Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.7.7.49 (reverse transcriptase)
 31,746 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The amino acid change K65R in human immunodeficiency virus type 1-reverse transcriptase (RT) confers viral resistance to various 2',3'-dideoxynucleoside drugs in vivo. Using pre-steady state kinetic methods, we found that K65R-reverse transcriptase is 3.2-14-fold resistant to 2',3'-dideoxynucleotides in vitro relative to wild-type reverse transcriptase, in agreement with resistance levels observed in vivo. A decreased catalytic rate constant k(pol) mostly accounts for the lower incorporation efficiency observed for 2',3'-dideoxynucleotides. Examination of the crystal structure of the RT.DNA.dNTP complex suggested that both the charge at position 65 and the 3'-OH of the incoming nucleotide act in synergy during the creation of the phosphodiester bond, resulting in a more pronounced decreased catalytic rate constant for 2',3'-dideoxynucleotides than for dNTPs. This type of intramolecular activation of the leaving phosphate by the 3'-OH group appears to be conserved in several nucleotide phosphotransferases. These data were used to design dideoxynucleotide analogues targeting K65R RT specifically. alpha-Boranophosphate ddATP was found to be a 2-fold better substrate than dATP and inhibited DNA synthesis by K65R RT 153-fold better than ddATP. This complete suppression of drug resistance at the nucleotide level could serve for other reverse transcriptases for which drug resistance is achieved at the catalytic step.
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PMID:Mechanism-based suppression of dideoxynucleotide resistance by K65R human immunodeficiency virus reverse transcriptase using an alpha-boranophosphate nucleoside analogue. 1160 79

We report the design, synthesis and activity studies on a novel class of template-competitive reverse transcriptase inhibitors (TCRTIs). The TCRTIs are 1,N(6)-etheno analogues of a series of dATP-based template-competitive DNA polymerase inhibitors synthesized in our laboratory (Moore, B. M.; Jalluri, R.; Doughty, M.B. Biochemistry 1996, 35, 11634). Thus, nucleotides 2-(4-azidophenacyl)thio-1,N(6)-etheno-2'-deoxyadenosine 5'-triphosphate 1, the tetrafluoro analogue 2-(4-azido-2,3,5,6-tetrafluorophenacyl)thio-1,N(6)-etheno-2'-deoxyadenosine 5'-triphosphate 2 and its analogues were synthesized by alkylation of 2-thio-1,N(6)-etheno-2'-deoxyadenosine 5'-monophosphate with the corresponding chloro- or bromo-alkyl halides and converted to the triphosphate. Kinetically, nucleotides 1 and 2 are both competitive inhibitors of reverse transcriptase versus template/primer with K(i)'s of 8.0 and 7.4 microM, respectively, and non-competitive inhibitors versus TTP with K(i)'s of 15 and 10 microM, respectively. Nucleotide 3, which differs from 1 only in that it lacks the etheno group, non-complementary nucleotide triphosphates, and related monophosphates and nucleosides, are completely inactive as inhibitors of reverse transcriptase at concentrations up to 1 mM. Photoinactivation of RT by 1 was both time- and concentration-dependent, and protected by template/primer but not by dNTPs. The concentration-dependent inactivation data gave a K(D,app) of 17.2 microM and maximum inactivation of 90%, and radiolabeled [beta, gamma-32P]-1 photoincorporated specifically and covalently into the p66 subunit of RT. Thus the photoinactivation data support our main conclusion from the kinetic data that this class of RT inhibitors are non-substrate and template-competitive.
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PMID:Template-competitive inhibitors of HIV-1 reverse transcriptase: design, synthesis and inhibitory activity. 1181 36

