Yeast cells as a tool for analysis of HIV-1 protease susceptibility to protease inhibitors, a comparative study.

HIV develops drug resistance at a high rate under drug selection pressure. Resistance tests are recommended to help physicians optimize antiretroviral drug therapies. For this purpose, genotypic and phenotypic tests have been developed. In order to propose a new phenotypic test that will be less laborious, expensive, and time consuming than the standard ones, a new procedure to measure HIV-1 protease susceptibility to protease inhibitor (PIs) in Saccharomyces cerevisiae yeast cells was developed. This procedure is based on HIV-1 protease expression in yeast. While the viral protein induces yeast cell death, its inhibition by PIs in the culture medium allows the cell to grow in a dose-dependent manner. In a comparative study of standard genotypic analysis vs. yeast cell-based phenotypic tests, performed on HIV-1 protease coding DNA in 17 different plasma samples from infected individuals, a clear match was found between the results obtained using the two technologies. This suggests that the yeast-based procedure is at least as accurate as standard genotypic test in defining susceptibility to protease inhibitors. This encouraging result should be the basis for large-scale validation of the new phenotypic resistance test.

HIV-2 Protease resistance defined in yeast cells.

BACKGROUND: Inhibitors of the HIV-1 Protease currently used in therapeutic protocols, have been found to inhibit, although at higher concentrations, the HIV-2 encoded enzyme homologue. Similar to observations in HIV-1 infected individuals, therapeutic failure has also been observed for some patients infected with HIV-2 as a consequence of the emergence of viral strains resistant to the anti-retroviral molecules. In order to be able to define the specific mutations in the Protease that confer loss of susceptibility to Protease Inhibitors, we set up an experimental model system based in the expression of the viral protein in yeast. RESULTS: Our results show that the HIV-2 Protease activity kills the yeast cell, and this process can be abolished by inhibiting the viral enzyme activity. Since this inhibition is dose dependent, IC50 values can be assessed for each anti-retroviral molecule tested. We then defined the susceptibility of HIV-2 Proteases to Protease Inhibitors by comparing the IC50 values of Proteases from 7 infected individuals to those of a sensitive wild type laboratory adapted strain. CONCLUSION: This functional assay allowed us to show for the first time that the L90M substitution, present in a primary HIV-2 isolate, modifies the HIV-2 Protease susceptibility to Saquinavir but not Lopinavir. Developing a strategy based on the proposed yeast expressing system will contribute to define amino acid substitutions conferring HIV-2 Protease resistance.

Involvement of a small GTP binding protein in HIV-1 release.

BACKGROUND: There is evidence suggesting that actin binding to HIV-1 encoded proteins, or even actin dynamics themselves, might play a key role in virus budding and/or release from the infected cell. A crucial step in the reorganisation of the actin cytoskeleton is the engagement of various different GTP binding proteins. We have thus studied the involvement of GTP-binding proteins in the final steps of the HIV-1 viral replication cycle. RESULTS: Our results demonstrate that virus production is abolished when cellular GTP binding proteins involved in actin polymerisation are inhibited with specific toxins. CONCLUSION: We propose a new HIV budding working model whereby Gag interactions with pre-existing endosomal cellular tracks as well as with a yet non identified element of the actin polymerisation pathway are required in order to allow HIV-1 to be released from the infected cell.

HIV-1 gag polyprotein rescues HLA-DR intracellular transport in a human CD4+ cell line.

Major histocompatibility complex class II HLA-DR molecules are plasma-membrane integral heterodimers, constitutively expressed in antigen-presenting cells. Their expression is known to be upregulated in peripheral T lymphocytes upon cell activation and to be constitutive in T cell lines. In H78-C10.0, a subclone of the human CD4+ T cell line HUT-78, the transport of MHC class II HLA-DR molecules is blocked, resulting in their localization within internal vesicular compartments rather than at the cell surface. In this article, we show that HIV-1(HX10) infection of H78-C10.0 cells induces HLA-DR surface expression. Moreover, the produced infectious viruses harbor the heterodimer molecules in their envelopes. To define which of the viral proteins was involved in this phenomenon, we infected H78-C10.0 cells with recombinant vaccinia vectors containing either the gag-pro coding sequence or the entire env gene. Only gag expression was able to induce HLA-DR cell-surface localization in H78-C10.0 cells. RT-PCR analysis of the infected cells revealed no significant alteration in the amount of HLA-DRalpha-specific RNA compared to untreated cells. This implies that Gag acts on downstream events. When the env viral gene, coding for the precursor glycoprotein gp160, was expressed in H78-C10.0, the Env protein targeted to the cell surface was poorly processed to its final mature forms gp120 and gp41. However, coexpression of the env and gag genes led to restoration of this phenotype. Although the mechanism is unknown, the data compiled in this study strongly suggest that the viral Gag protein can interact with the cellular trafficking apparatus. Moreover, in a specific cell type as H78-C10.0 this interaction can even reverse intracellular transport defects.

Viral and cellular specificities of caprine arthritis encephalitis virus Vif protein.

The caprine arthritis encephalitis virus (CAEV) Vif protein is necessary for a productive infection of susceptible goat cells. The vif gene is conserved among all primate and most nonprimate lentiviruses. However, previous reports demonstrated that, in their respective host cells, primate Vif deleted lentiviruses could not be complemented by nonprimate Vif proteins, suggesting that species-specific restrictions between Vif and the virus-producing cells may modulate the Vif function on viral infectivity. Here we bring further support to this hypothesis since we show that CAEV Vif, when expressed in goat cells, is able to increase the infectivity of Vif deleted human immunodeficiency type-1 virus and of murine leukemia virus. Moreover, we demonstrate in vitro interactions between different Vif proteins and NC domains of heterologous Gag precursors, supporting the notion that species specificity of lentiviral infection is not due to molecular interactions between Vif and viral components.