dna repair by:s.solali
DESCRIPTION
DNA repair by:S.Solali. Types of DNA Damage. Deamination: (C U and A hypoxanthine) Depurination: purine base (A or G) lost T-T and T-C dimers: bases become cross-linked, T-T more prominent, caused by UV light (UV-C (TRANSCRIPT
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DNA repairby:S.Solali
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Types of DNA Damage
1. Deamination: (C U and A hypoxanthine)
2. Depurination: purine base (A or G) lost
3. T-T and T-C dimers: bases become cross-linked, T-T more prominent, caused by UV light (UV-C (<280 nm) and UV-B (280-320 nm)
4. Alkylation: an alkyl group (e.g., CH3) gets added to bases; chemical induced; some
harmless, some cause mutations by mispairing during replication or stop polymerase altogether
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Types of DNA Damage (cont.)
5. Oxidative damage: guanine oxidizes to 8-oxo-guanine, also cause SS and DS breaks, very important for organelles
6. Replication errors: wrong nucleotide (or modified nt) inserted
7. Double-strand breaks (DSB): induced by ionizing radiation, transposons, topoisomerases, homing endonucleases, mechanical stress on chromosomes, or a single-strand nick in a single-stranded region (e.g., during replication and transcription)
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IMPORTANCE OF DNA REPAIRHoeijmakers , 2001
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DNA Repair
• DNA damage may arise: (i) spontaneously, (ii) environmental exposure to mutagens, or (iii) cellular metabolism.
• DNA damage may be classified as: (I) strand breaks, (ii) base loss (AP site), (iii) base damages, (iv) adducts, (v) cross-links, (vi) sugar damages, (vii) DNA-protein cross links.
• DNA damage, if not repaired, may affect replication and transcription, leading to mutation or cell death.
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Methyl-directed mismatch repair
• If any mismatch escapes the proof reading mechanisms it will cause distortion of the helix.
• This can be detected and repaired but it is important that the repair enzyme can distinguish the new strand from the old.
• This is possible in E. coli because there is an enzyme which methylates the A in a sequence GATC. This methylation does not occur immediately after synthesis and until it does the two strands are distinguishable.
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Mismatch repair
• MMR system is an excision/resynthesis system that can be divided into 4 phases:
• (i) recognition of a mismatch by MutS proteins,• (ii) recruitment of repair enzymes• (iii) excision of the incorrect sequence, • (iv) resynthesis by DNA polymerase using the
parental strand as a template.
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Mismatch Repair in E.coli
• MutS is responsible for initiation of E. coli mismatch repair.– 95 kDa polypeptide, which exists as an equilibrium
mixture of dimers and tetramers– recognizes mismatched base pairs.
• MutL, a 68 kDa polypeptide that is dimeric in solution, is recruited to the heteroduplex in a MutS- and ATP-dependent fashion.
• The MutL‚ MutS‚heteroduplex complex is believed to be a key intermediate in the initiation of mismatch repair
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Methyl Directed MisMatch repair in E. coli
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Methylataion and Mismatch Repair
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Model for Mismatch Repair
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Excision Repair
• Conserved throughout evolution, found inall prokaryotic and eukaryotic organisms
• Three step process:– 1. Error is recognized and enzymatically clipped outby a nuclease that cleaves the phosphodiester bonds(uvr gene products operate at this step)
– 2. DNA Polymerase I fills in the gap by inserting theappropriate nucleotides
– 3. DNA Ligase seals the gap
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Excision Repair
• Two know types of excision repair
– Base excision repair (BER)• corrects damage to nitrogenous bases created bythe spontaneous hydrolysis of DNA bases as wellas the hydrolysis of DNA bases caused by agentsthat chemically alter them
– Nucleotide excision repair (NER)• Repairs “bulky” lesions in DNA that alter or distortthe regular DNA double helix• Group of genes (uvr) involved in recognizing andclipping out the lesions in the DNA• Repair is completed by DNA pol I and DNA ligase
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Base excision Repair
• For correction of specific Chemical Damage in DNA– Uracil– Hypoxanthine– 3-m Adenine– Urea– Formamidopyrimidine– 5,6 Hydrated Thymine
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Base excision repair.
• Consist of DNA glycosylases and AP endonuclease
• The DNA glycosylases are specific– Uracil glycosylase– Hypoxanthine DNA glycosylase– Etc…
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Mechanism
1.DNA glycosylase recognizesSpecific Damaged base2. Cleaves glycosl bond to removeBase3. AP endonuclease cleaves Backbone4. DNA Pol removes abasic site5. Replacement of Base
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Base Excision Repair (BER)
Variety of DNA glycosylases, for different types of damaged bases.
