Retroviral recombination during reverse transcription

The power of "controllers": Transposon-mediated duplicated genes evolve towards neofunctionalization

Since the discovery of the first transposon by Dr. Barbara McClintock, the prevalence and diversity of transposable elements (TEs) have been gradually recognized. As fundamental genetic components, TEs drive organismal evolution not only by contributing functional sequences (e.g., regulatory elements or "controllers" as phrased by Dr. McClintock) but also by shuffling genomic sequences. In the latter respect, TE-mediated gene duplications have contributed to the origination of new genes and attracted extensive interest. In response to the development of this field, we herein attempt to provide an overview of TE-mediated duplication by focusing on common rules emerging across duplications generated by different TE types. Specifically, despite the huge divergence of transposition machinery across TEs, we identify three common features of various TE-mediated duplication mechanisms, including end bypass, template switching, and recurrent transposition. These three features lead to one common functional outcome, namely, TE-mediated duplicates tend to be subjected to exon shuffling and neofunctionalization. Therefore, the intrinsic properties of the mutational mechanism constrain the evolutionary trajectories of these duplicates. We finally discuss the future of this field including an in-depth characterization of both the duplication mechanisms and functions of TE-mediated duplicates.

Genomic fossils reveal adaptation of non-autonomous pararetroviruses driven by concerted evolution of noncoding regulatory sequences

The interplay of different virus species in a host cell after infection can affect the adaptation of each virus. Endogenous viral elements, such as endogenous pararetroviruses (PRVs), have arisen from vertical inheritance of viral sequences integrated into host germline genomes. As viral genomic fossils, these sequences can thus serve as valuable paleogenomic data to study the long-term evolutionary dynamics of virus-virus interactions, but they have rarely been applied for this purpose. All extant PRVs have been considered autonomous species in their parasitic life cycle in host cells. Here, we provide evidence for multiple non-autonomous PRV species with structural defects in viral activity that have frequently infected ancient grass hosts and adapted through interplay between viruses. Our paleogenomic analyses using endogenous PRVs in grass genomes revealed that these non-autonomous PRV species have participated in interplay with autonomous PRVs in a possible commensal partnership, or, alternatively, with one another in a possible mutualistic partnership. These partnerships, which have been established by the sharing of noncoding regulatory sequences (NRSs) in intergenic regions between two partner viruses, have been further maintained and altered by the sequence homogenization of NRSs between partners. Strikingly, we found that frequent region-specific recombination, rather than mutation selection, is the main causative mechanism of NRS homogenization. Our results, obtained from ancient DNA records of viruses, suggest that adaptation of PRVs has occurred by concerted evolution of NRSs between different virus species in the same host. Our findings further imply that evaluation of within-host NRS interactions within and between populations of viral pathogens may be important.

Quantification of the Latent HIV-1 Reservoir Using Ultra Deep Sequencing and Primer ID in a Viral Outgrowth Assay

BACKGROUND

In this study, we measured the latent HIV-1 reservoir harboring replication-competent HIV-1 in resting CD4 T cells in participants on highly active antiretroviral therapy, quantitating the frequency of latent infection through the use of a Primer ID-based Ultra Deep Sequencing Assay (UDSA), in comparison to the readout of the quantitative viral outgrowth assay (QVOA).

METHODS

Viral RNA derived from culture wells of QVOA that scored as HIV-1 p24 capsid antigen positive were tagged with a specific barcode during cDNA synthesis, and the sequences within the V1-V3 region of the HIV-1 env gene were analyzed for diversity using the Primer ID-based paired-end MiSeq platform. We analyzed samples from a total of 19 participants, 2 initially treated with highly active antiretroviral therapy in acute infection and 17 treated during chronic infection. Phylogenetic trees were generated with all viral lineages detected from culture wells derived from each participant to determine the number of distinct viral lineages growing out in each well, thus capturing another level of information beyond the well being positive for viral antigen. The infectious units per million (IUPM) cell values estimated using a maximum likelihood approach, based on the number of distinct viral lineages detected (VOA-UDSA), were compared with those obtained from QVOA measured using limiting dilution.

RESULTS

IUPM estimates determined by VOA-UDSA ranged from 0.14 to 3.66 and strongly correlated with the IUPM estimates determined by QVOA (r = 0.94; P < 0.0001).

CONCLUSIONS

VOA-UDSA may be an alternative readout for that currently used for QVOA.

LTR-mediated retroposition as a mechanism of RNA-based duplication in metazoans

In a broad range of taxa, genes can duplicate through an RNA intermediate in a process mediated by retrotransposons (retroposition). In mammals, L1 retrotransposons drive retroposition, but the elements responsible for retroposition in other animals have yet to be identified. Here, we examined young retrocopies from various animals that still retain the sequence features indicative of the underlying retroposition mechanism. In Drosophila melanogaster, we identified and de novo assembled 15 polymorphic retrocopies and found that all retroposed loci are chimeras of internal retrocopies flanked by discontinuous LTR retrotransposons. At the fusion points between the mRNAs and the LTR retrotransposons, we identified shared short similar sequences that suggest the involvement of microsimilarity-dependent template switches. By expanding our approach to mosquito, zebrafish, chicken, and mammals, we identified in all these species recently originated retrocopies with a similar chimeric structure and shared microsimilarities at the fusion points. We also identified several retrocopies that combine the sequences of two or more parental genes, demonstrating LTR-retroposition as a novel mechanism of exon shuffling. Finally, we found that LTR-mediated retrocopies are immediately cotranscribed with their flanking LTR retrotransposons. Transcriptional profiling coupled with sequence analyses revealed that the sense-strand transcription of the retrocopies often lead to the origination of in-frame proteins relative to the parental genes. Overall, our data show that LTR-mediated retroposition is highly conserved across a wide range of animal taxa; combined with previous work from plants and yeast, it represents an ancient and ongoing mechanism continuously shaping gene content evolution in eukaryotes.

TE-Tracker: systematic identification of transposition events through whole-genome resequencing

Background

Transposable elements (TEs) are DNA sequences that are able to move from their location in the genome by cutting or copying themselves to another locus. As such, they are increasingly recognized as impacting all aspects of genome function. With the dramatic reduction in cost of DNA sequencing, it is now possible to resequence whole genomes in order to systematically characterize novel TE mobilization in a particular individual. However, this task is made difficult by the inherently repetitive nature of TE sequences, which in some eukaryotes compose over half of the genome sequence. Currently, only a few software tools dedicated to the detection of TE mobilization using next-generation-sequencing are described in the literature. They often target specific TEs for which annotation is available, and are only able to identify families of closely related TEs, rather than individual elements.

