Human immunodeficiency virus type 1 transductive recombination can occur frequently and in proportion to polyadenylation signal readthrough

Putting an 'End' to HIV mRNAs: capping and polyadenylation as potential therapeutic targets

Like most cellular mRNAs, the 5′ end of HIV mRNAs is capped and the 3′ end matured by the process of polyadenylation. There are, however, several rather unique and interesting aspects of these post-transcriptional processes on HIV transcripts. Capping of the highly structured 5′ end of HIV mRNAs is influenced by the viral TAT protein and a population of HIV mRNAs contains a trimethyl-G cap reminiscent of U snRNAs involved in splicing. HIV polyadenylation involves active repression of a promoter-proximal polyadenylation signal, auxiliary upstream regulatory elements and moonlighting polyadenylation factors that have additional impacts on HIV biology outside of the constraints of classical mRNA 3’ end formation. This review describes these post-transcriptional novelties of HIV gene expression as well as their implications in viral biology and as possible targets for therapeutic intervention.

The remarkable frequency of human immunodeficiency virus type 1 genetic recombination

The genetic diversity of human immunodeficiency virus type 1 (HIV-1) results from a combination of point mutations and genetic recombination, and rates of both processes are unusually high. This review focuses on the mechanisms and outcomes of HIV-1 genetic recombination and on the parameters that make recombination so remarkably frequent. Experimental work has demonstrated that the process that leads to recombination--a copy choice mechanism involving the migration of reverse transcriptase between viral RNA templates--occurs several times on average during every round of HIV-1 DNA synthesis. Key biological factors that lead to high recombination rates for all retroviruses are the recombination-prone nature of their reverse transcription machinery and their pseudodiploid RNA genomes. However, HIV-1 genes recombine even more frequently than do those of many other retroviruses. This reflects the way in which HIV-1 selects genomic RNAs for coencapsidation as well as cell-to-cell transmission properties that lead to unusually frequent associations between distinct viral genotypes. HIV-1 faces strong and changeable selective conditions during replication within patients. The mode of HIV-1 persistence as integrated proviruses and strong selection for defective proviruses in vivo provide conditions for archiving alleles, which can be resuscitated years after initial provirus establishment. Recombination can facilitate drug resistance and may allow superinfecting HIV-1 strains to evade preexisting immune responses, thus adding to challenges in vaccine development. These properties converge to provide HIV-1 with the means, motive, and opportunity to recombine its genetic material at an unprecedented high rate and to allow genetic recombination to serve as one of the highest barriers to HIV-1 eradication.

Pseudodiploid genome organization AIDS full-length human immunodeficiency virus type 1 DNA synthesis

Template switching between copackaged human immunodeficiency virus type 1 (HIV-1) genomic RNAs is genetically silent when identical RNAs are copackaged but yields recombinants when virions contain two distinct RNAs. Sequencing has revealed that errors at retroviral recombination junctions are infrequent, suggesting that template switching is not intrinsically mutagenic. Here, we tested the hypothesis that template switching may instead contribute to replication fidelity. This hypothesis predicts that reverse transcription of a single-copy gene will be more error prone than replication in the presence of a second copy. To test this, HIV-1-based vectors containing both lacZ and the puromycin resistance marker were expressed either alone or with an excess of an "empty" vector lacking lacZ and puro. This resulted in virions with either RNA homodimers or haploid genomes with only a single lacZ-puro RNA. In untreated cells, lacZ inactivation rates suggested that haploid vector reverse transcription was slightly more error prone than that of homodimerized pseudodiploid vectors. Haploid reverse transcription was at least threefold more error prone than pseudodiploid-templated synthesis when slowed by hydroxyurea treatment or stopped prematurely with zidovudine. Individual products of one- and two-copy genes revealed both nucleotide substitutions and deletions, with deletions more frequent than point mutations among haploid genome products. Similar spectra of defective products were observed at early reverse transcription time points and among products of haploid virions. These results indicate that faithful, full-length reverse transcription products were underrepresented in the absence of a reserve of genetic information and suggest that template switching contributes to HIV-1 genomic integrity.

