout
evated uric acid in the plasma. uric acid
is
to
enhance
its
is
One method
ol
kidney and
in
in-
into
adipose tissue
GLUT5
is
actually a fructose transporter
the transporter present on the apical
membrane
of
The protein named GLUT6
cells.
turned out not to be a transporter, but by the time that
an inhibitor site,
was discovered, GLUT7 had already been named. GLUT7
but,
is
membrane.
a disease
mem-
and other hexoses found
in
the glucose transporter regulated by the
the
Competition between transported substrates has been put
good use
found
In the glu-
.
binding
for the
is
is
basolateral
epithelial cells in the
the intestinal epithelial
competing molecule
transporter
and on the
liver
transports glucose
GLUT4
neurons. The
Graph of competition
Figure 5-18
CLUT2
into
caused by
an
intracellular transporter
reticulum
to
membrane. The
found on the endoplasmic
restriction
transporters to different tissues
el-
is
of different
GLUT
an important feature
in
the metabolism and homeostasis of glucose.
decreasing plasma
excretion in the urine. Normally, the
kidney's organic acid transporter reclaims uric acid from the urine.
However,
if
tered, the carrier
an organic acid called probenecid
venting the reabsorption leaves the in
body
is
Saturation
adminis-
ol uric
at id.
As
a result,
more
uric
acid
just as
rate of substrate transport
the rate of
enzyme
substrate concentration
in the urine, lowering the uric acid concentration
«» [
activity p. 96).
number
depends on both
of carrier molecules,
depends on both enzyme and For a fixed
number
of carriers,
however, as substrate concentration increases, the rate increases
the plasma.
Extracellular fluid
CZT
The
the substrate concentration and the
binds to probenecid instead of to uric acid, pre-
or
Glucose
Glucose Maltose
GLUT transporter Intracellular fluid
(a)
The
across
GLUT transporter cell
membranes.
brings glucose
(b)
Maltose
a competitive binds to the GLUT
is
inhibitor that
transporter but
is
carried across the
not
itself
membrane.
Figure 5-19
Competitive inhibition 139
CHAPTER
MEMBRANE DYNAMICS
5
II of energy. Active transport requires energy input from ATP, either directly or indirectly.
GRAPH QUESTION
CHECK
On
the x-axis, mark the substrate concentration at which the carriers first
become
1
What would you
6.
Answers:
call a carrier
1
substrates
a cell
might increase
its
69
in
way
Using the door analogy above, can you think of another
7.
1
membrane?
opposite directions across the
saturated.
moves two
that
p.
maximum
transport rate?
Facilitated Diffusion Is Diffusion That Uses Membrane Proteins Some
polar molecules appear to
move
though we know from
diffusion, even
into and out of cells by
chemical properties
their
that they are unable to pass easily through the lipid core of the Extracellular substrate concentration
membrane. Most of these polar molecules travel by facilitated diffusion, in which carrier proteins transport them across the cell membrane. Glucose and amino acids are examples of cell
Transport rate is proportional to substrate concentration until the carriers are saturated.
Graph showing saturation of carrier-mediated
Figure 5-20
molecules that enter or leave diffusion carriers.
transport
same properties
Facilitated diffusion has the
up
to a
maximum,
the point at which
all
carriers are filled
substrate. At this point, the carriers are said to
working
ration. At saturation the carriers are rate,
no
and
have reached satuat their
shows saturation represented
5-20
effect. Figure
with
maximum
concentration will have
a further increase in substrate
The molecules move down
sion.
no input
process requires
when
equilibrium,
door has a
maximum number
concentration inside the
of people that
it
can
all
the
[glucose] ECI
.
=
maximum of 100 people per minute to enter the hall. This is the maximum transport rate, also called the transport maximum. When the concert hall is empty, three maintenance people enter the doors every hour. The transport
phosphate, the
doors together can allow a
the
3 people/60 minutes, or 0.05 people/minute, well under
maximum.
