A mutation in the primer grip region of HIV-1 reverse transcriptase that confers reduced fidelity of DNA synthesis

An in silico molecular modeling approach of halolactone derivatives as potential inhibitors for human immunodeficiency virus type-1 reverse transcriptase enzyme

Acquired Immune Deficiency Syndrome (AIDS) is an infectious disease caused by Human Immunodeficiency Virus (HIV) infection and its replication requires the Reverse Transcriptase (RT) enzyme. RT plays a key role in the HIV life cycle, making it one of the most important targets for designing new drugs. Thus, in order to increase therapeutic options against AIDS, halolactone derivatives (D-halolactone) that have been showed as potential non-nucleoside inhibitors of the RT enzyme were studied. In the present work, a series of D-halolactone were investigated by molecular modeling studies, combining Three-dimensional Quantitative Structure-Activity Relationship (3 D-QSAR), molecular docking and Molecular Dynamics (MD) techniques, to understand the molecular characteristics that promote biological activity. The internal and external validation parameters indicated that the 3 D-QSAR model has good predictive capacity and statistical significance. Contour maps provided useful information on the structural characteristics of compounds for anti-HIV-1 activity. The docking results showed that D-halolactone present good complementarity by the RT allosteric site. In MD simulations it was observed that the formation of enzyme-ligand complexes were favorable, and from the free energy decomposition it was found that Leu100, Val106, Tyr181, Try188, and Trp229 are key residues for stabilization in the enzymatic site. Thus, the results showed that the proposed models can be used to design promising HIV-1 RT inhibitors. Communicated by Ramaswamy H. Sarma.

Two Coselected Distal Mutations in HIV-1 Reverse Transcriptase (RT) Alter Susceptibility to Nonnucleoside RT Inhibitors and Nucleoside Analogs

Although antiretroviral therapy (ART) is highly successful, drug-resistant variants can arise that blunt the efficacy of ART. New inhibitors that are broadly effective against known drug-resistant variants are needed, although such compounds might select for novel resistance mutations that affect the sensitivity of the virus to other compounds. Compound 13 selects for resistance mutations that differ from traditional NNRTI resistance mutations. These mutations cause increased sensitivity to NRTIs, such as AZT.

Two mutations, G112D and M230I, were selected in the reverse transcriptase (RT) of human immunodeficiency virus type 1 (HIV-1) by a novel nonnucleoside reverse transcriptase inhibitor (NNRTI). G112D is located near the HIV-1 polymerase active site; M230I is located near the hydrophobic region where NNRTIs bind. Thus, M230I could directly interfere with NNRTI binding but G112D could not. Biochemical and virological assays were performed to analyze the effects of these mutations individually and in combination. M230I alone caused a reduction in susceptibility to NNRTIs, while G112D alone did not. The G112D/M230I double mutant was less susceptible to NNRTIs than was M230I alone. In contrast, both mutations affected the ability of RT to incorporate nucleoside analogs. We suggest that the mutations interact with each other via the bound nucleic acid substrate; the nucleic acid forms part of the polymerase active site, which is near G112D. The positioning of the nucleic acid is influenced by its interactions with the “primer grip” region and could be influenced by the M230I mutation.

IMPORTANCE Although antiretroviral therapy (ART) is highly successful, drug-resistant variants can arise that blunt the efficacy of ART. New inhibitors that are broadly effective against known drug-resistant variants are needed, although such compounds might select for novel resistance mutations that affect the sensitivity of the virus to other compounds. Compound 13 selects for resistance mutations that differ from traditional NNRTI resistance mutations. These mutations cause increased sensitivity to NRTIs, such as AZT.

Coronavirus Host Range Expansion and Middle East Respiratory Syndrome Coronavirus Emergence: Biochemical Mechanisms and Evolutionary Perspectives

Coronaviruses have frequently expanded their host range in recent history, with two events resulting in severe disease outbreaks in human populations. Severe acute respiratory syndrome coronavirus (SARS-CoV) emerged in 2003 in Southeast Asia and rapidly spread around the world before it was controlled by public health intervention strategies. The 2012 Middle East respiratory syndrome coronavirus (MERS-CoV) outbreak represents another prime example of virus emergence from a zoonotic reservoir. Here, we review the current knowledge of coronavirus cross-species transmission, with particular focus on MERS-CoV. MERS-CoV is still circulating in the human population, and the mechanisms governing its cross-species transmission have been only partially elucidated, highlighting a need for further investigation. We discuss biochemical determinants mediating MERS-CoV host cell permissivity, including virus spike interactions with the MERS-CoV cell surface receptor dipeptidyl peptidase 4 (DPP4), and evolutionary mechanisms that may facilitate host range expansion, including recombination, mutator alleles, and mutational robustness. Understanding these mechanisms can help us better recognize the threat of emergence for currently circulating zoonotic strains.

