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3' DNA Replication, Mutation, Repair

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Each of the parental strands serves as a. template for a ... round of replication, or if improperly repaired. C. G. C. G. and. C. G. C. G. C. A. and. C. G. T ... – PowerPoint PPT presentation

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Title: 3' DNA Replication, Mutation, Repair


1
3. DNA Replication, Mutation, Repair
a). DNA replication i). Cell cycle/
semi-conservative replication ii). Initiation
of DNA replication iii). Discontinuous DNA
synthesis iv). Components of the replication
apparatus b). Mutation i). Types and rates of
mutation ii). Spontaneous mutations in DNA
replication iii). Lesions caused by
mutagens c). DNA repair i). Types of lesions
that require repair ii). Mechanisms of
repair Proofreading by DNA polymerase Mism
atched repair Excision repair iii). Defects
in DNA repair or replication
2
The mammalian cell cycle
DNA synthesis and histone synthesis
Rapid growth and preparation for DNA
synthesis
S
phase
G1
G0
phase
Quiescent cells
G2
phase
Growth and preparation for cell division
M
phase
Mitosis
3
DNA replication is semi-conservative
Parental DNA strands
Each of the parental strands serves as a
template for a daughter strand
Daughter DNA strands
4
Origins of DNA replication on mammalian
chromosomes
origins of DNA replication (every 150 kb)
5 3
3 5
bidirectional replication
replication bubble
fusion of bubbles
5 3
3 5
daughter chromosomes
3 5
5 3
5
Initiation of DNA synthesis at the E. coli origin
(ori)
origin DNA sequence
binding of dnaA proteins
DNA melting induced by the dnaA proteins
dnaA proteins coalesce
6
dnaG (primase) binds...
G
B
dnaB further unwinds the helix and displaces
dnaA proteins
...and synthesizes an RNA primer
G
B
RNA primer
7
Primasome dna B (helicase) dna C
dna G (primase)
template strand
5
3
OH
3
5
RNA primer (5 nucleotides)
8
DNA polymerase
5
3
5
RNA primer
3
5
newly synthesized DNA
9
DNA
DNA
  • Reaction catalyzed by DNA polymerase
  • all DNA polymerases require a primer with a free
    3 OH group
  • all DNA polymerases catalyze chain growth in a
    5 to 3 direction
  • some DNA polymerases have a 3 to 5
    proofreading activity

10
Discontinuous synthesis of DNA
5 3
3 5
5 3
3 5
5 3
3 5
Because DNA is always synthesized in a 5 to 3
direction, synthesis of one of the strands...
5 3 ...has to be
discontinuous. This is the lagging strand.
11
Each replication fork has a leading and a lagging
strand
leading strand (synthesized continuously)
replication fork
replication fork
5 3
3 5
5 3
3 5
5 3
3 5
lagging strand (synthesized discontinuously)
  • The leading and lagging strand arrows show the
    direction
  • of DNA chain elongation in a 5 to 3
    direction
  • The small DNA pieces on the lagging strand are
    called
  • Okazaki fragments (100-1000 bases in length)

12
RNA primer
direction of leading strand synthesis
3 5
replication fork
5 3
3 5
direction of lagging strand synthesis
13
Movement of the replication fork
5 3
5
3
14
Movement of the replication fork
RNA primer
5
Okazaki fragment
RNA primer
15
RNA primer
pol III
5
5
3
DNA polymerase III initiates at the primer
and elongates DNA up to the next RNA primer
5
5
3
newly synthesized DNA (100-1000 bases)
(Okazaki fragment)
pol I
5
3
DNA polymerase I inititates at the end of the
Okazaki fragment and further elongates the DNA
chain while simultaneously removing the RNA
primer with its 5 to 3 exonuclease activity
16
newly synthesized DNA (Okazaki fragment)
5
3
DNA ligase seals the gap by catalyzing the
formation of a 3, 5-phosphodiester bond in an
ATP-dependent reaction
5
3
17
Proteins at the replication fork in E. coli
Rep protein (helicase)
3 5
pol III
5 3
Primasome
Single-strand binding protein (SSB)
pol III
DNA gyrase - this is a topoisomerase II, which
breaks and reseals the DNA to introduce
negative supercoils ahead of the fork
18
Components of the replication apparatus
dnaA binds to origin DNA sequence Primasome
dnaB helicase (unwinds DNA at origin)
dnaC binds dnaB dnaG primase (synthesizes
RNA primer) DNA gyrase introduces negative
supercoils ahead of the replication fork Rep
protein helicase (unwinds DNA at
fork) SSB binds to single-stranded DNA DNA pol
III primary replicating polymerase DNA pol
I removes primer and fills gap DNA ligase seals
gap by forming 3, 5-phosphodiester bond
19
Properties of DNA polymerases
DNA polymerases of E. coli_ pol I pol
II pol III (core) Polymerization 5 to 3
yes yes yes Proofreading exonuclease 3 to 5
yes yes yes Repair exonuclease 5 to 3 yes
no no DNA polymerase III is the main
replicating enzyme DNA polymerase I has a role
in replication to fill gaps and excise
primers on the lagging strand, and it is also a
repair enzyme
  • all DNA polymerases require a primer with a free
    3 OH group
  • all DNA polymerases catalyze chain growth in a
    5 to 3 direction
  • some DNA polymerases have a 3 to 5
    proofreading activity

