27 research outputs found
Exocyclic amino groups of flanking guanines govern sequence-dependent adduct conformations and local structural distortions for minor groove-aligned benzo[a]pyrenyl-guanine lesions in a GG mutation hotspot context
The environmental carcinogen benzo[a]pyrene (BP) is metabolized to reactive diol epoxides that bind to cellular DNA by predominantly forming N(2)-guanine adducts (G*). Mutation hotspots for these adducts are frequently found in 5′- ··· GG ··· dinucleotide sequences, but their origins are poorly understood. Here we used high resolution NMR and molecular dynamics simulations to investigate differences in G* adduct conformations in 5′- ··· CG*GC ··· and 5′- ··· CGG* C··· sequence contexts in otherwise identical 12-mer duplexes. The BP rings are positioned 5′ along the modified strand in the minor groove in both cases. However, subtle orientational differences cause strong distinctions in structural distortions of the DNA duplexes, because the exocyclic amino groups of flanking guanines on both strands compete for space with the BP rings in the minor groove, acting as guideposts for placement of the BP. In the 5′- ··· CGG* C ··· case, the 5′-flanking G · C base pair is severely untwisted, concomitant with a bend deduced from electrophoretic mobility. In the 5′- ··· CG*GC ··· context, there is no untwisting, but there is significant destabilization of the 5′-flanking Watson–Crick base pair. The minor groove width opens near the lesion in both cases, but more for 5′- ··· CGG*C···. Differential sequence-dependent removal rates of this lesion result and may contribute to the mutation hotspot phenomenon
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Effects of base sequence context on translesion synthesis past a bulky (+)-trans-anti-B[a]P-N2-dG lesion catalyzed by the Y-family polymerase pol kappa
The effects of bases flanking single bulky lesions derived from the binding of a benzo[a]pyrene 7,8-diol 9,10-epoxide derivative ((+)-7R,8S,9S,10R stereoisomer) to N(2)-guanine (G*) on translesion bypass catalyzed by the Y-family polymerase pol kappa (hDinB1) were examined in vitro. The lesions were positioned near the middle of six different 43-mer 5'-...XG*Y... sequences (X, Y = C, T, or G, with all other bases remaining fixed). The complementary dCTP is preferentially inserted opposite G* in all of the sequences; however, the proportions of other dNTPs inserted varies as a function of X and Y. The dCTP insertion efficiencies, f(ins) = (V(max)/K(m))(ins), are smaller in the XG*Y than in XGY sequences by factors of approximately 50-90 (GG*T and GG*C) or 5000-25000 (TG*G and CG*G). Remarkably, in XG*Y sequences, f(ins) varies by as much as 3 orders of magnitude, being smallest with G flanking the lesions on the 3'-side and highest with G flanking the adducts on the 5'-side. One-step primer extension efficiencies just beyond the lesions (f(ext)) are generally smaller than f(ins) and also depend on base sequence. However, reasonably efficient translesion bypass of the (+)-trans-[BP]-N(2)-dG adducts is observed in all sequences in running-start experiments with full, or nearly full, primer extension being observed under conditions of [dNTP] > K(m). The key features here are the relatively robust values of the kinetic parameters V(max) that are either diminished to a moderate extent or even enhanced in the presence of the (+)-trans-[BP]-N(2)-dG adducts. In contrast to the small effects of the lesions on V(max), the apparent K(m) values are orders of magnitude greater in XG*Y than in the unmodified XGY sequences. Thus the bypass of (+)-trans-[BP]-N(2)-dG adducts under conditions when [dNTP] < K(m) is quite inefficient. These considerations may be of importance in vivo where [dNTP] <or= K(m), and the translesion bypass of the (+)-trans-[BP]-N(2)-dG by pol kappa may be significantly less efficient than in vitro at higher dNTP concentrations. The base sequence-dependent features of translesion bypass are discussed in terms of the possible conformations of the adducts and the known structural features of bypass polymerases