Stability of HIV type 1 proviral genomes that contain two distinct primer-binding sites

MD simulations of HIV-1 RT primer-template complex: effect of modified nucleosides and antisense PNA oligomer

Human immunodeficiency virus type 1 (HIV-1) requires the human tRNA(3)(Lys) as a reverse transcriptase (RT) primer. The annealing of 3' terminal 18 nucleotides of tRNA(3)(Lys) with the primer binding site (PBS) of viral RNA (vRNA) is crucial for reverse transcription. Additional contacts between the A rich (A-loop) region of vRNA and the anticodon domain of tRNA(3)(Lys) are necessary, which show the specific requirement of tRNA(3)(Lys). The importance of modified nucleosides, present in tRNA(3)(Lys), in giving stability to the primer-template complex has been determined in earlier experiments. It has been observed that the PNA oligomer targeted to PBS of vRNA destabilized the crucial interactions between primer and template due to which the reverse transcription is inhibited. Molecular dynamics simulations have been carried out to study the effect of modified nucleosides on the vRNA-tRNA(3)(Lys) complex stability and the destabilization effect of PNA oligomer on the vRNA-tRNA(3)(Lys)-PNA complex. The root-mean-square deviation, hydrogen bonding, tertiary interactions, and free energy calculations of the simulation data support the experimental results. The analyses have revealed the structural changes in PBS region of vRNA which might be another strong reason for the inability of RT binding to 7F helix for its normal functioning of reverse transcription.

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.

Frequent dual initiation of reverse transcription in murine leukemia virus-based vectors containing two primer-binding sites

Retroviruses package two copies of viral RNA into each virion. Although each RNA contains a primer-binding site for initiation of DNA synthesis, it is unknown whether reverse transcription is initiated on both RNAs. To determine whether a single virion is capable of initiating reverse transcription more than once, we constructed a murine leukemia virus-based vector containing a second primer-binding site (PBS) derived from spleen necrosis virus and inserted the green fluorescent protein gene (GFP) between the two PBSs. Initiation of reverse transcription at either PBS results in a provirus that expresses GFP. However, initiation at both PBSs can result in the deletion of GFP, which can be detected by flow cytometry and Southern blotting analysis. Approximately 22-29% of the proviruses formed deleted the GFP in a single replication cycle, indicating the minimum proportion of virions that initiated reverse transcription on both PBSs. These results show that a significant proportion of MLV-based vectors containing two PBSs have the capacity to initiate reverse transcription more than once.

PNA targeting the PBS and A-loop sequences of HIV-1 genome destabilizes packaged tRNA3(Lys) in the virions and inhibits HIV-1 replication

During assembly of the HIV-1 virions, cellular tRNA(Lys)(3) is packaged into the virion particles and is utilized as a primer for the initiation of reverse transcription. The 3'-terminal 18 nucleotides of the cellular tRNA(Lys)(3) are complementary to nucleotides 183-201 of the viral RNA genome, referred to as the primer binding sequence (PBS). Additional sequences (A-Loop) upstream of the PBS are essential for tRNA primer selection. We report here that a PNA targeted to PBS and A-Loop sequence (PNA(PBS)) exhibits high specificity for its target sequence and prevents tRNA(Lys)(3) priming on the viral genome. We also demonstrate that PNA(PBS) is able to invade the duplex region of the tRNA(Lys)(3)-viral RNA complex and destabilize the priming process, thereby inhibiting the in vitro initiation of reverse transcription. The endogenously packaged tRNA(Lys)(3) bound to the PBS region of the viral RNA genome in the HIV-1 virion is efficiently competed out by PNA(PBS), resulting in near complete inhibition of initiation of endogenous reverse transcription. Examination of the effect of PNA(PBS) on HIV-1 production in CEM cells infected with pseudotyped HIV-1 virions carrying luciferase reporter exhibited dramatic reduction of HIV-1 replication by nearly 99%. Analysis of the mechanism of PNA(PBS)-mediated inhibition indicated that PNA(PBS) interferes at the step of reverse transcription. These findings suggest the antiviral efficacy of PNA(PBS) in blocking the process of HIV-1 replication.

