Molecular Insights into the Translesion Synthesis
of Benzyl-Guanine from Molecular Dynamics Simulations: Structural
Evidence of Mutagenic and Nonmutagenic Replication
posted on 2017-03-14, 00:00authored byKatie
A. Wilson, Stacey D. Wetmore
DNA
can be damaged by many compounds in our environment, and the
resulting damaged DNA is commonly replicated by translesion synthesis
(TLS) polymerases. Because the mechanism and efficiency of TLS are
affected by the type of DNA damage, obtaining information for a variety
of DNA adducts is critical. However, there is no structural information
for the insertion of a dNTP opposite an O6-dG adduct, which is a particularly
harmful class of DNA lesions. We used molecular dynamics (MD) simulations
to investigate structural and energetic parameters that dictate preferred
dNTP insertion opposite O6-benzyl-guanine (Bz-dG) by DNA polymerase
IV, a prototypical TLS polymerase. Specifically, MD simulations were
completed on all possible ternary insertion complexes and ternary
−1 base deletion complexes with different Bz-dG conformations.
Our data suggests that the purines are unlikely to be inserted opposite anti- or syn-Bz-dG, and dTTP is unlikely
to be inserted opposite syn-Bz-dG, because of changes
in the active site conformation, including critical hydrogen-bonding
interactions and/or reaction-ready parameters compared to natural
dG replication. In contrast, a preserved active site conformation
suggests that dCTP can be inserted opposite either anti- or syn-Bz-dG and dTTP can be inserted opposite anti-Bz-dG. This is the first structural explanation for
the experimentally observed preferential insertion of dCTP and misincorporation
of dTTP opposite Bz-dG. Furthermore, we provide atomic level insight
into why Bz-dG replication does not lead to deletion mutations, which
is in contrast with the replication outcomes of other adducts. These
findings provide a basis for understanding the replication of related
O6-dG adducts.