Functional insights from molecular modeling, docking, and dynamics study of a cypoviral RNA dependent RNA polymerase

Antheraea mylitta cytoplasmic polyhedrosis virus (AmCPV) contains 11 double stranded RNA genome segments and infects tasar silkworm A. mylitta. RNA-dependent RNA polymerase (RdRp) is reported as a key enzyme responsible for propagation of the virus in the host cell but its structure function relationship still remains elusive. Here a computational approach has been taken to compare sequence and secondary structure of AmCPV RdRp with other viral RdRps to identify consensus motifs. Then a reliable pairwise sequence alignment of AmCPV RdRp with its closest sequence structure homologue λ3 RdRp is done to predict three dimensional structure of AmCPV RdRp. After comparing with other structurally known viral RdRps, important sequence and/or structural features involved in substrate entry or binding, polymerase reaction and the product release events have been identified. A conserved RNA pentanucleotide (5'-AGAGC-3') at the 3'-end of virus genome is predicted as cis-acting signal for RNA synthesis and its docking and simulation study along with the model of AmCPV RdRp has allowed to predict mode of template binding by the viral polymerase. It is found that template RNA enters into the catalytic center through nine sequence-independent and two sequence-dependent interactions with the specific amino acid residues. However, number of sequence dependent interactions remains almost same during 10 nano-second simulation time while total number of interactions decreases. Further, docking of N(7)-methyl-GpppG (mRNA cap) on the model as well as prediction of RNA secondary structure has shown the template entry process in the active site. These findings have led to postulate the mechanism of RNA-dependent RNA polymerization process by AmCPV RdRp. To our knowledge, this is the first report to evaluate structure function relationship of a cypoviral RdRp.

Temperature effects on the fidelity of a thermostable HIV-1 reverse transcriptase

Transcriptomics and gene expression analysis are largely dependent of the availability of efficient thermostable reverse transcriptases (RTs). However, the intrinsic fidelity of DNA synthesis catalyzed by retroviral RTs is low. Reported error rates are in the range 1.2 × 10(-5)-6.7 × 10(-4), with oncoretroviral RTs being the most faithful enzymes. Wild-type HIV-1 group O (HIV-1O) RT is a thermostable polymerase that is able to synthesize cDNA at temperatures as high as 70 °C. At 37 °C, its error rate has been estimated at 5.8 × 10(-5) in M13mp2 lacZ-based forward mutation assays. However, at higher temperatures (e.g. 50 and 55 °C), the accuracy of HIV-1O RT is increased by approximately two- to five-fold. At 55 °C, the HIV-1O RT error rate (1.3 × 10(-5)) was similar to that shown by the AffinityScript (Agilent Technologies Inc., La Jolla, CA, USA) RT, a commercially available thermostable murine leukaemia virus RT. At higher temperatures, the increased accuracy of the HIV-1 enzyme results from a lower base substitution error rate, although it shows a higher tendency to introduce frameshifts. Kinetic studies carried out with model template-primers suggest minor differences in nucleotide discrimination, although, at higher temperatures, HIV-1O RT showed a reduced ability to extend mispaired template-primers.

Altered error specificity of RNase H-deficient HIV-1 reverse transcriptases during DNA-dependent DNA synthesis

Asp(443) and Glu(478) are essential active site residues in the RNase H domain of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT). We have investigated the effects of substituting Asn for Asp(443) or Gln for Glu(478) on the fidelity of DNA-dependent DNA synthesis of phylogenetically diverse HIV-1 RTs. In M13mp2 lacZα-based forward mutation assays, HIV-1 group M (BH10) and group O RTs bearing substitutions D443N, E478Q, V75I/D443N or V75I/E478Q showed 2.0- to 6.6-fold increased accuracy in comparison with the corresponding wild-type enzymes. This was a consequence of their lower base substitution error rates. One-nucleotide deletions and insertions represented between 30 and 68% of all errors identified in the mutational spectra of RNase H-deficient HIV-1 group O RTs. In comparison with the wild-type RT, these enzymes showed higher frameshift error rates and higher dissociation rate constants (koff) for DNA/DNA template-primers. The effects on frameshift fidelity were similar to those reported for mutation E89G and suggest that in HIV-1 group O RT, RNase H inactivation could affect template/primer slippage. Our results support a role for the RNase H domain during plus-strand DNA polymerization and suggest that mutations affecting RNase H function could also contribute to retrovirus variability during the later steps of reverse transcription.

Interrelationship between HIV-1 fitness and mutation rate

Differences in replication fidelity, as well as mutator and antimutator strains, suggest that virus mutation rates are heritable and prone to natural selection. Human immunodeficiency virus type 1 (HIV-1) has many distinct advantages for the study of mutation rate optimization given the wealth of structural and biochemical data on HIV-1 reverse transcriptase (RT) and mutants. In this study, we conducted parallel analyses of mutation rate and viral fitness. In particular, a panel of 10 RT mutants-most having drug resistance phenotypes-was analyzed for their effects on viral fidelity and fitness. Fidelity differences were measured using single-cycle vector assays, while fitness differences were identified using ex vivo head-to-head competition assays. As anticipated, virus mutants possessing either higher or lower fidelity had a corresponding loss in fitness. While the virus panel was not chosen randomly, it is interesting that it included more viruses possessing a mutator phenotype rather than viruses possessing an antimutator phenotype. These observations provide the first description of an interrelationship between HIV-1 fitness and mutation rate and support the conclusion that mutator and antimutator phenotypes correlate with reduced viral fitness. In addition, the findings here help support a model in which fidelity comes at a cost of replication kinetics and may help explain why retroviruses like HIV-1 and RNA viruses maintain replication fidelity near the extinction threshold.

