Strand transfer mediated by human immunodeficiency virus reverse transcriptase in vitro is promoted by pausing and results in misincorporation

High-Frequency Illegitimate Strand Transfers of Nascent DNA Fragments During Reverse Transcription Result in Defective Retrovirus Genomes

BACKGROUND

Two strand transfers of nascent DNA fragments during reverse transcription are required for retrovirus replication. However, whether strand transfers occur at illegitimate sites and how this may affect retrovirus replication are not well understood.

METHODS

The reverse transcription was carried out with reverse transcriptases (RTs) from HIV-1, HIV-2, and murine leukemia virus. The nascent complementary DNA fragments were directly cloned without polymerase chain reaction amplification. The sequences were compared with the template sequence to determine if new sequences contained mismatched sequences caused by illegitimate strand transfers.

RESULTS

Among 1067 nascent reverse transcript sequences, most of them (72%) matched to the template sequences, although they randomly stopped across the RNA templates. The other 28% of them contained mismatched 3'-end sequences because of illegitimate strand transfers. Most of the illegitimate strand transfers (81%) were disassociated from RNA templates and realigned onto opposite complementary DNA strands. Up to 3 strand transfers were detected in a single sequence, whereas most of them (93%) contained 1 strand transfer. Because most of the illegitimate strand-transfer fragments were generated from templates at 2 opposite orientations, they resulted in defective viral genomes and could not be detected by previous methods. Further analysis showed that mutations at pause/disassociation sites resulted in significantly higher strand-transfer rates. Moreover, illegitimate strand-transfer rates were significantly higher for HIV-2 RT (38.2%) and murine leukemia virus RT (44.6%) than for HIV-1 RT (5.1%).

CONCLUSIONS

Illegitimate strand transfers frequently occur during reverse transcription and can result in a large portion of defective retrovirus genomes.

Resolution of Specific Nucleotide Mismatches by Wild-Type and AZT-Resistant Reverse Transcriptases during HIV-1 Replication

A key contributor to HIV-1 genetic variation is reverse transcriptase errors. Some mutations result because reverse transcriptase (RT) lacks 3' to 5' proofreading exonuclease and can extend mismatches. However, RT also excises terminal nucleotides to a limited extent, and this activity contributes to AZT resistance. Because HIV-1 mismatch resolution has been studied in vitro but only indirectly during replication, we developed a novel system to study mismatched base pair resolution during HIV-1 replication in cultured cells using vectors that force template switching at defined locations. These vectors generated mismatched reverse transcription intermediates, with proviral products diagnostic of mismatch resolution mechanisms. Outcomes for wild-type (WT) RT and an AZT-resistant (AZT(R)) RT containing a thymidine analog mutation set-D67N, K70R, D215F, and K219Q-were compared. AZT(R) RT did not excise terminal nucleotides more frequently than WT, and for the majority of tested mismatches, both WT and AZT(R) RTs extended mismatches in more than 90% of proviruses. However, striking enzyme-specific differences were observed for one mispair, with WT RT preferentially resolving dC-rC pairs either by excising the mismatched base or switching templates prematurely, while AZT(R) RT primarily misaligned the primer strand, causing deletions via dislocation mutagenesis. Overall, the results confirmed HIV-1 RT's high capacity for mismatch extension during virus replication and revealed dramatic differences in aberrant intermediate resolution repertoires between WT and AZT(R) RTs on one mismatched replication intermediate. Correlating mismatch extension frequencies observed here with reported viral mutation rates suggests a complex interplay of nucleotide discrimination and mismatch extension drives HIV-1 mutagenesis.

Retroviral vectors for analysis of viral mutagenesis and recombination

Retrovirus population diversity within infected hosts is commonly high due in part to elevated rates of replication, mutation, and recombination. This high genetic diversity often complicates the development of effective diagnostics, vaccines, and antiviral drugs. This review highlights the diverse vectors and approaches that have been used to examine mutation and recombination in retroviruses. Retroviral vectors for these purposes can broadly be divided into two categories: those that utilize reporter genes as mutation or recombination targets and those that utilize viral genes as targets of mutation or recombination. Reporter gene vectors greatly facilitate the detection, quantification, and characterization of mutants and/or recombinants, but may not fully recapitulate the patterns of mutagenesis or recombination observed in native viral gene sequences. In contrast, the detection of mutations or recombination events directly in viral genes is more biologically relevant but also typically more challenging and inefficient. We will highlight the advantages and disadvantages of the various vectors and approaches used as well as propose ways in which they could be improved.

Fifteen to twenty percent of HIV substitution mutations are associated with recombination

HIV undergoes high rates of mutation and recombination during reverse transcription, but it is not known whether these events occur independently or are linked mechanistically. Here we used a system of silent marker mutations in HIV and a single round of infection in primary T lymphocytes combined with a high-throughput sequencing and mathematical modeling approach to directly estimate the viral recombination and mutation rates. From >7 million nucleotides (nt) of sequences from HIV infection, we observed 4,801 recombination events and 859 substitution mutations (≈1.51 and 0.12 events per 1,000 nt, respectively). We used experimental controls to account for PCR-induced and transfection-induced recombination and sequencing error. We found that the single-cycle virus-induced mutation rate is 4.6 × 10(-5) mutations per nt after correction. By sorting of our data into recombined and nonrecombined sequences, we found a significantly higher mutation rate in recombined regions (P = 0.003 by Fisher's exact test). We used a permutation approach to eliminate a number of potential confounding factors and confirm that mutation occurs around the site of recombination and is not simply colocated in the genome. By comparing mutation rates in recombined and nonrecombined regions, we found that recombination-associated mutations account for 15 to 20% of all mutations occurring during reverse transcription.

The A-nucleotide preference of HIV-1 in the context of its structured RNA genome

A bipartition of HIV-1 RNA genome sequences into single- and double-stranded nucleotides is possible based on the secondary structure model of a complete 9 kb genome. Subsequent analysis revealed that the well-known lentiviral property of A-accumulation is profoundly present in single-stranded domains, yet absent in double-stranded domains. Mutational rate analysis by means of an unrestricted model of nucleotide substitution suggests the presence of an evolutionary equilibrium to preserve this biased nucleotide distribution.

The origin of genetic diversity in HIV-1

One of the hallmarks of HIV infection is the rapid development of a genetically complex population (quasispecies) from an initially limited number of infectious particles. Genetic diversity remains one of the major obstacles to eradication of HIV. The viral quasispecies can respond rapidly to selective pressures, such as that imposed by the immune system and antiretroviral therapy, and frustrates vaccine design efforts. Two unique features of retroviral replication are responsible for the unprecedented variation generated during infection. First, mutations are frequently introduced into the viral genome by the error prone viral reverse transcriptase and through the actions of host cellular factors, such as the APOBEC family of nucleic acid editing enzymes. Second, the HIV reverse transcriptase can utilize both copies of the co-packaged viral genome in a process termed retroviral recombination. When the co-packaged viral genomes are genetically different, retroviral recombination can lead to the shuffling of mutations between viral genomes in the quasispecies. This review outlines the stages of the retroviral life cycle where genetic variation is introduced, focusing on the principal mechanisms of mutation and recombination. Understanding the mechanistic origin of genetic diversity is essential to combating HIV.

Mechanisms and factors that influence high frequency retroviral recombination

With constantly changing environmental selection pressures, retroviruses rely upon recombination to reassort polymorphisms in their genomes and increase genetic diversity, which improves the chances for the survival of their population. Recombination occurs during DNA synthesis, whereby reverse transcriptase undergoes template switching events between the two copackaged RNAs, resulting in a viral recombinant with portions of the genetic information from each parental RNA. This review summarizes our current understanding of the factors and mechanisms influencing retroviral recombination, fidelity of the recombination process, and evaluates the subsequent viral diversity and fitness of the progeny recombinant. Specifically, the high mutation rates and high recombination frequencies of HIV-1 will be analyzed for their roles in influencing HIV-1 global diversity, as well as HIV-1 diagnosis, drug treatment, and vaccine development.

