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PRECLINICAL
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AND
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GENETICS
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2023
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Editor
Sam Professor,
Turco,
PhD
Department
University
of
of
Kentucky
Biochemistry
College
Lexington,
of
Medicine
KY
CONTRIBUTORS
Roger Professor, University
Lane,
PhD
Department of
South
of
Alabama
College
Mobile,
Ryan
M.
MD,
Family Family
Professor, University
Department of
Minnesota
of
Health
MS
Clinic,
Ltd
MN
Family
Medicine
Medical Duluth,
Medicine
Medicine
Sandstone,
Assistant
of
AL
Harden,
Physician, Gateway
Biochemistry
School, M
and
Community
Duluth
Campus
Health
We
want
to
hear
what Please
you email
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What at
do
you
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[email protected]
or
not
like
about
the
Notes?
Table
PART
I:
of
Contents
BIOCHEMISTRY
CHAPTER
1:
Nucleic
Acid
CHAPTER
2:
DNA
CHAPTER
3:
Transcription
CHAPTER
4:
The
CHAPTER
5:
Regulation
CHAPTER
6:
Genetic
CHAPTER
7:
Techniques
CHAPTER
8:
Amino
CHAPTER
9:
Hormones
CHAPTER
10:
Vitamins
CHAPTER
11:
Energy
CHAPTER
12:
Glycolysis
CHAPTER
13:
Citric
CHAPTER
14:
Glycogen,
Structure
Replication
and
and
and
Genetic
of
and
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47
Translation
Expression
Analysis
Proteins,
.
.
Therapeutics
Genetic
.
.
and
Gene
in
.
.
Enzymes
.
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159
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171
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189
and
Cycle
Pyruvate
Dehydrogenase
and
Oxidative
Phosphorylation
Gluconeogenesis,
Monophosphate
and
Shunt
CHAPTER
15:
Lipid
Synthesis
and
CHAPTER
16:
Lipid
Mobilization
CHAPTER
17:
Amino
Acid
Metabolism
CHAPTER
18:
Purine
and
Pyrimidine
.
.
.
Metabolism
Acid
.
Processing
Eukaryotic
of
.
Mutations,
Strategies
Acids,
Repair
RNA
Code,
Organization
.
.
Storage
and
the
.
.
.
.
.
.
Catabolism
.
.
.
Metabolism
.
.
Hexose .
.
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201
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217
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237
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259
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283
3
PART
INDEX
v
II:
MEDICAL
GENETICS
CHAPTER
1:
Single
CHAPTER
2:
Population
CHAPTER
3:
Cytogenetics
CHAPTER
4:
Recombination
CHAPTER
5:
Genetic
.
.
.
.
.
.
.
Gene
Disorders
Genetics
.
.
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385
Frequency
Diagnosis
.
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PART
BIOCHEMISTR
I
Nucleic
Acid 1
Structure
LEARNING
❏
Explain
❏
Use
❏
Understand
information
of
be
all
the
are
to
able
of by
of
to
life.
DNA
versus
store
The
preserve
its
and
major
nomenclature
RNA
BIOLOGY
and
central
and
a chromosome
generations,
the
structure
MOLECULAR
future
processes
illustrated
nucleotide
of
features
OF
must along
to
organization
general
DOGMA
organism
tion
related
knowledge
information out
Organization
OBJECTIVES
CENTRAL
An
and
steps
dogma
genetic
express involved
of
information,
that in
molecular
pass
information
as
handling
genetic
it
that carries
informa
biology.
Replication Transcription
Translation
DNA
RNA
Protein
Reverse transcription
Figure
Genetic
FigureI 1 I 1. 1 1.Central Central
information
during
the
proteins
is stored
process
made
of by
an
gene
in
the
Dogma Dogma
base
expression,
of MolecularBiology of Molecular
sequence this
of
DNA
information
Biology
molecules.
is
used
Ultimately,
to
synthesize
all
the
organism. HY
HY Classically,
a gene
molecule. tion
is
Although
of
the
ways
a unit this
in
of
the
DNA
definition
which
genes
is may
that now be
encodes
a
particular
complicated
by
expressed,
it is
protein
our
still
or
increased
useful
RNA
apprecia MY
as
LY
definition.
Gene
Expression
Gene
expression
stage
in
double molecule.
and and
gene
If
the
RNA
of
replication
are transfer
molecule molecule the
High
Replication
involves
DNA
converts
DNA
DNA
expression,
stranded
translation sequence
MY
a working
information
to is
the
compared of
base
sequence
a messenger in
the
of
RNA, RNA
found
base
then
a single the
sequence
in
YIELDthe
first
YIELD
MEDIUM
YIELD
a
LOW stranded process
HIGH
Yield
MEDIUM Transcription,
below.
information
LY
YIELD RNA
known
to the amino FUNDAMENTALS
LOW
YIELD
as acid FUNDAMENTALS
a protein. REINFORCEMENT
REINFORCEMENT
3
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry When
cells
genetic
divide,
duplicated
Medical Genetics
each
information.
Table
before
I 1
Gene
1.
daughter
DNA cell
cell
must
replication
is
receive the
of
Gene
Expression
and
Expression
DNA
DNA
all
organism
requires
the
accurate in
copy
which
of
each
the
chromosome
is
division.
Comparison
Produces
an
process
proteins
an
Replication
Replication
Duplicates
the
before
cell
chromosomes
division
Behavioral Science/SocialSciences Transcription a
of
small
DNA:
section
of
(average
size
of
104–105
nucleotide
Transcription
human
gene,
occurs
Translation
of
RNA
sis)
in
the
throughout
the
concept
events
in
divides
of a
to
divisions
or
Interphase
•
be •
in
a
tion
entire
chromosome
of
108
Occurs
synthe
Replication
1)
is
human
chromo
nucleotide
during
S
in
pairs)
phase
nucleus
(DNA
of
called
the
is
the
timing
the
time
describes occurs
the
throughout
cellular
cycling,
of in
time all
some
of
which
the
between stages
these cell
2 cell of
interphase.
is
end
growth
such
as
preceding
muscle
and
time
during
DNA nerve
synthesis.
cells,
are
said
G0.
synthesis) At
is
follows:
a period
state
describe
(mitosis)
Interphase
stopped
special
to
phase
expression as
have
used
M
cells.
Gene
(gap
be
The
daughter
and
nucleus
can
cell.
occurs.
content
some,
the
cycle
subdivided
S phase
of size
cycle
cell
2
that
copy
(average
(protein
cell
the
phase
Cells
DNA
cytoplasm
mitoses. is
G1
in
eukaryotic form
of
pairs)
interphase
occurs
copy
chromosome
throughout
The
RNA
a
of
composed
S of
the
period
phase, 2
of each
which
chromosome
identical
DNA
has
sister
chromatids
growth
after
replica
doubled linked
its at
DNA
the
NOTE centromere. Many
chemotherapeutic
targeting This
is
Some
agents
specific a
phases
frequently
tested
commonly
cell
cycle
•
they
S phase:
of
tested
function
the
area
cell on
agents
with
by
•
cycle. the
phase
preceding
exam.
phase
G2
(gap
2)
mitosis.
is
a
period
of
Replicated
cellular DNA
is
checked
for
DNA any
division.
of
target:
methotrexate,
5 fluorouracil,
M
hydroxyurea
•
•
G2
G0
phase:
M phase:
bleomycin
paclitaxel,
G2
G1
vincristine,
vinblastine S •
Non
cell
errors
cycle
cyclophosphamide,
specific: cisplatin
Figure
I 1 Figure
2.
The Eukaryotic I 1 2. Eukaryotic
Cell
Cell Cycle
Cycle
synthesis before
but cell
to
CHAPTER
Control by
of
the
strategic
points lar
cell
cycle
proteins
ensure events
that in
Reverse
the
is
cells
will
tion
also
ing
certain
life
through
a
occurs
to
a
highly
and
enter
the
cycle
of
acids
(an
extent
repetitive
(DNA
components:
a
in
in
RNA)
nitrogenous
Carbon
the
AND are
base,
5
of
various
until
RNA,
is
and
DNA
(Chapter
plays
ACID
STRUCTURE
more
commonly their
a
transcrip
role
in
amplify
7).
NOMENCLATURE from
carbon
nucleotides,
sugar
(pentose),
nucleotides)
are
which and
consist
of
3
phosphate.
Sugars HY
HY Nucleic the
acids
(as
pentose
well
they
nucleic
acid);
nucleic
acid).
as
nucleosides
contain.
if
the
If
pentose
and
the
pentose
is
deoxyribose,
is
ribose, the
classified
the
nucleic
nucleic
acid
according
acid is
DNA
are
(ribo MY
LY
2 types and
of
nitrogen
containing
bases
commonly
found MEDIUM in nucleotides: YIELD
Pyrimidines O
NH2 N
N
N
H2N
H
N
N
N
YIELD
Figure
I 1 3. Figure
contain
nucleic RNA.
include
2
acids
xanthine,
Pyrimidines Thymine
found
only
only (T)
in
their
and
metabolites,
RNA.
is
1
and ring.
usually
The
guanine usually
uric
Cytosine found
N
Thymine
Acids
commonly
found
both
are
found
in
found
in
nucleic
DNA
acids,
acid. (C)
only
purines (G);
REINFORCEMENT CH3
H
Found in Nucleic Found in Nucleic Acids
not
O
O
Uracil
is in
present
DNA,
in whereas
both
DNA uracil
YIELD
FUNDAMENTALS
H
structure.
(A)
hypoxanthine, have
RNA.
in
Commonly Commonly
adenine
purine
N
O
Cytosine
Bases
rings
are
Other
Bases I 1 3.
LOW
HN
H
Guanine
Purines
N
O
YIELD
REINFORCEMENT
NH
H
Adenine
•
YIELD
MEDIUM
FUNDAMENTALS O
NH2
HN
N
N
and
HIGH
pyrimidines.
Purines
in
LY
Yield
LOW
•
MY
(deoxyribo
High
purines
to
is RNA
Bases There
AND
molecu
Reverse it
NUCLEIC
check
the
express
provirus). where
|
phases
These
cycle
an
cells,
assembled a
the
replicate
integrated
the
kinases. of
copies
human
sequences
and
concluded.
which
STRUCTURE
Nucleic
phase
are
DNA
intermediate
between
dependent
next
phase
retroviruses,
limited
checkpoints
cyclin
produces
cycles
NUCLEOTIDE
Five
not cell
DNA
at
cyclins
which
with
genome
as
previous
transcription,
associated
accomplished
such
1
and (U)
is
ORGANIzATION
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry Nucleosides
and
Nucleosides sugar.
are The
Nucleotides
formed
by
numbers
covalently
identifying
in
nucleosides
and
or
pyrimidine
base.
linking
the
nucleotides
to
a
carbons
of
distinguish
base the
to
the
sugar
them
number are
from
1
labeled
the
carbon
of
with
carbons
of
a
“primes” the
purine
Medical Genetics
Nucleotides carbon
are of
when
a nucleoside.
compounds
Behavioral Science/SocialSciences
formed
1 or
more
Nucleoside
because
of
the
phosphate
di
hydrolytic
and
groups
is
triphosphates
energy
attached
are
associated
to
high
with
the
5′
energy
the
acid
anhydride
bonds.
Uridine
Monophosphate
Deoxyguanosine
Monophosphate
(UMP)
(dGMP)
O
O
ATP
N HN
HN
NH2 N High
energy
N
N
N O
O
N
O
O O
O–P P O
O–P
O
O
CH2
P
́ O
5
CH2
1 ́
3
OH
́
2
OH
Figure Figure a
I 1 6. High Energy I 1 5. High Energy Bonds Nucleoside Triphosphate side Triphosphate
Bonds in a Nucleo
P
́
CH2
O
O
O: ́
4
́
1 ́ ́
3
OH
́
2 ́
OH
in Figure
The shown etc., always
6
O
O
O
4
O–OH
N
O
O–5
O
N
H2N
bonds
nomenclature below.
for Note
is sometimes found
the
that
to
5. Examples I 1 4. Examples
commonly the
understood attached
I 1 Figure
“deoxy” and
deoxyribose.
found part not
of Nucleotides of Nucleotides
bases, of
expressly
the
nucleosides, names stated
and
deoxythymidine, because
nucleotides dTMP,
thymine
is almost
is
CHAPTER
Table
I 1
2.
Nomenclature
of
Important
Bases,
Nucleosides,
and
1
|
NUCLEIC
ACID
STRUCTURE
AND
ORGANIzATION
Nucleotides
Base
Nucleoside
Nucleotides
Adenine
Adenosine
AMP
(dAMP)
ADP
(dADP)
ATP
GMP
(dGMP)
GDP
(dGDP)
GTP
(dGTP)
CMP
(dCMP)
CDP
(dCDP)
CTP
(dCTP)
UMP
(dUMP)
UDP
(dUDP)
UTP
(dUTP)
(dATP)
(Deoxyadenosine)
Guanine
Guanosine (Deoxyguanosine)
Cytosine
Cytidine (Deoxycytidine)
Uracil
Uridine (Deoxyuridine)
Thymine
(Deoxythymidine)
Names
of
nucleosides
(dTMP)
and
nucleotides
(dTDP)
attached
to
(dTTP)
deoxyribose
are
shown
in
parentheses.
NOTE
NUCLEIC Nucleic
acids
that
is,
sugar
a
A
the
at
In
(left left
•
If
•
The
•
In
in
ssDNA
genomes
is
of to
the
3′
has
a distinct
found
at
often
a nucleic
right).
Figure
joined
1
6
by
carbon
of 5′
the
5′
of “d”
DNA
is generally
3′,
5′
a sugar end
and
end,
phosphodiester
to
the
3′
and
a
which
5′
5′
end,
and
hydroxyl
•
bonds;
carbon
of thus
the
has
group
the 3′
next
of
the the
5′→3′ strand
TCAG:
GACT
5′
pTpCpApG dTdCdAdG
in dsRNA
(dsDNA) certain
viruses,
genomes.
and
RNA some
is of
generally which
Acids
Nucleotides
linked
phosphodiester
by
3′,
5′
bonds
polar
is often
in
sequence
or
3′
shown:
stranded
have
convention,
labeled:
included:
occur
by
TCAG
be be
double
of
written
convention,
must
be
Exceptions some
this
may may
is
written
ends
phosphates
(ssRNA). and
be
the
(deoxy)
strand to
must
backward,
a
acid
According I
positions
stranded
nucleotides
•
end.
written
DNA,
of links strand
group 3′
eukaryotes,
single
Each
sequence
direction the
group
chain.
the
base
on
polymers
phosphate
found
The
are
phosphate
in
ity.
Nucleic
ACIDS
have
•
Have
distinct
thus
polarity
Sequence
3′
always
and
5′
specified
ends,
as
5′→3′
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry 5
́
Phosphate
3 ́
Hydroxyl
O H O
Medical Genetics
P
O
N
H3C
O
N
H
OH
O 5 ́CH2
T
5
N
N
H
A
N 3 ́
O
N
́
N
Behavioral Science/SocialSciences
3
O O
3 ́
5 ́CH2
O
O
O
P
H
O
O
P
O
N N
H
O
O
O C
H
N
5 ́CH2
N
G
N 3 ́
O
N
N H
O
N O
3 ́
H 5 ́CH2
O H
O
N N O
P
CH3
O
O
O
O
5
H
A
N
H
N
N
O
T
N
́CH2
P
O
N O
O 3
́
3 ́ O O 5
H O
P
N
O
H
O
́CH2
N
O
O O N
G
N
H
N
H
O
P
O
C
5 ́CH2 N
N
O
N
O
H
3 ́
3 ́
O 5 ́CH2 OH 3
O ́ O
P
O 3
́
Hydroxyl
5 ́
Figure Figure
I 1 I 1
6. Hydrogen 7. Hydrogen
Bonded Base Bonded
Pairs Base
in DNA Pairs
in
DNA
Phosphate
5 ́ O
́
CHAPTER
DNA
Structure
Some
of
•
|
NUCLEIC
features
of
2 strands
double
are
stranded
antiparallel
DNA
Using
include:
(opposite
in
In
direction).
The
2 strands
bonds),
are
and
sequence
G on
complementary.
always
one
A
pairs
strand
with
C
defines
always
(3
the
pairs
with
hydrogen
base
T
bonds).
sequence
(2
Because T,
of
and
total
ORGANIzATION
the
the
the
specific
amount
base of
pyrimidines.
G
pairing,
equals
These
the
the
amount
amount
of
properties
are
of C.
known
A
the
other
as
(or
minor
modification
(substitution
of
U
for
T)
these
base
the
total
stranded)
% T (%
U)
% A =
amount
purines
Chargaff’s
rules
dsRNA)
strand.
equals
Thus,
Rules
double
=
% C
of equals
% purines
=
%
pyrimidines
rules. A sample
With
AND
hydrogen
Thus,
on
=
% G •
STRUCTURE
Chargaff’s
dsDNA
(ds •
ACID
NOTE
the
The
1
also
apply
to
of
what
is
10%
G
DNA
the
has
10%
G;
% T?
dsRNA.
Most
DNA
Watson strand
are
in
Crick
each
occurs DNA
in turn
in
G
nature
DNA is on
stacked
complete
Z
occurs
the of
or
the
as
B
DNA.
outside
center the
of
the A
sequences
is unknown,
but
right
handed
The
of
helix.
C–rich
a
the
hydrophilic double
left
is known may
be
related
helical
sugar helix.
molecule. rare
double
There handed
The are
phosphate
about
Z
to
gene
bonded
10
base
helical
DNA.
The
known backbone
hydrogen
double
as
molecule
form
biologic
pairs of
of base
+
10%
C =
20%
as therefore,
% A +
% T must
total
80%
pairs 40%
A and
Ans:
40%
40%
T
per DNA
function
that
T
of
regulation.
AT AT CG GC
BRIDGE
TO
PHARMACOLOGY
AT TA
Daunorubicin
GC
drugs
and
that
are
doxorubicin
used
in
are
the
antitumor
treatment
of
TA leukemias.
Major Groove
TA GC
Provide for
CG
They
intercalating
regulatory
binding
sites
thereby
exert
their
between
the
interfering
with
effects
by
bases
the
of
activity
DNA, of
proteins topoisomerase
II and
preventing
proper
AT replication
of
the
DNA.
Minor Groove
GC
Other
drugs,
such
as
cisplatin,
which
is used
GC in the
AT
bind
TA
treatment tightly
distortion AT AT
Figure
I 1
8. The B DNA Double Figure I 1 7. B DNA Double
Helix Helix
of to
and
the
bladder DNA,
malfunction.
and causing
lung
tumors,
structural
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry Denaturation
Double
stranded
DNA
Double
helical
bonding
and
single Medical Genetics
Denaturation
and
(heat)
Heat,
Denatured
Single
stranded
separate
DNA
is
again
(Figure
I
1
in
two
covalent
such
be
as
hydrogen
double
bonds
helix are
formamide
renatured
example,
if
and
(annealed)
a solution
complementary
to
then
Chapter
a mixture
of
renatured.
of blot
7).
In
target
When
complementarity,
stranded
annealing
a Southern
in
added
into
broken urea
two in
this
are
if
the
denaturing
containing
strands
can
heat
become
denatured
base
paired
these
the
in
is
binds
a well The to
strands
the
molecules.
DNA
process
DNA
performing
techniques,
DNA
probe
complementary
and
target
called
hybridization.
portion
of
is
an
polymerase
important
chain
characterized
reaction
probe
mixed
sample
DNA
sequences
DNA
is denatured of
is and
sufficient
DNA Recall
Denaturation I I 1 18. 9.Denaturation Renaturation Renaturation
can
For
the
or
probing
(reviewed
(cooling)
and
No
the
8).
renaturation
step
Renaturation
Figure Figure
other.
disrupt
of
DNA Such
Double
that
“melting”
chemicals
DNA
removed.
cooled,
conditions
the
DNA.
stranded
slowly
by in each
and
denature
slowly
DNA
denatured
from pH,
to
single is
be
of
resulting
alkaline used
condition
can stacking,
that
commonly
Behavioral Science/SocialSciences
DNA base
strands
process.
Renaturation
of
of DNA
Question
and Methotrexate
DNA
affects
A.
G1
phase
B.
G2
phase
C.
M phase
D.
S phase
which
the
cell
cycle?
Answer:
ORGANIzATION
Large cell
OF
DNA and
molecules
still
be
D
DNA
must
be
packaged
in
such
a way
that
they
can
fit
inside
functional.
Supercoiling Mitochondrial
DNA
structures. in
These
which
results
the
helix
from
and
the
molecules is
strain
twisted
on
DNA may
the
of
as
around molecule
most
exist
itself
prokaryotes relaxed in
caused
are
circles 3
closed
or
as
dimensional
by
under
space. or
circular
supercoiled
overwinding
structures
Supercoiling the
double
helix:
•
Negatively than
supercoiled
in
Watson
in
Watson
DNA Crick
is
DNA.
formed
This
if
form
the is
DNA
is
required
wound
for
most
more
loosely
biologic
reactions. •
Positively than
1
supercoiled
DNA Crick
DNA.
is
formed
if
the
DNA
is
wound
more
tightly
the
CHAPTER
•
Topoisomerases in
are
DNA
enzymes
molecules.
alternately
breaking
example,
in
introduce
make
and
can
coli,
amount in
sugar
gyrase into
the
breaks
the
DNA
supercoiling
and
change
transient
resealing
Escherichia
negative
Nucleosomes
that
They
of
DNA
|
NUCLEIC
ACID
STRUCTURE
supercoiling HY by
strands
phosphate (DNA
1
backbone. II)
MY
can LY
DNA.