For the local dance
minute go through the doors,
when
still
recital,
about 50 people per
well under the
maximum.
When
sands of people are clamoring to get allow 100 people/minute into the
maximum
rate,
so
3000 people trying
it
in.
hall.
How
can
cells
the doors open, thou-
They are working
The transport
rate
is
withdraw
insert additional carriers
membranes. Under other circumstances, carriers to decrease
movement
a cell
may
of a molecule Into or out
as glucose enters the cell,
cell
lorms
oi
mediated transport show saturation,
and competition. But they transport, better
known
clilter in
othei ways
With
|*
by keeping the concen-
glucose, for example, this
first
it is
(Fig.
5-22 •). As
phosphorylated to glucose
step of glycolysis
[
6-
103]. Addition of the
»* p.
low and also prevents glucose from leaving the
CHECK 1
8. Liver cells
p.
169
and make
glucose concentrations higher than the
extracellular glucose concentration.
happens to
cell.
Answers,
are able to convert glycogen to glucose
intracellular
facilitated diffusion of
What do you think when this occurs?
glucose
Active Transport Requires the Input
of Energy from \ctive transport
spe
is
hyperosmotic to A
C
is
isosmotk
B
is
hyperosmotic to
C
C
is
hyposmotic
1
OsM NaCL
to B
153
CHAPTER
MEMBRANE DYNAMICS
5
RUNNING PROS
Table 5-7: Tonicity of Solutions
Daniel's medical history
stant medical
problems since
ratory infections,
months,
tells a
frightening story of almost conbirth: recurring
weight
loss.
began having trouble breathing, hospital.
A
his
Daniel
mother rushed him
to the
last
and dehydrated.
mucus from
his
breeding
In cystic fibrosis, this thick
ground
thickened mucus
of the epithelial cells
Question 3:
infection-causing
for
in
and
Why would
THE SOLUTION
SOLUTION
IN
A
Cell swells
Solution
A
is
hypotonic
Cell doesn't
Solution B
is
isotonic
C
is
hypertonic
B
change
size
caus-
Solution
Cell shrinks
a per-
bacteria. The CFTR channels.
lutions (solution
tion 2
the lungs transport chloride ions out
a
is
into the airways.
hyperosmotic to solution
is
1
comparative term for a
happen
to cell
volume
1).
Tonicity,
were placed in the solution. For ex-
a cell
if
therefore solu-
2,
on the other hand, solution that describes what would
hyposmotic to solution
is
failure to transport chloride ions into
the lumen of the airways cause the secreted
Remember
mucus
and provides
a direct result of faulty
is
Normal CFTR channels
(Hint:
week,
airways was unusually
es life-threatening respiratory congestion fect
six
when
Then,
DESCRIPTION OF THE SOLUTION RELATIVE TO THE CELL
WHEN PLACED
culture taken from Daniel's lungs raised a red flag
for cystic fibrosis: the
thick
and, for the past
digestive ailments,
a history of
CELL BEHAVIOR
bouts with respi-
mucus
to
ample, "Solution
be thick?
hypotonic to red blood
1 is
red blood cells would swell at equilibrium
that water moves to dilute the more concen-
in solution
Tonicity has
1.
no
The
units.
you that
cells" tells
the cells were placed
if
tonicity of a solution
is
trated region.)
characterized relative to a particular
Q ^ ^ £j© ^
Furthermore, the tonicity of a solution depends not only on its
solution. Osmolarity says
nothing about what the
particles are
and how they behave. Before we can predict whether osmosis must know the properties of the membrane and of the
cross the cell
we on
can enter the
solutes
membrane is move by osmosis from a less concentrated (hyposmotic) solution into a more concentrated (hyperosmotic) solution, as illustrated in Figure 5-34. This movement follows the saying "water moves to dilute the more concentrated solution."
NaCl.