AP endonuclease recognizes sites with a missing base; cleaves sugar-phosphate backbone.
Deoxyribose phosphodiesterase removes the sugar-phosphate lacking the base.
Deaminated C
Fig. 6.15
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Nucleotide Excision Repair
• Used by the cell for bulky DNA damage• Non specific DNA damage
– Chemical adducts …– UV photoproducts
First identified in 1964 in E.coli.
Ludovic C. J. Gillet and Orlando D. Scharer Molecular Mechanisms of Mammalian Global Genome Nucleotide Excision Repair Chem. Rev. 2006, 106, 253-276
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Excision repairIn this form of repair the gene products of the E. coli uvrA, uvrB and uvrC genes form an enzyme complex that physically cuts out (excises the damged strand containing the pyrimidine dimers.
An incision is made 8 nucleotides (nt) away for the pyrimidine dimer on the 5’ side and 4 or 5 nt on the 3’ side.. The damaged strand is removed by uvrD, a helicase and then repaired by DNA pol I and DNA ligase.
Is error-free.
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TT
TT
Damage recognised by UvrABC, nicks made on both sides ofdimer
TT Dimer removed by UvrD, a helicase
Gap filled by DNA pol I and the nick sealed by DNA ligase
Excision Repair in E.coli
5’3’
3’5’
5’3’
5’3’
5’3’
3’5’
3’5’
3’5’
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Nucleotide-Excision Repair in E. coli and Humans
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Excision repairThe UvrABC complex is referred to as an exinuclease.
UvrAB proteins identify the bulky dimer lesion, UvrA protein then leaves, and UvrC protein then binds to UvrB protein and introduces the nicks on either side of the dimer.
In man there is a similar process carried out by 2 related enzyme complexes: global excision repair and transcription coupled repair.
Several human syndromes deficient in excision repair, Xeroderma pigmentosum, Cockayne Syndrome, and are characterised by extreme sensitivity to UV light (& skin cancers)
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Nucleotide Excision Repair
• Defects cause• Xeroderma Pigmentosum
– 1874, when Moriz Kaposi used this term for the first time to describe the symptoms observed in a patient.13 XP patients exhibit an extreme sensitivity to sunlight and have more than 1000-fold increased risk to develop skin cancer, especiallyin regions exposed to sunlight such as hands, face, neck
• Cockayne Syndrome• Trichothiodystrophy
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Nucleotide Excision Repair
• Defects cause• Cockayne Syndrome
– A second disorder with UV sensitivity was reported by Edward Alfred Cockayne in 1936. Cockayne syndrome CS) is characterized by additional symptoms such as short stature, severe neurological abnormalities caused by dysmyelination, bird-like faces, tooth decay, and cataracts. CS patients have a mean life expectancy of 12.5 years but in contrast to XP do not show a clear predisposition to skin cancer. CS cells are deficient in transcription-coupled NER but are proficient in global genome NER.
• Trichothiodystrophy
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Nucleotide Excision Repair• Defects cause• Trichothiodystrophy
– A third genetic disease characterized by UV sensitivity, trichothiodystrophy (TTD, literally: “sulfur-deficient brittle hair”), was reported by Price in 1980. In addition to symptoms shared with CS patients, TTD patients show characteristic sulfur-deficient, brittle hair and scaling of skin. This genetic disorder is now known to correlate with mutations in genes involved in NER (XPB, XPD, and TTDA genes). All of these genes are part of the 10-subunit transcription/repair factor TFIIH, and TTD is likely to reflect an impairment of transcriptional transactions rather than regular defect in DNA repair. This disorder is therefore sometimes referred as a “transcriptional syndrome”.
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Photoactivation Repair in E. coli
• Exposing UV treated cells to blue lightresults in a reversal of the thymine dimerformation
• Enzyme, photoactivation repair enzyme(PRE) absorbs a photon of light (from bluelight) and is able to cleave the bondforming the thymine dimer.
• Once bond is cleaved, DNA is back tonormal
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Direct Repair: Photoreactivation by photolyase
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Alkylation of DNA by alkylating agents
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O6-methyl G, if not repaired, may produce a mutation
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Direct Repair: Reversal of O6 methyl G to G by methyltransferase
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Direct re
Direct repair of alkylated bases by AlkB.
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Pairing of homologous chromosomes and crossing-over in meiosis.
