HIV-1 reverse transcriptase-associated RNase H cleaves RNA/RNA in arrested complexes: implications for the mechanism by which RNase H discriminates between RNA/RNA and RNA/DNA

Retroviral PBS-segment sequence and structure: Orchestrating early and late replication events

An essential regulatory hub for retroviral replication events, the 5' untranslated region (UTR) encodes an ensemble of cis-acting replication elements that overlap in a logical manner to carry out divergent RNA activities in cells and in virions. The primer binding site (PBS) and primer activation sequence initiate the reverse transcription process in virions, yet overlap with structural elements that regulate expression of the complex viral proteome. PBS-segment also encompasses the attachment site for Integrase to cut and paste the 3' long terminal repeat into the host chromosome to form the provirus and purine residues necessary to execute the precise stoichiometry of genome-length transcripts and spliced viral RNAs. Recent genetic mapping, cofactor affinity experiments, NMR and SAXS have elucidated that the HIV-1 PBS-segment folds into a three-way junction structure. The three-way junction structure is recognized by the host's nuclear RNA helicase A/DHX9 (RHA). RHA tethers host trimethyl guanosine synthase 1 to the Rev/Rev responsive element (RRE)-containing RNAs for m7-guanosine Cap hyper methylation that bolsters virion infectivity significantly. The HIV-1 trimethylated (TMG) Cap licenses specialized translation of virion proteins under conditions that repress translation of the regulatory proteins. Clearly host-adaption and RNA shapeshifting comprise the fundamental basis for PBS-segment orchestrating both reverse transcription of virion RNA and the nuclear modification of m7G-Cap for biphasic translation of the complex viral proteome. These recent observations, which have exposed even greater complexity of retroviral RNA biology than previously established, are the impetus for this article. Basic research to fully comprehend the marriage of PBS-segment structures and host RNA binding proteins that carry out retroviral early and late replication events is likely to expose an immutable virus-specific therapeutic target to attenuate retrovirus proliferation.

High-resolution view of HIV-1 reverse transcriptase initiation complexes and inhibition by NNRTI drugs

Reverse transcription of the HIV-1 viral RNA genome (vRNA) is an integral step in virus replication. Upon viral entry, HIV-1 reverse transcriptase (RT) initiates from a host tRNA^Lys₃ primer bound to the vRNA genome and is the target of key antivirals, such as non-nucleoside reverse transcriptase inhibitors (NNRTIs). Initiation proceeds slowly with discrete pausing events along the vRNA template. Despite prior medium-resolution structural characterization of reverse transcriptase initiation complexes (RTICs), higher-resolution structures of the RTIC are needed to understand the molecular mechanisms that underlie initiation. Here we report cryo-EM structures of the core RTIC, RTIC-nevirapine, and RTIC-efavirenz complexes at 2.8, 3.1, and 2.9 Å, respectively. In combination with biochemical studies, these data suggest a basis for rapid dissociation kinetics of RT from the vRNA-tRNA^Lys₃ initiation complex and reveal a specific structural mechanism of nucleic acid conformational stabilization during initiation. Finally, our results show that NNRTIs inhibit the RTIC and exacerbate discrete pausing during early reverse transcription.

Extended Interactions between HIV-1 Viral RNA and tRNALys3 Are Important to Maintain Viral RNA Integrity

The reverse transcription of the human immunodeficiency virus 1 (HIV-1) initiates upon annealing of the 3′-18-nt of tRNA^Lys3 onto the primer binding site (PBS) in viral RNA (vRNA). Additional intermolecular interactions between tRNA^Lys3 and vRNA have been reported, but their functions remain unclear. Here, we show that abolishing one potential interaction, the A-rich loop: tRNA^Lys3 anticodon interaction in the HIV-1 MAL strain, led to a decrease in viral infectivity and reduced the synthesis of reverse transcription products in newly infected cells. In vitro biophysical and functional experiments revealed that disruption of the extended interaction resulted in an increased affinity for reverse transcriptase (RT) and enhanced primer extension efficiency. In the absence of deoxyribose nucleoside triphosphates (dNTPs), vRNA was degraded by the RNaseH activity of RT, and the degradation rate was slower in the complex with the extended interaction. Consistently, the loss of vRNA integrity was detected in virions containing A-rich loop mutations. Similar results were observed in the HIV-1 NL4.3 strain, and we show that the nucleocapsid (NC) protein is necessary to promote the extended vRNA: tRNA^Lys3 interactions in vitro. In summary, our data revealed that the additional intermolecular interaction between tRNA^Lys3 and vRNA is likely a conserved mechanism among various HIV-1 strains and protects the vRNA from RNaseH degradation in mature virions.

Distinct Conformational States Underlie Pausing during Initiation of HIV-1 Reverse Transcription

A hallmark of the initiation step of HIV-1 reverse transcription, in which viral RNA genome is converted into double-stranded DNA, is that it is slow and non-processive. Biochemical studies have identified specific sites along the viral RNA genomic template in which reverse transcriptase (RT) stalls. These stalling points, which occur after the addition of three and five template dNTPs, may serve as checkpoints to regulate the precise timing of HIV-1 reverse transcription following viral entry. Structural studies of reverse transcriptase initiation complexes (RTICs) have revealed unique conformations that may explain the slow rate of incorporation; however, questions remain about the temporal evolution of the complex and features that contribute to strong pausing during initiation. Here we present cryo-electron microscopy and single-molecule characterization of an RTIC after three rounds of dNTP incorporation (+3), the first major pausing point during reverse transcription initiation. Cryo-electron microscopy structures of a +3 extended RTIC reveal conformational heterogeneity within the RTIC core. Three distinct conformations were identified, two of which adopt unique, likely off-pathway, intermediates in the canonical polymerization cycle. Single-molecule Förster resonance energy transfer experiments confirm that the +3 RTIC is more structurally dynamic than earlier-stage RTICs. These alternative conformations were selectively disrupted through structure-guided point mutations to shift single-molecule Förster resonance energy transfer populations back toward the on-pathway conformation. Our results support the hypothesis that conformational heterogeneity within the HIV-1 RTIC during pausing serves as an additional means of regulating HIV-1 replication.

Architecture of an HIV-1 reverse transcriptase initiation complex

Reverse transcription of the HIV-1 RNA genome into double-stranded DNA is a central step in infection¹ and a common target of antiretrovirals². The reaction is catalyzed by viral reverse transcriptase (RT)^3,4 that is packaged in an infectious virion along with 2 copies of dimeric viral genomic RNA⁵ and host tRNA^Lys₃, which acts as a primer for initiation of reverse transcription^6,7. Upon viral entry, initiation is slow and non-processive compared to elongation^8,9. Despite extensive efforts, the structural basis for RT function during initiation has remained a mystery. Here we apply cryo-electron microscopy (cryo-EM) to determine a three-dimensional structure of the HIV-1 RT initiation complex. RT is in an inactive polymerase conformation with open fingers and thumb and with the nucleic acid primer-template complex shifted away from the active site. The primer binding site (PBS) helix formed between tRNA^Lys₃ and HIV-1 RNA lies in the cleft of RT and is extended by additional pairing interactions. The 5′ end of the tRNA refolds and stacks on the PBS to create a long helical structure, while the remaining viral RNA forms two helical stems positioned above the RT active site, with a linker that connects these helices to the RNase H region of the PBS. Our results illustrate how RNA structure in the initiation complex alters RT conformation to decrease activity, highlighting a potential target for drug action.

