Residues in the alphaH and alphaI helices of the HIV-1 reverse transcriptase thumb subdomain required for the specificity of RNase H-catalyzed removal of the polypurine tract primer

HIV-1 Reverse Transcriptase Polymerase and RNase H (Ribonuclease H) Active Sites Work Simultaneously and Independently

HIV reverse transcriptase plays a central role in viral replication and requires coordination of both polymerase and RNase H activities. Although this coordination is crucial in viral replication, whether a DNA/RNA hybrid can simultaneously engage both active sites has yet to be determined as structural and kinetic analyses have provided contradictory results. Single nucleotide incorporation and RNase H cleavage were examined using presteady-state kinetics with global data analysis. The results revealed three interconverting reverse transcriptase-DNA/RNA species; 43% were active for both sites simultaneously, 27% showed only polymerase activity, and the remaining 30% were nonproductive. Our data clearly demonstrated that the DNA/RNA hybrid could contact both active sites simultaneously, although the single nucleotide incorporation (105 s^-1) was ∼5-fold faster than the cleavage (23 s^-1). By using a series of primers with different lengths, we found that a string of at least 4-6 nucleotides downstream of the cleaving site was required for efficient RNA cleavage. This was corroborated by our observations that during processive nucleotide incorporation, sequential rounds of RNA cleavage occurred each time after ∼6 nucleotides were incorporated. More importantly, during processive primer extension, pyrophosphate (PP_i) release was rate-limiting so that the average rate of nucleotide incorporation (∼28 s^-1) was comparable with that of net RNA cleavage (∼27 nucleotides(s)). Although polymerization is efficient and processive, RNase H is inefficient and periodic. This combination allows the two catalytic centers of HIVRT to work simultaneously at similar speeds without being tightly coupled.

Reverse Transcription of Retroviruses and LTR Retrotransposons

The enzyme reverse transcriptase (RT) was discovered in retroviruses almost 50 years ago. The demonstration that other types of viruses, and what are now called retrotransposons, also replicated using an enzyme that could copy RNA into DNA came a few years later. The intensity of the research in both the process of reverse transcription and the enzyme RT was greatly stimulated by the recognition, in the mid-1980s, that human immunodeficiency virus (HIV) was a retrovirus and by the fact that the first successful anti-HIV drug, azidothymidine (AZT), is a substrate for RT. Although AZT monotherapy is a thing of the past, the most commonly prescribed, and most successful, combination therapies still involve one or both of the two major classes of anti-RT drugs. Although the basic mechanics of reverse transcription were worked out many years ago, and the first high-resolution structures of HIV RT are now more than 20 years old, we still have much to learn, particularly about the roles played by the host and viral factors that make the process of reverse transcription much more efficient in the cell than in the test tube. Moreover, we are only now beginning to understand how various host factors that are part of the innate immunity system interact with the process of reverse transcription to protect the host-cell genome, the host cell, and the whole host, from retroviral infection, and from unwanted retrotransposition.

Ty3 reverse transcriptase complexed with an RNA-DNA hybrid shows structural and functional asymmetry

Retrotransposons are a class of mobile genetic elements that replicate by converting their single-stranded RNA intermediate to double-stranded DNA through the combined DNA polymerase and ribonuclease H (RNase H) activities of the element-encoded reverse transcriptase (RT). Although a wealth of structural information is available for lentiviral and gammaretroviral RTs, equivalent studies on counterpart enzymes of long terminal repeat (LTR)-containing retrotransposons, from which they are evolutionarily derived, is lacking. In this study, we report the first crystal structure of a complex of RT from the Saccharomyces cerevisiae LTR retrotransposon Ty3 in the presence of its polypurine tract-containing RNA-DNA hybrid. In contrast to its retroviral counterparts, Ty3 RT adopts an asymmetric homodimeric architecture whose assembly is substrate dependent. Moreover, our structure and biochemical data suggest that the RNase H and DNA polymerase activities are contributed by individual subunits of the homodimer.

HIV-1 reverse transcription

Reverse transcription and integration are the defining features of the Retroviridae; the common name "retrovirus" derives from the fact that these viruses use a virally encoded enzyme, reverse transcriptase (RT), to convert their RNA genomes into DNA. Reverse transcription is an essential step in retroviral replication. This article presents an overview of reverse transcription, briefly describes the structure and function of RT, provides an introduction to some of the cellular and viral factors that can affect reverse transcription, and discusses fidelity and recombination, two processes in which reverse transcription plays an important role. In keeping with the theme of the collection, the emphasis is on HIV-1 and HIV-1 RT.

Probing Retroviral and Retrotransposon Genome Structures: The "SHAPE" of Things to Come

Understanding the nuances of RNA structure as they pertain to biological function remains a formidable challenge for retrovirus research and development of RNA-based therapeutics, an area of particular importance with respect to combating HIV infection. Although a variety of chemical and enzymatic RNA probing techniques have been successfully employed for more than 30 years, they primarily interrogate small (100–500 nt) RNAs that have been removed from their biological context, potentially eliminating long-range tertiary interactions (such as kissing loops and pseudoknots) that may play a critical regulatory role. Selective 2′ hydroxyl acylation analyzed by primer extension (SHAPE), pioneered recently by Merino and colleagues, represents a facile, user-friendly technology capable of interrogating RNA structure with a single reagent and, combined with automated capillary electrophoresis, can analyze an entire 10,000-nucleotide RNA genome in a matter of weeks. Despite these obvious advantages, SHAPE essentially provides a nucleotide “connectivity map,” conversion of which into a 3-D structure requires a variety of complementary approaches. This paper summarizes contributions from SHAPE towards our understanding of the structure of retroviral genomes, modifications to which technology that have been developed to address some of its limitations, and future challenges.

