Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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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)

A new system for studying the molecular mechanisms of mutation by carcinogens is described. The system involves (a) site-specific modification of the essential gene G in phi X174 replicative form DNA by a combination of chemical and enzymatic steps; (b) production of mutant virus carrying a change at a single preselected site by transfection of spheroplasts with the site modified phi X174 DNA; (c) detection and propagation of mutants using a host carrying the plasmid, p phi XG, that rescues all type of gene G mutants by complementation; (d) identification of the mutation in the progeny virus by isolating and sequencing mutant phi X174 DNA in the region that carried the parental, site-specific change. To demonstrate that this system is operational, we have produced a previously unknown phi X174 gene G mutant carrying a C leads to T base change at position 2401 of the viral (plus) strand. This preplanned, nonsense (amber) mutant was obtained by changing G to A at the appropriate position in a chemically synthesized, octadeoxynucleotide, minus strand primer; elongating this enzymatically with Escherichia coli DNA polymerase I (larger fragment) (lacking 5' leads to 3' exonuclease activity) to a 17-mer; and repriming to obtain the site-modified phi X174 replicative form DNA enzymatically with E. coli DNA polymerase I (large fragment) and T4 DNA ligase. After transfection of spheroplasts with the heteroduplex DNA, the lysate was screened for mutant virus with permissive (carrying p phi XG) and nonpermissive (without p phi XG) host cells. About 1% of the progeny virus were mutants. Out of 15 isolates, 11 were suppressible by an amber Su1+ (serine) or an ochre Su8+ (glutamine) suppressor. The other 4 isolates were not suppressed at all. Replicative form DNA produced from one of the suppressible mutants was shown (by sequencing) to contain the expected C leads to T change at the preselected site in the viral strand. Replicative form DNA from one of the nonsuppressible mutants was partially sequenced. No change was found at or around position 2401. The nature of the mutation(s) in these isolates is still unknown. The occurrence of mutations outside the preselected sites represent a potential problem for our projected studies, but additional data is required before the problem can be fully evaluated. In spite of this, it should be possible to study, in vivo, the biological effects of any site-specific modification (including covalent modifications by carcinogens) that can be introduced into gene G of phi X174 DNA via a synthetic, oligonucleotide primer.
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PMID:A new system for studying molecular mechanisms of mutation by carcinogens. 22 5

A pyrimidine octanucleotide complementary to one of the cohesive ends of P2 DNA was chemically synthesized. Its sequence, d(C-T-T-T-C-C-C-C-OH), was verified by labeling it at the 5' end, followed by partial enzyme digestion and separation by a two-dimensional fingerprinting system. A single ribo-G residue was added to its 3' end using calf thymus deoxynucleotidyl terminal transferase. The resulting nonanucleotide primer was used in a detailed study on the stability of the duplexes formed in the partial as well as complete repair synthesis catalyzed by DNA polymerase I, at 5 degrees C in the presence of 70 mM potassium phosphate and 70 mM NaCl. The nonanucleotide primer was able to form a stable duplex with P2 DNA template only in the presence of DNA polymerase I. When the chain lengths of pyrimidine oligonucleotides were varied from 4 to 8 to test their abilities to serve as primers for the enzymatic repair synthesis, it was revealed that the minimum length required for the primer function is 8. Using the nonanucleotide as the primer and the right-hand cohesive end of the DNA as the template, repair synthesis was initiated simultaneously at the 3' end of the primer as well as at the right-hand 3' end of the DNA. This resulted in a decrease in the efficiency of repair synthesis at the 3' end of the primer, possibly due to the displacement of the primer by the enzyme. The enzyme was unable to displace the primer, when the primer was extended to a 13-mer prior to the initiation of repair synthesis at the 3'-OH end of the DNA. These data suggest that the strand displacement by DNA polymerase I at 5 degrees C in the presence of 70 mM potassium phosphate and 70 mM NaCl is not significant when the duplex is at least 13 nucleotides long. The efficiency of the repair synthesis at the 3'-OH end of the DNA-primer duplex could be increased by blocking the repair synthesis at the 3'-OH end of the DNA by converting it to 3'- phosphate. This method could be useful in DNA sequence analysis, where such specific repair synthesis is desired.
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PMID:Chemical synthesis of an octanucleotide complementary to a portion of the cohesive end of P2 DNA and studies on the stability of duplex formation with P2 DNA. 85 84