Entire-Dataset Analysis of NMR Fast-Exchange Titration Spectra: A Mg2+ Titration Analysis for HIV-1 Ribonuclease H Domain

This article communicates our study to elucidate the molecular determinants of weak Mg²⁺ interaction with the ribonuclease H (RNH) domain of HIV-1 reverse transcriptase in solution. As the interaction is weak (a ligand-dissociation constant >1 mM), nonspecific Mg²⁺ interaction with the protein or interaction of the protein with other solutes that are present in the buffer solution can confound the observed Mg²⁺-titration data. To investigate these indirect effects, we monitored changes in the chemical shifts of backbone amides of RNH by recording NMR ¹H-¹⁵N heteronuclear single-quantum coherence spectra upon titration of Mg²⁺ into an RNH solution. We performed the titration under three different conditions: (1) in the absence of NaCl, (2) in the presence of 50 mM NaCl, and (3) at a constant 160 mM Cl^- concentration. Careful analysis of these three sets of titration data, along with molecular dynamics simulation data of RNH with Na⁺ and Cl^- ions, demonstrates two characteristic phenomena distinct from the specific Mg²⁺ interaction with the active site: (1) weak interaction of Mg²⁺, as a salt, with the substrate-handle region of the protein and (2) overall apparent lower Mg²⁺ affinity in the absence of NaCl compared to that in the presence of 50 mM NaCl. A possible explanation may be that the titrated MgCl₂ is consumed as a salt and interacts with RNH in the absence of NaCl. In addition, our data suggest that Na⁺ increases the kinetic rate of the specific Mg²⁺ interaction at the active site of RNH. Taken together, our study provides biophysical insight into the mechanism of weak metal interaction on a protein.

Reverse Transcriptase-Associated Ribonuclease H Activity as a Target for Antiviral Chemotherapy

The availability of highly purified recombinant enzymes and model heteropolymeric nucleic acid substrates now allows more precise evaluation of the ribonuclease H (RNase H) activity associated with human immunodeficiency virus (HIV) reverse transcriptase. In addition to degrading the RNA–DNA replicative intermediate, this C-terminal domain of around 130 residues supports highly specialized events that cannot be complemented by host-coded enzymes during retrovirus replication. RNase H activity should therefore be considered a plausible candidate for therapeutic intervention. Events during HIV replication requiring precise RNase H-mediated hydrolysis, the methodologies available to study these events, and their potential for therapeutic intervention are reviewed here.

Inhibition of the ribonuclease H activity of HIV-1 reverse transcriptase by GSK5750 correlates with slow enzyme-inhibitor dissociation

Compounds that efficiently inhibit the ribonuclease (RNase) H activity of the human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) have yet to be developed. Here, we demonstrate that GSK5750, a 1-hydroxy-pyridopyrimidinone analog, binds to the enzyme with an equilibrium dissociation constant (K(d)) of ~400 nM. Inhibition of HIV-1 RNase H is specific, as DNA synthesis is not affected. Moreover, GSK5750 does not inhibit the activity of Escherichia coli RNase H. Order-of-addition experiments show that GSK5750 binds to the free enzyme in an Mg(2+)-dependent fashion. However, as reported for other active site inhibitors, binding of GSK5750 to a preformed enzyme-substrate complex is severely compromised. The bound nucleic acid prevents access to the RNase H active site, which represents a possible biochemical hurdle in the development of potent RNase H inhibitors. Previous studies suggested that formation of a complex with the prototypic RNase H inhibitor β-thujaplicinol is slow, and, once formed, it dissociates rapidly. This unfavorable kinetic behavior can limit the potency of RNase H active site inhibitors. Although the association kinetics of GSK5750 remains slow, our data show that this compound forms a long lasting complex with HIV-1 RT. We conclude that slow dissociation of the inhibitor and HIV-1 RT improves RNase H active site inhibitors and may circumvent the obstacle posed by the inability of these compounds to bind to a preformed enzyme-substrate complex.

Reverse transcriptase in motion: conformational dynamics of enzyme-substrate interactions

Human immunodeficiency virus type 1 reverse transcriptase (HIV-1 RT) catalyzes synthesis of integration-competent, double-stranded DNA from the single-stranded viral RNA genome, combining both polymerizing and hydrolytic functions to synthesize approximately 20,000 phosphodiester bonds. Despite a wealth of biochemical studies, the manner whereby the enzyme adopts different orientations to coordinate its DNA polymerase and ribonuclease (RNase) H activities has remained elusive. Likewise, the lower processivity of HIV-1 RT raises the issue of polymerization site targeting, should the enzyme re-engage its nucleic acid substrate several hundred nucleotides from the primer terminus. Although X-ray crystallography has clearly contributed to our understanding of RT-containing nucleoprotein complexes, it provides a static picture, revealing few details regarding motion of the enzyme on the substrate. Recent development of site-specific footprinting and the application of single molecule spectroscopy have allowed us to follow individual steps in the reverse transcription process with significantly greater precision. Progress in these areas and the implications for investigational and established inhibitors that interfere with RT motion on nucleic acid is reviewed here.

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.

Characterization of RNase HII substrate recognition using RNase HII–argonaute chimaeric enzymes from Pyrococcus furiosus

RNase H (ribonuclease H) is an endonuclease that cleaves the RNA strand of RNA–DNA duplexes. It has been reported that the three-dimensional structure of RNase H is similar to that of the PIWI domain of the Pyrococcus furiosus Ago (argonaute) protein, although the two enzymes share almost no similarity in their amino acid sequences. Eukaryotic Ago proteins are key components of the RNA-induced silencing complex and are involved in microRNA or siRNA (small interfering RNA) recognition. In contrast, prokaryotic Ago proteins show greater affinity for RNA–DNA hybrids than for RNA–RNA hybrids. Interestingly, we found that wild-type Pf-RNase HII (P. furiosus, RNase HII) digests RNA–RNA duplexes in the presence of Mn2+ ions. To characterize the substrate specificity of Pf-RNase HII, we aligned the amino acid sequences of Pf-RNase HII and Pf-Ago, based on their protein secondary structures. We found that one of the conserved secondary structural regions (the fourth β-sheet and the fifth α-helix of Pf-RNase HII) contains family-specific amino acid residues. Using a series of Pf-RNase HII–Pf-Ago chimaeric mutants of the region, we discovered that residues Asp110, Arg113 and Phe114 are responsible for the dsRNA (double-stranded RNA) digestion activity of Pf-RNase HII. On the basis of the reported three-dimensional structure of Ph-RNase HII from Pyrococcus horikoshii, we built a three-dimensional structural model of RNase HII complexed with its substrate, which suggests that these amino acids are located in the region that discriminates DNA from RNA in the non-substrate strand of the duplexes.

