TMC5

Question 1

What is the difference between G1, G0, S, G2 and M phases of the cell cycle?

Answer 1

G0 - Non-dividing state
G1 - Cell grows and prepares for cell division, checks previous cycle was completed correctly and cell cycle checkpoints, cell arrests if checkpoints aren’t met
S - DNA replication phase
G2 - Cell prepares for mitosis by growing, producing proteins, increased organelles
M - mitosis and cell division

Question 2

What is an origin of replication?

Answer 2

The points on DNA where replication begins

Question 3

What is the difference between NTPs and dNTPs?

Answer 3

NTPs - precursors of RNA
dNTPs - precursors of DNA

Question 4

List the items required by DNA polymerase for DNA synthesis

Answer 4

dNTPs
Primers
Template strand

Question 5

What are the differences between RNA polymerase and DNA polymerase?

Answer 5

RNA polymerase:
De novo
Produces a single strand
DNA:
Not de novo
Produces a double strand

Question 6

What is a primer in DNA synthesis?

Answer 6

The start point of DNA synthesis by DNA polymerase, synthesises from the 3’ end of an existing piece of RNA/DNA (primer)

Question 7

Explain how DNA polymerase synthesises a new strand of DNA.

Answer 7

Uses one strand of DNA as a template
Synthesises DNA onto the 3’ end of a primer
Attaches a dNTP onto the 3’ OH group of a deoxyribose (5’ to 3’)
Extends a primer annealed to a template
Catalyses the formation of a phosphodiester bond
High energy dNTP is consumed in the reaction releasing pyrophosphate

Question 8

What is the direction of DNA synthesis?

Answer 8

5’ to 3’

Question 9

Describe the properties of DNA polymerase.

Answer 9

Purified DNA polymerase can replicate DNA in vitro
Error rate is 1 in 100,000
Proofreading carried out by a 3’-5’ exonuclease activity
Needs a primer

Question 10

What is the basic DNA polymerase error rate?

Answer 10

1 in 100,000

Question 11

Describe proof reading by DNA polymerase.

Answer 11

Decreases error rate in DNA synthesis by 100 fold
Carried out by a 3’ to 5’ exonuclease activity in DNA polymerase (digests DNA 3’ and moves toward 5’)
Nucleotide misincorporated during DNA replication
Immediately slows down polymerisation by DNA pol by 10,000 fold
Increases the 3’ to 5’ exonuclease activity

Question 12

Describe mismatch repair

Answer 12

About 1% of the time, a misincorporated nucleotide is not excised by proofreading and remains in DNA creating a mismatch base pair
Corrects mismatched base pair
Mismatch repair system must be able to discriminate between the old strand of DNA and the newly synthesised DNA so that it can remove the mismatched base from the new strand

Question 13

Explain the differences between DNA polymerase proof reading and mismatch repair.

Answer 13

Proofreading by the DNA polymerase during DNA synthesis reduces error by about 100 fold.
Mismatch repair (MMR) repair occurs after DNA synthesis and reduces error by another 100 fold.

Question 14

What is HNPCC and what are the characteristics of HNPCC?

Answer 14

Hereditary Nonpolyposis Colorectal Cancer
Defects in mismatch repair system
Cancer of colon and rectum
Increased risk of cancers of GI tract and endometrium
3 relatives over 2 generations with colorectal cancer, 2 must be first degree relatives, 1 must be under 50, FAP must be excluded

Question 15

What is the genetic basis of HNPCC?

Answer 15

Mutations in any of the mismatch repair genes for the proteins that recognise different forms of mismatched base pairs in DNA cause HNPCC
MLH1, MSH2, MSH6, MSH3, PMS1, PMS2

Question 16

Explain how DNA replication is initiated.

Answer 16

Recognition:
Complex of proteins binds the origin of replication - key one being DnaA
ORC binds to ori in eukaryotes
Melting:
Proteins at ori recruit proteins and melts DNA at ori
Unwinding:
Helicases unwind DNA and cause a replication bubble at ori
Single stranded binding protein binds to the single stranded DNA and keep it single stranded so that replication can proceed
Recruitment:
Proteins assembled at ori must recruit DNA polymerase
Primer synthesis:
RNA primer is synthesised at ori by DNA primase
Supercoiling builds up at edges of opening
Supercoiling relieved by topoisomerases I and II in humans and DNA gyrase in prokaryotes
DNA polymerase then starts synthesising

Question 17

List the proteins involved in initiating DNA synthesis and each of their functions.

Answer 17

DnaA binds at ori
ORC binds at ori in eukaryotes
ORC recruited proteins melt DNA
Helicases unwind DNA and cause replication at bubble
Single stranded binding protein binds to the single stranded DNA and keep it single stranded so that replication can proceed
RNA primer is synthesised by DNA primase
Topoisomerase relieves supercoiling
DNA gyrase relieves supercoiling in prokaryotes
DNA polymerase synthesises DNA

Question 18

Explain leading and lagging strand DNA synthesis.

Answer 18

Leading strand is the DNA synthesised from the RNA primer that can continue all the way to the end of the DNA molecule
Two replication forks one travelling right and the other left
DNA replication occurs on both template strands at the same time in the same direction
5’-3’ action on one of the strands is achieved by Okasaki fragments on one strand being joined up to allow overall progress in a 3’-5’ direction
Okasaki fragments are started from a RNA primer
Sealed by DNA ligase after DNA polymerase removes primers
DNA pol I binds to 3’ of Okaskai fragment and extends fragment by synthesising new DNA til it meets a primer
DNA pol I has 5’ to 3’ exonuclease activity
DNA pol I then dissociates after primer is degraded leaving a nick which is sealed by DNA ligase
In humans, primer is removed by Fen-1 and RNAseH and the gap is closed by DNA polymerase

Question 19

What is the function of DNA polymerase I in E. Coli?