A template-dependent dislocation mechanism potentiates K65R reverse transcriptase mutation development in subtype C variants of HIV-1

Numerous studies have suggested that the K65R reverse transcriptase (RT) mutation develops more readily in subtype C than subtype B HIV-1. We recently showed that this discrepancy lies partly in the subtype C template coding sequence that predisposes RT to pause at the site of K65R mutagenesis. However, the mechanism underlying this observation and the elevated rates of K65R development remained unknown. Here, we report that DNA synthesis performed with subtype C templates consistently produced more K65R-containing transcripts than subtype B templates, regardless of the subtype-origin of the RT enzymes employed. These findings confirm that the mechanism involved is template-specific and RT-independent. In addition, a pattern of DNA synthesis characteristic of site-specific primer/template slippage and dislocation was only observed with the subtype C sequence. Analysis of RNA secondary structure suggested that the latter was unlikely to impact on K65R development between subtypes and that Streisinger strand slippage during DNA synthesis at the homopolymeric nucleotide stretch of the subtype C K65 region might occur, resulting in misalignment of the primer and template. Consequently, slippage would lead to a deletion of the middle adenine of codon K65 and the production of a -1 frameshift mutation, which upon dislocation and realignment of the primer and template, would lead to development of the K65R mutation. These findings provide additional mechanistic evidence for the facilitated development of the K65R mutation in subtype C HIV-1.

A critical analysis of Atoh7 (Math5) mRNA splicing in the developing mouse retina

The Math5 (Atoh7) gene is transiently expressed during retinogenesis by progenitors exiting mitosis, and is essential for ganglion cell (RGC) development. Math5 contains a single exon, and its 1.7 kb mRNA encodes a 149-aa polypeptide. Mouse Math5 mutants have essentially no RGCs or optic nerves. Given the importance of this gene in retinal development, we thoroughly investigated the possibility of Math5 mRNA splicing by Northern blot, 3'RACE, RNase protection assays, and RT-PCR, using RNAs extracted from embryonic eyes and adult cerebellum, or transcribed in vitro from cDNA clones. Because Math5 mRNA contains an elevated G+C content, we used graded concentrations of betaine, an isostabilizing agent that disrupts secondary structure. Although approximately 10% of cerebellar Math5 RNAs are spliced, truncating the polypeptide, our results show few, if any, spliced Math5 transcripts exist in the developing retina (<1%). Rare deleted cDNAs do arise via RT-mediated RNA template switching in vitro, and are selectively amplified during PCR. These data differ starkly from a recent study (Kanadia and Cepko 2010), which concluded that the vast majority of Math5 and other bHLH transcripts are spliced to generate noncoding RNAs. Our findings clarify the architecture of the Math5 gene and its mechanism of action. These results have implications for all members of the bHLH gene family, for any gene that is alternatively spliced, and for the interpretation of all RT-PCR experiments.

Factors Affecting Template Usage in the Development of K65R Resistance in Subtype C Variants of HIV Type-1

Background:

We have shown that the K65R resistance mutation in HIV type-1 (HIV-1) reverse transcriptase (RT) is selected more rapidly in subtype C than subtype B HIV-1 in biochemical, cell culture and clinical studies. Template-usage experiments demonstrated that subtype C nucleotide coding sequences caused RT to preferentially pause, leading to K65R acquisition. This new study now further establishes the basis for differential occurrence of both K65R and thymidine analogue mutations (TAMs) between subtypes.

Methods:

Gel-based nucleotide extension assays were used to study the homopolymeric sequence surrounding K65.

Results:

When positive double-stranded DNA synthesis was evaluated from a negative single-stranded DNA template, pausing at the 67 region, which is linked to occurrence of TAMs, was alleviated with both subtype B and C templates at high dCTP concentrations, but this alleviation was more pronounced with the subtype C template. By contrast, pausing at the 65 region on the subtype C but not subtype B template always occurred and was not alleviated at high levels of nucleotide triphosphates or by other means. Furthermore, templates containing repeats of the homopolymeric sequence spanning codons 64–66 of pol showed corresponding pausing repeats at the 65 region with the subtype C template only. Inverted RNA and DNA templates both displayed pausing at position K65 for the subtype C template and a ladder of pausing events culminating at codon 67 for the subtype B templates.

Conclusions:

These results further establish a mechanistic basis for the exclusion of both K65R and TAMs on single templates as well as the preferential acquisition of K65R in subtype C viruses.

Factors that determine the efficiency of HIV-1 strand transfer initiated at a specific site

Human immunodeficiency virus-1 employs strand transfer for recombination between two viral genomes. We have previously provided evidence that strand transfer proceeds by an invasion-mediated mechanism in which a DNA segment on the original RNA template is invaded by a second RNA template at a gap site. The initial RNA-DNA hybrid then expands until the DNA is fully transferred. Ribonuclease H (RNase H) cleavages and nucleocapsid protein (NC) were required for long-distance propagation of the hybrid. Evaluation was performed on a unique substrate, with a short gap serving as a precreated invasion site. In our current work, this substrate provided an opportunity for us to test what factors influence a specific invasion site to support transfer, and to distinguish factors that influence invasion site creation from those that impact later steps. RNase H can act in a polymerization-dependent or polymerization-independent mode. Polymerization-dependent and polymerization-independent RNase H were found to be important in creating efficiently used invasion sites in the primer-donor complex, with or without NC. Propagation and terminus transfer steps, emanating from a precreated invasion site in the presence of NC, were stimulated by polymerization-dependent, but not polymerization-independent, RNase H. RNase H can carry out primary and secondary cleavages during synthesis. While both modes of cleavage promoted invasion, only primary cleavage promoted propagation in the presence of NC in our system. These observations suggest that once invasion is initiated at a short gap, it can propagate through an adjacent region interrupted only by nicks, with help by NC. We considered the possibility that propagation solely by strand exchange was a significant contributor to transfers. However, it did not promote transfer even if synthetic progress of reverse transcriptase was intentionally slowed, consistent with strand exchange by random walk in which rate declines precipitously with distance.

A recombination hot spot in HIV-1 contains guanosine runs that can form a G-quartet structure and promote strand transfer in vitro

The co-packaged RNA genomes of human immunodeficiency virus-1 recombine at a high rate. Recombination can mix mutations to generate viruses that escape immune response. A cell-culture-based system was designed previously to map recombination events in a 459-bp region spanning the primer binding site through a portion of the gag protein coding region. Strikingly, a strong preferential site for recombination in vivo was identified within a 112-nucleotide-long region near the beginning of gag. Strand transfer assays in vitro revealed that three pause bands in the gag hot spot each corresponded to a run of guanosine (G) residues. Pausing of reverse transcriptase is known to promote recombination by strand transfer both in vivo and in vitro. To assess the significance of the G runs, we altered them by base substitutions. Disruption of the G runs eliminated both the associated pausing and strand transfer. Some G-rich sequences can develop G-quartet structures, which were first proposed to form in telomeric DNA. G-quartet structure formation is highly dependent on the presence of specific cations. Incubation in cations discouraging G-quartets altered gel mobility of the gag template consistent with breakdown of G-quartet structure. The same cations faded G-run pauses but did not affect pauses caused by hairpins, indicating that quartet structure causes pausing. Moreover, gel analysis with cations favoring G-quartet structure indicated no structure in mutated templates. Overall, results point to reverse transcriptase pausing at G runs that can form quartets as a unique feature of the gag recombination hot spot.