Preferred sequences within a defined cleavage window specify DNA 3' end-directed cleavages by retroviral RNases H

The RNase H activity of reverse transcriptase carries out three types of cleavage termed internal, RNA 5' end-directed, and DNA 3' end-directed. Given the strong association between the polymerase domain of reverse transcriptase and a DNA 3' primer terminus, we asked whether the distance from the primer terminus is paramount for positioning DNA 3' end-directed cleavages or whether preferred sequences and/or a cleavage window are important as they are for RNA 5' end-directed cleavages. Using the reverse transcriptases of human immunodeficiency virus, type 1 (HIV-1) and Moloney murine leukemia virus (M-MuLV), we determined the effects of sequence, distance, and substrate end structure on DNA 3' end-directed cleavages. Utilizing sequence-matched substrates, our analyses showed that DNA 3' end-directed cleavages share the same sequence preferences as RNA 5' end-directed cleavages, but the sites must fall in a narrow window between the 15th and 20th nucleotides from the recessed end for HIV-1 reverse transcriptase and between the 17th and 20th nucleotides for M-MuLV. Substrates with an RNA 5' end recessed by 1 (HIV-1) or 2-3 (M-MuLV) bases on a longer DNA could accommodate both types of end-directed cleavage, but further recession of the RNA 5' end excluded DNA 3' end-directed cleavages. For HIV-1 RNase H, the inclusion of the cognate dNTP enhanced DNA 3' end-directed cleavages at the 17th and 18th nucleotides. These data demonstrate that all three modes of retroviral RNase H cleavage share sequence determinants that may be useful in designing assays to identify inhibitors of retroviral RNases H.

HIV-1 reverse transcriptase can simultaneously engage its DNA/RNA substrate at both DNA polymerase and RNase H active sites: implications for RNase H inhibition

Reverse transcriptase of the human immunodeficiency virus possesses DNA polymerase and ribonuclease (RNase) H activities. Although the nucleic acid binding cleft separating these domains can accommodate structurally diverse duplexes, it is currently unknown whether regular DNA/RNA hybrids can simultaneously contact both active sites. In this study, we demonstrate that ligands capable of trapping the 3'-end of the primer at the polymerase active site affect the specificity of RNase H cleavage without altering the efficiency of the reaction. Experiments under single-turnover conditions reveal that complexes with a bound nucleotide substrate show specific RNase H cleavage at template position -18, while complexes with the pyrophosphate analogue foscarnet show a specific cut at position -19. This pattern is indicative of post-translocated and pre-translocated conformations. The data are inconsistent with models postulating that the substrate toggles between both active sites, such that the primer 3'-terminus is disengaged from the polymerase active site when the template is in contact with the RNase H active site. In contrast, our findings provide strong evidence to suggest that the nucleic acid substrate can engage both active sites at the same time. As a consequence, the bound and intact DNA/RNA hybrid can restrict access of RNase H active site inhibitors. We have mapped the binding site of the recently discovered inhibitor beta-thujaplicinol between the RNase H active site and Y501 of the RNase H primer grip, and have shown that the inhibitor is unable to bind to a preformed reverse transcriptase-DNA/RNA complex. In conclusion, the bound nucleic acid substrate and in turn, active DNA synthesis can represent an obstacle to RNase H inhibition with compounds that bind to the RNase H active site.

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.

Structure and function of HIV-1 reverse transcriptase: molecular mechanisms of polymerization and inhibition

The rapid replication of HIV-1 and the errors made during viral replication cause the virus to evolve rapidly in patients, making the problems of vaccine development and drug therapy particularly challenging. In the absence of an effective vaccine, drugs are the only useful treatment. Anti-HIV drugs work; so far drug therapy has saved more than three million years of life. Unfortunately, HIV-1 develops resistance to all of the available drugs. Although a number of useful anti-HIV drugs have been approved for use in patients, the problems associated with drug toxicity and the development of resistance means that the search for new drugs is an ongoing process. The three viral enzymes, reverse transcriptase (RT), integrase (IN), and protease (PR) are all good drug targets. Two distinct types of RT inhibitors, both of which block the polymerase activity of RT, have been approved to treat HIV-1 infections, nucleoside analogs (NRTIs) and nonnucleosides (NNRTIs), and there are promising leads for compounds that either block the RNase H activity or block the polymerase in other ways. A better understanding of the structure and function(s) of RT and of the mechanism(s) of inhibition can be used to generate better drugs; in particular, drugs that are effective against the current drug-resistant strains of HIV-1.

Delayed chain termination protects the anti-hepatitis B virus drug entecavir from excision by HIV-1 reverse transcriptase

Entecavir (ETV) is a potent antiviral nucleoside analogue that is used to treat hepatitis B virus (HBV) infection. Recent clinical studies have demonstrated that ETV is also active against the human immunodeficiency virus type 1 (HIV-1). Unlike all approved nucleoside analogue reverse transcriptase RT) inhibitors (NRTIs), ETV contains a 3'-hydroxyl group that allows further nucleotide incorporation events to occur. Thus, the mechanism of inhibition probably differs from classic chain termination. Here, we show that the incorporated ETV-monophosphate (MP) can interfere with three distinct stages of DNA synthesis. First, incorporation of the next nucleotide at position n + 1 following ETV-MP is compromised, although DNA synthesis eventually continues. Second, strong pausing at position n + 3 suggests a long range effect, referred to as "delayed chain-termination." Third, the incorporated ETV-MP can also act as a "base pair confounder" during synthesis of the second DNA strand, when the RT enzyme needs to pass the inhibitor in the template. Enzyme kinetics revealed that delayed chain termination is the dominant mechanism of action. High resolution foot-printing experiments suggest that the incorporated ETV-MP "repels" the 3'-end of the primer from the active site of HIV-1 RT, which, in turn, diminishes incorporation of the natural nucleotide substrate at position n + 4. Most importantly, delayed chain termination protects ETV-MP from phosphorolytic excision, which represents a major resistance mechanism for approved NRTIs. Collectively, these findings provide a rationale and important tools for the development of novel, more potent delayed chain terminators as anti-HIV agents.

The reverse transcriptase of the Tf1 retrotransposon has a specific novel activity for generating the RNA self-primer that is functional in cDNA synthesis

The Tf1 retrotransposon of Schizosaccharomyces pombe represents a group of eukaryotic long terminal repeat (LTR) retroelements that, based on their sequences, were predicted to use an RNA self-primer for initiating reverse transcription while synthesizing the negative-sense DNA strand. This feature is substantially different from the one typical to retroviruses and other LTR retrotransposons that all exhibit a tRNA-dependent priming mechanism. Genetic studies have suggested that the self-primer of Tf1 can be generated by a cleavage between the 11th and 12th bases of the Tf1 RNA transcript. The in vitro data presented here show that recombinant Tf1 reverse transcriptase indeed introduces a nick at the end of a duplexed region at the 5' end of Tf1 genomic RNA, substantiating the prediction that this enzyme is responsible for generating this RNA self-primer. The 3' end of the primer, generated in this manner, can then be extended upon the addition of deoxynucleoside triphosphates by the DNA polymerase activity of the same enzyme, synthesizing the negative-sense DNA strand. This functional primer must have been generated by the RNase H activity of Tf1 reverse transcriptase, since a mutant enzyme lacking this activity has lost its ability to generate the self-primer. It was also found here that the reverse transcriptases of human immunodeficiency virus type 1 and of murine leukemia virus do not exhibit this specific cleavage activity. In all, it is likely that the observed unique mechanism of self-priming in Tf1 represents an early advantageous form of initiating reverse transcription in LTR retroelements without involving cellular tRNAs.