A synthetic DNA fragment of 19 residues was enlarged by the enzymatic addition of deoxyadenylate residues to its 3'-end with calf thymus terminal deoxynucleotidyl transferase. The 3'-terminus of this elongated DNA strand was blocked with 2', 3'-dideoxyadenylate to prevent hydrolysis by the 3'-exonuclease function of E. coli DNA polymerase I. This elongated and 3'-blocked fragment was annealed to an oligomeric primer and used as a template for the synthesis of a complementary copy of the synthetic 19-mer. The product of such a repair synthesis was separated by gel filtration and analyzed by nearest neighbor techniques. All template strands were copied with complete repair in over 90% of the chains. Facile recovery of the elongated template by virtue of its size permitted repetition of the copy process, thus allowing accumulation of the desired strand.
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PMID:Enzymatic multiplication of a chemically synthesized DNA fragment. 109 43

Oligothymidylic acids couple to an activated ester silica (N-hydroxysuccinimidyl-silica) only when they contain an added aminoalkyl group. Heteropolymeric oligomers containing other nucleotide bases were shown to also couple by way of the nucleotide base (adenine, cytosine, or guanine); however, when a heteropolymeric oligonucleotide also contains a 5'-aminoalkyl moiety, coupling by way of the latter is the favored reaction. When duplex hybrids of oligonucleotides are formed, the nucleotide bases are protected from chemical coupling. Coupling by way of nucleotide bases would be detrimental to some chromatography experiments. On the basis of these observations, two different procedures were developed to produce DNA-silicas in which a single strand of the DNA is coupled by only its 5'-terminus. In the first of these, the polymerase chain reaction was used with a 5'-aminoalkyl primer to make a duplex DNA with one strand containing the 5'-aminoalkyl group and the duplex DNA is then coupled to the activated ester silica. This yielded a silica containing about 0.17 nmol of a 242-mer per gram silica which bound only probes specific for the coupled strand. In the other procedure, a template DNA strand was poly(A) tailed and hybridized to (dT)18-silica. DNA polymerase I (Klenow large fragments) was then used to copy the template-specified sequence directly onto the 3'-terminus of the (dT)18. This procedure yielded about 1.2 to 2.7 nmol DNA copied/g of silica of a specific 21-mer sequence. The DNA-silica produced selectively hybridized only with complementary sequences and not with DNA lacking that sequence. Either of these procedures thus produces DNA-silicas from heteropolymeric DNA sequences with a predetermined, specific 5'-terminal site of attachment.
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PMID:Enzymatic syntheses of DNA-silicas using DNA polymerase. 132 35

The minimal kinetic mechanism for misincorporation of a single nucleotide (dATP) into a short DNA primer/template (9/20-mer) by the Klenow fragment of DNA polymerase I [KF(exo+)] has been previously published [Kuchta, R. D., Benkovic, P., & Benkovic, S.J. (1988) Biochemistry 27, 6716-6725]. In this paper are presented refinements to this mechanism. Pre-steady-state measurements of correct nucleotide incorporation (dTTP) in the presence of a single incorrect nucleotide (dATP) with excess KF-(exo+) demonstrated that dATP binds to the KF(exo+)-9/20-mer complex in two steps preceding chemistry. Substitution of (alpha S)dATP for dATP yielded identical two-step binding kinetics, removing nucleotide binding as a cause of the elemental effect on the rate of misincorporation. Pyrophosphate release from the ternary species [KF'(exo+)-9A/20-mer-PPi] was found to occur following a rate-limiting conformational change, with this species partitioning equally to either nucleotide via internal pyrophosphorolysis or to misincorporated product. The rate of 9A/20-mer dissociation from the central ternary complex (KF'-9A/20-mer-PPi) was shown to be negligible relative to exonucleolytic editing. Pyrophosphorolysis of the misincorporated DNA product (9A/20-mer), in conjunction with measurement of the rate of dATP misincorporation, permitted determination of the overall equilibrium constant for dATP misincorporation and provided a value similar to that measured for correct incorporation. A step by step comparison of the polymerization catalyzed by the Klenow fragment for correct and incorrect nucleotide incorporation emphasizes that the major source of the enzyme's replicative fidelity arises from discrimination in the actual chemical step and from increased exonuclease activity on the ternary misincorporated product complex owing to its slower passage through the turnover sequence.
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PMID:Minimal kinetic mechanism for misincorporation by DNA polymerase I (Klenow fragment). 132 9

