Project description:We tested three compounds for their ability to inhibit the RNase H (RH) and polymerase activities of HIV-1 reverse transcriptase (RT). A high-resolution crystal structure (2.2 Å) of one of the compounds showed that it chelates the two magnesium ions at the RH active site; this prevents the RH active site from interacting with, and cleaving, the RNA strand of an RNA-DNA heteroduplex. The compounds were tested using a variety of substrates: all three compounds inhibited the polymerase-independent RH activity of HIV-1 RT. Time-of-addition experiments showed that the compounds were more potent if they were bound to RT before the nucleic acid substrate was added. The compounds significantly inhibited the site-specific cleavage required to generate the polypurine tract (PPT) RNA primer that initiates the second strand of viral DNA synthesis. The compounds also reduced the polymerase activity of RT; this ability was a result of the compounds binding to the RH active site. These compounds appear to be relatively specific; they do not inhibit either Escherichia coli RNase HI or human RNase H2. The compounds inhibit the replication of an HIV-1-based vector in a one-round assay, and their potencies were only modestly decreased by mutations that confer resistance to integrase strand transfer inhibitors (INSTIs), nucleoside analogs, or nonnucleoside RT inhibitors (NNRTIs), suggesting that their ability to block HIV replication is related to their ability to block RH cleavage. These compounds appear to be useful leads that can be used to develop more potent and specific compounds.IMPORTANCE Despite advances in HIV-1 treatment, drug resistance is still a problem. Of the four enzymatic activities found in HIV-1 proteins (protease, RT polymerase, RT RNase H, and integrase), only RNase H has no approved therapeutics directed against it. This new target could be used to design and develop new classes of inhibitors that would suppress the replication of the drug-resistant variants that have been selected by the current therapeutics.

Project description:Human telomerase reverse transcriptase (hTERT), the catalytic subunit of human telomerase, contains conserved motifs common to retroviral reverse transcriptases and telomerases. Within the C motif of hTERT is the Leu866-Val867-Asp868-Asp869 tetrapeptide that includes a catalytically essential aspartate dyad. Site-directed mutagenesis of Tyr183 and Met184 residues in HIV-1 RT, residues analogous to Leu866 and Val867, revealed that they are key determinants of nucleotide binding, processivity and fidelity. In this study, we show that substitutions at Val867 lead to significant changes in overall enzyme activity and telomere repeat extension rate, but have little effect on polymerase processivity. All Val867 substitutions examined (Ala, Met, Thr) led to reduced repeat extension rates, ranging from approximately 20 to 50% of the wild-type rate. Reconstitution of V867M hTERT and telomerase RNAs (TRs) with mutated template sequences revealed the effect on extension rate was associated with a template copying defect specific to template A residues. Furthermore, the Val867 hTERT mutants also displayed increased nucleotide incorporation fidelity, implicating Val867 as a determinant of telomerase fidelity. These findings suggest that by evolving to have a valine at position 867, the wild-type hTERT protein may have partially compromised polymerase fidelity for optimal and rapid repeat synthesis.

Project description:Nonnucleoside reverse transcriptase inhibitors (NNRTI) are a group of structurally diverse compounds that bind to a single site in HIV-1 reverse transcriptase (RT), termed the NNRTI-binding pocket (NNRTI-BP). NNRTI binding to RT induces conformational changes in the enzyme that affect key elements of the polymerase active site and also the association between the two protein subunits. To determine which conformational changes contribute to the mechanism of inhibition of HIV-1 reverse transcription, we used transient kinetic analyses to probe the catalytic events that occur directly at the enzyme's polymerase active site when the NNRTI-BP was occupied by nevirapine, efavirenz, or delavirdine. Our results demonstrate that all NNRTI-RT-template/primer (NNRTI-RT-T/P) complexes displayed a metal-dependent increase in dNTP binding affinity (K(d) ) and a metal-independent decrease in the maximum rate of dNTP incorporation (k (pol)). The magnitude of the decrease in k (pol) was dependent on the NNRTI used in the assay: Efavirenz caused the largest decrease followed by delavirdine and then nevirapine. Analyses that were designed to probe direct effects on phosphodiester bond formation suggested that the NNRTI mediate their effects on the chemistry step of the DNA polymerization reaction via an indirect manner. Because each of the NNRTI analyzed in this study exerted largely similar phenotypic effects on single nucleotide addition reactions, whereas each of them are known to exert differential effects on RT dimerization, we conclude that the NNRTI effects on subunit association do not directly contribute to the kinetic mechanism of inhibition of DNA polymerization.