We studied the kinetics of nontemplated nucleotide addition by the reverse transcriptase (RT) of human immunodeficiency virus type 1 (HIV-1) using model substrates derived from the 3' end of HIV-1 minus-strand strong-stop DNA. The addition of a nontemplated nucleotide was highly dependent on the nature of the base (fastest addition with dATP), type of nucleoside, and pH of the reaction buffer. The salt concentration, presence or absence of nucleocapsid protein, and nature of the blunt-ended duplex (DNA/DNA versus RNA/DNA) had only limited effects. The efficiency and base specificity were strongly affected by the sequence at the 3' end of the blunt-ended duplex. In every case, nontemplated nucleotide addition was much slower than templated polymerization. The K(d) for the incoming dNTP with an RT bound to a blunt-ended duplex was at least 1000-fold higher than with a duplex with a template overhang. At concentrations normally found in vivo, ATP can compete with dNTPs for binding to the polymerase active site and reduce the efficiency of nontemplated nucleotide addition. Although a stable ternary complex RT/DNA/dNTP could be readily detected by gel retardation assays if the DNA had a template overhang, stable ternary complexes were not observed with a blunt-ended duplex substrate. At in vivo concentrations of dNTPs (5-10 microM), nontemplated nucleotide addition occurred, but it was very inefficient and the rate of nontemplated polymerization is at least 10000-fold slower than the rate of templated polymerization. We could conclude that, in vivo, the unfavorable binding of the incoming dNTP, low concentration of dNTPs, the presence of a large concentration of ATP, and the inability to form a stable ternary complex prior to the polymerization step collaborate to reduce the efficiency of nontemplated nucleotide addition.
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PMID:Nontemplated nucleotide addition by HIV-1 reverse transcriptase. 1198 Apr 93

A number of compounds used for cancer chemotherapy exert their effects by inhibiting DNA replication. New inhibitors of DNA polymerases, therefore, could be potential candidates for new anti-cancer drugs. This study tested the effects of two phenalenone-skeleton-based compounds, which were isolated from a marine-derived fungus Penicillium sp., sculezonone-B (SCUL-B) and sculezonone-A (SCUL-A), upon DNA polymerase activity. Both compounds inhibited bovine DNA polymerases alpha and gamma, moderately affected the activity of DNA polymerase epsilon, and had almost no effect on HIV-reverse transcriptase and an E. coli DNA polymerase I Klenow fragment. Most notably, whereas SCUL-A inhibited pol beta (IC(50) = 17 microM), SCUL-B has only a weak influence upon this polymerase (IC(50) = 90 microM). Kinetic studies showed that inhibition of both DNA polymerases alpha and beta by either SCUL-A or SCUL-B was competitive with respect to dTTP substrate and noncompetitive with the template-primer. Whereas pol alpha inhibition by SCUL-B is competitive with respect to dATP, the inhibition by SCUL-A was found to be a mixed type with dATP substrate. The K(i) values of SCUL-B were calculated to be 1.8 and 6.8 microM for DNA polymerases alpha and gamma, respectively. The K(i) of DNA polymerase beta for SCUL-A was 12 microM and that for DNA polymerase alpha, 16 microM. Therefore, deletion of the OH-group at C12 enhanced inhibition of DNA polymerase beta. Since computational analyses of these two inhibitors revealed a remarkable difference in the distribution of negative electrostatic charge on the surface of molecules, we infer that different electrostatic charges might elicit different inhibition spectra from these two compounds.
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PMID:Novel phenalenone derivatives from a marine-derived fungus exhibit distinct inhibition spectra against eukaryotic DNA polymerases. 1205 92

Human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) resistance mutations K65R and M184V result in changes in susceptibility to several nucleoside and nucleotide RT inhibitors. K65R-containing viruses showed decreases in susceptibility to tenofovir, didanosine (ddI), abacavir, and (-)-beta-D-dioxolane guanosine (DXG; the active metabolite of amdoxovir) but appeared to be fully susceptible to zidovudine and stavudine in vitro. Viruses containing the K65R and M184V mutations showed further decreases in susceptibility to ddI and abacavir but increased susceptibility to tenofovir compared to the susceptibilities of viruses with the K65R mutation. Enzymatic and viral replication analyses were undertaken to elucidate the mechanisms of altered drug susceptibilities and potential fitness defects for the K65R and K65R+M184V mutants. The relative inhibitory capacities (K(i)/K(m)) of the active metabolites of tenofovir, ddI, and DXG were increased for the RT containing the K65R mutation compared to that for the wild-type RT, but the relative inhibitory capacity of abacavir was only minimally increased. For the mutant viruses with the K65R and M184V mutations, the increase in tenofovir susceptibility compared to that of the mutants with K65R correlated with a decrease in the tenofovir inhibitory capacity that was mediated primarily by an increased K(m) of dATP. The decrease in susceptibility to ddI by mutants with the K65R and M184V mutations correlated with an increase in the inhibitory capacity mediated by an increased K(i). ATP-mediated removal of carbovir as well as small increases in the inhibitory capacity of carbovir appear to contribute to the resistance of mutants with the K65R mutation and the mutants with the K65R and M184V mutations to abacavir. Finally, both the HIV-1 K65R mutant and, more notably, the HIV-1 K65R+M184V double mutant showed reduced replication capacities and reduced RT processivities in vitro, consistent with a potential fitness defect in vivo and the low prevalence of the K65R mutation among isolates from antiretroviral agent-experienced patients.
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PMID:Molecular mechanisms of resistance to human immunodeficiency virus type 1 with reverse transcriptase mutations K65R and K65R+M184V and their effects on enzyme function and viral replication capacity. 1238 48

