Nucleotide substitutions within U5 are critical for efficient reverse transcription of human immunodeficiency virus type 1 with a primer binding site complementary to tRNA(His)

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.

HIV-1 Subtypes and 5'LTR-Leader Sequence Variants Correlate with Seroconversion Status in Pumwani Sex Worker Cohort

Within the Pumwani sex worker cohort, a subgroup remains seronegative, despite frequent exposure to HIV-1; some of them seroconverted several years later. This study attempts to identify viral variations in 5′LTR-leader sequences (5′LTR-LS) that might contribute to the late seroconversion. The 5′LTR-LS contains sites essential for replication and genome packaging, viz, primer binding site (PBS), major splice donor (SD), and major packaging signal (PS). The 5′LTR-LS of 20 late seroconverters (LSC) and 122 early seroconverters (EC) were amplified, cloned, and sequenced. HelixTree 6.4.3 was employed to classify HIV subtypes and sequence variants based on seroconversion status. We find that HIV-1 subtypes A1.UG and D.UG were overrepresented in the viruses infecting the LSC (P < 0.0001). Specific variants of PBS (Pc < 0.0001), SD1 (Pc < 0.0001), and PS (Pc < 0.0001) were present only in the viral population from EC or LSC. Combinations of PBS [PBS-2 (Pc < 0.0001) and PBS-3 (Pc < 0.0001)] variants with specific SD sequences were only seen in LSC or EC. Combinations of A1.KE or D with specific PBS and SD variants were only present in LSC or EC (Pc < 0.0001). Furthermore, PBS variants only present in LSC co-clustered with PBS references utilizing tRNA^Arg; whereas, the PBS variants identified only in EC co-clustered with PBS references using tRNA^Lys,3 and its variants. This is the first report that specific PBS, SD1, and PS sequence variants within 5′LTR-LS are associated with HIV-1 seroconversion, and it could aid designing effective anti-HIV strategies.

On the primer binding site mutation that appears and disappears during HIV and SIV replication

A recent study by Fennessey et al. (Retrovirology 12:49, 2015) described the optimization of a popular SIV clone by removal of four suboptimal point mutations. One of these mutations is present in a non-coding part of the viral genome and is probed in that study in more detail because of some fascinating properties. This primer binding site (PBS) mutation reverts rapidly to the wild-type sequence, which the authors interpret as indicating that this mutation exerts a profound fitness impact. The authors proposed the involvement of a cellular DNA repair mechanism in the reversion. Furthermore, it was suggested that premature termination of reverse transcription can explain why some of the viral progeny still contained the mutant sequence. However, we argue that all these special properties are a direct consequence of the unique nature of the viral PBS motif. The PBS binds the tRNA primer for reverse transcription and the viral progeny inherits either the sequence of the cellular tRNA or the PBS sequence of the viral RNA genome. The presence of a variant tRNA species explains the rapid appearance and disappearance of a variant PBS sequence.

Vpr-host interactions during HIV-1 viral life cycle

Human immunodeficiency virus type 1 (HIV-1) viral protein R (Vpr) is a multifunctional viral protein that plays important role at multiple stages of the HIV-1 viral life cycle. Although the molecular mechanisms underlying these activities are subject of ongoing investigations, overall, these activities have been linked to promotion of viral replication and impairment of anti-HIV immunity. Importantly, functional defects of Vpr have been correlated with slow disease progression of HIV-infected patients. Vpr is required for efficient viral replication in non-dividing cells such as macrophages, and it promotes, to some extent, viral replication in proliferating CD4+ T cells. The specific activities of Vpr include modulation of fidelity of viral reverse transcription, nuclear import of the HIV-1 pre-integration complex, transactivation of the HIV-1 LTR promoter, induction of cell cycle G2 arrest and cell death via apoptosis. In this review, we focus on description of the cellular proteins that specifically interact with Vpr and discuss their significance with regard to the known Vpr activities at each step of the viral life cycle in proliferating and non-proliferating cells.

A succession of mechanisms stimulate efficient reconstituted HIV-1 minus strand strong stop DNA transfer

Donor-acceptor template systems in vitro were designed to test mechanisms of minus strand transfer of human immunodeficiency virus 1 (HIV-1). Donor RNA D199, extending from the 5' end of the HIV-1 genome to the primer binding site (PBS), promoted transfer to only 35% with an acceptor RNA representing the 3' terminal 97 nucleotides, whereas donor RNA D520, including an additional 321 nucleotides 3' of PBS, exhibited 75% transfer. Both donors transferred through an invasion-driven pathway, but transfer was stimulated by the folding structure resulting from the extra segment in D520. In this study, the significance of interaction between the tRNA(lys3) primer and U3 was examined. Measurements utilizing acceptors having or lacking the U3 region complementary with tRNA(lys3) indicated that a tRNA(lys3)-U3 interaction compensated for inefficient acceptor invasion observed with D199. Stimulation presumably occurred because binding to tRNA(lys3) increased the proximity of the acceptor to elongated cDNA, improving transfer to 78% efficiency with D199, and even higher to 85% with D520. The stimulation did not require natural viral sequences but could be achieved by substituting the original U3 sequence with an equal length sequence that binds a different region of tRNA(lys3). Comparison between acceptors sharing the natural region for tRNA(lys3)-U3 interaction but having or lacking the acceptor invasion site demonstrated that tRNA(lys3)-U3 interaction and acceptor invasion cooperate for maximal stimulation. Overall, observations suggest that both proximity and invasion mechanisms are applied successively by HIV-1 for efficient minus strand transfer.