High
Chromatin
LY
HIGH
Yield
MEDIUM
ORGANIzATION
HY
For MY
topoisomerase
AND
YIELD
YIELD
MEDIUM
YIELD
Sensitive Without
+H1
30
H1
LOW YIELD nuclease
to
10 FUNDAMENTALS
nm
LOW
nm
FUNDAMENTALS
REINFORCEMENT
H2A
YIELD
REINFORCEMENT
H3 H2B
H2B
H3
H4
Expanded
H4
a
view
of
nucleosome
H1
Expanded
H2A
view
Figure
Figure
I 1 9. Nucleosome I 1 10. Nucleosome Structure Structure
Nuclear
DNA
nonhistone
•
•
in
Histones the
proteins.
Two
copies
DNA (a
•
is
•
30
nm
and
associated
chromatin
histones
associated
unit
and
of
arginine,
H2A,
DNA
which
H2B,
with
chromatin
H3,
is
confer
and
a
H4
histones
the
and
nucleosome.
positive
charge
aggregate
to
on
form
the
the
referred is
outside
is to
associated
as
a
with
them
into
of
this
sometimes
a
octamer
called
10nm the
to
“beads
chromatin linker
solenoid
a
a
nucleosome
string”
but
is
fiber).
DNA like
form on
found
structure,
between
nucleosomes
which
is
a
thick
fiber. condensation
occurs
chromosome stranded
interphase for
lysine
around
H1
Further
in
in
packaging
nucleosomes
package
double
available
of
wound of
Histone help
in
each
eukaryotic
Cells
rich
properly
to
basic
Nucleofilament and Nucleofilament
octamer.
series
more
is found
The
are
histone •
eukaryotes
proteins.
and
in Eukaryotic DNA in Eukaryotic
2
types
expression) with
G0
eventually or
G1
form contains
the one
chromosome. linear
Each
molecule
of
DNA.
contain
gene
to
in
areas
and of
the
of
chromatin:
euchromatin
heterochromatin chromosomes
(much that
are
(more more
not
highly
opened
and
condensed
expressed).
1
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry More
Less
active
active
Medical Genetics
Behavioral Science/SocialSciencesDNA
double
helix
10
nm
chromatin
30
(nucleosomes)
nm
chromatin
30
(nucleofilament)
nm
to
fiber
forms
scaffolding
loops
attached
Higher
proteins
Euchromatin
Figure
Heterochromatin
Figure I 1 10. DNA Packaging I 1 11. DNA Packaging
Euchromatin with
condensed,
an
corresponds
each
other
producing
of
mitotic
nucleolus
Chapter
is
nucleosomes
nm
fibers).
(10
The
figure
as
below
region
fibers)
as
an
electron
chromatin
for
and
ribosome
assembly
of
a nucleolus. (discussed
3).
Euchromatin
Heterochromatin
Nucleolus
Figure
During sister
mitosis,
all
chromatids.
structure
is
visible.
chromosomes banding translocations,
1
the This
by
I 1 12. I 1 An Figure 11.
DNA
is
is the
only
highly
Chromosome karyotype
techniques
condensed
time
in
the
or inversions,
allow
cycle may
(metaphase prometaphase), and
Nucleus Nucleus
to cell
abnormalities analysis
(prophase deletions,
Interphase An Interphase
be
assessed
chromosomes) which
duplications.
separation when
identify
highly
character
micrograph
heterochromatin,
specialized
loosely is more
well
shows
euchromatin,
nm
Heterochromatin
heterochromatin
containing
a nuclear
the
30
interphase
nucleus
Cell
to
(looped
chromosomes.
interphase
The
in Eukaryotic Cell in Eukaryotic
generally
associated
istic
order
packaging
the
of chromosome on
mitotic
and
by
aneuploidy,
the
in
CHAPTER
Review Select
1.
|
NUCLEIC
ACID
STRUCTURE
AND
ORGANIzATION
Questions the
A
ONE
best
double
with age
2.
1
answer.
stranded
RNA
gastroenteritis of
guanine
A.
15
B.
25
C.
35
D.
75
E.
85
What
is
the
genome
was in
found
this
structure
to
isolated
from
contain
15%
a virus uracil.
in
the
What
is
stool
of
the
percent
a
child
genome?
indicated
below?
NH2
N N
N
5 ́
N
CH2OH
4
O
1 ́ ́
3 ́
2 ́
OH
3.
A.
Purine
B.
Purine
C.
Pyrimidine
D.
Purine
E.
Deoxyadenosine
nucleotide
nucleoside nucleoside
Endonuclease features
activation of
mosome
OH
eukaryotic
structures
A.
Barr
B.
10
nm
fiber
C.
30
nm
fiber
D.
Centromere
E.
Heterochromatin
and cell would
chromatin
death
by
most
likely
fragmentation apoptosis. be
are
Which degraded
of first
characteristic
the in
following an
apoptotic
chro cell?
body
1
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry 4.
A
medical
her sample
What
to left
analysis Medical Genetics
student
mentor
behind
show is
working determine
the
by
10% most
a
likely
A.
Bacterial
chromosome
B.
Bacterial
plasmid
C.
Mitochondrial
D.
Nuclear
E.
Viral
source
genome
biology
composition research
40%
chromosome chromosome
a molecular base
former
adenine,
Behavioral Science/SocialSciences
1
in the
the
an
technologist.
cytosine, of
laboratory of
nucleic
30%
The thymine
acid
is
unlabeled
in
results and
this
asked
by
nucleic
sample?
20%
of
acid her
guanine.
CHAPTER
1
|
NUCLEIC
ACID
STRUCTURE
AND
ORGANIzATION
Answers
1.
Answer: U
=
C. A
Since
= A
15%. +
G
=
Alternatively,
2.
3.
+
G
=
G
=
35%.
D.
=
35%.
=
15%,
nucleoside
then
U
consists
adenosine,
B.
The
+
nm
of
which
more
10
endonuclease
A
=
30%
is
“opened”
the
fiber,
without
would
attack
a
base
the
a
sugar.
adenine
The
figure
attached
DNA,
the
H1,
is the
most
region
of
unprotected
the the
and
base
more
shows
to
sensitive
it
open
ribose.
is
to
structure DNA
enzyme listed.
between
nucleosomes.
Answer: rules
E. (%A
A =
stranded,
base %T,
nucleic
circular Only
A
The
The
A
G
and
nucleoside
Answer:
the
=
70%,
Answer:
attack.
4.
U
C
the
50%,
(choices a
few
viruses
compositional %C
=
acid A,
analysis
%G)
molecule. B
(e.g.
and
that
is indicative All C)
parvovirus)
or
of options
linear
single
from
Chargaff’s
stranded,
listed
(choice have
deviates single
except D)
DNA
stranded
not E
are
double
double examples
of
helices.
DNA.
1
DNA
LEARNING
Explain
❏
Know
key
❏
Know
major
Repair
2#
how
DNA
steps
and
in
RNA
DNA
kinds
of
synthesis
differ
replication
DNA
repair
REPLICATION
Genetic
information
parental
DNA,
are
identical
each
2
complementary
is
then
used
is transmitted a
of
the
process to
in the
a template replication).
2 identical
DNA
from
which
parent
2 daughter
parental
strands as
(semiconservative one
and
OBJECTIVES
❏
DNA
Replication
DNA
of
parental
for
the
molecule. DNA
synthesis During
to
a
by
molecules During
are of
cell
progeny
DNA
DNA
pulled
apart.
new
complementary
division,
replication are
each
of
produced
replication, Each
daughter
parental
that the strand
strand cell
receives
molecules.
1
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry Replication The
of
process
of
Prokaryotic DNA
and
replication
Eukaryotic
in
Chromosomes
prokaryotes
and
eukaryotes
is
compared
below.
Medical Genetics
Prokaryotes Origin
Eukaryotes
of
replication
Multiple
origins
of
replication
Behavioral Science/SocialSciences
Centromere
Sister
chromatids
separated
Figure
I 2
1.
SemiFigure Conservative, I 2 1. DNA
DNA
Replication
by
Bidirectional Replication by a Semi
Bidirectional
are
during
mitosis
a
Mechanism Conservative,
Mechanism
NOTE •
Polymerases
are
synthesize
enzymes
nucleic
phosphodiester
that
acids (PDE)
by
The
forming
bonds.
bacterial a single
creates
2
around •
Nucleases PDE
–
are
enzymes
that
hydrolyze
bonds.
from
remove
the
5′
or
the
nucleotides 3′
end
of
nucleic
acid.
the –
Endonucleases nucleic fragments.
1
acid
cut and
within release
the nucleic
circle.
meet,
a closed,
double
replication.
stranded
Separation
that
Replication
eukaryotic
move is,
resulting
chromosome
origins
replication
of
away
thus, in
a
the
of from
circular
the
each
2
DNA
parental
other
bidirectional of
2
molecule
strands
in
of
opposite
process.
production
The divides
2
of occurs
identical during
contains
replication.
forks
production
replication acid
forks
eventually
multiple of
is of
The
identical
DNA
directions 2
replication
circular
molecules
DNA.
Each a
origin
replication the
forks of
Exonucleases
chromosome
having
2 in
sister mitosis.
produced
at
identical
linear
the
one
Bidirectional
nucleus
chromatids
each
origin. molecules
during are
linear
molecule occurs
Completion
of
of the
separated
of
replication
dsDNA
S phase from
by the
(sister of each
the
dsDNA
of
process
a
results
chromatids).
eukaryotic other
having means
when
pair in DNA
cell the
cycle. cell
CHAPTER
The shown
structure
of
a
representative
eukaryotic
chromosome
during
the
cell
cycle
2
|
DNA
REPLICATION
AND
REPAIR
is
below.
Panel
A
Cell division
M
G2
G1
S
Centromere
2 (sister
ds
DNA
ds
DNA
chromatids)
Panel
B
3 p
2 1
1
2 q 3 4
Drawing
Panel
B:
a
Drawing
of
a
chromosome
chromosome
chromatids
(metaphase)
difficult
Different
I 2 2. Panel
Panel A:
replicated
Photograph
stained
I Figure 2 2.
Figure
of
replicated
A: Eukaryotic Eukaryotic
DifferentRepresentations Representations
of
chromosome.
Chromosome Chromosome
a
stained
The and to
centromere
visualize
in
Replication Replication During
of a ofReplicated a Replicated Eukaryotic
replicated
individual
the
are photograph
S Phase During Panel
Chromosome Eukaryotic
B:S
Phase
Chromosome
1
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry COMPARISON
The
overall
RNA.
process
These
RNA
Medical Genetics
OF
2
of
types
polymerases,
DNA
DNA
of
AND
replication
nucleic
acids
are
́ C
A
T
5 ́
G
A
the
synthesis
synthesized
by
of
DNA
both
DNA
polymerases
and and
respectively.
RNA
Polymerase
Polymerase DNA
3
SYNTHESIS
requires
DNA Behavioral Science/SocialSciences
RNA
A
C
C
U
G
T
A
3
́
G
C
C
G
DNA
Template
A
A
C
T
C
Primer
RNA
T
G
G
A
required
DNA
synthesis
using
dNTP
3
5 ́
́ C
A
T
G
A
C
T
A
G
C
C
Template
G
A
for (5
A
C
T
Primer ́→3
́)
substrates
C
not
T
G
G
A
(5
́→3
required
RNA
synthesis
using
NTP
5
́
for ́)
substrates
primer
3 ́ C
A 5
́
T A
G C
A U
C G
T
A
A
T
G
C
C
G
C
G
A
G
T
3 ́
A
C
T
C
T
G
G
A
5
3 ́
́
C
A
T
G
A
C
5
Mispaired
́
T A
A
G
C
C
G
U
C
G
G
U
A 3
deoxynucleotide
removed
(3
́→5
A
C
T
C
Mispaired
́ exonuclease)
T
G
G
A
5
́
G
A
5
́
A
5
́
not
nucleotide
removed
dTMP
3
́ C
A
5 ́
3
́ C
A 5 ́
T
G
A
C
T
A
A
C
U
G
A
T
T
G
A
C
A
C
T
U
G
A
G
C
C
A T
G
C G
G 3
A
A
I 2
1.
G
C
C
G
A
C
G
G
C
T
Comparison
T
C
T
G
G
A
5 ́
3
acid
of
A T
DNA
C G
T A
C G
I 2 Figure
and
T A
G C
G 3
A
5
3 ́
3. I 2 Polymerase 3. Polymerase
RNA
Enzymes Enzymes
2
U
G C
C
C
G
polymerases
T
G
Synthesize DNA Synthesize
A
T
A
G
5 ́
C
A
U
C
G
and
DNA RNA
C G
G
A
U
3 ́
C G
A
C
3′→5′)
exonuclease)
require
Polymerase
dGTP,
(or
dCTP,
dTTP
DNA)
RNA
templates.
synthesis
A
A
C
T
C
T
G
U
G
A
G
A
C
Polymerase
CTP,
UTP
No
These
enzymes
are
most
commonly
G
fidelity
None
Yes
T
U
RNA
GTP,
C
G
RNA
ATP,
T
U
and
DNA*
RNA
(3′→5′
A
DNA*
primer
RNA
A
RNA
Required
and
A
DNA
dATP,
DNA
T
Polymerases
(5′→3′)
(copied
́ C
́
substrates
viruses.
C 5 ́
RNA
Required
with
A
Low
template
*Certain
G
synthesis
Required
activity
T
fidelity
synthesized
Proofreading
A
DNA
DNA
Nucleic
́ C
High
Figure
Table
C
́
associated
G 3
́
́
CHAPTER
Similarities
between
•
The
newly
•
The
template
•
The
newly
is
is
in
strand
is
added
when
DNA
REPLICATION
AND
REPAIR
include:
made
scanned
synthesized
nucleotide
reacts
template
is
with
a
strand.
during
this
Differences
in
the
the
5′→3′
3′→5′
direction.
direction.
complementary
and
antiparallel
to
the
nucleoside
the
3′
hydroxyl
triphosphate,
Pyrophosphate
(PPi,
group
which the
last
the
dNTPs,
is
two
of
base
the
growing
paired
with
phosphates)
is
the
released
reaction.
include:
The
substrates
for
RNA
•
DNA
•
DNA
for
whereas a
polymerases
whereas
the
substrates
RNA
contains
primer,
uracil.
whereas
cannot
RNA
initiate
polymerases
strand
do
synthesis,
not.
whereas
RNA
can. polymerases
can
correct
cannot.
mistakes
DNA
(“proofreading”),
polymerases
have
3′
whereas
→
5′
RNA
exonuclease
activity
proofreading.
STEPS
OF
DNA
molecular
1.
The
2.
Helicase
REPLICATION
mechanism
is as
of
DNA
replication
is shown
below.
The
sequence
of
follows:
base
the
are
NTPs.
require
DNA
polymerases
events
the
thymine,
polymerases DNA
synthesis
are
polymerases is,
for
DNA
synthesis
contains
That
The
synthesis
strand
strand
new
strand
•
RNA
|
strand.
Each
•
and
synthesized
template •
DNA
2
sequence
at
breaks
two
the
parental
the
origin
of
hydrogen
strands
replication
bonds of
DNA
is
holding to
recognized.
the
begin
base
pairs
unwinding
together.
and
forms
the
single
This 2
allows
replication
forks. 3.
Single
stranded
tion
of
them 4.
DNA
each
DNA
from
Primase
as
strand
a at
a
for
template are
from
the
III
at
the
3′
complementary strand ing •
be
each
to
stranded
reassociating
and
of
por
protecting
each
are
DNA,
in
The required
and
the
5′→3′
parental
strand
because
can
only
DNA
extend
a
“primer.”
synthesizing
of
primer
strand.
primers
synthesis
a preformed
RNA
parental
RNA
initiate
DNA
RNA
antiparallel
made
binds from
nucleotides)
on
process.
begins end
and
can
this
of
10
origin
to
end
polymerase
beginning
(about
the
unable 3′
(SSB) them
nucleases.
short
beginning
polymerases
DNA
by
synthesizes
is used
protein
preventing
degradation
direction,
5.
binding
strand,
primer.
to
continuously
the in
in The
parental
one
long
the
5′→3′
newly strand
piece
direction,
synthesized used
as
is
known
and
strand a
is
template. as
This
the
“lead
strand.” The
“lagging
strand”
fragments Each
(about Okazaki
primase, merase
and III.
is 1,000
synthesized
fragment then Each
is
long)
initiated
completed fragment
discontinuously
nucleotides
by is
made
by the
the
the
as
synthesis
synthesis in
as
known
of 5′→3′
a
series
Okazaki of
DNA
an using
of
small
fragments. RNA
primer DNA
by poly
direction.
2
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry •
6.
Medical Genetics
7.
Behavioral Science/SocialSciences
There
is
forks
on
the
RNA
primers
DNA
polymerase removes
ning
at
Both
eukaryotic their
makes
a of
DNA
9.
of
of
by
proteins
that
Eukaryotic •
DNA DNA
polymerase DNA,
the
I
begin
ability
to
If DNA
unpaired
synthesis
“proof
polymerase
base
at
the
3′
continues.
fragments,
converting
resealing
block
the
action
of
gyrase.
in
them
to
DNA
in
the
are acid
a
kills
topoisomerase
anticancer
II
agents.
to
be
worked
prokaryotes
DNA
Quinolones
eukaryotic
rep DNA
very
out.
are
similar
to
steps
and
with
those
The
compared
this.
used
2.
Polymerases α
lagging
and
δ
work
together
to
synthesize
both
the
leading
strands.
•
DNA
polymerase
•
DNA
polymerases
repair.
DNA
γ replicates β
mitochondrial
and
ε are
polymerase
thought
ε may
HY
DNA. to
participate
substitute
for
primarily
DNA
in
polymerase
δ
DNA MY in
certain LY
cases.
High
NOTE
Telomerase
Telomerase
Telomeres
are
eukaryotic
chromosomes.
•
Completes
the
telomere
replication
sequences
eukaryotic
of
at
both
the ends
telomeres of
chromosome
a
5′
the
telomeres
and •
Present and
in embryonic certain
present
adult in
cells, stem
adult
fetal
cells;
somatic
not
are
the
end
the
Inappropriately cancer unlimited
2
cells,
present contributing replication
in
many to
their
sequences
each
each
because
strand.
become
cells
at
With
shortened
of
Telomerase
DNA
This so
the
ends
round
that
linear
the
to
DNA
replication
polymerase
contributes
short
of of
cannot the
aging
chromosomes
molecules MEDIUM
in
most
cells,
cannot
H
in YIELD
normal
ME
cells,
the
LOW YIELD synthesis of
complete of
die.
telomere
an
stem
enzyme
template reverse
eukaryotes to activity
would
is present but
used
complementary
that
activity cells,
in
transcriptase
sequences
telomerase and
is RNA
telomerase •
repetitive
Yield
because
eventually
function properly FUNDAMENTALS
FUN
cells,
a short
cells
a
gyrase
passing
Nalidixic
believed
completely
replication
I 2
is
been
each the
DNA
DNA,
strands.
of as
of
forks,
topoisomerases.
useful
front
form. of
both
eukaryotes
yet
in
replication
strands
Inhibitors
becoming
“swivel”
the supercoils
both
then
not
a at
positive
nicking
and
polymerases
and
resulting
DNA
nick,
are
Table
uncharacterized
new
have
provides
and
replication
in in
an DNA
activity.
Okazaki
the
by
have
involved
eukaryotes
replication
fragment.
the
II)
DNA
details
and
synthesizes
before
unwinds
inhibiting
of the
two
prokaryotes
exonuclease
synthesis,
overwound
the
mechanism
In
polymerases
3′→5′
topoisomerase
teniposide)
However,
a
between
supercoils
(etoposide,
the
DNA.
becomes
drugs
bacteria
of
eukaryotes
Okazaki
is removed
helicase
through
family
each
and
DNA of
“nicks”
(DNA
in
DNA.
exonuclease)
DNA
of
negative
strands
for
H
with
prokaryotic
the
As
RNAase
neighboring
strand
seals
it
(5’
during
fork.
inserts
strand
gap
means
growing
gyrase
the
the
by
strand
ahead
in
of
mistake
lication
The
end
and
ligase
DNA
in
primer
work
continuous
lagging
by
fills
3′
the
a
removed
the
the
read”
and
chromosome. are
both
end 8.
a leading
not
in
otherwise only
somatic
in cells.
to
the
DNA
(hTRT). be embryonic
maintain
the
telomere
sequence,
Telomerase lost
during cells,
REINFORCEMENT telomeres. It contains
is thus replication.
germ
(reproductive)
as able
well to
as replace
Normally cells,
RE
CHAPTER
Cancer
cells
telomeres
often
have
from
relatively
becoming
high
levels
shortened
and
of
telomerase,
preventing
contributing
to
the
the
2
BRIDGE
immortality
|
TO
AND
REPAIR
PHARMACOLOGY and
fluoroquinolones
inhibit
DNA
cells. gyrase
Table
REPLICATION
of Quinolones
malignant
DNA
I 2
2.