Mechanisms involved in the selection of HIV-1 reverse transcriptase thumb subdomain polymorphisms associated with nucleoside analogue therapy failure

Previous studies showed an increased prevalence of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) thumb subdomain polymorphisms Pro272, Arg277, and Thr286 in patients failing therapy with nucleoside analogue combinations. Interestingly, wild-type HIV-1(BH10) RT contains Pro272, Arg277, and Thr286. Here, we demonstrate that in the presence of zidovudine, HIV-1(BH10) RT mutations P272A/R277K/T286A produce a significant reduction of the viral replication capacity in peripheral blood mononuclear cells in both the absence and presence of M41L/T215Y. In studies carried out with recombinant enzymes, we show that RT thumb subdomain mutations decrease primer-unblocking activity on RNA/DNA complexes, but not on DNA/DNA template-primers. These effects were observed with primers terminated with thymidine analogues (i.e., zidovudine and stavudine) and carbovir (the relevant derivative of abacavir) and were more pronounced when mutations were introduced in the wild-type HIV-1(BH10) RT sequence context. RT thumb subdomain mutations increased by 2-fold the apparent dissociation equilibrium constant (K(d)) for RNA/DNA without affecting the K(d) for DNA/DNA substrates. RNase H assays carried out with RNA/DNA complexes did not reveal an increase in the reaction rate or in secondary cleavage events that could account for the decreased excision activity. The interaction of Arg277 with the phosphate backbone of the RNA template in HIV-1 RT bound to RNA/DNA and the location of Thr286 close to the RNA strand are consistent with thumb polymorphisms playing a role in decreasing nucleoside RT inhibitor excision activity on RNA/DNA template-primers by affecting interactions with the template-primer duplex without involvement of the RNase H activity of the enzyme.

Retroviral reverse transcriptases

Reverse transcription is a critical step in the life cycle of all retroviruses and related retrotransposons. This complex process is performed exclusively by the retroviral reverse transcriptase (RT) enzyme that converts the viral single-stranded RNA into integration-competent double-stranded DNA. Although all RTs have similar catalytic activities, they significantly differ in several aspects of their catalytic properties, their structures and subunit composition. The RT of human immunodeficiency virus type-1 (HIV-1), the virus causing acquired immunodeficiency syndrome (AIDS), is a prime target for the development of antiretroviral drug therapy of HIV-1/AIDS carriers. Therefore, despite the fundamental contributions of other RTs to the understanding of RTs and retrovirology, most recent RT studies are related to HIV-1 RT. In this review we summarize the basic properties of different RTs. These include, among other topics, their structures, enzymatic activities, interactions with both viral and host proteins, RT inhibition and resistance to antiretroviral drugs.

Impact of template overhang-binding region of HIV-1 RT on the binding and orientation of the duplex region of the template-primer

Fingers domain of HIV-1 RT is one of the constituents of the dNTP-binding pocket that is involved in binding of both dNTP and the template-primer. In the ternary complex of HIV-1 RT, two residues Trp-24 and Phe-61 located on the beta1 and beta3, respectively, are seen interacting with N + 1 to N + 3 nucleotides in the template overhang. We generated nonconservative and conservative mutant derivatives of these residues and examined their impact on the template-primer binding and polymerase function of the enzyme. We noted that W24A, F61A, and F61Y and the double mutant (W24A/F61A) were significantly affected in their ability to bind template-primer and also to catalyze the polymerase reaction while W24F remained unaffected. Using a specially designed template-primer with photoactivatable bromo-dU base in the duplex region at the penultimate position to the primer terminus, we demonstrated that F61A, W24A, F61Y as well as the double mutant were also affected in their cross-linking ability with the duplex region of the template-primer. We also isolated the E-TP covalent complexes of these mutants and examined their ability to catalyze single dNTP incorporation onto the immobilized primer terminus. The E-TP covalent complexes from W24F mutant displayed wild-type activity while those from W24A, F61A, F61Y, and the double mutant (W24A/F61A) were significantly impaired in their ability to catalyze dNTP incorporation onto the immobilized primer terminus. This unusual observation indicated that amino acid residues involved in the positioning of the template overhang may also influence the binding and orientation of the duplex region of the template-primer. Molecular modeling studies based on our biochemical results suggested that conformation of both W24 and F61 are interdependent on their interactions with each other, which together are required for proper positioning of the +1 template nucleotide in the binary and ternary complexes.

The y271 and i274 amino acids in reverse transcriptase of human immunodeficiency virus-1 are critical to protein stability

Reverse transcriptase (RT) of human immunodeficiency virus (HIV)-1 plays a key role in initiating viral replication and is an important target for developing anti-HIV drugs. Our previous study showed that two mutations (Y271A and I274A) in the turn RT (Gln(269)-Arg(277)) abrogated viral replication, but the replication capacity and RT activity was discordant. In this study, we further investigated why alanine substitutions at these two sites would affect viral replication. We found that both RT activity and RT protein were almost undetectable in viral particles of these two mutants, although the Pr160(gag-pol) mutants were properly expressed, transported and incorporated. Using protease inhibition assay, we demonstrated a correlation between the degradation of the RT mutants and the activity of viral protease. Our native gel analysis indicated that the mutations at 271 and 274 amino acids might cause conformational changes, leading to the formation of higher order oligomers instead of dimers, resulting in increased protein instability and susceptibility to viral protease. Thus, residues 271 and 274 are critical to RT stability and resistance to viral protease. The conservation of the two amino acid residues among different strains of HIV-1 lent further support to this conclusion. The knowledge gained here may prove useful in drug design.