20
Properties of DNA polymerases DNA
polymerases of humans a b
g d e Location nucl
nucl mito nucl nucl Replication
yes no yes yes yes Repair
no yes no yes yes3 Functions
5 to 3 polymerase yes yes yes
yes yes 3 to 5 exonuclease no
no yes yes yes 5 to 3
exonuclease1 no no no no
no Primase yes no no no
no Associates with PCNA2 no no no
yes yes Processivity low
high Strand synthesis lagging repair
both leading lagging see notes below 1
activity present in associated proteins 2
Proliferating Cell Nuclear Antigen sliding
clamp 3 involved in transcription-linked DNA
repair
21
Proteins at the replication fork in humans
leading strand
helicase
3 5
PCNA
5 3
5 to 3 exo associated with the
complex
SSB
pol a (or pol d)
pol e
topoisomerases I and II
primase activity associated with pol a
lagging strand
22
Mutation
Types and rates of mutation Type
Mechanism Frequency________ Genome
chromosome 10-2 per cell division mutation
missegregation (e.g.,
aneuploidy) Chromosome chromosome 6 X 10-4
per cell division mutation
rearrangement (e.g., translocation) Gene
base pair mutation 10-10 per base pair per
mutation (e.g., point mutation, cell
division or or small deletion or
10-5 - 10-6 per locus per insertion
generation
23
Mutation rates of selected genes
Gene New
mutations per 106 gametes Achondroplasia
6 to 40 Aniridia 2.5 to
5 Duchenne muscular dystrophy 43 to
105 Hemophilia A 32 to 57 Hemophilia
B 2 to 3 Neurofibromatosis -1
44 to 100 Polycystic kidney disease 60 to
120 Retinoblastoma 5 to 12 mutation
rates (mutations / locus / generation) can
vary from 10-4 to 10-7 depending on gene size
and whether there are hot spots for mutation
(the frequency at most loci is 10-5 to 10-6).
24
  • Polymorphisms exist in the genome
  • the number of existing polymorphisms is 1 per
    500 bp
  • there are 5.8 million differences per haploid
    genome
  • polymorphisms were caused by mutations
  • New germline mutations
  • each sperm contains 100 new mutations
  • a normal ejaculate has 100 million sperm
  • 100 X 100 million 10 billion new mutations
  • 1 in 10 sperm carries a new deleterious
    mutation
  • at a rate of production of 8 X 107 sperm per
    day,
  • a male will produce a sperm with a new mutation
  • in the Duchenne muscular dystrophy gene
  • approximately every 10 seconds.

