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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)
DNA polymerase
from RNA tumor viruses ("reverse transcriptase") has been analyzed for activities which have been associated with other DNA polymerases. Homogeneous
DNA polymerase
from avian myeoblastosis virus catalyzes pyrophosphate exchange and pyrophosphorolysis.
Pyrophosphate
exchange is dependent on a template and is base-specific. With avian myeloblastosis virus
DNA polymerase
, ribonucleotide templates are more efficient for synthesis while deoxyribonucleotide templates are more effective for pyrophosphate exchange. Synthesis, pyrophosphate exchange, and pyrophosphorolysis were inhibited by the chelating agent 1,10-phenanthroline, suggesting that enzyme-bound zinc is required for each of these reactions. The pyrophosphate exchange reaction was also demonstrated with the
DNA polymerase
from a mutant of Rous sarcoma virus that possesses a temperature-sensitive
DNA polymerase
. The pyrophosphate exchange reaction with the mutant polymerase is temperature-sensitive which demonstrates that pyrophosphate exchange is indeed catalyzed by the viral
DNA polymerase
and that the same mutation effects both
DNA polymerase
and pyrophosphatase activity. Unlike Escherichia coli
DNA polymerase I
, the
DNA polymerase
from avian myeloblastosis virus fails to degrade polydeoxyribonucleotides or to convert deoxynucleoside triphosphates into monophosphates. This lack of hydrolytic activities in avian myeoblastosis
DNA polymerase
should facilitate kinetic studies on the mechanism of DNA synthesis by this enzyme.
...
PMID:On the fidelity of DNA replication. Enzyme activities associated with DNA polymerases from RNA tumor viruses. 5 14
A steady state kinetic study of Escherichia coli
DNA polymerase I
has been carried out using poly[d(A-T)] as the template-primer substrate. The results of substrate saturation and product inhibition kinetic studies suggest an altered Ordered Bi Bi mechanism for the enzyme. The Michaelis constants for polymer, d-atp, and dTTP are 5 nM (3'-OH ends), 1 muM, and 2 muM, respectively. The apparent equilibrium constant for the reaction, Keq equals [
PPi
]/[dNTP], was estimated as greater than or equal to 500. No quaternary complex of enzyme, template, and both deoxynucleoside triphosphates was detected. Single turnover experiments at 4 degrees indicated that the enzyme functions non-processively under the specified conditions, that is, dissociates after each catalytic step. The results at higher temperature were consistent with dissociation within 30 steps. Furthermore, at 4 degrees a burst of incorporation stoichiometric with the amount of enzyme was observed upon initiation of the reaction, indicating that the rate-limiting step in the steady state occurs after phosphodiester bond formation. There is a linear Arrhenius dependence of the initial reaction on temperature in the range 4-40 degrees, with an apparent Ea equals 17 kcal/mol. The rate equations appropriate for template-dependent polymerases which dissociate after each catalytic step have been derived.
...
PMID:The steady state kinetic parameters and non-processivity of Escherichia coli deoxyribonucleic acid polymerase I. 109 83
The freshly prepared crude cytoplasmic fraction of aqueously extracted KB cells contains a single major species of
DNA polymerase
activity (
DNA polymerase
C) that sediments homogeneously in low ionic strength sucrose gradients with a peak at 10.8 S. The enzyme activity from frozen crude extracts sediments heterogeneously under these conditions with peaks at 8.4 and 10 S. In 0.45 M salt-containing gradients all of the polymerase activity is recovered as a single 6.4 S species. When purified to a specific activity of 7,300,
DNA polymerase
C sediments in low ionic strength gradients as a single species of 6.5 S. From combined sedimentation and gel filtration analysis, we estimate the molecular weight of the active protomeric species of the polymerase to be about 170,000. Under no conditions of ionic strength does the enzyme disaggregate to active species smaller than 6.4 to 6.5 S. Sodium dodecyl sulfate-polyacrylamide gel analysis of the most highly purified enzyme fractions reveals two major protein bands of 87,000 and 175,000 daltons, respectively. These data suggest that
DNA polymerase
C contains an 87,000-dalton component and permit the interpretation that the active protomer of Mr equal 170,000 may be a dimer. The purified enzyme shows maximal activity with gapped duplex DNA and has an absolute requirement for 3'-hydroxyl termini. It utilizes initiated polydeoxynucleotide templates poorly and initiated polyribonucleotide templates not at all. Although the polymerase is inhibited by
PPi
it has only minimal ability to promote
PPi
exchange (0.8% of the polymerase activity). The purified enzyme is free of endonuclease and exonuclease activities (less than or equal to 0.003% of the polymerase activity) and demonstrates no primer-template-dependent conversion of substrate dNTP to free dNMP during the polymerization reaction. Finally,
DNA polymerase
C does not excise misparied primer termini from a synthetic homopolymer primer-template but can utilize such termini as initiation sites, although at a very slow rate.
