Formamidopyrimidine-DNA glycosylase (Fpg) is a primary participant in the repair of 8-oxoguanine, an abundant oxidative DNA lesion. Although the structure of Fpg has been established, amino acid residues that define damage recognition have not been identified. We have combined molecular dynamics and bioinformatics approaches to address this issue. Site-specific mutagenesis coupled with enzyme kinetics was used to test our predictions. On the basis of molecular dynamics simulations, Lys-217 was predicted to interact with the O 8 of extrahelical 8-oxoguanine accommodated in the binding pocket. Consistent with our computational studies, mutation of Lys-217 selectively reduced the ability of Fpg to excise 8-oxoguanine from DNA. Dihydrouracil, also a substrate for Fpg, served as a nonspecific control. Other residues involved in damage recognition (His-89, Arg-108, and Arg-109) were identified by combined conservation/structure analysis. Arg-108, which forms two hydrogen bonds with cytosine in Fpg-DNA, is a major determinant of opposite-base specificity. Mutation of this residue reduced excision of 8-oxoguanine from thermally unstable mispairs with guanine or thymine, while excision from the stable cytosine and adenine base pairs was less affected. Mutation of His-89 selectively diminished the rate of excision of 8-oxoguanine, whereas mutation of Arg-109 nearly abolished binding of Fpg to damaged DNA. Taken together, these results suggest that His-89 and Arg-109 form part of a reading head, a structural feature used by the enzyme to scan DNA for damage. His-89 and Lys-217 help determine the specificity of Fpg in recognizing the oxidatively damaged base, while Arg-108 provides specificity for bases positioned opposite the lesion.Oxidative metabolism produces reactive oxygen species that damage cellular DNA. DNA bases, deoxyribose, and the cellular nucleoside triphosphate pool are prone to such events. Redox reactions result in modification of the canonical DNA bases, with formamidopyrimidine (FaPy)
Current analyses of protein sequence/structure relationships have focused on expected similarity relationships for structurally similar proteins. To survey and explore the basis of these relationships, we present a general sequence/structure map that covers all combinations of similarity/dissimilarity relationships and provide novel energetic analyses of these relationships. To aid our analysis, we divide protein relationships into four categories: expected/unexpected similarity (S and S(?)) and expected/unexpected dissimilarity (D and D(?)) relationships. In the expected similarity region S, we show that trends in the sequence/structure relation can be derived based on the requirement of protein stability and the energetics of sequence and structural changes. Specifically, we derive a formula relating sequence and structural deviations to a parameter characterizing protein stiffness; the formula fits the data reasonably well. We suggest that the absence of data in region S(?) (high structural but low sequence similarity) is due to unfavorable energetics. In contrast to region S, region D(?) (high sequence but low structural similarity) is well-represented by proteins that can accommodate large structural changes. Our analyses indicate that there are several categories of similarity relationships and that protein energetics provide a basis for understanding these relationships.
Chemical and physical agents can alter the structure of DNA by modifying the bases and the phosphate-sugar backbone, consequently compromising both replication and transcription. During transcription elongation, RNA polymerase complexes can stall at a damaged site in DNA and mark the lesion for repair by a subset of proteins that are utilized to execute nucleotide excision repair, a pathway commonly associated with the removal of bulky DNA damage from the genome. This RNA polymerase-induced repair pathway is called transcription-coupled nucleotide excision repair. Although our understanding of DNA lesion effects on transcription elongation and the associated effects of stalled transcription complexes on DNA repair is broadening, the attainment of critical data is somewhat impeded by labor-intensive, time- consuming processes that are required to prepare damaged DNA templates. Here, we describe an approach for building linear DNA templates that contain a single, site-specific DNA lesion and support transcription by human RNA polymerase II. The method is rapid, making use of biotin-avidin interactions and paramagnetic particles to purify the final product. Data are supplied demonstrating that these templates support transcription, and we emphasize the potential versatility of the protocol and compare it with other published methods.
The covalent binding of bulky mutagenic or carcinogenic compounds to DNA can lead to bending, which could significantly alter the interactions of DNA with critical replication and transcription proteins. The impact of adducts derived from the highly reactive bay region enantiomeric (+)- and (-)-anti-7,8-diol-9,10-epoxide derivatives of benzo[a]pyrene (BPDE) are of interest because the (+)-7R,8S,9S,10R-anti-BPDE enantiomer is highly tumorigenic in rodents, while the (-)-7S,8R,9R,10S-anti-BPDE enantiomer is not. Both (+)- and (-)-anti-BPDE bind covalently with DNA predominantly by trans addition at the exocyclic amino group of guanine to yield 10S (+)- and 10R (-)-trans-anti-[BP]-N(2)-dG adducts. We have synthesized a number of different oligonucleotides with single (+)- and (-)-trans-anti-[BP]-N(2)-dG adducts (G) in the base sequence context XG*Y, where X and Y are different DNA bases. The G* residues were positioned at or close to the center of 11 base pair ( approximately 1 helical turn) or 16 base pair ( approximately 1.5 turns) duplexes. All bases, except for X and Y and their partners, were identical. These sequences were self-ligated with T4 ligase to form multimers that yield a ladder of bands upon electrophoresis in native polyacrylamide gels. The extent of bending in each oligonucleotide was assessed by monitoring the decrease in gel mobilities of these linear, self-ligated oligomers, relative to unmodified oligonucleotides of the same base sequence. The extent of global bending was then estimated using a sequence-specific three-dimensional model from which the values of the base-pair step parameter roll adjacent to the lesion site could be extracted. We find that (+)-trans-anti-[BP]-N(2)-dG adducts are considerably more bent than the (-) isomers regardless of sequence and that A-T base pairs flanking the [BP]-N(2)-dG lesion site allow for local flexibility consistent with adduct conformational heterogeneity. Interestingly, the fit of computed versus observed gel mobilities using classical reptation treatments requires enhancement of unmodified DNA flexibility in gels, compared to aqueous salt solution. The differences in bending between the two stereoisomeric adduct duplexes and the observed base sequence context effects may play a significant role in the differential processing of these lesions by cellular replication, transcription, and repair enzymes.
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