DNA Repair

Question 1

What is DNA Damage?

Answer 1

DNA is damaged thousands of times per cell per day

• due to many factors
  
  • including basic chemistry of the nucleic acids
  • external things like UV light, chemicals, radiation, pH, smoking, etc.

Allowing such cells to replicate is “bad”

Question 2

State the short term consequences of DNA damage?

Answer 2

1. Reduced proliferation
2. Altered gene expression
3. Cell death (apoptosis)

Question 3

What are the long term consequences of DNA damage?

Answer 3

• aging

- diseases especially cancer

Question 4

Is p53 a caretaker or gatekeeper?

Answer 4

p53 is the cellular gatekeeper for growth and division.

Question 5

What is the importance of DNA repair?

Answer 5

DNA damage is common

Normal metabolism causes about 10^4 DNA adducts/cell/day through generation of endogenous oxidants (e.g. hydrogen peroxide, suoeroxxude etc.)

It can be recognized and efficiently repaired BUT,

Trying to replicate through it can convert DNA damage into mutations

Important to distinguish between DNA damage and DNA mutation

Question 6

What is the molecular basis of mutation?

Answer 6

Mutations can be spontaneous or induced

Induced mutations are in addition to the rate of spontaneous mutation

There are two classes 9f spontaneous mutation- errrors of replication & spontaneous lesions

Question 7

Differentiate the two types of spontaneous mutations?

Answer 7

1. Errors of replication= mistakes made during replication
   - only occurs during S phase of cell division
2. Spontaneous lesions- chemical changes that occur spontaneously
   - Occurs in resting cell

Question 8

Explain errors of replication. What is tautomerism?

Answer 8

Errors of replication- wring base is incorporated by DNA polymerase
-due to chemistry of the nucleotides

Tautomerism= the ability of certain chemicals to exist as a mixture of two interconvertable isomers

Thymine usually pairs A, the rare enolase form now pairs with G

Question 9

Explain proofreading

Answer 9

Replication is very accurate but errors occur

DNA polymerase error rate= 1/100,000 bases

Actual error rate = 1 in 10,000,000

DNA Pol. enzyme has 5’ to 3’ polymerase activity AND 3’ to 5’ exonuclease activity

Also there are other repair systems that can detect and repair errors

Question 10

What causes bloom syndrome?

Answer 10

Defect in a gene encoding a DNA helicase enzyme

-Required for replication repair, recombination

Question 11

What are the characterist8cs if Bloom syndrome?

Answer 11

• smaller than average
• marrow chin, prominent nose and ears
• Fac8al rash (pigment and dilated blood vessels) upon exposure to sun (sometimes called a ‘butterfly’ rash
• often get diabetes and have neurological, lung and immune system deficiencies
• Chromosomal instability resulting in many chromosomal breaks and sister chromatid exchanges
• Higher risk of a broad range of cancer types

Increased sister chromatid exchange in bloom syndromes

Question 12

Explain spontaneous lesions

Answer 12

Changes that occur in a resting cell due to the chemical nature of the DNA

Extremely common= tens of thousands of mutation events per cell per day

Exposure to mutagens such as sunlight, radioactivity, ionizing, radiation, specific chemicals may increase the rate of this type of DNA damage

Three main types of spontaneous DNA damage:

• depurination
• deamination
• oxidative damage

Question 13

Explain depurination as a form of spontaneous lesions

Answer 13

Most common form of spontaneous lesions (about 10,000 each day/cell (about 1 in every 10 seconds)

Breaking of glycosidic bond between base and sugar in purine nucleotides

Sugar-phosphate backbone remains but base is lost

If it persists through replication then mutation can occur

Question 14

Explain deamination as a type of spontaneous lesions

Answer 14

Very common about 5000 a day

Loss of amine group from a base (we can use cytosine as an example)

-cytosine (which base pairs with G) deaminates to form uracil (Uracul would pair with A)

This one is easy to fix- uracul doesn’t belong in dna

Question 15

Why is 5-methyl cytosine a mutational hotspot?

Answer 15

5-methyl cytosine deaminates to form thymine, so this creates a T-G base pair
-Both of these bases are normally found in DNA; could be repaired back to a “C” (correct pair) or create a mutation “T”

So, repair machinery must guess

Question 16

Why are methyl cytosine found in mutational hotspots?