Results

We present TE-Tracker, a general and accurate computational method for the de-novo detection of germ line TE mobilization from re-sequenced genomes, as well as the identification of both their source and destination sequences. We compare our method with the two classes of existing software: specialized TE-detection tools and generic structural variant (SV) detection tools. We show that TE-Tracker, while working independently of any prior annotation, bridges the gap between these two approaches in terms of detection power. Indeed, its positive predictive value (PPV) is comparable to that of dedicated TE software while its sensitivity is typical of a generic SV detection tool. TE-Tracker demonstrates the benefit of adopting an annotation-independent, de novo approach for the detection of TE mobilization events. We use TE-Tracker to provide a comprehensive view of transposition events induced by loss of DNA methylation in Arabidopsis. TE-Tracker is freely available at http://www.genoscope.cns.fr/TE-Tracker.

Conclusions

We show that TE-Tracker accurately detects both the source and destination of novel transposition events in re-sequenced genomes. Moreover, TE-Tracker is able to detect all potential donor sequences for a given insertion, and can identify the correct one among them. Furthermore, TE-Tracker produces significantly fewer false positives than common SV detection programs, thus greatly facilitating the detection and analysis of TE mobilization events.

Electronic supplementary material

The online version of this article (doi:10.1186/s12859-014-0377-z) contains supplementary material, which is available to authorized users.

Recombination form and epidemiology of HIV-1 unique recombinant strains identified in Yunnan, China

Several studies identified HIV-1 recombination in some distinct areas in Yunnan, China. However, no comprehensive studies had been fulfilled in the whole province up to now. To illustrate the epidemiology and recombination form of Unique Recombinant Forms (URFs) circulating in Yunnan, 788 HIV-1 positive individuals residing in 15 prefectures of Yunnan were randomly enrolled into the study. Full-length gag and pol genes were amplified and sequenced. Maximum likelihood tree was constructed for phylogenetic analysis. Recombinant breakpoints and genomic schematics were identified with online software jpHMM. 63 (10.2%) unique recombinant strains were identified from 617 strains with subtypes. The URFs distributed significantly differently among prefectures (Pearson chi-square test, P<0.05). IDUs contained more URFs than sexual transmitted population (Pearson chi-square test, P<0.05). Two main recombinant forms were identified by considering the presence of CRF01_AE segments in full length gag-pol genes, which were B′/C and B′/C/CRF01-AE recombinants. Three clusters were identified in the ML tree which contained more than three sequences and supported by high bootstrap values. One CRF was identified. Many of URFs contained identical breakpoints. The results will contribute to our understanding on HIV recombination and provide clues to the identification of potential CRFs in China.

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.

The evolution of HIV: inferences using phylogenetics

Molecular phylogenetics has revolutionized the study of not only evolution but also disparate fields such as genomics, bioinformatics, epidemiology, ecology, microbiology, molecular biology and biochemistry. Particularly significant are its achievements in population genetics as a result of the development of coalescent theory, which have contributed to more accurate model-based parameter estimation and explicit hypothesis testing. The study of the evolution of many microorganisms, and HIV in particular, have benefited from these new methodologies. HIV is well suited for such sophisticated population analyses because of its large population sizes, short generation times, high substitution rates and relatively small genomes. All these factors make HIV an ideal and fascinating model to study molecular evolution in real time. Here we review the significant advances made in HIV evolution through the application of phylogenetic approaches. We first examine the relative roles of mutation and recombination on the molecular evolution of HIV and its adaptive response to drug therapy and tissue allocation. We then review some of the fundamental questions in HIV evolution in relation to its origin and diversification and describe some of the insights gained using phylogenies. Finally, we show how phylogenetic analysis has advanced our knowledge of HIV dynamics (i.e., phylodynamics).

Analysing recombination in nucleotide sequences

Throughout the living world, genetic recombination and nucleotide substitution are the primary processes that create the genetic variation upon which natural selection acts. Just as analyses of substitution patterns can reveal a great deal about evolution, so too can analyses of recombination. Evidence of genetic recombination within the genomes of apparently asexual species can equate with evidence of cryptic sexuality. In sexually reproducing species, nonrandom patterns of sequence exchange can provide direct evidence of population subdivisions that prevent certain individuals from mating. Although an interesting topic in its own right, an important reason for analysing recombination is to account for its potentially disruptive influences on various phylogenetic-based molecular evolution analyses. Specifically, the evolutionary histories of recombinant sequences cannot be accurately described by standard bifurcating phylogenetic trees. Taking recombination into account can therefore be pivotal to the success of selection, molecular clock and various other analyses that require adequate modelling of shared ancestry and draw increased power from accurately inferred phylogenetic trees. Here, we review various computational approaches to studying recombination and provide guidelines both on how to gain insights into this important evolutionary process and on how it can be properly accounted for during molecular evolution studies.

Accuracy estimation of foamy virus genome copying

BACKGROUND

Foamy viruses (FVs) are the most genetically stable viruses of the retrovirus family. This is in contrast to the in vitro error rate found for recombinant FV reverse transcriptase (RT). To investigate the accuracy of FV genome copying in vivo we analyzed the occurrence of mutations in HEK 293T cell culture after a single round of reverse transcription using a replication-deficient vector system. Furthermore, the frequency of FV recombination by template switching (TS) and the cross-packaging ability of different FV strains were analyzed.

RESULTS

We initially sequenced 90,000 nucleotides and detected 39 mutations, corresponding to an in vivo error rate of approximately 4 x 10-4 per site per replication cycle. Surprisingly, all mutations were transitions from G to A, suggesting that APOBEC3 activity is the driving force for the majority of mutations detected in our experimental system. In line with this, we detected a late but significant APOBEC3G and 3F mRNA by quantitative PCR in the cells. We then analyzed 170,000 additional nucleotides from experiments in which we co-transfected the APOBEC3-interfering foamy viral bet gene and observed a significant 50% drop in G to A mutations, indicating that APOBEC activity indeed contributes substantially to the foamy viral replication error rate in vivo. However, even in the presence of Bet, 35 out of 37 substitutions were G to A, suggesting that residual APOBEC activity accounted for most of the observed mutations. If we subtract these APOBEC-like mutations from the total number of mutations, we calculate a maximal intrinsic in vivo error rate of 1.1 x 10-5 per site per replication. In addition to the point mutations, we detected one 49 bp deletion within the analyzed 260000 nucleotides.Analysis of the recombination frequency of FV vector genomes revealed a 27% probability for a template switching (TS) event within a 1 kilobase (kb) region. This corresponds to a 98% probability that FVs undergo at least one additional TS event per replication cycle. We also show that a given FV particle is able to cross-transfer a heterologous FV genome, although at reduced efficiency than the homologous vector.

