Repair of a Rev-minus human immunodeficiency virus type 1 mutant by activation of a cryptic splice site.

We isolated a revertant virus after prolonged culturing of a replication-impaired human immunodeficiency virus type 1 (HIV-1) mutant of which the Rev open reading frame was inactivated by mutation of the AUG translation initiation codon. Sequencing of the tat-rev region of this revertant virus identified a second-site mutation in tat that restored virus replication in the mutant background. This mutation activated a cryptic 5' splice site (ss) that, when used in conjunction with the regular HIV 3' ss #5, fuses the tat and rev reading frames to encode a novel T-Rev fusion protein that rescues Rev function. We also demonstrate an alternative route to indirectly activate this cryptic 5' ss by mutational inactivation of an adjacent exon splicing silencer element.

The leader of the HIV-1 RNA genome forms a compactly folded tertiary structure.

The untranslated leader of the RNA genome of the human immunodeficiency virus type 1 (HIV-1) encodes multiple signals that regulate distinct steps of the viral replication cycle. The RNA secondary structure of several replicative signals in the HIV-1 leader is critical for function. Well-known examples include the TAR hairpin that forms the binding site for the viral Tat trans-activator protein and the DIS hairpin that is important for dimerization and subsequent packaging of the viral RNA into virion particles. In this study, we present evidence for the formation of a tertiary structure by the complete HIV-1 leader RNA. This conformer was recognized as a fast-migrating band on nondenaturing polyacrylamide gels, and such a migration effect is generally attributed to differences in compactness. Both the 5' and 3' domains of the 335-nt HIV-1 leader RNA are required for the formation of the compact RNA structure, and the presence of several putative interaction domains was revealed by an extensive analysis of the denaturing effect of antisense DNA oligonucleotides. The buffer conditions and sequence requirements for conformer formation are strikingly different from that of the RNA-dimerization reaction. In particular, the conformer was destabilized in the presence of Mg2+ ions and by the viral nucleocapsid (NC) protein. The presence of a stable RNA structure in the HIV-1 leader was also apparent when this RNA was used as template for reverse transcription, which yielded massive stops ahead of the structured leader domain. Formation of the conformer is a reversible event, suggesting that the HIV-1 leader is a dynamic molecule. The putative biological function of this conformational polymorphism as molecular RNA switch in the HIV-1 replication cycle is discussed.

Genetic instability of live, attenuated human immunodeficiency virus type 1 vaccine strains.

Live, attenuated viruses have been the most successful vaccines in monkey models of human immunodeficiency virus type 1 (HIV-1) infection. However, there are several safety concerns about using such an anti-HIV vaccine in humans, including reversion of the vaccine strain to virulence and recombination with endogenous retroviral sequences to produce new infectious and potentially pathogenic viruses. Because testing in humans would inevitably carry a substantial risk, we set out to test the genetic stability of multiply deleted HIV constructs in perpetuated tissue culture infections. The Delta3 candidate vaccine strain of HIV-1 contains deletions in the viral long terminal repeat (LTR) promoter and the vpr and nef genes. This virus replicates with delayed kinetics, but a profound enhancement of virus replication was observed after approximately 2 months of culturing. Analysis of the revertant viral genome indicated that the three introduced deletions were maintained but a 39-nucleotide sequence was inserted in the LTR promoter region. This insert was formed by duplication of the region encoding three binding sites for the Sp1 transcription factor. The duplicated Sp1 region was demonstrated to increase the LTR promoter activity, and a concomitant increase in the virus replication rate was measured. In fact, duplication of the Sp1 sites increased the fitness of the Delta3 virus (Vpr/Nef/U3) to levels higher than that of the singly deleted DeltaVpr virus. These results indicate that deleted HIV-1 vaccine strains can evolve into fast-replicating variants by multiplication of remaining sequence motifs, and their safety is therefore not guaranteed. This insight may guide future efforts to develop more stable anti-HIV vaccines.

The native structure of the human immunodeficiency virus type 1 RNA genome is required for the first strand transfer of reverse transcription.

Retroviral particles contain two genomic RNAs of approximately 9 kb that are linked in a noncovalent manner. In vitro studies with purified transcripts have identified particular RNA motifs that contribute to the RNA-dimerization reaction, but the situation may be more complex within virion particles. In this study, we tested whether the primer-binding site (PBS) of the human immunodeficiency virus type 1 (HIV-1) RNA genome and the associated tRNA(Lys3) primer play a role in the process of RNA dimerization. Deletion of the PBS motif did not preclude the formation of RNA dimers within virus particles, indicating that this motif and the tRNA primer do not participate in the interactions that control RNA packaging and dimerization. Genome dimerization has been proposed to play a role in particular steps of the reverse transcription mechanism. To test this, reverse transcription was performed with the native RNA dimer and the heat-denatured template. These two template forms yielded equivalent levels of minus-strand strong-stop cDNA product, which is an early intermediate of reverse transcription. However, melting of the RNA dimer precluded the next step of reverse transcription, in which the minus-strand strong-stop cDNA is translocated from the 5' repeat element to the 3' repeat element. The results suggest that the conformation of the dimeric RNA genome facilitates the first strand-transfer reaction of the reverse transcription mechanism.