Answer 19

Proofreading, primer removal

Question 20

What is the function of DNA polymerase III in E. Coli?

Answer 20

Lagging strand synthesis
Leading strand synthesis
Proofreading

Question 21

What is the function of DNA helicase in E. Coli?

Answer 21

Unwinds DNA from helix

Question 22

What is the function of DNA ligase in E. Coli?

Answer 22

Seals nicks in DNA

Question 23

What is the function of DNA primase in E. Coli

Answer 23

Primer synthesis

Question 24

What is the function of DNA topoisomerase?

Answer 24

Relieves supercoiling in front of replication fork

Question 25

What is the function of DNA gyrase in E. Coli?

Answer 25

Relieves supercoiling

Question 26

What unwinds DNA in humans?

Answer 26

ORC / DNA helicase

Question 27

What synthesises primers in humans?

Answer 27

DNA polymerase alpha / DNA primase

Question 28

What is in charge of leading strand synthesis in humans?

Answer 28

DNA polymerase epsilon

Question 29

What is in charge of lagging strand synthesis in humans?

Answer 29

DNA polymerase delta

Question 30

What is in charge of proofreading in humans?

Answer 30

DNA DELTA / epsilon

Question 31

What is in charge of primer removal in humans?

Answer 31

Fen-1
RNAseH

Question 32

What is in charge of primer extension after primer removal in humans?

Answer 32

DNA polymerase delta

Question 33

What seals the nicks of DNA in humans?

Answer 33

DNA ligase I

Question 34

What can kill the cell which is usually ceased in cancer cells?

Answer 34

Supercoiling

Question 35

What is the difference between leading strand and lagging strand synthesis?

Answer 35

1.A leading strand is the strand which is synthesized in the 5’-3’direction while a lagging strand is the strand which is synthesized in the 3’-5’ direction.
2.The leading strand is synthesized continuously while a lagging strand is synthesized in fragments which are called Okazaki fragments.
3.Leading strand synthesis does not require an RNA primer while a lagging strand synthesis requires RNA primase.

Question 36

Explain how DNA replication terminates in prokaryotes/E. Coli.

Answer 36

The genome is circular
The replication fork proceeds around the circle to a termination site
The termination site is opposite the ori
The protein tus binds to the 10 ter sequences at the termination site
Tus action with other proteins results in completion of replication of the genome
Genomes are intertwined and resolved/separated by topoisomerase IV

Question 37

Explain the difficulty in replicating the ends of linear chromosomes

Answer 37

Lagging strand causes problems as DNA polymerase requires a primer with a free 3’ OH group and RNA primers cannot remain in DNA meaning that the chromosome shortens each time its replicated

Question 38

What is the role and structure of telomeres

Answer 38

Eukaryotic chromosomes have telomeres that protect the end of a chromosome from damage
Telomeres are composed of repeated TTAGGG sequences
Telomerase maintains the length of telomeres
Telomeres contain TERT and TERC (adds TTAGGG)
The no. of TTAGGG repeats at the 3’ end of the
chromosomes increases with telomerase action
Telomerase extends chromosome by using a sequence on its own RNA as a template
Telomerase then translocates 6 bases

Question 39

Describe the relationship between telomerase and aging and cancer cells.

Answer 39

Telomere repeats are lost during every
mitosis as telomerase is repressed in somatic cells - eventually telomere shortening hits a threshold that causes senescence or cell death
Telomerase is active in >85% of cancer cells and telomere lengthening is strongly correlated with cancer.

Question 40

Describe the types of RNA genomes found in viruses.

Answer 40

2 types of viruses: Double stranded RNA viruses and retroviruses
Double stranded RNA virus:
encode their own polymerase for replication called RNA dependent RNA polymerase
Retroviruses:
Copied into DNA by viral encoded reverse transcriptase
DNA inserted into genome of host and inserted genome is transcribed by RNA polymerase

Question 41

What is a silent mutation, a missense mutation and a nonsense mutation?

Answer 41

Silent - no change in amino acid sequence
Missense - changes the code from one amino acid to another e.g. gcu codes A but changed to ccu coding P
Nonsense - changes the code to a stop codon e.g. aaa codes K but changed to uaa

Question 42

List the different type of agents that inhibits DNA replication

Answer 42

Nucleotide triphosphate inhibitors
Antimetabolites
Inhibitors of chain elongation
DNA polymerase inhibitors
DNA damaging drugs
DNA topoisomerase inhibitors

Question 43

What is the effect of methotrexate on DNA replication?

Answer 43

Antifolate that inhibits cell division

Question 44

What is the effect of 5-flurouracil on DNA replication?

Answer 44

Interferes with pyrimidine production

Question 45

What is the effect of AZT on DNA replication?

Answer 45

Causes chain termination as incoming nucleotides cannot be added on to DNA

Question 46

What is the effect of cisplatin on DNA replication?

Answer 46

Damages DNA
Common chemotherapy drug

Question 47

What is the effect of etoposide on DNA replication?

Answer 47

Inhibits the action of topoisomerase leading to cell death

Question 48

Why is AZT an effective anti-retroviral drug?

Answer 48

Reverse transcriptase of HIV has a higher affinity for AZT than dTTP while human DNA polymerases have a higher affinity for dTTP than AZT
AZT can be used selectively against HIV reverse transcription of RNA into cDNA without affecting the DNA polymerase of the host cell