Molecular dynamics simulation of the opposite-base preference and interactions in the active site of formamidopyrimidine-DNA glycosylase.
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ABSTRACT: Formamidopyrimidine-DNA glycosylase (Fpg) removes abundant pre-mutagenic 8-oxoguanine (oxoG) bases from DNA through nucleophilic attack of its N-terminal proline at C1' of the damaged nucleotide. Since oxoG efficiently pairs with both C and A, Fpg must excise oxoG from pairs with C but not with A, otherwise a mutation occurs. The crystal structures of several Fpg-DNA complexes have been solved, yet no structure with A opposite the lesion is available.Here we use molecular dynamic simulation to model interactions in the pre-catalytic complex of Lactococcus lactis Fpg with DNA containing oxoG opposite C or A, the latter in either syn or anti conformation. The catalytic dyad, Pro1-Glu2, was modeled in all four possible protonation states. Only one transition was observed in the experimental reaction rate pH dependence plots, and Glu2 kept the same set of interactions regardless of its protonation state, suggesting that it does not limit the reaction rate. The adenine base opposite oxoG was highly distorting for the adjacent nucleotides: in the more stable syn models it formed non-canonical bonds with out-of-register nucleotides in both the damaged and the complementary strand, whereas in the anti models the adenine either formed non-canonical bonds or was expelled into the major groove. The side chains of Arg109 and Phe111 that Fpg inserts into DNA to maintain its kinked conformation tended to withdraw from their positions if A was opposite to the lesion. The region showing the largest differences in the dynamics between oxoG:C and oxoG:A substrates was unexpectedly remote from the active site, located near the linker joining the two domains of Fpg. This region was also highly conserved among 124 analyzed Fpg sequences. Three sites trapping water molecules through multiple bonds were identified on the protein-DNA interface, apparently helping to maintain enzyme-induced DNA distortion and participating in oxoG recognition.Overall, the discrimination against A opposite to the lesion seems to be due to incorrect DNA distortion around the lesion-containing base pair and, possibly, to gross movement of protein domains connected by the linker.
<h4>Background</h4>Formamidopyrimidine-DNA glycosylase (Fpg) removes abundant pre-mutagenic 8-oxoguanine (oxoG) bases from DNA through nucleophilic attack of its N-terminal proline at C1' of the damaged nucleotide. Since oxoG efficiently pairs with both C and A, Fpg must excise oxoG from pairs with C but not with A, otherwise a mutation occurs. The crystal structures of several Fpg-DNA complexes have been solved, yet no structure with A opposite the lesion is available.<h4>Results</h4>Here we us ...[more]
Project description:The ubiquitous occurrence of DNA damages renders its repair machinery a crucial requirement for the genomic stability and the survival of living organisms. Deficiencies in DNA repair can lead to carcinogenesis, Alzheimer, or Diabetes II, where increased amounts of oxidized DNA bases have been found in patients. Despite the highest mutation frequency among oxidized DNA bases, the base-excision repair process of oxidized and ring-opened guanine, FapydG (2,6-diamino-4-hydroxy-5-formamidopyrimidine), remained unclear since it is difficult to study experimentally. We use newly-developed linear-scaling quantum-chemical methods (QM) allowing us to include up to 700 QM-atoms and achieving size convergence. Instead of the widely assumed base-protonated pathway we find a ribose-protonated repair mechanism which explains experimental observations and shows strong evidence for a base-independent repair process. Our results also imply that discrimination must occur during recognition, prior to the binding within the active site.
Project description:In recent years, significant progress has been made in determining the catalytic mechanisms by which base excision repair (BER) DNA glycosylases and glycosylase-abasic site (AP) lyases cleave the glycosyl bond. While these investigations have identified active site residues and active site architectures, few investigations have analyzed postincision turnover events. Previously, we identified a critical residue (His16) in the T4-pyrimidine dimer glycosylase (T4-Pdg) that, when mutated, interferes with enzyme turnover [Meador et al. (2004) J. Biol. Chem. 279, 3348-3353]. To test whether comparable residues and mechanisms might be operative for other BER glycosylase:AP-lyases, molecular modeling studies were conducted comparing the active site regions of T4-Pdg and the Escherichia coli formamidopyrimidine DNA glycosylase (Fpg). These analyses revealed that His71 in Fpg might perform a similar function to His16 in T4-Pdg. Site-directed mutagenesis of the Fpg gene and analyses of the reaction mechanism of the mutant enzyme revealed that the H71A enzyme retained activity on a DNA substrate containing an 8-oxo-7,8-dihydroguanine (8-oxoG) opposite cytosine and DNA containing an AP site. The H71A Fpg mutant was severely compromised in enzyme turnover on the 8-oxoG-C substrate but had turnover rates comparable to that of wild-type Fpg on AP-containing DNA. The similar mutant phenotypes for these two enzymes, despite a complete lack of structural or sequence homology between them, suggest a common mechanism for the rate-limiting step catalyzed by BER glycosylase:AP-lyases.