A polymerase-site-jumping model for strand transfer during DNA synthesis by reverse transcriptase

During reverse transcription, besides the obligatory strand transfers associated with replication at the ends of the viral genome, multiple strand transfers often occur associated with replication within internal regions. Here, based on previous structural and biochemical studies, a model is proposed for processive DNA synthesis along a single template mediated by reverse transcriptase and, based on this model, the mechanism of inter- or intramolecular strand transfers during minus DNA synthesis is presented. A strand-transfer event involves two steps, with the first one being the annealing of the nascent DNA with acceptor RNA at the upstream position of the reverse transcriptase while the second one being the jumping of the polymerase active site to the acceptor. Using the model, the promotion of strand transfer by pausing and high frequent deletions induced by strand transfers can be well explained. We present analytical studies of the efficiency of single strand-transfer event and of the efficiency of multiple-strand-transfer events, with which the high negative interference can be well explained. The dependence of strand-transfer efficiency on the ratio between polymerase and RNase H rates, the role of the polymerase-dependent and polymerase-independent cleavages in strand transfers and the efficiency of nonhomologous strand transfer are analytically studied. The theoretical results are in agreement with the available experimental data. Moreover, some predicted results of the dependence of negative interference on the ratio of polymerase over RNase H rates are presented.

Long patch base excision repair proceeds via coordinated stimulation of the multienzyme DNA repair complex

Base excision repair, a major repair pathway in mammalian cells, is responsible for correcting DNA base damage and maintaining genomic integrity. Recent reports show that the Rad9-Rad1-Hus1 complex (9-1-1) stimulates enzymes proposed to perform a long patch-base excision repair sub-pathway (LP-BER), including DNA glycosylases, apurinic/apyrimidinic endonuclease 1 (APE1), DNA polymerase beta (pol beta), flap endonuclease 1 (FEN1), and DNA ligase I (LigI). However, 9-1-1 was found to produce minimal stimulation of FEN1 and LigI in the context of a complete reconstitution of LP-BER. We show here that pol beta is a robust stimulator of FEN1 and a moderate stimulator of LigI. Apparently, there is a maximum possible stimulation of these two proteins such that after responding to pol beta or another protein in the repair complex, only a small additional response to 9-1-1 is allowed. The 9-1-1 sliding clamp structure must serve primarily to coordinate enzyme actions rather than enhancing rate. Significantly, stimulation by the polymerase involves interaction of primer terminus-bound pol beta with FEN1 and LigI. This observation provides compelling evidence that the proposed LP-BER pathway is actually employed in cells. Moreover, this pathway has been proposed to function by sequential enzyme actions in a "hit and run" mechanism. Our results imply that this mechanism is still carried out, but in the context of a multienzyme complex that remains structurally intact during the repair process.

Template usage is responsible for the preferential acquisition of the K65R reverse transcriptase mutation in subtype C variants of human immunodeficiency virus type 1

We propose that a nucleotide template-based mechanism facilitates the acquisition of the K65R mutation in subtype C human immunodeficiency virus type 1 (HIV-1). Different patterns of DNA synthesis were observed using DNA templates from viruses of subtype B or C origin. When subtype C reverse transcriptase (RT) was employed to synthesize DNA from subtype C DNA templates, preferential pausing was seen at the nucleotide position responsible for the AAG-to-AGG K65R mutation. This did not occur when the subtype B RT and template were used. Template factors can therefore increase the probability of K65R development in subtype C HIV-1.

Long-range recombination gradient between HIV-1 subtypes B and C variants caused by sequence differences in the dimerization initiation signal region

HIV-1 intersubtype recombinants have an increasingly important role in shaping the AIDS pandemic. We sought to understand the molecular mechanisms that generate intersubtype HIV-1 recombinants. We analyzed recombinants of HIV-1 subtypes B and C, and identified their crossover junctions in the viral genome from the 5' long terminal repeat (LTR) to the end of pol. We identified 56 recombination events in 56 proviruses; the distribution of these events indicated an apparent recombination gradient: there were significantly more crossover junctions in the 3' half than in the 5' half of the region analyzed. HIV-1 subtypes B and C have different dimerization initiation signal (DIS). We hypothesized that the inability of subtype B and C RNAs to form perfect base-pairing of the DIS affects the dimeric RNA structure and causes a decrease in recombination events at the 5' end of the viral genome. To test this hypothesis, we examined recombinants generated from a subtype C virus and a modified subtype B virus containing a subtype C DIS. In the 56 proviruses analyzed, we identified 96 recombination events, which are significantly more frequent than in the B/C recombinants. Furthermore, these crossover junctions were distributed evenly throughout the region analyzed, indicating that the recombination gradient was corrected by matching the DIS. Therefore, base-pairing at the DIS has an important function during HIV-1 reverse transcription, most likely in maintaining nucleic-acid structure in the complex. These findings reveal elements important to retroviral recombination and provide insights into the generation of HIV-1 intersubtype recombinants that are important to the AIDS epidemic.

Implications of recombination for HIV diversity

The human immunodeficiency virus (HIV) population is characterised by extensive genetic variability that results from high error and recombination rates of the reverse transcription process, and from the fast turnover of virions in HIV-infected individuals. Among the viral variants encountered at the global scale, recombinant forms are extremely abundant. Some of these recombinants (known as circulating recombinant forms) become fixed and undergo rapid expansion in the population. The reasons underlying their epidemiological success remain at present poorly understood and constitute a fascinating area for future research to improve our understanding of immune escape, pathogenicity and transmission. Recombinant viruses are generated during reverse transcription as a consequence of template switching between the two genetically different genomic RNAs present in a heterozygous virus. Recombination can thereby generate shortcuts in evolution by producing mosaic reverse transcription products of parental genomes. Therefore, in a single infectious cycle multiple mutations that are positively selected can be combined or, conversely, negatively selected mutations can be removed. Recombination is therefore involved in different aspects of HIV evolution, adaptation to its host, and escape from antiviral treatments.

Strand transfer events during HIV-1 reverse transcription

Human immunodeficiency virus type 1 (HIV-1) and other retroviruses replicate through reverse transcription, a process in which the single stranded RNA of the viral genome is converted to a double stranded DNA. The virally encoded reverse transcriptase (RT) mediates reverse transcription through DNA polymerase and RNase H activities. Conversion of the plus strand RNA to plus/minus strand RNA/DNA hybrid involves a transfer of the growing DNA strand from one site on the genomic RNA to another. This is called minus strong-stop DNA transfer. Later synthesis of the second or plus DNA strand involves a second strand transfer, involving a similar mechanism as the minus strand transfer. A basic feature of the strand transfer mechanism is the use of the RT RNase H to remove segments of the RNA template strand from the growing DNA strand, freeing a single stranded region to anneal to the second site. Viral nucleocapsid protein (NC) functions to promote transfer by facilitating this strand exchange process. Two copies of the RNA genomes, sometimes non-identical, are co-packaged in the genomes of retroviruses. The properties of the reverse transcriptase allow a transfer of the growing DNA strand between these genomes to occur occasionally at any point during reverse transcription, producing recombinant viral progeny. Recombination promotes structural diversity of the virus that helps it to survive host immunity and drug therapy. Recombination strand transfer can be forced by a break in the template, or can occur at sites where folding structure of the template pauses the RT, allowing a concentration of RNase H cleavages that promote transfers. Transfer can be a simple one-step process, or can proceed by a complex multi-step invasion mechanism. In this latter process, the second RNA template interacts with the growing DNA strand well behind the DNA 3'-terminus. The newly formed RNA-DNA hybrid expands by branch migration and eventually catches the elongating DNA primer 3'-terminus to complete the transfer. Transfers are also promoted by interactions between the two RNA templates, which accelerate transfer by a proximity effect. Other details of the role of strand transfers in reverse transcription and the biochemical features of the transfer reaction are discussed.