Effects of identity minimization on Moloney murine leukemia virus template recognition and frequent tertiary template-directed insertions during nonhomologous recombination

Homology requirements for Moloney murine leukemia virus recombination were addressed in this study by monitoring titer defects observed when acceptor/donor template identity lengths were systematically reduced. Recombination acceptors with at least 16 contiguous bases of donor template identity were recognized as efficiently as longer acceptors. In contrast, a sharp 1-log titer drop was observed for an acceptor of only 15 bases long, with an additional 1-log titer decline for an 8-base acceptor and further decreases for shorter acceptors. Eighty-three independent nonhomologous recombination products were sequenced to examine recombination template selection in the absence of significant sequence identity. These replication products contained a total of 152 nonhomologous crossover junctions. Forced copy choice models predict that forced nonhomologous recombination should result in DNA synthesis to the donor template's 5' end, followed by microidentity-guided acceptor template selection. However, only a single product displayed this structure. The majority of examined nonhomologous recombination products contained junction-associated sequence insertions. Most insertions resulted from the use of one or more tertiary templates, recognizable as discontiguous portions of viral or host RNA or minus-strand DNA. The donor/acceptor template microidentity evident at most crossovers reconfirmed the remarkable capability of the reverse transcription machinery to recognize short regions of sequence identity. These results demonstrate that recruitment of discontiguous host or viral sequences is a common way for retroviruses to resolve nonhomologous recombination junctions and provide experimental support for the role of splinting templates in the generation of retroviral insertions.

Evidence for the acquisition of multi-drug resistance in an HIV-1 clinical isolate via human sequence transduction

Insertions in HIV-1 reverse transcriptase's fingers subdomain can enhance chain terminator excision and confer resistance to multiple nucleoside analogs. Inserts that resemble flanking sequences likely arise by local sequence duplication. However, a remarkable variety of non-repeat fingers insertions have been observed. Here, molecular epidemiology, sequence analyses and mechanistic modeling were employed to show that one Japanese isolate's RT fingers insert likely resulted from non-homologous recombination between virus and host sequences and the transductive copying of 37 nucleotides from human chromosome 17. These findings provide evidence that human sequence transduction can, at least rarely, contribute to genetic and phenotypic variation in pandemic HIV.

Hairpin-induced tRNA-mediated (HITME) recombination in HIV-1

Recombination due to template switching during reverse transcription is a major source of genetic variability in retroviruses. In the present study we forced a recombination event in human immunodeficiency virus type 1 (HIV-1) by electroporation of T cells with DNA from a molecular HIV-1 clone that has a 300 bp long hairpin structure in the Nef gene (HIV-lhNef). HIV-lhNef does not replicate, but replication-competent escape variants emerged in four independent cultures. The major part of the hairpin was deleted in all escape viruses. In three cases, the hairpin deletion was linked to patch insertion of tRNA^asp, tRNA^glu or tRNA^trp sequences. The tRNAs were inserted in the viral genome in the antisense orientation, indicating that tRNA-mediated recombination occurred during minus-strand DNA synthesis. We here propose a mechanistic model for this hairpin-induced tRNA-mediated (HITME) recombination. The transient role of the cellular tRNA molecule as enhancer of retroviral recombination is illustrated by the eventual removal of inserted tRNA sequences by a subsequent recombination/deletion event.

Mutagenesis and oncogenesis by chromosomal insertion of gene transfer vectors

Increasing evidence reveals that random insertion of gene transfer vectors into the genome of repopulating hematopoietic cells may alter their fate in vivo. Although most insertional mutations are expected to have few if any consequences for cellular survival, clonal dominance caused by retroviral vector insertions in (or in the vicinity of) proto-oncogenes or other signaling genes has been described for both normal and malignant hematopoiesis. Important insights into these side effects were initially obtained in murine models. Results from ongoing clinical studies have revealed that similar adverse events may also occur in human gene therapy. However, it remains unknown to what extent the outcome of insertional mutagenesis induced by gene vectors is related to (1) the architecture and type of vector used, (2) intrinsic properties of the target cell, and (3) extrinsic and potentially disease-specific factors influencing clonal competition in vivo. This review discusses reports addressing these questions, underlining the need for models that demonstrate and quantify the functional consequences of insertional mutagenesis. Improving vector design appears to be the most straightforward approach to increase safety, provided all relevant cofactors are considered.

