Replication

Question 1

Replication

Answer 1

Process of DNA synthesis, occurs during S phase and uses DNA polymerase

Question 2

Protein + nuclear DNA=

Answer 2

chromatin

Question 3

Heterochromatin

Answer 3

Very condensed

Contains very few genes. Late replicating and genetically inactive

Question 4

DNA polymerase needs what to start replicating?

Answer 4

Short stretch of RNA serves as a primer

Question 5

Topoisomerase

Answer 5

Relieves overwound supercoils (called DNA gyrase in bacteria-inhibited by the quinolone family of antibiotics)

Breaks a phosphodiester bond

Question 6

Single-stranded DNA binding protein

Answer 6

Binds the single-stranded DNA that has been separated and keeps it exposed in a single-stranded conformation

Question 7

DNA polymerase α (in complex with primase)

Answer 7

Synthesizes RNA-DNA primer

Primase synthesizes an RNA primer that is 7-10 ribonucleotides long and is extended with 25 nucleotides of DNA by DNA polymerase α. The resulting RNA-DNA primer is complementary to a segment of the parental strand

Question 8

Euchromatin

Answer 8

Less condensed

Question 9

DNA and Histone interaction

Answer 9

• 142 hydrogen bonds formed in each nucleosome
• Hydrophobic interactions
• Salt linkages (lysine/argenine are positive and they neutralize negative charge on DNA)
• Histones are highly conserved

Question 10

Nucleosome

Answer 10

Each nucleosome core particle consists of a complex of 8 histone proteins

Question 11

DNA polymerase requires what to begin replication?

Answer 11

Primer with a free 3’ OH to begin

Question 12

Sliding clamp

Answer 12

Keeps DNA polymerase on DNA when moving; releases when double stranded DNA is encountered

Question 13

Telomerase

Answer 13

Replicates chromosome ends

Special sequence of GGGTTA at end of chromosome

Replenishes these sequences by elongating parental strand in 5’–>3’ direction using an RNA template on the enzyme. DNA polymerase comes in and extends

T-loops: structures protect ends and distinguishes them from broken ones that need to be repaired

Question 14

Telomere

Answer 14

Telomeres are the caps at the end of each strand of DNA that protect our chromosomes, like the plastic tips at the end of shoelaces. Without the coating, shoelaces become frayed until they can no longer do their job, just as without telomeres, DNA strands become damaged and our cells can’t do their job.

Question 15

Stem cells and telomeres

Answer 15

Stem cells retain full telomerase activity

Question 16

Replicative senescence

Answer 16

After many generations, daughter cells will have defective chromosomes and stop dividing; in this way the cell’s lifetime is regulated to guard against cancer

Human fibroblasts (synthesizes the extracellular matrix and collagen) normally divide 60 times before undergoing replicating senescence

Question 17

Dyskeratosis congenita disease

Answer 17

Carry a mutant telomerase RNA gene

• Premature shortening of telomeres
• Die of progressive bone marrow failure

Question 18

We need high fidelity replication rates

Answer 18

Germ cells need it to maintain the species

Somatic cells need it to avoid uncontrolled proliferation/cancer

Question 19

What are the two types of spontaneous DNA damage?

Answer 19

Depurination and Deamination

Question 20

Depurination

Answer 20

The purine base (adenine or guanine) is removed from the nucleotide via hydrolysis of the N-glycosidic bond between the base and the deoxyribose group. This generates an apurinic (AP) or abasic site in the DNA strand

hydrolysis of the N-glycosyl linkage

Repaired beginning with AP endonuclease

Question 21

Deamination

Answer 21

The amino group (NH2) of purine or pyrimidine base is hydrolyzed such that adenine is converted to hypoxanthine, guanine is converted to xanthine, and cytosine is converted to uracil, which forms an unnatural deoxyuridine (NH2–> =O)

C–>U

Hydrolysis of the N-glycosyl linkage

Question 22

Methylated cytosines are problematic

Answer 22

• Occurs at some CpG sequences
• Associated with inactive genes
• Deamination of methyl-C produces T mismatched with G (NH2–> =O)
• A special DNA glycosylase recognizes and removes the T
• Repair is relatively ineffective. Only 3% of C nucleotides are methylated but they account for 1/3 of all point mutations associated with inherited human diseases

Question 23

What does Direct repair (enzymatic repair) fix?