Project description: Not available

Project description:Efavirenz (EFV) is a potent nonnucleoside reverse transcriptase inhibitor (NNRTI) used in the treatment of AIDS. NNRTIs bind in a hydrophobic pocket located in the p66 subunit of reverse transcriptase (RT), which is not present in crystal structures of RT without an inhibitor. Recent studies showed that monomeric forms of the p66 and p51 subunits bind efavirenz with micromolar affinity. The effect of efavirenz on the solution conformations of p66 and p51 monomers was studied by hydrogen-deuterium exchange mass spectrometry (HXMS) and Fourier transform ion cyclotron resonance mass spectrometry (FT-ICR MS). HXMS data reveal that five peptides, four of which contain efavirenz contact residues seen in the crystal structure of the RT-EFV complex, exhibit a reduced level of exchange in monomer-EFV complexes. Moreover, peptide 232-246 undergoes slow cooperative unfolding-refolding in the bound monomers, but at a rate much slower than that observed in the p66 subunit of the RT heterodimer [Seckler, J. M., Howard, K. J., Barkley, M. D., and Wintrode, P. L. (2009) Biochemistry 48, 7646-7655]. These results suggest that the efavirenz binding site on p66 and p51 monomers is similar to the NNRTI binding pocket in the p66 subunit of RT. Nanoelectrospray ionization FT-ICR mass spectra indicate that the intact monomers each have (at least) two different conformations. In the presence of efavirenz, the mass spectra change significantly and suggest that p51 adopts a single, more compact conformation, whereas p66 undergoes facile, electrospray-induced cleavage. The population shift is consistent with a selected-fit binding mechanism.

Project description:Novel inhibitors are needed to counteract the rapid emergence of drug-resistant HIV variants. HIV-1 reverse transcriptase (RT) has both DNA polymerase and RNase H (RNH) enzymatic activities, but approved drugs that inhibit RT target the polymerase. Inhibitors that act against new targets, such as RNH, should be effective against all of the current drug-resistant variants. Here, we present 2.80 A and 2.04 A resolution crystal structures of an RNH inhibitor, beta-thujaplicinol, bound at the RNH active site of both HIV-1 RT and an isolated RNH domain. beta-thujaplicinol chelates two divalent metal ions at the RNH active site. We provide biochemical evidence that beta-thujaplicinol is a slow-binding RNH inhibitor with noncompetitive kinetics and suggest that it forms a tropylium ion that interacts favorably with RT and the RNA:DNA substrate.

Project description:RNA aptamers that bind the reverse transcriptase (RT) of human immunodeficiency virus (HIV) compete with nucleic acid primer/template for access to RT, inhibit RT enzymatic activity in vitro, and suppress viral replication when expressed in human cells. Numerous pseudoknot aptamers have been identified by sequence analysis, but relatively few have been confirmed experimentally. In this work, a screen of nearly 100 full-length and >60 truncated aptamer transcripts established the predictive value of the F1Pk and F2Pk pseudoknot signature motifs. The screen also identified a new, nonpseudoknot motif with a conserved unpaired UCAA element. High-throughput sequence (HTS) analysis identified 181 clusters capable of forming this novel element. Comparative sequence analysis, enzymatic probing and RT inhibition by aptamer variants established the essential requirements of the motif, which include two conserved base pairs (AC/GU) on the 5' side of the unpaired UCAA. Aptamers in this family inhibit RT in primer extension assays with IC(50) values in the low nmol/l range, and they suppress viral replication with a potency that is comparable with that of previously studied aptamers. All three known anti-RT aptamer families (pseudoknots, the UCAA element, and the recently described "(6/5)AL" motif) are therefore suitable for developing aptamer-based antiviral gene therapies.Molecular Therapy - Nucleic Acids (2013) 2, e71; doi:10.1038/mtna.2012.62; published online 5 February 2013.

