Anna Knezevich

Suv39H1 and HP1γ are responsible for chromatin‐mediated HIV‐1 transcriptional silencing and post‐integration latency

HIV‐1 gene expression is the major determinant regulating the rate of virus replication and, consequently, AIDS progression. Following primary infection, most infected cells produce virus. However, a small population becomes latently infected and constitutes the viral reservoir. This stable viral reservoir seriously challenges the hope of complete viral eradication. Viewed in this context, it is critical to define the molecular mechanisms involved in the establishment of transcriptional latency and the reactivation of viral expression. We show that Suv39H1, HP1γ and histone H3Lys9 trimethylation play a major role in chromatin‐mediated repression of integrated HIV‐1 gene expression. Suv39H1, HP1γ and histone H3Lys9 trimethylation are reversibly associated with HIV‐1 in a transcription‐dependent manner. Finally, we show in different cellular models, including PBMCs from HIV‐1‐infected donors, that HIV‐1 reactivation could be achieved after HP1γ RNA interference.

A 1,8-naphthyridone derivative targets the HIV-1 Tat-mediated transcription and potently inhibits the HIV-1 replication.

The emergence of multidrug resistant HIV-1 strains and the inability of the HAART to eradicate HIV-1 virus from infected patients demand new drugs able to interfere with an alternative step of the replicative cycle. The naphthyridone 3 (HM13N), described in the present study, is a promising anti-HIV agent due to its ability to inhibit the HIV-1 Tat-mediated transcription and the potent antiviral activity observed in acutely, chronically, and latently infected cells. The absence of any tendency to select for resistance mutations in vitro adds to the potential clinical value of this type of compounds, especially as these compounds are drug-like and obey the Lipinski rules.

Identification of a mutation that perturbs NF1 agene splicing using genomic DNA samples and a minigene assay

Neurofibromatosis type 1 (NF1) is a common autosomal dominant genetic disease. In recent studies on the neurofibromatosis type 1 (NF1) gene neurofibromin, splicing abnormalities were seen in 30-50% of cases when RNA taken from cell lines was analysed.1,2 Unlike mutations that alter critical amino acids or generate premature stop codons, splicing abnormalities can be very hard to predict from sequence analysis alone. Apart from the two base pairs 5′ and 3′ of each exon, few of the nucleotides in regions critical for splicing are absolutely conserved. As a consequence, it can be very difficult to conclude that a sequence variation found in a patient will alter splicing and so represents a pathogenic mutation. ### Key points This difficulty is well illustrated by a family with NF1 in which we recently identified a sequence variation. The three generation family is from the UK and meets NIH diagnostic criteria. The index case, at the age of 82, has classical features of NF1 including multiple cafe au lait macules, neurofibromas, and axillary and inguinal freckling. Her son was similarly affected and died …

Fast transcription rates of RNA polymerase II in human cells

Averaged estimates of RNA polymerase II (RNAPII) elongation rates in mammalian cells have been shown to range between 1.3 and 4.3 kb min−1. In this work, nascent RNAs from an integrated human immunodeficiency virus type 1‐derived vector were detectable at the single living cell level by fluorescent RNA tagging. At steady state, a constant number of RNAs was measured corresponding to a minimal density of polymerases with negligible fluctuations over time. Recovery of fluorescence after photobleaching was complete within seconds, indicating a high rate of RNA biogenesis. The calculated transcription rate above 50 kb min−1 points towards a wide dynamic range of RNAPII velocities in living cells.

Characterization of the HIV-1 RNA associated proteome identifies Matrin 3 as a nuclear cofactor of Rev function

BackgroundCentral to the fully competent replication cycle of the human immunodeficiency virus type 1 (HIV-1) is the nuclear export of unspliced and partially spliced RNAs mediated by the Rev posttranscriptional activator and the Rev response element (RRE).ResultsHere, we introduce a novel method to explore the proteome associated with the nuclear HIV-1 RNAs. At the core of the method is the generation of cell lines harboring an integrated provirus carrying RNA binding sites for the MS2 bacteriophage protein. Flag-tagged MS2 is then used for affinity purification of the viral RNA. By this approach we found that the viral RNA is associated with the host nuclear matrix component MATR3 (Matrin 3) and that its modulation affected Rev activity. Knockdown of MATR3 suppressed Rev/RRE function in the export of unspliced HIV-1 RNAs. However, MATR3 was able to associate with Rev only through the presence of RRE-containing viral RNA.ConclusionsIn this work, we exploited a novel proteomic method to identify MATR3 as a cellular cofactor of Rev activity. MATR3 binds viral RNA and is required for the Rev/RRE mediated nuclear export of unspliced HIV-1 RNAs.