Lys66 residue as a determinant of high mismatch extension and misinsertion rates of HIV-1 reverse transcriptase

A major factor contributing to the high mutation rate of HIV-1 reverse transcriptase (RT) is its high propensity for misincorporation. Misincorporation requires both deoxyribonucleotide triphosphate (dNTP) misinsertion and the subsequent extension of the mismatched terminus thus formed. We hypothesized that Lys66 is a determinant of mismatch extension based on its position near the primer terminus. This hypothesis was tested by steady-state kinetic studies using wild-type HIV-1 RT and four Lys66 substitution mutants: Lys66Arg, Lys66Ala, Lys66Asn and Lys66Thr. The mismatch extension efficiency was reduced for all mutants, with Lys66Ala, Lys66Asn and Lys66Thr showing a four- to six-fold reduction compared with wild-type HIV-1 RT. Surprisingly, the nonconservative substitutions also led to large decreases in misinsertion efficiency, ranging from as low as three-fold to values much higher than 23-fold. Thus, the Lys66Arg mutant was akin to wild-type HIV-1 RT, whereas all nonconservative mutants displayed significantly decreased efficiency for both events. Our results suggest that Lys66, much like Lys65, is a determinant of both dNTP misinsertion and mismatch extension efficiency. While Lys65 is known to contact the γ-phosphate of incoming dNTP, the Lys66 side chain is in the vicinity of the primer terminus. However, our results suggest that both residues have a similar influence on dNTP misinsertion and mispair extension efficiencies of HIV-1 RT. When we tested the mutants for susceptibility to selected nucleoside analog and non-nucleoside analog drugs, similarly to Lys65Arg, the Lys66Ala and Lys66Asn mutants displayed mild resistance to the nucleoside analog drug 3'-azido-3'-deoxythymidine-5'-triphosphate (AZTTP).

Retrovolution: HIV-driven evolution of cellular genes and improvement of anticancer drug activation

In evolution strategies aimed at isolating molecules with new functions, screening for the desired phenotype is generally performed in vitro or in bacteria. When the final goal of the strategy is the modification of the human cell, the mutants selected with these preliminary screenings may fail to confer the desired phenotype, due to the complex networks that regulate gene expression in higher eukaryotes. We developed a system where, by mimicking successive infection cycles with HIV-1 derived vectors containing the gene target of the evolution in their genome, libraries of gene mutants are generated in the human cell, where they can be directly screened. As a proof of concept we created a library of mutants of the human deoxycytidine kinase (dCK) gene, involved in the activation of nucleoside analogues used in cancer treatment, with the aim of isolating a variant sensitizing cancer cells to the chemotherapy compound Gemcitabine, to be used in gene therapy for anti-cancer approaches or as a poorly immunogenic negative selection marker for cell transplantation approaches. We describe the isolation of a dCK mutant, G12, inducing a 300-fold sensitization to Gemcitabine in cells originally resistant to the prodrug (Messa 10K), an effect 60 times stronger than the one induced by the wt enzyme. The phenotype is observed in different tumour cell lines irrespective of the insertion site of the transgene and is due to a change in specificity of the mutated kinase in favour of the nucleoside analogue. The mutations characterizing G12 are distant from the active site of the enzyme and are unpredictable on a rational basis, fully validating the pragmatic approach followed. Besides the potential interest of the G12 dCK variant for therapeutic purposes, the methodology developed is of interest for a large panel of applications in biotechnology and basic research.

We exploited the error-prone replication machinery of HIV-1 and its ability to stably introduce transgenes in human cells to develop a novel system, Retrovolution, to generate libraries of mutants of cellular genes. When libraries are screened to isolate variants that modify the phenotype of the human cell for biomedical applications or basic research, false positives often arise from the classical screening procedures performed in vitro or in bacteria. Retrovolution allows an easy screening of the libraries directly in the human cell, where they are generated. We describe the creation and screening of a library of the hdCK (a human kinase activating several anticancer compounds) gene, to identify variants increasing the sensitivity of cancer cells to treatment with low, poorly toxic doses of the anticancer drug Gemcitabine. We isolated a dCK variant inducing death in tumour cells at doses up to 300 times lower than those required for killing non-engineered cells. The mutant presents mutations unpredictable on structural basis and revealed a change in enzymatic properties that accounts for the observed cellular effect. Besides the intrinsic interest of the mutant identified, these results fully validate Retrovolution as a mutagenesis system with broad applications in applied and basic research.