The first strand transfer during HIV-1 reverse transcription can occur either intramolecularly or intermolecularly.

Reverse transcription is a complicated process that involves at least two cDNA transfer reactions to produce a full-length copy DNA of the retroviral RNA genome. Because one retrovirus particle contains two identical genomic RNA molecules, the transfers can occur in an intramolecular or intermolecular manner. The mechanism of the first transfer step (minus-strand strong-stop cDNA transfer) has been studied previously in detail in transduction experiments with spleen necrosis virus vectors containing genetic markers. Different results have been reported with respect to the type of strand transfer mechanism. In this study, we analyzed the first strand transfer for human immunodeficiency virus type 1 (HIV-1). Two genetically marked genomes were copackaged into virions and reverse transcription was initiated within these particles upon permeabilization by NP-40 and addition of dNTPs. To test whether intrastrand or interstrand transfer had occurred, the cDNA products of this endogenous reverse transcription reaction were extracted from the virions and analyzed for the presence of restriction enzyme recognition sites provided by the genetic markers. The results of this analysis demonstrated that the first DNA transfer reaction occurs in a random manner, with approximately the same contribution of intrastrand and interstrand transfers. The ability to perform intermolecular strand transfer was lost upon extraction of the dimeric RNA template from the virion particle.

A conserved hairpin motif in the R-U5 region of the human immunodeficiency virus type 1 RNA genome is essential for replication.

The untranslated leader region of the human immunodeficiency virus (HIV) RNA genome contains multiple hairpin motifs. The repeat region of the leader, which is reiterated at the 3' end of the RNA molecule, encodes the well-known TAR hairpin and a second hairpin structure with the polyadenylation signal AAUAAA in the single-stranded loop [the poly(A) hairpin]. The fact that this poly(A) stem-loop structure and its thermodynamic stability are well conserved among HIV and simian immunodeficiency virus isolates, despite considerable divergence in sequence, suggests a biological function for this RNA motif in viral replication. Consistent with this idea, we demonstrate that mutations that alter the stability of the stem region or delete the upper part of the hairpin do severely inhibit replication of HIV type 1. Whereas destabilizing mutations in either the left- or right-hand side of the base-paired stem interfere with virus replication, the double mutant, which allows the formation of new base pairs, replicates more rapidly than the two individual virus mutants. Upon prolonged culturing of viruses with an altered hairpin stability, revertant viruses were obtained with additional mutations that restore the thermodynamic stability of the poly(A) hairpin. Transient transfection experiments demonstrated that transcription of the proviral genomes, translation of the viral mRNAs, and reverse transcription of the genomic RNAs are not affected by mutation of the 5' poly(A) hairpin. We show that the genomic RNA content of the virions is reduced by destabilization of this poly(A) hairpin but not by stabilization or truncation of this structure. These results suggest that the formation of the poly(A) hairpin structure at the 5' end of the genomic RNA molecule is necessary for packaging of viral genomes into virions and/or stability of the virion RNA.

Role of the DIS hairpin in replication of human immunodeficiency virus type 1.

The virion-associated genome of human immunodeficiency virus type 1 consists of a noncovalently linked dimer of two identical, unspliced RNA molecules. A hairpin structure within the untranslated leader transcript is postulated to play a role in RNA dimerization through base pairing of the autocomplementary loop sequences. This hairpin motif with the palindromic loop sequence is referred to as the dimer initiation site (DIS), and the type of interaction is termed loop-loop kissing. Detailed phylogenetic analysis of the DIS motifs in different human and simian immunodeficiency viruses revealed conservation of the hairpin structure with a 6-mer palindrome in the loop, despite considerable sequence divergence. This finding supports the loop-loop kissing mechanism. To test this possibility, proviral genomes with mutations in the DIS palindrome were constructed. The appearance of infectious virus upon transfection into SupT1 T cells was delayed for the DIS mutants compared with that obtained by transfection of the wild-type provirus (pLAI), confirming that this RNA motif plays an important role in virus replication. Surprisingly, the RNA genome extracted from mutant virions was found to be fully dimeric and to have a normal thermal stability. These results indicate that the DIS motif is not essential for human immunodeficiency virus type 1 RNA dimerization and suggest that DIS base pairing does not contribute to the stability of the mature RNA dimer. Instead, we measured a reduction in the amount of viral RNA encapsidated in the mutant virions, suggesting a role of the DIS motif in RNA packaging. This result correlates with the idea that the processes of RNA dimerization and packaging are intrinsically linked, and we propose that DIS pairing is a prerequisite for RNA packaging.

Identification of a novel splice acceptor in the HIV-1 genome: independent expression of the cytoplasmic tail of the envelope protein.