Steps
and
Proteins
Involved
in
DNA
(prokaryotic
preventing
Replication
These Eukaryotic
drugs,
in
Origin
Replication
of
Prokaryotic
replication
Unwinding
of
(ori)
DNA
One
double
Cells
ori
site
replication
which
II),
and
are
most
transcription.
active
against
Cells aerobic
Step
topoisomerase
DNA
gram
negative
bacteria,
include:
(Nuclei)
per
Multiple
ori
chromosome
chromosome
Helicase
Helicase
sites
per
•
Levofloxacin
•
Ciprofloxacin
•
Moxifloxacin
helix Resistance Stabilization
of
template
unwound
Single
strands
stranded
DNA
binding
protein
Synthesis
Synthesis
of
RNA
primers
of
DNA
Lagging
strand
merase
protein
(SSB)
polymerase
III
binding
time;
DNA
DNA
polymerases
poly
δ
DNA
III
+
δ
α
polymerases
of
primers
DNA
polymerase
(5′→3′
of
RNA
with
and
infections
in
BRIDGE
TO
I
RNAase
exonucle
the
H
(5′→3′
exonuclease)
polymerase
I
DNA
polymerase
DNA
of
positive
supercoils
ahead
ligase
advancing
replication
DNA of
DNA
topoisomer
ase forks
of
ligase
DNA
azido
Once to
as
topoisomerase
II
in
genome.
The
replacement
normal
hydroxyl
telomeres
Not
required
the
Telomerase
by
High
transcriptase
HIV,
use
is to
this
in
cells
•
Associated
•
Encoded
tive
sequences
to
RNA
also
replicate
reverse
telomerase
human in
DNA
be
DNA new
polymerase
DNA.
RNA
genomes.
inhibited
by
transcriptase
most
DNA
AZT,
ddC,
is
related
enters
cells,
triphosphate for
it can
be
derivative the
viral
synthesizing
reverse
DNA
from
azide
instead
at
3′
the
and
its
of
position
a
MY prevents
deoxyribose effectively
causing it is
chain LY
(see
that Chapter
YIELDan
of
YIELD reverse
FUNDAMENTALS
play
a role
genomes in
amplifying
polymerase, proofreading
replication
termination. reverse activity.
YIELD
MEDIUM
YIELD
LOW
YIELD
ddI.
FUNDAMENTALS
REINFORCEMENT
viral
a DNA lacks
HIGH
further
notably LOW by
synthesis and
activity:
(residual DNA)
Yield
that requires MEDIUM
Retroviruses,
(hTRT)
retrotransposons in
of their
can
contain
with
dependent
synthesis
retroviruses
by
maintained
an the
enzyme
transcriptase
Eukaryotic
direct
HIV
gyrase)
Transcriptase
template
of
structurally
of an HY group
HY
II (DNA
transcriptase
RNA
tract
2′,3′
AZT
the
a substrate
RNA
Although
Reverse
urinary
treatment (3′
LY
Reverse
lower
sexes.
or
transcriptase
MY Synthesis
over of
PHARMACOLOGY
of AZT
converted
δ
fragments
Removal
both
compounds.
DNA
Okazaki
developed treatment
and
chemotherapeutic use
used of
upper
dideoxythymidine)
DNA
Joining
has
include
+
ase)
Replacement
gonorrhea
One
RNA
drugs
uses
α
fragments)
Removal
the
current
Primase
DNA
strand
to
stranded
DNA
(SSB)
Primase
Leading
(Okazaki
Single
REINFORCEMENT
permanently certain
repeti
7)
2
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry 5
́
3 ́
3
́
5 ́
Leading 1.
Strand
Primase
Synthesis
(Continuous)
synthesizes
the
primer
(
) 5
́
to
3
́.
Helicase 2.
Medical Genetics
DNA
polymerases
into
Origin 3.
the
Helicase
Lagging
Behavioral Science/SocialSciences
and
δ
fork
(
) continues
Strand
Synthesis
extend
the
(Leading to
primer,
strand unwind
moving
synthesis).
the
DNA.
(Discontinuous)
3 ́
5
3
α
replication
́
5 ́ ́
1.
Primase
2.
DNA
synthesizes polymerases
away 3.
α
from
the
Synthesis
stops
the
of
primer
of
the
the
primer
and
δ
DNA
leading
diagram,
or
the
fork
when
of
3
́. moving
strand
polymerase
primer
to
primer,
(Lagging
strand
the
) 5 ́
extend
replication
the
(
synthesis).
encounters
on
the
other
the
previous
side (Okazaki)
fragment. 4.
As
helicase
third
RNAase the
next
more
of
fragment
H RNA
(5
the
will
replication
be
from
cell, fragment
activity)
fragment
DNA
1.
In
polymerase
(2),
to
fork,
fill
in
digests the
extends the
a
added.
́ exoribonuclease
primer
eukaryotic
3 ́
5 ́
opens
Okazaki
the
gap.
5 ́
3 ́
In
prokaryotic
the
5
́
the
DNA
cells
(2)
both
to
types
fragments
of 1
polymerase
activity
polymerase
fragment In
DNA
exonuclease
to
activity fill
in
cells
and
2
the
to
has
both
primers,
extend
the
and next
gap.
DNA by
1 remove
ligase
making
connects a
phosphodiester
bond. 5 ́
3
́
5
́
5 ́
3
́
3 ́
5
́
3 ́ +
This
whole
primers
Figure Figure
I 2 4. I 2
4.
Question
Which
of
repeats
from
both
DNA
Replication
DNA
Recall
replication
process
the
following of
DNA
A.
DNA
gyrase
B.
DNA
helicase
C.
DNA
ligase
D.
DNA
polymerase
the
to
leading
remove and
all lagging
RNA strands.
Replication
enzymes
is
the
target
of
fluoroquinolones
in
strands?
Answer:
2
A
CHAPTER
DNA
BRIDGE
REPAIR
The
structure
of
chemicals tion.
or
of
their
DNA.
occurs
in
any
G2
bases
If
phase
to
also
of
correct
be
to
of
cells
exposure during
their
an
the
DNA
risk
cell
Mismatch
of
DNA
repair
may
tumor
not
I 2
3.
DNA
occur
properly
suppressor
inactivated
AND
REPAIR
PATHOLOGY
through
•
the
cancer.
Most
The
p53
when
genes
mutation
gene
prevents
repair
have
or
errors.
or
encodes
a cell
from
entering
been
deletion:
a
with the
deletion
protein
that
damaged
DNA
S phase.
associated
Fraumeni Table
REPLICATION
a
into
increased
DNA
|
TO
certain
sequence
using
mutations
cycle.
to
replica
maintain
stable
eukaryotic
replication
through
to
replicate
carries
the
ways
incorporated
introducing
repair
phase
of
allowing
allowed
risk
DNA
G1
number
can
are
high
in
the
a
evolved,
cells
is a
defect in
in
have
there
occurs the
damaged
Incorrect
genomes.
Thus
repair
be
systems
template,
DNA
can
repair
damaged new
DNA
radiation.
Multiple
stability
2
Inactivation
with
syndrome
and
Li
many
solid
Repair tumors. Recognition/
Damage
Cause
Excision
Repair Enzyme
•
Enzymes
ATM for
Thymine
UV
radiation
Excision
endonuclease
DNA
polymerase
DNA
ligase
DNA
polymerase
gene p53
ataxia dimers
(deficient
(G1)
in
xeroderma
encodes activity.
ATM
replication
A
mutation
on
one
of
(breast, matched
errors
two
base
genes,
or
(G2
and
hMSH2
hMLH1,
defective
S)
DNA
ligase
initiates repair
BRCA
2
The
retinoblastoma
first
tumor
and
is a
in
x rays
by
and
lymphomas.
BRCA
and
cancer)
(breast
ovarian
1
cancer).
Rb
gene
was
the
mismatches,
resulting tion
in
a
known
condi
as
hereditary sis
to prostate,
and
inactivated
of •
DNA
is
essential
characterized to
predisposition DNA
kinase
telangiectasia,
hypersensitivity
pigmentosum)
Mis
a
nonpolypo
colorectal
suppressor
gene
negative
cell
cycle
the
transcription
regulator
through
its
ability
factor
cloned, of
E2F
to
the bind
and
cancer—HNPCC. repress Cytosine
Spontaneous/
Uracil
glycosylase
deamination
heat
endonuclease
AP
DNA
polymerase
DNA
ligase
transcription
required
for
HY
G1
MY
LY
of
Thymine
Ultraviolet DNA
light (also
induces
the
occasionally
thymine
dimers
Thymine
formation
between
interferes
dimers
High
Dimers
are
of
other
with
pyrimidines).
replication
from
DNA
and by
The
normal
formation LOW expression.
gene
a nucleotide
excision
LY
HIGH
Yield
adjacentMEDIUM thymines YIELD
between
adjacent
DNA
eliminated
dimers
genes
S phase. HY
MY
Repair
of
in
YIELD
MEDIUM
YIELD
of YIELD
LOW
YIELD
repair
mechanism. FUNDAMENTALS Steps
in
•
nucleotide
An
excision
ter
backbone
and •
DNA
DNA
repair:
of the
the
damaged
fills
using seals
(excinuclease)
the the
makes
strand
defective
polymerase
ligase
REINFORCEMENT
endonuclease
removes
direction, •
excision
FUNDAMENTALS
on
both
nicks sides
in of
the
the
REINFORCEMENT
phosphodies
thymine
dimer
oligonucleotide. in
the
gap
undamaged nick
by
synthesizing
strand in
the
repaired
as
DNA
in
the
5′→3′
a template. strand.
2
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry Base
excision
Cytosine
repair:
cytosine
deamination
uracil.
The
uracil
deamination
(loss is
of
an
recognized
amino
and
group
from
removed
(base
cytosine)
converts
excision)
by
a
cytosine
uracil
to
glycosylase
enzyme. Medical Genetics •
Behavioral Science/SocialSciences
A
Subsequently
this
the
sequence
damaged
•
DNA
polymerase
•
DNA
ligase
summary
they
of
function
area
in
the
the
cycle
the
repaired
involved is
an
AP
endonuclease
that
removes
DNA
gap
in
genes cell
by
the
nick
important the
recognized
from fills
seals
in
is
in
shown
strand
maintaining
DNA
fidelity
and
where
below.
M
Mismatch repair • MSH2 • MLH1
G2
G1
G0 Thymine
dimer
(bulky S
lesion)
repair
• XP • Nucleotide
excision
repair DNA
polymerase
proofreads
(cytosine
deamination)
during
DNA
synthesis
Genes
controlling
entry
into
S
phase
• Rb • p53
Figure
Diseases
I 2 6. 5. Important Maintaining
Associated
Inherited with
Figure I 2
with
mutations
that
a predisposition
to
MY
Important Genes Associated with Genes Associated with Maintaining Fidelity Fidelity of Replicating DNA of Replicating DNA
DNA
result the
HY
High
Repair
in
LY
defective
DNA
development
of
mechanisms MEDIUM
repair
are
YIELD associated
extreme most
repair
replication.
2
sensitivity common
Hereditary to
pigmentosum
is an to
sunlight,
deficiency
mismatched
skin
occurs
nonpolyposis
autosomal
in
colorectal base
pairs
recessive
freckling the
and
DNA
disorder, ulcerations,
excinuclease
cancer in
ME
cancer. LOW
Xeroderma
H
Yield
results that
are
and
accidentally
a
skin
by cancer.
FUNDAMENTALS
enzyme.
from
YIELD
characterized
deficiency
FUN
REINFORCEMENT in the ability
introduced
The
during
RE
CHAPTER
XERODERMA
Xeroderma
pigmentosum
1/250,000) ulcerations, and
and
most
6
year
parents
and
creams
recessive
disorder
sensitivity
Carcinomas
to
and
The
most
Xeroderma
the
often
as
skin
melanomas
excision
should
Hereditary
appear
Hereditary
exposure
the
genes
early
in
occurs
These
deleted
of
the
occur,
causing
retain
errors
gene.
loss
of
life,
in
the
cell
of
the
in is
a
many
Patients
and
loci,
the
child’s
the
relevant
with
results
from
the
disease
a mutation
enzymes
remove
that
errors
or
one
in This
some
of
intestinal
the
causes
which
cells
out into
may
inherit
nonfunctional,
mutation
in
carry
introduced
individuals
function.
in
to
of
blood.
HNPCC,
somatic
other
manifested
area.
syndrome)
gene
repair
neck ointments
exposed
measurement
encoding
hMLH1
and
typical
was
(HNPCC)
with
facial
light.
detect
birth,
mismatch
This
UV
were
throughout
of
hMSH2)
families
After
the
(mutations)
progression.
undergoing
NOTE one
Microsatellites
prominent
instability.
other
copy
may
chromosomes
may
to
contribute
because
they
are
repeats)
to constant
a
are
repeats
of
patient
instability,
error with
whereas
used
repair) a family as
do
that
accompanies
HNPCC, normal
not
pedigree
a diagnostic
, tri
dispersed
usually
known
(but
, and
as
short
tandem
tetranucleotide
throughout
not
exclusively)
the in
DNA,
noncoding
regions.
DNA
cells cells
from
from
the the
replication resected
individual
is tumor (which
microsatellite show still
example,
particular micro
repair,
show and
tool.
microsatellite histologic
instability. analysis,
microsatellite
Along
with instability
TGTGTGTG locus.
the
may
If cells
replicated
occur
lack
at
a
in
the
mismatch
DNA
will
that
locus,
vary
retain number
mismatch
di
division.
type In
(also
deleted
For
from
REPAIR
tone.
(Lynch
enzymes
copy
hMSH2
of
parents
with
child
by cells
cancer
In
the
muscle
cancer
or
the
away
freckling
poor
white
colorectal
replication.
nonfunctional,
when
source
hMLH1
repair.
during
any
his
in go
diagnosed
colorectal
(usually
mismatch DNA
be in
to
nonpolyposis
of
and
because
not
excessive
stature
can
nonpolyposis
satellite
AND
freckling,
deficiency
blistering
did
worse
endonuclease
avoid
clinic
and
noted
slight
pigmentosum
enzyme
One
REPLICATION
(incidence
sunlight,
common
the
lesions
became
physician
well
to
lesions
that
and
as
brought
excessive
The
body,
cancer
autosomal
cancer.
was
noted
sunlight.
ly
child
with
The
copy
of
DNA
PIGMENTOSUM
extreme
cancer. die
old
concerned
the
skin
|
endonuclease.
A
DNA
an
by
patients
excision
one
is
characterized
2
of
repeats
at
e.g.,
information may
be
TGTGTGTGTGTG microsatellite
or
TGTGTG.
This
variation
is
instability.
2
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry Review Select
Medical Genetics
1.
Questions the
It
is
ONE
best
now
believed
stitutions
answer.
that
causing
bases
during
DNA
determining
substantial
proportion
genetic
mutation
are
Which
accuracy rate
of
disease
replication.
the
substitution
a
human
of
nuclear
in
human
the
due
to
single
proofreading DNA
nucleotide
sub
misincorporation
of
activity
is
and
thus
replication
critical the
in base
chromosomes?
Behavioral Science/SocialSciences
2.
A.
3′
to
5′
polymerase
B.
3′
to
5′
exonuclease
C.
Primase
D.
5′
to
3′
polymerase
E.
3′
to
5′
exonuclease
The
V.
a The
that
3.
inactivates
A.
TATA
B.
Cap
C.
Catabolite
D.
Acyl
E.
Single
The
is
box
deficiency to
lowing
of
impaired
expression
of
the
viral
protein
excision
endonuclease in
be
may
xeroderma
enzyme?
absent
in
produce
an
pigmentosum. a
patient
of
Protection
D.
Repair
of
mismatched
bases
during
DNA
E.
Repair
of
mismatched
bases
during
transcription
exquisite
Which
deficient
Removal
in
this
sensi of
the
fol
endonuclease?
introns pyrimidine
dimers
against
DNA
Pseudomonas
viruses
action
duplication
in
participates
in
bacterial
antibiotic?
A.
DNA
polymerase
I
B.
DNA
polymerase
II
C.
Topoisomerase
I
D.
Topoisomerase
II
E.
DNA
ligase
replication.
(SBP)
C.
this
DNA
enzyme
(CAP)
B.
by
HIV
encoded
(TBP)
of
enzymes
infection
designated
viral for
Removal
anti
a
required for
upon
virus,
(ACP)
would
chromosome
2
markedly
A.
The
δ
(CBP)
radiation
functions
III
polymerase
protein
protein
an
is
the
protein
binding
ultraviolet
polymerase
DNA
substrate
protein
strand
to
a potential
activator carrier
α
cells
nuclear
protein
γ
immunodeficiency
traced
binding
binding
T
human
δ
polymerase
DNA
of
cytotoxic
cell
DNA
of
activity
been
polymerase
polymerase
activity
a host
protein
tivity
4.
has
DNA
of
DNA
discovered
defect
Which
of
of
newly
of
activity
activity
proliferation
with
activity
of
norfloxacin
rapidly
is
dividing DNA
replication
replication
related
cells.
to
Which and
its of
is
ability the
directly
to
inhibit
following inhibited
CHAPTER
5.
Cytosine for
6.
arabinoside
cancer,
tain
cases,
nase
in
A.
cytosine
B.
cytidylic
C.
thymidine
D.
uracil
E.
cytidine
related
to
an
This
enzyme
congenital
(DKC)
capacity to
in
is
the
the
nuclei site
for
most
likely
centromeres
B.
Synthesis
of
Okazaki
C.
Synthesis
of
RNA
D.
Synthesis
of
telomeres
E.
Removal
Single
strand
DNA
damage.
damaging
of
These the
the
agent
develop.
enzyme
In
cytidine
araC
REPAIR
to
cer deami
form
is
ultimately of
enzyme
rapidly this
an
enzyme
in
cells.
contains
for
which
defect
Which
has
chromo
Structural a single
function.
DKC
in The
needed
dividing
protein
catalytic
disease
impaired.
analysis stranded
step
in
DNA
patients?
primers
in
DNA
comprise
breaks
are
by the
a
the
series
due
of
the
of
enzymes
phosphodiester
catalyzes
single
frequently
residues
repaired reform
class
of of
inherited
markedly
fragments
deoxyribose
break
DNA
in
AND
primers
RNA
breaks
is of
deficient
of
in
eventually
inactivate
genetically
cells
normal
Synthesis
Which
increase
production
A.
and
chemotherapeutic
may
would
is a stem
active
required is
of
inadequate
that
replication
of
effective
REPLICATION
arabinoside
that
type
an drug
DNA
arabinoside
shown
RNA
this
cells.
duplication
has
as
to
|
acid
traced
some
7.
is
tumor
proliferative
been
is used
resistance
resistance the
Dyskeratosis the
(araC)
although
2
the
most to
sugar
the
of
species
backbone.
reconstruct
between of
type
oxygen
phosphate that
bonds formation
frequent
reactive
This the
sugar
nucleotides. phosphodiester
bond
repair?
A.
DNA
glycosylases
B.
DNA
helicases
C.
DNA
ligases
D.
DNA
phosphodiesterases
E.
DNA
polymerases
2
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry Answers
1.
Medical Genetics
Answer:
2.
DNA.
otic)
do
with
DNA the
not
5′
to
5′
exonuclease
of
an
pol
participate
to
3′
E.
TBP
in
this
process,
and
CBP
participate CAP
ACP
is
Nucleotide
in
XP
4.
Answer:
D.
Norfloxacin
inhibits
5.
Answer:
D.
Deamination
of
6.
Answer:
D.
The
merase
required
for enzyme
This
the
ends
(telomeres)
C.
other
All
bonds of
DNA.
DNA primers are
eukaryotic
in
repair
the
of
human
pol
III
(prokary
are
replaced
always
gene the
fatty
of
is
DNA
synthesized
transcription
expression
acid
and
of
prokary
synthesis.
thymine
is of
(pyrimidine)
dimers
DNA
described
during
as
produce
an
RNA
duplication
linear
is
a
uracil.
dependent in
reverse
II).
the
DNA
nuclei
of
transcriptase,
poly
rapidly that
divid
replicates
chromosomes.
have
repair of
(topoisomerase
would
telomerase,
options
gyrase
cytosine
chromosome
backbone
phodiester strands
excision
enzyme
cells.
phosphate
represents
patients.
ing
Answer:
strands
regulates
involved
B.
7.
RNA
DNA
δ
replication
and
short
in
respectively.
operons.
the
new
pol
the
direction.
deficient
of
DNA
for
(mitochondrial)
and
Answer:
None
of
required
γ
replication,
translation, lactose
activity
enzyme
DNA
during
Answer:
otic
3
3′
chromosomal
mRNA
3.
The
activity
in
Behavioral Science/SocialSciences
E.
proofreading
reverse
systems
DNA. DNA
Although synthesis,
transcriptase
use
a
ligase
activity.
to
seal
polymerase these
breaks
in
enzymes enzymes
the
make do
not
ligate
sugar phos
Transcription
LEARNING
and
RNA
3#
Processing
OBJECTIVES
❏
Use
❏
Understand
concepts
of
prokaryotic
❏
Understand
concepts
of
eukaryotic
❏
Demonstrate
knowledge
of
types
of
RNA
understanding
primary
pre
mRNA
messenger
RNA
messenger
of
RNA
alternative
splicing
of
eukaryotic
transcripts
❏
Know
key
features
of
ribosomal
❏
Know
key
features
of
transfer
RNA
(rRNA)
RNA
(tRNA)
TRANSCRIPTION The
first
stage
in
information base
in
sequence
one
of
strand
of
merase moves is
as in
of
the
the
3′
to
single
along
below
the
illustrates on
stop
RNA.
of
For
strand)
strand
particular RNA
the only
poly
polymerase the
RNA
polymerase for
form gene,
by
DNA,
the
to
RNA
of
RNA
(terminators) an
any
Because
template.
of
molecule
is copied
direction.
template
the
transcription
DNA
product
recognizes
each
of
the
thousands
organism.
arrangement
and
direction
of
transcription
for
molecule.