Extensive mutagenesis of the conserved box E motif in duck hepatitis B virus P protein reveals multiple functions in replication and a common structure with the primer grip in HIV-1 reverse transcriptase

Hepadnaviruses, including the pathogenic hepatitis B virus (HBV), replicate their small DNA genomes through protein-primed reverse transcription, mediated by the terminal protein (TP) domain in their P proteins and an RNA stem-loop, ε, on the pregenomic RNA (pgRNA). No direct structural data are available for P proteins, but their reverse transcriptase (RT) domains contain motifs that are conserved in all RTs (box A to box G), implying a similar architecture; however, experimental support for this notion is limited. Exploiting assays available for duck HBV (DHBV) but not the HBV P protein, we assessed the functional consequences of numerous mutations in box E, which forms the DNA primer grip in human immunodeficiency virus type 1 (HIV-1) RT. This substructure coordinates primer 3'-end positioning and RT subdomain movements during the polymerization cycle and is a prime target for nonnucleosidic RT inhibitors (NNRTIs) of HIV-1 RT. Box E was indeed critical for DHBV replication, with the mutations affecting the folding, ε RNA interactions, and polymerase activity of the P protein in a position- and amino acid side chain-dependent fashion similar to that of HIV-1 RT. Structural similarity to HIV-1 RT was underlined by molecular modeling and was confirmed by the replication activity of chimeric P proteins carrying box E, or even box C to box E, from HIV-1 RT. Hence, box E in the DHBV P protein and likely the HBV P protein forms a primer grip-like structure that may provide a new target for anti-HBV NNRTIs.

Synthesis and HIV-1 RT inhibitory action of novel (4/6-substituted benzo[d]thiazol -2-yl)thiazolidin-4-ones. Divergence from the non-competitive inhibition mechanism

Reverse transcriptase (RT) inhibitors play a major role in the therapy of human immunodeficiency virus type 1 (HIV-1) infection. Although, many compounds are already used as anti-HIV drugs, research on development of novel inhibitors continues, since drug resistant strains appear because of prolonged therapy. In this paper, we present the synthesis and evaluation of HIV-1 RT inhibitory action of eighteen novel (4/6-halogen/MeO/EtO-substituted benzo[d]thiazol-2-yl)thiazolidin-4-ones. The two more active compounds (IC50 : 0.04 µM and 0.25 µM) exhibited better inhibitory action than the reference compound, nevirapine. Docking analysis supports a stable binding of the most active derivative to the allosteric centre of RT. Kinetic analysis of two of the most active compounds indicate an uncompetitive inhibition mode. This is a desired characteristic, since mutations that affect activity of traditional non-competitive NNRTIs may not affect activity of compounds of this series. Interestingly, the less active derivatives (IC50 > 40 µM) exhibit a competitive mode of action.

The reverse transcriptase encoded by the non-LTR retrotransposon R2 is as error-prone as that encoded by HIV-1

Reverse transcriptases (RTs) encoded by a wide range of mobile retroelements have had a major impact on the structure and function of genomes. Among the most abundant elements in eukaryotes are the non long terminal repeat (LTR) retrotransposons. Here we compare the dNTP concentration requirements and error rates of the RT encoded by the non-LTR retrotransposon R2 of Bombyx mori with the well-characterized RTs of retroviruses. Surprisingly, R2 was found to have properties more similar to those of lentiviral RTs, such as human immunodeficiency virus type 1 (HIV-1), than to those of oncoretroviral RTs, such as murine leukemia virus. Like HIV-1 RT, R2 RT was able to synthesize DNA at low dNTP concentrations, suggesting that R2 is able to retrotranspose in nondividing cells. R2 RT also showed levels of misincorporation in biased dNTP pools and replication error rates in M13 lacZα forward mutation assays, similar to HIV-1 RT. Most of the R2 base substitutions in the forward mutation assay were caused by the misincorporation of dTMP. Analogous to HIV-1, the high error rate of R2 RT appears to be a result of its ability to extend mismatches once generated. We suggest that the low fidelity of R2 RT is a by-product of the flexibility of its active site/dNTP binding pocket required for the target-primed reverse transcription reaction used by R2 for retrotransposition. Finally, we discuss that in spite of the high R2 RT error rate, the long-term nucleotide substitution rate for R2 is not significantly above that associated with cellular DNA replication, based on the frequency of R2 retrotranspositions determined in natural populations.