Most biological systems
of water
solutes, water will
membranes
are not this simple, however. Biological
are selectively permeable
cross in addition to water.
and out of
cells,
and allow some
solutes to
you must know the
tonicity of
the solution, ex-
If
a cell
is
may
a physiological term,
what would happen
to cell
if
solution [tonikos, pertaining to stretching].
If
were placed
a cell gains water
and
when placed in a solution and allowed to come to equilibrithe cell um, we say that the solution is hypotonic to the cell. loses water and shrinks when placed in the solution, the solution said to be hypertonic. is
It
the
cell
does not change
ways describe the tonicity of the solution Mow,
equilib-
we
tion.
number
oi particles in
,i
and NaCl
desc ribe a single solution (in osmoles/llter) or to
it
is
a
few
+
is
If
therefore con-
How
and
C'l
will
cannot enter the
cells.
cell in it? s
t
The key
lies in
knowing the
>iutcs in the cell
and
relative concentrations
in the solution.
By conven-
that cells are filled with nonpenetrating
compare two
so-
membrane remains
unable to
and
in the cell.
cell.
The
cell swells, ,u\d
the eell has a lowei
Here are the
//
rules.
com
The
the
cell
cell shrinks.
com
and
movement
the solution
is
ot w.itei
hypotonic.
movement
ami the solution
is
the solution, there I
he solution
is
is
no
net
out ot the
ot w.itei
hypertonh
entrations ot nonpenetrating solutes .»< the
equilibrium.
into
entration of nonpenetrating solutes than
the solution, there will he net
.•?.
you
the nil has a highei concentration at nonpenetrating solutes
the If
cell,
a
concentrations of nonpenetrating
than the solution, there will be net
2.
intact.
solution relative to
a
ol
relative
solutes in the solution If
a solu-
can you figure out the tonicity of the solution without
we always assume
cell.
can be used to
solution
a saline
put into the plasma, tin \a
To determine tonicity
relative to the cell.
solution,
+
by the Na -K -ATPase. NaCl
must consider the
al-
then, does tonicity differ from osmolality.' Osmolality
describes the
154
Size
isotonic (Table 5-7). By convention,
cell. (In reality,
Suppose you know the composition and osmolarity of
It
rium, the solution
into the
stay in the extracellular fluid because they
1.
is
ions
leave as long as the cell
swells
is
solute in physiolog\
sidered a functionally nonpenetrating solute.)
tion,
the
.it
solutes.
solutes. In other words, the solutes inside the cell are
in
a cell
call particles
Na +
extracellular fluid
used to describe solutions, that
volume
We
penetrating solute.
leak across, but they are immediately transported back to the
putting a
The Tonicity of a Solution Describes How the Size of a Cell Would Change If It Were Placed in the Solution tells
a
membrane nonpenetrating
placed in a solution of NaCl, the Na* and CI
of nonpenetrating
is
it
will
membrane
not cross the
To predict the movement of water into
plained in the next section.
Tonicity
call
The most important nonpenetrating
permeable only to water and not to any
the
we
cell,
that cannot cross the cell
each side of the membrane. If
on the nature of the solutes in the solution. By we mean whether the solute particles can membrane. If the solute particle (ion or molecule)
osmolarity, but
nature of the solutes,
will
take place between any two solutions divided by a membrane,
cell.
movement
isotonh to the cell.
same ot
in the
water
at
•
The
starting osmolalities of the cell
that penetrating solutes,
which contribute
when determining
be ignored
One
the
the
membrane
cell
placed in a
look
true,
move
freely into
why
5-35a«, the
In Figure
trating solute in
1
liter
of volume.
tains 6 particles of solute per
liter:
The
1
3 nonpenetrating particles
i.e.,
are
Solution
®
J
and
and solution have the same
concentrations (6 particles per
they are isosmotic.
liter),
and solution have equal
concentrations, isosmotic.
of solution also con-
liter
3 penetrating particles. Because cell
To
(a)
Cell
contains 6 particles of nonpene-
cell
the Body
this
the following example.
at
in
did not exist, and therefore do
not contribute to the solution's tonicity. To understand is
Water and Solutes
must
is
a cell
solution with penetrating solutes, these solutes cell, as if
reason
to osmolarity,
When
tonicity.
