L2: Enzymes involved in DNA replication and Repair Flashcards
Replication of DNA is initiated by..
Binding of 2 helicases (large T antigen) to origin of replication
Helicase
Break HB between strands -> separate strands
Topoisomerase
Remove twist/torsional stress
Primase
Synthesises short RNA primers
DNA polymerase
Requires primers
Copies template
RNaseH
Removes RNA primers -> ozaki fragments can join
Ligase
Joins nicks in lagging strand
Synthesis of DNA starts from..
Small piece of RNA (primer)
Leading strand
Continuous synthesis in 3’-5’ direction
Lagging strand
In opp direction
Short pieces of Ozaki fragments
DNA polymerase reaction
Primer strand, template strand and incoming substrate (dNTP)
dNTP -> HB with T residue in template
Proofreading
DNA polymerase can move ‘back’ one nucleotide to remove incorrectly paired nucleotide
Incorrect base pairing -> DNA strand moves to exonuclease site -> incorrect base pair recognised -> nucleotide removed -> DS relocates back to polymerase site -> polymerase can incorporate correct deoxynucleoside from triphosphate substrate
3’ -> 5’ exonuclease activity of DNA polymerases I, II, III
Active sites of DNA polymerase I
5’ -> 3’ polymerase site: incoming dNTP added to 3’OH group of primer -> strand grows 5’ -> 3’
3’ -> 5’ exonuclease site: strand shortens at 3’ end as enzyme moves ‘backwards’ one nucleotide
5’ -> 3’ exonuclease site: removes nucleotides in front of it as it moves forward. Can remove RNA primers
Nick translation
5’ -> 3’ exonuclease activity of DNA polymerase I
Nick in DNA -> polymerase subunit can remove nucleotides &/or deoxynucleotides ahead of polymerase -> adds nucleotides as moves along
Can run along nick and remove primers
Pol I
Function: ozaki fragment processing and DNA repair
Pol II
Function: translation synthesis and DNA repair
Pol III
Function: chromosome replication
Pol IV & V
Function: Translesion synthesis
Important for replication of ‘damaged DNA’ -> stalling of replication fork. Can incorporate incorrect nucleotide opp damaged base -> replication fork proceed (translesion)
Structure of DNA polymerase
Structure resembles hand with unwound 3’ end of DNA facing palm
Incorrect base pair prevents…
Pol I from closing -> slow catalysis (formation of phosphodiester bond) -> enables incorrect dNTP to dissociate
Role of metal ions in DNA polymerases
Active site contains 2 Mg2+ ions bound to conserved Asp residues
Helps catalysis & stabilising -ve charge from oxygen
- Attack phosphate -> cleavage of phosophodiester linkage -> join deoxynucleotide to new strand
Deprotonates primer 3’OH -> 3’O- nucleophile
- Stabilises pyrophosphates -> allow -ve charge on oxygen assist polymerase reaction.
Facilitates departure of pyrophosphate product
MutS
Detects mismatches from distortion of backbone
Mismatch repair by MutS
DNA replicated with MutS protein -> runs along looking for mutations in DNA helix from incorrect base pairing (mismatch) -> finds mismatch & recruits other proteins ( MutL & MutH) -> forms complex with MutS
MutL activated MutH -> nicks DNA strand near mutation -> exonuclease removes surrounding DNA including mismatch -> DNA repaired by Pol III & ligase
How MutS differentiates between parent and new strand
Through methylation pattern on DNA
Parent strand: heavily methylated
New strand: poorly methylated as methylation takes some time after replication
Uses of DNA in recombinant DNA technology
- PCR
- cDNA library construction
a) ssDNA -> dsDNA
b) mRNA copied -> ss CDNA (RNA-dependent DNA pol) - Nick translation.
5’ -> 3’ exonuclease activity & DNA pol activity - Fill in reactions using pol activity for any DNA manipulation that cause gap in 1 strand of dsDNA
