L6 Damage Repair and Recombination

Question 1

What four ways can damage occur to DNA

Answer 1

Deamination
Depurination
Pyrimidine Dimer Formation
DNA breaks

Question 2

What three types of chemical reactions would cause DNA damage

Answer 2

Oxidation, hydrolysis and methylation

Question 3

What way would oxidation damage the DNA

Answer 3

At C=C double bonds (gain of oxygen or loss of hydrogen)

Question 4

How would a hydrolysis reaction damage the DNA

Answer 4

Splitting a bond using water - can liberate from amino (NH2 groups)

Question 5

Describe how methylation would damage the DNA

Answer 5

Nitrogen (N) can be methylated to NH2 sponatenously on any of the four nucleotides

Question 6

What bases are purines

Answer 6

A or G

Question 7

What bases are pyrimidines

Answer 7

C or T

Question 8

Describe how a depurination occurs

Answer 8

Nitrogenous base removed from the deoxyribose sugar - using water

Question 9

Describe how deamination occurs

Answer 9

Change from cytosine to uracil (will pair with A)

Uses water and releases ammonia

Question 10

Describe how depurination can cause mutation

Answer 10

Nucleotide is missing therefore there is a deletion in one of the strands

Question 11

Describe how deamination can cause mutation

Answer 11

C–>U so now pairs with A, point mutation of a base pair in a strand

Question 12

Describe how a deamination may be repaired

Answer 12

By base excision repair

Question 13

What is the enzyme involved in base excision repair which recognises the damage

Answer 13

Uracil DNA glycosylase

Question 14

In base excision repair what is the sugar removed with

Answer 14

Apurinic/apyrimidinic endonucleases

Question 15

In base excision repair what is the phosphate removed using

Answer 15

Phosphodiesterase

Question 16

In base excision repair the removal of the sugar and phosphate causes –>

Answer 16

Formation of primer:template junction –> act of DNA polymerase
Nick is the sealed using DNA ligase

Question 17

What occurs during pyrimidine dimer formation

Answer 17

When two adjacent pyrimidines are able to form a covalent linkage

Question 18

What does pyrimidine dimer formation lead to

Answer 18

Arrest of DNA replication
Misreading by polymerases
Unable to complementary base pair with purines

Question 19

Describe the process of nucleotide excision repair

Answer 19

Excision nucleases cleave the single strnaded DNA with the defect
DNA helicase removes the damaged segment
Formation of primer template junction leads to activation of DNA polymerase then the nick is sealed by DNA ligase

Question 20

What disease is as a result of nucleotide excision repair deffects

Answer 20

Xeroderma Pigmentosum

Question 21

What are the 7 xeroderma pigmentosum genes

Answer 21

XPA XPC XPD XPF XPG

Question 22

What do the xeroderma pigementosum genes all encode

Answer 22

Proteins which are involved with nucelotide excision repair

Question 23

What are the E.coli homologues of the xeroderma pigmentosum genes

Answer 23

UvrA UvrB UvrC UvrD

Question 24

What is nucelotide excision repair targetted to

Why is this the case

Answer 24

DNA sequences which are being actively transcribed

By the physical coupling of RNA polymerase to the repair mechanisms

Question 25

Why are ds breaks dnagerous

Answer 25

Mean that large fragments of chromosomes can be lost

Question 26

What are the two methods of repairing a double strand break

Answer 26

Non-homologous end joining

Homologous recombination

Question 27

Why is non homologous end joining not be the ideal way to repair DNA

Answer 27

No specificity - so likely to cause mutation

Can cause deletions

Question 28

Describe the process of non homologous end joining

Answer 28

Accidental double stranded breaks
Loss of nucleotides due to degredation
End joining gives a deletion mutation

Question 29

Describe the process of homologous recombination

Answer 29

Double stranded break
Resection at the 5’ end so can be used as a template and anneal with the undamaged chromosome
Binding protein RecA promotes strand invasion of the undamaged template by one strand from a damaged DNA molecule that acts as a primer
Formation of heteroduplex facilitates templated synthesis of the one stand
Newly synthesised strand from its template and reaneals to partner strand - 2nd strand synthesis and two nicks sealed by ligation

Question 30

What are BRCA2, ATM and Fanconi Anaemia all examples of

Answer 30

Genes involved in homologous recombination

Question 31

What are BRCA2 mutations associated with

Answer 31

Breast, ovarian and prostate cancer

Question 32

What are ATM mutations associated with

Answer 32

Ataxia telangiectasia - leukameia and lymphoma

Question 33

What occurs once homologous recombination is inneffective

Answer 33

The cell becomes critically dependent on other mechanisms of repair

Question 34

If a cell that has a mutation in the genes involved in homologous recombination is then treated with an inhibitor for base excision repair
What is the clinical relevance of this