CONCLUSION

Our results indicate that the copying of the FV genome is more accurate than previously thought. On the other hand recombination among FV genomes appears to be a frequent event.

Recombination analysis and structure prediction show correlation between breakpoint clusters and RNA hairpins in the pol gene of human immunodeficiency virus type 1 unique recombinant forms

Recombination is recognized as a primary force in human immunodeficiency virus type 1 (HIV-1) evolution, increasing viral diversity through reshuffling of genomic portions. The strand-switching activity of reverse transcriptase is required to complete HIV-1 replication and can occur randomly throughout the genome, leading to viral recombination. Some recombination hotspots have been identified and found to correlate with RNA structure or sequence features. The aim of this study was to evaluate the presence of recombination hotspots in the pol gene of HIV-1 and to assess their correlation with the underlying RNA structure. Analysis of the recombination pattern and breakpoint distribution in a group of unique recombinant forms (URFs) detected two recombination hotspots in the pol region. Two stable and conserved hairpins were consistently predicted corresponding to the identified hotspots using six different RNA-folding algorithms on the URF parental strains. These findings suggest that such hairpins may play a role in the higher recombination rates detected at these positions.

Murine retroviral but not human cellular promoters induce in vivo erythroid-specific deregulation that can be partially prevented by insulators

We are developing lentiviral vectors for gene therapy of red blood cell disorders that co-express a transgene in an erythroid-specific manner and the O(6)-methylguanine-DNA-methyltransferase (MGMT) selective gene in a constitutive way. We report that transduction of murine hematopoietic stem cells (HSCs) with a human phosphoglycerate kinase promoter-based vector at low multiplicity of infection (MOI) does not result in a selective in vivo expansion in the presence of alkylating agents. In contrast, by replacing this cellular promoter with the powerful retroviral-derived myeloproliferative sarcoma virus enhancer, negative control region-deleted, dl587rev primer-binding site substituted promoter, the vector allowed efficient chemoprotection of transduced HSCs at low MOI. However, this promoter interacted with the erythroid HS40/ankyrin enhancer/promoter driving green fluorescent protein, leading to an unexpected loss of erythroid specificity. A partial restoration of tissue-specific expression was obtained by interposition of insulator sequences between the expression units. Alternatively, we found that the strong human cellular elongation factor1-alpha promoter allows similar chemoprotection but without any deregulation of the erythroid-specific promoter in the absence of insulators. These data demonstrate that the level of in vivo deregulation induced by a promoter is not correlated with its transcriptional activity.

Apparent defects in processive DNA synthesis, strand transfer, and primer elongation of Met-184 mutants of HIV-1 reverse transcriptase derive solely from a dNTP utilization defect

The 2',3'-dideoxy-3'-thiacytidine drug-resistant M184I HIV-1 reverse transcriptase (RT) has been shown to synthesize DNA with decreased processivity compared with the wild-type RT. M184A displays an even more severe processivity defect. However, the basis of this decreased processivity has been unclear, and both primer-template binding and dNTP interaction defects have been proposed to account for it. In this study, we show that the altered properties of the M184I and M184A RT mutants that we have measured, including decreased processivity, a slower rate of primer extension, and increased strand transfer activity, can all be explained by a defect in dNTP utilization. These alterations are observed only at low dNTP concentration and vanish as the dNTP concentration is raised. The mutant RTs exhibit a normal dissociation rate from a DNA primer-RNA template while paused during synthesis. Slower than normal synthesis at physiological dNTP concentration, coupled with normal dissociation from the primer-template, results in the lowered processivity. The mutant RTs exhibit normal DNA 3'-end-directed and RNA 5'-end-directed ribonuclease H activity. The reduced rate of DNA synthesis causes an increase in the ratio of ribonuclease H to polymerase activity thereby promoting increased strand transfer. These latter results are consistent with an observed higher rate of recombination by HIV-1 strains with Met-184 mutations.

Ezetimibe, a promising lipid-lowering agent for the treatment of dyslipidaemia in HIV-infected patients with poor response to statins

OBJECTIVE

To assess the efficacy, safety, and pharmacokinetic interactions of ezetimibe in HIV-infected patients with poorly controlled antiretroviral-associated dyslipidaemia while taking pravastatin alone.

DESIGN

A prospective, open-label, one-arm study of 24 weeks duration.

PATIENTS AND SETTING

Nineteen patients (18 on stable HAART), with low density lipoprotein (LDL)-cholesterol values of > or = 130 mg/dl despite the use of pravastatin.

METHODS

Ezetimibe, 10 mg/day, was added to pravastatin 20 mg/day, while patients maintained the same antiretroviral regimen. Determinations of total, LDL-, and high density lipoprotein (HDL)-cholesterol, triglycerides, apoproteins, and inflammatory factors (homocystein and C-reactive protein) were performed at baseline, and at weeks 6, 12, and 24. Liver enzymes and creatinine phosphokinase were also assessed. Protease inhibitor (PI) or non-nucleoside reverse transcriptase inhibitor (NNRTI) Cmin was determined just before and 12 weeks after ezetimibe introduction.

RESULTS

At week 24, 61.5% of patients achieved the endpoint of the study (LDL-cholesterol < 130 mg/dl). Significant declines in mean total and LDL-cholesterol levels were observed between baseline and weeks 6, 12, and 24, irrespective of antiretroviral type (PI or NNRTI). Mean HDL-cholesterol and apoprotein A increased significantly. No patients discontinued therapy due to intolerance or presented toxicity of grade 2 or more. No differences were observed in lopinavir or nevirapine Cmin measured just before and 12 weeks after ezetimibe introduction.

CONCLUSION

The addition of ezetimibe to ongoing pravastatin seems to be an effective and safe option for HIV-infected patients not achieving the NCEP ATPIII LDL-cholesterol goals while receiving a statin alone. Its high tolerability and the lack of interactions with the cytochrome CYP3A4 indicate that ezetimibe will not increase the risk of toxicity or pharmacokinetic interactions with antiretrovirals.

Using RT-prone recombination to promote re-building of complete retroviral vectors from two defective precursors: low efficiency and sequence specificities

Retroviral recombination has been suggested as a useful way to modify retroviral vectors. The possibility to combine two multiply deleted retroviral vectors into a novel vector was evaluated. To investigate this possibility we have constructed two defective vectors containing a shared internal ribosome entry site (IRES). The IRES was selected for its complex secondary structure, a feature described to favour retroviral recombination. The IRES was expected to promote a recombination event leading to the formation of a unique, functional retroviral vector. By supporting expression of two transgenes from a single promoter, this sequence was also expected to allow straightforward detection of the recombination event. The present data confirms the achievement of recombination-dependent rescue, albeit at low efficiency. Unexpectedly, a preferential use of the packaging signal (Psi) for recombination was observed, as compared to the IRES. Together these observations mitigate the idea of using this technique for the design of retroviral vectors.

