DNA Repair

Question 1

Why is DNA repair important?

Answer 1

1 unprepared DSB is sufficient to kill a cell

Defects in repair pathways contribute to tumourigenesis- promote chromosomal translocations

Question 2

What is the difference between mono- and multigenic diseases?

Answer 2

Multigenic- mutations in multiple genes, the combination causes the clinical phenotype
Monogenic- mutations in a single gene that are more severe, and tend to be recessive so they escape selection pressure

Question 3

What is replication stress?

Answer 3

Any process that obstructs DNA replication or interfere with the replication forks
Unresolved replication stress may lead to genetic instability

Question 4

Give specific examples of monogenic diseases in the DNA damage response

Answer 4

Fanconi anaemia- variations on the FANC gene- bone marrow failure, skeletal defects, genome instability, myeloid leukaemia
Seckel syndrome- ATR, ATRIP- growth retardation, dwarfism, microcephaly, mental retardation, genome instability
Ataxia Telangiectasia- ATM- genome instability, T/B cell leukaemia/lymphoma
Ataxia Telangiectasia-like disease- Mre11- neurodegeneration, ataxia, genome instability
Bloom syndrome- BLM- premature ageing, growth retardation, genome instability, leukaemia/lymphoma

Question 5

Describe Seckel1

Answer 5

Seckel syndrome is a group of monogenic inherited disorders
-severe microcephaly, growth retardation, mental retardation, dysmorphic features, skeletal abnormalities
Rare autosomal recessive disorder
ATR kinase or ATRIP
Are functionally related proteins that form part of the DDR
Found at replication forks, are crucial in maintaining genome stability
Defects in phosphorylation if Chk1 and H2AX
Increased numbers of centrosomes
Rapidly proliferating CNS progenitor cells cannot deal with stress without ATR/ATRIP

Question 6

Describe Bloom syndrome

Answer 6

Growth retardation, photosensitivity, Telangiectasia, hypo- and hyper pigmented skin, predisposition to malignancies, chromosomal instability
BLM is a helicase involved in resolving intermediates of DNA repair and removing proteins from DNA
➡️ reflects on replication, genome instability, increased genetic exchNge between chromosomes

Question 7

How would you identify where a disease gene is?

Answer 7

Use genetic markers to analyse inherited regions- linkage
Linkage is the non-random association of traits passed from parents to offspring including restriction enzyme markers and SNPs
Requires at least two generations with affected and unaffected individuals
Genotype using marked and analyse regions conserved between affected individuals and carriers
Evaluate all genes in that region to identify the causative mutation

Question 8

What is the principle behind using linkage when identifying disease genes?

Answer 8

If two sequences are close together they are likely to be inherited together- less likely to split up during recombination
Use restriction sites (trace inheritance of a particular pattern of restriction fragments) SNPs (SNP arrays- anneal to probes- measure fluorescent signal) and microsatellites

Question 9

What are the cyclin and Cyclin dependent kinases involved at the different stages of cell cycle?

Answer 9

G1- Cyclin D1-3
Cdk2,4,5,6
G1-S- Cyclin E 
Cdk2
S- Cyclin A
Cdk2
G2 and M- Cyclin A and B
Cdk2

Question 10

What are cell cycle checkpoints?

Answer 10

A point in eukaryotic cell cycle where progress through the cycle can be halted until conditions are suitable for the cell to proceed to the next stage
They prevent the propagation of deleterious genetic errors

Question 11

Describe the G1-S checkpoint

Answer 11

Prevents entry into S phase and the replication of damaged DNA
Targets G1 phase Cdk activity
Controlled by ATM
DSB➡️MRN➡️ ATM-P➡️
➡️p53-P➡️p21- cdk2 inhibitor
➡️Chk2-P➡️cdc25A-P➡️ degraded so it does not remove the phosphates from Cdk2➡️ cdk2-P inactive

Question 12

Describe the regulation of p53

Answer 12

Normally MDM2, bound to USP7 and inactive p53, targets and ubiquitinates p53 for destruction
If there is a DSB ATM-P inactivates MDM2 and blocks the interaction with USP7, it is ubiquitinated and degraded
ATM also activates Chk2 which activates p53 (WIP1 also removes phosphorylations on p53)
p53 promotes the transcription of p21 but build up of p53 in the cell activates MDM2 in a negative feedback loop

Question 13

Name two important serine residues on p53 for phosphorylation

Answer 13

Serine 15 and 20
Regulated by ATR, ATM, DNA-PK, chk1 and chk2
Decrease interaction with MDM2 increase transcriptional activity

Question 14

Describe the intra-S phase checkpoint

Answer 14

Prevents replication of damaged DNA
Both elongation and late origin firing are inhibited
Target replication associated cdk activity (cdk2/7)
Controlled by ATM/ATR dependent DDR pathway
DSB➡️MRN ➡️ MDC1➡️ ATM-P➡️ chk2-P➡️
Single strand DNA of the replication fork➡️ 9-1-1/TOPBP1➡ ATR/ATRIP-P➡️ chk1-P➡️
➡️cdc25A-P is degraded➡️ cdk2-P prevents exit out of S phase

Question 15

Name some proteins, sites of phosphorylation and associated diseases

Answer 15

ATM- S367, T1885, S1981, S2996- AT
RAD50- S635- NBS-like disorder
BRCA1- S1387- Fanconi anaemia complementarity group S
ATR/ATRIP- T1989 on ATR- Seckel syndrome
Chk1- S317, S345

Question 16

Describe the G2/M phase checkpoint

Answer 16

Prevents entry into mitosis with DNA damage
Targets G2/M phase cdk activity eg. Cyclin B and Cdk2
Controlled by ATM/ATR dependent DDR
Resected DSB (single DNA strand)➡️
9-1-1/TOPBP1 ➡ATR/ATRIP-P ➡️
MRN➡️ MDC1➡️ ATM-P➡️
➡️chk1 and 2-P➡️ cdc25B/C-P➡️ cdk1-P (inactive)
(➡14-3-3 exported from the nucleus)

Question 17

What can replication cause?

