Pre-steady state kinetic analysis of HIV-1 reverse transcriptase for non-canonical ribonucleoside triphosphate incorporation and DNA synthesis from ribonucleoside-containing DNA template (original) (raw)
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Journal of Biological Chemistry, 2013
Background: Under limiting dNTP concentrations, HIV-1 RT incorporates rNTPs during DNA synthesis. Results: HIV-1 RT utilizes dNTP less efficiently around rNMPs, and mismatch extension fidelity is significantly reduced. Conclusion: Presence of an rNMP in DNA template slows HIV-1 RT-mediated DNA synthesis and reduces fidelity. Significance: This study provides insight into how rNMP incorporation during proviral DNA synthesis can affect HIV-1 replication kinetics and fidelity. . The abbreviations used are: rNTP, ribonucleoside triphosphate; dNMP, deoxynucleoside monophosphate; rNMP, ribonucleoside monophosphate; AMV, avian myeloblastosis virus; T/P, template/primer; SA, streptavidin-coated; SIV, simian immunodeficiency virus.
Biochemistry, 2002
Recent crystallographic data suggest that a number of hydrophobic residues seen clustered between the structurally conserved R R motif of the palm subdomain and at the junction of palm and fingers subdomains of human immunodeficiency virus type 1 reverse transcriptase (HIV-1 RT) provide an optimal geometry to the R sandwich of the palm subdomain, which harbors the catalytic site and the primer-binding grip region. This region has also been implicated in binding to the non-nucleoside RT inhibitors. We have evaluated the impact of conserved and nonconserved amino acid substitutions at four hydrophobic positions in this region of HIV-1 RT, in the context of their biochemical characteristics. The residues that have been analyzed include Ile-167, Leu-187, and Val-189 which are located within the R R motif, while Trp-153 lies next to the conserved LPQG motif, at the juncture of the palm and fingers subdomains. Our results show that all substitutions at I167 with the exception of I167T were deleterious to enzyme function in contrast to substitutions at V189 which enhanced the enzymatic activity. Ala substitution at residues W153 and L187 also substantially hindered the polymerase function of the enzyme. Further analysis revealed that the defective mutant derivatives of I167 were substantially impaired in their apparent dNTP binding abilities, thereby impacting the geometry of the dNTP binding pocket. The extent of misinsertion and misincorporation was higher in the case of RT variants of W153 and V189, specifically on a DNA template. Interestingly, none of the mutant derivatives of these residues were resistant to nucleoside inhibitors. A salient finding was that all nonconserved mutants of these residues exhibited hypersensitivity to nevirapine. We have analyzed these findings and their significance in the context of the HIV-1 RT structure and propose that these residues exert their effect via their indirect interactions with the template-primer through residues in their vicinity.
Journal of Virology, 2005
The specific impact of mutations that abrogate human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) dimerization on virus replication is not known, as mutations shown previously to inhibit RT dimerization also impact Gag-Pol stability, resulting in pleiotropic effects on HIV-1 replication. We have previously characterized mutations at codon 401 in the HIV-1 RT tryptophan repeat motif that abrogate RT dimerization in vitro, leading to a loss in polymerase activity. The introduction of the RT dimerizationinhibiting mutations W401L and W401A into HIV-1 resulted in the formation of noninfectious viruses with reduced levels of both virion-associated and intracellular RT activity compared to the wild-type virus and the W401F mutant, which does not inhibit RT dimerization in vitro. Steady-state levels of the p66 and p51 RT subunits in viral lysates of the W401L and W401A mutants were reduced, but no significant decrease in Gag-Pol was observed compared to the wild type. In contrast, there was a decrease in processing of p66 to p51 in cell lysates for the dimerization-defective mutants compared to the wild type. The treatment of transfected cells with indinavir suggested that the HIV-1 protease contributed to the degradation of virion-associated RT subunits. These data demonstrate that mutations near the RT dimer interface that abrogate RT dimerization in vitro result in the production of replication-impaired viruses without detectable effects on Gag-Pol stability or virion incorporation. The inhibition of RT activity is most likely due to a defect in RT maturation, suggesting that RT dimerization represents a valid drug target for chemotherapeutic intervention.
Proceedings of the National Academy of Sciences, 2010
Single turnover studies on HIV reverse transcriptase suggest that nucleoside analogs bind more tightly to the enzyme than normal substrates, contrary to rational structural predictions. Here we resolve these controversies by monitoring the kinetics of nucleotide-induced changes in enzyme structure. We show that the specificity constant for incorporation of a normal nucleotide (dCTP) is determined solely by the rate of binding (including isomerization) because isomerization to the closed complex commits the substrate to react. In contrast, a nucleoside analog (3TC-TP, triphosphate form of lamivudine) is incorporated slowly, allowing the conformational change to come to equilibrium and revealing tight nucleotide binding. Our data reconcile previously conflicting reports suggesting that nucleotide analogs bind tighter than normal nucleotides. Rather, dCTP and 3TC-TP bind with nearly equal affinities, but the binding of dCTP never reaches equilibrium. Discrimination against 3TC-TP is ba...
Proceedings of the National Academy of Sciences, 2000
We have examined amino acid substitutions at residues 115 and 116 in the reverse transcriptase (RT) of HIV-1. A number of properties were examined, including polymerization and processivity on both DNA and RNA templates, strand displacement, ribonucleotide misincorporation, and resistance to nucleoside analogs. The RT variants Tyr-115-Phe and Phe-116-Tyr are similar to wild-type HIV-1 RT in most, but not all, respects. In contrast, the RT variant Tyr-115-Val is significantly impaired in polymerase activity compared with wild-type RT; however, Tyr-115-Val is able to incorporate ribonucleotides as well as deoxyribonucleotides during polymerization and is resistant to a variety of nucleoside analogs.
Subunit-specific analysis of the human immunodeficiency virus type 1 reverse transcriptase in vivo
2004
The human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) is a heterodimer comprised of two structurally distinct subunits (p51 and p66). Since p51 and p66 are derived from the same coding region, subunit-specific structure-function studies of RT have been conducted exclusively by in vitro biochemical approaches. To study RT subunit function in the context of infectious virus, we constructed an LTR-vpr-p51-IRES-p66 expression cassette in which the HIV-1 vpr gene was fused in frame with p51, followed by an internal ribosome entry site (IRES) sequence and the p66 coding region. By coexpression with RT-deficient proviral DNA, we demonstrated that the p66 subunit is specifically and selectively packaged into virions as a Vpr-p51/ p66 complex. Our analysis showed that cleavage by the viral protease liberates Vpr and generates functional heterodimeric RT (p51/p66) that supports HIV-1 reverse transcription and virus infection. By exploiting this novel trans-complementation approach, we demonstrated, for the first time with infectious virions, that the YMDD aspartates of p66 are both required and sufficient for RT polymerase function. Mutational analyses of the p51 YMDD aspartates indicated that they play an important structural role in p51 folding and subunit interactions that are required for the formation of an active RT heterodimer within infected cells. Understanding the role of the individual RT subunits in RNA-and DNA-dependent DNA synthesis is integral to our understanding of RT function. Our findings will lead to important new insights into the role of the p51 and p66 subunits in HIV-1 reverse transcription.