...
PMID:"Cytoplasmic" deoxyribonucleic acid polymerase. Structure and properties of the highly purified enzyme from human KB cells. 109
We have shown that a drug-resistant mutant from a clinical isolate of herpes simplex virus contains a single point mutation in the
DNA polymerase
gene that confers resistance to both acyclovir and foscarnet. The mutated amino acid is located within a distinct conserved region shared among alpha-like DNA polymerases which we designate region VII. We infer that these conserved sequences are directly or indirectly involved in the recognition and binding of nucleotide and
PPi
substrates.
...
PMID:A point mutation within a distinct conserved region of the herpes simplex virus DNA polymerase gene confers drug resistance. 131 Jul 79
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.
...
PMID:Minimal kinetic mechanism for misincorporation by DNA polymerase I (Klenow fragment). 132 9
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.
...
PMID:Kinetic characterization of the polymerase and exonuclease activities of the gene 43 protein of bacteriophage T4. 133 48
In a previously determined minimal kinetic scheme for DNA polymerization catalyzed by the
Klenow fragment
(KF) of Escherichia coli
DNA polymerase I
, a nonchemical step that interconverted the KF'.DNAn+1.
PPi
and KF.DNAn+1PPi complexes was not observed in correct incorporation [Kuchta, R. D., Mizrahi, V., Benkovic, P.A., Johnson, K.A., & Benkovic, S.J. (1987) Biochemistry 26, 8410-8417] but was detected in misincorporation [Kuchta, R. D., Benkovic, P.A., & Benkovic, S.J. (1988) Biochemistry 27, 6716-6725]. In a pulse-chase experiment in this study, a burst amplitude of 100% of the enzyme concentration is observed; under pulse-quench conditions, the burst amplitude is 80%, indicative of the accumulation of the KF'.DNA.dNTP species owing to a slow step subsequent to chemical bond formation. This latter step was unequivocally identified by single-turnover pyrophosphorolysis and pyrophosphate-exchange experiments as one interconverting KF'.DNAn+1.
PPi
and KF.DNAn+1.
PPi
. The rate constants for this step in both directions were established through the rate constants for processive synthesis and pyrophosphorolysis. Pyrophosphorolysis of a 3'-phosphorothioate DNA duplex confirmed that the large elemental effect observed previously [Mizrahi, V., Henrie, R. N., Marlier, J.F., Johnson, K.A., & Benkovic, S.J. (1985) Biochemistry 24, 4010-4018] in this direction but not in polymerization is due to a marked decrease in the affinity of KF for the phosphorothioate-substituted duplex and not to the chemical step. The combination of the experimentally measured equilibrium constant for the bound KF.DNA species with the collective kinetic measurements further extends previous insights into the dynamics of the polymerization process catalyzed by KF.
...