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.

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.

Each genomic RNA in HIV-1 heterozygous virus generate new virions

Retrovirus are unique because they present two complete copies of the genomic RNA in each virion. It is believed that only one proviral DNA is formed from the two genomic RNAs. To check this hypothesis, we constructed two deleterious HIV-1 variants in gag gene which upon transfection in Cos-1 cells were able, by complementation, to form heterozygous viruses, used to infect MT4 cells in a plaque assay. Analysis of the proviral DNA of the eight plaques obtained indicated that five were recombinants between the two deleterious mutants. Three other plaques showed three bands corresponding to the reverse transcription of both strands of one heterozygous virion and to the recombination of the two genomes. These results demonstrate that the two genomic RNAs in HIV-1 heterozygous virions could be used in the generation of new viruses. This mechanism permits the recovery of deleterious mutants and enhances the evolutive potential of HIV-1.

Detection of a novel sense-antisense RNA-hybrid structure by RACE experiments on endogenous troponin I antisense RNA

Conformational changes in the troponin/tropomyosin complex significantly alter the mechanical properties of cardiac muscle. Phosphorylation of cardiac troponin I, part of the troponin/tropomyosin complex, reduces calcium affinity, which leads to increased relaxation of cardiac muscle. Because cardiac troponin I plays a central role in tuning the heart to different work demands, detailed knowledge of troponin I protein regulation is required. Our group previously detected naturally occurring antisense RNA for troponin I in human and rat hearts, and here, attempt to unravel the structure of rat cardiac troponin I antisense RNA. We performed rapid amplification of cDNA ends (RACE) experiments and discovered antisense sequences identical to a copy of the sense mRNA, which led us to conclude that the antisense RNA must be transcribed from troponin I mRNA in the cytoplasm. Moreover, we isolated RNA structures comprising sense and antisense sequences in one continuous molecule. As we found no homolog structures described in the literature, we called this "hybrid RNA." Because a duplex formation was demonstrated previously we concluded that hybrid RNA is a consequence of a tight interaction between sense and antisense troponin I RNA in vivo, which we discuss in the article.

High prevalence of diverse forms of HIV-1 intersubtype recombinants in Central Myanmar: geographical hot spot of extensive recombination

OBJECTIVES

To investigate the molecular epidemiology and genetic structure of HIV-1s causing the epidemic in Central Myanmar and to explore the genesis of HIV epidemic in this area.

DESIGN

A molecular epidemiological investigation was conducted in 1999-2000 in the city of Mandalay among high-risk populations and the structural features of circulating HIV-1s were analyzed.

METHODS

HIV-1 genotypes of 59 specimens were screened based on gag (p17) and env (C2/V3) regions. Near full-length nucleotide sequences of HIV-1 isolates with subtype discordance were determined and their recombinant structures were characterized.

RESULTS

Three lineages of HIV-1 strains, including CRF01_AE (27, 45.8%), subtype B' (Thailand variant of subtype B) (15, 25.4%) and subtype C (8, 13.6%), were distributed in Mandalay, while substantial portions (9, 15.3%) of specimens showed various patterns of subtype discordance in different regions of HIV-1 genomes. The study on six HIV-1 isolates with subtype discordance revealed that they were highly diverse types of unique recombinant forms (URFs) comprised of various combinations of three circulating subtypes. One URF was a particularly complex mosaic that contained 13 recombination breakpoints between three HIV-1 subtypes. Approximately half of recombinants showed 'pseudotype' virion structures, in which the external portions of envelope glycoproteins were exchanged with different lineages of HIV-1 strains, suggesting the potential selective advantage of 'pseudotype' viruses over parental strains.

CONCLUSION

The study revealed the unique geographical hot spot in Central Myanmar where extensive recombination events appeared to be taking place continually. This reflects the presence of highly exposed individuals and social networks of HIV-1 transmission.

Role of the Reverse Transcriptase, Nucleocapsid Protein, and Template Structure in the Two-step Transfer Mechanism in Retroviral Recombination

Template switching during reverse transcription promotes recombination in retroviruses. Efficient switches have been measured in vitro on hairpin-containing RNA templates by a two-step mechanism. Pausing of the reverse transcriptase (RT) at the hairpin base allowed enhanced cleavage of the initial donor RNA template, exposing regions of the cDNA and allowing the acceptor to base pair with the cDNA. This defines the first or docking step. The primer continued synthesis on the donor, transferring or locking in a second step. Here we determine the enzyme-dependent factors that influence template switching by comparing the RTs from human immunodeficiency virus, type 1 (HIV-1), and equine infectious anemia virus (EIAV). HIV-1 RT promoted transfers with higher efficiency than EIAV RT. We found that both RTs paused strongly at the base of the hairpin. While stalled, HIV-1 RT made closely spaced cuts, whereas EIAV RT made only a single cut. Docking occurred efficiently at the multiply cut but not at the singly cut site. HIV-1 nucleocapsid (NC) protein stimulated strand transfers. It improved RNase H activity of both RTs. It allowed the EIAV RT to make a distribution of cuts, greatly stimulating docking at the base of the hairpin. Most likely, it also promoted strand exchange, allowing transfers to be initiated from sites throughout the hairpin. Minor pause sites beyond the base of the hairpin correlated with the locking sites. The strand exchange properties of NC likely promote this step. We present a model that explains the roles of RNase H specificity, template structure, and properties of NC in the two-step transfer reaction.

Strand transfer occurs in retroviruses by a pause-initiated two-step mechanism

Recombination promotes retrovirus evolution. It involves transferring a growing DNA primer from one genomic RNA template in the virus to the other. Strand transfer results in vitro suggested that pausing of the reverse transcriptase during synthesis allows enhanced RNase H cleavage of the initial, or donor, RNA template that facilitates primer interaction with the acceptor template. Hairpins are common structures in retrovirus RNAs that induce pausing. Analyzing primer transfers in hairpins by base substitution markers showed transfer sites well beyond the site of pausing. We developed methods to distinguish the initial site of primer-acceptor template interaction from the site of primer terminus transfer. The strand transfer mechanism was confirmed to involve two steps. In the first, the acceptor template invades the primer-donor complex. However, the primer terminus continues elongation on the donor RNA. The interacting primer and acceptor strands then propagate by branch migration to catch the advancing primer terminus. Some distance downstream of the invasion site the primer terminus transfers, marking the genetic shift from donor to acceptor. Nucleocapsid protein (NC) is known to influence primer elongation and strand exchange. The presence of NC increased the efficiency of transfers but did not appear to alter the fundamental transfer mechanism.