Distribution of
and solution usually can-
not be used to determine the tonicity of the solution. is
The
(b)
compare the concen-
determine tonicity of the solution,
and
trations of nonpenetrating solutes in the solution
cell.
The
When
the
cell is
placed
in
the
no water moves initially because the cell and solution are in osmotic equilibrium. solution,
solution has 3 nonpenetrating particles per
nonpenetrating particles per
move from
that water will
liter.
liter,
By rule
the solution into the
movement
of water into the cell will increase
solution
hypotonic to the
is
isosmotic to the If
cell,
When
lies
the
has 6
its
cell.
The net
volume, so the
even though the solution was
the solution was isosmotic to the
solutes.
cell
before they were put together.
cell
The answer
sis?
but the
above, this means
1
what caused osmo-
cell,
with the gradient of the nonpenetrating
cell
was
placed in the solution, there was
first
no osmotic gradient (and no water movement) across the cell membrane because cell and solution both had concentrations of 6 particles per cal
liter
dig. 5-35b). However, there were chemi-
concentration gradients: the nonpenetrating solutes were
(c)
However, there
is
a concentration
gradient for the penetrating solute
@, which diffuses into the cell.
This
disrupts the osmotic equilibrium, so
water follows the solute into the
cell.
L
more concentrated in the cell (6 versus .{), while the penetrating solutes were more concentrated in the solution (3 versus 0). The nonpenetrating solutes could not cross the membrane, but the penetrating solutes were free to diffuse
and move into the
tration gradient
moved
in,
1
solute into the cell
ment has no
and the
tonicity. ties
is
he
I
cell
some
volume increased (solute moveon cell volume). Thus, in this ex-
is
clinical decisions
medicine, the tonicity of
portant consideration.
One purpose
into dehydrated cells (in
which
case,
at equilibrium, therefore
was
hypotonic.
which
about intravenous
a solution
of IV fluids
case, a
an isotonic solution
depends on how the
distribute
clinician
is
an im-
is
hypotonic solution
between the extracellular and
approximate osmolarity cell.
is
used).
FIGURE QUESTION
to get water is
The choice
of
Using the same
cell,
give the relative osmolarity
the following solutions,
if
the solution has
and the
tonicity of
6 nonpenetrating
(a)
6 nonpenetrating and 3 penetrating particles, or nonpenetrating and 6 penetrating particles. particles, (b)
(c)
3
wants the solutes and water to
partments. Table 5-9 shows the most
human
volume
and
used) or to keep fluid in the extracellular fluid to replace blood
their
,
the solution
hypotonic.
rules for dealing with osmolarity
making good
(IV) fluid therapy. In
fluid
Equilibrium is restored when the concentrations of nonpenetrating are equal in the cell solutes (|J and the solution. The cell gained
Understanding the difference between the two proper-
critical to
loss (in
(d)
parti-
1
cell
ample, an isosmotic solution lists
5-/55c).
gradient was created, water followed the
significant eftect
Table 5-8
concen-
while the solution had 6 -
particles,
Once an osmotic
their
As soon as one particle
an osmotic gradient was created dig.
contained 6 + cles.
cell.
down
intracellular fluid
common
com-
[V solutions
,wk\ tonicity relative to the
and
normal
Figure 5-35
Tonicity depends on the relative concentra-
tions of nonpenetrating solutes
®
can cross the nonpenetrating solutes
solutes
cell
^
Water and penetrating
membrane
cannot
but
cross.
155
CHAPTER
5
MEMBRANE DYNAMICS
CHECK
RUNNING PROB Three days
after Daniel's
sults: salt levels in his
tration.