The incorporation of 6-thioguanine (S6G) in place of guanine proceeds readily in DNA synthesis reactions catalyzed by mammalian and bacterial polymerases. This report summarizes the consequences of such incorporation studied to date. S6G was incorporated into one strand of a defined M13mp18 phage sequence in a (+)reaction catalyzed by the Klenow fragment of Escherichia coli DNA polymerase I. After denaturation of the newly synthesized strand (containing S6G) and annealing with a reverse (-) 32P-labeled primer, polymerization catalyzed by the Klenow enzyme as well as by human DNA polymerases alpha, gamma, and delta was slowed considerably, compared with that across the corresponding guanine-containing template. To evaluate S6G-containing DNA as a substrate for DNA ligases, two oligodeoxynucleotides (19- and 20-mers) antisense to a 40-mer were synthesized so that the 40-mer coded for guanine at the 3' terminus of the 19-mer. After annealing of the synthetic oligonucleotides to form a duplex DNA containing a one-nucleotide gap (opposite cytosine in the 40-mer), the 19-mer was extended with 2'-deoxythioguanosine 5'-triphosphate using DNA polymerase, forming a nicked duplex DNA. The abilities of T4 DNA ligase and HeLa and calf thymus DNA ligase I to join the 5'-phosphate with the 3'-S6G-OH were severely inhibited, compared with the 3'-guanine-extended control. This finding suggests that incorporation of S6G at the 3' terminus of Okazaki fragments would inhibit lagging strand DNA synthesis. In other experiments, cleavage of S6G-containing DNA by some but not all restriction endonucleases progressed poorly, compared with the control guanine-containing DNA, independently of the location of S6G at recognition or cleavage sites, as previously observed by Iwaniec et al. [Mol. Pharmacol. 39:299-306 (1991)] with a different spectrum of enzymes. These findings indicate altered DNA-protein interactions due to S6G incorporation. The poor template function of S6G-containing DNA is consistent with the known delayed cytotoxicity and DNA damage previously reported to occur in S6G-treated cells.
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PMID:Consequences of 6-thioguanine incorporation into DNA on polymerase, ligase, and endonuclease reactions. 133 62

The DNA polymerase from the bacteriophage T4 is part of a multienzyme complex required for the synthesis of DNA. As a first step in understanding the contributions of individual proteins to the dynamic properties of the complex, e.g., turnover, processivity, and fidelity of replication, the minimal kinetic schemes for the polymerase and exonuclease activities of the gene 43 protein have been determined by pre-steady-state kinetic methods and fit by computer simulation. A DNA primer/template (13/20-mer) was used as substrate; duplexes that contained more single-strand DNA resulted in nonproductive binding of the polymerase. The reaction sequence features an ordered addition of 13/20-mer followed by dATP to the T4 enzyme (dissociation constants of 70 nM and 20 microM) followed by rapid conversion (400 s-1) of the T4.13/20-mer.dATP complex to the T4.14/20-mer.PPi product species. A slow step (2 s-1) following PPi release limits a single turnover, although this step is bypassed in multiple incorporations (13/20-mer-->17/20-mer) which occur at rates > 400 s-1. Competition between correct versus incorrect nucleotides relative to the template strand indicates that the dissociation constants for the incorrect nucleotides are at millimolar values, thus providing evidence that the T4 polymerase, like the T7 but unlike the Klenow fragment polymerases, discriminates by factors > 10(3) against misincorporation in the nucleotide binding step. The exonuclease activity of the T4 enzyme requires an activation step, i.e., T4.DNA-->T4.(DNA)*, whose rate constants reflect whether the 3'-terminus of the primer is matched or mismatched; for matched 13/20-mer the constant is 1 s-1, and for mismatched 13T/20-mer, 5 s-1. Evidence is presented from crossover experiments that this step may represent a melting of the terminus of the duplex, which is followed by rapid exonucleolytic cleavage (100s-1). In the presence of the correct dNTP, primer extension is the rate-limiting step rather than a step involving travel of the duplex between separated exonuclease and polymerase sites. Since the rate constant for 13/20-mer or 13T/20-mer dissociation from the enzyme is 6 or 8 s-1 and competes with that for activation, the exonucleolytic editing by the enzyme alone in a single pass is somewhat inefficient (5 s-1/(8 s-1+5 s-1)), ca. 40%. Consequently, a major role for the accessory proteins may be to slow the rate of enzyme.substrate dissociation, thereby increasing overall fidelity and processivity.
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PMID:Kinetic characterization of the polymerase and exonuclease activities of the gene 43 protein of bacteriophage T4. 133 48

A synthetic RNA oligonucleotide (15-mer) corresponding to the 3' end of the lysine tRNA primer was hybridized to single-stranded DNA containing the human immunodeficiency virus type 1 (HIV-1) primer-binding site and extended with a DNA polymerase. The resulting structures were used to study primer removal by the RNase H activity of HIV-1 reverse transcriptase. The initial cleavage event removes the RNA primer as a 14-mer and leaves a single ribonucleotide A residue bound to the 5' end of the DNA strand. This result explains the observation by several groups that HIV-1 circle junctions contain 4 bp that are not present in the integrated provirus instead of the predicted 3 bp. Subsequent cleavage events occur at other sites internal to the RNA molecule, and the ribonucleotide A residue on the end of the DNA strand is ultimately removed. Therefore, the biologically relevant cleavage that produces the 14-mer reflects the kinetics of the reaction as well as a specificity for nucleic acid sequence. When the RNA oligonucleotide alone was hybridized to the primer-binding site and tested as a substrate for HIV-1 RNase H, the cleavage pattern near the 3' end of the RNA was altered.
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PMID:Incomplete removal of the RNA primer for minus-strand DNA synthesis by human immunodeficiency virus type 1 reverse transcriptase. 137 87