Initiation of HIV Reverse Transcription

Reverse transcription of retroviral genomes into double stranded DNA is a key event for viral replication. The very first stage of HIV reverse transcription, the initiation step, involves viral and cellular partners that are selectively packaged into the viral particle, leading to an RNA/protein complex with very specific structural and functional features, some of which being, in the case of HIV-1, linked to particular isolates. Recent understanding of the tight spatio-temporal regulation of reverse transcription and its importance for viral infectivity further points toward reverse transcription and potentially its initiation step as an important drug target.

Human immunodeficiency virus type 1 Vpr: functions and molecular interactions

Human immunodeficiency virus type 1 (HIV-1) viral protein R (Vpr) is an accessory protein that interacts with a number of cellular and viral proteins. The functions of many of these interactions in the pathogenesis of HIV-1 have been identified. Deletion of the vpr gene reduces the virulence of HIV-1 dramatically, indicating the importance of this protein for the virus. This review describes the current findings on several established functions of HIV-1 Vpr and some possible roles proposed for this protein. Because Vpr exploits cellular proteins and pathways to influence the biology of HIV-1, understanding the functions of Vpr usually involves the study of cellular pathways. Several functions of Vpr are attributed to the virion-incorporated protein, but some of them are attributed to the expression of Vpr in HIV-1-infected cells. The structure of Vpr may be key to understanding the variety of its interactions. Due to the critical role of Vpr in HIV-1 pathogenicity, study of the interactions between Vpr and cellular proteins may help us to understand the mechanism(s) of HIV-1 pathogenicity.

The structure of the human tRNALys3 anticodon bound to the HIV genome is stabilized by modified nucleosides and adjacent mismatch base pairs

Replication of human immunodeficiency virus (HIV) requires base pairing of the reverse transcriptase primer, human tRNA^Lys3, to the viral RNA. Although the major complementary base pairing occurs between the HIV primer binding sequence (PBS) and the tRNA's 3′-terminus, an important discriminatory, secondary contact occurs between the viral A-rich Loop I, 5′-adjacent to the PBS, and the modified, U-rich anticodon domain of tRNA^Lys3. The importance of individual and combined anticodon modifications to the tRNA/HIV-1 Loop I RNA's interaction was determined. The thermal stabilities of variously modified tRNA anticodon region sequences bound to the Loop I of viral sub(sero)types G and B were analyzed and the structure of one duplex containing two modified nucleosides was determined using NMR spectroscopy and restrained molecular dynamics. The modifications 2-thiouridine, s²U₃₄, and pseudouridine, Ψ₃₉, appreciably stabilized the interaction of the anticodon region with the viral subtype G and B RNAs. The structure of the duplex results in two coaxially stacked A-form RNA stems separated by two mismatched base pairs, U₁₆₂•Ψ₃₉ and G₁₆₃•A₃₈, that maintained a reasonable A-form helix diameter. The tRNA's s²U₃₄ stabilized the interaction between the A-rich HIV Loop I sequence and the U-rich anticodon, whereas the tRNA's Ψ₃₉ stabilized the adjacent mismatched pairs.

The availability of the primer activation signal (PAS) affects the efficiency of HIV-1 reverse transcription initiation

Initiation of reverse transcription of a retroviral RNA genome is strictly regulated. The tRNA primer binds to the primer binding site (PBS), and subsequent priming is triggered by the primer activation signal (PAS) that also pairs with the tRNA. We observed that in vitro reverse transcription initiation of the HIV-1 leader RNA varies in efficiency among 3′-end truncated transcripts, despite the presence of both PBS and PAS motifs. As the HIV-1 leader RNA can adopt two different foldings, we investigated if the conformational state of the transcripts did influence the efficiency of reverse transcription initiation. However, mutant transcripts that exclusively fold one or the other structure were similarly active, thereby excluding the possibility of regulation of reverse transcription initiation by the structure riboswitch. We next set out to determine the availability of the PAS element. This sequence motif enhances the efficiency of reverse transcription initiation, but its activity is regulated because the PAS motif is initially base paired within the wild-type template. We measured that the initiation efficiency on different templates correlates directly with accessibility of the PAS motif. Furthermore, changes in PAS are critical to facilitate a primer-switch to a new tRNA species, demonstrating the importance of this enhancer element.

Forced selection of a human immunodeficiency virus type 1 variant that uses a non-self tRNA primer for reverse transcription: involvement of viral RNA sequences and the reverse transcriptase enzyme

Human immunodeficiency virus type 1 uses the tRNA(3)(Lys) molecule as a selective primer for reverse transcription. This primer specificity is imposed by sequence complementarity between the tRNA primer and two motifs in the viral RNA genome: the primer-binding site (PBS) and the primer activation signal (PAS). In addition, there may be specific interactions between the tRNA primer and viral proteins, such as the reverse transcriptase (RT) enzyme. We constructed viruses with mutations in the PAS and PBS that were designed to employ the nonself primer tRNA(Pro) or tRNA(1,2)(Lys). These mutants exhibited a severe replication defect, indicating that additional adaptation of the mutant virus is required to accommodate the new tRNA primer. Multiple independent virus evolution experiments were performed to select for fast-replicating variants. Reversion to the wild-type PBS-lys3 sequence was the most frequent escape route. However, we identified one culture in which the virus gained replication capacity without reversion of the PBS. This revertant virus eventually optimized the PAS motif for interaction with the nonself primer. Interestingly, earlier evolution samples revealed a single amino acid change of an otherwise well-conserved residue in the RNase H domain of the RT enzyme, implicating this domain in selective primer usage. We demonstrate that both the PAS and RT mutations improve the replication capacity of the tRNA(1,2)(Lys)-using virus.