Answer 17

Replication forks that are not moving properly can be converted into double strand breaks
Most likely to happen during S phase and also mitosis

Question 18

How are replication forks converted into DSBs?

Answer 18

Stalled forks means that the polymerase on the lagging strand can fall off
Then endonuclease processes it into a one ended DSB by cutting the single strand DNA at the ‘mouth’ of the fork

Question 19

When are regressed replication forks found in normal cell division?

Answer 19

They are holiday junctions that make up chiasmata during recombination in meiosis
Endonuclease normally cuts Holliday junctions and a regressed fork is seen as the same structure and so it is cut

Question 20

Describe the direct/alternative replication fork collapse

Answer 20

Single strand break on the template that is not repaired
Enzyme encounters break and falls off template
SSB transformed into a DSB

Question 21

How are collapsed replication forks dealt with?

Answer 21

DSB➡️ ATM pathway
ssDNA➡️ ATR pathway
Degradation of cdc25A and phosphorylated cdk1, 2 lead to cell cycle arrest
Either homologous recombination or apoptosis

Question 22

Describe homologous recombination of a one ended DSB

Answer 22

A 3’ over hang is required EXO1, Mre11 and BRCA1
Rad51 and BRCA2 finds the homologous sequence in the sister chromatid strand
Forms a D-loop
HJ resolution by HJ resolvases (GEN1, MUS81/EME1, SLX1/SLX4)
Re-establishes the replication fork

Question 23

How would you target homologous recombination for cancer therapy?

Answer 23

Familial cancers with mutation in enzymes such as BRCA1,2 and FANCN,J have a HR defect
Tumours are sensitive to PARP1 inhibitors (SSB repair enzyme) normal somatic cells still have one wild type copy
Cancer cells die of unrelated spontaneous SSBs

Question 24

What is the significance of oncogenes in replication stress?

Answer 24

Oncogenes slow down replication forks- spontaneous replication stress demonstrated by cancer cells- eventually the cell will go into mitosis with replication unfinished- anaphase bridge between chromatids
Leading to genomic instability, fragmentation and other damage

Question 25

How would you target endogenous replication stress for cancer therapy?

Answer 25

ATR inhibitors- ATR is a principle mediator of the G2/M cell cycle checkpoint
It prevents premature entry into mitosis with incomplete replication or DNA damage
When inhibited the cell will eventually go into mitosis unfinished and this will lead to mitotic catastrophe and apoptoisis

Question 26

Describe non-homologous end joining

Answer 26

Does not require homologous template and can occur at any phase of cell cycle
Mostly accurate but small deletions can occur at the site of the DSB
Essential for cell viability
Required for immune system development
Ku70/Ku80 is recruited to the break and recruits PAXX which forms a molecular bridge between the ends
The bridge complex recruits DNA-PK and Artemis processes the ends so they can be ligated
DNA ligase4 and XRCC4 form a ligation complex and stably recruits DNA polymerase with Ku

Question 27

Describe alternative DNA end joining

Answer 27

If Ku cannot be recruited then Mre11 will recognise the complex which looks for microhomology, recruits CtIP and exo1 processes ends to the microhomology
Flap removal can mean that a significant amount of DNA is lost
Extremely error prone and has been linked to the formation of chromosomal translocations

Question 28

Describe homologous recombination

Answer 28

Requires homologous template so can only occur during S phase
Very accurate
Mre11 recruits CtlP which promotes DNA resection by Exo1 and Dna2
53BP1 complex limits resection
RPA is a ssDNA binding protein that recruits RAD51 that recruits BRCA1, BRCA2, PALB2
RAD51 searches for the homologous sequence and DNA pol uses that as a template
The Holliday junction can be resolved by the BLM complex so there is no cross over or by a structure-specific nuclease complex that cuts the junctions and can give cross over or no crossover

Question 29

Name the protein that repairs DNA using NHEJ

Answer 29

Ku70/Ku80 heterodimer

Question 30

How does the MRN complex repair DSB?

Answer 30

Homologous recombination

Question 31

Describe how Ku binds to a DSB

Answer 31

Does not require a homologous template
Can occur at any phase in the cell cycle
Accurate but small deletions can occur
Essential for cell viability
Required for immune system maturation
Ku is shapers like a clamp and slides onto the broken ends of the DNA which are then tethered together by PAXX molecules that interact with both Kus and each other
Ku binds and activates DNA-PK which transphosphorylate each other and phosphorylates H2AX

Question 32

How does the MRN complex bind to a DSB?

Answer 32

Involved in 15-20% of DSB repairs in S and G2 phase
Extremely accurate
A MNR complex binds to each side and binds together through Mre11 and Rad50 dimers to hold the DNA together
ATM molecules at brought to the site and in close enough proximity to each other to transphosphorylate each other and phosphorylate H2AX which binds a phosphorylated MDC1 which binds NBS1
PARP1 binds to NDS1 and Mre11 complex

Question 33

Which factors affect the method of DNA DSB repair and how?

Answer 33

High cdk activity has a positive effect on MRN dependent repair
-phosphorylates CtIP which binds to NBS1
- suppresses Ku activity along with ATM
Euchromatin is more permissive to Ku repair
Heterochromatin can only be repaired by the ATM/MRN complex
MRN can fix ‘dirty’ breaks that Ku cannot