A previous study of UV-induced (254 nm) mutations in the lacI gene of Escherichia coli found that frameshift mutations accounted for about 35% of the observed mutations and that these mutations occurred predominantly at An.Tn sequences [Miller, J.H. (1985) J. Mol. Biol. 182, 48-65]. Because An.Tn sequences are hotspots for cis-syn thymine dimer formation [Brash, D.E., & Haseltine, W. A. (1982) Nature 298, 189-192], it would appear that UV-induced frameshift mutations are the result of an error during replicative bypass of a thymine dimer within such a sequence. To test the validity of such a proposal, replication experiments were carried out on templates containing cis-syn thymine dimers at each of the five possible sites of a T6 tract. The 59-mer templates were prepared by ligating oligonucleotides containing an EcoRI site to the 5'-end of decamers containing the cis-syn thymine dimer and oligonucleotides containing the primer site to the 3'-end. Primer-extension reactions were then carried out on these templates with a 3'----5' exonuclease-deficient (exo-) Klenow fragment of E. coli polymerase I and an exo-T7 polymerase (Sequenase Version 2.0). The replicative bypass products were cleaved with EcoRI to rigorously establish and quantify the presence of frameshift mutations. Both polymerases were able to bypass dimers at all sites, but only the exo-T7 polymerase led to detectable frameshifts, both -1 (approximately 30%) and -2 (approximately 5%), and only with the template containing a cyclobutane dimer at the second site from the 5'-end of the T6 tract. Sequencing of the T7 polymerase-catalyzed bypass products of all templates demonstrated that within the limits of discrimination only As were introduced opposite the dimer-containing T tracts. The only exception was for the template with the dimer at the second site which led to a readily detectable amount of a substitution mutation (approximately 30%) opposite the 5'-thymine of the T6 tract. A mechanism involving a competition between reversible misalignment and realignment steps and irreversible elongation steps is proposed to explain the origin of both the frameshift and the substitution mutations. The implications of this work to the mechanism of UV-induced frameshift and substitution mutations at T tracts in vivo are discussed.
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PMID:In vitro evidence that UV-induced frameshift and substitution mutations at T tracts are the result of misalignment-mediated replication past a specific thymine dimer. 156 22

Introduction of a reactive 5-mercapto group into some of the cytosine and/or uracil bases of various oligo- and polynucleotides by partial thiolation resulted in several potent inhibitors of the replication of human immunodeficiency virus type 1 (HIV-1) in primary human lymphocytes. These compounds exhibited little if any toxicity against uninfected peripheral blood mononuclear cells and showed 15 to 75 times higher antitemplate activity against a p66/p51 HIV-1 recombinant reverse transcriptase (RT) than against the DNA polymerase alpha from human lymphocytes. In contrast, the unthiolated oligo- and polynucleotides are void of antitemplate activity, and their apparent inhibitory effect on HIV-1 closely paralleled their toxicity for the cells. Partially thiolated poly(dC) (MPdC) was the most potent of all the compounds tested against HIV-1 in peripheral blood mononuclear cells (50% effective concentration, 1.8 micrograms/ml or 0.019 microM), while showing low cytotoxicity (greater than 100 micrograms/ml). The corresponding unmodified poly(dC) showed no anti-HIV-1 activity at 50 micrograms/ml but had pronounced cytotoxicity. MPdC was also a potent inhibitor of HIV-1 RT (50% inhibitory concentration, 0.30 micrograms/ml). The inhibitory activities of thiolated homooligo(dCs) against both HIV-1 replication and HIV-1 RT increased with increasing chain length. The heterooligonucleotides included in this study were designed as structural analogs of portions of the natural primer of HIV-1 RT, i.e., tRNA(3Lys). An 18-mer analog of the 3' terminus, complementary (antisense) to the primer-binding site of the HIV-1 genome, was attached to an oligo(dC) tail and 5-thiolated; this increased its activity and decreased its toxicity. This compound will serve as a new lead in the development of more effective antitemplates against HIV-1.
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PMID:Structure-activity relationships and mode of action of 5-mercapto-substituted oligo- and polynucleotides as antitemplates inhibiting replication of human immunodeficiency virus type 1. 159 Jun 75


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