Connection domain mutations N348I and A360V in HIV-1 reverse transcriptase enhance resistance to 3'-azido-3'-deoxythymidine through both RNase H-dependent and -independent mechanisms

Thymidine analogue-associated mutations (TAMs) in reverse transcriptase (RT) of the human immunodeficiency virus type 1 (HIV-1) cause resistance to 3'-azido-3'-deoxythymidine (AZT) through excision of the incorporated monophosphate. Mutations in the connection domain of HIV-1 RT can augment AZT resistance. It has been suggested that these mutations compromise RNase H cleavage, providing more time for AZT excision to occur. However, the underlying mechanism remains elusive. Here, we focused on connection mutations N348I and A360V that are frequently observed in clinical samples of treatment-experienced patients. We show that both N348I and A360V, in combination with TAMs, decrease the efficiency of RNase H cleavage and increase excision of AZT in the presence of the pyrophosphate donor ATP. The TAMs/N348I/A360V mutant accumulates transiently formed, shorter hybrids that can rebind to RT before the template is irreversibly degraded. These hybrids dissociate selectively from the RNase H-competent complex, whereas binding in the polymerase-competent mode is either not affected with N348I or modestly improved with A360V. Both connection domain mutations can compensate for TAM-mediated deficits in processive DNA synthesis, and experiments with RNase H negative mutant enzymes confirm an RNase H-independent contribution to increased levels of resistance to AZT. Moreover, the combination of diminished RNase H cleavage and increased processivity renders the use of both PP(i) and ATP advantageous, whereas classic TAMs solely enhance the ATP-dependent reaction. Taken together, our findings demonstrate that distinct, complementary mechanisms can contribute to higher levels of excision of AZT, which in turn can amplify resistance to this drug.

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.

Mutations in the U5 region adjacent to the primer binding site affect tRNA cleavage by human immunodeficiency virus type 1 reverse transcriptase in vivo

In retroviruses, the first nucleotide added to the tRNA primer defines the end of the U5 region in the right long terminal repeat, and the subsequent removal of this tRNA primer by RNase H exactly defines the U5 end of the linear double-stranded DNA. In most retroviruses, the entire tRNA is removed by RNase H cleavage at the RNA/DNA junction. However, the RNase H domain of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase cleaves the tRNA 1 nucleotide from the RNA/DNA junction at the U5/primer binding site (PBS) junction, which leaves an rA residue at the U5 terminus. We made sequence changes at the end of the U5 region adjacent to the PBS in HIV-1 to determine whether such changes affect the specificity of tRNA primer cleavage by RNase H. In some of the mutants, RNase H usually removed the entire tRNA, showing that the cleavage specificity was shifted by 1 nucleotide. This result suggests that the tRNA cleavage specificity of the HIV-1 RNase domain H depends on sequences in U5.

APOBEC3G inhibits DNA strand transfer during HIV-1 reverse transcription

Human APOBEC3G (hA3G) has been identified as an anti-HIV-1 host factor. The presence of hA3G in HIV-1 strongly inhibits the ability of the virus to produce new viral DNA upon infection. In this report, we demonstrate that the reduction of late viral DNA synthesis is due to the inhibition by hA3G of the strand transfer steps that occur during reverse transcription. Analysis of viral cDNA intermediates in vivo reveals that hA3G causes an inhibition of the minus and plus strand transfers, without having a significant impact on DNA elongation. Using an in vitro system to measure minus strand transfer similarly shows a dose-dependent reduction of strand transfer by hA3G. This inhibition of strand transfer occurs independently the editing activity of hA3G and is correlated with its ability to prevent RNaseH degradation of the template RNA.

The major 5' end of HIV type 1 RNA corresponds to G456

In the course of studies on HIV-1 RNA structure, we determined that the main 5' end of viral RNA from virions and virus producer cells corresponds to G456 in the proviral DNA sequence, one or two nucleotides down-stream from the reported ends that correspond to G454 and G455. We mapped 5' ends using the highly accurate RNA ligase-mediated rapid amplification of cDNA ends (RLM-RACE) method. The reactivity of the 5' ends indicates that they are mainly capped, although the presence of some uncapped (5'-triphosphorylated) RNA cannot formally be excluded. When we used a 5' mapping method susceptible to incorporating a cytosine at the 3' end of cDNA first strands, at a position templated by the 7-methylguanosine cap, 50% of clones derived from virion RNA had incorporated the additional cytosine. Reassignment of the 5' end has consequences for the design of short RNAs used to study HIV-1 RNA structural dynamics.

Relationship between retroviral replication and RNA interference machineries

Small interfering RNAs (siRNAs) associated with gene silencing are cellular defense mechanisms against invading viruses. The viruses fight back by suppressors or escape mechanisms. The retroviruses developed a unique escape mechanism by disguising as DNA proviruses. An evolutionary relationship between the siRNA machinery and the replication machinery of retroviruses is likely. The RNA cleavage enzymes PIWI and RNase H proteins are structurally related. This relationship can be extended from structure to function, since the retroviral reverse transcriptase (RT)/RNase H can also cause silencing of viral RNA by siRNA. Thus, both enzymes can cleave RNA-DNA hybrids and double-stranded RNA (dsRNA) with various efficiencies shown previously and here, demonstrating that their specificities are not absolute. Other similarities may exist, for example between PAZ and the RT and between RNA-binding proteins and the viral nucleocapsid protein. Dicer has some similarities with the viral integrase, since both specifically generate dinucleotide 3'-overhanging ends. We described previously the destruction of the human immunodeficiency virus (HIV) RNA by a DNA oligonucleotide ODN (oligodeoxynucleotide). Variants of the ODN indicated high length and sequence specificities, which is reminiscent of siRNA and designated here as "siDNA." Cleavage of the viral RNA in the presence of the ODN is caused by the retroviral RT/RNase H and cellular RNase H activities. Several siRNA-mediated antiviral defense mechanisms resemble the interferon system.

Study of binding stoichiometries of the human immunodeficiency virus type 1 reverse transcriptase by capillary electrophoresis and laser-induced fluorescence polarization using aptamers as probes

Binding stoichiometries between four DNA aptamers (RT12, RT26, RTlt49, and ODN93) and the reverse transcriptase (RT) of the type 1 human immunodeficiency virus (HIV-1) were studied using affinity CE (ACE) coupled with LIF polarization and fluorescence polarization (FP). The ACE/LIF study showed evidence of two binding stoichiometries between the HIV-1 RT protein and aptamers RT12, RT26, and ODN93, suggesting that these aptamers can bind to both the p66 and p51 subunits of the HIV-1 RT. Only one binding stoichiometry for aptamer RTlt49 was found. The affinity complexes were easily separated from the unbound aptamers; however, the different stoichiometries were not well resolved. A complementary technique, FP, was able to provide additional information about the binding and supporting evidence for the ACE/LIF results. The ACE/LIFP study also revealed that the FP values of the 1:1 complexes of the HIV-1 RT protein with aptamers RT12, RT26, and ODN93 were always much greater than those of the 1:2 complexes. This was initially surprising because the larger molecular size of the 1:2 complexes was expected to result in higher FP values than the corresponding 1:1 complexes. This phenomenon was probably a result of fluorescence resonance energy transfer between the two fluorescent molecules bound to the HIV-1 RT protein.