Proximity and branch migration mechanisms in HIV-1 minus strand strong stop DNA transfer

Human immunodeficiency virus type 1 minus strand transfer was measured using a genomic donor-acceptor template system in vitro. Donor RNA D199, having the minimum region required for minus strong stop DNA synthesis, was previously shown to transfer with 35% efficiency to an acceptor RNA representing the 3' repeat region. Donor D520, having an additional 321-nucleotide segment extending into gag, transferred at 75% efficiency. In this study each transfer step was analyzed to account for the difference. Measurement of terminal transfer indicated that the 3' terminus of the cDNA generated using D520 is more accessible for transfer than that of D199. Nevertheless, acceptor competition experiments demonstrated that D520 has a greater preference for invasion-driven versus terminal transfer than D199. Competition mapping showed that the base of the transactivation response element is the primary invasion site for D520, important for efficient acceptor invasion. Acceptors complementary to the invasion and terminal transfer sites, but not the region between, allowed assessment of the significance of hybrid propagation by branch migration. These bipartite acceptors showed that with D520, invasion raises the local concentration of the acceptor for efficient terminal transfer by a proximity effect. However, with D199, invasion is relatively inefficient, and the cDNA 3' terminus is not very accessible. For most transfers that occurred, the acceptor accessed the cDNA 3' end by branch migration. Results suggest that both proximity and branch migration mechanisms contribute to transfers, with the proportion determined by donor-cDNA structure. D520 transfers better because it has greater accessibility for both invasion and terminus transfer.

Environment determines fidelity for an RNA virus replicase

The rate of insertion and deletion mutations of the replicase of Cucumber mosaic virus (CMV) was determined in planta by using a parasitic satellite RNA (satRNA) as a reporter. We found that the CMV replicase had different fidelity in different environments, with important implications in viral disease evolution. Insertions were very rare events, irrespective of the region of the satRNA genome assayed and independent of the hosts tested. On the other hand, deletion events were more frequent but were restricted to a highly structured region of the reporter. Deletion mutation rates were different for the two hosts tested, although the mutation distribution was not influenced by the hosts. Moreover, hot spots with high mutation rates were identified on the satRNA genome.

Ty1 reverse transcriptase does not read through the proposed 2',5'-branched retrotransposition intermediate in vitro

2',5'-branched RNA was recently proposed as a key Ty1 retrotransposition intermediate, for which cleavage by lariat debranching enzyme (Dbr1p) enables reverse transcription to continue synthesizing the complete Ty1 cDNA. Because dbr1 cells can produce substantial Ty1 cDNA despite lacking Dbr1p, the obligatory intermediacy of branched RNA would require that Ty1 reverse transcriptase (RT) can read through the proposed branch site with considerable efficiency. Here we have used deoxyribozyme-synthesized 2',5'-branched RNA corresponding exactly to the proposed Ty1 branch site for a direct test of this read-through ability. Using an in vitro assay that incorporates all components known to be required for Ty1 cDNA synthesis (including the TyA chaperone protein), Ty1 RT can elongate up to the branch site. Strand transfer from the 2'-arm to the 3'-arm of the branch is observed when the Ty1 RT is RNase H+ (i.e., wild-type) but not when the Ty1 RT is RNase H-. When elongating from either the 2'-arm or the 3'-arm, Ty1 RT reads through the branch site with <or=0.3% efficiency. This is at least 60-fold lower than would be necessary to explain in vivo Ty1 cDNA synthesis in dbr1 cells, because others have reported 18% cDNA synthesis relative to wild-type cells. Our finding that Ty1 RT cannot efficiently read through the proposed Ty1 branch site is inconsistent with the hypothesis that branched RNA is an obligatory Ty1 retrotransposition intermediate. This suggests that Dbr1p acts as other than a 2',5'-phosphodiesterase during Ty1 retrotransposition.

Mechanisms that prevent template inactivation by HIV-1 reverse transcriptase RNase H cleavages

The RNase H activity of human immunodeficiency virus, type 1 (HIV-1) reverse transcriptase (RT) cleaves the viral genome concomitant with minus strand synthesis. We previously analyzed RT-mediated pausing and RNase H cleavage on a hairpin-containing RNA template system and reported that RT generated 3' end-directed primary and secondary cuts while paused at the base of the hairpin during synthesis. Here, we report that all of the prominent cleavage products observed during primer extension on this template correlated with pause induced cuts. Products that persisted throughout the reaction corresponded to secondary cuts, about eight nucleotides in from the DNA primer terminus. This distance allows little overlap of intact template with the primer terminus. We considered whether secondary cuts could inactivate further synthesis by promoting dissociation of the primer from the template. As anticipated, 3' end-directed secondary cuts decreased primer extendibility. This provides a plausible mechanism to explain the persistence of secondary cut products in our hairpin template system. Improving the efficiency of synthesis by increasing the concentration of dNTPs or addition of nucleocapsid protein (NC) reduced pausing and the generation of pause related secondary cuts on this template. Further studies reveal that 3' end-directed primary and secondary cleavages were also generated when synthesis was stalled by the presence of 3'-azido-3'-deoxythymidine at the primer terminus, possibly contributing to 3'-azido-3'-deoxythymidine inhibition. Considered together, the data reveal a role for NC and other factors that enhance DNA synthesis in the prevention of RNase H cleavages that could be detrimental to viral replication.

Insights into the multiple roles of pausing in HIV-1 reverse transcriptase-promoted strand transfers

We previously analyzed the role of pausing induced by hairpin structures within RNA templates in facilitating strand transfer by HIV-1 RT (reverse transcriptase). We proposed a multistep transfer mechanism in which pause-induced RNase H cuts within the initial RNA template (donor) expose regions of cDNA. A second homologous RNA template (acceptor) can interact with the cDNA at such sites, initiating transfer. The acceptor-cDNA hybrid is thought to then propagate by branch-migration, eventually catching up with the primer terminus and completing the transfer. The prominent pause site in the template system facilitated acceptor invasion; however, very few of the transfers terminated at this pause. To examine the effects of homology on pause-promoted transfer, we increased template homology before the pause site, from 19 nucleotides (nt) in the initial template system to 52 nt in the new system. Significantly, the increased homology enhanced transfers 3-fold, with 32% of the transfers now terminating at the pause site. Additionally, the acceptor cleavage profile indicated the creation of a new invasion site in the added region of homology. NC (nucleocapsid) increased the strand transfer throughout the whole template. However, the prominent hot spot for internal transfer remained, which was still at the pause site. We interpret the new results to mean that pause sites can also serve to stall DNA synthesis, allowing acceptor invasions initiated earlier in the template to catch up with the primer terminus.

Short partially double-stranded oligodeoxynucleotide induces reverse transcriptase/RNase H-mediated cleavage of HIV RNA and contributes to abrogation of infectivity of virions

We describe a novel mechanism of viral RNA eradication by an oligodeoxynucleotide A (ODN A) directly in HIV virions. The ODN A consists of an antisense and a passenger strand, and was designed to target the polyp-urine tract (PPT) of HIV-1, a conserved region of the viral genome. It leads to HIV reverse transcriptase/ribonuclease H (RT/RNase H)-dependent degradation of the RNA in viral particles. Illimaquinone, a specific inhibitor of RNase H, activity of HIV RT/RNase H, prevents RNA cleavage. The effect of the ODN A is sequence-specific and the passenger strand is important, since a lack or alteration of this strand reduces the antiviral activity of the ODN. ODN A has a stronger antiviral effect compared to a control ODN CO, targeted to a site outside of the PPT. The pretreatment with ODN A strongly reduced the infectivity of virions in cell culture in the absence of any DNA carriers or detergents.