This study was aimed to apply an LC-MS-MS method previously developed for intracellular nucleoside reverse transcriptase inhibitors-triphosphate (NRTI-TPs) to the determination of natural deoxyribonucleotides (dNTPs) in human peripheral blood mononuclear cells. The LC-MS-MS method was directly used in assay of dATP and dTTP. Interferences by ribonucleotides (rNTPs) prevented direct application to the two other analytes: dGTP and dCTP. A periodate oxidation procedure was therefore optimized to remove rNTPs from the cell medium in order to quantitate dCTP and dGTP. The determination of the intracellular ratio of NRTI-TP/dNTP in HIV-infected patients now involves use of the same chromatographic system for simultaneous assay of several analytes.
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PMID:Liquid chromatography-tandem mass spectrometry assays for intracellular deoxyribonucleotide triphosphate competitors of nucleoside antiretrovirals. 1274 19

The high fidelity of DNA replication is largely dependent upon accurate incorporation of dNTPs by DNA polymerases. To study the mechanism underlying nucleotide selection, we synthesized four nucleotide analogues bearing the unnatural bases benzimidazole, 5-nitrobenzimidazole, 6-nitrobenzimidazole, and 5-nitroindole and analyzed their incorporation by three DNA polymerases. We have found that human DNA polymerase alpha (pol alpha) and the Klenow fragment of Escherichia coli DNA polymerase I (KF) incorporate all four nucleotide analogues opposite all four canonical bases up to 4000-fold more efficiently than an incorrect natural dNTP (i.e., rates that approach those of a correct, natural dNTP), even though the shape of any base pair formed between the analogue and the template likely does not resemble a normal base pair. While pol alpha preferentially incorporated the analogues opposite template pyrimidines, KF surprisingly preferred to polymerize them opposite template purines. Although neither pol alpha nor KF readily polymerized a natural dNTP opposite either 5- or 6-nitrobenzimidazole in the template strand, the enzymes did incorporate the analogues to generate novel base pairs. Both pol alpha and KF polymerized the analogues up to 140-fold more efficiently than dATP both across from abasic sites and as 3'-overhangs on blunt-ended templates. Although Maloney murine leukemia virus reverse transcriptase did not measurably incorporate the analogues, this enzyme bound the analogues with K(I)'s only slightly higher than the K(m) for polymerization of the normal dNTP. The implications of these results with respect to how polymerases discriminate between correct and incorrect dNTPs are discussed.
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PMID:Facile polymerization of dNTPs bearing unnatural base analogues by DNA polymerase alpha and Klenow fragment (DNA polymerase I). 1295 Jan 74