Sequence, distance, and accessibility are determinants of 5'-end-directed cleavages by retroviral RNases H

The RNase H activity of reverse transcriptase is essential for retroviral replication. RNA 5'-end-directed cleavages represent a form of RNase H activity that is carried out on RNA/DNA hybrids that contain a recessed RNA 5'-end. Previously, the distance from the RNA 5'-end has been considered the primary determinant for the location of these cleavages. Employing model hybrid substrates and the HIV-1 and Moloney murine leukemia virus reverse transcriptases, we demonstrate that cleavage sites correlate with specific sequences and that the distance from the RNA 5'-end determines the extent of cleavage. An alignment of sequences flanking multiple RNA 5'-end-directed cleavage sites reveals that both enzymes strongly prefer A or U at the +1 position and C or G at the -2 position, and additionally for HIV-1, A is disfavored at the -4 position. For both enzymes, 5'-end-directed cleavages occurred when sites were positioned between the 13th and 20th nucleotides from the RNA 5'-end, a distance termed the cleavage window. In examining the importance of accessibility to the RNA 5'-end, it was found that the extent of 5'-end-directed cleavages observed in substrates containing a free recessed RNA 5'-end was most comparable to substrates with a gap of two or three bases between the upstream and downstream RNAs. Together these finding demonstrate that the selection of 5'-end-directed cleavage sites by retroviral RNases H results from a combination of nucleotide sequence, permissible distance, and accessibility to the RNA 5'-end.

Reverse transcriptase and integrase of the Saccharomyces cerevisiae Ty1 element

Integrase (IN) and reverse transcriptase (RT) play a central role in transposition of retroelements. The mechanism of integration by IN and the steps of the replication process mediated by RT are briefly described here. Recently, active recombinant forms of Ty1 IN and RT have been obtained. This has allowed a more detailed understanding of their biochemical and structural properties and has made possible combined in vitro and in vivo analyses of their functions. A focus of this review is to discuss some of the results obtained thus far with these two recombinant proteins and to propose future directions.

Crystal structures of RNase H bound to an RNA/DNA hybrid: substrate specificity and metal-dependent catalysis

RNase H belongs to a nucleotidyl-transferase superfamily, which includes transposase, retroviral integrase, Holliday junction resolvase, and RISC nuclease Argonaute. We report the crystal structures of RNase H complexed with an RNA/DNA hybrid and a mechanism for substrate recognition and two-metal-ion-dependent catalysis. RNase H specifically recognizes the A form RNA strand and the B form DNA strand. Structure comparisons lead us to predict the catalytic residues of Argonaute and conclude that two-metal-ion catalysis is a general feature of the superfamily. In nucleases, the two metal ions are asymmetrically coordinated and have distinct roles in activating the nucleophile and stabilizing the transition state. In transposases, they are symmetrically coordinated and exchange roles to alternately activate a water and a 3'-OH for successive strand cleavage and transfer by a ping-pong mechanism.

Drug targeting of HIV-1 RNA.DNA hybrid structures: thermodynamics of recognition and impact on reverse transcriptase-mediated ribonuclease H activity and viral replication

RNA degradation via the ribonuclease H (RNase H) activity of human immunodeficiency virus type I (HIV-1) reverse transcriptase (RT) is a critical component of the reverse transcription process. In this connection, mutations of RT that inactivate RNase H activity result in noninfectious virus particles. Thus, interfering with the RNase H activity of RT represents a potential vehicle for the inhibition of HIV-1 replication. Here, we demonstrate an approach for inhibiting the RNase H activity of HIV-1 RT by targeting its RNA.DNA hybrid substrates. Specifically, we show that the binding of the 4,5-disubstituted 2-deoxystreptamine aminoglycosides, neomycin, paromomycin, and ribostamycin, to two different chimeric RNA-DNA duplexes, which mimic two distinct intermediates in the reverse transcription process, inhibits specific RT-mediated RNase H cleavage, with this inhibition being competitive in nature. UV melting and isothermal titration calorimetry studies reveal a correlation between the relative binding affinities of the three drugs for each of the chimeric RNA-DNA host duplexes and the relative extents to which the drugs inhibit RT-mediated RNase H cleavage of the duplexes. Significantly, this correlation also extends to the relative efficacies with which the drugs inhibit HIV-1 replication. In the aggregate, our results highlight a potential strategy for AIDS chemotherapy that should not be compromised by the unusual genetic diversity of HIV-1.

Extension and cleavage of the polypurine tract plus-strand primer by Ty1 reverse transcriptase

Using hybrid RNA/DNA substrates containing the polypurine tract (PPT) plus-strand primer, we have examined the interaction between the Ty1 reverse transcriptase (RT) and the plus-strand initiation complex. We show here that, although the PPT sequence is relatively resistant to RNase H cleavage, it can be cleaved internally by the polymerase-independent RNase H activity of Ty1 RT. Alternatively, this PPT can be used to initiate plus-strand DNA synthesis. We demonstrate that cleavage at the PPT/DNA junction occurs only after at least 9 nucleotides are extended. Cleavage leaves a nick between the RNA primer and the nascent plus-strand DNA. We show that Ty1 RT has a strand displacement activity beyond a gap but that the PPT is not efficiently re-utilized in vitro for another round of DNA synthesis after a first plus-strand DNA has been synthesized and cleaved at the PPT/U3 junction.

Aminoglycoside complexation with a DNA.RNA hybrid duplex: the thermodynamics of recognition and inhibition of RNA processing enzymes

Spectroscopic and calorimetric techniques were employed to characterize and contrast the binding of the aminoglycoside paromomycin to three octamer nucleic acid duplexes of identical sequence but different strand composition (a DNA.RNA hybrid duplex and the corresponding DNA.DNA and RNA.RNA duplexes). In addition, the impact of paromomycin binding on both RNase H- and RNase A-mediated cleavage of the RNA strand in the DNA.RNA duplex was also determined. Our results reveal the following significant features: (i) Paromomycin binding enhances the thermal stabilities of the RNA.RNA and DNA.RNA duplexes to similar extents, with this thermal enhancement being substantially greater in magnitude than that of the DNA.DNA duplex. (ii) Paromomycin binding to the DNA.RNA hybrid duplex induces CD changes consistent with a shift from an A-like to a more canonical A-conformation. (iii) Paromomycin binding to all three octamer duplexes is linked to the uptake of a similar number of protons, with the magnitude of this number being dependent on pH. (iv) The affinity of paromomycin for the three host duplexes follows the hierarchy, RNA.RNA > DNA.RNA >> DNA.DNA. (v) The observed affinity of paromomycin for the RNA.RNA and DNA.RNA duplexes decreases with increasing pH. (vi) The binding of paromomycin to the DNA.RNA hybrid duplex inhibits both RNase H- and RNase A-mediated cleavage of the RNA strand. We discuss the implications of our combined results with regard to the specific targeting of DNA.RNA hybrid duplex domains and potential antiretroviral applications.

Suppression of an intrinsic strand transfer activity of HIV-1 Tat protein by its second-exon sequences

The Tat protein of human immunodeficiency virus type 1 (HIV-1) has been shown to restrict premature reverse transcription at late stages of virus infection and to thus ensure the integrity of the viral RNA genome for packaging. To gain further insights into the roles of Tat in HIV-1 reverse transcription, we have assessed its effects on the first-strand transfer during the synthesis of minus-strand DNA through use of a reconstituted cell-free system. The results demonstrated that a form of Tat, containing only the first exon (Tat72), was able to enhance the first-strand transfer as efficiently as did the viral nucleocapsid protein. Coincidentally, this form of Tat was unable to inhibit the production of minus-strand strong-stop DNA. Further studies with various mutated forms of Tat showed that its Cys-rich region, rather than the core and Arg-rich domains, was essential for this strand transfer activity. Moreover, this activity of Tat is largely independent of the TAR RNA structure. Although full-length Tat protein (Tat86) was also able to promote strand transfer, this activity was limited by a strong overall inhibition of reverse transcription because of the presence of the second Tat exon. Other nucleic-acid-binding proteins (e.g., single-strand DNA-binding protein) were employed as negative controls and were unable to promote strand transfer in these assays. We propose that Tat possesses nucleic acid chaperone activity and can promote the first-strand transfer during HIV-1 reverse transcription; however, these activities are restricted by the second Tat exon, and the roles of these Tat activities in viral replication remain to be elucidated.