Proviral progeny of heterodimeric virions reveal a high crossover rate for human immunodeficiency virus type 2

Human immunodeficiency virus type 1 (HIV-1), the causative agent of AIDS in humans, exhibits a very high rate of recombination. Bearing in mind the significant epidemiological and clinical contrast between HIV-2 and HIV-1 as well as the critical role that recombination plays in viral evolution, we examined the nature of HIV-2 recombination. Towards this end, a strategy was devised to measure the rate of crossover of HIV-2 by evaluating recombinant progeny produced exclusively by heterodimeric virions. The results showed that HIV-2 exhibits a crossover rate similar to that of HIV-1 and murine leukemia virus, indicating that the extremely high rate of crossover is a common retroviral feature.

Sequence determinants of breakpoint location during HIV-1 intersubtype recombination

Retroviral recombination results from strand switching, during reverse transcription, between the two copies of genomic RNA present in the virus. We analysed recombination in part of the envelope gene, between HIV-1 subtype A and D strains. After a single infection cycle, breakpoints clustered in regions corresponding to the constant portions of Env. With some exceptions, a similar distribution was observed after multiple infection cycles, and among recombinant sequences in the HIV Sequence Database. We compared the experimental data with computer simulations made using a program that only allows recombination to occur whenever an identical base is present in the aligned parental RNAs. Experimental recombination was more frequent than expected on the basis of simulated recombination when, in a region spanning 40 nt from the 5′ border of a breakpoint, no more than two discordant bases between the parental RNAs were present. When these requirements were not fulfilled, breakpoints were distributed randomly along the RNA, closer to the distribution predicted by computer simulation. A significant preference for recombination was also observed for regions containing homopolymeric stretches. These results define, for the first time, local sequence determinants for recombination between divergent HIV-1 isolates.

Reduced dNTP interaction of human immunodeficiency virus type 1 reverse transcriptase promotes strand transfer

We have recently demonstrated that HIV-1 RT mutants characterized by low dNTP binding affinity display significantly reduced dNTP incorporation kinetics in comparison to wild-type RT. This defect is particularly emphasized at low dNTP concentrations where WT RT remains capable of efficient synthesis. Kinetic interference in DNA synthesis can induce RT pausing and slow down the synthesis rate. RT stalling and slow synthesis rate can enhance RNA template cleavage by RT-RNase H, facilitating transfer of the primer to a homologous template. We therefore hypothesized that reduced dNTP binding RT mutants can promote template switching during minus strand synthesis more efficiently than WT HIV-1 RT at low dNTP concentrations. To test this hypothesis, we employed two dNTP binding HIV-1 RT mutants, Q151N and V148I. Indeed, as the dNTP concentration was decreased, the template switching frequency progressively increased for both WT and mutant RTs. However, as predicted, the RT mutants promoted more transfers compared with WT RT. The WT and mutant RTs were similar in their intrinsic RNase H activity, supporting that the elevated template switching efficiency of the mutants was not the result of the mutations enhancing RNase H activity. Rather, kinetic interference leading to stalled DNA synthesis likely enhanced transfers. These results suggest that the RT-dNTP substrate interaction mechanistically influences strand transfer and recombination of HIV-1 RT.

Nidovirus transcription: how to make sense...?

Many positive-stranded RNA viruses use subgenomic mRNAs to express part of their genetic information. To produce structural and accessory proteins, members of the order Nidovirales (corona-, toro-, arteri- and roniviruses) generate a 3' co-terminal nested set of at least three and often seven to nine mRNAs. Coronavirus and arterivirus subgenomic transcripts are not only 3' co-terminal but also contain a common 5' leader sequence, which is derived from the genomic 5' end. Their synthesis involves a process of discontinuous RNA synthesis that resembles similarity-assisted RNA recombination. Most models proposed over the past 25 years assume co-transcriptional fusion of subgenomic RNA leader and body sequences, but there has been controversy over the question of whether this occurs during plus- or minus-strand synthesis. In the latter model, which has now gained considerable support, subgenomic mRNA synthesis takes place from a complementary set of subgenome-size minus-strand RNAs, produced by discontinuous minus-strand synthesis. Sense-antisense base-pairing interactions between short conserved sequences play a key regulatory role in this process. In view of the presumed common ancestry of nidoviruses, the recent finding that ronivirus and torovirus mRNAs do not contain a common 5' leader sequence is surprising. Apparently, major mechanistic differences must exist between nidoviruses, which raises questions about the functions of the common leader sequence and nidovirus transcriptase proteins and the evolution of nidovirus transcription. In this review, nidovirus transcription mechanisms are compared, the experimental systems used are critically assessed and, in particular, the impact of recently developed reverse genetic systems is discussed.

Pausing during reverse transcription increases the rate of retroviral recombination

Retroviruses package two copies of genomic RNA into viral particles. During the minus-sense DNA synthesis step of reverse transcription, the nascent DNA can transfer multiple times between the two copies of the genome, resulting in recombination. The mechanism for this process is similar to the process of obligate strand transfers mediated by the repeat and primer binding site sequences. The location at which the DNA 3' terminus completely transfers to the second RNA strand defines the point of crossover. Previous work in vitro demonstrated that reverse transcriptase pausing has a significant impact on the location of the crossover, with a proportion of complete transfer events occurring very close to pause sites. The role of pausing in vivo, however, is not clearly understood. By employing a murine leukemia virus-based single-cycle infection assay, strong pausing was shown to increase the probability of recombination, as reflected in the reconstitution of green fluorescent protein expression. The infection assay results were directly correlated with the presence of strong pause sites in reverse transcriptase primer extension assays in vitro. Conversely, when pausing was diminished in vitro, without changing the sequence of the RNA template involved in recombination, there was a significant reduction in recombination in vivo. Together, these data demonstrate that reverse transcriptase pausing, as observed in vitro, directly correlates with recombination during minus-sense DNA synthesis in vivo.

Modulating the splicing activity of Tetrahymena ribozyme via RNA self-assembly

The internal guiding sequence (IGS) is normally located at the 5' end of trans-splicing ribozymes that are derived from the Tetrahymena group I intron, and is required for the recognition of substrate RNAs and for trans-splicing reactions. Here, we separated the Tetrahymena group I intron at the L2 loop to produce two fragments: the IGS-containing substrate, and the IGS-lacking ribozyme. We show here that two fragments can complex not through the IGS interaction but under the guidance of appended interacting nucleotides, and perform trans-splicing. The splicing reactions took place both in vitro and in mammalian cells, and the spliced mRNA product from the self-assembled ribozyme complex can be translated into functional proteins in vivo. The splicing efficiency was dependent on the length of appending nucleotides.

Dissection of a circumscribed recombination hot spot in HIV-1 after a single infectious cycle

Recombination is a major source of genetic heterogeneity in the human immunodeficiency virus type 1 (HIV-1) population. The main mechanism responsible for the generation of recombinant viruses is a process of copy choice between the two copies of genomic RNA during reverse transcription. We previously identified, after a single cycle of infection of cells in culture, a recombination hot spot within the gp120 gene, corresponding to the top portion of a RNA hairpin. Here, we determine that the hot region is circumscribed to 18 nucleotides located in the descending strand of the stem, following the sense of reverse transcription. Three factors appeared to be important, albeit at different extents, for the high rate of recombination observed in this region. The position of the hot sequence in the context of the RNA structure appears crucial, because changing its location within this structure triggered differences in recombination up to 20-fold. Another pivotal factor is the presence of a perfectly identical sequence between donor and acceptor RNA in the region of transfer, because single or double nucleotide differences in the hot spot were sufficient to almost completely abolish recombination in the region. Last, the primary structure of the hot region also influenced recombination, although with effects only in the 2-3-fold range. Altogether, these results provide the first molecular dissection of a hot spot in infected cells and indicate that several factors contribute to the generation of a site of preferential copy choice.

