Characterization of a mobilization-competent simian immunodeficiency virus (SIV) vector containing a ribozyme against SIV polymerase

A Stretch of Unpaired Purines in the Leader Region of Simian Immunodeficiency Virus (SIV) Genomic RNA is Critical for its Packaging into Virions

Simian immunodeficiency virus (SIV) is an important lentivirus used as a non-human primate model to study HIV replication, and pathogenesis of human AIDS, as well as a potential vector for human gene therapy. This study investigated the role of single-stranded purines (ssPurines) as potential genomic RNA (gRNA) packaging determinants in SIV replication. Similar ssPurines have been implicated as important motifs for gRNA packaging in many retroviruses like, HIV-1, MPMV, and MMTV by serving as Gag binding sites during virion assembly. In examining the secondary structure of the SIV 5' leader region, as recently deduced using SHAPE methodology, we identified four specific stretches of ssPurines (I-IV) in the region that harbors major packaging determinants of SIV. The significance of these ssPurine motifs were investigated by mutational analysis coupled with a biologically relevant single round of replication assay. These analyses revealed that while ssPurine II was essential, the others (ssPurines I, III, & IV) did not significantly contribute to SIV gRNA packaging. Any mutation in the ssPurine II, such as its deletion or substitution, or other mutations that caused base pairing of ssPurine II loop resulted in near abrogation of RNA packaging, further substantiating the crucial role of ssPurine II and its looped conformation in SIV gRNA packaging. Structure prediction analysis of these mutants further corroborated the biological results and further revealed that the unpaired nature of ssPurine II is critical for its function during SIV RNA packaging perhaps by enabling it to function as a specific binding site for SIV Gag.

Effectiveness of a 'hunter' virus in controlling human immunodeficiency virus type 1 infection

Engineered therapeutic viruses provide an alternative method for treating infectious diseases, and mathematical models can clarify the system's dynamics underlying this type of therapy. In particular, this study developed models to evaluate the potential to contain human immunodeficiency virus type 1 (HIV-1) infection using a genetically engineered 'hunter' virus that kills HIV-1-infected cells. First, we constructed a novel model for understanding the progression of HIV infection that predicted the loss of the immune system's CD4(+) T cells across time. Subsequently, it determined the effects of introducing hunter viruses in restoring cell population. The model implemented direct and indirect mechanisms by which HIV-1 may cause cell depletion and an immune response. Results suggest that the slow progression of HIV infection may result from a slowly decaying CTL immune response, leading to a limited but constant removal of uninfected CD4 resting cells through apoptosis - and from resting cell proliferation that reduces the rate of cell depletion over time. Importantly, results show that the hunter virus does restrain HIV infection and has the potential to allow major cell recovery to 'functional' levels. Further, the hunter virus persisted at a reduced HIV load and was effective either early or late in the infection. This study indicates that hunter viruses may halt the progression of the HIV infection by restoring and sustaining high CD4(+) T-cell levels.

Mobilization-competent Lentiviral Vector-mediated Sustained Transcriptional Modulation of HIV-1 Expression

Current anti-HIV-1 strategies reduce replication through targeting of viral proteins and RNA; meanwhile, targeting at the level of the integrated provirus has been less explored. We show here that mobilization-competent vectors containing small noncoding RNAs targeted to transcriptionally active regions of the human immunodeficiency virus type 1 (HIV-1) long terminal repeat (LTR) can take advantage of integrated virus and modulate HIV-1 replication. Transcriptional silencing of HIV-1 correlates with an increase in silent-state epigenetic marks including histone and DNA methylation, a loss of nuclear factor-kappaB (NF-kappaB) recruitment, and requires Argonaute 1 (Ago-1), histone deacetylase 1 (HDAC-1), and DNA methyltransferase 3a (DNMT3a) localization to the LTR. Long-term suppression of the virus was observed for 1 month with no evidence of viral resistance. These data show that RNA-directed transcriptional silencing of HIV-1 can be delivered by a mobilization-competent vector, suggesting that this system could be used to target long-term selective pressures on conserved promoter elements to evolve less pathogenic variants of HIV-1.

Genetic-based therapies to select nonpathogenic variants of HIV-1

Lentiviral-based genetic therapies offer a valuable addition to the current anti-HIV arsenal and allow for a rational directed approach to evolve HIV-1 to a less pathogenic state. Many lentiviral vector systems have been described that can be either replication incompetent, self-inactivating or conditionally replicating. Importantly, lentiviral vectors can be engineered to deliver anti-HIV-1 genes such as antisense RNAs, aptamers and siRNAs to those cells involved in HIV-1 infection: T-cells, hematopoietic stem cells and dendritic cells. Furthermore, the use of HIV-2-based vectors that can be mobilized by wild-type HIV-1 in vivo and spread to those cells targeted by the virus, as well as compete with HIV-1 viral RNA for packaging and access to viral proteins such as Tat and Rev required for viral replication, are of special interest. This review will focus on the rational design of therapeutic lentiviral vectors that can be used in combination with current antiretroviral therapies to essentially direct the evolution of HIV-1 to a less pathogenic state of existence.

Therapeutic potential of siRNA-mediated transcriptional gene silencing

RNA interference (RNAi) and specifically the use of small interfering RNAs (siRNAs) represents a potentially new paradigm in gene knockout technology. Clearly siRNAs can be used to knockdown the expression of a targeted transcript in what has been termed posttranscriptional gene silencing (PTGS). While there are a plethora of reports applying siRNA-mediated PTGS the limitation of the duration of the effect remains. Recently, in human cells, siRNAs have been shown, similar to plants and Schizosaccharomyces pombe, to mediate transcriptional gene silencing (TGS). The observation that siRNAs can function in a TGS manner in human cells suggests that, similar to plants, human genes may also be able to be silenced more permanently via epigenetic modifications. The ramifications of siRNA-mediated TGS in humans suggest that longer term suppression of gene function can be obtained via siRNA-directed chromatin modifications. Undoubtedly the potential to employ siRNA technology is broader than once envisioned in human cells and suggests that siRNA-mediated TGS is not simply limited to PTGS. The potential to utilize siRNAs to direct epigenetic changes in local chromatin structure offers a new therapeutic avenue that could prove remarkably robust and of immeasurable therapeutic value in the directed control of target gene expression.