Polypurine tract formation by Ty1 RNase H

To better understand the mechanism by which Ty1 RNase H creates the polypurine tract (PPT) primer, we have demonstrated the polymerase-dependent hydrolytic activity of Ty1 reverse transcriptase (RT) during minus-strand synthesis. Using RNase H and polymerase mutants of the recombinant Ty1 RT protein, we show that the two domains of Ty1 RT can act independently of one another. Our results indicate that RNA/DNA substrates containing a short RNA PPT, which serve as primers for plus-strand DNA synthesis, are relatively resistant to RNase H cleavage. RNA substrates with a correct 5' end but with 3' end extending beyond the plus-strand initiation site were cleaved specifically to generate the correct 3' end of the PPT. Using long RNA/DNA duplexes containing the PPT, we show that Ty1 RT is able to make specific internal cleavages that could generate the plus-strand primer with correct 5' and 3' ends. Long RNA/DNA duplexes with mutations in the PPT or in a U-rich region upstream of the PPT, which abolish plus-strand initiation in vivo, were not cleaved specifically at the 5' end of the PPT. Our work demonstrates that the in vitro enzyme can recapitulate key processes that control proper replication in vivo.

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.

Analysis of plus-strand primer selection, removal, and reutilization by retroviral reverse transcriptases

The ability of reverse transcriptase to generate, extend, and remove the primer derived from the polypurine tract (PPT) is vital for reverse transcription, since this process determines one of the ends required for integration of the viral DNA. Based on the ability of the RNase H activity of Moloney murine leukemia virus reverse transcriptase to cleave a long RNA/DNA hybrid containing the PPT, it appears that cleavages that could generate the plus-strand primer can occur by an internal cleavage mechanism without any positioning by an RNA 5'-end, and such cleavages may serve to minimize cleavage events within the PPT itself. If the PPT were to be cleaved inappropriately just upstream of the normal plus-strand origin site, the resulting 3'-ends would not be extended by reverse transcriptase. Extension of the PPT primer by at least 2 nucleotides is sufficient for recognition and correct cleavage by RNase H at the RNA-DNA junction to remove the primer. Specific removal of the PPT primer after polymerase extension deviates from the general observation that primer removal occurs by cleavage one nucleotide away from the RNA-DNA junction and suggests that the same PPT specificity determinants responsible for generation of the PPT primer also direct PPT primer removal. Once the PPT primer has been extended and removed from the nascent plus-strand DNA, reinitiation at the resulting plus-strand primer terminus does not occur, providing a mechanism to prevent the repeated initiation of plus strands.

In vitro hyperprocessing of Drosophila tRNAs by the catalytic RNA of RNase P the cloverleaf structure of tRNA is not always stable?

We have previously reported that the catalytic RNA subunit of RNase P of Escherichia coli (M1 RNA) cleaves Drosophila initiator methionine tRNA (tRNA(Met)i) within the mature tRNA sequence to produce specific fragments. This cleavage was dependent on the occurrence of an altered conformation of the tRNA substrate. We call this further cleavage hyperprocessing. In the present paper, to search for another tRNA that can be hyperprocessed in vitro, we used total mature tRNAs from Drosophila as substrates for the in vitro M1 RNA reaction. We found that some tRNAs can be hyperprocessed by M1 RNA and that two such tRNAs are an alanine tRNA and a histidine tRNA. Using mutant substrates of these tRNAs, we also show that the hyperprocessing by M1 RNA is dependent on the occurrence of altered conformations of these tRNAs. The altered conformations were very similar to that of tRNA(Met)i. We show here that M1 RNA can be used as a powerful tool to detect the alternative conformation of tRNAs. The relationship between these hyperprocessing reactions and stability of the tRNA structure will also be discussed.

The role of steric hindrance in 3TC resistance of human immunodeficiency virus type-1 reverse transcriptase

Treating HIV infections with drugs that block viral replication selects for drug-resistant strains of the virus. Particular inhibitors select characteristic resistance mutations. In the case of the nucleoside analogs 3TC and FTC, resistant viruses are selected with mutations at amino acid residue 184 of reverse transcriptase (RT). The initial change is usually to M184I; this virus is rapidly replaced by a variant carrying the mutation M184V. 3TC and FTC are taken up by cells and converted into 3TCTP and FTCTP. The triphosphate forms of these nucleoside analogs are incorporated into DNA by HIV-1 RT and act as chain terminators. Both of the mutations, M184I and M184V, provide very high levels of resistance in vivo; purified HIV-1 RT carrying M184V and M184I also shows resistance to 3TCTP and FTCTP in in vitro polymerase assays. Amino acid M184 is part of the dNTP binding site of HIV-1 RT. Structural studies suggest that the mechanism of resistance of HIV-1 RTs carrying the M184V or M184I mutation involves steric hindrance, which could either completely block the binding of 3TCTP and FTCTP or allow binding of these nucleoside triphosphate molecules but only in a configuration that would prevent incorporation. The available kinetic data are ambiguous: one group has reported that the primary effect of the mutations is at the level of 3TCTP binding; another, at the level of incorporation. We have approached this problem using assays that monitor the ability of HIV-1 RT to undergo a conformational change upon binding a dNTP. These studies show that both wild-type RT and the drug-resistant variants can bind 3TCTP at the polymerase active site; however, the binding to M184V and M184I is somewhat weaker and is sensitive to salt. We propose that the drug-resistant variants bind 3TCTP in a strained configuration that is salt-sensitive and is not catalytically competent.

Expression of an active form of recombinant Ty1 reverse transcriptase in Escherichia coli: a fusion protein containing the C-terminal region of the Ty1 integrase linked to the reverse transcriptase-RNase H domain exhibits polymerase and RNase H activities

Replication of the Saccharomyces cerevisiae Ty1 retrotransposon requires a reverse transcriptase capable of synthesizing Ty1 DNA. The first description of an active form of a recombinant Ty1 enzyme with polymerase and RNase H activities is reported here. The Ty1 enzyme was expressed as a hexahistidine-tagged fusion protein in Escherichia coli to facilitate purification of the recombinant protein by metal-chelate chromatography. Catalytic activity of the recombinant protein was detected only when amino acid residues encoded by the integrase gene were added to the N-terminus of the reverse transcriptase-RNase H domain. This suggests that the integrase domain could play a role in proper folding of reverse transcriptase. Several biochemical properties of the Ty1 enzyme were analysed, including the effect of MgCl(2), NaCl, temperature and of the chain terminator dideoxy GTP on its polymerase activity. RNase H activity was examined by monitoring the cleavage of a RNA-DNA template-primer. Our results suggest that the distance between the RNase H and polymerase active sites corresponds to the length of a 14-nucleotide RNA-DNA heteroduplex. The recombinant protein produced in E. coli should be useful for further biochemical and structural analyses and for a better understanding of the role of integrase in the activation of reverse transcriptase.