Synthetic tRNALys,3 as the replication primer for the HIV-1HXB2 and HIV-1Mal genomes

In order to determine the contribution of modified bases on the efficiency with which tRNA(Lys,3) is used in vitro as the HIV-1 replication primer, the properties of synthetic derivatives prepared by three independent methods were compared to the natural, i.e. fully modified, tRNA. When prepared directly by in vitro run-off transcription, we show here that the predominant tRNA species is 77 nt, representing a non-templated addition of a single nucleotide. As a consequence, this aberrant tRNA inefficiently primes (-) strand strong stop DNA synthesis from the primer binding site (PBS) on the HIV-1 viral RNA genome to which it must hybridize. In contrast, correctly sized tRNA(Lys,3) can be prepared by (i) total chemical synthesis and ligation of 'half' tRNAs, (ii) transcription of a cassette whose DNA template contained strategically placed 2'-O-Methyl-containing ribonucleotides and (iii) processing from a larger precursor by means of targeted cleavage with Escherichia coli RNase H. When each of these 76 nt tRNAs was supplemented into a (-) strand strong stop DNA synthesis reaction utilizing the HXB2 strain of HIV-1, the amount of product obtained was comparable to that from the fully modified counterpart. Parallel assays monitoring early events in (-) strand strong stop DNA synthesis using either the HXB2 or Mal strain of HIV-1 RNA as the template indicated little difference in the pattern or total product amount when primed with either natural or synthetic tRNA(Lys,3). In addition, nuclease mapping of PBS-bound tRNA suggests inter-molecular base pairing between bases of the tRNA anticodon domain and the U-rich U5-IR loop of the viral 5' leader region is less stable on the HIV-1(HXB2) genome than the HIV-1(Mal) isolate.

Structural variability of the initiation complex of HIV-1 reverse transcription

HIV-1 reverse transcription is initiated from a tRNA(3)(Lys) molecule annealed to the viral RNA at the primer binding site (PBS), but the structure of the initiation complex of reverse transcription remains controversial. Here, we performed in situ structural probing, as well as in vitro structural and functional studies, of the initiation complexes formed by highly divergent isolates (MAL and NL4.3/HXB2). Our results show that the structure of the initiation complex is not conserved. In MAL, and according to sequence analysis in 14% of HIV-1 isolates, formation of the initiation complex is accompanied by complex rearrangements of the viral RNA, and extensive interactions with tRNA(3)(Lys) are required for efficient initiation of reverse transcription. In NL4.3, HXB2, and most isolates, tRNA(3)(Lys) annealing minimally affects the viral RNA structure and no interaction outside the PBS is required for optimal initiation of reverse transcription. We suggest that in MAL, extensive interactions with tRNA(3)(Lys) are required to drive the structural rearrangements generating the structural elements ultimately recognized by reverse transcriptase. In NL4.3 and HXB2, these elements are already present in the viral RNA prior to tRNA(3)(Lys) annealing, thus explaining that extensive interactions with the primer are not required. Interestingly, such interactions are required in HXB2 mutants designed to use a non-cognate tRNA as primer (tRNA(His)). In the latter case, the extended interactions are required to counteract a negative contribution associate with the alternate primer.

Structure-function relationships of the initiation complex of HIV-1 reverse transcription: the case of mutant viruses using tRNA(His) as primer

Reverse transcription of HIV-1 RNA is initiated from the 3' end of a tRNA3Lys molecule annealed to the primer binding site (PBS). An additional interaction between the anticodon loop of tRNA3Lys and a viral A-rich loop is required for efficient initiation of reverse transcription of the HIV-1 MAL isolate. In the HIV-1 HXB2 isolate, simultaneous mutations of the PBS and the A-rich loop (mutant His-AC), but not of the PBS alone (mutant His) allows the virus to stably utilize tRNA(His) as primer. However, mutant His-AC selects additional mutations during cell culture, generating successively His-AC-GAC and His-AC-AT-GAC. Here, we wanted to establish direct relationships between the evolution of these mutants in cell culture, their efficiency in initiating reverse transcription and the structure of the primer/template complexes in vitro. The initiation of reverse transcription of His and His-AC RNAs was dramatically reduced. However, His-AC-GAC RNA, which incorporated three adaptative point mutations, was reverse transcribed more efficiently than the wild type RNA. Incorporation of two additional mutations decreased the efficiency of the initiation of reverse transcription, which remained at the wild type level. Structural probing showed that even though both His-AC and His-AC-GAC RNAs can potentially interact with the anticodon loop of tRNA(His), only the latter template formed a stable interaction. Thus, our results showed that the selection of adaptative mutations by HIV-1 mutants utilizing tRNA(His) as primer was initially dictated by the efficiency of the initiation of reverse transcription, which relied on the existence of a stable interaction between the mutated A-rich loop and the anticodon loop of tRNA(His).

