Inhibition of the initiation of HIV-1 reverse transcription by 3'-azido-3'-deoxythymidine. Comparison with elongation.

Initiation of human immunodeficiency virus-1 reverse transcription requires formation of a complex containing the viral RNA, primer tRNA(3)(Lys), and reverse transcriptase. Initiation, corresponding to addition of the first six nucleotides to tRNA(3)(Lys), is distinguished from elongation by its high specificity and low efficiency (processivity). Here, we compared the inhibition of initiation and elongation of reverse transcription by 3'-azido-3'-deoxythymidine 5'-triphosphate (AZTTP), the active form of 3'-azido-3'-deoxythymidine. We report the first detailed study of nucleotide binding, discrimination, and pyrophosphorolysis by the authentic initiation complex. We showed that the initiation and elongation complexes bound AZTTP and dTTP with the same affinity, while the polymerization rates were reduced by 148-160-fold during initiation. The pyrophosphorolysis rate of dTTP was reduced by the same extent, indicating that the polymerization equilibrium is the same in the two phases. The efficient unblocking of the 3'-azido-3'-deoxythymidine 5'-monophosphate (AZTMP)-terminated primer by pyrophosphorolysis significantly relieved inhibition of DNA synthesis during elongation in the presence of physiological pyrophosphate concentrations. Remarkably, although pyrophosphorolysis of dTMP and AZTMP were equally efficient during elongation, reverse transcriptase was almost totally unable to unblock the AZTMP-terminated primer during initiation. As a result, inhibition of reverse transcription by AZTTP was more efficient during initiation than elongation of reverse transcription, despite a reduced selectivity of incorporation.

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.

Contacts between reverse transcriptase and the primer strand govern the transition from initiation to elongation of HIV-1 reverse transcription.

HIV-1 reverse transcriptase (RT) utilizes RNA oligomers to prime DNA synthesis. The initiation of reverse transcription requires specific interactions between HIV-1 RNA, primer tRNA3Lys, and RT. We have previously shown that extension of an oligodeoxyribonucleotide, a situation that mimicks elongation, is unspecific and differs from initiation by the polymerization rate and dissociation rate of RT from the primer-template complex. Here, we used replication intermediates to analyze the transition from the initiation to the elongation phases. We found that the 2'-hydroxyl group at the 3' end of tRNA had limited effects on the polymerization and dissociation rate constants. Instead, the polymerization rate increased 3400-fold between addition of the sixth and seventh nucleotide to tRNA3Lys. The same increase in the polymerization rate was observed when an oligoribonucleotide, but not an oligodeoxyribonucleotide, was used as a primer. In parallel, the dissociation rate of RT from the primer-template complex decreased 30-fold between addition of the 17th and 19th nucleotide to tRNA3Lys. The polymerization and dissociation rates are most likely governed by interactions of the primer strand with helix alphaH in the p66 thumb subdomain and the RNase H domain of RT, respectively.

Binding and kinetic properties of HIV-1 reverse transcriptase markedly differ during initiation and elongation of reverse transcription.

We recently showed that primer tRNA3Lys, human immunodeficiency virus type 1 (HIV-1) RNA and HIV-1 reverse transcriptase (RT) form a specific complex of initiation of reverse transcription that can be functionally distinguished from the elongation complex, which can be obtained by substituting an 18mer oligodeoxyribonucleotide (ODN) for the natural primer (Isel et al., 1996). Here, we compared the binding properties and the single and multiple turnover kinetics of HIV-1 RT in the initiation and elongation complexes. Even though the equilibrium dissociation constants of HIV-1 RT are not very different for the two complexes, RT dissociates approximately 200-fold faster from the initiation complex. Furthermore, nucleotide incorporation by the pre-formed primer-template-RT complexes is reduced by a approximately 50-fold factor during initiation of reverse transcription, compared with elongation. As a consequence, processivity of HIV-1 RT in the initiation complex is close to unity, while it increases by four orders of magnitude during elongation, as expected for a replication enzyme. This processivity change is reminiscent of the transition from initiation to elongation of transcription. Furthermore, our results indicate that the post-transcriptional modifications of tRNA3Lys play a role similar to that of the sigma factor in transcription by the Escherichia coli RNA polymerase: they favour the formation of the specific initiation complex but do not affect the polymerization rate of the bound enzyme.