In vitro intersubtype recombinants of human immunodeficiency virus type 1: comparison to recent and circulating in vivo recombinant forms

The increased prevalence of human immunodeficiency virus type 1 (HIV-1) intersubtype recombinants (ISRs) is shaping HIV-1 evolution throughout the world and will have an impact on both therapeutic and vaccine strategies. This study was designed to generate and compare in vitro ISRs to those isolated from HIV-infected individuals throughout the world. Human peripheral blood mononuclear cells were dually infected with seven pairs of HIV-1 isolates from different subtypes (i.e., A to F). Recombinant crossover sites were mapped to specific regions in the envelope (env) gene by using a cloning-hybridization technique and subtype-specific probes. In vitro intersubtype recombination was at least twofold more frequent in the V1-to-V3 region than in any other env fragment, i.e., C1 to V1, V3 to V5, or V5 to gp41. Sequence and recombination site analyses suggested the C2 env domain as a "hot region" for recombination and selection of replication-competent ISRs during the 15-day incubation. In addition to these regional preferences for env recombination, homopolymeric nucleotide tracts, i.e., sequences known to pause reverse transcriptase and promote template switching, were found in most in vitro crossover sites. ISRs, originating from recent dual infections and limited transmission events, partly retained this in vitro regional or sequence preference for recombination sites. However, a shift to crossover sites flanking the gp120-coding sequence was evident in the stable circulating recombinant forms of HIV-1. Based on these findings, HIV-1 recombinants generated from these dual infections may be used as a model for in vivo intersubtype recombination and for the design of various diagnostic assays and vaccine constructs.

Development of virus vectors for gene therapy of beta chain hemoglobinopathies: flanking with a chromatin insulator reduces gamma-globin gene silencing in vivo

We have previously described the development of oncoretrovirus vectors for human gamma-globin using a truncated beta-globin promoter, modified gamma-globin cassette, and alpha-globin enhancer. However, one of these vectors is genetically unstable, and both vectors exhibit variable expression patterns in cultured cells, common characteristics of oncoretrovirus vectors for globin genes. To address these problems, we identified and removed the vector sequences responsible for genetic instability and flanked the resultant vector with the chicken beta-globin HS4 chromatin insulator to protect expression from chromosomal position effects. After determining that flanking with the cHS4 element allowed higher, more uniform levels of gamma-globin expression in MEL cell lines, we tested these vectors using a mouse bone marrow transduction and transplantation model. When present, the gamma-globin cassettes from the uninsulated vectors were expressed in only 2% to 5% of red blood cells (RBCs) long term, indicating they are highly sensitive to epigenetic silencing. In contrast, when present the gamma-globin cassette from the insulated vector was expressed in 49% +/- 20% of RBCs long term. RNase protection analysis indicated that the insulated gamma-globin cassette was expressed at 23% +/- 16% per copy of mouse alpha-globin in transduced RBCs. These results demonstrate that flanking a globin vector with the cHS4 insulator increases the likelihood of expression nearly 10-fold, which in turn allows for gamma-globin expression approaching the therapeutic range for sickle cell anemia and beta thalassemia.

Topological constraints governing the use of the chicken HS4 chromatin insulator in oncoretrovirus vectors

The expression of integrated oncoretrovirus vectors is subject to the inhibitory effects of surrounding chromatin. A previous report from our laboratory indicated that such position effects can be overcome by flanking a reporter vector with the cHS4 chromatin insulator. To characterize this activity more thoroughly, we switched the promoter-gene combinations in the reporter vector and analyzed expression of these vectors flanked with the cHS4 fragment in both orientations following bone marrow transduction and transplantation in mice. The results indicate that the cHS4 fragment can function in both orientations and can insulate both the virus long-terminal-repeat (LTR) promoter and an internal phosphoglycerate kinase (Pgk) promoter. However, insulation of the LTR promoter diminished when the orientation of the cHS4 fragment placed the CTCF-binding core element immediately proximal to the U3 region, suggesting a minimal distance requirement. Moreover, placement of the cHS4 fragment in the U3 region of the 3' LTR dramatically decreased the level of expression from an internal Pgk promoter, presumably by blocking interaction with the 3' LTR enhancer. Finally, sorting studies suggest that the severity of position effects or autonomous promoter silencing increases as transduced progenitors differentiate into mature progeny. These findings have direct implications for the use of chromatin insulators such as cHS4 in oncoretrovirus vectors.

Differential inhibition of polymerase and strand-transfer activities of HIV-1 reverse transcriptase

A new class of inhibitors of HIV-1 reverse transcriptase obtained by the systematic structural simplification of epicatechin and epigallocatechin gallates are also shown here to inhibit DNA-strand-transfer, a process critical to the completion of the HIV-1-RT reproduction and to recombination-associated mutation of the virus. Up to 80-fold selectivity for DNA-strand-transfer inhibition over polymerase inhibition was observed for a defined subset of these agents. Such specific DNA-strand-transfer inhibitors may have important therapeutic potential.

The kissing hairpin sequence promotes recombination within the HIV-I 5' leader region

The role of RNA-RNA template interactions in facilitating recombination during reverse transcription of minus strand DNA has been examined. The tested hypothesis is that template switching by reverse transcriptase is promoted at sites where homologous regions of two RNAs are brought in close proximity via stable intertemplate interactions. Frequency and distribution of template switching between homologous donor and acceptor RNAs were examined within the human immunodeficiency virus type I (HIV-I) 5'-untranslated region (UTR) containing the dimer initiation sequence (DIS). Results were compared with control nondimerizing templates from the pol region. The dimerizing UTR templates displayed a 4-fold higher transfer efficiency than the control. A striking 53% of transfers in the UTR mapped near the DIS, of which two-thirds occurred immediately 5' to this sequence. In the UTR template, deletion of the DIS hairpin disrupted template dimerization and caused a 4-fold drop in transfer efficiency. Insertion of the DIS within the pol template increased both dimerization and transfer efficiency. Transfer distributions revealed that in both sets of templates, DIS-induced dimerization increased the efficiency of transfers across the whole template, with the transfers peaking around the dimerization site. Overall, these results suggest that template dimerization facilitated by the unique geometry of the DIS-promoted kissing interactions effectively promotes recombination within the HIV-I 5'-UTR.

Retroviral recombination: what drives the switch?