K65R and K65A substitutions in HIV-1 reverse transcriptase enhance polymerase fidelity by decreasing both dNTP misinsertion and mispaired primer extension efficiencies

Lys65 residue, in the fingers domain of human immunodeficiency virus reverse transcriptase (RT), interacts with incoming dNTP in a sequence-independent fashion. We showed previously that a 5-amino-acid deletion spanning Lys65 and a K65A substitution both enhanced the fidelity of dNTP insertion. We hypothesized that the Lys65 residue enhances dNTP misinsertion via interactions with the gamma-phosphate of the incoming dNTP. We now examine this hypothesis in pre-steady-state kinetic studies using wild-type human immunodeficiency virus-1 RT and two substitution mutants, K65A and K65R. K65R mutation did not greatly increase misinsertion fidelity, but K65A mutation led to higher incorporation fidelity. For a misinsertion to become a permanent error, it needs to be accompanied by the extension of the mispaired terminus thus formed. Both mutants and the wild-type enzyme discriminated against the mismatched primer at the catalytic step (k(pol)). Additionally, K65A and K65R mutants displayed a further decrease in mismatch extension efficiency, primarily at the level of dNTP binding. We employed hydroxyl radical footprinting to determine the position of the RT on the primer/template. The wild-type and Lys65-substituted enzymes occupied the same position at the primer terminus; the presence of a mismatched primer terminus caused all three enzymes to be displaced to a -2 position relative to the primer 3' end. In the context of an efficiently extended mismatched terminus, the presence of the next complementary nucleotide overcame the displacement, resulting in a complex resembling the matched terminus. The results are consistent with the observed reduction in k(pol) in mispaired primer extension being due to the position of the enzyme at a mismatched terminus. Our work shows the influence of the stabilizing interactions of Lys65 with the incoming dNTP on two different aspects of polymerase fidelity.

HIV-1 Ribonuclease H: Structure, Catalytic Mechanism and Inhibitors

Since the human immunodeficiency virus (HIV) was discovered as the etiological agent of acquired immunodeficiency syndrome (AIDS), it has encouraged much research into antiviral compounds. The reverse transcriptase (RT) of HIV has been a main target for antiviral drugs. However, all drugs developed so far inhibit the polymerase function of the enzyme, while none of the approved antiviral agents inhibit specifically the necessary ribonuclease H (RNase H) function of RT. This review provides a background on structure-function relationships of HIV-1 RNase H, as well as an outline of current attempts to develop novel, potent chemotherapeutics against a difficult drug target.

The M230L nonnucleoside reverse transcriptase inhibitor resistance mutation in HIV-1 reverse transcriptase impairs enzymatic function and viral replicative capacity

The M230L mutation in HIV-1 reverse transcriptase (RT) is associated with resistance to first-generation nonnucleoside reverse transcriptase inhibitors (NNRTIs). The present study was designed to determine the effects of M230L on enzyme function, viral replication capacity (RC), and the extent to which M230L might confer resistance to the second-generation NNRTI etravirine (ETR) as well as to the first-generation NNRTIs efavirenz (EFV) and nevirapine (NVP). Phenotyping assays with TZM-bl cells confirmed that M230L conferred various degrees of resistance to each of the NNRTIs tested. Recombinant viruses containing M230L displayed an 8-fold decrease in RC compared to that of the parental wild-type (WT) virus. Recombinant HIV-1 WT and M230L mutant RT enzymes were purified; and both biochemical and cell-based phenotypic assays confirmed that M230L conferred resistance to each of EFV, NVP, and ETR. RT that contained M230L was also deficient in regard to each of minus-strand DNA synthesis, both DNA- and RNA-dependent polymerase activities, processivity, and RNase H activity, suggesting that this mutation contributes to diminished viral replication kinetics.

Mutation rates and intrinsic fidelity of retroviral reverse transcriptases

Retroviruses are RNA viruses that replicate through a DNA intermediate, in a process catalyzed by the viral reverse transcriptase (RT). Although cellular polymerases and host factors contribute to retroviral mutagenesis, the RT errors play a major role in retroviral mutation. RT mutations that affect the accuracy of the viral polymerase have been identified by in vitro analysis of the fidelity of DNA synthesis, by using enzymological (gel-based) and genetic assays (e.g., M13mp2 lacZ forward mutation assays). For several amino acid substitutions, these observations have been confirmed in cell culture using viral vectors. This review provides an update on studies leading to the identification of the major components of the fidelity center in retroviral RTs.

Solution characterization of [methyl-(13)C]methionine HIV-1 reverse transcriptase by NMR spectroscopy

HIV reverse transcriptase (RT) is a primary target for drug intervention in the treatment of AIDS. We report the first solution NMR studies of [methyl-(13)C]methionine HIV-1 RT, aimed at better understanding the conformational and dynamic characteristics of RT, both in the presence and absence of the non-nucleoside RT inhibitor (NNRTI) nevirapine. The selection of methionine as a structural probe was based both on its favorable NMR characteristics, and on the presence of two important active site methionine residues, M184(66) and M230(66). Observation of the M184 resonance is subunit dependent; in the p66 subunit the solvent-exposed residue produces a readily observed signal with a characteristic resonance shift, while in the globular p51 subunit, the M184(51) resonance is shifted and broadened as M184 becomes buried in the protein interior. In contrast, although structural data indicates that the environment of M230 is also strongly subunit dependent, the M230 resonances from both subunits have very similar shift and relaxation characteristics. A comparison of chemical shift and intensity data with model-based predictions gives reasonable agreement for M184(66), while M230(66), located on the beta-hairpin "primer grip", is more mobile and solvent-exposed than suggested by crystal structures of the apo enzyme which have a "closed" fingers-thumb conformation. This mobility of the primer grip is presumably important for binding of non-nucleoside RT inhibitors (NNRTIs), since the NNRTI binding pocket is not observed in the absence of the inhibitors, requiring instead that the binding pocket be dynamically accessible. In the presence of the nevirapine, both the M184(66) and M230(66) resonances are significantly perturbed, while none of the methionine resonances in the p51 subunit is sensitive to this inhibitor. Site-directed mutagenesis indicates that both M16 and M357 produce two resonances in each subunit, and for both residues, the intensity ratio of the component peaks is strongly subunit dependent. Conformational features that might explain the multiple peaks are discussed.