On the importance of the primer activation signal for initiation of tRNA(lys3)-primed reverse transcription of the HIV-1 RNA genome

Initiation of reverse transcription is a complex and regulated process in all retroviruses. Several base pairing interactions have been proposed to occur between the HIV-1 RNA genome and the specific tRNA(lys3) primer. The tRNA primer can form up to 21 bp with the primer binding site (PBS), and an additional 8 bp interaction may form between the primer activation signal (PAS) in the HIV-1 RNA and sequences within the T(Psi)C arm of the tRNA. The latter interaction is further analyzed in this in vitro study with mutant RNA transcripts that were designed to preclude the PAS interaction. These mutant transcripts are able to efficiently bind the tRNA primer, but they exhibit a profound defect at initiating reverse transcription. This defect is specific for the tRNA primer because it is not observed for PBS-bound DNA oligonucleotide primers. These results reinforce the model of regulated reverse transcription in which the PAS-mediated interaction is critical for efficient initiation.

Negative effect of the M184V mutation in HIV-1 reverse transcriptase on initiation of viral DNA synthesis

The M184V mutation in HIV reverse transcriptase (RT) is associated with high-level resistance against the nucleoside inhibitor lamivudine as well as diminished viral replication capacity. We have previously demonstrated that HIV variants containing the M184V mutation were relatively unable to successfully undergo compensatory mutagenesis following deletion of an A-rich loop located upstream of the primer binding site (PBS). To understand the mechanisms involved, we synthesized viral RNA templates containing different compensatory mutations that were emergent during the long-term culture of the A-rich loop-deleted viruses. These templates were then used in cell-free reverse transcription initiation assays and in tRNA primer placement assays performed with either recombinant wild-type RT or recombinant RT containing the M184V substitution. The results showed that the RNA template that contained the A-rich loop deletion was impaired in ability to initiate reverse transcription and that the presence of the M184V substitution in RT amplified this effect. Clearance from pausing at position +3 during synthesis of viral DNA was identified as a sensitive step in this reaction that could not be efficiently bypassed with the M184V mutant enzyme. Increased efficiency of initiation was seen with the deleted RNA templates that also contained mutations identified in the revertant viruses, provided that these mutations facilitated formation of a competent binary tRNA/RNA complex. These findings provide biochemical evidence that initiation of tRNA(Lys3)-primed DNA synthesis is an important rate-limiting step in reverse transcription that correlates with viral replication fitness.

Identification of specific HIV-1 reverse transcriptase contacts to the viral RNA:tRNA complex by mass spectrometry and a primary amine selective reagent

We have devised a high-resolution protein footprinting methodology to dissect HIV-1 reverse transcriptase (RT) contacts to the viral RNA:tRNA complex. The experimental strategy included modification of surface-exposed lysines in RT and RT-viral RNA:tRNA complexes by the primary amine selective reagent NHS-biotin, SDSPAGE separation of p66 and p51 polypeptides, in gel proteolysis, and comparative mass spectrometric analysis of peptide fragments. The lysines modified in free RT but protected from biotinylation in the nucleoprotein complex were readily revealed by this approach. Results of a control experiment examining the RT-DNA:DNA complex were in excellent agreement with the crystal structure data on the identical complex. Probing the RT-viral RNA:tRNA complex revealed that a majority of protein contacts are located in the primer-template binding cleft in common with the RT-DNA:DNA and RT-RNA:DNA species. However, our footprinting data indicate that the p66 fingers subdomain makes additional contacts to the viral RNA:tRNA specific for this complex and not detected with DNA:DNA. The protein footprinting method described herein has a generic application for high-resolution solution structural studies of multiprotein-nucleic acid contacts.

The M184V mutation in HIV-1 reverse transcriptase reduces the restoration of wild-type replication by attenuated viruses

OBJECTIVE

To study the ability of HIV constructs containing the M184V substitution in reverse transcriptase (RT), which causes resistance to lamivudine, to evolve mutations that compensate for deletions within the HIV genome.

METHODS

Viruses containing deletions in non-coding regions of the viral genome were examined in tissue culture to see whether the additional presence of M184V delays the reestablishment of wild-type replication kinetics. Potential compensatory mutations were identified by sequencing, and site-directed mutagenesis was carried out to confirm the biological relevance of such substitutions. The rate of initiation of reverse transcription was measured using either recombinant wild-type RT or RT containing M184V.

RESULTS

M184V-containing viruses were unable to undergo compensatory mutagenesis to reestablish wild-type replication kinetics, whereas viruses that did not contain M184V were able to mutate extensively. This ability was demonstrated most extensively in viruses deleted of an "A-rich loop", located upstream of the primer-binding site, which is involved in initiation of reverse transcription. The rate of such initiation was severely diminished in virus containing the RT enzyme carrying the M184V substitution. This inhibitory effect was significantly enhanced in a biochemical system that included both the M184V mutant enzyme and a viral DNA template that contained the deletion in the A-rich loop.

CONCLUSIONS

These findings provide further biological and biochemical evidence that M184V-containing viruses are impaired in replication fitness. Viruses that had the A-rich-loop deleted were able to reestablish replication ability quickly in the wild-type RT, which provides further evidence for the plasticity of the HIV genome.