Answer 34

Too much DNA damage and the cell will die - synthetically lethal
Can be used to treat cancer

Question 35

What drugs are specific inhibitors of poly ADP ribose

Answer 35

Olaparib and lumpaza

Question 36

What does homologous recombination machinery mediate

Answer 36

Genetic recombination in meiotic cells

Question 37

What is the function of SPO11 in homologous recombination

Answer 37

Makes the initial clevage

Question 38

What is the function of Mre11 in homologous recombination

Answer 38

Resection at the 5’ end

Question 39

What does RecA mediate

Answer 39

Strand invasion

Question 40

What does homologous recombination result in

Answer 40

Formation of the double holliday junction

Question 41

What is the resolution of the double holliday junction if only internal strands are broken and rejoined

Answer 41

Then no recombination

Question 42

What is the resolution of the double holliday junction if both internal and external strands are cut

Answer 42

Recombinattion

Question 43

Recall the purine bases

Answer 43

Adenine, guanine

Question 44

Recall the pyrimidine bases

Answer 44

Thymine, cytosine, uracil

Question 45

What are the four main types of DNA damage

Answer 45

Deamination, depuration, pyrimidine dimers, DNA breaks

Question 46

What are the three main methods of DNA repair

Answer 46

Base excision repair, nucleotide excision repair, homologous recombination

Question 47

What chemical modifications can lead to DNA damage

Answer 47

Hydrolysis, oxidation or random uncontrolled methylation

Question 48

What is the most frequency types of DNA damage

Answer 48

Hydrolytic depurination and deamination of bases

Question 49

What happens when cytosine is deaminated and what are the downstream effects of this

Answer 49

Converted to uracil. This will still pair with guanine but during replication the guanine will be replaced with an adenine, leading to a nucleotide substitution from CG–>TA

Question 50

Explain how deamination of cytosine is achieved

Answer 50

The NH2 group attached to the purine ring of cytosine at position 4 is replaced with a carbonyl group

Question 51

Explain the process of depurination

Answer 51

The carbon to nitrogen bond between the carbon position one in the deoxyribose sugar and the nitrogen in the purine ring is hydrolysed. This releases the base and results in the loss of a base pair, nucleotide deletion, in one of the daughter DNA molecules produced during replication

Question 52

Which DNA damage(s) is base excision repair used for

Answer 52

Deamination and depurination

Question 53

Explain the process of DNA excision repair

Answer 53

The damage base is first removed by DNA glycosylase which cleaves off the inappropriate base(s). The deoxyribose sugar is then removed by an enzyme known as apurinic/apyrimidinic endonuclease. Lastly the phosphate is removed by the phosphodiesterase enzyme. This leads to a ssDNA break in the polynucleotide chain. This gap is then recognised by DNA polymerase which then extends over this gap which acts as a primer template junction. Finally, DNA ligase uses ATP hydrolysis to provide the energy required to seal the nick

Question 54

What are pyrimidine dimers and what causes them

Answer 54

Pyrimidine dimers are caused by the covalent linkage of benzene rings in two adjacent pyrimidine bases. This is usually caused by UV light

Question 55

Which base is primarily affected by UV light and more prone to form dimers

Answer 55

Thymine

Question 56

What is the results of the formation of pyrimidine dimers

Answer 56

This arrests DNA replication or can cause mis-reading of the DNA sequence by DNA polymerase

Question 57

Nucleotide excision repair is only used to repair pyrimidine dimers, T or F

Answer 57

F – it is used to repair a variety of different types of DNA damage including pyrimidine dimers

Question 58

Pyrimidine dimers can only occur between identical adjacent pyrimidine bases, T or F

Answer 58

F – it can be the same pyrimidine or different ones (i.e. T-C, T-T, C-C)

Question 59

Explain the process of nucleotide excision repair

Answer 59

An excision endonuclease enzyme cleaves the single strand of the DNA containing the defect by cleaving either side of the dimer etc. This creates a polynucleotide fragment from the DNA molecule that contains the defect which is then removed by DNA helicase. DNA polymerase then extends the primer template junction created to replace the excised sequence. This is followed by resealing of the nick mediated by DNA ligase.

