Yea-Lih Lin

Suppression of microRNA-silencing pathway by HIV-1 during virus replication.

MicroRNAs (miRNAs) are single-stranded noncoding RNAs of 19 to 25 nucleotides that function as gene regulators and as a host cell defense against both RNA and DNA viruses. We provide evidence for a physiological role of the miRNA-silencing machinery in controlling HIV-1 replication. Type III RNAses Dicer and Drosha, responsible for miRNA processing, inhibited virus replication both in peripheral blood mononuclear cells from HIV-1–infected donors and in latently infected cells. In turn, HIV-1 actively suppressed the expression of the polycistronic miRNA cluster miR-17/92. This suppression was found to be required for efficient viral replication and was dependent on the histone acetyltransferase Tat cofactor PCAF. Our results highlight the involvement of the miRNA-silencing pathway in HIV-1 replication and latency.

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.

Cell surface CCR5 density determines the postentry efficiency of R5 HIV-1 infection

We have recently reported that the mean number of CCR5 coreceptors at the surface of CD4+ T cells (CCR5 density) correlates with viral load and disease progression in HIV-1-infected persons. Here, we definitively establish that CCR5 density determines the level of virus production and identify the stages of HIV-1 replicative cycle modulated by this effect. We show, by transducing the CCR5 gene into CCR5+ cells, that CCR5 overexpression resulted in an HIV-1 overinfectability. We sorted HOS-CD4+-CCR5+ cells into two subpopulations, HOShigh and HOSlow, the former expressing seven times more cell surface CCR5 molecules than the latter. Virus production was 30–80 times higher in HOShigh cells than in HOSlow cells after a single round of infection. In contrast, only twice as many viral particles entered the cytosol of HOShigh cells as compared with the cytosol of HOSlow cells. Yet, seven times as many early, and 24 times as many late, reverse transcription products were found in HOShigh cells as compared with HOSlow cells. Moreover, a 24- to 30-fold difference in the number of copies of integrated HIV-1 DNA was observed. No difference in HIV-1 LTR activation between the two cell lines was evident. Finally, we show that the higher virus production observed in HOShigh cells is inhibited by pertussis toxin, a Gαi protein inhibitor. Thus, CCR5 density mainly modulates postentry steps of the virus life cycle, particularly the reverse transcription. These data explain why CCR5 density influences HIV-1 disease progression and underline the therapeutic interest of lowering CCR5 expression.

Small-Molecule Inhibition of HIV pre-mRNA Splicing as a Novel Antiretroviral Therapy to Overcome Drug Resistance

The development of multidrug-resistant viruses compromises antiretroviral therapy efficacy and limits therapeutic options. Therefore, it is an ongoing task to identify new targets for antiretroviral therapy and to develop new drugs. Here, we show that an indole derivative (IDC16) that interferes with exonic splicing enhancer activity of the SR protein splicing factor SF2/ASF suppresses the production of key viral proteins, thereby compromising subsequent synthesis of full-length HIV-1 pre-mRNA and assembly of infectious particles. IDC16 inhibits replication of macrophage- and T cell–tropic laboratory strains, clinical isolates, and strains with high-level resistance to inhibitors of viral protease and reverse transcriptase. Importantly, drug treatment of primary blood cells did not alter splicing profiles of endogenous genes involved in cell cycle transition and apoptosis. Thus, human splicing factors represent novel and promising drug targets for the development of antiretroviral therapies, particularly for the inhibition of multidrug-resistant viruses.

Morus alba and active compound oxyresveratrol exert anti-inflammatory activity via inhibition of leukocyte migration involving MEK/ERK signaling

BackgroundMorus alba has long been used in traditional Chinese medicine to treat inflammatory diseases; however, the scientific basis for such usage and the mechanism of action are not well understood. This study investigated the action of M. alba on leukocyte migration, one key step in inflammation.MethodsGas chromatography-mass spectrometry (GC-MS) and cluster analyses of supercritical CO2 extracts of three Morus species were performed for chemotaxonomy-aided plant authentication. Phytochemistry and CXCR4-mediated chemotaxis assays were used to characterize the chemical and biological properties of M. alba and its active compound, oxyresveratrol. fluorescence-activated cell sorting (FACS) and Western blot analyses were conducted to determine the mode of action of oxyresveratrol.ResultsChemotaxonomy was used to help authenticate M. alba. Chemotaxis-based isolation identified oxyresveratrol as an active component in M. alba. Phytochemical and chemotaxis assays showed that the crude extract, ethyl acetate fraction and oxyresveratrol from M. alba suppressed cell migration of Jurkat T cells in response to SDF-1. Mechanistic study indicated that oxyresveratrol diminished CXCR4-mediated T-cell migration via inhibition of the MEK/ERK signaling cascade.ConclusionsA combination of GC-MS and cluster analysis techniques are applicable for authentication of the Morus species. Anti-inflammatory benefits of M. alba and its active compound, oxyresveratrol, may involve the inhibition of CXCR-4-mediated chemotaxis and MEK/ERK pathway in T and other immune cells.