Terminator
Promoter
3′
signals
genome
the
a DNA
of
to
the to
and in
5′
is
stranded
template
the
complementary
units
genes
(the in
direction
information
a double molecule
molecule RNA
5′
genetic of
stranded
(promoters)
figure
of
sequence
DNA
transcription
several
a
and
signals
The
expression base
it synthesizes
antiparallel
start
the the
Terminato
Promoter
Transcription
5
́ Spacer
Gene
DNA 3
Spacer
1
Gene
DNA
Spacer
2
Gene
DNA
3
́
5
́
DNA
́
Transcription
3 Spacer
Transcription
Promoter Terminator Figure
I 3
1.
Figure
Transcription I 3
1.
Transcription
of
Several of Several
Genes Genes
on on
a
Chromosome
a Chromosome
31
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry TYPES
OF
RNA
RNA
molecules
•
play
Ribosomal
Medical Genetics
cell.
a
variety
RNA
It
is
used
associates
of
roles
(rRNA), as
in
which
is
a structural
with
the
cell.
the
The
most of
proteins
to
types
abundant
component
ribosomal
major
the
form
of
type
of
ribosome.
the
RNA
are:
RNA
in
the
Ribosomal
complete,
RNA
functional
ribosome. •
Transfer
Behavioral Science/SocialSciences
Its
RNA
function
linked •
is
type
of
(mRNA),
very
heterogeneous
that
by
that
the
•
of
•
nuclear
of
RNA
information
ribosome.
of
they
will
RNA. be
mRNA
the
in
cell
thousands
has
of
the
RNA
population as
the
specifying Messenger
sequence, of
or
cells.
is
a
cell
the is
essentially
different
a
proteins
It
its
pre
mRNA),
represents
which
is
precursors
of
found
only
mRNA,
processing.
(snRNA), of
which
major
is
also
functions
only
in
the
participate
in
splicing
with
enzymatic
activity.
that
synthesizes
is
to
found
nucleus
of
mRNA.
which both
(hnRNA
posttranscriptional
introns)
Ribozymes, in
base each
RNA
RNA One
found
the
the The
and
eukaryotic
its
eukaryotes. (removal
to
for
nuclear
during
Small
type
where
cell.
nucleus
formed
abundant
ribosome,
carries
translated.
size
most
the
synthesis.
protein
molecule
Heterogeneous in
is
in
mRNA
a
second to
which
of
RNA
the
protein
sequence
only
made
are
RNA
molecules
prokaryotes
and
They
are
eukaryotes.
POLYMERASES
There
is a cell.
single
The
prokaryotic
core
subunit
structure of
transcription
of
transcription.
protein
are
RNA
they
3
RNA
factor.
5.8S
called
promoter.
binds
the
is
transcription
of
RNA
has
required
released
for
the after
requires is
in
the
immediately
polymerase
preventing
polymerases,
is
types
molecule
sometimes
RNA
DNA,
all RNA
(σ)
factor
prokaryotic to
the
sigma
Sigma of
The
RNA
I is
polymerase and polymerase
some
snRNA,
Transcription
factors
transcription.
The
mushrooms).
factor
making
a
inhibited
by
transcription.
distinguished
by
the
particular
types
of
II some
in
the
nucleolus
and
synthesizes
28S,
18S,
is
located
and (such
is
5S
located
the
nucleoplasm
and
synthesizes
hnRNA/
All
in
the
nucleoplasm
and
synthesizes
tRNA,
rRNA. as
TFIID
requirements
polymerase
in
snRNA. III
understood. RNA
located
rRNAs.
RNA
addition,
D
polymerase
RNA
well
a
Termination
(ρ)
eukaryotic
mRNA •
protein at
for
produce.
and •
A
Actinomycin
There
•
rho
polymerase
responsible
α2ββ′.
called
rifampin.
RNA
polymerase
initiation initiation
3
acids
during
acid
different
not
is
RNA
amino
the
which amino
carry
together
Messenger
•
(tRNA), to
for
for
transcription II
is
RNA
polymerase
termination can
inhibited
of be by
inhibited α
amanitin
II)
help
transcription by
to in
actinomycin (a
toxin
initiate eukaryotes D.
from
certain
are In
CHAPTER
Table
I 3
1.
Comparison
of
RNA
RNA
polymerase
ββ′)
Requires
sigma
initiate
at
(ρ)
to
(σ)
RNAP
1:
rRNA
RNAP
2:
hnRNA/mRNA
RNAP
3:
tRNA,
No
to
sigma,
promoter
bind
requires
No
a
Sometimes
AND
RNA
PROCESSING
(nucleolus)
rho
and
5S
but
before
Except some
rRNA
snRNA
rRNA
transcription
RNA
5S
factors
(TFIID)
polymerase
required
terminate
Inhibited
by
rifampin
RNAP
D
Actinomycin
Actinomycin
TRANSCRIPTION:
AND
TRANSCRIPTION
Eukaryotic
Single
rho
|
Polymerases
Prokaryotic
(α2
3
2
inhibited
by
α
amanitin
(mushrooms)
D
IMPORTANT
CONCEPTS
TERMINOLOGY
RNA
is
synthesized
template
for
transcription
•
RNA
RNA
which
its
The
polymerase
(uses
terminology
genes
begins,
which
moves
CTP,
DNA
used
DNA for
as
searching
as
when
the
of
template in
a
discussing
is
5′
DNA
is No
RNA
to
used
regions. establishes
as
primer in
3′
the
is
the
3′
direction
to
does
and
template,
required. 5′
direction
using
polymerase
complementary
promoter Binding
strand
the
substrates.
for
polymerase.
strand
product
product
by
RNA
proceeds.
along
RNA
UTP)
RNA
in site
transcription
the
The
RNA Important
binding
direction
GTP, work.
template
NTPs
not
antiparallel
proofread to
the
strand. coding
(antitemplate)
identical uracil By
the
synthesizes
(ATP,
•
locates is
polymerase
it
RNA).
below.
transcription in
dependent
of
polymerase
and
•
DNA
illustrated
promoter
where
as
a
synthesis
is
The
•
by
the
in
strand
sequence
instead
of
convention,
to the
the
the
thymine base
is
RNA
not
used
molecule,
found
sequence
in of
a
during
transcription.
except
that
It
RNA
is
contains
DNA. gene
is
given
from
the
coding
strand
(5′→3′). •
In
the
vicinity
location as –
the To
of +1 the
bases – •
To
Transcription
of
base left are
the
a gene,
important
right
of
that
(5′, –1,
a numbering bases.
gene
or –2,
(3′, ends
The
or
base
this
starting
is
used
to
transcribed
identify as
RNA
the is
defined
region.
upstream) –3,
system first
of
point
for
transcription,
etc. downstream)
when
RNA
of polymerase
this
point, reaches
bases
are
a termination
+2,
+3,
etc. signal.
3
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry Upstream
Downstream
Transcription
unit
Start Medical Genetics
Terminator
site
-10
+1+10
Coding
(antitemplate)
strand RNA
3
5 ́
́
Promoter 5
3 ́ Behavioral Science/SocialSciences
Template
DNA
RNA
polymerase
transcribes ́
DNA
template
strand
strand
RNA
5 ́
3
transcript
is
́ synthesized
5
́
3
́
HY
Figure
I 3 Figure 2. Transcription I 3 2. Transcription
of
MY
DNA of DNA
LY
Flow
of
Genetic
DNA
to
Protein
For
the
case
Information
High
of
a gene
found
in
double
stranded
below.
Messenger
RNA
and
antiparallel
mRNA carboxyl
in
from
the
5′
to
the
to
3′
coding
for
a protein,
DNA, is
the
single
synthesized
template
in strand
direction,
as
it
relationship
stranded
of
the
among MEDIUMthe
mRNA, 5′
DNA.
synthesizes
to
3′
and
The
ribosome
the
protein
sequences YIELD
protein
direction.
It
is
ME
illustrated
LOW YIELD complementary
is
translates from
H
Yield
the
the amino FUNDAMENTALS
to
the FUN
terminus. REINFORCEMENT
Coding
strand DNA
5 ́
DNA
A
T
GGGGC
T
CAGCGAC
coding to
(except
T
DNA 3 ́
TACCCCGAGTCGCTG Template
mRNA
5 ́
A
strand
is
3 ́ identical
Transcription
RE
5 ́
is
strand
the for
3
U)
template
strand
complementary
antiparallel
UGGGGCUCAGCGAC
mRNA
and to
Direction ́
the
mRNA
of
transcription Translation
Codons
Protein
NH2
Met
Gly
Leu
Ser
Asp
Direction
COOH
translation
Figure
3
I 3
3.
Figure Flow
I 3 3. Flow of Genetic
of Genetic Information Information
from from
DNA to DNA
Protein to Protein
of
CHAPTER
Review
|
TRANSCRIPTION
AND
RNA
PROCESSING
Questions
Select
the
1.
The
ONE
best
During
RNA
scribed
to
A.
ATCG
B.
GCTA
C.
CGTA
D.
AUCG
E.
GCUA
answer
Also
answer.
synthesis,
is
E.
DNA
which
RNA
is
that, of
of
template
the
and
convention, the
sequence
following
antiparallel
by
regardless
the
the
produce
remember
direction in
3
direction
TAGC
complementary
all
base
in
which
would
be
tran
sequences?
to
sequences the
are
the
template
written
sequence
in
may
strand. the
5′
actually
to
be
3′
used
cell.
Approach:
•
Cross
•
Look
•
What
out at
is
Examine
the
example)
at
usually
option 5′
end
the
complement
options end.
of
direction mRNA
(T
the
(RNA
has
in
this
case).
base?
(A)
this
correct
two
the
T
of
A
or
a
DNA
Repeat
one
Transcription
the
of
given.
3′
only
the
with
the
the
leave
2.
any
option
U).
will
procedure
have
for
the
the
3′
complement
end
of
the
(A DNA.
in
This
this will
options.
following
indicated
sequence
by
the
of
arrow.
the
What
tryptophan
would
be
operon the
base
occurs
sequence
in of
produced? 3′
CGTCAGC
5′
Transcription
→
Which
product?
5′...GCAGTCG...3′
The
5′...GCAGUCG...3′
B.
5′...CGUGAGC...3′
C.
5′...GCUGACG...3′
D.
5′...CGUCAGC...3′
E.
5′...CGUGAGC...3′
answer
tion, the
A.
is
mRNA direction
example
A.
Because
and
the
of is
the
all
nucleic
coding
transcription. coding
acids
strand
of
This
strand.
are
DNA
means
The
top
synthesized
must that
strand
the is
in
each
be
bottom
the
the
5′
to
oriented
5′
strand
template
in
3′ to
direc 3′,
i.e.,
in
this
strand.
Approach:
•
Cross
•
Identify
•
Find ber
•
out
any
option
the the
to
coding
option
strand,
U if
you
will
a
strand with
substitute
Alternatively,
with
a for
T.
of
DNA
sequence T,
you
prefer
get
the
if
identical
the to
direction the
of
coding
transcription. strand
(remem
necessary). to
same
from
find
the
complement
of
the
template
answer.
3
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry PRODUCTION
The
OF
structure
illustrated Medical Genetics
in
and
expression
Figure
I
of
3
4.
MESSENGER
a typical
The
prokaryotic
following
RNA
gene
events
occur
coding
during
for
the
a
protein
are
expression
of
this
gene:
1.
With
the
help
promoter the
the
plate
2.
base
core
ecule.
There
are
prokaryotic
•
Rho
independent
back
on
two
a
The
enzyme
the
promoter on
strands
factor
transcription
GC
rich
the
5′
is
to
of
the
tem
DNA
released
template
3′
as
it
reads
as
soon
as
strand
in
the
3′
to
direction.
transcription and
of
termination
release
the
signal,
completed
terminators
to that
polymerase
from and
the
of of
at
mRNA
commonly
at
has
paused
the
message
mol
found
in
message.
ribosome from
end
of
a the
Shine
and
the
RNA
folds
by
6–8
synthesized
U
RNA
template.
This
is
the
type
of moves site.
rho
factor.
toward
the
Rho
then
This RNA
displaces
RNA
RNA. simultaneously
in
(no
introns),
transcription
is
Dalgarno
sequence
synthesis
begins
continues
coding
terminus
DNA
termination
occur
before
newly
and
mRNA
Protein
the
at of
formed followed
participation RNA
prokaryotic
region
translates amino
end
the
the
newly closely
4.
formed
even the
of
from I 3
can
of
coding the
3′
the loop
requires
newly
translation
called
the
RNA
Figure
the
the
when
hairpin features
the
in
processing
a sequence
(UTR)
structural
termination
binds
no
occurs
of
dependent
is
a
shown
polymerase
protein
the
transcription
form two
terminator
Rho
The
two
Sigma
along
in
termination
dissociation
codon
mRNA
kinds
to
promote
ning
the
the
pair.
reaches
stop
These
translating
6.
will
itself
Transcription
to
base
moving
the
residues.
there
sequence.
orients
to sequences,
genes:
protein
5.
–35
binds
“consensus”
strand.
+1
eventually it
of
the
the
and
template
at
and
separates
continues
polymerase point
box)
and
two
initiated.
polymerase
which
•
the
synthesizing
RNA
TATA
recognizes contains
transcription
polymerase
begins is
direction,
4.
RNA
polymerase
promoter
(or for
of
Transcription
The
box
sequence
RNA
bacterial
site
The
transcription 3.
factor,
The
start
strand.
the
sigma
Pribnow
identifies
Behavioral Science/SocialSciences
of
region.
called
3
PROKARYOTIC
until
at
Because can
complete. in
the
bacteria. ribosomes
an
the AUG
ribosome
Ribosomes 5′
bind
untranslated codon
begin
region at
reaches
the
begin
a stop
region. message to
in carboxyl
the
5′
to
terminus.
3′
direction,
synthesizing
the
5′
CHAPTER
DNA
3
|
TRANSCRIPTION
AND
RNA
PROCESSING
Transcription TATA box –35
5
́
3
́
ATG
TGA Coding
–10
region 3 ́
5 ́ Promoter 5
́ Untranslated region
3
(UTR)
́ Untranslated region
(UTR)
+1 Transcription Transcription
terminates
mRNA Shine
AUG
Dalgarno
UGA Coding
sequence
GC
rich
and
loop
stem
region UUUUUU
5 ́
5
́
UTR
3
́
3 ́
UTR
Translation
H2N
I Figure 3 4.
Figure
The
mRNA That
protein.
The
example, related in
this
I 3 4. Expression Expression
produced
message.
the genes case
is,
by it
word
the
cistron
shown
operon)
grouped
another
ProteinProteinCoding
the
figure
single
above
gene
for
a
and
gene.
the
DNA
from
are
several
Gene Coding
is
for
In
transcribed
as
and
only
bacterial
messages.
genes
Gene
a monocistronic
codes
Some
polycistronic
in
information
a name
produce
together
contains
in
from
is
- COOH
Prokaryotic of of a a Prokaryotic
gene
is transcribed
lactose
- Protein
codes
a
single
operons these
one
unit.
for
(for
cases, The
several
mRNA different
proteins.
Promoter
5
́ UTR
Gene
1
AUG
Gene
UAA
AUG
2
Gene
3
AUG
UGA
́ UTR
UAG
5 ́ UTR
3 ́ Gene
Polycistronic
3
1
Gene
2
Gene
UTR
3
mRNA Shine
Dalgarno
Shine
Each
Dalgarno
gene
H2N–Protein–COOH
Shine
is
translated
Dalgarno
independently
H2N–Protein–COOH
H2N–Protein–COOH
12
Figure Figure
I 3 5. Polycistronic I 3 5. Polycistronic
3
Gene
Gene Region
Region Codes for
Codes Several
for Different
Several Proteins
Different
Proteins
3
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry PRODUCTION
OF
In
eukaryotes,
by
noncoding
most
Introns
nucleus. lated
in
coding as
genes
segments
nucleus.
Medical Genetics
EUKARYOTIC
are
during
eukaryotes,
all
cytoplasm.
The
protein
is
of
Both
removed
In
a
composed
(introns).
are
the for
MESSENGER
coding
exons
segments
and
processing
mRNA
RNA
introns of
and
illustrated
in
are
the
is monocistronic.
structure
RNA
The
I
3
of
6.
interrupted
transcribed
in
molecule
mature
transcription
Figure
(exons)
in
mRNA
a typical
the
the is trans
eukaryotic
Transcription
of
this
gene
gene
occurs
follows:
Behavioral Science/SocialSciences 1.
2.
With
the
of
and
eukaryotic
genes
(also
called
RNA
polymerase
initiate in
3.
help
recognizes
proteins to
3′
Hogness
to
sized
in
the
RNA
polymerase
These
signals
3′ II
are
the
RNA
not
ends
of
DNA
the
in
it
a short
primary
reaches
is
read
synthe
transcribed. a termination
signal.
eukaryotes.
Poly
Exon
is
transcript) are
to
strand
A
addition
signal
TAG
1
Exon
–25
box
region
template
introns
ATG
–70
of
TATA
DNA
Promoter
II region
the
over The
and when
understood
DNA
(the
exons
transcription
well
called
sequence.
product
Both
polymerase
promoter
box.
strands
the
RNA basal
sequences
CAAT
read
direction.
The
consensus
the
as
factors,
region.
the
separates
direction to
two
and
and
5′
transcription
promoter
has
box) II
5′
the
usually
transcription
the
called
binds
2
Intron
5 ́
3 ́
3 ́
5 ́ CAAT
TATA
box
box
5
́
Untranslated
region
3
(UTR)
́
Untranslated
region
(UTR)
+1
Transcription terminates
Transcription Poly AUG
UAG
Exon
1
A
addition
signal
Exon
2
Intron Pre
5
mRNA
́
3
5
́
UTR
3
FigureI 3 I 6.3
Figure
6.A AEukaryotic Eukaryotic
Transcription Transcription
́ UTR
́
HY
MY
Unit
Unit LY
Processing Pre The
of
Eukaryotic
Messenger primary
transcript
processing
inside
the
processing
steps
include
1.
A
7
High
RNA must
being
also
helps
protect
is
The the
form
extensive the
co
mature
and
post
mRNA
transcriptional MEDIUM
molecule.
LOW
added cap
mRNA
YIELD
to
the
structure chain
5′
end
serves from
while as
a
the ribosome
RNA
YIELD
molecule
FUNDAMENTALS binding
is site
and
FUN
degradation. REINFORCEMENT
38
ME
These
following:
cap
synthesized. to
to
the
methylguanosine
still
undergo
nucleus
H
Yield
R
CHAPTER
2.
A the
poly
tail
on
poly
A
poly
A
transport no
is attached
molecule
then The
A
poly
the
3′
side
polymerase tail
to A
to
3′
of adds
protects
the
the
the
end.
the
sequence
the
poly
message
cytoplasm.
A
few
In
this
A
tail
process,
an
AAUAAA
rapid
mRNAs
(poly
(about
against (for
endonuclease
200
As)
A
degradation example,
histone
|
TRANSCRIPTION
AND
RNA
PROCESSING
cuts
addition
to
3
signal),
the
new
3′
and
aids
in
end.
mRNAs)
its have
tails.
Poly AUG
Exon
A addition signal
UAG
1
Exon
2
Intron Pre
5
mRNA
́
3
5 ́ UTR
3
Capping
and
addition
AUG
Exon
Poly
(nucleus)
́
UTR
Poly
A
A addition signal
UAG
Exon
1
́
2
Cap Intron Me
hnRNA 5
́
AAAAAAAA Gppp
Poly 5 ́
UTR
5 ́ Splice
Splicing
by
3 ́
Splice
donor
acceptor
site
site
spliceosome
(snRNA)
A
tail
A
tail
3
́
3
́
3 ́ UTR
(nucleus)
3 ́ Excised (lariat)
Poly
intron
A addition
degraded in
signal
nucleus AUG
Exon
1
UAG
Exon
2
Cap Me mRNA
5
AAAAAAAA ́ Gppp
Poly
5 ́
UTR
3 Transport
to and
́ UTR
cytoplasm
translation
H2N–Protein–COOH
Figure
I
3
7.
Figure Processing
I 3 7. Eukaryotic Processing
Eukaryotic Pre
Pre mRNA mRNA
3
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry 3.
NOTE
Introns
are
(also Mutations
in
abnormal that Medical Genetics β
splice
proteins.
interfere globin
cases
of
β
For
with
mRNA
sites
are
proper
can
lead
example,
as
from
an
hnRNA
snRNP,
or
by
splicing,
snurp),
accomplished
which
are
by
complexes
of
spliceosomes
snRNA
and
to mutations
splicing
responsible
removed
known
of for
thalassemia.
protein.
The
ceptor)
ends
and some
of
All
is
intron.
The
Neighboring
of of
molecule
the
degraded.
region 4.
hnRNA
the
the
mature
cut
at
intron
splice
sites
exons
is excised are
at in
joined
the
5′
the
(donor)
form
together
to
of
and a
3′
lariat
assemble
(ac
structure
the
coding
mRNA.
intermediates
in
this
processing
pathway
are
collectively
known
as
hnRNA. Behavioral Science/SocialSciences
5.
The
mature
lated
to
mRNA form
molecule
ALTERNATIVE
PRE
SPLICING
mRNA
For
some
more
genes,
the of
splicing. in
this
unstimulated
primary
may
the
be
in
By
alternative
than
it
is
at
technique
discussed
because
genes
in
Chapter
they
should may
not change
be
memorized upon
́
A
T
by by
undergo
primary
giving
rise
alternative transcript
to
can
make
many of of
detected
Exon
a gene
specific
estimate be
of
tissue
estimate
current can
are
by
more the
number
human
of
genes
Northern
is
blot,
a
7.
pre
RNA
Exon
1
1
Intron Exon
2
transcript
1
Exon mRNA
Figure
2
Exon
2
Intron Exon
Splicing
Exon
variation
5
3 ́
́
Exon
1
Exon mRNA
Alternative
4
3
́
#2
#1
I 3 8.
