S1: DNA Synthesis

Question 1

How is DNA replication described as?

Answer 1

Semi-conservative

Question 2

What is the replication origins?

Answer 2

Specific sites where DNA replication is initiated

Question 3

What recognises the replication origins?

Answer 3

Initiation complexes

Question 4

Why does DNA at the origin unwind to form a replication bubble?

Answer 4

Allow access to the replication machinery

Question 5

What phase of the cell cycle does DNA synthesis occur in?

Answer 5

(S) phase

It involves complete unwinding of the parental DNA

Question 6

How long is the bacterial cell cycle and phases does it include?

Answer 6

20-30 minutes

M phase- S Phase

Question 7

How long is the mammalian cell cycle and phases does this include?

Answer 7

16-24 hours

M Phase - G1- S - G2

Question 8

Why is the mammalian cell cycle longer than the bacterial cycle?

Answer 8

Human have more chromosomes

Question 9

Compare the number of replication origins in bacteria and mammalian cells

Answer 9

Bacteria DNA only has a single replication origin

Eukaryotic cells DNA replication initiates at multiple replication origins

Question 10

What is DNA polymerase?

Answer 10

This is the enzyme that synthesises DNA and cells have multiple DNA polymerases

Question 11

Name the types of polymerases and function in eukaryotic cells

Answer 11

Alpha – replication
Beta – replication
Gamma – mitochondrion
Delta – replication (causes elongation)
Epsilon – replication (causes elongation)

Question 12

List the key properties of DNA polymerases

Answer 12

• Acts in 5’ to 3’ directions
• Utilises AT and CG base pairing to synthesise new DNA strands
• It requires a DNA template = a DNA or RNA primer, the four dNTP and Mg2+ ions
• Proof reading function

Question 13

What does dNTP stand for?

Answer 13

Deoxyribosenucleoside triphosphate

Question 14

Why does DNA polymerase require a DNA template?

Answer 14

DNA polymerase requires an -OH on the 3’ carbon to start adding nucleotide (building blocks can only be added to the 3’ end).

Question 15

What are the building blocks for DNA?

Answer 15

dNTPs

Question 16

What is the significance of DNA polymerase acting in the 5’-3’ direction?

Answer 16

One DNA strand must be made discontinuously while the other is made continuously.

Question 17

What is a replication fork?

Answer 17

A replication fork will appear at the replication origin.

The parental strands will seperate and they are antiparallel.

Question 18

What is the leading strand?

Answer 18

On the 5’-3’ strand of DNA, DNA polymerase will cause a continuous strand to be made called the leading strand. This is because as DNA opens up, DNA polymerase can attach to the 3’ end of DNA and continue to synthesis the DNA strand.

Question 19

What is the lagging stand?

Answer 19

In the 3’-5’ strand, DNA polymerase is working in the opposite direction to the unwinding. This means that behind the polymerase, the strand will be opening up while it moves forward. This is called the lagging stand and it forms okazaki fragments. This is because replication has to be reinitiated again and again.

Question 20

What does DNA Helicase do?

Answer 20

Seperates the base pairs producing single strands

Question 21

What does Topoisomerase do?

Answer 21

Goes in front of helicase and gets rid of the coils in DNA (as it gets supercoiled by gyrase)

Question 22

What does DNA primase do?

Answer 22

Lays down some RNA (produces 3’-OH) so that DNA polymerase knows where to start replicating

Question 23

What do DNA binding proteins do?

Answer 23

Stabilise the single stranded DNA stop it being reannealed with the other parent strand.

Question 24

What do replicative DNA polymerases do?

Answer 24

Copies parental strand

Question 25

What do repair DNA polymerases do?

Answer 25

Repair the fragments and takes out the RNA so it will a full DNA strand

Question 26

What does DNA ligase do?

Answer 26

Splices the fragments together (Okazaki fragments)

Question 27

What does DNA polymerase have that ensures DNA replication proceeds with high fidelity?

Answer 27

Proof reading and mismatch repair system

• They check for mistakes and if made will go back and change them
• This makes error rate very low

Question 28

Give an example of a disease from inherited defects in mismatch repair genes

Answer 28

Colon Cancer

failure to correct DNA synthesis may lead to cancer

Question 29

What are DNA replication inhibitors used for?

Answer 29

DNA replication inhibitors are importantantibacterial, antitumour(so used in chemotherapy against cancers) andantiviral agents.