Dynamics of the HIV-1 reverse transcription complex during initiation of DNA synthesis

Initiation of human immunodeficiency virus-1 (HIV-1) reverse transcription requires formation of a complex containing the viral RNA (vRNA), tRNA(3)(Lys) and reverse transcriptase (RT). The vRNA and the primer tRNA(3)(Lys) form several intermolecular interactions in addition to annealing of the primer 3' end to the primer binding site (PBS). These interactions are crucial for the efficiency and the specificity of the initiation of reverse transcription. However, as they are located upstream of the PBS, they must unwind as DNA synthesis proceeds. Here, the dynamics of the complex during initiation of reverse transcription was followed by enzymatic probing. Our data revealed reciprocal effects of the tertiary structure of the vRNA.tRNA(3)(Lys) complex and reverse transcriptase (RT) at a distance from the polymerization site. The structure of the initiation complex allowed RT to interact with the template strand up to 20 nucleotides upstream from the polymerization site. Conversely, nucleotide addition by RT modified the tertiary structure of the complex at 10-14 nucleotides from the catalytic site. The viral sequences became exposed at the surface of the complex as they dissociated from the tRNA following primer extension. However, the counterpart tRNA sequences became buried inside the complex. Surprisingly, they became exposed when mutations prevented the intermolecular interactions in the initial complex, indicating that the fate of the tRNA depended on the tertiary structure of the initial complex.

The HIV-1 reverse transcription (RT) process as target for RT inhibitors

Since the Human Immunodeficiency Virus Type 1 (HIV-1) was identified as the etiologic agent of the Acquired Immune Deficiency Syndrome (AIDS), the HIV-1 reverse transcriptase (RT) has been the subject of intensive study. The reverse transcription entails the transition of the single-stranded viral RNA into double-stranded proviral DNA, which is then integrated into the host chromosome. Therefore, the HIV-1 reverse transcriptase plays a pivotal role in the life cycle of the virus and is consequently an interesting target for anti-HIV drug therapy. In the first section, we describe the complex process of reverse transcription and the different activities involved in this process. We then highlight the structure-function relationship of the HIV-1 reverse transcriptase, which is of great importance for a better understanding of resistance development, a major problem in anti-AIDS therapies. Finally, we summarize the mechanisms of HIV resistance toward various RT inhibitors and the implications thereof for the current anti-HIV drug therapies.

Biochemical mechanisms involved in overcoming HIV resistance to nucleoside inhibitors of reverse transcriptase

The development of drug combinations that act effectively against both wild-type and mutated resistant forms of HIV-1 reverse transcriptase (RT) is a major goal in management of HIV disease. Recent studies have shown that resistance to different nucleoside analog RT inhibitors (NRTIs), an important class of anti-viral drugs, can result in different amino acid substitutions in close proximity to the dNTP binding pocket of the enzyme. Some of these mutations have been shown to cause cross- or multiple resistance among various members of this family of inhibitors. In contrast, certain combinations of amino acid substitutions can sometimes lead to increased drug susceptibility and may also result in resensitization of formerly resistant viruses. A biochemical understanding of these complex viral phenotypes may be of major importance in regard to development of novel chemotherapeutic strategies that can act at the level of drug-resistant mutated enzymes. In this review, we discuss several principles that help to explain the increased susceptibility and resensitization to some antiviral agents used in the context of combination treatment. The conclusions are largely based on our current understanding of mechanisms involved in drug-resistance to 3TC and AZT. Copyright 2000 Harcourt Publishers Ltd.

Structural Studies of Model RNA Helices with Relevance to Aminoacyl-tRNA Synthetase Specificity and HIV Reverse Transcription

Abstract We describe high-resolution crystal structures of synthetic nucleic-acid fragments determined as part of an effort to understand determinants of sequence-specific protein binding on the level of double-helix structure. In a first set of experiments, 7-base-pair RNA duplexes representing the acceptor-stem helix of Escherichia coli tRNA(Ala) and variants thereof were characterized at atomic resolution. The structures revealed a standard A-form double helix locally perturbed by a G·U wobble base pair at sequence position 3/70 of the tRNA. The G·U pair shows a characteristic hydration pattern which must be considered an integral part of the double-helix structure. It does not seem to exert a global effect on the duplex structure. A second experiment concerned the chimeric DNA-RNA hybrid structure formed transiently during initiation of minus-strand synthesis by the reverse transcriptase of HIV-1. The crystal structure of an 8-base-pair duplex with an RNA template strand derived from HIV-1 and a complementary strand representing the junction between the tRNA(Lys,3) RNA primer and the newly synthesized DNA strand was solved at a resolution of 1.9 Å. As before, the double helix was found to adopt standard A-type conformation with only local variations of backbone conformation. Based on the global helix structure as present in the crystal, it remains difficult to explain the preference of the reverse-transcriptase-associated RNAse H activity for certain sites of the template strand. Structural plasticity near the main cleavage site in suggested to govern cutting preferences. In both systems investigated, structural studies by NMR spectroscopy were carried out by others in parallel. In both cases, the solution structures are in partial disagreement with the crystallographic results by describing a significantly higher level of deviation from the canonical A-conformation.

Similarities and differences in the RNase H activities of human immunodeficiency virus type 1 reverse transcriptase and Moloney murine leukemia virus reverse transcriptase

Retroviral revXerse transcriptases (RTs) have an associated RNase H activity that can cleave RNA-DNA duplexes with considerable precision. We believe that the structure of the RNA-DNA duplexes in the context of RT determines the specificity of RNase H cleavage. To test this idea, we treated three related groups of synthetic RNA-DNA hybrids with either Moloney murine leukemia virus (MLV) RT or human immunodeficiency virus type 1 (HIV-1) RT. All of the hybrids were prepared using the same 81-base RNA template. The first series of RNase H substrates was prepared with complementary DNA oligonucleotides of different lengths, ranging from 6 to 20 nucleotides, all of which shared a common 5' end and were successively shorter at their 3' ends. The second series of oligonucleotides had a common 3' end but shorter 5' ends. The DNA oligonucleotides in the third series were all 20 bases long but had non-complementary stretches at either the 5' end, 3' end, or both ends. Several themes have emerged from the experiments with these RNA-DNA duplexes. (1) Both HIV-1 RT and MLV RT cleave fairly efficiently if the duplex region is at least eight bases long, but not if it is shorter. (2) Although, under the conditions we have used, both enzymes require the substrate to have a region of RNA-DNA duplex, both MLV RT and HIV-1 RT can cleave RNA outside the region that is part of the RNA-DNA duplex. (3) The polymerase domain of HIV-1 RT uses certain mismatched segments of RNA-DNA to position the enzyme for RNase H cleavage, whereas the polymerase domain of MLV RT does not use the same mismatched segments to define the position for RNase H cleavage. (4) For HIV-1 RT, a mismatched region near the RNase H domain can interfere with RNase H cleavage; cleavage is usually (but not always) more efficient if the mismatched segment is deleted. These results are discussed in regard to the structure of HIV-1 RT and the differences between HIV-1 RT and MLV RT.