Multiple splicing sites exist in the RNA genome of the human immunodeficiency virus type 1 (HIV-1). In a screen for subgenomic forms of the HIV-1 genome that could be transferred to fresh cells by virus infection, we identified a novel spliced variant of HIV-1 RNA that uses a hitherto unknown splice acceptor site within the envelope (Env) gene. We demonstrate that this splice acceptor is infrequently used in HIV-infected T cells. Interestingly, an AUG initiator codon is created at this splice junction which has the potential to direct the synthesis of the cytoplasmic tail of the Env gp41 protein. Transient transfection experiments with the new cDNA cloned in an expression vector demonstrated efficient utilization of this start codon and the C-terminus of the Env open reading frame. Independent expression of the 152 amino acid long, intracellular Env domain provides novel regulatory mechanisms for modulating viral infectivity and perhaps pathogenicity.

Inhibition of human immunodeficiency virus expression by sense transcripts encoding the retroviral leader RNA.

Towards gene therapy for the treatment of human immunodeficiency virus type 1 (HIV-1) infections, we tested the potency of several antiviral constructs in transient HIV-1 production assays. Whereas little effect was obtained with antisense- and TAR decoy-constructs, we measured efficient inhibition of HIV-1 mRNA translation and virion production in the presence of HIV-1 leader-containing transcripts. The infectivity of these virions was also reduced by this sense inhibitor RNA. These results suggest that leader-encoded functions, like the dimer-linkage structure, can be used to specifically inhibit HIV expression in trans.

Human immunodeficiency virus uses tRNA(Lys,3) as primer for reverse transcription in HeLa-CD4+ cells.

Significant amounts of different tRNA molecules are present in retroviral particles, but one specific tRNA species functions as primer in reverse transcription. It is generally believed that the HIV-1 virus uses the tRNA(Lys,3) molecule as primer. This is based on sequence complementarity between the 3' end of tRNA(Lys,3) and the primer-binding site (PBS) on HIV-1 genomic RNA. Recent biochemical analyses indicated that tRNA(LYs,3) is indeed incorporated into viral particles. Interestingly, tRNA(Lys,3) could not be detected in virions produced by HeLa-CD4+ cells [(1992) Biochem. Biophys. Res. Commun. 185, 1105-1115]. In order to test whether alternative tRNA molecules can function as primer in HIV replication, we performed a series of experiments based on the observation that tRNA primer sequences are inherited by the viral progeny. We cultured HIV-1 for prolonged periods of time in HeLa-CD4+ cells, but did not detect sequence changes in the PBS region. Furthermore, we found PBS-mutants to be replication-incompetent, again suggesting that HIV-1 solely uses tRNA(Lys,3) as primer. Most importantly, we obtained revertants of one such PBS-mutant, which had restored a wild-type PBS sequence. This tRNA(Lys,3)-mediated repair demonstrates a general requirement for this primer in HIV-1 reverse transcription.

Functional Analysis of the ACTGCTGA Sequence Motif in the Human Immunodeficiency Virus Type-1 Long Terminal Repeat Promoter.

The ACTGCTGA sequence (CTG motif) is located immediately upstream of the NF-kappaB enhancer in the human immunodeficiency virus type-1 (HIV-1) long terminal repeat (LTR). We previously reported on the frequent duplication of this motif in HIV-1-infected individuals. In this study we further characterized the role of the CTG element in transcription and its interaction with cellular proteins. We analyzed the biological activity of LTR promoters with dimeric, monomeric or deleted CTG motifs. Our results indicate that LTRs containing the monomeric CTG motif are the most active transcriptional promoters. Furthermore, mutant viruses with dimeric or deleted CTG motif were consistently out-competed by the wild-type virus in co-culture experiments. Gel mobility shift assays were used to identify a nuclear protein of approximately 68 kD that specifically interacts with this DNA sequence. Copyright 1994 S. Karger AG, Basel

Natural variants of the HIV-1 long terminal repeat: analysis of promoters with duplicated DNA regulatory motifs.

Sequence variation in the long terminal repeat (LTR) region of HIV-1 was analyzed in viral isolates of 17 infected individuals. Two classes of LTR size variants were found. One HIV-1 variant was detected containing an additional binding site for the transcription factor Sp1. Another LTR size variation was observed in four patients in a region just upstream of the NF-kappa B enhancer. This variation was the result of a duplication of a short DNA sequence (CTG-motif). Cell culture experiments demonstrated that the natural variant with four Sp1 sites had a slightly higher promoter activity and viral replication rate than the isogenic control LTR with three Sp1 sites. No positive effect of the duplicated CTG-motif could be detected. In order to measure small differences in virus production more accurately, equal amounts of a size variant and the wild-type plasmid were cotransfected into T-cells. The virus with four Sp1 sites did outgrow the three Sp1 virus in 35 days of culture and CTG-monomer virus outcompeted the CTG-dimer virus in 42 days. Based on these results we estimate a 5-10% difference in virus production of the LTR variants when compared to that of wild-type.

Application of the polymerase chain reaction to the detection of bovine viral diarrhea virus infections in cattle.

We used the polymerase chain reaction (PCR) technique to detect bovine viral diarrhea virus (BVDV) infections in cattle. Of 120 cattle screened in this study, 29 were scored positive for BVDV with both PCR and conventional virus isolation. Ninety cattle were negative in both assays. One cow was scored positive for BVDV with the PCR but was negative with virus isolation. In dilution experiments PCR analysis was at least 10 times more sensitive than BVDV isolation.