The strength of the chemotactic response to a CCR5 binding chemokine is determined by the level of cell surface CCR5 density

We have shown that the intensity of expression of the C‐C chemokine receptor CCR5 at the single CD4+ cell level strongly determines the efficiency of its function as a coreceptor for human immunodeficiency virus type 1. By analogy, we examined if the number of CCR5 molecules at the cell surface might determine its chemotactic response to CCR5 ligands. To test this hypothesis, we measured by flow cytometry the migration of primary human T cells towards the CCR5‐binding chemokine CCL5 in vitro. First, we observed a dose‐dependent blockage of this migration exerted by an anti‐CCR5 monoclonal antibody. Second, we sorted peripheral blood mononuclear cells into five subpopulations expressing various cell surface CCR5 densities, and observed a correlation between the intensity of migration towards CCL5 and the level of CCR5 expression on these subpopulations. Third, we transduced CCR5+ peripheral blood mononuclear cells with the CCR5 gene, and observed that the CCR5 over‐expression induced an over‐migration towards CCL5. Finally, we observed in healthy donors a correlation between the chemotactic response of peripheral blood CD8+ T cell to CCL5 and their level of surface CCR5 expression. T‐cell surface CCR5 density, which is constant over time for a given individual, but varies drastically among individuals, might therefore be an important personal determinant of T‐cell migration in many biological situations where CCR5‐binding chemokines play a role, such as graft rejection, T helper 1‐mediated auto‐immune diseases, and infectious diseases involving CCR5. Moreover, our data highlight the therapeutic potential of CCR5 antagonists in these situations.

G-Protein Signaling Triggered by R5 Human Immunodeficiency Virus Type 1 Increases Virus Replication Efficiency in Primary T Lymphocytes

ABSTRACT The binding of R5 envelope to CCR5 during human immunodeficiency virus type 1 (HIV-1) entry provokes cell activation, which has so far been considered to have no effect on virus replication, since signaling-defective CCR5 molecules have been shown to function normally as HIV-1 coreceptors on transformed cells or mitogen-stimulated T lymphocytes. As the background state of activation of these cells might have biased the results, we performed experiments using the same approach but with nonactivated primary T lymphocytes. We now report that the single R126N mutation in the DRY motif, involved in G-protein coupling, results in a signaling-defective CCR5 coreceptor with a drastically impaired capacity to support HIV-1 infection.

Feline immunodeficiency virus vectors for efficient transduction of primary human synoviocytes: application to an original model of rheumatoid arthritis.

The potential of gene therapeutics is hindered by the limitations of the delivery systems presently available. Recently, human immunodeficiency virus (HIV) vectors have been developed that allow the efficient and stable transduction of primary nondividing cells in vivo. Because of the safety concerns raised by HIV vectors, we developed a gene delivery system derived from the ungulate lentivirus feline immunodeficiency virus (FIV). We describe in the present study the optimization of the safety and efficiency of this system that proved to be as potent as HIV vectors to transduce nondividing cells, with titers over 10(8) transducing units per ml. We used this tool to transduce TNF-alpha into human primary synoviocytes, and showed a high efficiency of transduction. TNF-alpha-transduced synoviocytes injected into the knee joints of severe combined immunodeficient (SCID) mice induced cell proliferation, as well as cartilage and bone erosion as soon as day 7, creating a standardized, humanized animal model relevant for rheumatoid arthritis. FIV vectors appear to be promising tools for biologic research and gene therapy.

Strategy for anti-aquaporin-4 auto-antibody identification and quantification using a new cell-based assay.

NMO-IgG is a specific biomarker of neuromyelitis optica (NMO) that targets the aquaporin-4 (AQP4) water channel protein. The current gold standard for NMO-IgG identification is indirect immunofluorescence (IIF). Our aim in this study was to develop a new quantitative cell-based assay (CBA) and to propose a rational strategy for anti-AQP4 Ab identification and quantification. We observed an excellent correlation between the CBA and IIF for NMO-IgG/anti-AQP4 detection. The CBA appeared more sensitive than IIF but on the other hand, IIF allows the simultaneous detection of various auto-Abs, underlining the complementarity between both methods. In conclusion, we propose to use IIF for the screening of patients at diagnosis in order to identify auto-Abs targeting the central nervous system. A highly sensitive, AQP4 specific and quantitative assay such as our CBA could be used thereafter to specifically identify the target of the Ab and to monitor its serum concentration under treatment.

The chemokine CCL5 regulates the in vivo cell surface expression of its receptor, CCR5.

The efficiency of CCR5 as an HIV coreceptor is strongly dependent on its level of cell surface expression. Therefore, it is of major importance to identify the factors that regulate cell surface density of CCR5. Among the chemokines that bind to CCR5, and induce its internalization, CCL5 is the most abundant in vivo. We show that the level of CCL5 production is a main factor determining CD4+ T cell surface CCR5 density.