Project description:The formamidopyrimidine-DNA glycosylase (Fpg, MutM) is a bifunctional base excision repair enzyme (DNA glycosylase/AP lyase) that removes a wide range of oxidized purines, such as 8-oxoguanine and imidazole ring-opened purines, from oxidatively damaged DNA. The structure of a non-covalent complex between the Lactoccocus lactis Fpg and a 1,3-propanediol (Pr) abasic site analogue-containing DNA has been solved. Through an asymmetric interaction along the damaged strand and the intercalation of the triad (M75/R109/F111), Fpg pushes out the Pr site from the DNA double helix, recognizing the cytosine opposite the lesion and inducing a 60 degrees bend of the DNA. The specific recognition of this cytosine provides some structural basis for understanding the divergence between Fpg and its structural homologue endo nuclease VIII towards their substrate specificities. In addition, the modelling of the 8-oxoguanine residue allows us to define an enzyme pocket that may accommodate the extrahelical oxidized base.
Project description:Vancomycin is a glycopeptide antibiotic produced by Amycolaptopsis orientalis used to treat serious infections by Gram-positive pathogens including methicillin-resistant Staphylococcus aureus. Vancomycin inhibits cell wall biosynthesis by targeting lipid II, which is the membrane-bound peptidoglycan precursor. The heptapeptide aglycon structure of vancomycin binds to the d-Ala-d-Ala of the pentapeptide stem structure in lipid II. The third residue of vancomycin aglycon is asparagine, which is not directly involved in the dipeptide binding. Nonetheless, asparagine plays a crucial role in substrate recognition, as the vancomycin analogue with asparagine substituted by aspartic acid (VD) shows a reduction in antibacterial activities. To characterize the function of asparagine, binding of vancomycin and its aspartic-acid-substituted analogue VD to l-Lys-d-Ala-d-Ala and l-Lys-d-Ala-d-Lac was investigated using molecular dynamic simulations. Binding interactions were analyzed using root-mean-square deviation (RMSD), two-dimensional (2D) contour plots, hydrogen bond analysis, and free energy calculations of the complexes. The analysis shows that the aspartate substitution introduced a negative charge to the binding cleft of VD, which altered the aglycon conformation that minimized the repulsive lone pair interaction in the binding of a depsipeptide. Our findings provide new insight for the development of novel glycopeptide antibiotics against the emerging vancomycin-resistant pathogens by chemical modification at the third residue in vancomycin to improve its binding affinity to the d-Ala-d-Lac-terminated peptidoglycan in lipid II found in vancomycin-resistant enterococci and vancomycin-resistant S. aureus.
Project description:7,8-Dihydro-8-oxoguanine (8-oxoG) is the major oxidative product of guanine and the most prevalent base lesion observed in DNA molecules. Because 8-oxoG has the capability to form a Hoogsteen pair with adenine (8-oxoG:A) in addition to a normal Watson-Crick pair with cytosine (8-oxoG:C), this lesion can lead to a G:C-->T:A transversion after replication. However, 8-oxoG is recognized and excised by the 8-oxoguanine DNA glycosylase (Ogg) of the base excision repair pathway. Members of the Ogg1 family usually display a strong preference for a C opposite the lesion. In contrast, the atypical Ogg1 from Clostridium actetobutylicum (CacOgg) can excise 8-oxoG when paired with either one of the four bases, albeit with a preference for C and A. Here we describe the first high-resolution crystal structures of CacOgg in complex with duplex DNA containing the 8-oxoG lesion paired to cytosine and to adenine. A structural comparison with human OGG1 provides a rationale for the lack of opposite base specificity displayed by the bacterial Ogg.
Project description:In contrast to proteins recognizing small-molecule ligands, DNA-dependent enzymes cannot rely solely on interactions in the substrate-binding centre to achieve their exquisite specificity. It is widely believed that substrate recognition by such enzymes involves a series of conformational changes in the enzyme-DNA complex with sequential gates favoring cognate DNA and rejecting nonsubstrates. However, direct evidence for such mechanism is limited to a few systems. We report that discrimination between the oxidative DNA lesion, 8-oxoguanine (oxoG) and its normal counterpart, guanine, by the repair enzyme, formamidopyrimidine-DNA glycosylase (Fpg), likely involves multiple gates. Fpg uses an aromatic wedge to open the Watson-Crick base pair and everts the lesion into its active site. We used molecular dynamics simulations to explore the eversion free energy landscapes of oxoG and G by Fpg, focusing on structural and energetic details of oxoG recognition. The resulting energy profiles, supported by biochemical analysis of site-directed mutants disturbing the interactions along the proposed path, show that Fpg selectively facilitates eversion of oxoG by stabilizing several intermediate states, helping the rapidly sliding enzyme avoid full extrusion of every encountered base for interrogation. Lesion recognition through multiple gating intermediates may be a common theme in DNA repair enzymes.