Evidence that HIV-1 reverse transcriptase employs the DNA 3' end-directed primary/secondary RNase H cleavage mechanism during synthesis and strand transfer

We previously analyzed strand transfers catalyzed by human immunodeficiency virus, type 1 reverse transcriptase (RT) in a hairpin-containing RNA template system. In this system, RT produces a series of adjacent RNase H cuts before the hairpin base on the first, or donor template that clears a region of the donor, facilitating invasion by the second, or acceptor RNA. Here we analyze characteristics of the prominent cuts before the hairpin base and their role in strand transfers. Analysis of the template cleavage pattern during synthesis suggested that the RT performs DNA 3' end-directed primary and secondary cuts while paused at the hairpin base and that these cuts contribute to creation of the invasion site. RT catalyzed similar cleavages on a substrate representing a paused cDNA-template intermediate. DNA 3' end-directed secondary cuts, which require positioning of the polymerase active site downstream of the primer terminus, had previously not been specifically identified during synthesis. Our findings indicate that during synthesis DNA 3' end-directed primary and secondary cuts occur at pause sites. RT mutants with substitutions at the His(539) residue in the RNase H active site were defective in secondary cleavages. Analysis of the template cleavage pattern generated by the His(539) mutants during synthesis revealed inefficient cleavage at the invasion site, correlating with defects in strand transfer. Overall, results indicate RT can catalyze pause-associated DNA 3' end-directed primary and secondary cuts during synthesis and these cuts can contribute to strand transfer by creation of an invasion site.

Heterologous RNA replication enhancer stimulates in vitro RNA synthesis and template-switching by the carmovirus, but not by the tombusvirus, RNA-dependent RNA polymerase: implication for modular evolution of RNA viruses

The viral RNA plays multiple roles during replication of RNA viruses, serving as a template for complementary RNA synthesis and facilitating the assembly of the viral replicase complex. These roles are coordinated by cis-acting regulatory elements, such as promoters and replication enhancers (REN). To test if these RNA elements can be used by related viral RNA-dependent RNA polymerases (RdRp), we compared the potential stimulatory effects of homologous and heterologous REN elements on complementary RNA synthesis and template-switching by the tombus- (Cucumber necrosis virus, CNV), carmovirus (Turnip crinkle virus, TCV) and hepatitis C virus (HCV) RdRps in vitro. The CNV RdRp selectively utilized its cognate REN, while discriminating against the heterologous TCV REN. On the contrary, RNA synthesis by the TCV RdRp was stimulated by the TCV REN and the heterologous tombusvirus REN with comparable efficiency. The heterologous REN elements also promoted in vitro template-switching by the TCV and HCV RdRps. Based on these observations, we propose that REN elements could facilitate intervirus recombination and post-recombinational amplification of new recombinant viruses.

Effects of donor and acceptor RNA structures on the mechanism of strand transfer by HIV-1 reverse transcriptase

Template switching during reverse transcription contributes to recombination in human immunodeficiency virus type 1 (HIV-1). Our recent studies suggest that the process can occur through a multi-step mechanism involving RNase H cleavage, acceptor invasion, branch migration, and finally primer terminus transfer. In this study, we analyzed the effects of reverse transcriptase (RT)-pausing, RNase H cleavages and template structure on the transfer process. We designed a series of donor and acceptor template pairs with either minimal pause sites or with pause sites at various locations along the template. Restriction sites within the region of homology allowed efficient mapping of the location of primer terminus transfer. Blocking oligomers were used to probe the acceptor invasion site. Introduction of strong pause sites in the donor increased transfer efficiency. However, the new pauses were not necessarily associated with effective invasion. In this system, the primary invasion occurred at a region of donor cleavage associated with weak pausing. These results together with acceptor structure predictions indicated that a potential invasion site is used only in conjunction with a favorable acceptor structure. Stabilizing acceptor structure at the predicted invasion region lowered the transfer efficiency, supporting this conclusion. Differing from previous studies, terminus transfer occurred at a short distance from the invasion site. Introduction of structure into the acceptor template shifted the location of terminus transfer. Nucleocapsid protein, which can improve cDNA-acceptor interactions, increased transfer efficiency with some shift of terminus transfer closer to the invasion site. Overall results support that the acceptor structure has a major influence on the efficiency and position of the invasion and terminus transfer steps.

Precise identification of endogenous proviruses of NFS/N mice participating in recombination with moloney ecotropic murine leukemia virus (MuLV) to generate polytropic MuLVs

Polytropic murine leukemia viruses (MuLVs) are generated by recombination of ecotropic MuLVs with env genes of a family of endogenous proviruses in mice, resulting in viruses with an expanded host range and greater virulence. Inbred mouse strains contain numerous endogenous proviruses that are potential donors of the env gene sequences of polytropic MuLVs; however, the precise identification of those proviruses that participate in recombination has been elusive. Three different structural groups of proviruses in NFS/N mice have been described and different ecotropic MuLVs preferentially recombine with different groups of proviruses. In contrast to other ecotropic MuLVs such as Friend MuLV or Akv that recombine predominantly with a single group of proviruses, Moloney MuLV (M-MuLV) recombines with at least two distinct groups. In this study, we determined that only three endogenous proviruses, two of one group and one of another group, are major participants in recombination with M-MuLV. Furthermore, the distinction between the polytropic MuLVs generated by M-MuLV and other ecotropic MuLVs is the result of recombination with a single endogenous provirus. This provirus exhibits a frameshift mutation in the 3' region of the surface glycoprotein-encoding sequences that is excluded in recombinants with M-MuLV. The sites of recombination between the env genes of M-MuLV and endogenous proviruses were confined to a short region exhibiting maximum homology between the ecotropic and polytropic env sequences and maximum stability of predicted RNA secondary structure. These observations suggest a possible mechanism for the specificity of recombination observed for different ecotropic MuLVs.

Rare One and Two Amino Acid Inserts Adjacent to Codon 103 of the HIV-1 Reverse Transcriptase (Rt) Affect Susceptibility to Non-Nucleoside Rt Inhibitors

HIV-1 strains that possess a one or two amino acid insert between codons 102 and 103 of the reverse transcriptase (RT) gene were identified in three HIV-1-infected individuals. Each strain also had one or more known mutations associated with nucleoside RT inhibitors (NRTIs) and non-nucleoside RT inhibitors (NNRTIs). Recombinant viruses from these strains had reduced susceptibility to efavirenz and nevirapine, and homology modelling predicted a loss of binding contacts with efavirenz. Mutagenesis studies indicated that replication of insert-containing strains was dependent on RT gene mutations and polymorphisms that co-evolved with the insert. These results suggest that inserts in the NNRTI-binding pocket contribute to NNRTI resistance, but are tolerated only under specific genetic conditions.