3
3
Splicing #1
4
to
4
genes
current
the
splicing
variation
5 ́
or
UAA Intron
5
two alterna
troponin
AUG
more
research.
is trans
splicing.
the
organism
encode.
whereas
Primary
figures
of
an
to
as
immunoglobulins
or
tissues,
Alternative
NOTE
These
it
immunoglobulins
alternative
cell,
different
100,000,
20,000–25,000.
same
known
and
secreted
involves
splicing,
has
least
to
produce
is
bound
percentage
the
to
process
tropomyosin
opposed
a large
This
membrane
also
within
spliced
proteins only
of
as
occur
proteins
human
where
differently
gene.
proteins
synthesis
from
may
products.
different
same
B lymphocytes,
alternatively
protein
cytoplasm,
PRIMARY
is spliced
the
muscle
The
transcripts This
about
from
of
way.
stimulated
splicing.
the
EUKARYOTIC
transcript
protein
B lymphocytes,
antigen
The
OF
primary
a
Variants
produced
to
TRANSCRIPTS
variants
tive
is transported
a protein.
Splicing Produce
of Different
Eukaryotic Proteins
hnRNA
(Pre
mRNA)
3 #2
Exon
4
3
́
CHAPTER
RIBOSOMAL
RNA
CONSTRUCT
RIBOSOMES
Eukaryotic
ribosomal
a single
piece
rRNA,
and
separate
rRNA.
RNA
is
in
protein
Prokaryotic
nucleolus
by
cleaved
to
transcribes
assemble
proteins.
during
the
III
subunits
|
TRANSCRIPTION
in
to
RNA 28S
5S
the
the
from
subunits
whole
80S
Eukaryotic
a
rRNA are
60S
ribosome.
Ribosome
BRIDGE
80S
50S
Shiga 5S
RNA
TO
toxin
and 5.8S
(Shigella
Verotoxin,
a
RNA
28S
rRNA
in
16S
40S
RNA
18S
RNA
subunit
are
single
adenine prevents
ribosome,
I 3
The
large
The
complete
and
The I 3 Composition 9. The Composition
small
by
both
prokaryotic
size
and
TRANSFER
ribosome
behavior
of
shape,
TRANSLATION
There
are
activated these
tRNAs
enter
the
many
different acid in
eukaryotic
Although
all
tRNAs
structural
features
the
distinguish
tRNAs.
making cells
are
they
combine
the
same among
(Note:
are
and The
tRNA
transcribed
shape
their
only The
the
the
RNA
The
A subunits
glycosylases residue aminoacyl
halting
protein
that from tRNA
of
these
remove
the
28S binding
a rRNA. to
the
synthesis.
a
function
in
ACIDS
one
type
genes
polymerase
appropriate shown
of
are
are
AMINO
carries
RNA
inactivate
additive.)
translation. by
with
coli), subunit
respectively.
S values
They not
60S
toxin
RibosomesFigure
30S,
ACTIVATED
during
general
50S
ultracentrifuge.
numbers
Each
proteins
are
particle. an
CARRIES
where have
a 70S in
therefore
and andEukaryotic Eukaryotic Ribosomes
subunits
is
specific for
ofProkaryotic Prokaryotic
particles
(tRNA)
amino
cytoplasm
the
and
RNA
FOR
of
ribosomal
prokaryotic
determined of
9.
E. the
ribosome.
toxins
This
Figure
like
RNA eukaryotic
30S
dysenteriae) Shiga
(enterohemorrhagic 28S
subunit
MICROBIOLOGY
RNA
60S subunit
23S
PROCESSING
18S
unit
as
70S
5S
RNA
I as
rRNA,
rRNA
nucleolus ribosomal
form
polymerase
yield
the the
Eukaryotic
synthesis
Ribosome
subunit
AND
TO
subsequently
polymerase
ribosomal
join
USED
transcribed
which
ribosomal
with
They
IS
is
RNA,
The
combine 40S.
RNA 45S
5.8S gene.
pieces and
of
(rRNA)
3
III. amino
Figure
I
of
encoding The
tRNAs
acids. 3
10,
small
them.
4
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry 3
́ end
A
OH
Activated acid
C
to Medical Genetics
amino is
3
attached
́ OH.
C 5
́ end
A
C
A
G
C
C
G
G
C
G
C
G
C
G
C
P
Behavioral Science/SocialSciences
A C
G
G
C
A
U
C
U C
A
G A
C
C
G
G
A
G G
U
U
C
G
G T
C G
G
A G
C
U
C
C
ψ
U
D
G G A
U C
G
G
C
G
C
G
C
A
G
A
Cm U
A
C
U Anticodon
A
sequence
pairs
Figure Figure
RNA
Editing
RNA
editing
is
nucleotide RNA
base RNA
tRNA
molecules
important
4
In codon,
the thus
RNA
some
RNA
cells
discrete its
events
(such
as
has
been
editing
mRNA.
(tRNA)
make after
editing
in
(tRNA)
RNA
molecule
(CAU)
codon
may
adenine
changes
gene
has
to
been
include
insertion,
deamination)
observed
in
specific
transcribed
within
some
mRNA,
by deletion,
the rRNA,
and
humans.
example is
Transfer
Transfer
nucleotides RNA
in
B100
intestines.
of
molecule.
Apoprotein
which a
10.
10.
Posttranscription
alterations
edited
a stop
by within
polymerase.
and
An
a process
sequences
I 3
I 3
with
is
cytosine
expressed
intestines, producing
to in
the
the
uracil liver,
mRNA the
shorter
deamination and
is
in
apoprotein
edited apoprotein
from
the
B48 a CAA B48
form.
apoprotein is
B gene.
expressed
sequence
in to
be
the UAA,
CHAPTER
Recall
Question
Which
eukaryotic
A.
mRNA
B.
rRNA
C.
tRNA
RNA
contains
I 3
2.
Important
Points
About
regions
Transcription
and
May
be
RNA
Core
of
transcription
continuous
little
coding
spacer
between
Initiation
regions
(noncoding)
DNA
genes
enzyme:
α2ββ′
Promoter
(–10)
TATAAT
initiation
recognize
Template
of
Relationship transcript
transcription
of to
RNA
DNA
and
Posttranscriptional processing (pre
subunit
(–35)
to
have
Large
spacer
and
introns
(noncoding)
DNA
RNA
polymerase
I:
RNA
polymerase
II:
mRNA;
RNA
polymerase
III:
tRNA,
(–25)
between
rRNA
TATA
snRNA 5S
and
factors
read strand
3′
to
5′
5′;
to
mRNA
3′;
and
loop
+
UUUUU
Stem
and
loop
+
rho
is
antiparallel
(except
U
5′ begins
to
at
Not
RNA
(–70)
(TFIID)
CAAT bind
3′;
+1
gene
sequence
specified
from
base
well
characterized
factor
and
substitutes
synthesized
transcription
complementary for
T)
to
to DNA
DNA
coding
hnRNA
template
strand;
RNA
is
identical
strand
In
nucleus:
5′
cap
(7
3′
tail
(poly
MeG)
mRNA)
Removal •
Ribosomes
70S
(30S
rRNA
and
Cloverleaf
and
50S)
protein
rRNA
secondary
•
Acceptor
•
Anticodon
80S
A of
sequence)
introns
from
Alternative of
tRNA
exons
promoter
None of
Genes
Promoter
required
Stem
RNA
monocistronic
promoter
coding
Termination
Always
Transcription
Sigma
synthesis
PROCESSING
genes
sequence
mRNA
RNA
Processing
polycistronic are
Very
polymerase
AND
Eukaryotic
Genes
RNA
TRANSCRIPTION
A
Prokaryotic
Gene
|
UTR?
Answer:
Table
3
splicing
protein
(40S and
pre yields
RNA variants
product
and
60S)
protein
structure
arm arm;
(CCA)
carries
anticodon
amino complementary
acid and
antiparallel
to
codon
in
mRNA
4
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry Review
Medical Genetics
Questions
Select
the
ONE
1.
The
base
Behavioral Science/SocialSciences
2.
answer.
sequence
of
CAGCGC.
The
tain
sequence?
which
A.
GCGCTG
B.
CUGCGC
C.
GCGCUG
D.
CAGCGC
E.
GUCGCG
A
gene
1,000 of
Items
best
200
bp.
start
AUG
A.
1,750
B.
750
C.
650
D.
450
E.
150
3–5:
mRNA
encodes bps,
Identify
a In
codons
the
final
the
150 region
processed
to
the
the
cytochrome
β5
transcription
amino
acids.
of
bp,
100
mRNA,
final
nuclear
in
upon
with
untranslated
codon
58
produced
a protein 5′
57
There and
how
termination
of
many
this
is
a 3′
reductase gene
one
intron
nucleotides
lie
location.
A C
4
Transcription
4.
Euchromatin
5.
Polyadenylation
of
genes
by
of
mRNA
pre
RNA
polymerase
by
poly
1
A
polymerase
is
con
of region
ED
3.
will
untranslated
codon?
B
gene
from
the
CHAPTER
3
|
TRANSCRIPTION
AND
RNA
PROCESSING
Answers
1.
Answer: the
D.
Since
mRNA
means
no
U
in
2.
Answer:
D.
Only
3.
Answer:
B.
rRNA
4.
Answer:
A.
Less
areas
5.
Answer: Generally
are
the
sequence
sequence
must
the
in be
the
stem
identical
represents
(except
U
the for
T).
coding No
strand,
T
in
the
3
×
150
DNA
mRNA.
the
coding
genes
condensed
region
are
remains
to
transcribed
by
chromatin,
lighter
this
be
calculated:
enzyme
areas
in
in
the
the
=
450.
nucleolus.
nucleus.
Darker
heterochromatin.
A.
Polyadenylation associated
of with
active
pre gene
mRNA expression
occurs
in in
the
nucleoplasm.
euchromatin.
4
The
Genetic
Code,
Mutations, 4#
and
LEARNING
Translation
OBJECTIVES
❏
Demonstrate
❏
Solve
❏
Interpret by
understanding
problems
of
concerning
scenarios
the
genetic
code
mutations
about
amino
acid
activation
and
codon
translation
tRNAs
❏
Demonstrate
❏
Explain
❏
Interpret
❏
Answer
understanding
of
information
related
scenarios
to
about
questions
translation
inhibitors
protein
about
how
(protein
of
folding
translation
synthesis)
protein
and
synthesis
subunit
occurs
on
assembly
the
rough
endoplasmic
reticulum
❏
Demonstrate
understanding
of
co
and
posttranslational
covalent
modifications
❏
Solve
problems
concerning
posttranslational
modifications
of
collagen
TRANSLATION The
second
stage
messenger
RNA
genetic in
code
DNA
Each
(or
is
is
into as
the
the
translating
amino
acid
relationship
transcripts) by
the
one
or
of the
sequence more
nucleotide
sequence
between
and
specified
the
sequence a protein.
sequence
of
amino
nucleotide
a
The of
acids
triplets
of
nucleotides in
a protein.
(codons)
in
DNA.
translation, for
mRNA.
tRNAs
the
mRNA
each
amino
before
amino serve
acids peptide
protein
interactions
they
RNA
acid
codons
for
expression
defined
its
During
of
gene
molecule
is
amino
the
in
protein prepare
they bond
and
rRNA between
synthesis. to
assume
acts
acid as
as
in
the
adapter
each
specify,
thus
Many their
copy
as tRNA,
been
that
couple
aligning
proteins ultimate
molecular the
gene
place
the
and posttranslational
in
the
in
which
the
from
DNA
codons
in
the on
machines
enzymes,
undergo roles
the
transcribed
them takes
the
of
have
Translation
serve
mRNA,
working
protein
molecules
formation. that
a
in
appropriate
protein
with sequence
ribosomes,
complexes
coordinating the
to
mRNA
the factors
modifications
required as
cell.
4
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry THE
GENETIC
Most es.
CODE
genetic
code
Important
Medical Genetics
•
of
codon
written 61
designate
features
Each
•
tables
consists
in
the
codons (or
genetic
of
5′
to
code
codons
the
3′
for
the
3
code
bases
for
amino
acids
as
mRNA
sequenc
include:
(triplet).
There
are
64
codons.
They
are
all
direction.
amino
nonsense
codons
acids.
codons)
The that
other
3
terminate
(UAA,
UGA,
UAG)
are
stop
translation.
Behavioral Science/SocialSciences •
There
is
Protein
one
start
codon
synthesis
formylmethionine •
The
(initiation
begins
with
(fMet)
code
is
unambiguous.
is
degenerate.
codon),
AUG,
methionine
in
coding
(Met)
in
for
methionine.
eukaryotes,
and
prokaryotes. Each
codon
specifies
no
more
than
one
amino
acid. •
The
•
code
acid.
All
one
codon.
For
those
codon •
The to
•
this code
between
in is
more
same.
The
(the
same
codon
and
than base
in
can
specify
tryptophan
all
one
in
codon,
the
a
(Trp),
third
the
first
position
organisms).
Some
commaless on codons
(contiguous). an
2
minor
than
bases
in
varies. exceptions
There
are
no
spacers
or
“commas”
mRNA. on
a
First
message
Second
are
nonoverlapping.
Third
Position
Position U
́ End)
UUU U
}
UUC UUA UUG
}
C
UCU
Phe
UCC
}
CUA
UCA Leu
A
Leu
}
Pro
CCA
ACC
Thr
Met
GUU }
Val
Trp
G
AAA
GAC
GCG
GAA
U
CGU
His
CGC
}
CGA }
}
Gln
}
}
AGU
Asn
AGA Lys
AGG
Asp
GAG
I 4 1. The Genetic Figure I 4 1. The Genetic
Code Code
GGG
A
U
}
Ser
}
Arg
C A G
U
GGU GGA
Glu
C
G
AGC
GGC }
Arg
CGG
AAC
GAU Ala
}
Stop
CAA
GCC
}
}
CAC
GCU
GUG
Figure
A
UGG
AAG
GCA
C
Stop
ACG
GUA
Cys
UGA
AAU }
U }
UAA
CAG
ACU lle
UGU
Tyr
(3
UGC
CAU }
ACA
AUG
G
CCC
}
G
UAC UAG
CCG
AUA
GUC
Ser
UCG
CUG
AUC
UAU }
CCU
CUC
AUU
A
C
CUU
48
amino
more
often
Position (5
single
have
mitochondria.
codons
Neighboring
one
Met
having
the
universal
occur
than
except
acids
usually is
More
acids,
amino are
code
The
•
amino
}
C Gly
A
́
End)
the
CHAPTER
4
|
THE
GENETIC
CODE,
MUTATIONS,
AND
TRANSLATION
MUTATIONS
A
mutation
is any
organism.
This
sequence
of
altered
Mutations
enzyme
activity,
antigenicity,
A
•
of
with
a different
base
pair
becomes
becomes
a T are
gene’s
often
protein
the
A
code
table
can
also
in acid
of
the
an
base
sequence
cause
of
changes
a
in
morphology,
alteration
a
base
or
point
purine
pair.
mutation.
pyrimidine For
base
example,
an
A
T
replaces
pair.
For
the
effect
a
purine
pyrimidine
example,
an
A
T
base
base
pair
pair. to
change
in
amino
replaces
that
according This
changes
the
susceptibility,
base
base
base
classified product.
genetic
G
sequence
pair.
mutation
a C
by
in
pyrimidine
purine
or
base
cells.
that
base
a point
a pyrimidine
reflected
a single
mutation
C
DNA
antibiotic
is
G
the
They
of
purine
is
with
Mutations
mutation
a
transversion
be
diseases.
properties
a point
pair
pair
using
other
in
changes
requirements,
many
is
can by
genetic
nutritional
transition
A
sequence
cause
type
change
sometimes,
can
common
•
the
and,
and
very
heritable
DNA
mRNA,
protein.
A
permanent,
in
they
protein
conjunction
have
structure
with
the
on
can
base
the be
structure
of
predicted
sequence
of
DNA
A
T
or
mRNA.
Normal
A
T
G
G
Met
Silent
A
C
A
A
T
Ala
T
G
G
C
T
CGT
Ile
A
A
T
T
Arg
T
T
T
T
Phe
CGT
T
T
A
CCT
Leu
T
T
T
Pro
TG
A
G
Ile
CCT
A
G
G
Gly
T
A
G
G
DNA
Amino
G
coding
strand
coding
strand
coding
strand
coding
strand
Acid
DNA
Mutation Met
Missense
A
Ala
T
G
G
C
Ile
A
A
T
Arg
Phe
TCGT
T
Leu
T
T
TC
Pro
A
Ile
CCT
A
Gly
T
A
G
G
Amino
G
Acid
DNA
Mutation Met
Nonsense
Ala
ATG
G
C
Ile
A
A
T
Arg
T
CG
Phe
T
T
Ser
T
T
T
Pro
G
A
Ile
CCT
A
Gly
T
A
G
G
Amino
G
Acid
DNA
Mutation Met
Ala
Ile
Arg
Phe
Stop
Amino
Acid
Frameshift A
Mutation (1bp
deletion)
T
G
G
Met
C
A
AT
Ala
T
CGT
Ile
Arg
Figure
I 4 Figure
Large Large
Segment
somes
in is
of
DNA
meiosis. part
cells event,
can
be
Crossover
a normal
reproductive crossover
T
T
T
Phe
2.
A
C
CT
Tyr
Some
I 4 2. Some
A
A
G
Leu
Stop
Types
of Mutations
Common Common
T
G
G
coding
DNA Amino
Types
of
Mutations
in
strand
Acid
DNA
in DNA
Deletions
segments
crossover
T
(egg the
of
or
meiosis
and homologous
deleted
sperm),
from
a chromosome
recombination I that a maternal
during
between
generates largely
genetic beneficial
and
paternal
an
homologous diversity result.
In
chromosomes
unequal chromo
in a normal exchange
4
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry equivalent
segments,
maternal
and
one.
On
loses
rare
some
and
although
paternal
alleles,
occasions,
a
of
its
the no
crossover
genetic
resultant
genetic
chromosomes
information
can
be
has
unequal
been
and
one
of
are
mosaics
lost
from
the
of either
two
homologs
information.
Medical Genetics
HY α
thalassemia
is
crossover chat
has
a
like
known
deleted
(intellectual
kitten
well one
example
or
more
disability, cry)
of
α
a
globin
from
from
wide
a terminal
disease
genes
microcephaly,
results
genetic
set
deletion
in
unequal
chromosome
eyes,
of
which
and
the
16.
Cri MY du
a characteristic
short
arm
of
LY
chromosome
5.
Behavioral Science/SocialSciences
Mutations
in
Mutations
in
Splice
splice
sites
posttranscriptional somes
High
Sites affect
the
processing.
If
accuracy
of
a splice
intron
site
is
MEDIUM from hnRNA YIELD during
removal
lost
through
mutation,
Delete
LOW
•
Leave
•
Use
nucleotides
from
the
adjacent
YIELD
exon FUNDAMENTALS
nucleotides the
from
next
the
Mutations
in
including
of normal
intron
upstream
processed splice
β
the
sites
have
now
is a β
are
two
globin
that
of
and
frameshift
(more
A
9
his
an
month
severely
due
to
are
the
against
red
marrow bones
5
the
face skull.
from
common
treatment
a serious
consequence.
and is
A
is
there
large
number
deletions,
mutations
β
globin
mRNA
not
encoding
information
site
mutations
at
intron
of
involving
involve
splice
was
the
1 create
a new
splice
to
hospital
by
brought
listless,
and was
unusual
in and red
due
to
of
with
the
the
in role
face weak every
that
large
areas. 6
The
abnormally transfusions
features
cells
irritable. and
Mediterranean
blood
the
frequently enlarged
glucose
bloodstream.
are
diseases,
thalassemia,
defects
gene as
spleen
deformities
blood
globin
β
globin. gene
mutations
within
had
is
legs
α
Other
such
primarily
the
different
In
with
translational
β
the
anemia of
many
hemoglobin.
including
descent
that
the
cell
bone arms
exon
Sachs.
and
pale,
Splenomegaly
produces of
REINFORCEMENT deleting an
site,
site,
mRNA.
Greek
abnormality
cells
the
became
found
sickle
malaria.
damaged
of
out),
His
Tay
compared
mutations
noted
in
to
deficiency,
of
of he
anemic.
similar
splice
THALASSEMIA
chain
long
infant
deformities
thalassemias
FUN
mRNA
in
and
described,
spliced
Also,
physician
was
that,
be
because
attending
been
abnormally
old
parents
beta
70%
must
in
processed
documented
mutations.
sequences.
resulting
downstream
process,
than
eventually
or
disease,
protein
have
transcriptional
consensus
the
globin
the
processing and
for β
mutations
slow
nonsense
β
genes
deficiency
the
been
Gaucher
β
There
in
mRNA
thalassemia,
ME
spliceo
may:
•
H
Yield
It
phosphate β
the
believed
may
spleen
in
activity other
and 2–3
is
dehydrogenase
excessive and
infant
cheekbones
thalassemia
of
The the
areas.
fracture weeks,
clearing of The
easily. but
protect
iron
the
bone long The
overload
most is
RE
MY
4 LY|
CHAPTER
Trinucleotide The
Repeat
mutant
alleles
syndrome, the
and
number
repeats
in
certain
diseases,
myotonic
of
increases
and
decreasing
such
dystrophy,
tandem
often
High
Expansion
copies
of
with
as
differ a
their
trinucleotide.
successive
In
normal these
generations
and
YIELD X only
the
LOW YIELD number
correlates
with
GENETIC
HIGH
of
disorder,
has
decade
4.
example, the
in
the
coding
age
normal
region.
repeats.
