EC:2.7.7.7 - FACTA Search

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Query: EC:2.7.7.7 (DNA polymerase)
17,007 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The inherent infidelity of Taq DNA polymerase in the polymerase chain reaction was exploited to produce random mutations in the trp A gene. Screening of the resulting clones allowed selection of non-interactive mutant alpha subunits retaining their intrinsic catalytic activity. Two single changes responsible for this phenotype were identified by DNA sequencing as: alpha 126 valine (GTG)----glutamic acid (GAG) and alpha 128 valine (GTT)----aspartic acid (GAT). Three single changes giving a non-interactive phenotype with an impaired intrinsic catalytic activity were identified by DNA sequencing as alpha 66 asparagine (AAC)----aspartic acid (GAC); alpha 109 lysine (AAA)----arginine (AGA); alpha 118 cysteine (TGC)----arginine (CGC). Where possible, we individually assessed the importance of these residues in alpha beta interaction in light of structural information from X-ray crystallography and by intergeneric protein sequence comparison.
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PMID:Selection and analysis of non-interactive mutants in the Escherichia coli tryptophan synthase alpha subunit. 160 55

The polA1 mutation of Escherichia coli K12 and two further mutations, resA1 and resA2, characterized in E. coli B have been shown to produce enzymatically active nonsense (amber) peptides. These enzymes can be purified to virtual homogeneity by use of the lambda polA transducing phage system. The peptides are immunologically related and react weakly but specifically with antibody to whole DNA polymerase I. In their purified form the peptides are less heat-labile than the whole enzyme or the Klenow fragment produced by proteolysis. Physiological studies indicate that all three alleles are compatible with a number of different streptomycin resistance mutations (rpsL alleles) in a variety of genetic backgrounds. There is, however, clear evidence for slight amounts of "read-through" of these mutations under these conditions. DNA sequence studies have indicated the exact nucleotides that have been mutated to produce the amber alleles. The resA1 and resA2 alleles appear to be independent isolates of the same mutation both resulting in CAG (Gln) leads to TAG (amber) at amino acid residue 298. The polA1 mutation results in TGC (Trp) leads to TAG (amber) at amino acid residue 342. The significance of these findings is discussed with reference to the structure of the whole enzyme as shown by the DNA sequence data of Joyce et al. (1982) and protein chemistry of Brown et al. (1982).
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PMID:Genetic characterization of early amber mutations in the Escherichia coli polA gene and purification of the amber peptides. 630 78

We describe a procedure by which the codon (AGC) for the active-site serine-70 of pBR322 beta-lactamase (penicillinase, penicillin amido-beta-lactamhydrolase, EC 3.5.2.6) is altered to that for cysteine (TGC). The pertinent nucleotide bases, A-G-C-A, positions 410-413, of pBR322 are excised by treating a limited HgiAI digest of pBR322 with the 3' leads to 5' exonuclease of T4 DNA polymerase. The new sequence, T-G-C-A, is inserted in two steps. First, the Kpn I molecular linker d(T-G-G-T-A-C-C-A) is ligated into the gap described above. The internal sequence G-T-A-C is then excised enzymatically with Kpn I and T4 DNA polymerase and the molecule is recircularized. This mutant gene, which codes for a thiol-beta-lactamase, confers on Escherichia coli K-12 hosts an ampicillin resistance that is reduced compared with that given by pBR322 yet is greater than that of E. coli lacking any intact beta-lactamase gene. Cell-free extracts of E. coli strains hosting the thiol-beta-lactamase gene possess a p-chloromercuribenzoate-sensitive beta-lactamase activity.
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PMID:Thiol-beta-lactamase: replacement of the active-site serine of RTEM beta-lactamase by a cysteine residue. 681 41

