Like other pathogenic viruses, HIV-1 down-modulates surface expression of major histocompatibility complex class I (MHC-I) molecules in infected cells, thus impairing lysis by cytotoxic T lymphocytes. We have observed that this phenomenon depends on the expression of Nef. nef is an early gene of primate lentiviruses, which is necessary for maintaining high virus loads and inducing AIDS. Nef is not necessary for viral replication in vitro and stimulates the endocytosis of CD4. We show that the expression of MHC-I at the surface of lymphoid, monocytic and epithelial cells was reduced in the presence of Nef protein from various HIV-1 strains. Whereas MHC-I protein synthesis and transport through the endoplasmic reticulum and cis Golgi apparatus occurred normally in Nef(+) cells, surface MHC-I molecules were rapidly internalized, accumulated in endosomal vesicles and were degraded. The stimulation of MHC-I endocytosis by Nef represents a previously undocumented viral mechanism for evading the immune response.
Whereas human immunodeficiency virus (HIV) infects various cell types by fusion at the plasma membrane, we observed a different entry route in human primary macrophages, in which macropinocytosis is active. Shortly after exposure of macrophages to HIV-1 and irrespective of viral envelope-receptor interactions, particles were visible in intracellular vesicles, which were identified as macropinosomes. Most virions appeared subsequently degraded. However, fusion leading to capsid release in the cytosol and productive infection could take place inside vesicles when particles were properly enveloped. These observations provide new insights into HIV-1 interactions with a cell target relevant to pathogenesis. They may have implications for the design of soluble inhibitors aimed at interfering with the fusion or entry processes.
We have analyzed the replication of Nef ؉ and Nef ؊ isogenic human immunodeficiency virus in CEM, HUT78, MT4 lymphoid, and U937 monocytic cell lines. At each passage of infected cells, we have assessed the relative infectivity of the virus particles released in culture media by measuring the number of infectious units per nanogram of p24 protein. Values appeared to be 3-to 10-fold higher for the Nef ؉ virus than for the Nef ؊ virus. The positive effect of Nef was observed regardless of the cell line, the multiplicity of infection, and the number of virus replication cycles achieved. We showed, by using cells expressing glycosylphosphatidylinositollinked CD4, that the enhancement of virion infectivity could be dissociated from the down-regulation of cell surface CD4 also induced by Nef. The gp120-to-p24 ratio and the RNA content of virus particles produced in the presence or in the absence of Nef were equivalent. Virions bound to cell surface CD4 receptors with equal efficiencies. Equivalent reverse transcriptase activities were measured both on exogenous substrate and on particle genomic RNAs. In contrast, reverse transcription in infected cells generated 5-to 10-fold less DNA when the virions were produced in the absence of Nef, indicating that these particles performed reverse transcription in a suboptimal environment. These data suggest that the expression of Nef in virus-producing cells is required for efficient processing of the early stages of virus replication in target cells, including the internalization in an appropriate cell compartment and the uncoating of the particle.
We have investigated the cellular uptake of Gag p24 shortly after exposure of cells to human immunodeficiency virus (HIV) particles. In the absence of envelope glycoprotein on virions or of viral receptors or coreceptors at the cell surface, p24 was incorporated in intracellular vesicles but not detected in the cytosolic subcellular fraction. When appropriate envelope-receptor interactions could occur, the nonspecific vesicular uptake was still intense and cytosolic p24 represented 10 to 40% of total intracellular p24. The measurement of cytosolic p24 early after exposure to HIV type 1 is a reliable assay for investigating virus entry and early events leading to authentic cell infection.
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