Ribonuclease H: properties, substrate specificity and roles in retroviral reverse transcription

Retroviral reverse transcriptases possess both a DNA polymerase and an RNase H activity. The linkage with the DNA polymerase activity endows the retroviral RNases H with unique properties not found in the cellular counterparts. In addition to the typical endonuclease activity on a DNA/RNA hybrid, cleavage by the retroviral enzymes is also directed by both DNA 3' recessed and RNA 5' recessed ends, and by certain nucleotide sequence preferences in the vicinity of the cleavage site. This spectrum of specificities enables retroviral RNases H to carry out a series of cleavage reactions during reverse transcription that degrade the viral RNA genome after minus-strand synthesis, precisely generate the primer for the initiation of plus strands, facilitate the initiation of plus-strand synthesis and remove both plus- and minus-strand primers after they have been extended.

Autoimmunogenicity of the helix-loop-helix DNA-binding domain

Nonimmunogenic character of native DNA, and its high immunogenicity when presented in complex with the DNA-binding proteins indicate that the latter might contain molecular triggers of anti-DNA response. To find if this is the case, we have evaluated the autoimmunogenic potential of the main DNA-binding domain of HIV-1 reverse transcriptase that belongs to the canonical helix-loop-helix type. BALB/c mice were immunized with a peptide representing the domain, alone or in complex with the fragmented human DNA in the presence of an adjuvant. Mice were assessed for specific antibodies, autoantibodies against a panel of self-antigens; glomerular immunoglobulin deposition; and for the signs of autoimmune disease, such as proteinuria, and changes in the blood components. Immunization with the adjuvanted peptide-DNA complex induced autoantibodies against double-stranded DNA, histones, heterochromatin, and kidney proteins; glomerular IgG and IgA deposition; proteinuria; thrombocytopenia, and anemia. Altogether, this identifies the helix-loop-helix DNA-binding domain as one of the molecular triggers of autoimmunity to DNA and DNA-associated proteins. The experiments cast new light on the role of the DNA-binding retroviral proteins in the induction of autoimmunity, and on the origins of autoimmune complications in the microbial infections in general. It also implies that choosing the DNA-binding proteins as vaccine candidates should be done with precaution.

RNase H activity: structure, specificity, and function in reverse transcription

This review compares the well-studied RNase H activities of human immunodeficiency virus, type 1 (HIV-1) and Moloney murine leukemia virus (MoMLV) reverse transcriptases. The RNase H domains of HIV-1 and MoMLV are structurally very similar, with functions assigned to conserved subregions like the RNase H primer grip and the connection subdomain, as well as to distinct features like the C-helix and loop in MoMLV RNase H. Like cellular RNases H, catalysis by the retroviral enzymes appears to involve a two-metal ion mechanism. Unlike cellular RNases H, the retroviral RNases H display three different modes of cleavage: internal, DNA 3' end-directed, and RNA 5' end-directed. All three modes of cleavage appear to have roles in reverse transcription. Nucleotide sequence is an important determinant of cleavage specificity with both enzymes exhibiting a preference for specific nucleotides at discrete positions flanking an internal cleavage site as well as during tRNA primer removal and plus-strand primer generation. RNA 5' end-directed and DNA 3' end-directed cleavages show similar sequence preferences at the positions closest to a cleavage site. A model for how RNase H selects cleavage sites is presented that incorporates both sequence preferences and the concept of a defined window for allowable cleavage from a recessed end. Finally, the RNase H activity of HIV-1 is considered as a target for anti-virals as well as a participant in drug resistance.

The diversity of retrotransposons and the properties of their reverse transcriptases

A number of abundant mobile genetic elements called retrotransposons reverse transcribe RNA to generate DNA for insertion into eukaryotic genomes. Four major classes of retrotransposons are described here. First, the long-terminal-repeat (LTR) retrotransposons have similar structures and mechanisms to those of the vertebrate retroviruses. Genes that may enable these retrotransposons to leave a cell have been acquired by these elements in a number of animal and plant lineages. Second, the tyrosine recombinase retrotransposons are similar to the LTR retrotransposons except that they have substituted a recombinase for the integrase and recombine into the host chromosomes. Third, the non-LTR retrotransposons use a cleaved chromosomal target site generated by an encoded endonuclease to prime reverse transcription. Finally, the Penelope-like retrotransposons are not well understood but appear to also use cleaved DNA or the ends of chromosomes as primer for reverse transcription. Described in the second part of this review are the enzymatic properties of the reverse transcriptases (RTs) encoded by retrotransposons. The RTs of the LTR retrotransposons are highly divergent in sequence but have similar enzymatic activities to those of retroviruses. The RTs of the non-LTR retrotransposons have several unique properties reflecting their adaptation to a different mechanism of retrotransposition.

HIV-1 reverse transcriptase structure with RNase H inhibitor dihydroxy benzoyl naphthyl hydrazone bound at a novel site

The rapid emergence of drug-resistant variants of human immunodeficiency virus, type 1 (HIV-1), has limited the efficacy of anti-acquired immune deficiency syndrome (AIDS) treatments, and new lead compounds that target novel binding sites are needed. We have determined the 3.15 A resolution crystal structure of HIV-1 reverse transcriptase (RT) complexed with dihydroxy benzoyl naphthyl hydrazone (DHBNH), an HIV-1 RT RNase H (RNH) inhibitor (RNHI). DHBNH is effective against a variety of drug-resistant HIV-1 RT mutants. While DHBNH has little effect on most aspects of RT-catalyzed DNA synthesis, at relatively high concentrations it does inhibit the initiation of RNA-primed DNA synthesis. Although primarily an RNHI, DHBNH binds >50 A away from the RNH active site, at a novel site near both the polymerase active site and the non-nucleoside RT inhibitor (NNRTI) binding pocket. When DHBNH binds, both Tyr181 and Tyr188 remain in the conformations seen in unliganded HIV-1 RT. DHBNH interacts with conserved residues (Asp186, Trp229) and has substantial interactions with the backbones of several less well-conserved residues. On the basis of this structure, we designed substituted DHBNH derivatives that interact with the NNRTI-binding pocket. These compounds inhibit both the polymerase and RNH activities of RT.