The N-2 atom of guanine (G) is susceptible to modification by various carcinogens. Oligonucleotides with increasing bulk at this position were analyzed for fidelity and catalytic efficiency with the processive DNA polymerases human immunodeficiency virus, type 1, reverse transcriptase (RT), and bacteriophage T7 exonuclease(-) (T7(-)). RT and T7(-) effectively bypassed N(2)-methyl(Me)G and readily extended primers but were strongly blocked by N(2)-ethyl(Et)G, N(2)-isobutylG, N(2)-benzylG, and N(2)-methyl(9-anthracenyl)G. Steady-state kinetics of single nucleotide incorporation by RT and T7(-) showed a decrease of 10(3) in k(cat)/K(m) for dCTP incorporation opposite N(2)-MeG and a further large decrease opposite N(2)-EtG. Misincorporation frequency was increased 10(2)-10(3)-fold by a Me group and another approximately 10(3)-fold by an Et group. dATP was preferentially incorporated opposite bulky N(2)-alkylG molecules. N(2)-MeG attenuated the pre-steady-state kinetic bursts with RT and T7(-), and N(2)-EtG eliminated the bursts. Large elemental effects with thio-dCTP(alphaS) were observed with N(2)-EtG (6- and 72-fold decreases) but were much less with N(2)-MeG, indicating that the N(2)-Et group may affect the rate of the chemistry step (phosphodiester bond formation). Similar values of K(d(dCTP)) and K(d(DNA)) and k(off) rates of DNA substrates from RT and T7(-) indicate that ground-state binding and dissociation rates are not considerably affected by the bulk. We conclude that even a Me group at the guanine N-2 atom can cause a profound interfering effect on the fidelity and efficiency; an Et or larger group causes preferential misincorporation and strong blockage of replicative polymerases, probably at and before the chemistry step, demonstrating the role of bulk in DNA lesions.
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PMID:Analysis of the effect of bulk at N2-alkylguanine DNA adducts on catalytic efficiency and fidelity of the processive DNA polymerases bacteriophage T7 exonuclease- and HIV-1 reverse transcriptase. 1498 30

Mechanisms governing viral replicative capacity are poorly understood at the biochemical level. Human immunodeficiency virus, type 1 reverse transcriptase (HIV-1 RT) K65R or L74V substitutions confer viral resistance to 2',3'-dideoxyinosine (ddI) in vivo. The two substitutions never occur together, and L74V is frequently found in patients receiving ddI, while K65R is not. Here we show that recombinant viruses carrying K65R and K65R/L74V display the same resistance level to ddI (about 9.5-fold) relative to wild type. Consistent with this result, purified HIV-1 RT carrying K65R RT or K65R/L74V substitutions exhibits an 8-fold resistance to ddATP as judged by pre-steady state kinetics of incorporation of a single nucleotide into DNA. Resistance is due to a selective decrease of the catalytic rate constant k(pol): 22-fold (from 7.2 to 0.33 s(-1)) for K65R RT and 84-fold (from 7.2 to 0.086 s(-1)) for K65R/L74V RT. However, the K65R/L74V virus replication capacity is severely impaired relative to that of wild-type virus. This loss of viral fitness is correlated to a poor ability of K65R/L74V RT to use natural nucleotides relative to wild-type RT: 15% that of wild-type RT for dATP, 36% for dGTP, 50% for dTTP, and 25% for dCTP. The order of incorporation efficiency is wild-type RT > L74V RT > K65R RT > K65R/L74V RT. Processivity of DNA synthesis remains unaffected. These results explain why the two mutations do not combine in the clinic and might give a mechanism for a decreased viral fitness at the molecular level.
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PMID:A loss of viral replicative capacity correlates with altered DNA polymerization kinetics by the human immunodeficiency virus reverse transcriptase bearing the K65R and L74V dideoxynucleoside resistance substitutions. 1504 78

Hepadnavirus DNA polymerase functions in DNA synthesis and encapsidation, and acts as a primer for minus-strand DNA synthesis. Through protein priming reaction, a short DNA oligomer synthesized from the bulge of epsilon as template is covalently attached to the Tyr residue in the terminal protein (TP) domain of DNA polymerase. Using endogenous polymerase assays and native agarose gel analysis, we detected endogenous polymerase activity in priming-deficient mutant core particles, but not in reverse transcriptase (RT) reaction- or P protein-deficient mutant core particles. In addition, priming-deficient mutant core particles incorporated radiolabeled (32)P-dATP, (32)P-TTP, and (32)P-dGTP, but not (32)P-dCTP. Our results suggest that the priming-deficient mutant P protein has the ability to synthesize oligomers (presumably nascent minus-strand DNA) in the absence of covalent linkage between TP and the first deoxynucleotide. We propose that the priming-deficient mutant may be defective in minus-strand DNA translocation to direct repeat (DR) 1 at the 3' end of pregenomic RNA (pgRNA) that leads to the elongation of minus-strand DNA.
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PMID:Oligomer synthesis by priming deficient polymerase in hepatitis B virus core particle. 1506 13


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