Mechanistic insights into the role of Val75 of HIV-1 reverse transcriptase in misinsertion and mispair extension fidelity of DNA synthesis

The side chain of Val75 stabilizes the fingers subdomain of the human immunodeficiency virus type 1 reverse transcriptase (RT), while its peptide backbone interacts with the single-stranded DNA template (at nucleotide +1) and with the peptide backbone of Gln151. Specific DNA polymerase activities of mutant RTs bearing amino acid substitutions at position 75 (i.e., V75A, V75F, V75I, V75L, V75M, V75S and V75T) were relatively high. Primer extension experiments carried out in the absence of one deoxyribonucleoside-triphosphate suggested that mutations did not affect the accuracy of the RT, except for V75A, V75F, V75I, and to a lesser extent V75T. The fidelity of RTs bearing mutations V75F and V75I increased 1.8- and 3-fold, respectively, as measured by the M13 lacZ alpha forward mutation assay, while V75A showed 1.4-fold decreased accuracy. Steady- and pre-steady-state kinetics demonstrated that the increased fidelity of V75I and V75F was related to their decreased ability to extend mismatched template-primers, while misincorporation efficiencies were not significantly affected by mutations. The increased mispair extension fidelity of mutant V75I RT could be attributed to the nucleotide affinity loss, observed in reactions with mismatched template-primers. Altogether, these data suggest that Val75 interactions with the 5' template overhang are important determinants of fidelity.

Immunogenicity of candidate DNA vaccine based on subtype A of human immunodeficiency virus type 1 predominant in Russia

Human immunodeficiency virus (HIV)-1 subtype A strains circulating among the majority of HIVinfected individuals in the former Soviet Union (FSU) countries demonstrate low genetic diversity. The consensus sequence of the FSU region-specific isolate has been used for the candidate DNA vaccine development. We constructed recombinant plasmids with four viral genes: env (gp140), gag, pol (reverse transcriptase), and nef. We immunized BALB/c mice intramuscularly using equimolar mixture of four recombinant plasmids, and observed significant cytotoxic T lymphocyte response and specific CD8(+) cell production against cells presenting HIV-1 peptides. Overall, the Th1 pathway of immune response clearly dominated. Immunological properties of this candidate DNA vaccine against HIV-1 suggest the possibility of its further study in clinical trials.

DNA structure-induced recruitment and activation of the Fanconi anemia pathway protein FANCD2

The Fanconi anemia (FA) pathway proteins are thought to be involved in the repair of irregular DNA structures including those encountered by the moving replication fork. However, the nature of the DNA structures that recruit and activate the FA proteins is not known. Because FA proteins function within an extended network of proteins, some of which are still unknown, we recently established cell-free assays in Xenopus laevis egg extracts to deconstruct the FA pathway in a fully replication-competent context. Here we show that the central FA pathway protein, xFANCD2, is monoubiquitinated (xFANCD2-L) rapidly in the presence of linear and branched double-stranded DNA (dsDNA) structures but not single-stranded or Y-shaped DNA. xFANCD2-L associates with dsDNA structures in an FA core complex-dependent manner but independently of xATRIP, the regulatory subunit of xATR. Formation of xFANCD2-L is also triggered in response to circular dsDNA, suggesting that dsDNA ends are not required to trigger monoubiquitination of FANCD2. The induction of xFANCD2-L in response to circular dsDNA is replication and checkpoint independent. Our results provide new evidence that the FA pathway discriminates among DNA structures and demonstrate that triggering the FA pathway can be uncoupled from DNA replication and ATRIP-dependent activation.

The cost of replication fidelity in human immunodeficiency virus type 1

Mutation rates should be governed by at least three evolutionary factors: the need for beneficial mutations, the benefit of minimizing the mutational load and the cost of replication fidelity. RNA viruses show high mutation rates compared with DNA micro-organisms, and recent findings suggest that the cost of fidelity might play a role in the evolution of increased mutation rates. Here, by analysing previously published data from HIV-1 reverse transcriptase in vitro assays, we show a trade-off between enzymatic accuracy and the maximum rate of polymerization, thus providing a biochemical basis for the fitness cost of fidelity in HIV-1. This trade-off seems to be related to inefficient extension of mispairs, which increases fidelity at the expense of the polymerization rate. Since in RNA viruses fast replication is critical for survival, this could impose a high cost of fidelity and favour the evolution of high mutation rates.

