Alkylation of guanine at the O6 atom is a highly mutagenic DNA lesion because it alters the coding specificity of the base causing G:C to A:T transversion mutations. Specific DNA repair enzymes, e.g.
O-6-alkylguanin-DNA-Transferases (AGT), recognize and repair such damage after looping out the damaged base to transfer it into the enzyme active site. The exact mechanism how the repair enzyme identifies a damaged site within a large surplus of undamaged DNA is not fully understood.
The O-6-alkylation of guanine may change the deformability of DNA which may facilitate the initial binding of a repair enzyme at the damaged site. In order to characterize the effect of O-6-methyl-guanine (O-6-MeG) containing base pairs on the DNA deformability extensive comparative molecular dynamics (MD) simulations on duplex DNA with central G:C, O-6-MeG:C or O-6-MeG:T base pairs were performed.
The simulations indicate significant differences in the helical deformability due to the presence of O-6-MeG compared to regular undamaged DNA. This includes enhanced base pair opening, shear and stagger motions and alterations in the backbone fine structure caused in part by transient rupture of the base pairing at the damaged site and transient insertion of water molecules.
It is likely that the increased opening motions of O-6-MeG:C or O-6-MeG:T base pairs play a decisive role for the induced fit recognition or for the looping out of the damaged base by repair enzymes. (c) 2014 Wiley Periodicals, Inc. Biopolymers 103: 23-32, 2015.