Project description:During repair of damaged DNA, the oxidized base 8-oxoguanine (8-oxoG) is removed by 8-oxoguanine-DNA glycosylase (Ogg) in eukaryotes and most archaea, whereas in most bacteria it is removed by formamidopyrimidine-DNA glycosylase (Fpg). We report the first characterization of a bacterial Ogg, Clostridium acetobutylicum Ogg (CacOgg). Like human OGG1 and Escherichia coli Fpg (EcoFpg), CacOgg excised 8-oxoguanine. However, unlike hOGG1 and EcoFpg, CacOgg showed little preference for the base opposite the damage during base excision and removed 8-oxoguanine from single-stranded DNA. Thus, our results showed unambiguous qualitative functional differences in vitro between CacOgg and both hOGG1 and EcoFpg. CacOgg differs in sequence from the eukaryotic enzymes at two sequence positions, M132 and F179, which align with amino acids (R154 and Y203) in human OGG1 (hOGG1) found to be involved in opposite base interaction. To address the sequence basis for functional differences with respect to opposite base interactions, we prepared three CacOgg variants, M132R, F179Y, and M132R/F179Y. All three variants showed a substantial increase in specificity for 8-oxoG.C relative to 8-oxoG.A. While we were unable to definitively associate these qualitative functional differences with differences in selective pressure between eukaryotes, Clostridia, and other bacteria, our results are consistent with the idea that evolution of Ogg function is based on kinetic control of repair.
Project description:Formamidopyrimidine-DNA glycosylase (Fpg) excises 8-oxoguanine (oxoG) from DNA but ignores normal guanine. We combined molecular dynamics simulation and stopped-flow kinetics with fluorescence detection to track the events in the recognition of oxoG by Fpg and its mutants with a key phenylalanine residue, which intercalates next to the damaged base, changed to either alanine (F110A) or fluorescent reporter tryptophan (F110W). Guanine was sampled by Fpg, as evident from the F110W stopped-flow traces, but less extensively than oxoG. The wedgeless F110A enzyme could bend DNA but failed to proceed further in oxoG recognition. Modeling of the base eversion with energy decomposition suggested that the wedge destabilizes the intrahelical base primarily through buckling both surrounding base pairs. Replacement of oxoG with abasic (AP) site rescued the activity, and calculations suggested that wedge insertion is not required for AP site destabilization and eversion. Our results suggest that Fpg, and possibly other DNA glycosylases, convert part of the binding energy into active destabilization of their substrates, using the energy differences between normal and damaged bases for fast substrate discrimination.
Project description:Although the cation-pi pair, formed between a side chain or substrate cation and the negative electrostatic potential of a pi system on the face of an aromatic ring, has been widely discussed and has been shown to be important in protein structure and protein-ligand interactions, there has been little discussion of the potential structural and functional importance in proteins of the related anion-aromatic pair (i.e., interaction of a negatively charged group with the positive electrostatic potential on the ring edge of an aromatic group). We posited, based on prior structural information, that anion-aromatic interactions between the anionic Asp general base and Phe54 and Phe116 might be used instead of a hydrogen-bond network to position the general base in the active site of ketosteroid isomerase from Comamonas testosteroni as there are no neighboring hydrogen-bonding groups. We have tested the role of the Phe residues using site-directed mutagenesis, double-mutant cycles, and high-resolution X-ray crystallography. These results indicate a catalytic role of these Phe residues. Extensive analysis of the Protein Data Bank provides strong support for a catalytic role of these and other Phe residues in providing anion-aromatic interactions that position anionic general bases within enzyme active sites. Our results further reveal a potential selective advantage of Phe in certain situations, relative to more traditional hydrogen-bonding groups, because it can simultaneously aid in the binding of hydrophobic substrates and positioning of a neighboring general base.
Project description:DNA polymerase (pol) iota, a member of the mammalian Y-family of DNA polymerases involved in translesion DNA synthesis, has been previously suggested to peculiarly utilize Hoogsteen base pairing for DNA synthesis opposite template purines, unlike pols eta and kappa, which utilize Watson-Crick (W-C) base pairing. To investigate the possible roles of Hoogsteen, W-C, and wobble base-pairing modes in the selection of nucleotides opposite template pyrimidines by human pol iota, we carried out kinetic analyses of incorporation of modified purine nucleoside triphosphates including 7-deazapurines, inosine, 2-aminopurine, 2,6-diaminopurine, and 6-chloropurine, which affect H-bonding in base-pair formation opposite template pyrimidines. Carbon substitution at the N7 atom of purine nucleoside triphosphates, which disrupts Hoogsteen base pairing, only slightly inhibited DNA synthesis opposite template pyrimidines by pol iota, which was not substantially different from human pols eta and kappa. Opposite template T, only the relative wobble stabilities (inferred from the potential numbers of H-bonding, steric, and electrostatic interactions but not measured) of base pairs were positively correlated to the relative efficiencies of nucleotide incorporation by pol iota but not the relative W-C or Hoogsteen stabilities, unlike pols eta and kappa. In contrast, opposite C, only the relative W-C stabilities of base pairs were positively correlated to the relative efficiencies of nucleotide incorporation by pol iota, as with pols eta and kappa. These results suggest that pol iota might not indispensably require Hoogsteen base pairing for DNA synthesis opposite pyrimidines but rather might prefer wobble base pairing in the selection of nucleotides opposite T and W-C base pairing opposite C.