Anti-TAR polyamide nucleotide analog conjugated with a membrane-permeating peptide inhibits human immunodeficiency virus type 1 production

The emergence of drug-resistant variants has posed a significant setback against effective antiviral treatment for human immunodeficiency virus (HIV) infections. The choice of a nonmutable region of the viral genome such as the conserved transactivation response element (TAR element) in the 5' long terminal repeat (LTR) may potentially be an effective target for drug development. We have earlier demonstrated that a polyamide nucleotide analog (PNA) targeted to the TAR hairpin element, when transfected into cells, can effectively inhibit Tat-mediated transactivation of HIV type 1 (HIV-1) LTR (T. Mayhood et al., Biochemistry 39:11532-11539, 2000). Here we show that this anti-TAR PNA (PNA(TAR)), upon conjugation with a membrane-permeating peptide vector (transportan) retained its affinity for TAR in vitro similar to the unconjugated analog. The conjugate was efficiently internalized into the cells when added to the culture medium. Examination of the functional efficacy of the PNA(TAR)-transportan conjugate in cell culture using luciferase reporter gene constructs resulted in a significant inhibition of Tat-mediated transactivation of HIV-1 LTR. Furthermore, PNA(TAR)-transportan conjugate substantially inhibited HIV-1 production in chronically HIV-1-infected H9 cells. The mechanism of this inhibition appeared to be regulated at the level of transcription. These results demonstrate the efficacy of PNA(TAR)-transportan as a potential anti-HIV agent.

Destabilization of tRNA3(Lys) from the primer-binding site of HIV-1 genome by anti-A loop polyamide nucleotide analog

Initiation of human immunodeficiency virus type 1 (HIV-1) reverse transcription occurs by extension of the cellular tRNA3(Lys) which anneals to the primer-binding site (PBS) on the 5' non-translated region of the viral RNA genome. The A-rich sequence (A-loop) upstream of the PBS interacts with the anticodon loop of tRNA3(Lys) and has been proposed to be essential for conferring specificity to tRNA3(Lys) for priming the initiation of HIV-1 reverse transcription. We observed that polyamide nucleic acid targeted to the A-loop sequence (PNAAL) exhibits high binding specificity for its target sequence. The PNAAL pre-bound to the A-loop sequence prevents tRNA3(Lys) priming on the viral RNA consequently blocking in vitro initiation of reverse transcription. Further, PNAAL can efficiently disrupt the preformed [tRNA3(Lys)--viral RNA] complex thereby rendering it non-functional for reverse transcription. The endogenous reverse transcription in disrupted HIV-1 virions containing packaged tRNA3(Lys) and its replicating enzyme RT was significantly inhibited by PNAAL, thus providing direct evidence of the involvement of the A-loop region of viral RNA genome in tRNA3(Lys) priming process. These findings suggest the potential of the A-loop region as a critical target for blocking HIV-1 replication.

Genetic analysis of a unique human immunodeficiency virus type 1 (HIV-1) with a primer binding site complementary to tRNAMet supports a role for U5-PBS stem-loop RNA structures in initiation of HIV-1 reverse transcription

Human immunodeficiency virus type 1 (HIV-1) exclusively uses tRNA3Lys to initiate reverse transcription. A novel HIV-1 mutant which stably utilizes tRNAMet rather than tRNA3Lys as a primer was previously identified [HXB2(Met-AC] (S.-M. Kang, Z. Zhang, and C. D. Morrow, J. Virol. 71:207-217, 1997). Comparison of RNA secondary structures of the unique sequence (U5)-primer binding site (PBS) viral RNA genome alone or complexed with tRNAMet of HXB2(Met-AC) revealed structural motifs in common with the U5-PBS of the wild-type virus. In the current study, mutations were constructed to alter the U5-PBS structure and disrupt the U5-PBS-tRNAMet interaction of the virus derived from HXB2(Met-AC). All of the mutant viruses were infectious following transfection and coculture with SupT1 cells. Analysis of the initiation of reverse transcription revealed that some of the mutants were impaired compared to HXB2(Met-AC). The genetic stability of the PBS from each virus was determined following in vitro culture. Two mutant proviral constructs, one predicted to completely disrupt the stem-loop structure in U5 and the other predicted to destabilize contact regions of U5 with tRNAMet, reverted back to contain a PBS complementary to tRNA3Lys. All other mutants maintained a PBS complementary to tRNAMet after in vitro culture, although all contained multiple nucleotide substitutions within the U5-PBS from the starting proviral clones. Most interestingly, a viral mutant containing a 32-nucleotide deletion between nucleotides 142 and 173, encompassing regions in U5 which interact with tRNAMet, maintained a PBS complementary to tRNAMet following in vitro culture. All of the proviral clones recovered from this mutant, however, contained an additional 19-nucleotide insertion in U5. RNA modeling of the U5-PBS from this mutant demonstrated that the additional mutations present in U5 following culture restored RNA structures similar to those modeled from HXB2(Met-AC). These results provide strong genetic evidence that multiple sequence and structural elements in U5 in addition to the PBS are involved in the interaction with the tRNA used for initiation of reverse transcription.

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.