Answer 16

Found in CpG islands as discussed in epigenetics

Not all positions are equally mutable, hotspots include things like 5-methyl cytosine or repeated baddd (AAAAA)

The point is that you can see the same mutation occurring at a relatively high frequency in specific pl@ces in the genome

Question 17

Explain oxidative damage as a type of spontaneous lesion

Answer 17

A result of reactive oxidative compounds due to oxidative metabolism
-superoxides, peroxide’s etc.

Causes oxidative damage to many parts of cell including addition of oxygen groups to nucleotide bases
An example would be 8-oxo-7-hydroxyguanosine

Thus is oxidized to G will mispair with A and cause a potential TRANSVERSE MUTATION

Question 18

What are mutagens?

Answer 18

These increase frequency 9f normal functions

Question 19

What are common mutagens in our environment?

Answer 19

Serious

• uv (from sun. Or tanning beds)
• ionizing radiation
• aflatoxin (from moldy grain)
• benzene
• formaldehyde
• mustard gas
• anything that reacts with dna

Not serious:
Alcohol(aldehyde, break down product)
-bbq hamburgers(benzoapyrene)

Question 20

Explain ionizing radiation

Answer 20

Include cosmic radiation, y-rays,x-rays, and radioactive particles (a,B,Y)

Relevant. To clinician and research scientists

But also relevant to everyone as we encounter a surprisingly large amount of radiation

• high energy particles or rays can cause many types of cellular damage up to and including death
• also causes extensive damage to DNA (base damaging type) including heritable mutations

Question 21

Explain uv light as a mutagen

Answer 21

Generates several deleterious photo products

Such as cyclobutane pyrimidine dimers or 6-4 photo products

• covalent linkages. Between adjacent pyrimidine bases on the same strand
• these dimers will interfere with normal base pairing and block replication

These are known as pyrimidine dimers, or thymine dimers

Question 22

What are the common repair mechanisms?

Answer 22

Most are indirect

Main mechanisms-but not intended to be comprehensive

Nucleotide excision

• removes more than a few (up to 30) base around a damaged site
• This is how pyrimidine dimers formed by UV damage are repaired

Base excision
-repairs a single (or just a few) damaged bases by removing it (damage by methylation, oxidation etc)

Mismatch repair(post replication repair)

• repairs mismatched bases
• that formed due to tautorism

Question 23

Explain the excision repair mechanism

Answer 23

Mechanism is essentially the same fir all excision repair, just the size of the excised region varies

Involves:

Recognition of damage

Removal of damaged base or region around damaged base

The above 2 require specific. Repair proteins

Replacement

Question 24

How does excision repair occur?

Answer 24

1. Recognition of damage
2. Recruit endonucleases
3. Region excised
4. DNA polymerase fills in gap
5. Ligase seal nick

Question 25

Explain the cause of Xeroderma pigmentosum

Answer 25

Autosomal recessive, biallelic pathogenic mutations in 9 different NER genes can lead to XP

So 9 complementation groups

Locus heterogeneity because there are many genes involved in the NER pathway

• XPA, ERCC3(XPB), XPC,ERCC2(XPD), DDB2(XPE), ERCC4(XPF), ERCC5(XPG), ERCC1, and POLH(XP-V)
• Recognize that XP is the common gene name for NER pathway components; other names don’t need to be memorized)

Question 26

What is the incidence of XP?

Answer 26

Incidence:
- Europe-USA: 1:250,000

-Japan: 1:40,000=extreme sun sensitivity

Question 27

What are the clinical features of Xeroderma pigmentosum ?

Answer 27

Clinical sun sensitivity

=sunburn, blistering, freckled with hyper pigmented skin lesions

Ocular involvement

-conjunctivitis, ocular tumors

Over 1000-fold increase in skin cancer including melanomas

• 20% have progressive neurologic degernation
• DNA Damage is cumulative and of course, irreversible

Question 28

What is base excision repair?

Answer 28

Base nucleotides can be removed by DNA glycosylases which recognize specific damaged bases in DNA

Uracil glycosolase as a specific example for removal of U from DNA

Aberrant dna base removed by glycosylated, then sugar phosphate removed by endonuclease then base is replaced and ligated

There are different types of DNA glycosylases which are specific for different aberrant bases

Question 29

What is mismatch repair?