Project description:The steric flexibility or rigidity of polymerase active sites may play an important role in their fidelity of nucleic acid synthesis. In this regard, reverse transcriptases offer an unusual opportunity to compare two enzymatic activities that proceed in the same active site. For HIV-1 reverse transcriptase, reverse transcription (RNA-templated synthesis) is known to proceed with lower fidelity than DNA-templated synthesis. Here, we describe the use of a set of variably sized nonpolar thymidine and uracil mimics as molecular rulers to probe the active site steric constraints of HIV-1 RT, and for the first time, we directly compare the functional flexibility of these two activities. Steady-state kinetics of incorporation for natural dNTPs opposite unnatural template bases as well as for unnatural dNTPs opposite natural template bases are reported for the DNA-templated DNA synthesis, and comparison is made with recent data for the RNA-templated activity. Kinetics for extension beyond a base pair containing the analogue template bases are also reported both for RNA and DNA templates. Our results show that the DNA-dependent polymerization by HIV-RT is highly sensitive to size, strongly biasing against both too-small and too-large base pairs, while, by contrast, the RNA-dependent polymerization is only biased against analogues that are too small, and is much more accepting of larger base pairs. In addition, base pair extension with HIV-RT is found to be relatively insensitive to varied base pair size, consistent with its high mutagenicity. Overall, the data show greater rigidity with a DNA template as compared with an RNA template, which correlates directly with the higher fidelity of the DNA-templated synthesis. Possible structural explanations for these differences are discussed. We also report kinetics data for two HIV-1 RT mutants reported to have altered fidelity (F61A and K65R) using DNA templates containing nonpolar base analogues, and find that one of these (F61A) is a high-fidelity enzyme that appears to be sensitive to a loss of hydrogen-bonding groups.

Project description:The RNase H (RNH) function of HIV-1 reverse transcriptase (RT) plays an essential part in the viral life cycle. We report the characterization of YLC2-155, a 2-hydroxyisoquinoline-1,3-dione (HID)-based active-site RNH inhibitor. YLC2-155 inhibits both polymerase (50% inhibitory concentration [IC50] = 2.6 ?M) and RNH functions (IC50 = 0.65 ?M) of RT but is more effective against RNH. X-ray crystallography, nuclear magnetic resonance (NMR) analysis, and molecular modeling were used to show that YLC2-155 binds at the RNH-active site in multiple conformations.

Project description:The retrovirus HIV-1 has been a major health issue since its discovery in the early 80s. In 2017, over 37 million people were infected with HIV-1, of which 1.8 million were new infections that year. Currently, the most successful treatment regimen is the highly active antiretroviral therapy (HAART), which consists of a combination of three to four of the current 26 FDA-approved HIV-1 drugs. Half of these drugs target the reverse transcriptase (RT) enzyme that is essential for viral replication. One class of RT inhibitors is nucleoside reverse transcriptase inhibitors (NRTIs), a crucial component of the HAART. Once incorporated into DNA, NRTIs function as a chain terminator to stop viral DNA replication. Unfortunately, treatment with NRTIs is sometimes linked to toxicity caused by off-target side effects. NRTIs may also target the replicative human mitochondrial DNA polymerase (Pol γ), causing long-term severe drug toxicity. The goal of this work is to understand the discrimination mechanism of different NRTI analogues by RT. Crystal structures and kinetic experiments are essential for the rational design of new molecules that are able to bind selectively to RT and not Pol γ. Structural comparison of NRTI-binding modes with both RT and Pol γ enzymes highlights key amino acids that are responsible for the difference in affinity of these drugs to their targets. Therefore, the long-term goal of this research is to develop safer, next generation therapeutics that can overcome off-target toxicity.