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Chemistry of DNA synthesis
Substrates for DNA
synthesis:
• Deoxyribonucleotide
triphosphates (dNTPs)
• Primer: template junction
The primer provides a free 3’-OH while template provides a
single-stranded DNA to be copied.
DNA polymerization is a NUCLEOPHILIC SUBSTITUTION (SN2)
REACTION.
DNA polymerase has 3 main domains:
– Palm domain
– Thumb domain
– Finger domain
v Palm domain:
• Possess the active site of DNA synthesis and is
composed of a β-sheet.
• The active site in the palm domain can distinguish
between rNTPs and dNTPs.
• The rNTPs are present in around 10 fold higher
concentrations in the cell.
• But the nucleotide-binding pocket is too small for the
2’-OH on the incoming rNTP.
• Thus the polymerase can exclude the rNTPs by steric
constraining.
• Correct base pairing is also required for catalysis.
• If an incorrect dNTP comes, its α-phosphoryl
group cannot properly align with the 3’-OH of the growing strand.
• Once the correct dNTP is bound in the pocket, the
reaction can continue.
• The palm domain also binds Zn2+ and Mg2+
which are crucial for catalysis.
v Finger domain:
• Composed of α-helix.
• Once the correct dNTP is bound in the pocket, the
finger domain moves to enclose the base-paired dNTPs.
• This conformational change brings the dNTP and
the primer (or growing DNA strand) into correct orientation with the
divalent metal ions.
• The O-helix of the finger domain moves 40°
to enclose the base by stacking interaction with its tyrosine residue.
• Metal ion A helps to deprotonate the 3’-OH of the primer
producing an oxyanion.
• This oxyanion attacks the α–phosphoryl
group of the incoming
dNTP.
• Metal ion B coordinates the negative charge of the β-
and γ-phosphate groups and stabilizes the pyrophosphate leaving group.
• Lysine and arginine residues on the finger domain also help to stabilize the
pyrophosphate and the tyrosine residue holds the dNTP in place for
catalysis (stacking interaction).
• The finger domain also associates with the template
region resulting in a 90° turn in the template which helps to avoid
confusion in the active site.
• This ensures that only one template nucleotide
remains in the active site.
v Thumb domain:
• It is not intimately involved in catalysis.
• It interacts with the DNA that has been synthesized
most recently and holds the primer: template junction in the active site.
• This reduces the dissociation of the polymerase from
the template.
Proofreading
• If
an incorrect nucleotide is incorporated by DNA polymerase (frequency of error
is 10-6), it is recognized immediately.
• The
3’ → 5’ exonuclease activity of the polymerase then excise the incorrect
nucleotide from the new strand.
• The
polymerase then resumes its forward motion and inserts the correct nucleotide.
• The palm domain also has proofreading activity.
• It H-bonds with the base pairs in the minor groove. It
is not sequence-specific but occurs only when the nucleotides are correctly
base-paired.
• If a mismatch occurs, replication slows down and the
palm domain is not able to make contact with the minor groove.
• This frees the primer: template junction to move and make
contact with the exonuclease site.
• The exonuclease site removes the incorrect base from
3’ to 5’ direction in a process called proofreading.
• After excision is complete, the primer: template
junction slides back to the replication active site.