Answer 29

Post replication repair mechanism

A form of excision repair (same basic mechanism, just different proteins involved)

Mismatched bases are recognized and excised

Also very important in relation to removing small repeats that tend to expand (e.g, triplet expansion disorders)

Question 30

What are the steps in mismatch repair (a type of excision repair)?

Answer 30

Shows strand discrimination

1. Mismatch missed by proofreading is recognized by MSH proteins
2. Repair may occur during S-phase (if missed by proof-reading) or in G2 when genome is scanned for errors
3. Excision of bases around mismatch
4. Repair by re-synthesis
   Many genes function in this pathway such as MSH2/6, MLH1-3, PMS2 + Several more

(It is enough that the MSH genes are the founding members =miss-match)

Question 31

How does the cell know which is. The right strand in mismatch repair?

Answer 31

In prokaryotes it has been shown that hemimethylated strands are recognized. The methylatedstrand is the original and the unmethylated strand is the new one

In eukaryotes it may be more complex (of course). And interaction with replication machinery occurs but it also involves discernment of methylated/unmethylated DNA strands

Question 32

What are frameshift mutations?

Answer 32

Tend to occur where there base repeats

• thought to result from slipping of DNA polymerase during replication of these repeats
• DNA loops or kinks at these points and one or more bases aren’t copied or are copied twice

Question 33

Explain hereditary nonpolyposis for colon cancer

Answer 33

Autosomal dominant

• a result of mutations in genes encoding mis,at h repair proteins MSH2*, PMS1, PMS2, or MSH
• results in Microsatellites instability

Microsatellite instability frequently seen with these tumors= simple repetitive DNA tandem repeat sequences show size variability due to inaccurate replication

SSR

Question 34

What are double stranded breaks?

Answer 34

A difficult type of mutation repair DSBs are particularly dangerous to dividing cells; high probability of loss of genet8c material of chromosomal rearrangements

Question 35

What two mechanisms are used to f8x FNA double stranded breaks?

Answer 35

1. Non-homologous end joining
   - the more common method used
   - doesn’t use homologous chromosome to repair the break
2. Recombination all repair
   - doesn’t use homologous chromosome
   - less error prone than NHEJ

Question 36

Explain the effect of BRCA1 & BRCA2

Answer 36

Autosomal dominant breast cancer predisposition syndrome

Found in cells of breast and other tissue

-involved in DNA repair or apoptosis when DNA can’t be repaired

Women with BRCA1 or BRCA2 mutations have 85% risk 9f developing breast cancer by age 70

• And the risk of developing ovarian cancer is about 55% for BRCA1 and 25% for BRCA2 mutations
• this cancer risk increases as the person ages
• these are two different genes, so locus heterogeneity

Many hundreds of pathogenic variants have been identified in the BRCA1 gene, most associated with an increased risk of cancer (allelic heterogeneity)

Question 37

Contrast somatic and germline errors

Answer 37

Somatic errors- can result in cancer

• does result in aging
• bad for you

Germline- can result in genetic disease visited on your descendants - bad for kids

It is thought that in gametes, one mutation every 10^8 nucleotides replicated, or about 60 mutations occur in every cell generation.

Question 38

What are the consequences to mutations in DNA repair?

Answer 38

1. Increased error rate
   - Particularly true for proofreading and mismatch repair (MMR), producing “mutator” phenotype

-Damaged bases aren’t repaired efficiently

2. Genomic instability
   - mutations in gene involved in resting DNA repair and chromosome break repair will de-stabilize the genome e.g. Bloom syndrome, XP, many others

Question 39

What is ataxia telangiectasia?

Answer 39

Defect is in ATM gene (11q22-23)
= a serine-threonine protein kinase with a number of functions including:

• detecting DNA damage (I.e. it is a sensor) and activating cell cycle arrest and DNA repair proteins(e.g. p53)
• autosomal recessive
• rare disease(incidence estimated to be 1:50,000)
• increased cancer risk (should avoid x-rays) affects cerebellum(=ataxia) and immune system
• ocular telaangiectasia common

Question 40

DNA repair components…

Answer 40

All interact with each other