The high rate of recombination in retroviruses is due to the frequent template switching that occurs during reverse transcription. Although the mechanism that leads to this switch is still a matter of debate, there is increasing evidence that specific RNA structures are involved. And the implications might go beyond retroviral genetic variability.

Homologous recombination between different genotypes of hepatitis B virus

Phylogenetic analysis was used to examine the evolutionary relationships among 99 complete HBV sequences. Analysis revealed nine viral genomes clustered with different genotypes depending on genome region analyzed. This discordance indicated that recombination events occurred during HBV history. The putative breakpoints between genomes of different genotypes have been mapped. Six mosaic genomes representing B/C hybrids were isolated in East Asia and three A/D hybrids in Italy. At least some recombinant strains appear to be fully viable and possess high evolutionary potential. As a result, B/C recombinants overspread through the East Asia region. They were found among the isolates from Japan, China and Indonesia. Our results suggest that recombination is a significant and relatively frequent event in the evolution of HBV genome. A possible mechanism and the implications of recombination for the natural history of HBV, clinically important properties, and phylogenetic reconstruction are discussed.

Genetic reassortment and patch repair by recombination in retroviruses

Retroviral particles contain a diploid RNA genome which serves as template for the synthesis of double-stranded DNA in a complex process guided by virus-encoded reverse transcriptase. The dimeric nature of the genome allows the proceeding polymerase to switch templates during copying of the copackaged RNA molecules, leading to the generation of recombinant proviruses that harbor genetic information derived from both parental RNAs. Template switching abilities of reverse transcriptase facilitate the development of mosaic retroviruses with altered functional properties and thereby contribute to the restoration and evolution of retroviruses facing altering selective forces of their environment. This review focuses on the genetic patchwork of retroviruses and how mixing of sequence patches by recombination may lead to repair in terms of re-established replication and facilitate increased viral fitness, enhanced pathogenic potential, and altered virus tropisms. Endogenous retroelements represent an affluent source of functional viral sequences which may hitchhike with virions and serve as sequence donors in patch repair. We describe here the involvement of endogenous viruses in genetic reassortment and patch repair and review important examples derived from cell culture and animal studies. Moreover, we discuss how the patch repair phenomenon may challenge both safe usage of retrovirus-based gene vehicles in human gene therapy and the use of animal organs as xenografts in humans. Finally, the ongoing mixing of distinct human immunodeficiency virus strains and its implications for antiviral treatment is discussed.

Recombinant retrovirus vectors for the expression of MHC class II heterodimers

Class II antigens are critical in determining the fate of vascularized allografts across major histocompatibility differences. We have recently developed a new approach to induce transplantation tolerance in miniature swine by creating MHC class II antigen "molecular chimerism" in bone marrow cells of potential recipients through retrovirus-mediated gene transfer. As part of this project, the ability of a recombinant double-expression vector (ZQ32N) to express MHC class II DQA and DQB was investigated. Flow cytometry analyses of ZQ32N transfected virus-producer cells demonstrated the cell surface expression of DQa/DQb heterodimers, thus suggesting a correct transcription, translation, and transport of the swine polypeptides to the cell surface. The analyses of RNA isolated from virus particles produced from ZQ32N transfected virus-producer cells indicated the DQ sequences to be correctly packaged. However, the DQ-negative cells transduced with the ZQ32N retrovirus did not show any DQ-retrovirus surface expression. Southern and Northern blot analyses of ZQ32N transfected and transduced cells strongly suggested DNA rearrangements and deletions which could account for transgene expression loss. An analysis of transduced cell genomes suggested DNA recombinations targeted to homologous sequences within the recombinant provirus. The implications of the sequence instability in designing vectors for gene therapy of organ transplantation are discussed.

Genetic analysis of the rat leukemia virus: influence of viral sequences in transduction of the c-ras proto-oncogene and expression of its transforming activity

The rat leukemia virus (RaLV) is an endogenous retrovirus that is spontaneously released by Sprague-Dawley rat embryo cells. The overall structure of the RaLV genome resembles that of other simple, replication-competent retroviruses, but the sequence of the long terminal repeats (LTR) is unique and unrelated to the known retroviruses. Phylogenetically, the RaLV genome appears to be more closely related to the feline leukemia virus group of retroviruses than to the murine leukemia virus group. A remarkable feature of RaLV is that it is capable of transducing a ras proto-oncogene from rat tumor cells in the form of an acutely transforming virus, designated the Rasheed strain of the rat sarcoma virus (RaSV). With the exception of the c-ras sequence, the genomes of both RaLV and RaSV are collinear. The RaSV-encoded oncogene v-Ra-ras expresses a fusion protein with a molecular mass of 29 kDa, and it exhibits a unique structure that has not been described previously for any known virus. The 5' end of this gene is derived from sequences encoding RaLV matrix followed by 20 bp derived from the U5 region of the RaLV LTR (RS-U5 element) which is joined at its 3' end to sequences derived from all six (coding and noncoding) exons of the c-ras proto-oncogene at the 3' end. This recombinational event represents a novel mechanism among the acutely transforming viruses that have been studied.

Pausing of reverse transcriptase on retroviral RNA templates is influenced by secondary structures both 5' and 3' of the catalytic site

In the most extensive examination to date of the relationship between the pausing of reverse transcrip-tase (RT) and RNA secondary structures, pause events were found to be correlated to inverted repeats both ahead of, and behind the catalytic site in vitro. In addition pausing events were strongly associated with polyadenosine sequences and to a lesser degree diadenosines and monoadenosine residues. Pausing was also inversely proportional to the potential bond strength between the nascent strand and the template at the point of termination, for both mono and dinucleotides. A run of five adenosine and four uridine residues caused most pausing on the HIV-1 template, a region which is the site of much sequence heterogeneity in HIV-1. We propose that homopolyadenosine tracts can act as termination signals for RT in the context of inverted repeats as they do for certain RNA polymerases.

Possible roles of nucleocapsid protein of MoMuLV in the specificity of proviral DNA synthesis and in the genetic variability of the virus

Retroviral nucleocapsid (NC) protein, in addition to its structural roles in the virion core, is involved in the early and late phases of the viral replication cycle. To further characterise the role of NC protein of MoMuLV (NCp10) in the replication of the viral genome, the influence of NCp10 on self-primed versus primer-specific reverse transcription has been analysed in vitro. The results show that NCp10 can enhance the specificity of proviral DNA synthesis by inhibiting self-primed cDNA synthesis while promoting primer-specific DNA synthesis within active NCp10-RNA nucleoprotein complexes. Retroviruses are known to show a high degree of variability and this prompted us to examine the possible implication of NCp10 in the genetic variability of MoMuLV. The ability of reverse transcriptase (RT) to extend different mutated primers using an RNA or a DNA template has been investigated in the presence or in the absence of NCp10. NCp10 was found to have different effects on RT depending on the nature of the template: an enhancement at the elongation level of mutated primers using RNA as template versus a slight inhibition using DNA as template. These observations suggest that NCp10 could be implicated in the genetic variability of MoMuLV by allowing nucleotide misincorporation principally during minus strand DNA synthesis.