The
proteins
normal
The
a
the
long
contains disease
A
clinical
disorders
is neurodegeneration
5
makes
have
the
30–60
of
or
the
adjacent
proteins
expansion
region
or
of in
an
the
trinucleotide
untranslated
region
of
in the
the
followed
allele
can
I 4
1.
Two
Translation
Classes
repeat
(polyglutamine
of
Trinucleotide
be
in
a
by
of
(CAG)n
muscular
Fragile
atrophy:
repeat
until
death
impaired the
gait,
dystonia,
memory,
first
signs,
chorea
(loss
dementia,
of
and
onset
most
(age
frequently
1
acid)
codon);
missense,
1
segment
Met)
or
2
often
differ
at
base
3
nonsense
nucleotides;
not
multiple
of
3)
deletion
Mutation
in
splice
site
Trinucleotide
repeat
expansion
Amino
acid
Aminoacyl
tRNA
synthetase:
two
high
energy
bonds
(ATP)
to
link
amino
acid
to
cap
on
tRNA
activation
Translation:
30S
Initiation
sequence
subunit
binds on
fMet–tRNAi
GTP
Translation:
Charged
Elongation
A
to
Shine
Dalgarno
40S
binds
to
P
site
Peptide bonds
associates
Met–tRNAi
required
site
subunit
with
5′
mRNA
mRNA
GTP
aminoacyl–tRNA
binds
to
binds
to
P
site
required
Charged
aminoacyl–tRNA
binds
to
A
site
(GTP)
(GTP)
bond from
forms amino
(two acid
high
energy
activation)
28S
rRNA
is
removing
cut
an
by
Shiga
adenine
and
Shiga
residue.
like
toxins
Prevents
protein
synthesis.
Peptide
bond
amino
Peptidyl
transferase
Translocation:
(50S
GTP
subunit)
required
acid
Peptidyl
forms
transferase
Translocation:
eEF
(two
2
high
energy
bonds
from
activation)
(60S
GTP
required
by
Diphtheria
inhibited
subunit)
and
Pseudomonas
toxins
Termination
Protein
Release
targeting
of
protein;
protein
synthesized
N
to
C
Secreted
or
membrane
hydrophobic Lysosomal
Other disease
important
Scurvy Menkes
by
N
terminal
sequence
enzymes:
mannose I cell
proteins:
signal
phosphorylation
of
phosphotransferase
in
Golgi
disease
(prolyl Disease
hydroxylase, (Cu
Vit deficiency,
C) lysyl
oxidase)
associations
6
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry Review
Questions
Select
Medical Genetics
the
1.
In
Behavioral Science/SocialSciences
in most
the
best
amino
acid
is
A.
AAC
B.
UAG
C.
UCC
D.
AUG
E.
UAU
2
code acid
and
human
ATGCAA.
. .→
ATGTAA
B.
ATGAAA.
. .→
GTGAAA
C.
TATAAG.
D.
CTTAAG.
. .→
GTTAAG
E.
ATGAAT.
. .→
ATGCAT
options
. .→
above
boldface
nuclear
is
A.
UAC.
DNA,
one
Another
closely
For
mutations
each
related
mutation
3.
Mutation
decreasing
4.
Accumulation
affected
by
this
in
in
of
same
amino
2.
can
Which
of
the
globin steps
mRNA
B.
Attachment
of
the
to
the
endoplasmic
C.
Met
D.
Translocation
E.
Attachment
tRNAmet
of of
to
mRNA
RNA
swab
paroxysmal
coughing was
ribosome
binding
nasopharyngeal
most
A.
erythromycin
B.
tetracycline
C.
chloramphenicol
D.
rifamycin
E.
levofloxacin
on
obtained
P
the
synthesis
by
is most
directly
the
with
rhinitis
to of
ribosome
with
II
to
hospital 70S
the
a 4
positive the
the
reticulum
site
from
tested
admitted
treated
the
polymerase
translocation likely
choose
mechanism?
pre
He
indicated
below,
regulate
to
the
changes
following
spliceosomes
pertussis.
base
transcription
of
was
specifying this
above.
Attachment
inhibits
codons
questions
options
reticulocytes
eIF
with the
A.
and
the
specifying
DNA in
the
initiation
heme
inactivating
the
described
change
the
of
in
mutation
sequence
Nonsense
A
of
codon
TCTAAG
represent
type.
2.
5.
of
tyrosine
3
indirectly
6
answer.
genetic
the
Items
The
ONE
ribosomes
promoter
month
upon for
old culture
therapy on
infant for with
the
mRNA.
Bordetella an
antibiotic This
that patient
CHAPTER
6.
A
25
month
old
hyperplasia symptoms
of
show
lowing
Golgi
B.
Lysosomal
C.
Endoplasmic
D.
Cytoplasmic
E.
Lysosomal
α
is
B.
First
C.
Middle
D.
Last
E.
3′
9.
from
recessive of
a 12 of
base
Factor
of
immunoreactive V
serum,
and of
the
fol
observations?
peptidase
the
bleeding Factor
pair
deletion
by
hepatocytes
V
Factor
gene
would
this
V
disorder
V
blood
in
the
Factor
and
results
antigen
in
mutation
characterized
coagulation V
gene
that
an
abnormal
in
the
most
by protein.
cytoplasm.
likely
be
In
which
located?
region
region
most in
abundant
many
tissues,
B.
proline
C.
hydroxyproline
D.
cysteine
E.
lysine
month
infant
is
level
prominent. to
these
A.
Lysyl
B.
Prolyl
C.
γ Glutamyl
D.
Phosphotransferase
E.
α
1,4
If
could
is
hematoma.
copper
protein
tissues.
one
old
subdural
relates
and
her
A
autosomal
Untranslated
glycine
delay
progressive
Which
these
TRANSLATION
phosphorylase
Factor
the
serum
with
AND
exon
several
6
consistent
MUTATIONS,
intron
amounts
and
cytoplasm.
CODE,
exon
A.
A
an
Untranslated
Collagen,
of
1,4
secretion
the
the
signal
concentration
arises the
5′
in
in
GENETIC
gingival
hepatomegaly, elevated
THE
glucosidase
hexosaminidase
accumulation
ing
1,4
plasma
A.
are
reticulum–associated
Parahemophilia
of
inclusions most
and multiple,
contractures,
enzymes
is
features
developing
joint
lysosomal dense
facial
began
|
phosphotransferase
α
Deficiency
coarse
age,
disability, of
associated
a reduced
has of
deficiencies
A.
impairs
girl
months
phase
enzyme
region
2
Levels
fibroblasts
8.
at
intellectual
cardiomegaly.
7.
Caucasian
and,
4
seen The
is
5.5
nM
A
deficiency
in
one
the
measure
their
in
emergency
the
child’s (normal of
human
wished
hair for which
to
body,
compare
content
thin,
age, enzyme
present
in
collagen
vary
content
of
room is
is the
with
colorless, 11–12
nM). activity
a
fractured
and
tangled.
rib His
Developmental most
closely
symptoms?
oxidase hydroxylase carboxylase in
Golgi
glucosidase
6
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry 10.
Respiratory ed
tract
with
the
toxin
infections
secretion
most
caused
of
likely
have
of
by
exotoxin
on
A
eukaryotic
nitric
Pseudomonas
by
this
aeruginosa
organism.
are
What
effect
associat will
this
cells?
A.
Stimulation
oxide
(NO)
B.
ADP
ribosylation
of
a
C.
ADP
ribosylation
of
eEF
2
D.
ADP
ribosylation
of
a
protein
E.
Stimulation
synthesis
Medical Genetics
Behavioral Science/SocialSciences
11.
A
4
year
upper oral
of
old
tide
CF
Prior as
a
sequences
alleles
Codon
Normal
Mutant
are
with
and
therapy.
causing
release
cystic
infection
ciprofloxacin
gene
3 of
compared
Number
Gene
Gene
fibrosis
with is
to
testing pair
codons
a of
deletion 506–511
is
seen
by
his
physician
aeruginosa.
CF the in
in
center
as
patient
identified
exon
this
10
of
region
of
He
a potential
the the
for started
gene.
normal
The
506
507
508
509
510
511
ATC
ATC
TTT
GGT
GTT
TCC
ATC
AT•
••T
GGT
GTT
TCC
3
base
for
mutation
and
an on
candidate the
CF
is
below.
deletion
6
(CF)
Pseudomonas
referred
genetic base
protein
Gi
histamine
toddler
respiratory
Gs
nucleo mutant
CHAPTER
What
effect
protein
will
this
encoded
patient’s
by
the
mutation
CF
U
C
} Leu
}
GUU GUC GUA GUG
G
Deletion
UCU UCC UCA UCG
Phe
Leu
AUU } AUC AUA AUG
A
A.
}
CUU CUC CUA CUG
C
lle Met
}
of
on
Val
a
the
amino
acid
|
sequence
of
THE
GENETIC
CODE,
MUTATIONS,
AND
TRANSLATION
the
gene?
U
UUU UUC UUA UUG
have
4
}
A
Ser
CCU CCC } CCA CCG
Pro
ACU ACC ACA ACG
}
Thr
GCU GCC GCA GCG
}
Ala
phenylalanine
G
UAU } Tyr UAC UAA } Stop UAG
UGU UGC UGA UGG
CAU } CAC CAA CAG }
Gln
CGU CGC CGA CGG
AAU } Asn AAC AAA } Lys AAG
AGU AGC AGA AGG
GAU } GAC GAA } GAG
GGU GGC GGA GGG
His
Asp Glu
residue
with
U
} Cys
C
Stop Trp
A G
U }
C
Arg
A G
} Ser
U
} Arg
A
C G
U }
C
Gly
A G
no
change
in
C
terminal
sequence B.
Deletion
C.
Deletion
of
a leucine
residue
of
a
phenylalanine
of
a
leucine
causing
a change
in
causing
a
residue
the
C
terminal
change
in
sequence the
C
terminal
sequence D.
12.
A
Deletion
10
year
tance
old
to
boy
infection,
genetic
deficiency
a single
base
well
as
deletion
type
of
gene
A.
Frameshift
B.
In
C.
Missense
D.
Nonsense
E.
Splice
residue
with
severe
and
impaired
of
the
of
a
at 45
base was
no
progressive
change
skin
cognitive
enzyme
substitution
mutation
with
exon most
3’
end (exon
likely
C
intron 7)
inherited
in
sequence
decreased
has
been
Mutation of
terminal
ulceration,
ability
prolidase.
the
in
analysis 6
the
of
the
this
has
mutant
prolidase by
resis
diagnosed
cDNA.
with
a
identified allele
as
Which
boy?
mutation
frame
mutation mutation mutation site
mutation
6
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry Answers
1.
Answer:
E.
position) acceptable,
Medical Genetics
2.
3.
A. in
C.
is
is
a
stop
the
third
nucleotide
amino
acid.
position
Option
B
(wobble
would
be
codon.
contains
transcription
the
TAA,
eIF
A.
promoter
distractor
2
B.
designates
of
The
a The
placement
Answer:
at same
now
translation.
phase
5.
it
sequence
The
C.
eukaryotic
differ the
which
will
be
transcribed
to
mRNA.
choose
Answer:
UAU specify
that
The
the
Answer: Don’t
4.
and
often except
Answer: UAA
Behavioral Science/SocialSciences
UAC
and
TATA
protein
only
tRNA
Erythromycin
is
the
is
of
listed
that
in
the
P
antibiotic
been
not
factor
event
initiator
has
question
changed
about
the
to
TCTA.
translation.
initiation
phase
would
occur
in
during
this
site.
of
choice
for
pertussis.
It
inhibits
translocation.
6.
Answer:
A.
lysosomal
Characteristic
symptoms
enzymes
into
of
serum,
which
I
cell
disease.
would
not
Note
be
seen
release in
the
of other
deficiencies.
7.
Answer: tion
B. of
nascent the
N
to
terminal
Answer:
by
C. rich
the
V
acid
the
first
glycine,
signal
a
defect
in
sequence
of
is many
and
a
reticulum.
exon
Hydroxyproline in
secretion
suggest
endoplasmic
amino
encoded
is also
factor antigen
protein
and
8.
Decreased
cytoplasmic
the
accumula
translocation
This
implies
required
of a
for
the
mutation
targeting
in to
the
ER
gene.
found
other
corresponding the
uniquely
in
proteins
collagen.
contain
Although
significant
collagen
amounts
of
glycine.
9.
Answer: port in
A. is
10.
11.
Answer:
12.
7
weak,
C.
Answer: C
ile
(the
A.
in
E.
poorly
and
of
base an
cellular
His
diphtheria
deficiency.
fragile
connective
copper
bones
and
trans
Lysyl
oxidase
blood
vessels
tissue.
toxins
inhibit
eEF
2,
the
translo
translation.
of
CTT are is
results
exon
only
unaltered
in
the
because
loss ATC
of
phe
and
508; ATT
ile both
507
and
code
for
unchanged).
substitution entire
which copper
copper.
crosslinked
eukaryotic
sequence
in
a functional
requires
sequence
A
disease,
produces
Deletion
coding
deletion
Menkes
Pseudomonas
terminal
Answer: the
and
factor
the
has
metabolism
from
cation
child
abnormal
collagen
result
The
at is
an
indicative
intron
exon of
a
junction, splice
site
which mutation.
leads
to
Regulation
of
Eukaryotic 5#
Gene
LEARNING
❏
Expression
OBJECTIVES
Demonstrate
understanding
of
regulation
of
eukaryotic
gene
expression
❏
Know
concept
GENETIC of
integrity
of
through
gene
a
expression
cell.
rate
of
or
mechanisms,
specific
of
the
(enhancer
In
TFIID
in
process.
or
addition
transcription
are
feature
of
factors
to
the
regulatory
expression
of
important
ones
a
gene
to
can
occur
involve
regulating RNA
proteins specific
eukaryotic
help DNA
gene
expression
functional
proteins,
repressor bind
with
gene
the
transcription and
proteins
and
maintaining
the basic
associated
important,
in
the
activator
elements)
mechanisms
many
eukaryotes
These
silencer
essential
decreasing but
transcription. and
rate
Other
of
is an
Increasing
various
polymerase the
examples
REGULATION
Regulation
the
and
control
sequences
regions.
is controlled
at
multiple
levels.
REGULATION In
OF
eukaryotic
cells,
typically
requires
accessible
to
for
gene
•
•
DNA
RNA
Histone
in
and
in other
that
of
bind
structures,
order
to
proteins
aspects
factors
EXPRESSION
chromatin
remodeling
Important
histone
GENE
packaged
polymerase
Transcription as
is
chromatin
expression.
such
EUKARYOTIC
to
make
(transcription
chromatin
the
and the
gene
desired factors)
remodeling
DNA
and
expression gene
region required
include:
recruit
other
coactivators
acetylases
acetylases
(favor
gene
expression)
and
deacetylases
(favor
inactive
chromatin) •
Certain
lysyl
charge •
A
and
chromatin
reconfigures •
Additional RNA
residues weakening
in the
remodeling the
DNA
transcription
to
the
histones
are
interaction
acetylated
with
engine
that
binds
expose
the
promoter
factors
bind
in
to
the
decreasing
the
positive
DNA. acetylated
lysyl
residues
and
region. promoter
region
and
recruit
polymerase.
7
Immunology
PART
I
|
BIOCHEMISTRY
Biochemistry
H3
H3
H2A
H2A
H2B
Medical Genetics
H2B
Transcription
H4
H4
factor
Behavioral Science/SocialSciences
Transcription factor
Co
activator
histone acetylase
Transcription factor
Histone acetylase
Acetylated
lysyl
residues
in
histone
Chromatin
remodeling
residues for
and
engine
reconfigures
additional
transcription
Figure I 5 1.
the
transcription
maintaining the
cell.
The
general
are
case
specific together
when
the
such are
as
DNA
transcription to
form
1.
TFIID,
assembled
and
sites others).
Remodeling
basal of
lysyl expose
(low
the in
level)
protein this
transcription encoded
complex
occurs,
by
are
this
gene
referred
to
expression
of
hormones,
growth
sequences factors.
an
gene
of
that
allows
should
factors,
referred Several
enhancer
the
to these
as
be
response
response
control
increased
intracellular
of
in
elements elements
gene
response
conditions. that may
be
expression
In bind
by
grouped multiple
signals.
–75
GRE
CRE
–25
CCAAT
ERE
UPE
box
GC
Rich
+1
TATA
Transcribed
box
regio
1000 Enhancer
Figure
72
in
as
factors.
signals there
I 5 Chromatin
levels
factors
acetylated to
(TBP,
is formed,
adequate
transcription
times
specific
this
but
transcription
There to
complex
moderate
to
nucleosome
factors
Figure
Once
binds
the
tails
base
I 5 2. Figure
Promoter
pairs
Enhancers I 5 2. Enhancers
and
and
Upstream Upstream
Promoter Promoter
Elements
Elements
CHAPTER
Upstream Only
Promoter the
of
it
|
REGULATION
OF
EUKARYOTIC
from
the
upstream
an
promoter
enhancer.
element
Upstream
to
promoter
the
–25
elements
CCAAT
•
GC
box
sequence
HY
HY
(around
–75)
that
binds
a
transcription
factor
NF
transcription
factor
SP
MY
1 LY
rich
sequence
that
binds
a
general
in
following
the
DNA
are
binding
sites
for
activator
proteins.
Yield
Enhancers MEDIUM
They
may
be
up
to
1,000
base
pairs
away
from
the
HIGH
NOTE
have YIELD
the
characteristics: LOW
•
LY
1
High
Enhancers Enhancers
YIELD
The
IgMEDIUM heavy
the
large
They
may
gene •
be
they
The
located
upstream,
downstream,
or
YIELD
chain YIELD locus
intron
regions
for
has
separating
an the
LOW YIELD the variable
enhancer
in
coding
domain
from
the
gene. coding
•
EXPRESSION
include: MY
•
GENE
Elements
proximity
distinguishes
5
within
an intron of FUNDAMENTALS
the
regions
for
the
constant
domains.
FUNDAMENTALS
control.
orientation
of
the
enhancer
sequence
with
respect
to
REINFORCEMENT the gene is
REINFORCEMENT
not
important. •
They
can
proteins •
They
may
bending Similar There
are
appear that
to
act
interact be
of
brought
the
sequences
that
fewer
examples
in with
a
tissue
close
DNA
specific
them
are
to
the
manner
present
basal
only
if in
promoter
the
DNA
certain
region
binding tissues.
in
space
by
molecule.
bind
repressor of
these
proteins
in
sequences
Enhancer
elements
specific
eukaryotes
are
called
silencers.
known.
binding
transcription
NOTE
factors The
CRE
GRE
ERE
CREB
DNA
Estrogen
and as
E
Cortisol
binding
RNA pol 1
SP
in
the
sites
sequences response
elements,
of
that
vicinity for
(e.g.,
genes
proteins
are
often
serve called
regulators.
R
bending
NF
base
enhancers,
UPEs)
“cis” DNA
regulatory
promoters,
R
C
P
DNA
Transcription II
code
for
factors them)
are
(and
the
called
genes
that
“trans”
TFIID
1
regulators. TBP
diffuse
Trans through
regulatory the
cell
proteins to
their
point
can of
action. CAAT
UPE RICH
GC
TATA
Transcription
rich
Increased Promoter
elements
transcription
binding
factors
Figure Figure EnhancerEnhancer
and
general RNA
I I5 5 3.3. Stimulation Stimulation andand
Its Its
Associated Associated
(basal)
of
transcription
by
an
rate
polymerase
of Transcription of Transcription by
an
Transcription Transcription Factors
Factors
7
Immunology MY
PART
I
|
LY
BIOCHEMISTRY
Biochemistry Transcription The
High
Factors
activator
proteins
scription
factors.
domains,
that
Typically,
a DNA
bind
response
elements
transcription
binding
are
factors
domain
and
an
often
contain
activation
Yield
referred MEDIUM
at
least
2
to
H
as tran YIELD
ME
recognizable LOW
domain.
YIELD
Medical Genetics •
The
DNA
binding
promoter
or
motifs Behavioral Science/SocialSciences
response
have
families
domain element.
been
of
binds
to
specific
Several
characterized
transcription
a
types
and factors.
nucleotide
have
Some
of
been
sequence
DNA used
common
in
the
FUNDAMENTALS binding domain to
FUN
define certain REINFORCEMENT binding domains
DNA
RE
include: –
Zinc
–
Leucine
–
Helix
loop
helix
–
Helix
turn
helix
fingers
(steroid
zippers
homeobox •
The
Bind
–
Interact
dependent
transcription
(homeodomain
to
domain
other
proteins
allows
the
transcription
with
initiation –
(cAMP
receptors) factor)
encoded
by
homeotic/
genes)
activation
–
hormone
RNA
transcription
factors
polymerase
factor
and II
to
to:
coregulators
stabilize
the
formation
of
the
complex
Recruit
chromatin
modifying
proteins
such
as
histone
acetylases
or
deacetylases Two
types
can
scription
Table
I 5 1.
Important
be
Specific
Transcription
Factor
Response
(DNA
Protein)
(Binding
Steroid
cAMP
receptors
response
binding
element
(CREB)
Peroxisome
transcription
factors
and
specific
tran
Protein
Class
Element Site)
Function
HRE
Steroid
response
CRE
Response
Zinc
to
cAMP
finger
Leucine
protein
zipper
proliferator
activated
general
Factors
Transcription Binding
distinguished:
factors.