Effects of unpaired nucleotides within HIV-1 genomic secondary structures on pausing and strand transfer

Reverse transcriptase-mediated RNA displacement synthesis is required for DNA polymerization through the base-paired stem portions of secondary structures present in retroviral genomes. These regions of RNA duplex often possess single unpaired nucleotides, or "bulges," that disrupt contiguous base pairing. By using well defined secondary structures from the human immunodeficiency virus, type 1 (HIV-1), genome, we demonstrate that removal of these bulges either by deletion or by introducing a complementary base on the opposing strand results in increased pausing at specific positions within the RNA duplex. We also show that the HIV-1 nucleocapsid protein can increase synthesis through the pause sites but not as efficiently as when a bulge residue is present. Finally, we demonstrate that removing a bulge increases the proportion of strand transfer events to an acceptor template that occur prior to complete replication of a donor template secondary structure. Together our data suggest a role for bulge nucleotides in enhancing synthesis through stable secondary structures and reducing strand transfer.

Identification of a preferred region for recombination and mutation in HIV-1 gag

We designed a cell culture-based system to test the hypothesis that recombination events during HIV-1 replication would be more frequent near the dimerization initiation sequence (DIS). A 459-bp region spanning the DIS through the 5'-end of gag was sequenced and analyzed to determine the frequency and distribution of crossover sites. We found a strong preference for recombination events occurring within a 112-nt-long region encompassing the gag AUG (64% of crossovers occurred in this region, compared to 10-14% in surrounding regions with similar lengths). Surprisingly, the region immediately surrounding the DIS was not a preferred site of recombination. Analysis of recombination events using RNA templates transcribed in vitro revealed a preference for crossover sites at the start of the gag coding region, similar to that observed in cell culture. This recombinogenic region was unusually G-rich and promoted extensive pausing by RT in vitro. Template features that induce RT pausing very likely contribute to the observed template switching events in gag during minus-strand synthesis. The region in gag that was a preferred site for recombination also had an approximately 2-fold higher mutation frequency compared to the rest of the region sequenced, but mutations were no more common in recombinant compared to non-recombinant clones, suggesting that recombination events were not mutagenic.

The structure of HIV-1 genomic RNA in the gp120 gene determines a recombination hot spot in vivo

By frequently rearranging large regions of the genome, genetic recombination is a major determinant in the plasticity of the human immunodeficiency virus type I (HIV-1) population. In retroviruses, recombination mostly occurs by template switching during reverse transcription. The generation of retroviral vectors provides a means to study this process after a single cycle of infection of cells in culture. Using HIV-1-derived vectors, we present here the first characterization and estimate of the strength of a recombination hot spot in HIV-1 in vivo. In the hot spot region, located within the C2 portion of the gp120 envelope gene, the rate of recombination is up to ten times higher than in the surrounding regions. The hot region corresponds to a previously identified RNA hairpin structure. Although recombination breakpoints in vivo cluster in the top portion of the hairpin, the bias for template switching in this same region appears less marked in a cell-free system. By modulating the stability of this hairpin we were able to affect the local recombination rate both in vitro and in infected cells, indicating that the local folding of the genomic RNA is a major parameter in the recombination process. This characterization of reverse transcription products generated after a single cycle of infection provides insights in the understanding of the mechanism of recombination in vivo and suggests that specific regions of the genome might be prompted to yield different rates of evolution due to the presence of circumscribed recombination hot spots.

The AU-rich RNA recombination hot spot sequence of Brome mosaic virus is functional in tombusviruses: implications for the mechanism of RNA recombination

RNA recombination can be facilitated by recombination signals present in viral RNAs. Among such signals are short sequences with high AU contents that constitute recombination hot spots in Brome mosaic virus (BMV) and retroviruses. In this paper, we demonstrate that a defective interfering (DI) RNA, a model template associated with Tomato bushy stunt virus (TBSV), a tombusvirus, undergoes frequent recombination in plants and protoplast cells when it carries the AU-rich hot spot sequence from BMV. Similar to the situation with BMV, most of the recombination junction sites in the DI RNA recombinants were found within the AU-rich region. However, unlike BMV or retroviruses, where recombination usually occurred with precision between duplicated AU-rich sequences, the majority of TBSV DI RNA recombinants were imprecise. In addition, only one copy of the AU-rich sequence was essential to promote recombination in the DI RNA. The selection of junction sites was also influenced by a putative cis-acting element present in the DI RNA. We found that this RNA sequence bound to the TBSV replicase proteins more efficiently than did control nonviral sequences, suggesting that it might be involved in replicase "landing" during the template switching events. In summary, evidence is presented that a tombusvirus can use the recombination signal of BMV. This supports the idea that common AU-rich recombination signals might promote interviral recombination between unrelated viruses.

Complementarity-directed RNA dimer-linkage promotes retroviral recombination in vivo

Retroviral particles contain a dimeric RNA genome, which serves as template for the generation of double-stranded DNA by reverse transcription. Transfer between RNA strands during DNA synthesis is governed by both sequence similarity between templates and structural features of the dimeric RNA. A kissing hairpin, believed to facilitate intermolecular recognition and dimer formation, was previously found to be a preferred site for recombination. To investigate if hairpin loop-loop-complementarity is the primary determinant for this recombination preference, we have devised a novel 5' leader recombination assay based upon co-packaging of two wild-type or loop-modified murine leukemia virus vector RNAs. We found that insertion of an alternative palindromic loop in one of the two vectors disrupted site-directed template switching, whereas site-specificity was restored between vectors with complementary non-wild-type palindromes. By pairing vector RNAs that contained identical non-palindromic loop motifs and that were unlikely to interact by loop-loop kissing, we found no preference for recombination at the kissing hairpin site. Of vector pairs designed to interact through base pairing of non-palindromic loop motifs, we could in one case restore hairpin-directed template switching, in spite of the reduced sequence identity, whereas another pair failed to support hairpin- directed recombination. However, analyses of in vitro RNA dimerization of all studied vector combinations showed a good correlation between efficient dimer formation between loop-modified viral RNAs and in vivo cDNA transfer at the kissing hairpin. Our findings demonstrate that complementarity between wild-type or non-wild-type hairpin kissing loops is essential but not sufficient for site-specific 5' leader recombination and lend further support to the hypothesis that a specific 'kissing' loop-loop interaction is guided by complementary sequences and maintained within the mature dimeric RNA of retroviruses.

Advances in the molecular biology of tombusviruses: gene expression, genome replication, and recombination

The tombusviruses are among the most extensively studied messenger-sensed RNA plant viruses. Over the past decade, there have been numerous important advances in our understanding of the molecular biology of members in this genus. Unlike most other RNA viruses, the synthesis of tombusvirus proteins has been found to involve an atypical translational mechanism related to the uncapped and nonpolyadenylated nature of their genomes. Tombusviruses also appear to employ an unusual mechanism for transcription of the sg mRNAs that template translation of a subset of their viral proteins. In addition to these new insights into tombusvirus gene expression, there has also been significant progress made in our understanding of tombusvirus RNA replication. These studies have been facilitated greatly by small genome-derived RNA replicons, referred to as defective interfering RNAs. In addition, the development of an in vitro system to study viral RNA synthesis has allowed for dissection of some of the steps involved in the replication process. Another exciting recent advance has been the creation of yeast-based systems that support amplification of tombusvirus RNA replicons and will allow the identification of host factors involved in viral RNA synthesis. Lastly, the recombinogenic nature of tombusvirus genomes has made them ideal systems for studying RNA-RNA recombination and genetic rearrangements, both in vivo and in vitro. In this review, we compile recent information on each of the aforementioned processes-translation, transcription, replication and recombination-and discuss the significance of the results.