Direct and indirect contributions of RNA secondary structure elements to the initiation of HIV-1 reverse transcription

Initiation of human immunodeficiency virus type 1 (HIV-1) reverse transcription requires specific recognition between the viral RNA (vRNA), tRNA(3)(Lys), which acts as primer, and reverse transcriptase (RT). The specificity of this ternary complex is mediated by intricate interactions between the HIV-1 RNA and tRNA(3)(Lys). Here, we compared the relative importance of the secondary structure elements of this complex in the initiation process. To this aim, we used the previously published three-dimensional model of the initiation complex to rationally introduce a series of deletions and substitutions in the vRNA. When necessary, we used chemical probing to check the structure of the tRNA(3)(Lys)-mutant vRNA complexes. For each of them, we measured the binding affinity of RT and the kinetics of initial extension of tRNA(3)(Lys) and of synthesis of the (-) strand strong stop DNA. Our results were overall in keeping with the three-dimensional model of the initiation complex. Surprisingly, we found that disruption of the intermolecular template-primer interactions, which are not directly recognized by RT, more severely affected reverse transcription than deletions or disruption of one of the intramolecular helices to which RT directly binds. Perturbations of the highly constrained junction between the intermolecular helix formed by the primer binding site and the 3' end of tRNA(3)(Lys) and the helix immediately upstream also had dramatic effects on the initiation of reverse transcription. Taken together, our results demonstrate the overwhelming importance of the overall three-dimensional structure of the initiation complex and identify structural elements that constitute promising targets for anti-initiation-specific drugs.

The M184V mutation in reverse transcriptase can delay reversion of attenuated variants of simian immunodeficiency virus

We previously constructed a series of simian immunodeficiency virus (SIV) mutants containing deletions within a 97-nucleotide region of the SIVmac239 untranslated region or leader sequence. However, as is common with live attenuated viruses, several of the mutants exhibited a moderate propensity for reversion. Since the M184V mutation in human immunodeficiency virus type 1 reverse transcriptase is associated with diminished fitness as well as lamivudine resistance, we introduced this substitution into several of our deletion mutants to determine its effects on viral replication and compensatory reversion. Our results indicate that M184V impaired viral fitness in pair-wise comparisons of mutants that contained or lacked this substitution. We also observed that M184V significantly impaired the potential for both compensatory mutagenesis and reversion in these mutants both in cell lines and in peripheral blood mononuclear cells.

The Tat protein of human immunodeficiency virus type 1 (HIV-1) can promote placement of tRNA primer onto viral RNA and suppress later DNA polymerization in HIV-1 reverse transcription

Human immunodeficiency virus type-1 Tat has been proposed to play a role in the regulation of reverse transcription. We previously demonstrated that wild-type Tat can augment viral infectivity by suppressing the reverse transcriptase (RT) reaction at late stages of the viral life cycle in order to prevent the premature synthesis of potentially deleterious viral DNA products. Here we have performed a detailed analysis of the cell-free reverse transcription reaction to elucidate the mechanism(s) whereby Tat can affect this process. Our results show that Tat can suppress nonspecific DNA elongation while moderately affecting the specific initiation stage of reverse transcription. In addition, Tat has an RNA-annealing activity and can promote the placement of tRNA onto viral RNA. This points to a functional homology between Tat and the viral nucleocapsid (NC) protein that is known to be directly involved in this process. Experiments using a series of mutant Tat proteins revealed that the cysteine-rich and core domains of Tat are responsible for suppression of DNA elongation, while each of the cysteine-rich, core, and basic domains, as well as a glutamine-rich region in the C-terminal domain, are important for the placement of tRNA onto the viral RNA genome. These results suggest that Tat can play at least two different roles in the RT reaction, i.e., suppression of DNA polymerization and placement of tRNA onto viral RNA. We believe that the first of these activities of Tat may contribute to the overall efficiency of reverse transcription of the viral genome during a new round of infection as well as to enhanced production of infectious viral particles. We hypothesize that the second activity, illustrating functional homology between Tat and NC, suggests a potential role for NC in the displacement of Tat during viral maturation.

Switching the in vitro tRNA usage of HIV-1 by simultaneous adaptation of the PBS and PAS

Reverse transcription of the HIV-1 RNA genome is primed by the cellular tRNA(lys3) molecule that anneals to a complementary sequence in the viral genome, the primer-binding site (PBS). Additional interactions between the tRNA primer and the viral RNA were proposed to play a role in reverse transcription. We recently identified an 8-nt element in the U5 region upstream of the PBS that is critical for initiation and processive elongation of reverse transcription. This motif was termed the primer activation signal (PAS), and is proposed to interact with the "antiPAS sequence" in the TphiC arm of tRNA(lys3). In this study, we demonstrate that the efficiency of initiation of reverse transcription can be modulated by PAS mutations that strengthen or weaken the interaction with antiPAS. These results provide further evidence for a direct base-pairing interaction between the PAS in the viral RNA and the antiPAS in the tRNA(lys3) molecule. A broad phylogenetic survey indicated that a PAS element is present in all retroviral RNA genomes, suggesting that the process of reverse transcription is regulated by a common mechanism in all retroviridae. It has proven very difficult to change the identity of the tRNA primer for HIV-1 reverse transcription by changing the PBS sequence. Using in vitro reverse transcription assays, we demonstrate that the identity of the priming tRNA species can be switched by simultaneous alteration of the PBS and PAS motifs to accommodate a new tRNA primer. These results indicate that the PAS-antiPAS interaction is important for both primer selection and efficient reverse transcription.

