HIV-1 Nef Inhibits Protease Activity and Its Absence Alters Protein Content of Mature Viral Particles (original) (raw)
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Journal of Virology, 2007
The Nef protein enhances human immunodeficiency virus type 1 (HIV-1) infectivity by facilitating an early postentry step in the virus life cycle. We report here that the addition of MG132 or lactacystin, each a specific inhibitor of cellular proteasome activity, preferentially enhances cellular permissiveness to infection by Nef-defective versus wild-type HIV-1. Pseudotyping by the glycoprotein of vesicular stomatitis virus rendered Nef-defective HIV-1 particles minimally responsive to the enhancing effects of proteasome inhibitors. These results suggest that Nef enhances the infectivity of HIV-1 particles by reducing their susceptibility to proteasomal degradation in target cells.
Human Immunodeficiency Virus Type 1 Nef Incorporation into Virions Does Not Increase Infectivity
Journal of Virology, 2009
The viral protein Nef contributes to the optimal infectivity of human and simian immunodeficiency viruses. The requirement for Nef during viral biogenesis particles suggests that Nef might play a role in this process. Alternatively, because Nef is incorporated into viruses, it might play a role when progeny virions reach target cells. We challenged these hypotheses by manipulating the amounts of Nef incorporated in viruses while keeping its expression level constant in producer cells. This was achieved by forcing the incorporation of Nef into viral particles by fusing a Vpr sequence to the C-terminal end of Nef. A cleavage site for the viral protease was introduced between Nef and Vpr to allow the release of Nef fragments from the fusion protein during virus maturation. We show that the resulting Nef-CS-Vpr fusion partially retains the ability of Nef to downregulate cell surface CD4 and that high amounts of Nef-CS-Vpr are incorporated into viral particles compared with what is seen ...
Virology, 1998
The HIV-1 Nef protein is present within the virion and is processed there by the viral protease. Mutational analysis indicated that residues 54±60 in HIV-1 Nef were required for intravirion cleavage. When viruses were produced using T cell lines or primary lymphoblasts, these residues were also required for optimal viral infectivity. However, substitution of native Nef residues with those of a functional Gag cleavage site demonstrated that intravirion cleavage was insufficient for the virological function of this domain. Furthermore, the importance of certain cleavage site residues to infectivity was conditional on the producer cell type. In particular, a mutant containing a deletion of residues 54±57 was phenotypically nef defective when produced using T cells (CEM, A2.01, or primary lymphoblasts) but was minimally impaired when produced from 293 or HeLa cells. This mutant was cleavage resistant, indicating that proteolytic processing of Nef was dispensable for infectivity enhancement when virions were assembled in certain non-T cells. Residues 54±61 of the cleavage site, including 54±57, were also required for Nef-mediated down-regulation of CD4. However, the surface expression of CD4 on HeLa cells in amounts comparable to that on the surface of primary T lymphoblasts did not create a producer cell environment in which residues 54±57 acquired greater virological importance. Furthermore, these residues were required for optimal infectivity even during virion assembly in T cells (A2.01) that expressed a CD4 molecule that is unable to respond to Nef. These data suggested that in producer T cells, certain cleavage site residues (54±57) contribute to a Nef-mediated virological effect that is unlikely to be linked causally to CD4 down-regulation. Conversely, in the context of 293 cells as viral producers, the ⌬54±57 mutant separated genetically down-regulation of CD4 (for which it was defective) from enhancement of infectivity (for which it was functional). Together, these data indicate that the virological function of the cleavage site domain is both independent of intravirion proteolytic processing of Nef and independent of CD4 down-regulation.
European Journal of Biochemistry, 1994
Negative factor (Nef) protein from human immunodeficiency virus type 1 (HIV-1) is cleaved into two well-defined domains by the HIV-1-encoded protease. The cleavage site is located between Trp57 and Leu58 and is well conserved. The two domains are stable in the presence of protease for more than 48 h. The C-terminal core domain contains a well-conserved well-folded region. The cleavage releases the core domain from the myristoylated membrane anchor domain. As is the case for other HIV proteins, cleavage of Nef could be crucial for correct biological function.