PMID:Kinetic mechanism of DNA polymerase I (Klenow fragment): identification of a second conformational change and evaluation of the internal equilibrium constant. 164 80
The elementary steps of DNA polymerization catalyzed by T7
DNA polymerase
have been resolved by transient-state analysis of single nucleotide incorporation, leading to the complete pathway: [formula: see text] where E, D, N, and P represent T7
DNA polymerase
, DNA primer/template, deoxynucleoside triphosphate, and inorganic pyrophosphate, respectively. A DNA primer/template consisting of a synthetic 25/36-mer has been used as a substrate for correct nucleotide incorporation of dTTP in all the experiments. The rate constants and equilibrium constants of each step have been established by direct measurement of individual reactions and fit by computer simulation of the data to obtain a single set of rate constants accounting for all the data. Analysis of the single-turnover kinetics provided measurements of equilibrium dissociation constants for 25/36-mer, dTTP, and
PPi
equal to 18 nM (koff/kon), 18 microM (k-1/k1), and 2 mM (k5/k-5), respectively. The rate-limiting step during single-nucleotide incorporation has been identified as a conformational change, E.Dn.N----E'.Dn.N, which occurs at a rate of 300 s-1 (k2) upon binding of the correct dNTP. Accordingly, tighter binding of the transition states for the reaction resulting from the conformational change facilitates the phosphodiester bond formation. The chemical step itself was excluded as the rate-limiting step because of the small phosphothioate elemental effect. An observed rate constant of 70 s-1 for dTTP (alpha S) incorporation suggest that the chemical step (k3) occurs at a fast rate, greater than or equal to 9000 s-1. Following chemistry, the resulting ternary complex, E'.Dn+1.P, undergoes a second conformational change at a rate of 1200 s-1 (k4), leading to release of
PPi
and translocation of the DNA to continue subsequent cycles of polymerization. The rate constants of the reverse steps, 100 s-1 (k-2), greater than or equal to 18,000 s-1 (k-3) and 18 s-1 (k-4), were derived as fits to the data based upon simulation of single-turnover kinetics of pyrophosphorolysis including measurements of pyrophosphate exchange and the overall equilibrium constant of 1.0 x 10(4) for elongation of E.25/36-mer and analysis of the kinetics of the pulse-chase experiment. These studies provide the first complete and self-consistent thermodynamic descriptions of
DNA polymerase
and establish the basis for quantitative assessment of the reactions contributing to its extraordinary fidelity.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:Pre-steady-state kinetic analysis of processive DNA replication including complete characterization of an exonuclease-deficient mutant. 184 98
Phosphonoformate (PFA) is a simple
PPi
analog which inhibits the activities of a variety of viral
DNA polymerase
, RNA polymerase, and reverse transcriptase enzymes. PFA is a topical and parenteral treatment for human herpesvirus infections and is currently in phase I trials for treatment of acquired immunodeficiency syndrome. Pharmacokinetic properties of PFA in young (growing) and adult specific-pathogen-free cats were compared. Mean PFA clearance from plasma was twofold higher in young cats (7.52 ml/min per kg of body weight) than in adult cats (3.70 ml/min per kg). Higher PFA clearance from plasma observed in young cats may result from higher renal clearance or enhanced accumulation of PFA in bone tissue of young versus adult cats. No plasma protein binding of PFA was observed. Mean oral bioavailability was 35% in young cats. These data indicate that age-related differences in PFA clearance from plasma occur in cats.
...
PMID:Age-related differences in pharmacokinetics of phosphonoformate in cats. 214 79
AMP and NaF each taken separately were shown to activate DNA polymerization catalyzed by
Klenow fragment
of
DNA polymerase I
by means of interaction of AMP or NaF with 3'----5'-exonuclease center of the enzyme. In the presence of NaF which is a selective inhibitor of 3'----5'-exonuclease center, AMP is an inhibitor of polymerization competitive with respect to dATP. Ki values and the pattern of inhibition with respect to dATP were determined for AMP, ADP, ATP, carboxymethylphosphonyl-5'-AMP, Pi,
PPi
, PPPi, methylenediphosphonic acid and its ethylated esters, phosphonoformic acid, phosphonoacetic acid and its ethylated esters as well as for some bicarbonic acids in the reactions of DNA polymerization catalyzed by
Klenow fragment
of
DNA polymerase I
(in the presence of NaF) and
DNA polymerase alpha
from human placenta in the presence of poly(dT) template and r(pA)10 primer. All nucleotides and their analogs were found to be capable of competing with dATP for the active center of the enzyme. Most of the analogs of
PPi
and phosphonoacetic acid are inhibitors of
Klenow fragment
competitive with respect to dATP. Nowever these analogs display a mixed-type inhibition in the case of human
DNA polymerase alpha
. We postulated a similar mechanism of interaction for dNTP with both DNA-polymerases. It is suggested that each phosphate group of
PPi
makes equal contribution to the interaction with DNA polymerases and that the distance between the phosphate groups is important for this interaction. beta-phosphate of NTP or dNTP is suggested to make negligible contribution to the efficiency of the formation of enzyme complexes with dNTP. beta-phosphate is likely to be an essential point of
PPi
interaction with the active center of proteins during the cleavage of the alpha-beta-phosphodiester bond of dNTP in the reaction of DNA polymerization.
...
PMID:[Interaction of dNTP-binding sites of human DNA polymerase alpha and The Klenow fragment of Escherichia coli DNA polymerase I with nucleotides, pyrophosphate and their analogs]. 216 89
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