Daniel
sweat
test,
re-
Which
27.
cystic fibrosis.
Now, along
mucus
loosen the
enzymes
in his
airways, Daniel
must begin
a
his
will
Why
will
Daniel starve
if
he does not take
(a)
1
(b)
1
M M
volume?
(c)
1
OsM
Compartment B
NaCI
1
OsM
urea
2
M
1
OsM
NaCI
who
29. You have a patient
lost
NaCI
urea urea
blood and you need to blood transfusion
of
liter
1
volume quickly while waiting arrive from the blood bank.
restore
© © © ©£i®
to
(a)
Would in
for a
be better to administer in water?
it
water or 0.9% NaCI
how
these solutes distribute
in
5%
dextrose (glucose)
(Hint:
Think about
the body.) Defend your
choice.
Table 5-8: Rules for Osmolarity and Tonicity (b)
By convention, we assume
unit
artificial
pancreatic enzymes?
1.
most water per NaCI?
OsM
1
Membrane
Compartment A
probably die before the age of 30.
Question 4:
NaCI, or
life.
mucus in the pancreatic ducts blocks the secretion of digestive enzymes into the intestine. Without artificial enzymes, he would starve. Yet even with these treatments, In cystic fibrosis, thick
Daniel
M
1
70
are separated by a membrane that is permeable to water and urea but not to NaCI. Which way will water move when the solutions below are placed in the two compartments?
regimen
to be taken whenever he eats, for the rest of
solution(s) has/have the
glucose,
1
Two compartments
28.
with antibiotics to prevent lung infections and therapy to
of
M
1
sweat are over twice the normal concen-
diagnosed with
is
the lab returns the grim
Answers: p.
How much
of
your solution of choice would you have volume to normal?
to administer to return blood all
intracellular solutes are
nonpenetrating.
When
2.
a cell
solutes will
is
exposed to a solution, water and penetrating the system will go to equilibrium. At
move and
equilibrium the total concentration of solute particles in the cell
and the solution
will
be the same.
we have
of a
cell
and a solution before they
many body
seen that the compartments of the body are in
solutes are ions that carry either positive or negative
be the same.
trical
tonicity of a solution
is
determined by the volume of the
equilibrium (see Table 5-7).
we must
also consider the distribution of elec-
charge between the intracellular and extracellular compart-
ments. Although the body as a whole a
matching positive ions are found
solution.
(Na
that
is
You cannot predict the tonicity of isosmotic and hyperosmotic solutions unless you know the concentration of nonpenetrating solutes relative to the cell. Net water movement will be into the compartment that has the higher
Potassium (K + )
+
electrically neutral,
)
is
the major cation of the
D
s
D5
— 0.9% saline W
anions of the intracellular
fluid.
cell that
0.45%
do not
Isosmoth
Isotonic
5%
dextrose** in normal saline
Hvperosinotk
Isotonic
5%
dextrose
Isosnu'tu
ii\
Half-normal saline
saline
D s—0.45% saline •Saline
156
n.i(
I
dextrose Dextrose
glucose.
In
half-normal saline
151).
do not have matching cations and
ions in the extracellular fluid that
Noriiuii saline
watei
and sodium
However, there are some protein
rONl( in
In
cells,
whereas phosphate ions and negatively charged proteins ate the
OSMOLARIT*
0.9%
saline*
KNOWN AS
has
in the extracellular fluid,
Table 5-9: Intravenous Solutions ALSO
it
while their
fluid (see Fig. 5-33, p.
