HIV-1 vpr encodes a 96-amino acid, nuclear protein whose function is not well understood. Unlike the other lentivirus regulatory proteins, Vpr is present in virions at relatively high copy number. In cells, Vpr is localized to the nucleus. Possible functions for vpr consistent with these findings include the nuclear import of preintegration complexes, transactivation of cellular genes, or induction of cellular differentiation. We show here, using both replication competent, macrophage-tropic virus and a sensitive, single-cycle luciferase HIV-1 reporter vector, that vpr is important for efficient viral replication in primary monocyte/macrophages, but appears to play no role in activated or resting T cell infection. The block to infection in monocytes was localized by PCR analysis of newly synthesized viral DNA and with the luciferase reporter vector to a stage in the viral life cycle after entry and reverse transcription, yet prior to, or at the time of, proviral transcription. In addition, infection of mononuclear phagocytes with virions that had been loaded with Vpr molecules in the producer cells by trans-complementation still showed a vpr-phenotype. These data suggest a role for vpr molecules produced in newly infected cells, in addition to its presumed function in the virion.
To avoid detection by CTL, HIV encodes mechanisms for removal of class I MHC proteins from the surface of infected cells. However, class I downregulation potentially exposes the virus-infected cell to attack by NK cells. Human lymphoid cells are protected from NK cell cytotoxicity primarily by HLA-C and HLA-E. We present evidence that HIV-1 selectively downregulates HLA-A and HLA-B but does not significantly affect HLA-C or HLA-E. We then identify the residues in HLA-C and HLA-E that protect them from HIV down-regulation. This selective downregulation allows HIV-infected cells to avoid NK cell-mediated lysis and may represent for HIV a balance between escape from CTL and maintenance of protection from NK cells. These results suggest that subpopulations of CTL and NK cells may be uniquely suited for combating HIV.
Cytotoxic T lymphocytes (CTLs) lyse virally infected cells that display viral peptide epitopes in association with major histocompatibility complex (MHC) class I molecules on the cell surface. However, despite a strong CTL response directed against viral epitopes, untreated people infected with the human immunodeficiency virus (HIV-1) develop AIDS. To resolve this enigma, we have examined the ability of CTLs to recognize and kill infected primary T lymphocytes. We found that CTLs inefficiently lysed primary cells infected with HIV-1 if the viral nef gene product was expressed. Resistance of infected cells to CTL killing correlated with nef-mediated downregulation of MHC class I and could be overcome by adding an excess of the relevant HIV-1 epitope as soluble peptide. Thus, Nef protected infected cells by reducing the epitope density on their surface. This effect of nef may allow evasion of CTL lysis by HIV-1-infected cells.
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