The tRNA primer activation signal in the human immunodeficiency virus type 1 genome is important for initiation and processive elongation of reverse transcription

Human immunodeficiency virus type 1 (HIV-1) reverse transcription is primed by the cellular tRNA(3)(Lys) molecule, which binds, with its 3"-terminal 18 nucleotides (nt), to a complementary sequence in the viral genome, the primer-binding site (PBS). Besides PBS-anti-PBS pairing, additional interactions between viral RNA sequences and the tRNA primer are thought to regulate the process of reverse transcription. We previously identified a novel 8-nt sequence motif in the U5 region of the HIV-1 RNA genome that is critical for tRNA(3)(Lys)-mediated initiation of reverse transcription in vitro. This motif activates initiation from the natural tRNA(3)(Lys) primer but is not involved in tRNA placement and was therefore termed primer activation signal (PAS). It was proposed that the PAS interacts with the anti-PAS motif in the TphiC arm of tRNA(3)(Lys). In this study, we analyzed several PAS-mutated viruses and performed reverse transcription assays with virion-extracted RNA-tRNA complexes. Mutation of the PAS reduced the efficiency of tRNA-primed reverse transcription. In contrast, mutations in the opposing leader sequence that trigger release of the PAS from base pairing stimulated reverse transcription. These results are similar to the reverse transcription effects observed in vitro. We also selected revertant viruses that partially overcome the reverse transcription defect of the PAS deletion mutant. Remarkably, all revertants acquired a single nucleotide substitution that does not restore the PAS sequence but that stimulates elongation of reverse transcription. These combined results indicate that the additional PAS-anti-PAS interaction is needed to assemble an initiation-competent and processive reverse transcription complex.

The HIV plus-strand transfer reaction: determination of replication-competent intermediates and identification of a novel lentiviral element, the primer over-extension sequence

Current retroviral replication models propose that during (+) strand synthesis, the initial (-) strand tRNA primer is partially replicated to reproduce the 18 nt primer-binding site (PBS). Subsequent removal of the tRNA primer from the (-) strand template exposes the PBS, which anneals to complementary sequences on a DNA acceptor template to enable (+) strand transfer. We used model templates composed of primed (-) strand DNA covalently linked with post-transcriptionally modified tRNA(3)(lys) along with natural sequence human immunodeficiency virus (HIV) acceptor DNA to study the generation of the (+) strand strong stop intermediate and the subsequent (+) strand transfer reaction. The rate of formation of the (+) strand transfer reaction products was modestly increased (threefold) by inclusion of nucleocapsid protein, suggesting an ancillary role for this protein in this stage of retroviral replication. In addition to the well-known stop site opposite G59 of the tRNA primer, we detected two additional stop sites opposite psi55 and at A38. Kinetic analysis showed that only the intermediates formed by stops opposite G59 and psi55 were active in the subsequent (+) strand transfer reaction. The surprising discovery of the longer, viable (+) strand interaction intermediate prompted us to survey retroviral sequences for a region complementary to the additional donor DNA nucleotides involved in this over-extension. Indeed, complementary sequences that could support this over-extension were found. A strong consensus sequence is immediately adjacent to and downstream of the PBS in lentiviruses and spumaviruses. This consensus sequence was not found in other genera of retroviruses. We have named this element the "primer over-extension sequence" (POS), and propose that it provides a complementary sequence for strand transfer reactions proceeding from intermediates that extend beyond the standard 18 nt complement of the PBS.

Initiation of HIV-2 reverse transcription: a secondary structure model of the RNA-tRNA(Lys3) duplex

Human immunodeficiency virus type 2 (HIV-2) reverse transcription is initiated from cellular tRNA(Lys3) partially annealed to the RNA viral genome at the primer binding site (PBS). This annealing involves interactions between two highly structured RNA molecules. In contrast to HIV-1, in which the reverse transcription initiation complex has been thoroughly studied, there is still little information regarding a possible model to describe the secondary structure of the template-primer complex in HIV-2. To determine whether HIV-2 RNA sequences flanking the PBS may specifically interact with the natural primer tRNA, we performed site-directed mutagenesis and enzymatic footprinting. An RNA fragment corresponding to the HIV-2 U5 RNA domain and tRNA(Lys3) were probed either in their free form or in the binary complex. Important reactivity changes to nucleases were obtained upon complex formation. In addition to the canonical contacts between the viral PBS and the 3' end acceptor stem of tRNA(Lys3), we identified two additional interacting domains: (i) the U-rich region of the anticodon loop with the A-rich sequence of the internal loop within the U5-prePBS region; (ii) nucleotides 48-54 from the TPsiC domain of tRNA(Lys3) and the 240-247 region of viral U5-RNA. In view of these experimental data and sequence comparison between different HIV-2 isolates, we propose a model for the secondary structure of the HIV-2 template-primer initiation complex.

A novel interaction of tRNA(Lys,3) with the feline immunodeficiency virus RNA genome governs initiation of minus strand DNA synthesis

Complementarity between nucleotides at the 5' terminus of tRNA(Lys,3) and the U5-IR loop of the feline immunodeficiency virus RNA genome suggests a novel intermolecular interaction controls initiation of minus strand synthesis in a manner analogous to other retroviral systems. Base pairing of this tRNA-viral RNA duplex was confirmed by nuclease mapping of the RNA genome containing full-length or 5'-deleted variants of tRNA(Lys,3) hybridized to the primer-binding site. A major pause in RNA-dependent DNA synthesis occurred 14 nucleotides ahead of the primer-binding site with natural and synthetic tRNA(Lys,3) primers, indicating it was not a consequence of tRNA base modifications. The majority of the paused complexes resulted in dissociation of the reverse transcriptase from the template/primer, as demonstrated by an assay limited to a single binding event. Hybridization of a tRNA mutant whose 5' nucleotides are deleted relieved pausing at this position and subsequently allowed high level DNA synthesis. Additional experiments with tRNA-DNA chimeric primers were used to localize the stage of minus strand synthesis at which the tRNA-viral RNA interaction was disrupted. Finally, replacing nucleotides of the feline immunodeficiency virus U5-IR loop with the (A)(4) sequence of its human immunodeficiency virus (HIV)-1 counterpart also relieved pausing, but did not induce pausing immediately downstream of the primer-binding site previously noted during initiation of HIV-1 DNA synthesis. These combined observations provide further evidence of cis-acting sequences immediately adjacent to the primer-binding site controlling initiation of minus strand DNA synthesis in retroviruses and retrotransposons.