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Helicase and nuclease activities of the RecBCD
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Helicase and nuclease activities of the RecBCD
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The RecBCD pathway of recombination
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Recombination during meiosisis initiated by double-strand breaks.
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RuvA and RuvB
• DNA helicase that catalyzes branch migration• RuvA tetramer binds to HJ (each DNA helix
between subunits)• RuvB is a hexamer ring, has helicase & ATPase
activity • 2 copies of ruvB bind at the HJ (to ruvA and 2 of
the DNA helices)• Branch migration is in the direction of recA
mediated strand-exchange
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RuvC bound to Holliday junction
Fig. 22.31a
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Models for recombinational DNA repair
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Models for recombinational DNA repair of stalled replication fork
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DNA non-homologous end-joining (NHEJ)
• Predominant mechanism for DSB repair in mammals.
• Also exists in single-celled eukaryotes, e.g. Saccharomyces cerevisiae
• Particularly important in G0/G1
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Homologous recombination
ResectionRad50, Mre11, Xrs2 complex
Strand invasion
Rad52
Rad51; BRCA2
DNA synthesis
Ligation, branch migration, Holliday junction resolution
DSB
Non-homologous end-joining
Ku70, Ku80
Ligation
DSB
DNA-PKcs
Rad50, Mre11, Xrs2 complex “Cleaning up”
of ends
XRCC4/Ligase IV
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DNA-dependent protein kinase (DNA-PK)
DNA-PK
INACTIVE
DNA-PK
ACTIVE KINASE
DNA
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DNA-PK has three subunits
INACTIVE ACTIVE
DNA
Ku70Ku80
Ku70Ku80
DNA-PKcs69 kDa
83 kDa
470 kDa
DNA-PKcs
ATP ADP
X
P
Target sites: Ser/Thr-Gln
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DNA-PK has three subunits
INACTIVE ACTIVE
DNA
Ku70Ku80
Ku70Ku80
DNA-PKcs69 kDa
83 kDa
470 kDa
DNA-PKcs
ATP ADP
X
P
… and is activated by DNA DSBs!
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Multiple potential roles for Ku/DNA-PKcs in NHEJ
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Fig. 20.38
Model for nonhomologous end-joining
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End-joining repair of nonhomologous DNA
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SOS response
• SOS repair occurs when cells are overwhelmed by UV damage - this allows the cell to survive but at the cost of mutagenesis.
• SOS response only triggered when other repair systems are overwhelmed by amount of damage so that unrepaired DNA accumulates in the cell.
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The Error-Prone (SOS) Repair Mechanism
The error-prone repair mechanism involves DNA pol. III and 2 other gene products encoded by umuCD.
The UmuCD proteins are produced in times of dire emergency and instruct DNA pol. III to insert any bases opposite the tymine dimers, as the DNA damage would otherwise be lethal.
The risk of several mutations is worth the risk as measured against threat of death.
How is this SOS repair activated?
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The SOS response
In response to extensive genetic damage there is a regulatory system that co-ordinates the bacterial cell response. This results in the increased expression of >30 genes, involved in DNA repair, these include:recA - activator of SOS response, recombinationsfiA (sulA) - a cell division inhibitor (repair before
replication)umuC, D - an error prone bypass of thymine dimers
(loss of fidelity in DNA replication)uvrA,B,C,D - excision repair
The SOS response is regulated by two key genes: recA & lexA
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SOS
• LexA normally represses about 18 genes• SOS regulon includes lexA (autoregulation),
recA, uvrA, uvrB, uvrC, umuDC, sulA, sulB, and ssb
• sulA and sulB, activated by SOS system, inhibit cell division in order to increase amount of time cell has to repair damage before replication.
• Each gene has SOS box in promoter. LexA binds SOS box to repress expression. However, LexA catalyses its own breakdown when RecA is stimulated by ssDNA.
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SOS
• SOS repair is error-prone. This is why UV is a mutagen. May be due to RecA binding ssDNA in lesions, which could then bind to DNA Pol III complex passing through this area of the DNA and inhibit 3'>5' exonuclease (proofreading) ability. This makes replication faster but also results in more mutations.
• This affect on proofreading seems to involve UmuD'-UmuC complex as well. RecA facilitates proteolytic cleavage of UmuD to form UmuD'. The UmuD'-UmuC complex may bind to the RecA-Pol III complex and promote error-prone replication.
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SOS
• Also allows Pol III to replicate past a T-dimer but introduces many mutations while doing so
• Once damage is repaired, RecA no longer catalyzes cleavage of LexA (which is still being made), so uncleaved LexA accumulates and turns the SOS system off.