Two distinct Moloney murine leukemia virus RNAs produced from a single locus dimerize at random

Two genetically distinct retroviral RNAs can be co-packaged if the RNAs are co-expressed in virion producing cells. For Moloney murine leukemia virus (MLV), co-packaged RNAs are not randomly selected from among all packaging-competent RNAs, but instead primarily associate as homodimers. Here, we tested the hypothesis that the distance between proviral templates might hinder RNA heterodimerization, thus generating the observed preferential homodimerization of co-expressed MLV RNAs. To do this, two genetically distinct RNAs were co-expressed from a single locus and the proportions of hetero- and homodimeric virion RNAs were determined. Unlike RNAs transcribed from two different templates, RNAs transcribed from a single locus dimerized at random. Additionally, in vitro transcription experiments suggested that MLV RNA dimerization can occur more efficiently for longer RNAs during transcription than post-synthesis. Together, these findings show that MLV RNA dimer-partner selection likely occurs either co-transcriptionally or within a pool of transcripts near the proviral template.

Single point mutations in the zinc finger motifs of the human immunodeficiency virus type 1 nucleocapsid alter RNA binding specificities of the gag protein and enhance packaging and infectivity

A specific interaction between the nucleocapsid (NC) domain of the Gag polyprotein and the RNA encapsidation signal (Psi) is required for preferential incorporation of the retroviral genomic RNA into the assembled virion. Using the yeast three-hybrid system, we developed a genetic screen to detect human immunodeficiency virus type 1 (HIV-1) Gag mutants with altered RNA binding specificities. Specifically, we randomly mutated full-length HIV-1 Gag or its NC portion and screened the mutants for an increase in affinity for the Harvey murine sarcoma virus encapsidation signal. These screens identified several NC zinc finger mutants with altered RNA binding specificities. Furthermore, additional zinc finger mutants that also demonstrated this phenotype were made by site-directed mutagenesis. The majority of these mutants were able to produce normal virion-like particles; however, when tested in a single-cycle infection assay, some of the mutants demonstrated higher transduction efficiencies than that of wild-type Gag. In particular, the N17K mutant showed a seven- to ninefold increase in transduction, which correlated with enhanced vector RNA packaging. This mutant also packaged larger amounts of foreign RNA. Our results emphasize the importance of the NC zinc fingers, and not other Gag sequences, in achieving specificity in the genome encapsidation process. In addition, the described mutations may contribute to our understanding of HIV diversity resulting from recombination events between copackaged viral genomes and foreign RNA.

Expression and recombination of the EGFP and EYFP genes in lentiviral vectors carrying two heterologous promoters

BACKGROUND

Expressing two genes in the progeny of stem and progenitor cells that are transduced with a unique viral vector is desirable in certain situations. We tested the ability of two lentiviral vectors to transduce human cells of hematopoietic origin and concomitantly express two reporter genes, either EGFP (enhanced green fluorescent protein) and DsRed2, or EGFP and EYFP (enhanced yellow fluorescent protein), from two internal promoters.

METHODS

The vectors were generated from the pTRIP deltaU3 EF1alpha EGFP lentiviral vector. Following transduction of hematopoietic and non-hematopoietic cell lines, we performed FACS, PCR and Southern blot analyzes to quantify transduction, integration efficiencies and size of integrated lentiviral vectors, respectively.

RESULTS

The detection of DsRed2 fluorescence appeared unexpectedly low in human cells of hematopoietic origin. Alternatively, a modification in the flow cytometry assay allowed us to distinguish between the two overlapping fluorescence signals emitted by EGFP and EYFP, when transduced cells were excited with a 488-nm laser beam. However, the low frequency of double-positive EGFP+ EYFP+ cells, and the existence of single-positive, mostly EGFP- EYFP+, cells, prompted us to search for recombinations in the vector sequence. Southern blotting of DNA obtained from transduced cells indeed demonstrated that recombination had occurred between the two closely related EGFP and EYFP sequences.

DISCUSSION

These observations suggest that recombination occurred within the EGFP and EYFP genes, which differ by only four amino acids. We conclude that the insertion of two highly homologous sequences into a lentiviral backbone can favor recombination.