Nef from Human Immunodeficiency Virus Type 1F12 Inhibits Viral Production and Infectivity
Journal of Virology, 2001
Human immunodeficiency virus type 1 F12 (HIV-1 F12 ) interferes with the replication of other strains of HIV. Its accessory protein, Nef, is sufficient for this phenotype, where the production and infectivity of HIV are impaired significantly. The analysis of three rare mutations in this Nef protein revealed that these effects could be separated genetically. Moreover, the defect in virus production correlated with the lack of processing of the p55 Gag precursor in the presence of Nef from HIV-1 F12 . Importantly, the introduction of one of these mutations (E177G) into Nef from HIV-1 NL4-3 also created a dominant-negative Nef protein. Effects of Nef from HIV-1 F12 on virus production and Gag processing correlated with its altered subcellular distribution. Moreover, the association with two new cellular proteins with molecular masses of 74 and 75 kDa, which do not interact with other Nef proteins, correlated with the decreased virion infectivity. The identification of a dominant-negative protein for the production and infectivity of HIV suggests that Nef plays an active role at this stage of the viral replicative cycle.
Nef enhances HIV-1 infectivity via association with the virus assembly complex
Virology, 2008
The HIV-1 accessory protein Nef enhances virus infectivity by facilitating an early post-entry step of infection. Nef acts in the virus producer cell, leading to a beneficial modification to HIV-1 particles. Nef itself is incorporated into HIV-1 particles, where it is cleaved by the viral protease during virion maturation. To probe the role of virion-associated Nef in HIV-1 infection, we generated a fusion protein consisting of the host protein cyclophilin A (CypA) linked to the amino terminus of Nef. The resulting CypA-Nef protein enhanced the infectivity of Nef-defective HIV-1 particles and was specifically incorporated into the virions via association with Gag during particle assembly. Pharmacologic or genetic inhibition of CypA-Nef binding to Gag prevented incorporation of CypA-Nef into virions and inhibited infectivity enhancement. Our results indicate that infectivity enhancement by Nef requires its association with a component of the assembling HIV-1 particle.
FEBS Letters, 1995
Recombinant purified Nef protein of HIV-I, as well as Nef protein derived from extracts of permanently HIV-I infected glioblastoma cells and monocytes, are specifically cleaved by the HIV-1 protease. Nef cleavage products in cellular extracts treated with protease showed identical molecular weights as those obtained by digotion of purified Nef with recombinant HIV-I protease. Since cellular extracts were prepared by detergent and mechanical lysis it cannot be excluded that physiological cytoplasmic conditions were altered. The lack of Nef cleavage by endogenous HIV-1 protease in infected cells might be due to low concentrations of viral protease and the presence of Gag precursor molecules as natural substrate. Using a panel of monoclonal antibodies two cleavage fragments of 19 kDa and 8 kDa were defined. The cleavage site was located by microsequencing between amino acid 57 and 58 (AW*LEAQEEEEVGF). The conserved cleavage motif within HIV-I Nef suggests a potential biological function of Nef processing.
The Journal of general virology, 2002
The vif gene, one of the six auxiliary genes of human immunodeficiency virus (HIV), is essential for virus propagation in peripheral blood lymphocytes and macrophages and in certain T-cell lines. Previously, it was demonstrated that Vif inhibits the autoprocessing of truncated HIV type 1 (HIV-1) Gag-Pol polyproteins expressed in bacterial cells, as well as the protease-mediated cleavage of synthetic peptides in vitro. Peptides derived from the aa 78-98 region in the Vif molecule specifically inhibit and bind the HIV-1 protease in vitro and arrest the production of infectious viruses in HIV-1-infected cells. This study demonstrates that (i) purified recombinant Vif protein and HIV-1 but not avian sarcoma leukaemia virus protease specifically bind each other and (ii) the interaction between these two proteins takes place at the N terminus of the protease (aa 1-9) and the central part of Vif (aa 78-98). The data presented in this report suggest a model in which Vif interacts with the d...
Journal of virology, 2002
The human immunodeficiency virus type 1 (HIV-1) Vif protein is specifically packaged into virus particles through an interaction with viral genomic RNA in which it associates with the viral nucleoprotein complex. We now demonstrate for the first time that virus-associated Vif is subject to proteolytic processing by the viral protease (Pr). Pr-dependent processing of Vif was observed both in vivo and in vitro. In vivo processing of Vif was cell type independent and evident by the appearance of a 7-kDa processing product, which was restricted to cell-free virus preparations. Processing of Vif required an active viral Pr and was sensitive to Pr inhibitors such as ritonavir. The processing site in Vif was characterized both in vivo and in vitro and mapped to Ala(150). Interestingly, the Vif processing site is located in a domain that is highly conserved among HIV-1, HIV-2, and simian immunodeficiency virus Vif isolates. Mutations at or near the processing site did not affect protein sta...