To assess which residues of Oct-1 POU-specific (POUs) are important for DNA recognition and stimulation of adenovirus DNA replication we have mutated 10 residues of the POUs helix-turn-helix motif implicated in DNA contact. Seven of these turned out to have reduced DNA binding affinity. Of these, three alanine substituted proteins were found to have a changed specificity using a binding site selection procedure. Mutation of the first residue in the recognition helix, Gln44, to alanine led to a loss of specificity for the first two bases, TA, of the wild-type recognition site TATGC(A/T)AAT. Instead of the A, a T was selected, suggesting a new contact and a novel specificity. A change in specificity was also observed for the T45A mutant, which could bind to TATAC(A/T)AAT, a site hardly recognized by the wild-type protein. Mutation of residue Arg49 led to a relaxed specificity for three consecutive bases, TGC. This residue, which is critical for high affinity binding, is absent from the structurally homologous lambdoid helix-turn-helix motifs. Employing a reconstituted system all but two mutants could stimulate adenovirus DNA replication upon saturation. Mutation of residues Gln27 and Arg49 impairs the ability of the Oct-1 POU domain protein to enhance replication, with a concomitant loss of DNA contacts. Since the POU domain binds the precursor terminal protein-DNA polymerase complex and guides it to the origin, lack of stimulation may be caused by incorrect targetting of the DNA polymerase due to loss of specificity.
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PMID:Mutation of the Oct-1 POU-specific recognition helix leads to altered DNA binding and influences enhancement of adenovirus DNA replication. 766 96

The process of carcinogenesis is initiated by mutagenesis, which often involves replication past damaged DNA. One question - what exactly is a DNA polymerase seeing when it incorrectly copies a damaged DNA base (e.g., inserting dATP opposite a dG adduct)? - has not been answered in any case. Herein, we reflect on this question, principally by considering the mutagenicity of one activated form of benzo[a]pyrene, (+)-anti-B[a]PDE, and its major adduct [+ta]-B[a]P-N(2)-dG. In previous work, [+ta]-B[a]P-N(2)-dG was shown to be capable of inducing>95% G-->T mutations in one sequence context (5'-TGC), and approximately 95% G-->A mutations in another (5'-AGA). This raises the question - how can a single chemical entity induce different mutations depending upon DNA sequence context? Our current working hypothesis is that adduct conformational complexity causes adduct mutational complexity, where DNA sequence context can affect the former, thereby influencing the latter. Evidence supporting this hypothesis was discussed recently (Seo et al., Mutation Res. [in press]). Assuming this hypothesis is correct (at least in some cases), one goal is to consider what these mutagenic conformations might be. Based on molecular modeling studies, 16 possible conformations for [+ta]-B[a]P-N(2)-dG are proposed. A correlation between molecular modeling and mutagenesis work suggests a hypothesis (Hypothesis 3): a base displaced conformation with the dG moiety of the adduct in the major vs. minor groove gives G-->T vs. G-->A mutations, respectively. (Hypothesis 4, which is a generalized version of Hypothesis 3, is also proposed, and can potentially rationalize aspects of both [+ta]-B[a]P-N(2)-dG and AP-site mutagenesis, as well as the so-called "A-rule".) Finally, there is a discussion of how conformational complexity might explain some unusual mutagenesis results that suggest [+ta]-B[a]P-N(2)-dG can become trapped in different conformations, and why we think it makes sense to interpret adduct mutagenesis results by modeling ds-DNA (at least in some cases), even though the mutagenic event must occur at a ss/ds-DNA junction in the presence of a DNA polymerase.
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PMID:Toward an understanding of the role of DNA adduct conformation in defining mutagenic mechanism based on studies of the major adduct (formed at N(2)-dG) of the potent environmental carcinogen, benzo[a]pyrene. 1083 33