Generation of G-to-A and C-to-U changes in HIV-1 transcripts by RNA editing

RNA editing involves posttranscriptional alterations of messenger RNA (mRNA) sequences modifying the information content encoded by the genetic message. Here, it is shown that, in chronically infected H9 cells, human immunodeficiency virus-type 1 (HIV-1) mRNAs undergo guanine-to-adenine (G-to-A) and cytosine-to-uracil (C-to-U) changes. G-to-A modification in the untranslated region of exon 1 was present only in spliced HIV-1 mRNAs. The creation of stop codons in HIV-1 mRNAs may function to control the translation of viral proteins, such as viral protein R, that are involved in the regulation of HIV-1 expression and the survival of chronically infected cells.

In vitro studies on tRNA annealing and reverse transcription with mutant HIV-1 RNA templates

The human immunodeficiency virus type 1 (HIV-1) RNA genome encodes a semistable stem-loop structure, the U5-PBS hairpin, which occludes part of the tRNA primer binding site (PBS). In previous studies, we demonstrated that mutations that alter the stability of the U5-PBS hairpin inhibit virus replication. A reverse transcription defect was measured in assays with the virion-extracted RNA-tRNA complexes. We now extend these studies with in vitro synthesized wild-type and mutant RNA templates that were tested in primer annealing and reverse transcription assays. The effect of annealing temperature and the presence of the viral nucleocapsid protein on reverse transcription was analyzed for the templates with a stabilized or destabilized U5-PBS hairpin, and in reactions initiated by tRNA or DNA primers. The results of this in vitro assay are consistent with the in vivo findings, in that both tRNA annealing and initiation of reverse transcription are sensitive to stable template RNA structure. Reverse transcription initiated by a DNA primer is less hindered by secondary structure in the RNA template than tRNA primed reactions. The inhibitory effect of template structure on tRNA-primed reverse transcription is more pronounced in this in vitro assay compared with the in vivo material, indicating that the heat-annealed RNA-tRNA complex differs from the virion-extracted viral RNA-tRNA complex.

A structured RNA motif is involved in correct placement of the tRNA(3)(Lys) primer onto the human immunodeficiency virus genome

Human immunodeficiency virus type 1 (HIV-1) reverse transcription is primed by the cellular tRNA(3)(Lys) molecule that binds with its 3'-terminal 18 nucleotides to the fully complementary primer-binding site (PBS) on the viral RNA genome. Besides this complementarity, annealing of the primer may be stimulated by additional base-pairing interactions between other parts of the tRNA molecule and viral sequences flanking the PBS. According to the RNA secondary structure model of the HIV-1 leader region, part of the PBS sequence is involved in base pairing to form a small stem-loop structure, termed the U5-PBS hairpin. This hairpin may be involved in the process of reverse transcription. To study the role of the U5-PBS hairpin in the viral replication cycle, we introduced mutations in the U5 region that affect the stability of this structured RNA motif. Stabilization and destabilization of the hairpin significantly inhibited virus replication. Upon prolonged culturing of the virus mutant with the stabilized hairpin, revertant viruses were obtained with additional mutations that restore the thermodynamic stability of the U5-PBS hairpin. The thermodynamic stability of the U5-PBS hairpin apparently has to stay within narrow limits for efficient HIV-1 replication. Transient transfection experiments demonstrated that transcription of the proviral genomes, translation of the viral mRNAs, and assembly of the virions with a normal RNA content is not affected by the mutations within the U5-PBS hairpin. We show that stabilization of the hairpin reduced the amount of tRNA primer that is annealed to the PBS. Destabilization of the hairpin did not affect tRNA annealing, but the viral RNA-tRNA complex was less stable. These results suggest that the U5-PBS hairpin is involved in correct placement of the tRNA primer on the viral genome. The analysis of virus mutants and revertants and the RNA structure probing experiments presented in this study are consistent with the existence of the U5-PBS hairpin as predicted in the RNA secondary structure model.

Structural basis for the specificity of the initiation of HIV-1 reverse transcription

Initiation of human immunodeficiency virus type 1 (HIV-1) reverse transcription requires specific recognition of the viral genome, tRNA3Lys, which acts as primer, and reverse transcriptase (RT). The specificity of this ternary complex is mediated by intricate interactions between HIV-1 RNA and tRNA3Lys, but remains poorly understood at the three-dimensional level. We used chemical probing to gain insight into the three-dimensional structure of the viral RNA-tRNA3Lys complex, and enzymatic footprinting to delineate regions interacting with RT. These and previous experimental data were used to derive a three-dimensional model of the initiation complex. The viral RNA and tRNA3Lys form a compact structure in which the two RNAs fold into distinct structural domains. The extended interactions between these molecules are not directly recognized by RT. Rather, they favor RT binding by preventing steric clashes between the nucleic acids and the polymerase and inducing a viral RNA-tRNA3Lys conformation which fits perfectly into the nucleic acid binding cleft of RT. Recognition of the 3' end of tRNA3Lys and of the first template nucleotides by RT is favored by a kink in the template strand promoted by the short junctions present in the previously established secondary structure.