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.

The HIV-1 reverse transcriptase mutants G190S and G190A, which confer resistance to non-nucleoside reverse transcriptase inhibitors, demonstrate reductions in RNase H activity and DNA synthesis from tRNA(Lys, 3) that correlate with reductions in replication efficiency

We evaluated the replication efficiency of the HIV reverse transcriptase (RT) mutants K103N, G190A, and G190S, which confer resistance to the non-nucleoside RT inhibitor efavirenz, using growth competition assays in cell culture. In the absence of efavirenz, the fitness hierarchy was G190S < G190A < K103N < wild-type. The fitness reduction of G190S relative to K103N was less evident at high efavirenz concentrations, although K103N still replicated more efficiently. Efficiency of RNase H cleavage and RNA-dependent DNA synthesis from tRNA(Lys, 3) correlated with relative fitness, in biochemical studies of mutant RTs. Presteady state and steady state polymerization assays using DNA primers detected no abnormalities. This work is consistent with previous studies demonstrating that initiation of viral DNA synthesis is reduced in mutants with slowed RNase H cleavage, and suggests that both abnormalities contribute to the replication defect of these mutants. It also suggests that high concentrations of efavirenz are unlikely to favor the selection of G190S clinically.

Examining Ty3 polypurine tract structure and function by nucleoside analog interference

We have combined nucleoside analog interference with chemical footprinting, thermal denaturation, NMR spectroscopy, and biochemical studies to understand recognition of the polypurine tract (PPT) primer of the Saccharomyces cerevisiae long terminal repeat-containing retrotransposon Ty3 by its cognate reverse transcriptase. Locked nucleic acid analogs, which constrain sugar ring geometry, were introduced pairwise throughout the PPT (-)-DNA template, whereas abasic tetrahydrofuran linkages, which lack the nucleobase but preserve the sugar phosphate backbone, were introduced throughout the (-)-strand DNA template and (+)-strand RNA primer. Collectively, our data suggest that both the 5'- and 3'-portions of the PPT-containing RNA/DNA hybrid are sensitive to nucleoside analog substitution, whereas the intervening region can be modified without altering cleavage specificity. These two regions most likely correspond to portions of the PPT that make close contact with the Ty3 reverse transcriptase thumb subdomain and RNase H catalytic center, respectively. Achieving a similar phenotype with nucleoside analogs that have different effects on duplex geometry reveals structural features that are important mediators of Ty3 PPT recognition. Finally, the results from introducing tetrahydrofuran lesions around the scissile PPT/unique 3'-sequence junction indicate that template nucleobase -1 is dispensable for catalysis, whereas a primer nucleobase on either side of the junction is necessary.

HIV-1 reverse transcriptase mutations that confer decreased in vitro susceptibility to anti-RT DNA aptamer RT1t49 confer cross resistance to other anti-RT aptamers but not to standard RT inhibitors

RNA and DNA aptamers specific for HIV-1 reverse transcriptase (RT) can inhibit reverse transcription in vitro. RNA aptamers have been shown to potently block HIV-1 replication in culture. We previously reported mutants of HIV-1 RT with substitutions N255D or N265D that display resistance to the DNA aptamer RT1t49. Variant viruses bearing these mutations singly or in combination were compromised for replication. In order to address the wider applicability of such aptamers, HIV-1 RT variants containing the N255D, N265D or both (Dbl) were tested for the extent of their cross-resistance to other DNA/RNA aptamers as well as to other RT inhibitors. Both N265D and Dbl RTs were resistant to most aptamers tested. N255D mutant displayed mild resistance to two of the DNA aptamers, little change in sensitivity to three and hypersensitivity to one. Although all mutants displayed wild type-like ribonuclease H activity, their activity was compromised under conditions that prevent re-binding. This suggests that the processivity defect caused by these mutations can also affect RNase H function thus contributing further to the replication defect in mutant viruses. These results indicate that mutants conferring resistance to anti-RT aptamers significantly affect many HIV-1 RT enzymatic activities, which could contribute to preventing the development of resistance in vivo. If such mutations were to arise in vivo, our results suggest that variant viruses should remain susceptible to many existing anti-RT inhibitors. This result was tempered by the observation that NRTI-resistance mutations such as K65R can confer resistance to some anti-RT aptamers.

Interaction of the Ty3 reverse transcriptase thumb subdomain with template-primer

Amino acid sequence alignment was used to identify the putative thumb subdomain of reverse transcriptase (RT) from the Saccharomyces cerevisiae long terminal repeat-containing retrotransposon Ty3. The counterpart to helix alphaH of human immunodeficiency virus type 1 (HIV-1) RT, which mediates important interactions with a duplex nucleic acid approximately 3-6 bp behind the DNA polymerase catalytic center, was identified between amino acids 290 and 298 of the Ty3 enzyme. The consequences of substituting Ty3 RT Gln290, Phe292, Gly294, Asn297, and Tyr298 (the counterparts of HIV-1 RT Gln258, Leu260, Gly262, Asn265, and Trp266, respectively) for both DNA polymerase and RNase H activities were examined. DNA-dependent DNA synthesis was evaluated on unmodified substrates and on duplexes containing targeted insertion of locked nucleic acid analogs and abasic lesions in either the template or primer. Based on this combined strategy, our data suggest an interaction of Ty3 RT Tyr298 with primer nucleotide -3, Gly294 with primer nucleotide -4, and Asn297 with template nucleotide -6. Substitution of Ala for Gln290 was well tolerated, despite the high degree of conservation at this position. Mutations in the thumb subdomain of Ty3 also affected RNase H activity, suggesting a closer spatial relationship between its N- and C-terminal catalytic centers compared with HIV-1 RT.

