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).

Effects of tRNA 3 Lys aminoacylation on the initiation of HIV-1 reverse transcription.

HIV-1 utilizes cellular tRNA(3)(Lys) to prime the initiation of reverse transcription. The selective incorporation of cytoplasmic tRNA(3)(Lys) into HIV-1 particles was recently shown to involve the lysyl-tRNA synthetase, and hence, the encapsidated tRNA(3)(Lys) is likely to be aminoacylated. Here, we tested the effect of aminoacylation on the initiation of reverse transcription. We show that HIV-1 reverse transcriptase is unable to extend lysyl-tRNA(3)(Lys). In addition, the viral polymerase does not significantly enhance the rate of tRNA deacylation, in contrast with previous studies on avian retroviruses. Thus, aminoacylation of the primer tRNA might prevent the initiation of HIV-1 reverse transcription from taking place before viral budding and maturation.

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.

Primer unblocking and rescue of DNA synthesis by azidothymidine (AZT)-resistant HIV-1 reverse transcriptase: comparison between initiation and elongation of reverse transcription and between (-) and (+) strand DNA synthesis.

Azidothymidine (AZT) is a widely used inhibitor of type 1 human immunodeficiency virus reverse transcriptase (RT) that acts as chain terminator. Upon treatment, mutations conferring AZT resistance to RT are gradually selected. It has been shown that resistant RT is able to unblock the AZT-terminated primer by an ATP-dependent mechanism. However, this resistance mechanism has only been demonstrated for DNA-dependent DNA elongation. Here, we compared the AZT resistance of mutant RT during DNA elongation on DNA and RNA templates. We showed that, during DNA elongation, primer unblocking and rescue of DNA synthesis take place with similar rate constants on DNA and RNA templates. However, the fraction of a primer eventually repaired during RNA-dependent DNA synthesis is 2x lower compared with that of DNA-dependent synthesis, leading to reduced resistance. We also compared the initiation of reverse transcription, which uses tRNA(3)(Lys) as a primer and displays characteristic kinetic features, and the subsequent RNA-dependent elongation. Unlike during elongation, resistant RT was unable to unblock the AZT-terminated primer during initiation of (-) DNA strand synthesis. Our results demonstrate that the efficiency of primer unblocking conferred by the AZT resistance mutations greatly vary during the different steps of the provirus synthesis. These results also suggest that inhibitors specifically targeting the initiation of reverse transcription might prove to be advantageous, as compared with elongation inhibitors.