Chloride ions (CP) remain with Na*
some K +
SOLUTION
fluid,
in the extracellular fluid.
dominates the extracellular
anions inside the
concentration of nonpenetrating solutes.
is
few excess negative ions in the intracellular
hyposmotic to a cell will always be hypotonic, no matter what the nature of the solutes in the
A solution
6.
far,
electrical charges,
cell at 5.
the osmolarities
are put together, because at equilibrium, the osmolarities will
The
4.
is,
of Electrical Disequilibrium Thus
osmotic equilibrium but in chemical disequilibrium. Because
Compare the osmolarity
3.
be equal; that
will
The Body Is in a State
1
1\
posmotic
Hyperosmotic
potonlc
Hypotonic Hypotonic
haw
matching
The
anions.
One consequence
is
commonly known
compartments
extracellular
The
electrical equilibrium.
uneven distribution of ions
of this
and
that the intracellular
are not
electrical disequilibrium in the
membrane
as the resting
is
in
body
potential difference.
from the separation of
tricity) arises
when
Distribution of
electrons
move from
Water and Solutes
Are Generated
Cells
The concept
tionally
been taught
of resting
membrane
the chapters
in
Many Types
in
of
charge that occurs
electrical
the amber atoms to the cloth. To sep-
arate these charged particles, energy (work)
must be put into the
system. In the case of the amber, work was done by rubbing the
work
rod. In the case of biological systems, the
Electrical Signals
the Body
in
is
done by
usually
energy stored in ATP and other chemical bonds.
potential has tradi-
on nerve and muscle func-
known
tion because those tissues generate electrical signals
as
action potentials. Yet one of the most exciting recent discoveries
Cell Membrane Allows Separation of Electrical Charge in the Body
The
In the body, separation of electrical charge takes place across the in
physiology
is
the realization that other kinds of
use
cells also
membrane. This process
cell
communication. This section reviews the
electrical signals for
basic principles of electricity
ing
membrane
and discusses what
The chapter ends with
potential.
tial
creates the rest-
a
look at
the
minus
They
composed
are
are electrically neutral
atom
is
known
as
important in the
an
We
ion.
human
of these positive ions,
in
balanced pro-
neither positive nor negative.
moval or addition of electrons particle
to
an atom creates
body
a
The
re-
charged
Na
body, such as
somewhere
there
+
K
,
is
a
+ ,
and
H
+ .
matching
For each electron,
when Na
in
enters in the form of NaCl, the "missing" electron from
+
Na can be found on The following
The
principles are important to
remember when
bilayer of the artificial
The law of conservation of
electric
charge
states that the
amount of electric charge produced in any process is zero. This means that, for everj positive charge on an ion, there is an electron on another ion. Overall, the human body
In the
2.
electrically neutral.
positive ions ent.
membrane. This
(
+ out of the )
The negative ions
try to
move
into the
to leak across
As soon as the
3.
and negative charges,
use energy. For example, energy
is
it
is
is
disrupted: the
impermeable to negative
is
cell.
cell,
needed to separate the
ward each ing
is
other, the material
called a
move
freely to-
through which they are mov-
conductor. Water
is
a
good conductor
of
move through the material that separates them, the material is known as an insulator. The phospholipid bilayer of the cell membrane is
electricity.
a
good
If
separated charges are unable to
insulator, as
is
the plastic coating
on
electricity
electrical wires.
comes from the Greek word
they rubbed a
elektron, for
The Greeks discovered that if rod of amber with doth, the amber acquired the
amber, the fossilized resin of
ability to attract hair
and
by the negative charge
membrane does not
positive ion leaves the
first
allow ions
cell,
the electrical
has a net charge of -1, while the
cell's interior
membrane
The input of energy
to trans-
has created an electrical gradient:
example, the inside of the
became negative
cell
relative to
active transport ot positive ions out of the cell also cre-
ates a concentration, or chemical, gradient: there are
ions outside the
electrical
chemical gradient. The cause water can
move
more
posi-
than inside. The combination of
cell
and concentration gradients cell
remains
in
freely across the
called
is
an electro-
osmotic equilibrium be-
membrane
movement. An electrical gradient between the
in
response to
solute
the intracellular fluid tial
difference or
name sounds The word
Positive ions outside the cell
attracted
exterior has a net charge of +1.