Question 60

Xeroderma pigmentosum is a disease caused by defective nucleotide excision repair machinery, what is the effect of this on patients

Answer 60

XP renders patients extremely sensitive to sunlight-induced skin cancer

Question 61

How many different genes have been identified as being responsible for xeroderma pigmentosum, give some examples

Answer 61

7 different genes including XPA, XPC, XPD, XPF and XPG

Question 62

What are the products of genes encoded by the genes mutated in xeroderma pigmentosum

Answer 62

These genes encode proteins that participate in the nucleotide excision repair pathway

Question 63

What is significant about the function of the XP genes

Answer 63

Their function is tightly coupled and targeted to regions of the genome that are highly transcribed. This acts as a surveillance system to signify regions of the genome that are transcribed. RNA polymerase required for transcription is physically coupled to the DNA repair machinery

Question 64

Uvr genes are homologues of the XP genes found in yeast and are also transcription coupled, T or F

Answer 64

T

Question 65

dsDNA breaks are often caused by non-ionising radiation, T or F

Answer 65

F – they are caused by ionising radiation

Question 66

Why are dsDNA breaks especially dangerous

Answer 66

Large fragments of chromosomes can be lost

Question 67

What two methods are there of repairing dsDNA breaks

Answer 67

Non-homologous end joining, homologous recombination

Question 68

What can make DNA molecules susceptible to dsDNA breaks

Answer 68

If the DNA has already suffered a ssDNA break due to base excision repair or nucleotide excision repair. This may weaken the DNA structure

Question 69

What is meant when we refer to non-homologous end joining being quick and dirty

Answer 69

Non-homologous end joining is a far from optimal repair mechanism. It is carried out quickly but in itself, can induce mutations

Question 70

Explain the process of non-homologous end joining

Answer 70

The ends of the double stranded break are rendered flush with loss of bases via degradation from the ends of the strands. These flush ends are then ligated together. However, this leads to a loss of DNA sequence due to the degradation that occurs prior to ligation.

Question 71

Homologous recombination also isn’t a perfect repair mechanism, T or F

Answer 71

F – homologous recombination provides a perfect repair of dsDNA breaks and is an accurate and preferred method of repair

Question 72

What does homologous recombination rely on

Answer 72

Using the intact DNA sequence information in the undamaged homologous chromosome

Question 73

Explain how homologous recombination is mediated

Answer 73

Firstly, the 5’ ends are resected by exonuclease to create single strands that can be used to prime DNA synthesis when annealed to a template strand from the complimentary chromosome. The DNA-binding protein RecA promotes strand invasion of the undamaged template molecule by one strand from the damaged DNA molecule that acts as a primer. This forces complimentary binding with the same sequence in the undamaged sister chromatid. This forms a heteroduplex structure between the dsDNA helix of the sister chromatid and the single stranded sequence from the damage DNA molecule. This facilitates templated DNA synthesis of one strand by DNA polymerase. DNA polymerase synthesises across the damaged region by reading information out of the undamaged sister chromatid. The newly synthesised DNA then dissociates from its template and re-anneals to its original partner strand allowing second strand synthesis and formation of a pair of staggered singles stranded nicks. These nicks are then ligated by DNA ligase

Question 74

Give an example of a gene involved in homologous recombination that when mutated can cause cancer

Answer 74

BCRA2 – causing breast, ovarian and prostate cancer

Question 75

What happens in patients with mutations in genes needed for homologous recombination

Answer 75

Homologous recombination is defective and thus these cells become critically dependant on other pathways for correct DNA repair i.e. base excision and nucleotide excision repair

Question 76

How can this defective recombination pathway seen in some cancers be harnessed as a cancer treatment

Answer 76

Combined inactivation of homologous recombination by mutations and the inhibition of base or nucleotide excision repair by anticancer drugs make cells that suffer DNA damage unable to make adequate repairs to their DNA and die. This is known as synthetic lethality.

Question 77

Homologous recombination is required to mediate genetic recombination and diversity created in meiosis, T or F

Answer 77

T

Question 78

Explain how a Double Holliday Junction is created during genetic recombination in meiosis

Answer 78

Two chromatids exist with different alleles for two genes (AB and ab). Spo11 endonuclease makes an initial cleavage in chromatid to create a dsDNA break. Mre11 then carries out a 5’ resection to create a targeted dsDNA break with a 3’ overhang in the DNA molecule. RecA then mediates strand invasion by this strand on the other chromosome creating a heterocomplex/triple helix structure. DNA polymerase then synthesises across the gap between the end of the 3’ overhang from the invading strand and the 3’ end of the other chromosome. The 3’ end is then relegated with the original strand to create a double holliday junction whereby the invading strand from one helix is forced into interactions with the complimentary strand in the helix of the other chromatid and vice versa.

Question 79

How many ways can the Double Holliday Junction be resolved

Answer 79

2

Question 80

Explain how different resolutions of the Double Holliday Junction account for whether homologous recombination occurs or not

Answer 80

If the internal strands are broken and re-joined than the same DNA strands are broken and re-joined at each junction and recombination is not achieved as each chromatid will contain the same sequence of alleles it did prior to cleavage. If external and internal strands are broken and re-joined then different DNA strands are broken and re-joined at each junction. Hence recombination is achieved. This recombination of allelic forms results in chromatids with different combinations of alleles (Ab and aB)