Examining interactions of HIV-1 reverse transcriptase with single-stranded template nucleotides by nucleoside analog interference

Crystallographic studies have implicated several residues of the p66 fingers subdomain of human immunodeficiency virus type-1 reverse transcriptase in contacting the single-stranded template overhang immediately ahead of the DNA polymerase catalytic center. This interaction presumably assists in inducing the appropriate geometry on the template base for efficient and accurate incorporation of the incoming dNTP. To investigate this, we introduced nucleoside analogs either individually or in tandem into the DNA template ahead of the catalytic center and investigated whether they induce pausing of the replication machinery before serving as the template base. Analogs included abasic tetrahydrofuran linkages, neutralizing methylphosphonate linkages, and conformationally locked nucleosides. In addition, several Phe-61 mutants were included in our analysis, based on previous data indicating that altering this residue affects both strand displacement synthesis and the fidelity of DNA synthesis. We demonstrate here that altering the topology of the template strand two nucleotides ahead of the catalytic center can interrupt DNA synthesis. Mutating Phe-61 to either Ala or Leu accentuates this defect, whereas replacement with an aromatic residue (Trp) allows the mutant enzyme to bypass the template analogs with relative ease.

Nucleotide specificity of HIV-1 reverse transcriptases with amino acid substitutions affecting Ala-114

Ala-114, together with Asp-113, Tyr-115 and Gln-151, form the pocket that accommodates the 3'-OH of the incoming dNTP in the HIV-1 RT (reverse transcriptase). Four mutant RTs having serine, glycine, threonine or valine instead of Ala-114 were obtained by site-directed mutagenesis. While mutants A114S and A114G retained significant DNA polymerase activity, A114T and A114V showed very low catalytic efficiency in nucleotide incorporation assays, due to their high apparent K(m) values for dNTP. Discrimination between AZTTP (3'-azido-3'-deoxythymidine triphosphate) and dTTP was not significantly affected by mutations A114S and A114G in assays carried out with heteropolymeric template/primers. However, both mutants showed decreased susceptibility to AZTTP when poly(rA)/(dT)16 was used as substrate. Steady-state kinetic analysis of the incorporation of ddNTPs compared with dNTPs showed that substituting glycine for Ala-114 produced a 5-6-fold increase in the RT's ability to discriminate against ddNTPs (including the physiologically relevant metabolites of zalcitabine and didanosine), a result that was confirmed in primer-extension assays. In contrast, A114S and A114V showed wild-type ddNTP/dNTP discrimination efficiencies. Discrimination against ribonucleotides was not affected by mutations at position 114. Misinsertion and mispair extension fidelity assays as well as determinations of G-->A mutation frequencies using a lacZ complementation assay showed that, unlike Tyr-115 or Gln-151 mutants, the fidelity of HIV-1 RT was not largely affected by substitutions of Ala-114. The role of the side-chain of Ala-114 in ddNTP/dNTP discrimination appears to be determined by its participation in van der Waals interactions with the ribose moiety of the incoming nucleotide.

Polymorphisms of NS5B protein relates to early clearance of hepatitis C virus by interferon plus ribavirin: a pilot study

Although randomized trials have shown enhancement of efficacy for combination therapy with interferon (IFN) alpha-2b and ribavirin compared with IFN monotherapy as first-line treatment for chronic hepatitis C, infection with genotype 1b and high viremia are still associated with significantly low response rates compared with non-1 genotypes and low viremia. We analysed amino acid sequences of the viral RNA-dependent RNA polymerase (RdRP) or nonstructural protein 5B (NS5B), responsible for ribavirin misincorporation into RNA products in patients with genotype 1b-related chronic hepatitis C and high viremia, and examined the relationship between such RdRp polymorphisms, and the initial decline in viral load induced by combination therapy with IFN-alpha and ribavirin. Substitution of glutamic acid to lysine at the 124th position (E124K) and of isoleucine to valine at the 85th position (I85V) were found to be closely associated with a potent decline of viral load and viral clearance at 8 weeks of treatment (five of five patients, coincidence rate 100%). In conclusion, our results suggest that the polymorphisms of E124K and I85V identified in NS5B protein are crucial for early viral clearance in patients with genotype 1b and high viremia by combination therapy with IFN and ribavirin, and that detection of amino acid sequence motifs might enable prediction of clinical efficacy.

Increased G-->A transition frequencies displayed by primer grip mutants of human immunodeficiency virus type 1 reverse transcriptase

A genetic screen based on the blue-white beta-galactosidase complementation assay designed to detect G-->A mutations arising during RNA-dependent DNA synthesis was used to compare the fidelity of mutant human immunodeficiency virus type 1 reverse transcriptases (RTs) with the mutations M230L and M230I with the wild-type enzyme, in the presence of biased deoxynucleoside triphosphate (dNTP) pools. The mutant RTs with the M230L and M230I changes were found to be 20 to 70 times less faithful than the wild-type RT in the presence of low [dCTP]/[dTTP] ratios but showed similar fidelity in assays carried out with equimolar concentrations of each nucleotide. Biased dNTP pools led to short tandem repeat deletions in the target sequence, which were also detectable with the assay. However, deletion frequencies were similar for all of the RTs tested. The reported data suggest that RT pausing due to the low dNTP levels available in the RT reaction mixture facilitates strand transfer, in a process that is not necessarily mediated by nucleotide misinsertion.