PPREs
Regulate
receptors
of
(PPARs)
multiple
lipid
aspects
Zinc
finger
metabolism
Activated
by
fibrates
and
thiazolidinediones
NFkB
(nuclear
kappa
factor
kB ——Regulates elements
expression
B)
many
genes
in
of
Rel
domains
immune
system
Homeodomain
proteins
Regulate
gene
during
General In
Transcription
eukaryotes,
RNA
polymerase
transcription. general
7
Helix
turn
helix
Factors
general II General
transcription
expression
development
transcription to
bind
and
transcription factor
TFIID
factors form
must
the
initiation
factors with
are its
TATA
bind
to
the
complex
promoter at
common
to
box
binding
most
to
the
start genes.
protein
allow
site The subunit
for
CHAPTER
5
|
REGULATION
OF
EUKARYOTIC
must
bind
examples
to
include
the
SP
TATA
1
and
box NF
before
1
that
RNA
polymerase
modulate
II
basal
can
bind.
transcription
Other MY
of
LY
Transcription
Specific
and
rate
of
silencer
factors
modulate of
sequences
time
in
Additionally,
hormones
factors.
Examples
of
regulatory
which factors
enhancer
(and
genes are
will
include
The in
contains exact a
cell
at
rates.
what can
activity
receptors
of
and
the
be
cell
YIELD to
or
specific
CREB
protein.
LOW BRIDGE
bind
proliferator
to
DNA
response
metabolism. vated
activated elements
Individual
by
a
variety
Fatty
•
Prostaglandin
•
Fibrates
•
Thiazolidinediones
natural
(PPARs)
(PPREs)
and
of
family
members of
•
receptors
and
this
xenobiotic
are
control of
caused genes
transcription
transcription
multiple zinc
ligands,
of
proteins
that
in
insulin
resistance
their
different
including:
seen
interaction
aspects
of
with
with
lipid
thiazolidinediones
PPARγ.
metabolism
is
Clofibrate
than
the
binds
thought
to
PPARα,
PEROXISOMES:
acute
year
(8.4
old pain
orders
HYPERTRIGLYCERIDEMIA
fasting
AND
for
and
the
8.9–10.3
mg/dL)
normal
1/100,
recessive
used
normal
producing would
Hardy
frequently
who
disease
prevalence
equation
A
the
simplification
2
FUNDAMENTALS NOTE
artificially
sweetened
professor producing
The
Her
her
births,
of
affected
carriers
The
carrier
the
the
risk
she
for
would
She
marry
a
of
from
and
asks
man
her genetics REINFORCEMENT
with
the
an
the known
is
much
the
REINFORCEMENT Hardy
disease
the
two
than
person
Weinberg
would
the
Equilibrium
estimate
in
the
PKU
is 1/10,000
live
the •
of
Allele
frequency
(1/10,000)
identifiable
to
of
births
First,
frequency
in
(PKU)
Prevalence
approximately
be
disease
•
is
reasons. the
equation of
population
higher,
for
Weinberg
prevalence
in
much
higher
affected
Hardy
PKU
a carrier
is
second,
of
carriers
marrying
condition
used
from
prevalence
frequency
this
geneticist
frequency
known
comes
homozygotes,
clinically.
(NutraSweetTM).
that
that
but
greatest
frequency
aspartame
chances
Phenylketonuria
tells live
1/50.
the
allele.
geneticist
1/10,000
with
about
the
•
Carrier
= =
1/100
frequency
=
=
0.01
2(1/100)
=
following 1/50
way:
Disease
prevalence
Carrier
frequency
q = 2q
square =
The
of
or
1/50,
marrying
now a
asks
carrier
q2
=
root
2/100,
woman
=
of
a
2q
=
1/10,000
(to
be
1/10,000, the
this
which
is
1/100
frequency
question:
allele,
births
calculated)
carrier
second
live
“Knowing
what
is the
that
probability
I have that
a
1/50
I will
have
chance
of
child
with
a
PKU?”
The
geneticist
answer
answers,
is based
•
The
•
If
“The the
probability he
is
normal
These
on
a
that
carrier,
allele
the to
probabilities
chance
joint
the
would
of
occurrence
she
will
of
marry
probability child
be
you
having two
a that
a
child
with
PKU
nonindependent
heterozygous he
will
carrier pass
is
1/100.”
This
events:
his
(1/50),
PKU
allele
and versus
the
(1/2).
multiplied
to
BRIDGE
TO
STATISTICS
If events
are
nonindependent,
probability
of
the
second
event,
has
occurred.
For
example,
1/50
×
1/2
=
1/100,
the
probability
event
husband
producing
allele
probability
that
by
the
assuming
what
student’s
is the will to
he
probability
that
the
probability pass
the
the
of
first
that
the
disease
the
child?
It is
will
be
a
the
probability
carrier
the (1/50,
give: event
•
one
multiply
that
she
will
have
a
child
with
PKU.
will (1/2,
1) pass event
multiplied the
by
disease 2),
assuming
causing
gene he
is
a
that
he
along carrier.
32
Biochemistry
PART
II
|
MEDICAL
GENETICS
Medical Genetics In
NOTE
summary,
there
equation Assuming
random
Weinberg
principle
relationship Behavioral Science/SocialSciences
frequencies
principle
can
autosomal
of
be
the
specifies
between
genotype
frequency
mating,
in applied
and
populations.
heterozygous
recessive
predictable
frequencies
to
3
major
terms
autosomal
one
usually
recessive
works
with
in
the
Hardy
Weinberg
conditions:
•
q2,
the
disease
prevalence
•
2q,
the
carrier
frequency
•
q,
This
estimate carriers
mutation.
to
Hardy a
allele
are
applied
the
frequency
of
the
disease
causing
allele
the of
an
When to
answering
identify
which
questions
which term
This
you
exercise
•
are
Hardy
terms
asked
to
heterozygous
of
the
For
two
calculations,
in
the
stem
it
of
the
is
important
question
and
points:
principle
can
in
recessive
carriers
is
effect,
given
be
applied
to
when
we
populations
estimate
the
know
only
prevalence the
prevalence
disease.
autosomal
gous
Weinberg
been
important
carriers
recessive
Hardy
has calculate.
Weinberg
of
In
involving
these
demonstrates
The
•
of
the
diseases,
much
vast
higher
such than
majority
of
as
the
PKU,
the
prevalence
prevalence
recessive
of
genes
are
of
affected
heterozy
homozygotes.
hidden
in
the
heterozy
gotes.
Hardy
Weinberg
The
calculations will
the
gous
be
dominant
diseases
heterozygous.
assumption
affected
severe
that
p
individuals
symptoms.
•
for
for
individuals use
Equilibrium
1/500
people
and
are
at
~
1.)
Diseases
must
In The
who,
For
Dominant
acknowledge
this
case,
term
q2
although
the
that
prevalence
most is
represents
the
much
less
commonly
have
a form
of
2q.
of
the
(One
prevalence
of
seen,
affected
can
may
again
homozy have
more
example,
in
the
United
increased
States
risk
for
cardiovascular
can
calculate
LDL
receptor
disease
and
deficiency
myocardial
infarction. •
Taking
2q
million
live
have
=
1/500,
greatly
are
elevated
cardiovascular present
one
births
LDL
disease with
that
homozygous
for
cholesterol
than
q2
the levels,
and
xanthomas,
1/106,
or
one
in
These
a much
heterozygotes,
characteristic
=
condition.
higher
are
more
xanthelasmas,
a
individuals risk likely
and
for to
corneal
arcus.
In
contrast,
repeats
in
gous
or
Sex
Chromosomes
When
homozygous
occur
but,
the
statement
the
disease
more
(autosomal
strongly
dominant),
with
disease
the
severity
number than
does
of
triplet
heterozy
status.
and
in
frequency
disease
much
considering
cases
32
Huntington
correlates
X
Allele
linked
Frequencies
recessive
hemizygous
conditions,
males
paradoxically,
it
“1/10,000
males
producing
allele:
(xY). also has
one
Therefore,
equals
q
the
must =
prevalence
hemophilia
A”
acknowledge
disease of
also
gives
affected the
1/10,000.
•
q2
=
prevalence
of
disease
in
females
•
2q
=
prevalence
of
female
carriers
(1/108, (1/5,000)
or
that
producing
1/100,000,000)
allele
most
allele males. frequency
Thus, for
CHAPTER
This
exercise
•
demonstrates
As
with
are
•
X
recessive
in
number
of
linked
|
POPULATION
GENETICS
that:
autosomal
hidden
2
female
these
traits,
the
heterozygous
genes
recessive
are
seen
traits
majority
carriers
are
in
affected
seen
of
X
linked
(although
recessive
genes
a considerable
males).
much
more
commonly
in
males
than
in
females.
FACTORS
RESPONSIBLE
IN/AMONG human loci,
populations
deviations
introduction
a new
mating
genetic
drift,
mutation
into
flow.
one
in can
example,
gene
than
typically
equilibrium
(for
and
more
are
from
of
nonrandom
often
GENETIC
VARIATION
POPULATIONS
Although most
FOR
Weinberg
produced
a population
contributes
factors
to
allele
new
of
effect),
natural
discussed
frequencies
the
(founder
action
are
for
mutations,
outside
the
these
equilibrium
by
from
consanguinity),
Although
effect
Hardy
be
selection,
independently,
in
a population.
NOTE Mutation Mutation,
discussed
in
populations.
to
population.
In
some
In
cases,
carrying
the
referred
to
general,
a new
as
a
drift
is
founder frequency
(see
below),
chain
disease) PA,
while
live
births.
chain
and
be
acts
upon
into of
a
be
genetic
much
expands
affected
someone
This
natural
DEHYDROGENASE
at
in to
this a
(maple
Mennonite
large,
the
a single
selection,
disease
a
variation
in
•
Mutation
•
Natural
selection
•
Genetic
drift
•
Gene
populations
responsible
for
are:
by flow
urine of
occurs (allele)
suggests
founder
syrup
community
mutation
group
factors
DEFICIENCY
deficiency the
evolutionary
is
through
by
4
genetic
population
when
community.
The
variation
from
population
the
rapidly can
in
of
due
very
new
in in
common
only the
Lancaster, 1/180,000
branched
origin
of
the
effect.
Selection
Natural
selection promote
frequencies disease
of
to do
or
fertility
alleles
that
reduce
alleles diseases,
the
recessive
genetic
survival
producing Dominant
exposed than
may
differ
community
births
population
gene
not
all
consanguinity.
predominance
This
the
KETOACID
live
of
founders
dehydrogenase
1/176
source
introduced
mutation
by
the do
early
the
CHAIN
U.S.
be
the As
of
dehydrogenase
Natural
rare.
the The
mutation.
that
in
in
of
ketoacid
occurs
rates
can
one effect.
the
ultimately
mutation
BRANCHED
Branched
is
mutation
mutation
generations, genetic
previously,
effects
helps in
of
diseases,
which
natural where
variation,
increasing
(referred
to
fitness. explain the
why
most
and
genetic
to
is typically
of
of
lower hidden
is
alleles
the
most
diseases allele
have
frequencies decreasing
fitness
causing tend
allele
fitness)
reduced
disease
selection, the
as
The
the
are more allele in
relatively readily
frequencies heterozygotes.
32
Biochemistry
PART
II
|
MEDICAL
GENETICS
Medical Genetics SICKLE
Sickle in
cell
some
disease parts
affects of
CELL
1/600
Africa.
DISEASE
African
How
AND
MALARIA
Americans
could
this
and
highly
up
to
deleterious
1/50
individuals
disease
causing
Behavioral Science/SocialSciences mutation that
become
the
Africa,
does
These
so
falciparum not
survive
individuals,
thus
high
is now
diseases
that
Cystic
•
Hemochromatosis
•
Glucose
frequency
in
for
33
of
sickle
some
of
(heterozygote
cell cell
and
in
the
much
heterozygotes.
disease,
are there
it
fact of
is
maintains
a
populations.
some
for
several
populations.
to
other
recessive
Examples
typhoid
advantage
dehydrogenase to
sickle
mutation,
resistance
resistance
lies in
Consequently,
advantages in
answer
common
sickle
malaria.
African
common
phosphate
The been of
cell
(heterozygote 6
has
signs
effects the
Africa?
in
include:
fever) iron
deficiency,
poor
environments)
hemolytic
anemia
malaria)
Drift
Mutation
small
clinical
heterozygote
relatively
(heterozygote
they
erythrocytes
the
no
for
fibrosis
in
lethal
advantage
evidence are
•
Genetic
the
in which
have
against
a heterozygote
There
especially parasite,
well
who
protected
relatively
frequent, malaria
rates can
result
do in
not
vary
significantly
significant
populations
or
founder
effects
common
(or
rarer)
act
Consider
the
pedigrees
are
along in
from
differences introduced with
small, (very
in by
genetic isolated small
a
population allele
founder
drift populations populations)
to
to
population,
frequencies effect.
make
Mutation
certain than shown
although
when
they rates
genetic
in
the in
occur
diseases
world Figure
at II
2
in
and
large. 1.
more
CHAPTER
Affected
person
either the
or
small
(founder
|
POPULATION
GENETICS
who
founds
into
I
2
moves
population
effect)
II
III
I
New
mutation
in
a
family
II
III
Genetic
drift
generation
begins. III
is
In 2/3,
both
II Figure 2 1.
Figure
than
the
woman
rather
than
would
be
6,
prevalence to
When
a
drift
alone A
would
many
natural the Hardy
the
or
can
the
in
a
top their
effect
allele
panel
more
in
1,000
drift
illustrates
less
children
(Generation
genetic
occurs or
had
offspring
example
founder
persons
Populations Populations
Although
this
affected
statistics.
Disease) Disease)
the in
mean. family,
mutation make
5)
disease
statistical
of by
Drift in Two Small Small in Two
(II
the
a single
frequency predicted
in
two
a
small
prevalent
than
III) affects points:
population, statistics
predict.
relatively
or
1/2
a Dominant with a Dominant
man of
than
new
with (Illustrated
affected
1/2,
larger
genetic
•
the
the
closer
populations
•
and
the
the
II 2 1. Genetic Genetic Drift
(Illustrated
If
examples
higher
large alleles disaster
population. Weinberg
population can
be
or
large
Genetic equilibrium
in
Hardy
affected scale drift
by
genocide may is
Weinberg
population
then
equilibrium “bottlenecks”
dramatically change
reduces allele
for in
frequencies
an
allele
which the
size
of
and
a
new
reached.
33
Biochemistry
PART
II
|
MEDICAL
GENETICS
Medical Genetics Gene
Flow
Gene
flow
flow,
refers
to
populations
frequencies.
the
exchange
located
close
Gene
flow
of to
can
also
cell
disease
genes
one
among
populations.
another
cause
often
gene
Because
tend
to
frequencies
to
have
of
gene
similar
change
gene
through
time:
Behavioral Science/SocialSciences The of
frequency gene
flow
disease cell
mutation
matings
produce
offspring
diseases
because
sectors in
(see
text
are
affected
with
individuals
more
likely
to
who
and
Consanguinity a union
individuals
share
ancestors
are mutations.
more
liable
to
the
U.S.
in
African
Americans
population
the
that
heterozygote
disappeared
Health
to is
related for
in
do
not
malaria
the
for
has
because
carry
advantage
because
part
the
sickle
become
rare
in
the
Consequences
mating
of
considered
at
the
to
second
individuals
be cousin
a consanguineous
who
are
consanguineous level
union.
related
if or
Because
closer). of
to
it occurs Figure
their
one
another
between II
mutual
2
2
illustrates
descent
from
disease
causing
a
share common
causing
lower
addition,
has
Its
refers
(typically,
recessive
box)
of
is
America.
pedigree
disease
other mutation;
Consanguinity
Consanguineous
common
sickle
from
causing
North
NOTE
of
ancestors,
genes.
•
Siblings
•
First
•
Second
These III
relatives
are
more
likely
to
share
the
same
Statistically,
(II
and
cousins
numbers
are a
has
3
3
4) IV
to
1/8
4)
III
causing a
II
1 and
referred
and
or
and
(IV
disease
it
II
(III
cousins
1 carries
brother)
2
as
the
1/2
share 2)
allele,
chance
share
1/8
their
of
share
of a 1/2
individual
genes
of
coefficients is
genes.
their
1/32
there
that
of
their
(1/2 genes
relationship. chance
III
4
1/2
×
1/2).
(1/8
×
1/2
×
Thus, that
(his
×
if individual
individual
first
cousin)
1/2).
III
3
has
it.
the
health
(his
I
II
III
IV
Figure II 2
Figure
Consequently,
there
consanguineous consequences show present frequency (e.g.,
33
is
an
matings. of
that
the with
uncle/niece
2 2. A Pedigree A Pedigree
increased
genetic
genetic
of
of
of
disease
brother/sister
cousin as
are
increases
disease studies
first matings
the
matings).
the
offspring
examined
matings.
These
approximately of
in
in have
cousin are
offspring further
Consanguinity Consanguinity
genetic
empirical
particularly first
disease or
Illustrating Illustrating
risk
Dozens
consanguinity,
offspring a
of
II 2.
the
twice
unrelated
matings.
offspring
of
closer
of
studies as
likely
The unions
to
CHAPTER
Review
1.
|
POPULATION
GENETICS
Questions
A
population
ing
has
genotype
been
assayed
counts
have
for
been
a
4
allele
polymorphism,
On
the
alleles
basis
of
and
2?
1
A.
0.38,
0.28
B.
0.19,
0.14
C.
0.095,
D.
0.25,
0.25
E.
0.38,
0.20
Which
the
A.
Consanguinity
B.
Genotype
Natural Once many
E.
The tion gotes
follow
Count
1,1
4
1,3
8
1,4
3
2,3
5
2,4
9
3,3
4
3,4
6
4,4
11
these
genotype
counts,
following
best
characterizes
has
no
frequencies
reverse
D.
the
what
are
the
gene
frequencies
of
0.07
of
C.
and
obtained:
Genotype
2.
2
is
not
has
population
in
to of
be the
be
no
Hardy
Weinberg
estimated
effect
deviates
generations frequency can
can
on
Weinberg
equilibrium?
equilibrium.
from
allele
frequencies,
but
the
true.
selection a
effect
Hardy
estimated
return
to
heterozygous if
on from
Hardy
Weinberg
equilibrium. equilibrium,
it
takes
equilibrium. carriers
one
Weinberg
Hardy
knows
of the
an
autosomal
incidence
recessive of
affected
muta homozy
population.
33
Biochemistry
PART
II
|
MEDICAL
GENETICS
Medical Genetics 3.
In
a
first
genetic
counseling
cousins
and
spring.
Which
A.
of
Because
session,
that
they
the
the
a healthy
are
following
couple
couple
concerned best
shares
about
has
revealed
health
risks
characterizes
these
approximately
half
that for
they
their
are off
risks?
of
their
type
of
genes,
most
of
the
Behavioral Science/SocialSciences offspring B.
The
are
couple
has
dominant C.
The
couple
The
to
be
affected
with
some
genetic
disorder.
an
increased
risk
of
producing
a child
with
an
autosomal
an
increased
risk
of
producing
a child
with
an
autosomal
disease. has
recessive D.
likely
disease. couple
has
an
increased
risk
of
producing
a
child
with
Down
syn
drome. E.
4.
There
An
is no
African They
African
American
provides
B.
Genetic
C.
Increased
gene
D.
Increased
mutation
E.
Natural
fibrosis
1/25
B.
1/50
C.
2/2,500
D.
1/2,500
E.
(1/2,500)2
a
known
and
that
mutation
33
1%
B.
0.5%
C.
0.25%
D.
0.1%
E.
0.05%
in
this
the
offspring.
two
children
seems
other
to
U.S.
with
be
more
sickle
cell
common
populations.
in
Which
of
the the
explanation?
population
in
this
population
in
from
this
with and
(1/100) (1/200) (1/400) (1/1,000) (1/2,000)
his
mate
of
carrier
of
recessive high
for
somebody
among
from will
a population
heterozygous
of carriers
of
a
population?
Suppose the
a
mutation
causing
condition.
urinary
seizures.
homozygous
1/2,500
incidence
autosomal
including
he
is
heterozygous
involved?
A.
than
predicted
ranges
is
mates
disease
fibrosis
the
an
population
bility
produced
this
best
rate
mutation
manifestations
man
in
cystic is
hyperprolinemia, is variable
flow
of what
is
for
selection
incidence
man
the
risk
drift
A.
A
has
why
population
Consanguinity
Europeans,
6.
asked
A.
cystic
in
couple
have
factors
If the
increase
American
disease.
following
5.
known
Phenotypic
excretion
of
that
0.0025%
mutation
causing
the
general
produce
a
proline
who
neurologic
(1/40,000) this
population, child
expression to
what is
of
condition.
homozygous
the
If the is
the
proba for
the
CHAPTER
7.
The
incidence
1/3,000 this
males. X
linked
A.
1/3,000
B.
2/3,000
C.
(1/3,000)2
D.
1/6,000
E.
1/9,000
of
Duchenne
On
the
recessive
muscular basis
for
this
dystrophy figure,
what
in is
North the
America gene
frequency
is
2
|
POPULATION
GENETICS
about of
mutation?
33
Biochemistry
PART
II
|
MEDICAL
GENETICS
Medical Genetics Answers
1.
Answer:
B.
The
obtained
by
adding
multiplying
Behavioral Science/SocialSciences
denominator
by
numerator
is
2
heterozygotes 3
alleles.
Dividing
by are
with
2.
and
2,4
The
Hardy
of
of
the
the
ing
number
expectation
(i.e.,
random
in
choice
a specific
and
1.
For
9
allele
2,
those copies
of
the
estimation
Using
the
frequency to
and
estimate
gen
the
fre
population.
equilibrium
in
a
by
above
violation
the
of
increas
equilibrium
the
assumption
of
be
from
gene
estimated
from
frequencies
(choice
genotype
B),
frequencies
(as
genotype
from
selection
can
the
population
cause
(e.g.,
deviations
affected
from
equilibrium
C). one
generation
C.
the
they
child
general
mating
couple
are
recessive
a
random
shares
more
likely
disease
with
an
is
required
to
return
a
population
D).