High fidelity of internal strand transfer catalyzed by human immunodeficiency virus reverse transcriptase

A system to study the fidelity of internal strand transfer events was constructed. A donor RNA, on which reverse transcriptase (RT)-directed DNA synthesis was initiated, shared homology with an acceptor RNA, to which DNAs initiated on the donor could transfer. The homology occurred over a 119-base internal region of the donor which coded for the N-terminal portion of the alpha-lac gene. Polymerase chain reaction (PCR) was used to amplify DNA synthesis products. The PCR products were then digested with PvuII and EcoRI and ligated into a vector which had this same region excised. Transformed Escherichia coli were screened for the ability to produce a functional beta-galactosidase protein by blue-white phenotype analysis with white colonies scored as those with errors in alpha-lac. Products synthesized on the donor were used to assess the error rate of human immunodeficiency virus-RT while products transferring to and subsequently extended on the acceptor (transfer products) were used to monitor transfer fidelity. Human immunodeficiency virus-RT made approximately 1 error per 7500 bases copied in the assay. Nucleocapsid protein (NCp), although stimulating strand transfer 3-fold, had no effect on RT fidelity. Transfer products in the absence of NCp had essentially the same amount of errors as donor-directed products while those produced with NCp showed a slight increase in error frequency. Overall, strand transfer events on this template were highly accurate. Since experiments with other templates have suggested that transfer is error prone, the fidelity of strand transfer may be highly sequence dependent.

Homologous recombination occurs in a distinct retroviral subpopulation and exhibits high negative interference

Homologous recombination and deletions occur during retroviral replication when reverse transcriptase switches templates. While recombination occurs solely by intermolecular template switching (between copackaged RNAs), deletions can occur by an intermolecular or an intramolecular template switch (within the same RNA). To directly compare the rates of intramolecular and intermolecular template switching, two spleen necrosis virus-based vectors were constructed. Each vector contained a 110-bp direct repeat that was previously shown to delete at a high rate. The 110-bp direct repeat was flanked by two different sets of restriction site markers. These vectors were used to form heterozygotic virions containing RNAs of each parental vector, from which recombinant viruses were generated. By analyses of the markers flanking the direct repeats in recombinant and nonrecombinant proviruses, the rates of intramolecular and intermolecular template switching were determined. The results of these analyses indicate that intramolecular template switching is much more efficient than intermolecular template switching and that direct repeat deletions occur primarily through intramolecular template switching events. These studies also indicate that retroviral recombination occurs within a distinct viral subpopulation and exhibits high negative interference, whereby the selection of one recombination event increases the probability that a second recombination event will be observed.

Evidence for a unique mechanism of strand transfer from the transactivation response region of HIV-1

We previously found that strand transfer by human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) is promoted at sites where RT pauses during synthesis. In this report, strand transfer is measured within the 5' transactivation response region (TAR) of HIV-1 RNA. We hypothesized that the stable hairpin structure of TAR would induce RT pausing, promoting RNase H-directed cleavage of the template and subsequent transfer at that site. We further predicted that HIV-1 nucleocapsid protein (NC), known to melt secondary structures, would decrease transfer. We show that TAR created a strong pause site for RT, but NC significantly promoted strand transfer. The effect of NC is specific, since other single strand binding proteins failed to stimulate transfer. In another unexpected outcome, preferred positions of internal transfer were not at the pause site but were in the upper stem and loop of TAR. Thus, we propose a new mechanism for transfer within TAR described by an interactive hairpin model, in which association between the donor and the acceptor templates within the TAR stem promotes transfer. The model is consistent with the observed stimulation of strand transfer by NC. The model is applicable to internal and replicative end transfer.

Possible roles of HIV-1 nucleocapsid protein in the specificity of proviral DNA synthesis and in its variability

Retroviral nucleocapsid (NC) protein is an integral part of the virion nucleocapsid where it coats the dimeric RNA genome. Due to its nucleic acid binding and annealing activities, NC protein directs the annealing of the tRNA primer to the primer binding site and greatly facilitates minus strand DNA elongation and transfer while protecting the nucleic acids against nuclease degradation. To understand the role of NCp7 in viral DNA synthesis, we examined the influence of NCp7 on self-primed versus primer-specific reverse transcription. The results show that HIV-1 NCp7 can extensively inhibit self-primed reverse transcription of viral and cellular RNAs while promoting primer-specific synthesis of proviral DNA. The role of NCp7 vis-a-vis the presence of mutations in the viral DNA during minus strand elongation was examined. NCp7 maximized the annealing between a cDNA(-) primer containing one to five consecutive errors and an RNA representing the 3' end of the genome. The ability of reverse transcriptase (RT) in the presence of NCp7 to subsequently extend the mutated primers depended upon the position of the mismatch within the primer:template complex. When the mutations were at the polymerisation site, primer extension by RT in the presence of NCp7 was very high, about 40% for one mismatch and 3% for five consecutive mismatches. Mutations within the DNA primer or at its 5' end had little effect on the extension of viral DNA by RT. Taken together these results indicate that NCp7 plays major roles in proviral DNA synthesis within the virion core due to its ability to promote prime-specific proviral DNA synthesis while concurrently inhibiting non-specific reverse transcription of viral and cellular RNAs. Moreover, the observation that NCp7 enhances the incorporation of mutations during minus strand DNA elongation favours the notion that NCp7 is a factor contributing to the high mutation rate of HIV-1.

Evolution and probable transmission of intersubtype recombinant human immunodeficiency virus type 1 in a Zambian couple

The extraordinary genetic diversity of human immunodeficiency virus type 1 (HIV-1) results from the introduction of mutations by an error-prone reverse transcriptase and from recombination of the two RNA genomes packaged in the virion during the synthesis of proviral DNA. The occurrence of multiple, genetically distant HIV-1 subtypes and their geographic intermixing set up conditions for dramatic, rather than gradual, changes in genotype whenever genomes from different subtypes are copackaged in virions. Here we describe, for the first time, the sequential generation of multiple different, but related, intersubtype HIV-1 recombinants within an infected individual. Full-length gag and env genes were recovered directly from peripheral blood mononuclear cells or from primary virus cultures, using serial blood samples from a Zambian woman and a sample from her spouse. DNA sequencing and phylogenetic analysis established that two different A/C recombinant forms of HIV-1 predominated at two time points in the woman. A related but distinct recombinant HIV-1 was recovered from her spouse. Intersubtype recombination apparently played a central role in the evolution of HIV-1 in this couple and may contribute substantially to the rapid emergence of HIV-1 variants whenever mixed-subtype HIV-1 infections occur.