Answer 23

Pyrimidine/thymine dimers via DNA photolyase

O6 methylguanine via Methylguanine methyltransferase

Question 24

What does Base excision repair (BER) fix?

Answer 24

Single-base mismatches, nondistorting alterations (i.e. depurination)

How?

DNA glycolases (each recognizes a specific type of altered base), AP endonuclease (cut phosphodiester backbone, damage is removed and gap is repaired), AP lyase (of DNA polymerase β), DNA polymerase β, DNA ligase

Question 25

What does Nucleotide excision repair (NER) fix?

Answer 25

UV damage (Pyrimidine dimers/thymine)

UV radiation can make a covalent linkage(cross-linking) between two adjacent pyrimidines (T-T or C-T) or thymines

Chemical adducts that distort DNA (i.e. pyrimidine/thymine dimers, BPDE-guanine adducts, cisplatin adducts)

How?

NER protein complex, DNA polymerase Ɛ (epsilon), DNA ligase

Question 26

What disease can be caused by errors in Nucleotide Excision Repair (NER)?

Answer 26

Xeroderma pigmentosum

Question 27

What does Mismatch excision repair (MER) fix?

Answer 27

Mismatched base in daughter strand

How?

MER complex, helicase/endonuclease, DNA polymerase 𝛿,, DNA ligase

• MER complex binds to DNA and recognizes mismatch in daughter strand (MutS binds to mismatch, MutL scans for nick and triggers degredation of nicked strand)
• Daughter strand cut, and segment with mismatch is removed
• DNA polymerase (delta) fills gap
• DNA ligase seals nick

Question 28

What disease can be caused by errors in Mismatch excision repair?

Answer 28

Hereditary nonpolyposis

Colorectal cancers

Question 29

What does Recombination repair fix?

(Nonhomologous end joining (NHEJ)

Homologous recombination

Answer 29

Double-strand breaks, interstrand cross-linking

We have 2 strands so the 1 that is ok can be used as template

Question 30

What happens during Nonhomologous end joining? (part of recombination repair)

Answer 30

Damaged ends filled in and joined; some base pairs may be missing. Multiple proteins and enzymes including DNA ligase

You have a break in each of the strands, so you cut out a chunk that encompasses both cuts, and then join the two strands together (you’ll lose some nucleotides b/c of degradation from ends)

Question 31

What happens during homologous recombination? (part of recombination repair)

Answer 31

Exonucleases, DNA polymerase, MER system (mismatch excision repair). Damaged duplex repair using information on undamaged homologous duplex

Damage is repaired accurately using info from sister chromatid

Question 32

What disease can be caused by problems in the homologous recombination repair mechanism?

Answer 32

BRCA1/2 breast cancer

Question 33

What does Transcription-coupled repair (TCR) fix?

Answer 33

Stalled RNA polymerase during transcription (not replication). Directs repair machinery there

Question 34

What disease can be caused by an error in the Transcription-coupled repair (TCR)?

Answer 34

Cockayne syndrome

• Defect in transcription-coupled repair
• Growth retardation, skeletal abnormalities, sensitivity to sunlight
• RNA polymerase is permanently stalled at sites of damage in important genes

Question 35

What does Translesion synthesis (bypass synthesis) fix?

Answer 35

Unrepaired thymine dimers or apurini AP sites

How?

2 of the reduced-fidelity DNA polymerases (weird greek symbols)

Question 36

Why is RNA not the hereditary information?

Answer 36

It cannot distinguish between deaminated Cytosine and natural Uracil

Question 37

How is BER different from NER? (base excision repair vs nucleotide excision repair)

Answer 37

NER: Can repair any bulky lesion like those chemically induced and thymine dimers

A multienzyme complex scans DNA for distortion in double helix instead of specific base change

Cleaves phosphodiester backbone on both sides; DNA helicase peels lesion-containing strand away

Large gap is repaired by DNA polymerase and ligase

Question 38

Transcription-coupled repair

Answer 38

Cells can preferentially direct DNA repair to sequences that are being actively transcribed by linking RNA polymerase with DNA repair

• Sequences that urgently need repair
• Works with BER, NER and others to repair genes that are being expressed when the damage occurs