Because
autosomal
common to
causing
autosomal
be
ancestors
mutations.
recessive
(i.e.,
heterozygous Thus,
disease
one
carriers
is
of
their
risk
elevated
set
of
the
of
above
same
produc that
of
the
population.
First
cousins
Because
share both
harbor
a
with
a
allele
approximately
members
dominant
consanguinity
itself
is
syndrome it
mutation
is
not
the
(choice
thus
studies cousin
would
E).
are
that is
genes,
healthy,
mutation
elevate
the only
typically
an not
indicate couples
their
not neither
(choice of
copy
of
(choice
one B).
probability one
1/2
the
is
In
A).
likely
to
addition,
producing
a
disease
child
causing
disease.
D) by
of
couple
because
cause
transmitted
Empirical
(choice
does
to
and
the
causing
disease
needed
When
of
1/8
disease
dominant
Down
first
of (choice
grandparents),
33
allele:
gene
population
estimated
also
natural
Answer:
tion
4
1,3
A).
equilibrium
ing
be
can
eliminating
Only
of
1.
the 5
used
Weinberg
the
results
can
frequencies
(choice
3.
Hardy in
allele
allele of
population.
be
the
the
the
con
of
permits the
then
in
affects
consanguinity
homozygotes),
to
A)
frequencies
gene
By
can
type: 1;
0.14.
between
frequency
homozygotes
for
copy
homozygotes in
The
heterozygotes
yield =
each allele
copies
0.19 a
locus).
mating).
Genotype but
of
1,4
genotypes
mutation
genotype
(choice
the
of
is and
the
of of
19
have
relationship
gene
the
14/100
affected
heterozygous
Consanguinity
2 of
at
alleles
obtain
that
recessive
equilibrium
frequency,
quency
of
the
and
frequency
frequency
which (50)
alleles
of
we
These
a
100,
8 copies
alleles;
a gene
incidence
Weinberg
otype
8
heterozygotes
for
frequency
number
together,
genotypes.
respectively,
E.
the
yields of
two
contribute
another
this
has
the
genotype
is
individuals
individual
these
classes
2,3
2,
Answer: of
100,
frequency
genotyped
counting
1,1
Adding
two
the
allele
by the
gene
of
each
contribute
tribute
there
(because
with
the
number
obtained
homozygotes
of
the
is
affected be
the
affected the
approximately
result
female,
risk
it
by of
of acts
mutation. a
dominant
consanguinity.
genetic
double
a new like
disease that
of
in the
the
general
offspring popula
CHAPTER
4.
Answer:
E.
The
populations resistant is
to
disease
elevated
incidence
population African to
Although
is
no
6.
A.
frequency
for
frequency
is
Answer: will
also
(q2)
is
in
One a
be
allele
(probability
ty
7.
of
Answer: male dence is
of
a direct
mutation
are
disease,
POPULATION
GENETICS
which
the
mutation
population.
of
this
autosomal
account
for
the
American
for
obtained
causing or
their
the If
(probability 1/2),
and
the
occurrence
copy X
estimate
gives
males of
linked of
man the
the
have disease
is
the
mate
must
also
1/100
only
×
The
a
single
causing disease
the
frequency
×
in
the
X
1/2
pass along
the
determine =
frequency events The the
mate mutant
mutant the
allele probabili
1/400.
chromosome,
the
portion
the
mate
carrier
along
mutation.
in
man’s
mutation.
recessive male
carrier
homozygotes
independent
to 1/2
the
affected
Three
pass
the gene
The
1/200.
must
a
(0.02).
that
for
of
get
this
strong.
1/25.
of
1/100.
in
very
root
1/50
or
3 probabilities
recessive gene
of
homozygous
1/100),
Multiplying
Because
is
the
elevated is
to
frequency q,
2q) be
is
square
probability
the
frequency,
to
D)
the
2q,
determine
child
because
selection
(q)
into
decrease,
populations.
homozygotes)
mutation
allele
to
be
B).
populations
disease
(choice
approximately
carrier. the
cell
taking
affected
other
African
not
(choice
expected
natural
by
of
would drift
from be
rate
evidence
(approximately
one an
highest
the
first
then
joint
A. has
sickle
2pq,
must
1/2).
their
the
genetic
C) would
some
heterozygous
carrier
(probability
African
consequently of
(choice this of
is
by
for
a
many mutation
for
African
and
in
disease
population
must
flow
frequency
the
C.
happen
cell
not
the
levels
is
the
answer
given
be
must
does
large
frequency
that
the
1/40,000,
the
the
contrast,
This
(i.e.,
gene
disease
evidence
incidence
is
population,
this
In
Answer:
sickle
incidence
it in
elevated
been
increase,
population.
cell
in
the
disease
in
sickle
advantage
frequency
but
population
has
of
There
selective
elevate
specific
elevated
the
develop
a
family,
this
American
than
not
is
could
experienced
there
frequency
do
is
of
|
general.
have
African
rather
5.
of
disease
its
a specific
American
expected
the
A)
in
in
but there
elevating
(choice
recessive
cell carriers
Thus,
carriers,
Consanguinity
sickle
infection
recessive.
heterozygous
The
of
heterozygous
malarial
autosomal
in
frequency
because
2
each Thus, of
affected the
inci
a population
population.
33
3#
Cytogenetics
LEARNING
OBJECTIVES
❏
Interpret
❏
Solve
❏
Demonstrate
❏
Solve
scenarios
about
problems
basic
concerning
and
numerical
understanding
problems
definitions
of
concerning
terminology
chromosome
structural
abnormalities
chromosome
advances
in
abnormalities
molecular
cytogenetics
OVERVIEW This
chapter
reviews
alterations
in
chromosomes
or
alterations ly
1
vast
of
in
150
the
loss
of
and
are
of
fetuses
of
with
pregnancy
by
Thus,
the
microscopically may
They
observable
involve may
the
also
known
are
cause
of
abnormalities
are
seen
in
and
they
are
chromosome
50%
of
seen
20%
structural
seen
in
of
approximate
losses
fetuses the
The
prenatally:
fetal
are
extra
disability.
lost
spontaneous in
of
of
intellectual are
abnormalities
presence
consist
abnormalities
leading
chromosome
pregnancy,
trimester.
caused
alterations
chromosomes.
abnormalities
trimester
are
Chromosome
births
Chromosome
second
that These
chromosomes.
live
majority
first
diseases
chromosomes.
lost
during
during
leading
the
known
cause
DEFINITIONS
AND
X chromosome
contains
~1,200
Y chromosome
contains
~50
genes
of
loss.
BASIC
NOTE
the
genes
TERMINOLOGY
Karyotype Chromosomes
are
when
they
scope
to
are create
haploid
in
of
autosome,
the
with
the
an
an
typical
of
Y
(Figure
each
II
type
of
It
is
is
diploid,
chromosome.
chromosomes
(X
metaphase
the 3
Y)
23
1).
pairs
In
II
are in
3
the
both
the
II copies
1A,
a
presentation 3
1B of
is
is
a
each
ordered
lower
micro
human
Figure
Figure
mitosis,
the
of
chromosome; shown).
showing
placed
of
under
Chromosomes and
stage
photographed of
chromosome
male. the
the
are
display
cell of
each
individual
sex
ordered
somatic
copy
X and
during They
a drawing
one
karyotype
size,
a
visualized
condensed.
represents (only
easily
a karyotype,
chromosomes karyogram
most
maximally
according
right
to
portion
of
the
karyotype.
Metaphase the of
chromosomes
centromere, dyes
to
but reveal
can accurate
characteristic
be
grouped
identification banding
according requires
to
size
staining
and with
to
the one
position of
a
of
variety
patterns.
33
Biochemistry
PART
II
|
MEDICAL
GENETICS
Medical Genetics Chromosome To
banding
visualize
applied
Behavioral Science/SocialSciences
•
G
chromosomes so
G
that
banding. some
binds
DNA.
stains II
that
3
1 have
be
be
been
are
protein)
pattern
of
in
and
light
accurately
used
and
a similar
stained
with
1
1
1
1
1
1
1
2
2
3
3 4
digested
stained
(G
with
bands)
a karyotype.
manner.
stains
are
The
with
trypsin
Giemsa,
regions
that
There
are
chromosomes
(to
a dye
that
allow several
other
depicted
in
Figure
Giemsa.
1
2 p
1
1
1
1
2
2
1
1
1 2
1
q 2 2
2 q 2
in
2
2
various
partially
then
dark
identified
1
2
unambiguously,
chromosomes
2
3 p
a
to can
a karyotype
evident.
associated
reveals
chromosomes
is
Mitotic
digest
banding
in
banding
3
2
1
1
1
1
1
1
1
2 3
2
2
2
4
3
1
2
3
p 1 1
1 1
1 1
q 2
2
2
3
4
5
1
3
6
1
7
1
1
2
2
2
9
10
11
1
1
1 1 2
2
1
1
1
1
1
1 1 2
13
14
Negative
15
or
Positive
'Q'
Variable
bands
pale and
16
17
staining 'G'
bands
18
'Q'
and
Negative
19
'G'
20
bands 'R'
Positive
21
22
'R'
Y
bands
bands
A
B
Figure (Karyogram)
34
12
2
1
1
8
II
3 1. Human Metaphase Chromosomes. Figure II 3 1. Human Metaphase Chromosomes. and (B) Photograph of Metaphase (Karyogram) and (B) Photograph of Metaphase
(A) Idealized Drawing (A) Idealized Drawing Chromosomes (Karyotype) Chromosomes (Karyotype)
X
CHAPTER
Chromosome the
abnormalities
banding
tions)
pattern,
only
must
be
to
mitotic
cell
karyotype q,
relative
position
and
mere
is
the of
it
the
Smaller
at
the
by
looking
instance,
abnormalities
3
II 3
The
at
larger
dele
(microdeletions) end
1.
of
the
chapter.
p
One
of
the
sister
entered
long
instance, and
chromatids mitosis
arm
of
the
when
the
chromosome
characteristics
is
described
q
p
arm
are
the
4).
arm.
chromosome
q arms have
the the
the
chromosomes.
p
roughly
and
is
the
the
equal
arms
are
far
little 13,
have
the
15,
acrocentric
toward
one
evident.
toward
genetic 14,
centro
length.
displaced q
centromere
contains
Only
of
1)
centromere
The
Chromosomes
the
translocations,
which
chromosomes
are
called
1 contains
some
standard
Common
Symbols
Used
Autosome
Y
Sex
(
p.
two
has
one
end.
In
information, 21,
and
most
22
are
chromosomes
of
the are
in
22
or
and and The
have
chromosomes,
of
labeled
chromosome
on
centromere
(for
middle.
Robertsonian
II
is
chromosomes
residing
tips
a
chromosomes
involved
(+)
visually (for
CYTOGENETICS
centromere.
example,
acrocentric
X,
identified
discussed
interphase
chromosomes
(for
these
1
be
differences
(metaphase).
arm
the
Acrocentric
Table
4 Mb.
through
short
near
end
Table
can
reveals
(FISH),
performed
Submetacentric
•
about ways
gone
Metacentric
•
cases
contains
has
analysis
labeled
The
other
chromosome
the
•
of
in
some
technique
|
nomenclature
because
•
this
a resolution
identified
Chromosome Each
in
but
3
)
will
be
in
this
chapter.
telomeres.
nomenclature
in
discussed
Karyotype
applied
to
chromosomes.
Nomenclature
number
chromosomes
When
placed
before
chromosome
p
Short
q
Long
t
Translocation
del
Deletion
is
arm
of
arm
the
of
an
extra
autosomal or
number,
indicates
that
missing
chromosome
the
chromosome
NOTE Euploid
HY
23
Cells
(multiple HY
MY
MY •
Haploid
(23
chromosomes):
LY NUMERICAL
CHROMOSOME
•
Diploid
(46
somatic Euploidy When (sperm
cell and
each
pair);
both
members
has
a multiple
egg
cells)
they
are of
of are
said each
23
chromosomes,
euploid to
pair,
be or
cells haploid. 46
that Most
it is have somatic
23
said
to
be
MEDIUM euploid.
chromosomes cells
are
YIELD Gametes
(one diploid,
member
LOW YIELD containing
chromosomes.
REINFORCEMENT
most
Triploid
YIELD (69
MEDIUM condition
chromosomes):
rare
lethal
YIELD
of •
Tetraploid LOW rare
FUNDAMENTALS
chromosomes):
cells
HIGH
Yield •
a
gametes
LY
ABNORMALITIES
High
of
chromosomes)
(92YIELD chromosomes):
lethal
very
condition
FUNDAMENTALS
REINFORCEMENT 34
Biochemistry
PART
II
|
MEDICAL
GENETICS
Medical Genetics Two
types
of
humans:
Behavioral Science/SocialSciences
euploid
Triploidy
refers
Triploidy,
which
sperm are
cells, lost
have
cells
triploidy
and
to
with
cells
that
usually
prenatally.
contain
occurs
is common
numbers
defects
3
as
at
conception,
the
heart
However,
multiple
abnormal
of
chromosomes
are
seen
of of
but
about
of
copies
a result
1 in and
each
the
the
10,000 central
chromosome
(69
fertilization
of
vast
majority
live
births
nervous
of is
an
total).
ovum
these
a triploid.
system,
by
These
and
they
babies
do
not HY
Tetraploidy
refers
lethal
cases
to
cells
condition
have
been
is
that
contain
much
4
rarer
than
copies
of
each
triploidy
chromosome
among
live
(92
births:
) of
a few LY
High
Aneuploidy,
total). MY
Only
described.
Aneuploidy
(
2
conceptions
survive.
This
in
tetraploidy.
a deviation a specific
from
the
chromosome.
euploid
Two
number,
major
represents
forms
of
the gain MEDIUM
aneuploidy
are
(+)YIELD or
Monosomy
•
Trisomy
(loss
of
(gain
of
a
a
loss
ME
observed: LOW
•
H
Yield
YIELD
chromosome)
chromosome)
FUNDAMENTALS
FUN
REINFORCEMENT Autosomal Two
generalizations
•
All
•
Only
Trisomy
are
autosomal 3
live
helpful:
monosomies
autosomal
are
trisomies
inconsistent
(trisomy
with 13,
18,
a live
and
21)
are
birth. consistent
with
a
birth. 21
(47,XY,+21
•
Most
•
Intellectual
•
Short
•
Hypotonia
•
Depressed
•
Congenital
•
Increased
•
Alzheimer
or
common
47,XX,+21);
autosomal
Down
Syndrome
trisomy
disability stature
gene
342
R
aneuploidy
nasal heart risk
Reduced
•
Risk
upslanting
defects of
acute
disease on
•
bridge,
in
palpebral
approximately
40%
lymphoblastic
by
chromosome
fifth
fissures,
or
of
sixth
decade
(amyloid
21)
with
Trisomy
18
(47,XY,+18
•
Clenched
fist
•
Inward
•
Congenital
•
Low
•
Intellectual
•
Very
or
with
turning,
set
poor
prognosis
age
47,XX,+18);
Edward
Syndrome
fingers bottom”
feet
defects
micrognathia disability
maternal
overlapping “rocker
heart ears,
increased
fold
cases
leukemia
fertility increases
epicanthal
(small
lower
jaw)
precursor
protein,
APP
CHAPTER
Trisomy
Sex
13
(47,XY,+13
•
Polydactyly
•
Cleft
•
Microphthalmia
•
Microcephaly,
•
Cardiac
•
Very
(extra
lip,
renal
severe
tions
are
helpful:
•
If a
•
If
one
more
NOTE
the
X
sex
in
one
each
cell.
sex
syndrome.
Klinefelter
Syndrome
•
Testicular
•
Infertility
•
Gynecomastia
•
Female
•
Low
•
Elevated
•
High
•
Majority
is present,
required the
for
is
and
aneuploidy.
phenotype
chromosome
chromosome
common
autosomal
present,
aneuploidies
tends
Some
to
generaliza
Trisomy of
is the
most
spontaneous
common
loss
of
genetic
cause
pregnancy.
survival. is male
(with
all
one
are
but
Turner
minor will
exceptions). become
syndrome
a Barr
and
(47,XXY)
atrophy
NOTE distribution
of
hair
Genetic
Mosaicism
Genetic
mosaicism
in
Turner
Syndrome
testosterone FSH
and
pitched
LH
or
monosomy
or
within
a
Turner
syndrome
consistent
with
45,X
life
arise
47,XXX,
46,XY)
•
Females
with
•
Short
•
Edema
•
Cystic
cells
of
as
a condition
different
chromosome
single
and
constitutions
individual.
Some
are
mosaics
for
45,X
and
one
other
cell
lineage
women
with
are
at
increased
risk
for
gonadal
that
in Turner early
somatic are
46,XX
syndrome
embryogenesis
cells
that
or
47,XXX.
is by
thought
are
to
mechanisms
(46,XX, that
45,X;46,XY
in
have
others
Mosaicism
others
is defined are
45,XO)
45,X of
there
genotypes
(45,X
are
in which
voice
Syndrome
50%
X
is relatively
does
chromosome
than
Klinefelter
•
chromosomes than
is
important
Only
disability
defects
Y chromosome
body
•
eyes)
consequences
least
two
toes)
prognosis
involving
less
CYTOGENETICS
Syndrome
aneuploidy
have
At
Patau
and
intellectual and
Aneuploidy
Turner
fingers
(small
poor
•
47,XX,+13);
|
palate
chromosome
The
or
3
are
not
completely
understood
blastoma.
stature of
wrists
hygroma
and
in
ankles
in
utero
resulting
aorta
or
newborn
in
excess
nuchal
skin
and
heart
defect
in
“webbed”
neck •
Primary
•
Coarctation
•
Infertility
•
Gonadal
amenorrhea of
the
other
congenital
some
cases
dysgenesis
343
Biochemistry
PART
II
|
MEDICAL
GENETICS
Medical Genetics Nondisjunction Germ
is
cells
the
all
for
simplicity.
In
the
will
other diploid
with
will
egg
one
would
a
or
sperm.
The
homologous occur
for
live
each
original
cell
pair
is
shown
in
pair
of
homologs
When
fertilization
The
other
that
2,
fail
to
the
in
21)
the
cell.
occurs, gametes
are
sister
monosomy
of
the
conception
no
21,
during
Two the
with
chromatids
segregate One
fertilization
a
monosomy
is
the
has
the
the
no
21.
The
of
occurs,
gamete
of
(disjoin).
normally.
One is
When
conceptions
meiosis
syndrome. that
chromosome
normally
21.
segregate
a conception
example,
copy
of
a condition
birth.
21)
21.
(for
(disjoin)
syndrome.
in
during
Down
pair
Down
result
chromosomes
haploid
events
chromosome
chromosome
chromosome
in
haploid
only
segregate
with
nondisjunction
with
the
homologous
for
incompatible
example,
one
21 21
other
same
homologs
a trisomy
chromosome
In
produce although
The
of all
are be
aneuploidies
cell.
1,
gametes
to
of
chromosomes,
nondisjunction
meiosis
cause
meiosis
for
figure
within
usual
undergo
is diploid
Behavioral Science/SocialSciences
the
The
gametes
conception
copy
a
chromosome
sister
of
chromosome
remaining
two
(for
chromatids is
diploid
will
be
of
a trisomy
21
all
for
and
gametes
21
will
are
result
normal
ones.
Some
important
•
points:
Nondisjunction Edward,
•
Patau,
usual
Turner,
Nondisjunction
is
cause
and
more
of
aneuploidies
Klinefelter
likely
to
including
Down,
syndromes.
occur
during
oogenesis
than
during
age.
Environ
spermatogenesis. •
Nondisjunction
is
mental
agents
more
(e.g.,
likely
with
radiation,
increasing
alcohol)
maternal
appear
to
have
no
measurable
influence. •
Nondisjunction
is
CLINICAL
Surveys
of
copy
of
with
meiosis
MATERNAL
trisomy
chromosome
show
is
contributed
the
18th
Down
syndrome
•
For
•
At
age
35
the
risk
increases
to
about
•
At
age
40
the
risk
increases
to
1/100.
•
At
age
≥45
they
of
is are
3
of
the
is
Then
recombination
the
and
a Marker
0.01
0.05
0.10
0.20
0.30
0.40
score
0.58
1.89
3.47
2.03
–0.44
–1.20
interpreting
LOD
scores,
the
following
rules
apply:
LOD
score
more
likely
>3.00
shows
statistical
evidence
of
linkage.
(It
is
1,000
times
recombination
above
recombination
the
row
of
frequencies. the
LOD
• The
score
>3
LOD
that
score
times
value
at
is •
frequency.
An
the
gene
and
the
marker
are
linked
at
that
distance
than
likely
score
for most
of
likely
no
of
LOD
results
Gene
on
by
•
Linked
markers
genetic
testing
genetic
testing
Linkage
10
and
the
of
nonlinkage.
marker
are
(It
unlinked
is
100
than
linked
4
and
1
the
shows
score
is
analysis
indeterminate.
in
only
one
recombination
gene
>3.00,
and
the
with
analysis
the
the
case
is
there
frequency the
can
be
marker
cM can
may
used
several
along
show distant identify
5).
In
less
of
is
convincing 0.10.
evi
Therefore,
a recombination
locus
of with
a
disease
family
1% the
suggestive need
recombination
heterogeneity.
be
linkage,
but
gathered.
functions:
causing pedigree
markers
gene).
of to
important
practice,
than from
be
would
location
Chapter
must
data disease
serves
approximate
(see