Genetic evidence of the interaction between tRNA(Lys,3) and U5 facilitating efficient initiation of reverse transcription by human immunodeficiency virus type 1

Previous studies using in vitro chemical and enzyme methods demonstrated that, in addition to the primer-binding site (PBS), two regions upstream of the PBS in U5 of HIV-1 RNA interact with tRNA(Lys,3) during the initiation of reverse transcription. One region corresponds to nucleotides 167-172 of U5, which are complementary to the anticodon region of tRNA(Lys,3); a second region corresponds to nucleotides 142-145 of U5, which interacts with nucleotides 43-46 of tRNA(Lys,3). To study the importance of these viral RNA-tRNA interactions in reverse transcription and viral replication, we mutated the two corresponding regions in the infectious HIV-1 proviral DNA (HXB2). Changing nucleotides 167-172 from GAAAAU to CCACAA (which is complementary to the anticodon of tRNA(His)) or changing nucleotides 142-144 from CCC to GGG did not affect protein expression or production of virus from transfected proviral DNAs. Analysis of these viruses revealed that, although all were infectious, the initial replication was delayed compared with wild-type virus. Using an endogenous reverse transcription-PCR assay, we found that the initiation of the reverse transcription in the mutant viruses was less efficient than that for the wild-type virus. Analysis of the proviral DNA sequences after 2 months of in vitro culture revealed that most progeny viruses derived from the mutant that contained the CCACAA motif had acquired nucleotide substitutions within and surrounding the CCACAA nucleotides. All the viruses recovered from the mutant that originally contained the GGG nucleotides reverted back to contain the wild-type CCC sequence. The majority of the proviral clones derived from virus containing the double mutations had gained additional mutations within the CCACAA and GGG motifs. The replication of the mutant viruses was now similar to that of the wild type. The results of these studies demonstrate that interactions between the tRNA and U5 are important for generation of an optimized initiation complex required for efficient reverse transcription.

Mutational analysis of the tRNA3Lys/HIV-1 RNA (primer/template) complex

Retroviruses use a specific tRNA, whose 3' end is complementary to the 18 nucleotides of the primer binding site (PBS), to prime reverse transcription. Previous work has shown that initiation of HIV-1 reverse transcription is a specific process, in contrast with the subsequent elongation phase. HIV-1 reverse transcriptase (RT) specifically recognizes the complex formed by the viral RNA and tRNA3Lys. We previously proposed a secondary structure model of this complex based on chemical and enzymatic probing. In this model, tRNA3Lysextensively interacts with the genomic RNA. Here, we have combined site-directed mutagenesis and structural probing to test crucial aspects of this model. We found that the complex interactions between tRNA3Lysand HIV-1 RNA, and the intra-molecular rearrangements did not depend on the presence of upstream and downstream viral sequences. Indeed, a short RNA template, encompassing nucleotides 123-217 of the HIV-1 Mal genome, was able, together with the primer tRNA, to adopt the same structure as longer viral RNA fragments. This model primer/template is thus amenable to detailed structural and functional studies. The probing data obtained on the tRNA3Lys/mutant viral RNA complexes support the previously proposed model. Furthermore, they indicate that destroying the complementarity between the anticodon of tRNA3Lysand the so-called viral 'A-rich loop' destabilizes all four helices of the extended tRNA3Lys/HIV-1 RNA interactions.

Insights into the interaction between tRNA and primer binding site from characterization of a unique HIV-1 virus which stably maintains dual PBS complementary to tRNA(Gly) and tRNA(His)

Previously our laboratory constructed an HIV-1 which stably maintained a primer binding site (PBS) complementary to tRNA(His) by mutating the region of the provirus within U5 postulated to interact with the anticodon of tRNA(His) (J. Wakefield, S-M Kang, and C. D. Morrow, 1996, J. Virol, 70, 966-975). From the analysis of the virus obtained after long-term culture, we identified an unusual proviral DNA in which the U5-PBS region contained a dual PBS complementary to tRNA(Gly) and tRNA(His), respectively, separated by a 21-nucleotide intervening sequence. To determine if this U5-PBS region containing the dual PBS would give rise to an infectious virus, the mutant U5-PBS containing the dual PBS was subcloned into an infectious HIV-1 proviral clone, pHXB2; the resultant proviral DNA was designated as pHXB2(Gly-His). Transfection of pHXB2(Gly-His) into cells gave rise to infectious virus. Analysis of the U5-PBS region revealed that the virus stably maintained the dual PBS rather than revert back to the wild-type PBS. In addition to genomes with the PBS complementary to tRNA(Gly) and tRNA(His), proviral genomes were identified after extended in vitro culture which contained dual PBS complementary to tRNA(Gly) and tRNA(Phe). To determine which PBS could be used for reverse transcription, we utilized an endogenous reverse transcription/PCR method which could discriminate (based on molecular size of the products) between the minus strand DNA initiated from the two PBSs. The results of this assay demonstrated that either the PBS complementary to tRNA(Gly) or tRNA(His) could be used for the initiation of reverse transcription. The results of our study highlight the complex interrelationship between U5-PBS and primer tRNA required for positioning the tRNA at the PBS and provides new insights into how the tRNA primer used to initiate reverse transcription is selected.