The tive
separated positive and negative charges can
ions, so
the outside.
necessary to
protons and electrons of an atom. 4. If
is
move
equilibrium between the extracellular fluid and intracellular fluid
in this
To separate positive
energy to
carrier uses
it.
port ions across the
protons and electrons in an atom exhibit this attraction.
at os-
(-) in the cell attempt to follow the posi-
they remain trapped within the
two charges of the same type + and + or - and -)
The
is
against their concentration gradi-
cell
membrane
Opposite charges (+ and -) are attracted to each other, but repel.
intracellu-
ions because of the attraction of positive and negative
tive
cell's
(
and
next step (Figure 5-36b), an active transport protein
inserted into the
net
is
extracellular
motic, chemical, and electrical equilibrium.
of the intracellular fluid, but the 1.
cell, like
not permeable to ions. Water can freely
ion concentrations equal. In Figure 5-36a, the system
might
dealing with electricity in physiological systems:
cell, is
membrane, making the
cross this cell lar
placed in a similar solution, also electri-
cell is
the bilayer of a real
charges. But the
the CI".
dia-
by the plus and
ions, represented
The phospholipid
cally neutral.
have discussed several ions that are
usually found as part of a negative ion. For example,
the
21].
of positively charged protons, negatively
charged electrons, and uncharged neutrons, but portions, so that an
p.
[
.
with molecules that dissociate
Because the molecules were electrically neutral to
signs.
inside the cell.
Atoms
» The
in Figure 5-36
begin with, there are equal numbers of positive and negative ions
to trigger insulin secretion.
Electricity review
artificial cell filled
and negative
into positive
how
membrane poten-
beta cells of the pancreas use changes in their
gram shows an
shown
is
is
known
membrane
intimidating,
extracellular fluid
as the resting
membrane
and
poten-
potential, for short. Although the
we can break
it
apart to see
what
it
means.
trees.
dust. This attraction (called static elec-
1.
The
resting part of
electrical gradient
the is
name comes from
seen in
all
the fact that this
living cells,
even those that 157
w
.
CHAPTER
MEMBRANE DYNAMICS
5
appear to be without
reached a steady state and
tential has 2.
The
electrical activity.
potential part of the
membrane
cell
gy.
When
a source of stored, or potential, energy, is
a
form of potential ener-
oppositely charged molecules
come back
together,
two
scales.
On
than an absolute
electrical gradients
scale. Figure
simple example has a charge of +1 from the positive ion charge of -1
gained, while the intracellular fluid has a
negative ion that was
measure the charges
we
behind. However, in
left
as
numbers
stead
sending
gives the intracellular fluid a charge of -2, the
The
difference part of
membrane
the
name
is
to
remind you that the
potential represents a difference in the electrical
charge inside and outside the
cell.
The word
difference
is
often
dropped.
(a) Cell
and solution are
electrically
and chemically
the
membrane
the
first.
at zero
artificially setsjone side
and measures the second
side relative to
In our example, resetting the extracellular fluid to zero cell's
resting
mem-
for measuring a cell's membrane poshown in Figure 5-37 I Electrodes are created from hollow glass tubes drawn to very fine points. These micropipets are filled with fluid that conducts electricity. They are con-
The
equipment
actual
tential difference
is
.
nected to a voltmeter that measures the electrical difference
cell.
A
reference electrode
which represents the
In living systems,
+
|0
A
in volts (V) or millivolts (mV).
membrane
inserted through the cell
is
plasm of the bath,
+
is
recording
into the cyto-
placed in the external fluid
extracellular fluid.
by convention, the extracellular fluid
When
mV.
recording electrode
the voltmeter
is
placed inside a living
cell,
the
measures the membrane potential (V m ), the electrical difference between the intracellular fluid and the extracellular fluid. A chart
+
membrane membrane
+
cells,
and solution in chemical and electrical disequilbrium. Energy to pump one cation out of the cell, leaving a net charge of -1 the cell and +1 outside the cell.