Steps of the acceptor invasion mechanism for HIV-1 minus strand strong stop transfer

Minus strand strong stop transfer is obligatory for completion of HIV-1 minus strand synthesis. We previously showed evidence for an acceptor invasion-initiated mechanism for minus strand transfer. In the present study, we examined the major acceptor invasion initiation site using a minus strand transfer system in vitro, containing the 97-nucleotide full-length R region. A series of DNA oligonucleotides complementary to different regions of the cDNA was designed to interfere with transfer. Oligomers covering the region around the base of the TAR hairpin were most effective in inhibiting transfer, suggesting that the hairpin base is a preferred site for acceptor invasion. The strong pausing of reverse transcriptase at the base of the TAR and the concomitant RNase H cleavages 10-19 nucleotides behind the pause site correlated with the location of the invasion site. Oligomers closer to the 5'-end of R also inhibited transfer, though less effectively, presumably by blocking strand exchange and branch migration. We propose that pausing of reverse transcriptase at the base of TAR increases RNase H cleavages, creating gaps for acceptor invasion and transfer initiation. Strand exchange then propagates by branch migration, displacing the fragmented donor RNA, including the fragment at the 5' terminus. The primer terminus switches to the acceptor, completing the transfer. Nucleocapsid (NC) protein stimulated transfer efficiency by 5-7-fold. NC enhanced RNase H cleavages close to the TAR base, creating more effective invasion sites for efficient transfer. Most likely, NC also stimulates transfer by promoting strand exchange invasion and branch migration.

Evidence for the differential effects of nucleocapsid protein on strand transfer in various regions of the HIV genome

An in vitro strand transfer assay that mimicked recombinational events occurring during reverse transcription in HIV-1 was used to assess the role of nucleocapsid protein (NC) in strand transfer. Strand transfer in highly structured nucleic acid species from the U3 3' long terminal repeats, gag-pol frameshift region, and Rev response element were strongly enhanced by NC. In contrast, weakly structured templates from the env and pol-vif regions transferred well without NC and showed lower enhancement. The lack of strong polymerase pause sites in the latter regions demonstrated that non-pause driven mechanisms could also promote transfer. Assays conducted using NC zinc finger mutants supported a differential role for the two fingers in strand transfer with finger 1 (N-terminal) being more important on highly structured RNAs. Overall this report suggests a role for structural intricacies of RNA templates in determining the extent of influence of NC on recombination and illustrates that strand transfer may occur by several different mechanisms depending on the structural nature of the RNA.

Evidence for a mechanism of recombination during reverse transcription dependent on the structure of the acceptor RNA

Genetic recombination is a major force driving retroviral evolution. In retroviruses, recombination proceeds mostly through copy choice during reverse transcription. Using a reconstituted in vitro system, we have studied the mechanism of strand transfer on a major recombination hot spot we previously identified within the genome of HIV-1. We show that on this model sequence the frequency of copy choice is strongly influenced by the folding of the RNA template, namely by the presence of a stable hairpin. This structure must be specifically present on the acceptor template. We previously proposed that strand transfer follows a two-step process: docking of the nascent DNA onto the acceptor RNA and strand invasion. The frequency of recombination under copy choice conditions was not dependent on the concentration of the acceptor RNA, in contrast with strand transfer occurring at strong arrests of reverse transcription. During copy choice strand transfer, the docking step is not rate limiting. We propose that the hairpin present on the acceptor RNA could mediate strand transfer following a mechanism reminiscent of branch migration during DNA recombination.

Template dimerization promotes an acceptor invasion-induced transfer mechanism during human immunodeficiency virus type 1 minus-strand synthesis

The biochemical mechanism of template switching by human immunodeficiency virus type 1 (HIV-1) reverse transcriptase and the role of template dimerization were examined. Homologous donor-acceptor template pairs derived from the HIV-1 untranslated leader region and containing the wild-type and mutant dimerization initiation sequences (DIS) were used to examine the efficiency and distribution of transfers. Inhibiting donor-acceptor interaction was sufficient to reduce transfers in DIS-containing template pairs, indicating that template dimerization, and not the mere presence of the DIS, promotes efficient transfers. Additionally, we show evidence that the overall transfer process spans an extended region of the template and proceeds through a two-step mechanism. Transfer is initiated through an RNase H-facilitated acceptor invasion step, while synthesis continues on the donor template. The invasion then propagates towards the primer terminus by branch migration. Transfer is completed with the translocation of the primer terminus at a site distant from the invasion point. In our system, most invasions initiated before synthesis reached the DIS. However, transfer of the primer terminus predominantly occurred after synthesis through the DIS. The two steps were separated by 60 to 80 nucleotides. Sequence markers revealed the position of primer terminus switch, whereas DNA oligomers designed to block acceptor-cDNA interactions defined sites of invasion. Within the region of homology, certain positions on the template were inherently more favorable for invasion than others. In templates with DIS, the proximity of the acceptor facilitates invasion, thereby enhancing transfer efficiency. Nucleocapsid protein enhanced the overall efficiency of transfers but did not alter the mechanism.

Dimerization and template switching in the 5' untranslated region between various subtypes of human immunodeficiency virus type 1

The human immunodeficiency virus type 1 (HIV-1) particle contains two identical RNA strands, each corresponding to the entire genome. The 5' untranslated region (UTR) of each RNA strand contains extensive secondary and tertiary structures that are instrumental in different steps of the viral replication cycle. We have characterized the 5' UTRs of nine different HIV-1 isolates representing subtypes A through G and, by comparing their homodimerization and heterodimerization potentials, found that complementarity between the palindromic sequences in the dimerization initiation site (DIS) hairpins is necessary and sufficient for in vitro dimerization of two subtype RNAs. The 5' UTR sequences were used to design donor and acceptor templates for a coupled in vitro dimerization-reverse transcription assay. We showed that template switching during reverse transcription is increased with a matching DIS palindrome and further stimulated proportional to the level of homology between the templates. The presence of the HIV-1 nucleocapsid protein NCp7 increased the template-switching efficiency for matching DIS palindromes twofold, whereas the recombination efficiency was increased sevenfold with a nonmatching palindrome. Since NCp7 did not effect the dimerization of nonmatching palindromes, we concluded that the protein most likely stimulates the strand transfer reaction. An analysis of the distribution of template-switching events revealed that it occurs throughout the 5' UTR. Together, these results demonstrate that the template switching of HIV-1 reverse transcriptase occurs frequently in vitro and that this process is facilitated mainly by template proximity and the level of homology.

Molecular basis of fidelity of DNA synthesis and nucleotide specificity of retroviral reverse transcriptases

Reverse transcription involves the conversion of viral genomic RNAinto proviral double-stranded DNA that integrates into the host cell genome. Cellular DNA polymerases replicate the integrated viral DNA and RNA polymerase II transcribes the proviral DNA into RNA genomes that are packaged into virions. Although mutations can be introduced at any of these replication steps, reverse transcriptase (RT) errors play a major role in retroviral mutation. This review summarizes our current knowledge on fidelity of reverse transcriptases. Estimates of retroviral mutation rates or fidelity of retroviral RTs are discussed in the context of the different techniques used for this purpose (i.e., retroviral vectors replicated in culture, misinsertion and mispair extension fidelity assay, etc.). In vitro fidelity assays provide information on the RT's accuracy during the elongation reaction of DNA synthesis. In addition, other steps such as initiation of reverse transcription, or strand transfer, and factors including viral proteins such as Vpr [in the case of the human immunodeficiency virus type 1 (HIV-1)] have been shown to influence fidelity. A comprehensive description of the effect of amino acid substitutions on the fidelity of HIV-1 RT is presented. Published data point to certain dNTP-binding residues, as well as to various amino acids involved in interactions with the template or the primer strand, and to residues in the minor groove-binding track as major components of the fidelity center of retroviral RTs. Implications of these studies include the design of novel therapeutic strategies leading to virus extinction, by increasing the viral mutation rate beyond a tolerable threshold.