Effect of polypurine tract (PPT) mutations on human immunodeficiency virus type 1 replication: a virus with a completely randomized PPT retains low infectivity

We introduced polypurine tract (PPT) mutations, which we had previously tested in an in vitro assay, into the viral clone NL4-3KFSdelta nef. Each mutant was tested for single-round infectivity and virion production. All of the PPT mutations had an effect on replication; however, mutation of the 5' end appeared to have less of an effect on infectivity than mutation of the 3' end of the PPT sequence. Curiously, a mutation in which the entire PPT sequence was randomized (PPTSUB) retained 12% of the infectivity of the wild type (WT) in a multinuclear activation of galactosidase indicator assay. Supernatants from these infections contained viral particles, as evidenced by the presence of p24 antigen. Two-long terminal repeat (2-LTR) circle junction analysis following PPTSUB infection revealed that the mutant could form a high percentage of normal junctions. Quantification of the 2-LTR circles using real-time PCR revealed that number of 2-LTR circles from cells infected with the PPTSUB mutant was 3.5 logs greater than 2-LTR circles from cells infected with WT virus. To determine whether the progeny virions from a PPTSUB infection could undergo further rounds of replication, we introduced the PPTSUB mutation into a replication-competent virus. Our results show that the mutant virus is able to replicate and that the infectivity of the progeny virions increases with each passage, quickly reverting to a WT PPT sequence. Together, these experiments confirm that the 3' end of the PPT is important for plus-strand priming and that a virus that completely lacks a PPT can replicate at a low level.

Two modes of HIV-1 polypurine tract cleavage are affected by introducing locked nucleic acid analogs into the (-) DNA template

Unusual base-pairing in a co-crystal of reverse transcriptase (RT) and a human immunodeficiency virus type 1 (HIV-1) polypurine tract (PPT)-containing RNA/DNA hybrid suggests local nucleic acid flexibility mediates selection of the plus-strand primer. Structural elements of HIV-1 RT potentially participating in recognition of this duplex include the thumb subdomain and the ribonuclease H (RNase H) primer grip, the latter comprising elements of the connection subdomain and RNase H domain. To investigate how stabilizing HIV-1 PPT structure influences its recognition, we modified the (-) DNA template by inserting overlapping locked nucleic acid (LNA) doublets and triplets. Modified RNA/DNA hybrids were evaluated for cleavage at the PPT/U3 junction. Altered specificity was observed when the homopolymeric dA.rU tract immediately 5' of the PPT was modified, whereas PPT/U3 cleavage was lost after substitutions in the adjacent dT.rA tract. In contrast, the "unzipped" portion of the PPT was moderately insensitive to LNA insertions. Although a portion of the dC.rG and neighboring dT.rA tract were minimally affected by LNA insertion, RNase H activity was highly sensitive to altering the junction between these structural elements. Using 3'-end-labeled PPT RNA primers, we also identified novel cleavage sites ahead (+5/+6) of the PPT/U3 junction. Differential cleavage at the PPT/U3 junction and U3 + 5/+6 site in response to LNA-induced template modification suggests two binding modes for HIV-1 RT, both of which may be controlled by the interaction of its thumb subdomain (potentially via the minor groove binding track) at either site of the unzipped region.

Using pyrrolo-deoxycytosine to probe RNA/DNA hybrids containing the human immunodeficiency virus type-1 3' polypurine tract

Recent structural analyses indicate that localized regions of abnormal base pairing exist within RNA/DNA hybrids containing the HIV-1 polypurine tract (PPT) and that these distortions may play a role in PPT function. To examine this directly, we have introduced pyrrolo-deoxycytosine (pdC), a fluorescent, environmentally sensitive analog of deoxycytosine (dC), into the DNA strand of PPT-containing hybrids. Steady-state fluorescence analysis of these hybrids reveals that the DNA base 11 nt from the PPT-U3 junction is unpaired even in the absence of reverse transcriptase (RT). Unstable base pairing is also observed within the (rG:dC)6 tract in the downstream portion of the duplex, suggesting that HIV-1 RT may recognize multiple pre-existing distortions during PPT selection. HIV-1 RT hydrolyzes pdC-containing hybrids primarily at the PPT-U3 junction, indicating that the analog does not induce a gross structural deformation of the duplex. However, aberrant cleavage is frequently observed 3 bp from the site of pdC substitution, most likely reflecting a specific interaction between the analog and amino acid residues within the RNase H primer grip. pdC substitution within the template strand of a DNA duplex does not appear to significantly affect RT-catalyzed DNA synthesis. Implications of these findings on the use of pdC to examine nucleic acid structure are discussed.

Hydrolysis of RNA/DNA hybrids containing nonpolar pyrimidine isosteres defines regions essential for HIV type 1 polypurine tract selection

Both x-ray crystallography and chemical footprinting indicate that bases of the HIV type 1 (HIV-1) polypurine tract (PPT)-containing RNA/DNA hybrid deviate from standard Watson-Crick base pairing. However, the contribution of these structural anomalies to the accuracy of plus-strand primer selection by HIV-1 reverse transcriptase is not immediately clear. To address this issue, DNA templates harboring single and pairwise non-hydrogen-bonding isosteres of cytosine (2-fluoro-4-methylbenzene deoxyribonucleoside) and thymine (2,4-difluoro-5-methylbenzene deoxyribonucleoside) were synthesized and hybridized to PPT-containing RNA primers as a means of locally removing hydrogen bonding and destabilizing paired structure. Cleavage of these hybrids was examined with p66/p51 HIV-1 reverse transcriptase and a mutant carrying an alteration in the p66 RNase H primer shown to specifically impair PPT processing. Analog insertion within the PPT (rG):(dC) and central (rA):(dT) tracts repositioned the RNase H domain such that the RNA/DNA hybrid was cleaved 3-4 bp from the site of insertion, a distance corresponding closely to the spatial separation between the catalytic center and RNase H primer grip. However, PPT processing was significantly impaired when the junction between these tracts was substituted. Substitutions within the upstream (rA):(dT) tract, where maximum distortion had previously been observed, destroyed PPT processing. Collectively, our scanning mutagenesis approach implicates multiple regions of the PPT in the accuracy with which it is excised from (+) U3 RNA and DNA, and also provides evidence for close cooperation between the RNase H primer grip and catalytic center in achieving this cleavage.