(b) Cell
used
mV). As you saw
On an
(c)
be
a recording of the
the voltmeter will record a resting
-40 and -90 mV,
potential difference between
cating that intracellular fluid lar fluid (0
make
potential difference versus time.
For nerve and muscle
is
indi-
negative relative to the extracellu-
in Figure 5-36c, the extracellular fluid
absolute charge scale, the extracellular and the intracellular fluid (ICF) at -1
fluid
(ECF) would
at +1
Extracellular fluid
Intracellular fluid
I
\ +
+
+2
+1
-1
+
Absolute charge scale
\
A©
+
T •
©
.0
f
©
//
© •
+
• © •
I
I -2
—
to the
158
Separation of ehi tin al liarge
left
+2
+1
-1
Relative charge scale
Physiological
i
Extracellular fluid
Intracellular fluid
extracellular fluid set to
measurements are always on a
(ground).
relative scale,
on which
assigned a value of zero. This shifts the scale and gives the inside of the cell a relative charge of -2.
the extracellular
Figure 5-36
is
designated as the ground and assigned a charge of
recorder connected to the voltmeter can
+
of
at equilibrium.
+
in
lost. In-
brane potential difference.
electrode
is
for the
use a device that measures the difference in electrical
between two points
i
it
we cannot
real life
of electrons gained or
charge between two points. This device
electrical signals.
a rela-
5-36c compares the
moving down their concentration gradient can perform work. The work done by electrical energy includes opening voltage-gated membrane channels and that molecules
on
the absolute scale, the extracellular fluid in our
they release energy that can be used to do work, in the same
way
3.
is
we measure
In living systems, tive scale rather
the fact that the
by active transport of ions across
concentration gradient
just as the
not changing.
is
name comes from
electrical gradient created
the
The membrane po-
fluid is
The
in
the Body
The voltmeter measures
A is
Water and Solutes
Distribution of
recording electrode placed inside the cell
the difference
in
electrical
charge between the inside of a cell and the surrounding solution. This value
membrane
difference, or
The chart recorder measures changes
is
the
potential
Vm
.
membrane
in
potential over time.
Measuring membrane potential difference In the laboratory, a voltmeter measures the difference in electrical Figure 5-37 charge between the inside of a cell and the surrounding solution.
is
not really neutral because
it
has excess positive charges that ex-
actly balance the excess negative charges inside the cell.
body remains
The
total
ions create the resting
animal
cells?
The
artificial cell
the only force acting on K~ were the concentration gradi-
If
ent,
Which
a negative charge inside the cell as K
diffuses out of the cell.
electrically neutral at all times.
The Resting Membrane Potential Is Due Mostly to Potassium
up
proteins gradually build
+ K would
leak out of the cell until the K* concentration in-
side the cell equaled the K" concentration outside. But the loss of
positive ions
membrane potential difference in shown in Figure 5-36b used an ac-
from the
cell creates
back into the
K
cell.
Thus,
down
cal gradient?
the negative charge inside the
Real cells are not completely
impermeable
to
all
ions.
They
have open channels and protein transporters that allow ions to
move between
the cytoplasm and the extracellular fluid.
use a different
artificial cell to
show how the
resting
We
can
membrane
(Fig.
tem
whose membrane
5-38a#) contains K
teins,
Cl~.
artificial cell
represented by Pr
Both the is
cell
.
+
impermeable
is
cell is
and solution
in electrical equilibrium.
placed in a solution of
are electrically neutral
However,
it is
not in
librium. There are concentration gradients for in the system,
and they would
concentration gradients In Figure 5-38b, a
brane,
making
it
if
K+
all
diffuse
all
leak channel
is
and the
sys-
chemical equi-
four types of ions
down
they could cross the
Na + and
cell
some point
cell,
moving down
some
dig. 5-38