25
Types of base pair mutations
normal sequence
CATTCACCTGTACCA GTAAGTGGACATGGT
transition (T-A to C-G)
transversion (T-A to G-C)
CATGCACCTGTACCA GTACGTGGACATGGT
CATCCACCTGTACCA GTAGGTGGACATGGT
base pair substitutions transition pyrimidine
to pyrimidine transversion pyrimidine to
purine
deletion
insertion
CATCACCTGTACCA GTAGTGGACATGGT
CATGTCACCTGTACCA GTACAGTGGACATGGT
deletions and insertions can involve one
or more base pairs
26
Spontaneous mutations can be caused by tautomers
Tautomeric forms of the DNA bases
Adenine
Cytosine
AMINO
IMINO
27
Tautomeric forms of the DNA bases
Guanine
Thymine
KETO
ENOL
28
Mutation caused by tautomer of cytosine
Cytosine
Guanine
Normal tautomeric form
Cytosine
Adenine
Rare imino tautomeric form
  • cytosine mispairs with adenine resulting in a
    transition mutation

29
Mutation is perpetuated by replication
C
G
C
G
C
G
and
  • replication of C-G should give daughter strands
    each with C-G

C
G
C
A
  • tautomer formation C during replication will
    result in mispairing
  • and insertion of an improper A in one of the
    daughter strands

A
C
T
A
  • which could result in a C-G to T-A transition
    mutation in the next
  • round of replication, or if improperly repaired

30
Chemical mutagens
Deamination by nitrous acid
31
Derivation by hydroxylamine
Alkylation by dimethyl sulfate causes
depurination
The formation of a quarternary nitrogen
destabilizes the deoxyriboside bond and the base
is released from deoxyribose
32
Attack by oxygen radicals
33
Thymine dimer formation by UV light
34
Summary of DNA lesions
Missing base Acid and heat depurination (104
purines per day per cell in humans)
Altered base Ionizing radiation alkylating
agents Incorrect base Spontaneous
deaminations cytosine to uracil adenine
to hypoxanthine Deletion-insertion Intercalati
ng reagents (acridines) Dimer formation UV
irradiation Strand breaks Ionizing radiation
chemicals (bleomycin) Interstrand
cross-links Psoralen derivatives mitomycin C
(Tautomer formation Spontaneous and transient)
35
  • Mechanisms of Repair
  • Mutations that occur during DNA replication are
    repaired when
  • possible by proofreading by the DNA polymerases
  • Mutations that are not repaired by proofreading
    are repaired
  • by mismatched (post-replication) repair followed
    by
  • excision repair
  • Mutations that occur spontaneously any time are
    repaired by
  • excision repair (base excision or nucleotide
    excision)

36
Mismatched (post-replication) repair
  • the parental DNA strands are
  • methylated on certain
  • adenine bases
  • mutations on the newly
  • replicated strand are
  • identified by scanning
  • for mismatches prior to
  • methylation of the newly
  • replicated DNA

5 3
  • the mutations are repaired
  • by excision repair mechanisms
  • after repair, the newly
  • replicated strand is methylated

37
Excision repair (base or nucleotide)
thymine dimer
ATGCUGCATTGATAG TACGGCGTAACTATC
excinuclease
AT AG TACGGCGTAACTATC
(30 nucleotides)
DNA polymerase b
ATGCCGCATTGATAG TACGGCGTAACTATC
DNA ligase
ATGCCGCATTGATAG TACGGCGTAACTATC
Base excision repair
Nucleotide excision repair
38
Deamination of cytosine can be repaired
Deamination of 5-methylcytosine cannot be repaired
More than 30 of all single base changes that
have been detected as a cause of genetic disease
have occurred at 5-mCG-3 sites
39
  • Defects in DNA repair or replication
  • Xeroderma pigmentosum
  • Ataxia telangiectasia
  • Fanconi anemia
  • Bloom syndrome
  • Cockayne syndrome

100
human
elephant
cow
Life span
10
hamster
Correlation between DNA repair activity in
fibroblast cells from various mammalian species
and the life span of the organism
rat
mouse
shrew
1
DNA repair activity
40
  • Defects in DNA repair or replication
  • All are associated with a high frequency of
    chromosome
  • and gene (base pair) mutations most are also
    associated with a
  • predisposition to cancer, particularly leukemia
  • Xeroderma pigmentosum
  • caused by mutations in genes involved in
    nucleotide excision repair
  • associated with a 2000-fold increase of
    sunlight-induced
  • skin cancer and with other types of cancer such
    as melanoma
  • Ataxia telangiectasia
  • caused by gene that detects DNA damage
  • increased risk of X-ray
  • associated with increased breast cancer in
    carriers
  • Fanconi anemia
  • increased risk of X-ray
  • sensitivity to sunlight
  • Bloom syndrome
  • caused by mutations in a a DNA helicase gene
  • increased risk of X-ray
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