Nonpolar thymine isosteres in the Ty3 polypurine tract DNA template modulate processing and provide a model for its recognition by Ty3 reverse transcriptase

Despite diverging in sequence and size, the polypurine tract (PPT) primers of retroviruses and long terminal repeat-containing retrotransposons are accurately processed from (+) U3 RNA and DNA by their cognate reverse transcriptases (RTs). In this paper, we demonstrate that misalignment of the Ty3 retrotransposon RT on the human immunodeficiency virus-1 PPT induces imprecise removal of adjacent (+)-RNA and failure to release (+)-DNA from the primer. Based on these observations, we explored the structural basis of Ty3 PPT recognition by chemically synthesizing RNA/DNA hybrids whose (-)-DNA template was substituted with the non-hydrogen-bonding thymine isostere 2,4-difluoro-5-methylbenzene (F). We observed a consistent spatial correlation between the site of T --> F substitution and enhanced ribonuclease H (RNase H) activity approximately 12-13 bp downstream. In the most pronounced case, dual T --> F substitution at PPT positions -1/-2 redirects RNase H cleavage almost exclusively to the novel site. The structural features of this unusual base suggest that its insertion into the Ty3 PPT (-)-DNA template weakens the duplex, inducing a destabilization that is recognized by a structural element of Ty3 RT approximately 12-13 bp from its RNase H catalytic center. A likely candidate for this interaction is the thumb subdomain, whose minor groove binding tract most likely contacts the duplex. The spatial relationship derived from T --> F substitution also infers that Ty3 PPT processing requires recognition of sequences in its immediate 5' vicinity, thereby locating the RNase H catalytic center over the PPT-U3 junction, a notion strengthened by additional mutagenesis studies of this paper.

Human immunodeficiency virus type 2 reverse transcriptase activity in model systems that mimic steps in reverse transcription

Human immunodeficiency virus type 2 (HIV-2) infection is a serious problem in West Africa and Asia. However, there have been relatively few studies of HIV-2 reverse transcriptase (RT), a potential target for antiviral therapy. Detailed knowledge of HIV-2 RT activities is critical for development of specific high-throughput screening assays of potential inhibitors. Here, we have conducted a systematic evaluation of HIV-2 RT function, using assays that model specific steps in reverse transcription. Parallel studies were performed with HIV-1 RT. In general, under standard assay conditions, the polymerase and RNase H activities of the two enzymes were comparable. However, when the RT concentration was significantly reduced, HIV-2 RT was less active than the HIV-1 enzyme. HIV-2 RT was also impaired in its ability to catalyze secondary RNase H cleavage in assays that mimic tRNA primer removal during plus-strand transfer and degradation of genomic RNA fragments during minus-strand DNA synthesis. In addition, initiation of plus-strand DNA synthesis was much less efficient with HIV-2 RT than with HIV-1 RT. This may reflect architectural differences in the primer grip regions in the p66 (HIV-1) and p68 (HIV-2) palm subdomains of the two enzymes. The implications of our findings for antiviral therapy are discussed.

Incorporation of uracil into minus strand DNA affects the specificity of plus strand synthesis initiation during lentiviral reverse transcription

Many retroviruses either encode dUTP pyrophosphatase (dUTPase) or package host-derived uracil DNA glycosylase as a means to limit the accumulation of uracil in DNA strands, suggesting that uracil is detrimental to one or more steps in the viral life cycle. In the present study, the effects of DNA uracilation on (-) strand DNA synthesis, RNase H activity, and (+) strand DNA synthesis were investigated in a cell-free system. This system uses the activities of purified human immunodeficiency virus type 1 (HIV-1) reverse transcriptase to convert single-stranded RNA to double-stranded DNA in a single reaction mixture. Substitution of dUTP for dTTP had no effect on (-) strand synthesis but significantly decreased yields of (+) strand DNA. Mapping of nascent (+) strand 5' ends revealed that this was due to decreased initiation from polypurine tracts with a concomitant increase in initiation at non-polypurine tract sites. Aberrant initiation correlated with a change in RNase H cleavage specificity when assayed on preformed RNA-DNA duplexes containing uracilated DNA, suggesting that appropriate "selection" of the (+) strand primer is affected. Collectively, these data suggest that accumulation of uracil in retroviral DNA may disrupt the viral life cycle by altering the specificity of (+) strand DNA synthesis initiation during reverse transcription.

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.

Structures of complexes formed by HIV-1 reverse transcriptase at a termination site of DNA synthesis

This study presents structural parameters associated with termination of human immunodeficiency virus, type 1 (HIV-1) reverse transcriptase (RT) at Ter2, the major termination site located in the center of the HIV-1 genome. DNA footprinting studies of various elongation complexes formed by RT around wild type and mutant Ter2 sites have revealed two major structural transformations of these complexes when the enzyme gets closer to Ter2. First, the interactions between RT and the DNA duplex are less extended, although the global affinity of the enzyme for this duplex is only decreased by 2-fold. Second, there is an atypical positioning of the RT RNase H domain on the DNA duplex. We interpret our data as indicating that the A(n)T(m) motif located upstream of Ter2 prevents a classical positioning of the enzyme on the double-stranded part of the DNA duplex at some precise positions of elongation downstream of this motif. Instead, novel species of binary and/or ternary complexes, characterized by atypical footprints, are formed. The new rate-limiting step of the reaction, characterized in the preceding paper (Lavigne, M., Polomack, L., and Buc, H. (2001) J. Biol. Chem. 276, 31429-31438), would be a transition leading from these new species to a catalytically competent ternary complex.