NF1 mRNA biogenesis: Effect of the genomic milieu in splicing regulation of the NF1 exon 37 region

We have studied the splicing regulation of NF1 exons 36 and 37. We show that they not only require an intact exonic Splicing Enhancer (ESE) within exon 37, but also need the genomic region stretching from exons 31 to 38. Any nucleotide change in two exon 37 third codon positions disrupts the ESE. The extent of exons 36 and 37 skipping due to a mutated ESE depends on the genomic context. This is a unique example of what may be a more general phenomena involved in the tuning of pre‐mRNA processing and gene expression modulation in the chromosomal setting.

Transcriptional competence of the integrated HIV‐1 provirus at the nuclear periphery

Spatial distribution of genes within the nucleus contributes to transcriptional control, allowing optimal gene expression as well as constitutive or regulated gene repression. Human immunodeficiency virus type 1 (HIV‐1) integrates into host chromatin to transcribe and replicate its genome. Lymphocytes harbouring a quiescent but inducible provirus are a challenge to viral eradication in infected patients undergoing antiviral therapy. Therefore, our understanding of the contribution of sub‐nuclear positioning to viral transcription may also have far‐reaching implications in the pathology of the infection. To gain an insight into the conformation of chromatin at the site of HIV‐1 integration, we investigated lymphocytes carrying a single latent provirus. In the silenced state, the provirus was consistently found at the nuclear periphery, associated in trans with a pericentromeric region of chromosome 12 in a significant number of quiescent cells. After induction of the transcription, this association was lost, although the location of the transcribing provirus remained peripheral. These results, extended to several other cell clones, unveil a novel mechanism of transcriptional silencing involved in HIV‐1 post‐transcriptional latency and reinforce the notion that gene transcription may also occur at the nuclear periphery.

A real-time view of the TAR:Tat:P-TEFb complex at HIV-1 transcription sites

HIV-1 transcription is tightly regulated: silent in long-term latency and highly active in acutely-infected cells. Transcription is activated by the viral protein Tat, which recruits the elongation factor P-TEFb by binding the TAR sequence present in nascent HIV-1 RNAs. In this study, we analyzed the dynamic of the TAR:Tat:P-TEFb complex in living cells, by performing FRAP experiments at HIV-1 transcription sites. Our results indicate that a large fraction of Tat present at these sites is recruited by Cyclin T1. We found that in the presence of Tat, Cdk9 remained bound to nascent HIV-1 RNAs for 71s. In contrast, when transcription was activated by PMA/ionomycin, in the absence of Tat, Cdk9 turned-over rapidly and resided on the HIV-1 promoter for only 11s. Thus, the mechanism of trans-activation determines the residency time of P-TEFb at the HIV-1 gene, possibly explaining why Tat is such a potent transcriptional activator. In addition, we observed that Tat occupied HIV-1 transcription sites for 55s, suggesting that the TAR:Tat:P-TEFb complex dissociates from the polymerase following transcription initiation, and undergoes subsequent cycles of association/dissociation.

Real-time imaging of the HIV-1 transcription cycle in single living cells.

The dynamic nature of cellular processes is emerging as an important modulator of physiological and pathological events. The key event in the life cycle of the human immunodeficiency virus type 1 (HIV-1) is transcription: it controls both viral gene expression and the latent phenotype. The basal transcription machinery and cellular and viral regulatory elements are dynamically recruited to the proviral DNA embedded into chromatin and to newly synthesized viral RNA. Their interactions determine fundamental steps, such as RNA polymerase recruitment, initiation, elongation, splicing, termination, and processing of pre-mRNA. The study of these events requires a novel armamentarium of techniques for live-cell imaging and fluorescence tagging of proteins and nucleic acids. The final outcome should not be only a descriptive view of the process but, most importantly, a quantitative analysis of the kinetics involved. Here, we provide an overview of the methodologies available for fluorescent labeling proteins and nucleic acids in live-cell imaging. We also describe the concept of fluorescent recovery after photobleaching (FRAP) and how it can be used to obtain information about HIV RNA transcription dynamics in living cells.

Intragenic transcriptional cis-activation of the human immunodeficiency virus 1 does not result in allele-specific inhibition of the endogenous gene

BackgroundThe human immunodeficiency virus type 1 (HIV-1) favors integration in active genes of host chromatin. It is believed that transcriptional interference of the viral promoter over the endogenous gene or vice versa might occur with implications in HIV-1 post-integrative transcriptional latency.ResultsIn this work a cell line has been transduced with a HIV-based vector and selected for Tat-inducible expression. These cells were found to carry a single silent integration in sense orientation within the second intron of the HMBOX1 gene. The HIV-1 Tat transactivator induced the viral LTR and repressed HMBOX1 expression independently of vector integration. Instead, single-cell quantitative in situ hybridization revealed that allele-specific transcription of HMBOX1 carrying the integrated provirus was not affected by the transactivation of the viral LTR in cis.ConclusionA major observation of the work is that the HIV-1 genome has inserted in genes that are also repressed by Tat and this could be an advantage for the virus during transcriptional reactivation. In addition, it has also been observed that transcription of the provirus and of the endogenous gene in which it is integrated may coexist at the same time in the same genomic location.