The kissing-loop motif is a preferred site of 5' leader recombination during replication of SL3-3 murine leukemia viruses in mice

A panel of mouse T-cell lymphomas induced by SL3-3 murine leukemia virus (MLV) and three primer binding site mutants thereof (A. H. Lund, J. Schmidt, A. Luz, A. B. Sorensen, M. Duch, and F. S. Pedersen, J. Virol. 73:6117-6122, 1999) were analyzed for the occurrence of recombination between the exogenous input virus and endogenous MLV-like sequences within the 5' leader region. Evidence of recombination within the region studied was found in 14 of 52 tumors analyzed. Sequence analysis of a approximately 330-bp fragment of 44 chimeric proviruses, encompassing the U5, the primer binding site, and the upstream part of the 5' untranslated region, enabled us to map recombination sites, guided by distinct scattered nucleotide differences. In 30 of 44 analyzed sequences, recombination was mapped to a 33-nucleotide similarity window coinciding with the kissing-loop stem-loop motif implicated in dimerization of the diploid genome. Interestingly, the recombination pattern preference found in replication-competent viruses from T-cell tumors is very similar to the pattern previously reported for retroviral vectors in cell culture experiments. The data therefore sustain the hypothesis that the kissing loop, presumably via a role in RNA dimer formation, constitutes a hot spot for reverse transcriptase-mediated recombination in MLV.

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

During retrovirus replication, reverse transcriptase (RT) must specifically interact with the polypurine tract (PPT) to generate and subsequently remove the RNA primer for plus-strand DNA synthesis. We have investigated the role that human immunodeficiency virus-1 RT residues in the alphaH and alphaI helices in the thumb subdomain play in specific RNase H cleavage at the 3'-end of the PPT; an in vitro assay modeling the primer removal step was used. Analysis of alanine-scanning mutants revealed that a subgroup exhibits an unusual phenotype in which the PPT is cleaved up to seven bases from its 3'-end. Further analysis of alphaH mutants (G262A, K263A, N265A, and W266A) with changes in residues in or near a structural motif known as the minor groove binding track showed that the RNase H activity of these mutants is more dramatically affected with PPT substrates than with non-PPT substrates. Vertical scan mutants at position 266 were all defective in specific RNase H cleavage, consistent with conservation of tryptophan at this position among lentiviral RTs. Our results indicate that residues in the thumb subdomain and the minor groove binding track in particular, are crucial for unique interactions between RT and the PPT required for correct positioning and precise RNase H cleavage.

HIV-1 reverse transcription: a brief overview focused on structure-function relationships among molecules involved in initiation of the reaction

An early step in the life cycle of the human immunodeficiency virus type 1 (HIV-1) is reverse transcription of viral RNA into proviral DNA, which can then be integrated into the host cell genome. Reverse transcription is a discontinuous process carried out by the viral encoded reverse transcriptase that displays DNA polymerase activities on RNA and DNA templates as well as an RNase H activity that degrades transcribed RNA. DNA synthesis is initiated by cellular tRNALys3 that binds at its 3'-terminus to the complementary primer binding site of the genomic RNA. The initiation of reverse transcription is itself a complex reaction that requires tRNA placement onto viral RNA and the formation of a specific primer/template complex that is recognized by reverse transcriptase. After initiation takes place, the enzyme translocates from the initially bound RNA/RNA duplex into chimeric replication intermediates and finally accommodates newly synthesized DNA/RNA hybrids. This review focuses on structure-function relationships among these various molecules that are involved in the initiation of HIV-1 reverse transcription.

Temporal coordination between initiation of HIV (+)-strand DNA synthesis and primer removal

In this study, we have analyzed the interdependence between the polymerase and RNase H active sites of human immunodeficiency virus-1 reverse transcriptase (RT) using an in vitro system that closely mimics the initiation of (+)-strand DNA synthesis. Time course experiments show that RT pauses after addition of the 12th DNA residue, and at this stage the RNase H activity starts to cleave the RNA primer from newly synthesized DNA. Comparison of cleavage profiles obtained with 3'- and 5'-end-labeled primer strands indicates that RT now translocates in the opposite direction, i.e. in the 5' direction of the RNA strand. DNA synthesis resumes again in the 3' direction, after the RNA-DNA junction was efficiently cleaved. Moreover, we further characterized complexes generated before, during, and after position +12, by treating these with Fe2+ to localize the RNase H active site on the DNA template. Initially, when RT binds the RNA/DNA substrate, oxidative strand breaks were seen at a distance of 18 base pairs upstream from the primer terminus, whereas 17 base pairs were observed at later stages when the enzyme binds more and more DNA/DNA. These data show that the initiation of (+)-strand synthesis is accompanied by a conformational change of the polymerase-competent complex.

NMR structure of the chimeric hybrid duplex r(gcaguggc).r(gcca)d(CTGC) comprising the tRNA-DNA junction formed during initiation of HIV-1 reverse transcription

A high-quality NMR solution structure of the chimeric hybrid duplex r(gcaguggc).r(gcca)d(CTGC) was determined using the program DYANA with its recently implemented new module FOUND, which performs exhaustive conformational grid searches for dinucleotides. To ensure conservative data interpretation, the use of 1H-1H lower distance limit constraints was avoided. The duplex comprises the tRNA-DNA junction formed during the initiation of HIV-1 reverse transcription. It forms an A-type double helix that exhibits distinct structural deviations from a standard A-conformation. In particular, the minor groove is remarkably narrow, and its width decreases from about 7.5 A in the RNA/RNA stem to about 4.5 A in the RNA/DNA segment. This is unexpected, since minor groove widths for A-RNA and RNA/DNA hybrid duplexes of approximately 11 A and approximately 8.5 A, respectively, were previously reported. The present, new structure supports that reverse transcriptase-associated RNaseH specificity is related primarily to conformational adaptability of the nucleic acid in 'induced-fit'-type interactions, rather than the minor groove width of a predominantly static nucleic acid duplex.

Crystal structure of an eight-base pair duplex containing the 3'-DNA-RNA-5' junction formed during initiation of minus-strand synthesis of HIV replication

During initiation of minus-strand synthesis by HIV-1 reverse transcriptase, a 3'-DNA-RNA-5' junction is formed involving the 3'-end of tRNAlys,3. The HIV-RT-associated RNase H cleaves the RNA template strand specifically, opposite the newly synthesized DNA strand. We have determined the crystal structure at 1.9 A resolution of an eight-base pair hybrid duplex representing the junction to identify global or local structural perturbations which may be recognized by HIV-RT RNase H. The junction octamer is in a global A-type conformation throughout. A base pair step with distinct stacking geometry and variable backbone conformation is located next to the main endonucleolytic cleavage site. This base pair step may serve as a recognition site for HIV-RT RNase H.

Mechanistic studies of early pausing events during initiation of HIV-1 reverse transcription

We have investigated the role of sequences that surround the primer binding site (PBS) in the reverse transcriptase-mediated initiation of (-) strand DNA synthesis in human immunodeficiency virus type 1. In comparisons of reverse transcription initiated from either the cognate primer tRNALys.3 or a DNA primer D-Lys.3, bound to PBS sequences, we observed that a +3 pausing site occurred in both circumstances. However, the initiation reaction with tRNALys.3 was also characterized by a pausing event after incorporation of the first nucleotide. Alteration of sequences at the 5'-end instead of the 3'-end of the PBS resulted in elimination of the +3 pausing site, suggesting that this site was template sequence-dependent. In contrast, the pausing event at the +1 nucleotide position was still present in experiments that employed either of these mutated RNA templates. The mutations at the 5'-end of the PBS also caused a severely diminished rate of initiation and the strong arrest of reactions at the +1 stage when tRNALys.3 was used as primer. Therefore, we propose that the +1 pausing event is an initiation-specific event in regard to reactions primed by tRNALys.3 and that sequences at the 5'-end of the PBS may facilitate the release of reverse transcription from initiation to elongation.