HIV-1 reverse transcriptase interaction with model RNA-DNA duplexes

HIV-1 reverse transcriptase (HIV-1 RT) is a multifunctional enzyme responsible for converting viral RNA into preintegrative DNA during the early stages of viral infection. DNA polymerase and RNase H activities are required, and several conformationally distinct primer-templates must be accommodated by the enzyme during the process. Parameters of interaction between model substrates (ligands) and HIV-1 RT (wild type p66/p51 and the RNase H-deficient mutant p66(E478Q)/p51) (analytes) were estimated by surface plasmon resonance at 25 degrees C, pH 8.0. Binding of RT to the ligands is specific and can be analyzed using a conventional 1:1 binding algorithm. RNA-DNA hybrids with 5'-template overhangs of 6 and 12 nucleotides bind to RT approximately one order of magnitude stronger than the corresponding 36-mer with blunt ends due to slower dissociation. Immobilization of the latter through either the 5'-end of RNA or DNA strand does not change the equilibrium constant (K(D)) for wild-type RT but the values of kinetic constants of association and dissociation differ significantly. For the p66(E478Q)/p51 enzyme, orientation effects are notable even altering the K(D) value. Binding of the p66(E478Q)/p51 to any RNA-DNA hybrids is slightly stronger compared with wild type. Data can be interpreted in terms of the mechanism of reverse transcription.

An immunodominant neutralization epitope on the 'thumb' subdomain of human immunodeficiency virus type 1 reverse transcriptase revealed by phage display antibodies

An antibody phage display library was produced from the splenocytes of mice immunized with an infectious vaccinia virus recombinant (WRRT) expressing the reverse transcriptase (RT) of human immunodeficiency virus type 1 (HIV-1). The library was panned against HIV-1 RT. Two clones, 5F and 5G, which produced Fab fragments specific for RT, were isolated. Surprisingly, both 5F and 5G Fab fragments were capable of strongly inhibiting the RNA-dependent DNA polymerase activity of HIV-1 RT. A hybridoma cell line that produces the monoclonal antibody 7C4, which strongly inhibits RT activity, was established previously using splenocytes from mice immunized with WRRT by the same immunization protocol. The epitope recognized by 7C4 exists in the region of the template primer-binding sites (or the 'helix clump') of RT. By epitope mapping and competitive ELISA analysis, it was shown that the 5F and 5G Fab fragments were directed against the same, or a very closely related, epitope that is recognized by 7C4. The neutralizing activities of the 5F, 5G and 7C4 Fab fragments correlated with their affinities for HIV-1 RT. DNA sequencing indicated that the immunoglobulin genes of the heavy chains of 5G and 7C4, as well as those of the light chains of 5F and 5G, had the same origin. These results suggest that the neutralizing epitope, which is recognized by these antibodies, becomes immunodominant after repeated immunization of mice with WRRT. This unique epitope, HIV-1 RT-specific and immunodominant neutralizing epitope (HRSINE), is a logical target for new types of HIV-1 RT inhibitors and gene therapy.

Human immunodeficiency virus type 1 central DNA flap: dynamic terminal product of plus-strand displacement dna synthesis catalyzed by reverse transcriptase assisted by nucleocapsid protein

To terminate the reverse transcription of the human immunodeficiency virus type 1 (HIV-1) genome, a final step occurs within the center of the proviral DNA generating a 99-nucleotide DNA flap (6). This step, catalyzed by reverse transcriptase (RT), is defined as a discrete strand displacement (SD) synthesis between the first nucleotide after the central priming (cPPT) site and the final position of the central termination sequence (CTS) site. Using recombinant HIV-1 RT and a circular single-stranded DNA template harboring the cPPT-CTS sequence, we have developed an SD synthesis-directed in vitro termination assay. Elongation, strand displacement, and complete central flap behavior were analyzed using electrophoresis and electron microscopy approaches. Optimal conditions to obtain complete central flap, which ended at the CTS site, have been defined in using nucleocapsid protein (NCp), the main accessory protein of the reverse transcription complex. A full-length HIV-1 central DNA flap was then carried out in vitro. Its synthesis appears faster in the presence of the HIV-1 NCp or the T4-encoded SSB protein (gp32). Finally, a high frequency of strand transfer was shown during the SD synthesis along the cPPT-CTS site with RT alone. This reveals a local and efficient 3'-5' branch migration which emphasizes some important structural fluctuations within the flap. These fluctuations may be stabilized by the NCp chaperone activity. The biological implications of the RT-directed NCp-assisted flap synthesis are discussed within the context of reverse transcription complexes, assembly of the preintegration complexes, and nuclear import of the HIV-1 proviral DNA to the nucleus toward their chromatin targets.

Crystal structure of HIV-1 reverse transcriptase in complex with a polypurine tract RNA:DNA

We have determined the 3.0 A resolution structure of wild-type HIV-1 reverse transcriptase in complex with an RNA:DNA oligonucleotide whose sequence includes a purine-rich segment from the HIV-1 genome called the polypurine tract (PPT). The PPT is resistant to ribonuclease H (RNase H) cleavage and is used as a primer for second DNA strand synthesis. The 'RNase H primer grip', consisting of amino acids that interact with the DNA primer strand, may contribute to RNase H catalysis and cleavage specificity. Cleavage specificity is also controlled by the width of the minor groove and the trajectory of the RNA:DNA, both of which are sequence dependent. An unusual 'unzipping' of 7 bp occurs in the adenine stretch of the PPT: an unpaired base on the template strand takes the base pairing out of register and then, following two offset base pairs, an unpaired base on the primer strand re-establishes the normal register. The structural aberration extends to the RNase H active site and may play a role in the resistance of PPT to RNase H cleavage.

