DNA replication

Question 1

Define DNA replication

Answer 1

It is a semiconservative replication
Each strand of the double helix is used as a template strand for the synthesis of 2 new strands, resulting DNA will have 1 parental strand and 1 new strand

Question 2

Leading strand replication - continuous (5)

Answer 2

1. Helicase - enzyme that finds AT rich region and unwinds the DNA in order for DNA polymerase to get into the middle of DNA. It moves along the DNA helix, forming a replication bubble
2. Topoisomerase - enzyme that cuts the tightly wind DNA helix to release tension and glues the strands back together to allow helicase to continue (moves in from of helicase)
3. ssbp (single stranded DNA binding proteins)
   - Protein that stabilises the unwound template strands until it is used as a template
   - Protein that protects the separated single strand DNA from enzyme attack
   - Prevents separated DNA strands from joining back together before replication has finished
4. Primase (type of RNA polymerase) - enzyme that synthesises an RNA primer at the 5’ end - the starting point for DNA polymerisation
5. DNA polymerase (DNA Pol III) - enzyme that uses the parental DNA as a template, synthesises new DNA strand by adding complimentary nucleotides to an RNA primer or a pre-existing DNA strand. As DNA polymerase III moves along the DNA strand, it kicks off the ssbp proteins

Question 3

Lagging strand replication - discontinuous (5)

Answer 3

1. Helicase, Topoisomerase and ssbp do their jobs
2. Enzyme primase begins synthesis of RNA primer at the 5’ end of each okazaki fragment with OH group at 3’ end
3. DNA pol III synthesises each okazaki fragment by attaching to the 3’ OH group and adding nucleotides complementary to the parental template strands
4. DNA polymerase I - 2 activities
   - RNase activity: endonuclease enzyme that recognises DNA-RNA hybrids and degrades the RNA part by removing the RNA primer
   - DNA polymerase activity: fill the gap and synthesises DNA by adding nucleotides to the 3’end of each okazaki fragment, complimentary to the parental DNA template of the lagging strand
   After the last addition, the backbone is left with a free 3’ end
5. DNA ligase joins newly synthesised okazaki fragments together by creating phosphdiester bonds

Question 4

Where does the origin of replication occur and why

Answer 4

AT rich region because only 2 hydrogen bonds present so easier to pull apart as it is held together more weakly

Question 5

Direction of leading strand replication vs. lagging strand replication

Answer 5

Leading strand: 5’ - 3’

Lagging strand: 3’ - 5’

Question 6

why can primase make RNA primers from scratch

Answer 6

Because it contains an internal 3’ OH group

Question 7

Why can’t DNA polyerase bind directly onto ssDNA and start replication without an initial RNA or DNA primer

Answer 7

The primer provides an 3’OH group to which the phosphate group of the incoming nucleotide can be attached

Question 8

Prokaryotic replication vs. eukaryotic replication (4)

Answer 8

Prokaryotic replication
- occurs in the cytoplasm 
- single circular chromosome
- single origin of replication (ori)
- rapid 
Eukaryotic replication
- occurs in the nucleus
- Multiple linear chromosome
- multiple origin of replication (ori)
- slower than prokaryotic replication

Question 9

when is the X-shaped chromosome formed

Answer 9

After DNA replication, just before mitosis

Question 10

What is nuclease

Answer 10

Enzyme that removes nucleotides

Question 11

Repair of DNA errors - during replication (3)

Answer 11

1. DNA Pol III has proofreading mechanism, it checks the newly inserted nucleotide bases against the template
2. Incorrect bases are moved by the 3’ - 5’ EXOnuclease activity of DNA pol III
3. DNA synthesis continues
   Only nucleotides at the ends can be removed

Question 12

Repair of DNA errors - after replication (3)

Answer 12

1. Damaged/incorrect DNA removed by enzyme ENDO nuclease (removes nucleotides from within a sequence)
2. DNA polymerase makes new DNA
3. DNA ligase joins new DNA to existing DNA

Question 13

DNA damage/error causes (3)

Answer 13

1. Incorrectly inserted bases are not corrected by DNA pol III
2. Radiation damage eg. UV –> pyrimidine dimers
3. chemical modifications of bases

Question 14

Importance of correcting DNA errors

Answer 14

If a DNA error is not corrected , it becomes part of the DNA template causing a permanent DNA change - DNA damage/mutation

Question 15

‘in vitro’ DNA replication by the Polymerase Chain Reaction (PCR) - (4)

Answer 15

• DNA replication carried out in test tube to make multiple copies of DNA
• only ‘targeted’ DNA region will be copied
• Rapid exponential increase of DNA molecules
• Method utilises cycles of heating and cooling

Question 16

PCR components (6)

Answer 16

• DNA template (chromosomal/genomic)
• Primers (short stretch of DNA nucleotides, usually 20)
• Heat stable DNA polymerase (special enzyme that will polymerase at high temperature)
• dNTPs (deoxynucleotide triphosphates)
• Buffer solution (maintain the pH that the DNA polymerase requires to work)
• Divalent cations (Mg2+)/co-factors (ions essential for DNA polymerase to work)

Question 17

what are dNTPs

Answer 17

Free nucleotides with equal amount of A,C,G,T that act as the building blocks used by DNA polymerase in PCR

Question 18

Process of PCR

Answer 18

1. Denaturing (98°C) - Temperature increased to separate DNA strands by breaking H-bonds
2. Annealing (48°C - 72°C) - Temperature decreased to allow primers anneal/form H-bonds to their target DNA following the base paring rules
3. Extension (68°C - 72°C) - (Taq) Polymerase (works optimally at this temperature) starts polymerisation by extending primer (adding complimentary nucleotides to the 3’ end) to form nascent DNA strand
   Above steps are repeated 25-30 times resulting in exponential increase of DNA molecules

Question 19

Up to how many times is PCR repeated

Answer 19

35 times

Question 20

Direction of DNA synthesis

Answer 20

5’ - 3’

Question 21

Parental template DNA strand direction

Answer 21

Run from 3’ - 5’

Question 22

Product of 1 complete cycle of PCR

Answer 22

2 double stranded copies of the target DNA

Question 23

most common polymerase used in PCR

Answer 23

Taq polymerase (derived from hot spring bacteria)