Primer selection by HIV-1 reverse transcriptase on RNA-tRNA(3Lys) and DNA-tRNA(3Lys) hybrids.

During reverse transcription of the genomic RNA of human immunodeficiency virus type 1 (HIV-1) into double-stranded DNA, reverse transcriptase (RT) must accommodate RNA-RNA, DNA-RNA, RNA-DNA and DNA-DNA hybrids as primer-template. In this study, we examined extension of RNA-tRNA3Lys, and DNA-tRNA3Lys complexes by HIV-1 RT. When the 3' end of tRNA3Lys is annealed to oligoribonucleotides, tRNA3Lys, but not the complementary RNAs, is extended by HIV-1 RT, indicating that tRNA3Lys is efficiently used as primer and RNA as template. An opposite primer usage is observed when tRNA3Lys is annealed to complementary oligodeoxyribonucleotides. In this case, the oligodeoxyribonucleotides are efficiently used as primer and tRNA3Lys as template. This result indicates that the nature of nucleic acid bound to tRNA3Lys determines which strand of the RNA-tRNA3Lys and DNA-tRNA3Lys hybrids is extended by HIV-1 RT. When an oligoribonucleotide is annealed to an unmodified transcript of tRNA3Lys, both nucleic acids are extended by HIV-1 RT, indicating that specific selection of tRNA3Lys as primer requires the post-transcriptional modifications of tRNA3Lys.

Specific initiation and switch to elongation of human immunodeficiency virus type 1 reverse transcription require the post-transcriptional modifications of primer tRNA3Lys.

Initiation of RNA-dependent DNA synthesis by retroviral reverse transcriptases is generally considered as unspecific. In the case of human immunodeficiency virus type 1 (HIV-1), the natural primer is tRNA3Lys. We recently found evidence of complex interactions between tRNA3Lys and HIV-1 RNA that may be involved in the priming process. In this study, we compare the ability of natural and unmodified synthetic tRNA3Lys and 18mer oligoribo- and oligodeoxyribonucleotides complementary to the viral primer binding site to initiate replication of HIV-1 RNA using either homologous or heterologous reverse transcriptases. We show that HIV-1 RNA, HIV-1 reverse transcriptase and primer tRNA3Lys form a specific initiation complex that differs from the unspecific elongation complex formed when an oligodeoxyribonucleotide is used as primer. Modified nucleosides of tRNA3Lys are required for efficient initiation and transition to elongation. Transition from initiation to elongation, but not initiation of reverse transcription itself, is facilitated by extended primer-template interactions. Elongation, but not initiation of reverse transcription, is inhibited by Mn2+, which further differentiates these two different functional states of reverse transcriptase. These results define initiation of reverse transcription as a target to block viral replication.

Structural and functional evidence that initiation and elongation of HIV-1 reverse transcription are distinct processes.

Retroviral reverse transcription starts with the extension of a cellular tRNA primer bound near the 5' end of the viral genomic RNA at a site called the primer binding site (PBS). Formation of the HIV-1 initiation complex between tRNA3(Lys), viral RNA and reverse transcriptase probably occurs during encapsidation of these components. tRNA3(Lys) is thought to be selectively packaged by interaction with the reverse transcriptase domain of the Pr160Gag-Pol precursor protein, then annealed to the PBS of viral RNA with the help of the nucleocapsid protein. tRNA3(Lys) and HIV-1 viral RNA form a highly-structured complex, with extended interactions between the two molecules. Two different modes of reverse transcription have been distinguished: initiation, a tRNA3(Lys)-specific and distributive mode of polymerization corresponding to the addition of the first five nucleotides, followed by elongation, a non-specific and processive mode of DNA synthesis. These two modes are reminiscent of the initiation and elongation processes previously observed with DNA-dependent RNA polymerases.