DNA replication and repair

Question 1

What are initiator proteins?

Answer 1

DNA binding proteins that initiate the assembly of replication machinery (e.g. the recruitment of helicase) by binding to the initiator sequence on DNA. In eukaryotes -> orc/cdc6 protein. In prokaryotes dnaA protein which causes some unwinding as well.

Question 2

How does initiation work in bacteria?

Answer 2

Bacteria have a single start site (oriC) followed by a consensus sequence of DnaA binding sites. Binding of DnaA triggers the process, promoting unwinding of DNA. There are at least 10 proteins involved in bacterial DNA replication and the timing of the process is regulated by DNA methylation ( replication will not start until oriC is methylated).

Question 3

How is eukaryotic DNA replication regulated?

Answer 3

By cell cycle checkpoints (prokaryotes can replicate DNA continuously even before cell division is complete). Sequence specificity varies widely between eukaryotes some organisms have consensus sequences while others don’t but have the same set of chromatin modifications to initiate replication.

Question 4

DNA replication is semi conservative how was this discovered?

Answer 4

Two groups of bacteria where grown, one in normal conditions the other in the presence of heavier carbon isotopes which created heavier DNA molecules. When the 2 samples where mixed, their DNA weight was measured which showed that the heavy and light DNA had combinedinto one helix: semi conservative. When these DNA molecules where denatured it was shown that one strand was heavy the other light not each strand being a mix.

Question 5

What is dNTP and what does it do?

Answer 5

Deoxynucleotide triphosphate.
Substrate for genome replication. The phosphate group binds to the OH group on the strand being constructed creating a new phosphodiester bond (DNA polymerase catalyses the hydrolysis, removing 2x Pi from the dNTp) and the base hydrogen bonds to the base on the template strand. dNTP is called something different dependent on the base it carries, e.g. guanine = dGTP.

Question 6

How is a new DNA chain initiated?

Answer 6

By the synthesis of a short RNA primer on the template strand (catalysed by primase) that is then extended by DNA polymerase/dNTPs. RNA primers are then removed.

Question 7

Why is DNA synthesis always 5’-3’?

Answer 7

Most likely to make proofreading easier.

Question 8

How does DNA polymerase stop rNTP binding in the place of dNTP?

Answer 8

Discriminator amino acids in DNA polymerase prevent rNTP binding. rNTP is incompatible with the active site because of its hydroxyl group whereas dNTPs have a hydrogen which can bind with the active site.

Question 9

How is DNA polymerase prevented from diffusing away from the primer?

Answer 9

Sliding clamp protein encircles newly synthesised DNA and holds the DNA polymerase.

Question 10

What is the difference between the lagging and the leading strand in DNA replication.

Answer 10

One of the template strands has a 3’ end the other a 5 prime end. The one with a 3’ is the leading strand and undergoes continuous DNA synthesis as you would expect as the new strand can be constructed in the 5’ - 3’ direction. The template strand with a 5’ end is the lagging strand because it encounters a problem. The strand is synthesized in small sections in the opposite direction to that of DNA replication. This allows for synthesis in the 5’ - 3’ direction as the 5’ end of the template strand must have a 3’ on the newly synthesised strand next to it. This is all discontinuous synthesis and the small sections made are called Okazaki fragments, all with their own RNA primer that must be removed later.

Question 11

What is the trombone model of replication?

Answer 11

The leading strand can be synthesised continuously in a 5’-3’ direction

The lagging strand is looped out so that it passes through the polymerase active site in a 3’-5’ direction, allowing synthesis to occur in the 5’-3’ direction.

One asymmetric DNA polymerase dimer synthesises both strands.

Question 12

How is DNA synthesis finished?

Answer 12

RNA fragments removed by RNAase enzyme
DNA polymerase fills the gaps
DNA ligase makes the final seal

Question 13

What does helicase and topoisomerase do?

Answer 13

Helicase unwinds DNA
Topoisomerase relaxes DNA prior to unwinding by creating transient breaks which allows the DNA strands to rotate relative to each other preventing damage.

Question 14

What is bidirectional DNA replication?