The heterosexual human immunodeficiency virus type 1 epidemic in Thailand is caused by an intersubtype (A/E) recombinant of African origin

Since 1989, human immunodeficiency virus type 1 (HIV-1) has spread explosively through the heterosexual population in Thailand. This epidemic is caused primarily by viruses classified as "subtype E", which, on the basis of limited sequence comparisons, appear to represent hybrids of subtypes A (gag) and E (env). However, the true evolutionary origins of "subtype E" viruses are still obscure since no complete genomes have been analyzed, and only one full-length subtype A sequence has been available for phylogenetic comparison. In this study, we determined full-length proviral sequences for "subtype E" viruses from Thailand (93TH253) and the Central African Republic (90CR402) and for a subtype A virus from Uganda (92UG037). We also sequenced the long terminal repeat (LTR) regions from 16 virus strains representing clades A, C, E, F, and G. Detailed phylogenetic analyses of these sequences indicated that "subtype E" viruses do indeed represent A/E recombinants with multiple points of crossover along their genomes. The extracellular portion of env, parts of vif and vpr, as well as most of the LTR are of subtype E origin, whereas the remainder of the genome is of subtype A origin. The possibility that the discordant phylogenetic positions of "subtype E" viruses in gag- and env-derived trees are the result of unusual rates or patterns of evolution was also considered but was ruled out on the basis of two lines of evidence: (i) phylogenetic trees constructed for synonymous and nonsynonymous substitutions yielded the same discordant branching orders for "subtype E" gag and env gene sequences, thus excluding selection-driven evolution, and (ii) multiple crossovers in the viral genome are most consistent with the copy choice model of recombination and have been observed in other documented examples of HIV-1 intersubtype recombination. Thai and CAR "subtype E" viruses exhibited the same pattern of A/E mosaicism, indicating that the recombination event occurred in Africa prior to the spread of virus to Asia. Finally, all "subtype E" viruses were found to contain a distinctive two-nucleotide bulge in their transactivation response (TAR) elements. This feature was present only in viruses which also contained a subtype A 5' pol region (i.e., subtype A viruses or A/D and A/E recombinants), raising the possibility of a functional linkage between the TAR region and the polymerase. The implications of epidemic spread of a recombinant HIV-1 strain to viral natural history and vaccine development are discussed.

Strand transfer is enhanced by mismatched nucleotides at the 3' primer terminus: a possible link between HIV reverse transcriptase fidelity and recombination

Strand transfer catalyzed by HIV reverse transcriptase (RT) was examined. The system consisted of a 142 nt RNA (donor) to which a 50 nt DNA primer was hybridized. The primer bound such that its 3' terminal nucleotide hybridized to the 12th nt from the 5' end of the donor. The 3' terminal nucleotide on the primer was either a G, A or T residue. Since the corresponding nucleotide of the donor was a C, the G formed a matched terminus and the A or T a mismatched terminus. The efficiency with which DNA bound to the donor transferred to a second RNA, termed acceptor, was monitored. The acceptor was homologous to the donor for all but the last 9 nt at the 5' end of the donor. Therefore, homologous strand transfer could occur at any point prior to the DNA being extended into the nonhomologous region on the donor. Strand transfer occurred approximately twice as efficiently with the mismatched versus matched substrates. The mismatched nucleotide was fixed into transfer products indicating that excision of the mismatch was not required for RT extension or transfer. Results suggest that base misincorporations by RT may promote recombination by enhancing strand transfer.

Homologous and nonhomologous retroviral recombinations are both involved in the transfer by infectious particles of defective avian leukosis virus-derived transcomplementing genomes

We previously described avian leukosis virus-based packaging cell lines that produce stocks of retroviral vectors in which replication-competent viruses were not detectable. However, following infection of target cells with these retroviral stocks, we recently obtained colonies resulting from the transmission of recombinant genomes. Here, we have analyzed their genetic structure and shown that (i) each of them results from recombination between the packaging- and integration-defective transcomplementing genomes and the retroviral vector; (ii) recombination probably occurred during the reverse transcription step, involving strand switching of the reverse transcription growing point from the infectious retroviral vector to the transcomplementing RNA; and (iii) sequence identity and nonhomologous sequences were both used for the strand switching.

Recombination leads to the rapid emergence of HIV-1 dually resistant mutants under selective drug pressure

The potential contribution of recombination to the development of HIV-1 resistance to multiple drugs was investigated. Two distinct viruses, one highly resistant to a protease inhibitor (SC-52151) and the other highly resistant to zidovudine, were used to coinfect T lymphoblastoid cells in culture. The viral genotypes could be distinguished by four mutations conferring drug resistance to each drug and by other sequence differences specific for each parental virus. Progeny virions recovered from mixed infection were passaged in the presence and absence of both zidovudine and SC-52151. Dually resistant mutants emerged rapidly under selective conditions, and these viruses were genetic recombinants. These results emphasize that genetic recombination could contribute to high-level multiple-drug resistance and that this process must be considered in chemotherapeutic strategies for HIV infection.

Differences in mutagenesis during minus strand, plus strand and strand transfer (recombination) synthesis of the HIV-1 gene in vitro

We have developed an HIV nef-Escherichia coli lacZ fusion system in vitro that allows the detection of low frequency mutations, including frameshifts, deletions and insertions. A portion of the nef gene that encompasses a hypervariable region was fused in-frame with a downstream lacZalpha peptide coding region. The resulting lacZalpha peptide fusion protein remained functional. Any frameshift mutations in the nef insert would put the downstream lacZ alpha peptide gene out of frame, eliminating alpha complementation. With this system we compared the error rates of frameshift mutations that arise during DNA-directed and RNA-directed DNA synthesis. Results showed that DNA-directed and RNA-directed DNA synthesis did not contribute equally to the generation of mutations. DNA-directed DNA synthesis generated frameshift mutations at a frequency approximately 10-fold higher than those arising from RNA-directed DNA synthesis. RNA-directed DNA synthesis in the presence of acceptor templates showed an increase in mutation rate and differences in the mutation spectrum. The enhancement of mutation rate was caused by the appearance of mutations at three new locations that correlated with likely recombination sites. Results indicate that recombination is another source of mutations during viral replication.