Molecular model of SARS coronavirus polymerase: implications for biochemical functions and drug design

The causative agent of severe acute respiratory syndrome (SARS) is a previously unidentified coronavirus, SARS-CoV. The RNA-dependent RNA polymerase (RdRp) of SARS-CoV plays a pivotal role in viral replication and is a potential target for anti-SARS therapy. There is a lack of structural or biochemical data on any coronavirus polymerase. To provide insights into the structure and function of SARS-CoV RdRp, we have located its conserved motifs that are shared by all RdRps, and built a three-dimensional model of the catalytic domain. The structural model permits us to discuss the potential functional roles of the conserved motifs and residues in replication and their potential interactions with inhibitors of related enzymes. We predict important structural attributes of potential anti-SARS-CoV RdRp nucleotide analog inhibitors: hydrogen-bonding capability for the 2′ and 3′ groups of the sugar ring and C3′ endo sugar puckering, and the absence of a hydrophobic binding pocket for non-nucleoside analog inhibitors similar to those observed in hepatitis C virus RdRp and human immunodeficiency virus type 1 reverse transcriptase. We propose that the clinically observed resistance of SARS to ribavirin is probably due to perturbation of the conserved motif A that controls rNTP binding and fidelity of polymerization. Our results suggest that designing anti-SARS therapies can benefit from successful experiences in design of other antiviral drugs. This work should also provide guidance for future biochemical experiments.

Influence of reverse transcriptase variants, drugs, and Vpr on human immunodeficiency virus type 1 mutant frequencies

The evolution of drug resistance is a major complication of human immunodeficiency virus type 1 (HIV-1) chemotherapy. HIV-1 reverse transcriptase (RT) is a major target of antiretroviral therapy and ultimately the target of drug resistance mutations. Previous studies have indicated that drug-resistant HIV-1 RTs can alter HIV-1 mutant frequencies. In this study, we have tested a panel of HIV-1 RT variants for their ability to influence virus mutant frequencies. The RT variants tested included drug-resistant RT variants as well as other variants analyzed in enzyme fidelity studies with the lacZalpha gene as a mutation target and/or implicated as being important for enzyme fidelity by structural studies. Combinations of mutations that alone had a statistically significant influence on virus mutant frequencies resulted in different mutant frequency phenotypes. Furthermore, when virus replication occurred in the presence of drugs [e.g., 3'-azido-3'-deoxythymidine, (-)2/,3'-dideoxy-3'-thiacytidine, hydroxyurea, thymidine, or thioguanine] with selected RT variants, virus mutant frequencies increased. Similarly, Vpr variants deficient for binding to the uracil DNA glycosylase repair enzyme were observed to influence HIV-1 virus mutant frequencies when tested alone or in combination with RT variants. In summary, these observations indicate that HIV-1 mutant frequencies can significantly change by single amino acid substitutions in RT and that these effects can be altered by additional mutations in RT, by drugs, and/or by expression of Vpr variants. Such altered virus mutant frequencies could impact HIV-1 dynamics and evolution in small population sizes.

Molecular basis of fidelity of DNA synthesis and nucleotide specificity of retroviral reverse transcriptases

Reverse transcription involves the conversion of viral genomic RNAinto proviral double-stranded DNA that integrates into the host cell genome. Cellular DNA polymerases replicate the integrated viral DNA and RNA polymerase II transcribes the proviral DNA into RNA genomes that are packaged into virions. Although mutations can be introduced at any of these replication steps, reverse transcriptase (RT) errors play a major role in retroviral mutation. This review summarizes our current knowledge on fidelity of reverse transcriptases. Estimates of retroviral mutation rates or fidelity of retroviral RTs are discussed in the context of the different techniques used for this purpose (i.e., retroviral vectors replicated in culture, misinsertion and mispair extension fidelity assay, etc.). In vitro fidelity assays provide information on the RT's accuracy during the elongation reaction of DNA synthesis. In addition, other steps such as initiation of reverse transcription, or strand transfer, and factors including viral proteins such as Vpr [in the case of the human immunodeficiency virus type 1 (HIV-1)] have been shown to influence fidelity. A comprehensive description of the effect of amino acid substitutions on the fidelity of HIV-1 RT is presented. Published data point to certain dNTP-binding residues, as well as to various amino acids involved in interactions with the template or the primer strand, and to residues in the minor groove-binding track as major components of the fidelity center of retroviral RTs. Implications of these studies include the design of novel therapeutic strategies leading to virus extinction, by increasing the viral mutation rate beyond a tolerable threshold.