Answer 14

Best way I can explain this for me to remember. Imagine DNA as a zipper, it starts unzipping in the middle and unzips in both directions from that origin. So each side of the zipper is a strand and each of those strands undergoes DNA synthesis. If you look at one strand, one side of the origin will be a leading strand the other a lagging strand and the same for the other strand but on opposite sides.

Question 15

Do eukaryotes or prokaryotes have multiple origins of DNA replication?

Answer 15

Eukaryotes

Question 16

What are the steps in PCR?

Answer 16

1. Denature DNA (95 c)
2. Annealing of desired primers (40 - 60 c)
3. DNA synthesis (70 c)
   Cool fact: cus of the high temperature required the DNA polymerase used is from a thermophilic organism i.e lives in a mf volcanoe

Question 17

What is the initiator and what does it do?

Answer 17

DNA binding proteins that initiate the assembly of replication machinery (e.g. the recruitment of helicase) by binding to the initiator sequence on DNA. In eukaryotes -> orc/cdc6 protein. In prokaryotes dnaA protein which causes some unwinding as well.

Question 18

What is different about DNA replication in bacteria compared to eukaryotes?

Answer 18

Bacteria can divide continuously, with DNA replication restarting before division is completed.
Eukaryotes have complex cell cycles in which DNA replication is a critical control point and ensures DNA is only replicated once per cycle.

Question 19

Very roughly: what are some of the key points of eukaryotic DNA replication initiation?

Answer 19

Sequence specificity varies widely between eukaryotes. For example some have consensus sequences others don’t. But many have the same chromatin modifications. Cyclin proteins license initiation and ensure each origin is only used once per cycle in part by phosphorylating ORC proteins.

Question 20

What is the ‘end’ problem with replication at telomeres? How is it resolved?

Answer 20

Removal of RNA primers can leave unrepaired Okazaki fragments on the lagging strand creating a shorter chromosome. Next replication of this chromosome will result in further shortening unless it is fixed.
The attrition of telomere ends is stopped by short repeat sequences (TTAGGG). Most of these repeats are double stranded but right a the end of telomere the leading strand (3’ end) extends beyond the lagging strand (5’ end) as a single strand. Telomerase contains a small RNA strand that is complimentary of the extended part of the leading strand, this RNA strand acts as a template for reverse transcription, copying the RNA to DNA and extending the 5’ end.

Question 21

What happens to telomeres as we age?

Answer 21

Telomeres shorten over time.
Adult somatic cells lose their telomerase activity, whereas it is retained by stem cells and germ cells. Once cancer cells start multiplying they have to activate telomerase to escape rapid senescence.

Question 22

What does persistent DNA damage cause?

Answer 22

Chromosome breakage and rearrangements which are readily visible to images of metaphase chromosomes stained with chromosome paints. -> cancer

Question 23

What are the common types of DNA damage?

Answer 23

1. Alklyation -> base damaged
2. Depurination -> base lost
3. Deamination -> base converted
4. UV irradiation -> two consecutive bases linked

Question 24

What does damage base-excision repair and how?

Answer 24

Deamination: C -> U
Its in the name, bad base removed and synthesis fills in the gap :)

Question 25

What damage does nucleotide excision repair and how?

Answer 25

Important for removing lesions that distort the double helix such as thymidine dimers (2x thymine’s linked).
A substantial length of one strand is removed by helicase, replaced by the activity of DNA polymerase and finally sealed by DNA ligase. This is an essential mechanism for survival -> humans are susceptible to UV radiation and this mechanism helps mend the damage.

Question 26

How are breaks formed in double stranded DNA helices?

Answer 26

Exogenous
- chemicals
- radiation
Endogenous
-oxygen free radicals
- DNA replication
Specialised
- genetic recombination for antibody production
- class switching
- meiosis

Question 27

How are double strand breaks repaired?

Answer 27

Ku protein complex detects the break and binds to each of the ends of the break and acts as a platform to assemble the other necessary proteins to repair the break on.

Question 28

How do DNA lesions block DNA replication?

Answer 28

In the case of thymine dimers (caused by UV radiation.)
If a replication fork tries to replicate through the location of the it will get blocked.