Analysis of efficiency and fidelity of HIV-1 (+)-strand DNA synthesis reveals a novel rate-limiting step during retroviral reverse transcription

We have analyzed the efficiency and accuracy of polymerization at several different stages during the initiation of human immunodeficiency virus type 1 (HIV-1) (+)-strand DNA synthesis. This reaction is of particular interest, as it involves the recruitment by reverse transcriptase of an RNA primer that serves as substrate for both the polymerase and RNase H activities of the enzyme. We found that the correct incorporation of the first two nucleotides was severely compromised and that formation of mismatches was completely absent at this stage of initiation. Although the fidelity of incorporations decreased concomitantly with ensuing polymerization, the elongation of mispaired primers was literally blocked. Instead, mispaired primer strands initiated a switch from active synthesis of DNA to premature RNase H-mediated primer removal. These findings suggest the existence of a fragile equilibrium between these two enzymatic activities that is shifted toward RNase H cleavage once the polymerization process is aggravated. Our data show that the initiation of HIV-1 (+)-strand DNA synthesis differs significantly from reactions involving other primer/template combinations, including tRNA-primed (-)-strand DNA synthesis.

The sequential mechanism of HIV reverse transcriptase RNase H

Synthesis of the minus strand of viral DNA by human immunodeficiency virus, type 1 (HIV-1) reverse transcriptase is accompanied by RNase H degradation of the viral RNA genome. RNA fragments remain after synthesis and are degraded by the polymerase-independent mode of RNase H cleavage. Recently, we showed that this mode of cleavage occurs by a specific ordered mechanism in which primary cuts are first, secondary and 5-nucleotide cuts are next, and second primary cuts occur last (Wisniewski, M., Balakrishnan, M., Palaniappan, C., Fay, P., J., and Bambara, R., A. (2000) Proc. Natl. Acad. Sci. U.S.A. 97, 11978-11983). Ultimately the RNAs are cleaved into small fragments that can dissociate from the DNA template. Because the cleavage mechanism is an ordered series of events, we determined in this study whether any earlier cut is required for a later cut. By precisely inhibiting cleavage at each site, we examined the dependence of later cuts on cleavage at that site. We found that each cut is independent of the other cuts, demonstrating that the order of this stepwise mechanism is based on the rates of each cut. A mechanism for unlinked ordered cleavage consistent with these results is presented.

Comparison of second-strand transfer requirements and RNase H cleavages catalyzed by human immunodeficiency virus type 1 reverse transcriptase (RT) and E478Q RT

Truncated tRNA-DNA mimics were examined in an in vitro assay for second-strand transfer during human immunodeficiency virus type 1 (HIV-1) reverse transcription. Strand transfer in this system requires the progressive degradation of the RNA within the 18-mer tRNA-DNA (plus-strand strong stop DNA) intermediate to products approximately 8 nucleotides in length. The ability of the truncated substrates to substitute for directional processing by RNase H or reverse transcriptase (RT) was examined. Using wild-type HIV-1 RT, substrates which truncated the 5' end of the tRNA primer by 6, 9, and 12 nucleotides (Delta6, Delta9, and Delta12, respectively) were recognized by RNase H and resulted in strand transfer. An overlap of 5 nucleotides between the acceptor and newly synthesized DNA template was sufficient for strand transfer. The mutant RT, E478Q correctly catalyzed the initial cleavage of the 18-mer tRNA-DNA mimic in the presence of Mn(2+); however, no directional processing was observed. In contrast, no RNase H activity was observed with the Delta6, Delta9, and Delta12 substrates with E478Q RT in this strand transfer assay. However, when complemented with Escherichia coli RNase H, E478Q RT supported strand transfer with the truncated substrates. E478Q RT did cleave the truncated forms of the substrates, Delta6, Delta9, and Delta12, in a polymerase-independent assay. The size requirements of the substrates which were cleaved by the polymerase-independent RNase H activity of E478Q RT are defined.

Mutants of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase resistant to nonnucleoside reverse transcriptase inhibitors demonstrate altered rates of RNase H cleavage that correlate with HIV-1 replication fitness in cell culture

Three mutants of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (V106A, V179D, and Y181C), which occur in clinical isolates and confer resistance to nonnucleoside reverse transcriptase inhibitors (NNRTIs), were analyzed for RNA- and DNA-dependent DNA polymerization and RNase H cleavage. All mutants demonstrated processivities of polymerization that were indistinguishable from wild-type enzyme under conditions in which deoxynucleoside triphosphates were not limiting. The V106A reverse transcriptase demonstrated a three- to fourfold slowing of both DNA 3'-end-directed and RNA 5'-end-directed RNase H cleavage relative to both wild-type and V179D enzymes, similar to what was observed for P236L in a previously published study (P. Gerondelis et al., J. Virol. 73:5803-5813, 1999). In contrast, the Y181C reverse transcriptase demonstrated a selective acceleration of the secondary RNase H cleavage step during both modes of RNase H cleavage. The relative replication fitness of these mutants in H9 cells was assessed in parallel infections as well as in growth competition experiments. Of the NNRTI-resistant mutants, V179D was more fit than Y181C, and both of these mutants were more fit than V106A, which demonstrated the greatest reduction in RNase H cleavage. These findings, in combination with results from previous work, suggest that abnormalities in RNase H cleavage are a common characteristic of HIV-1 mutants resistant to NNRTIs and that combined reductions in the rates of DNA 3'-end- and RNA 5'-end-directed cleavages are associated with significant reductions in the replication fitness of HIV-1.