The presence of benzo[a]pyrene diol epoxide (B[a]PDE) adducts in DNA is known to interfere with DNA replication. Kinetic studies of nucleotide insertion by exonuclease-deficient E. coli DNA polymerase I (Klenow fragment) across from either the (+)-trans- or the (+)-cis-B[a]P-N(2)-dG adduct in the 5'-CGT-3' sequence context indicated that the rate of nucleotide incorporation followed the order: dAMP > dGMP > dTMP > dCMP, which did not correlate with the mutational spectrum observed for these adducts in this sequence in E. coli (mostly G-->A transitions). Interestingly, a kinetic analysis of extension past the adduct showed that, unlike other sequences studied, the primer-template was extended best when dT was positioned at the 3'-terminus of the primer across from either a (+)-trans- or a (+)-cis-B[a]P-N(2)-dG adduct. In contrast, when the (+)-trans-B[a]P-N(2)-dG adduct was positioned in the 5'-TGC-3' sequence context, which gives predominantly G-->T mutations in E. coli, extension was detectable only when dA was positioned across from the adduct. These data provide the first in vitro evidence that may explain why G-->A transitions, rather than the G-->T transversions found in other sequences, are preferred in the 5'-CGT-3' sequence in vivo.
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PMID:In vitro replication of primer-templates containing benzo[a]pyrene adducts by exonuclease-deficient Escherichia coli DNA polymerase I (Klenow fragment): effect of sequence context on lesion bypass. 1095 33

The potent mutagen/carcinogen benzo[a]pyrene (B[a]P) is activated to (+)-anti-B[a]PDE, which induces a variety of mutations (e.g., G --> T, G --> A, etc.) via its major adduct [+ta]-B[a]P-N2-dG. One hypothesis is that adducts (such as [+ta]-B[a]P-N2-dG) induce different mutations via different conformations, probably when replicated by different lesion-bypass DNA polymerases (DNAPs). We showed that Escherichia coli DNAP V was responsible for G --> T mutations with [+ta]-B[a]P-N2-dG in a 5'-TGT sequence (Yin et al., (2004) DNA Repair 3, 323), so we wish to study conformations of this adduct/sequence context by molecular modeling. The development of a CHARMM-based molecular dynamics (MD) simulations protocol with free-energy calculations in the presence of solvent and counterions is described. A representative base-pairing and base-displaced conformation of [+ta]-B[a]P-N2-dG in the 5'-TGT sequence are used: (1) BPmi5, which has the B[a]P moiety in the minor groove pointing toward the base on the 5'-side of the adduct, and (2) Gma5, which has the B[a]P moiety stacked with the surrounding base pairs and the dG moiety displaced into the major groove. The MD output structures are reasonable when compared to known NMR structures. Changes in DNA sequence context dramatically affect the biological consequences (e.g., mutagenesis) of [+ta]-B[a]P-N2-dG. Consequently, we also developed a MD-based free-energy perturbation (FEP) protocol to study DNA sequence changes. FEP involves the gradual "fading-out" of atoms in a starting structure (A) and "fading-in" of atoms in a final structure (B), which allows a realistic assessment of the energetic and structural changes when two structures A and B are closely related. Two DNA sequence changes are described: (1) 5'-TGT --> 5'-TGG, which involves two steps [T:A --> T:C --> G:C], and (2) 5'-TGT --> 5'-TGC, which involves three steps [T:A --> T:2AP --> C:2AP --> C:G], where 2AP (2-aminopurine) is included, because T:2AP and C:2AP retain more-or-less normal pairing orientations between complementary bases. FEP is also used to evaluate the impact that a 5'-TGT to 5'-UGT sequence change might have on mutagenesis with [+ta]-B[a]P-N2-dG. In summary, we developed (1) a CHARMM-based molecular dynamics (MD) simulations protocol with free-energy calculations in the presence of solvent and counterions to study B[a]P-N2-dG adducts in DNA duplexes, and (2) a MD-based free-energy perturbation (FEP) protocol to study DNA sequence context changes around B[a]P-N2-dG adducts.
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PMID:Free-energy perturbation methods to study structure and energetics of DNA adducts: results for the major N2-dG adduct of benzo[a]pyrene in two conformations and different sequence contexts. 1602 3