A novel kinase activity associated with Nef derived from neurovirulent simian immunodeficiency virus.

The Nef proteins of Simian immunodeficiency virus (SIV) and human immunodeficiency virus (HIV) have been shown to associate with several cellular kinases. Further, the ability of SIVmac239 Nef to associate with a p21-activated kinase (PAK)-related kinase has been correlated with pathogenic progression to AIDS in rhesus macaques. Because the ability of Nef to associate with the PAK-related kinase is viral isolate dependent, we reasoned that viral isolates derived from distinct physiological locations may encode Nef proteins that exhibit distinct kinase association profiles. In this study, we compared kinase activities associated with Nef proteins derived from the prototypic lymphocyte-tropic SIVmac239 and a macrophage-tropic, neurovirulent clone, SIV/17E-Fr. Our findings not only support previous studies that have documented the association of SIVmac239 Nef with a PAK-related kinase and a Nef-associated kinase complex (NAKC) but describe a novel serine kinase activity detectable only in conjunction with the Nef protein derived from the neurovirulent clone, SIV/17E-Fr. The latter Nef protein does not associate with PAK, and unlike PAK or NAKC, this novel kinase activity is enhanced in association with nonmyristoylated forms of Nef and can utilize both ATP and GTP as phosphodonors. We also show that at least one substrate for the kinase is Nef itself and demonstrate that the SIV/17E-Fr Nef protein is phosphorylated in SIV-infected cells. These results suggest that the ability to associate with cellular kinases in general may be a conserved feature of Nef, but particular kinase/Nef associations may evolve with changes in the host environment concomitant with viral spread.

Neurovirulent simian immunodeficiency virus incorporates a Nef-associated kinase activity into virions.

We have demonstrated that a molecular clone, SIV/17E-Fr, is neurovirulent in vivo and molecular analyses of this virus in primary macrophages and neuroendothelial cells mapped the domains critical for this phenotype to the transmembrane and Nef proteins. The Nef protein is crucial for virus replication and pathogenesis in SIV-infected rhesus macaques. In addition, both HIV and SIV require full-length Nef proteins for efficient virus replication in primary cells and optimal virion infectivity. To characterize further the contribution of Nef to enhanced infectivity and replication, we analyzed virus particles from a number of SIV recombinant clones. These clones contained nef genes derived from either a lymphocyte-tropic (SIVmac239) or neurovirulent (SIV/17E-Fr) virus or a nef gene with a premature stop codon or deletion. Immunoprecipitation of Nef from virus particles revealed that SIV Nef is incorporated into virions. Incorporation of the Nef protein was dependent on the presence of the N-terminal myristoylation sequence in the nef gene. In addition, enhanced replication and virion infectivity was associated only with viruses containing the full-length Nef protein. To investigate a potential mechanism of virion modification by Nef, in vitro kinase assays were performed on the virion-derived Nef protein. Nef-associated kinase activity was detected only in virions containing Nef sequences derived from the neurovirulent virus SIV/17E-Fr. Thus, these results suggest that selection for specific nef sequences occurs in vivo and has a significant effect on virus replication in specific cells and organs.

Molecular and biological characterization of a neurovirulent molecular clone of simian immunodeficiency virus.

To identify the molecular determinants of neurovirulence, we constructed an infectious simian immunodeficiency virus (SIV) molecular clone, SIV/17E-Fr, that contained the 3' end of a neurovirulent strain of SIV, SIV/17E-Br, derived by in vivo virus passage. SIV/17E-Fr is macrophage tropic in vitro and neurovirulent in macaques. In contrast, a molecular clone, SIV/17E-Cl, that contains the SU and a portion of the TM sequences of SIV/17E-Br is macrophage tropic but not neurovirulent. To identify the amino acids that accounted for the replication differences between SIV/17E-Fr and SIV/17E-Cl in primary macaque cells in vitro, additional infectious molecular clones were constructed. Analysis of these recombinant viruses revealed that changes in the TM portion of the envelope protein were required for the highest level of replication in primary macaque macrophages and brain cells derived from the microvessel endothelium. In addition, a full-length Nef protein is necessary for optimum virus replication in both of these cell types. Finally, viruses expressing a full-length Nef protein in conjunction with the changes in the TM had the highest specific infectivity in a sMAGI assay. Thus, changes in the TM and nef genes between SIV/17E-Cl and SIV/17E-Fr account for replication differences in vitro and correlate with replication in the central nervous system in vivo.

Pathogenesis of simian immunodeficiency virus encephalitis: viral determinants of neurovirulence.

To examine the relationship between macrophage tropism and neurovirulence, macaques were inoculated with two recombinant hybrid viruses derived from the parent viruses SIVmac239, a lymphocyte-tropic, non-neurovirulent clone, and SIV/17E-Br, a macrophage-tropic, neurovirulent virus strain. The first recombinant, SIV/17E-Cl, contained the portion of the env gene that encodes the surface glycoprotein and a short segment of the transmembrane glycoprotein of SIV/17E-Br in the backbone of SIVmac239. Unlike SIVmac239, SIV/17E-Cl replicated productively in macrophages, demonstrating that sequences in the surface portion of env determine macrophage tropism. None of five macaques inoculated with SIV/17E-Cl developed simian immunodeficiency virus (SIV) encephalitis. The second recombinant, SIV/17E-Fr, which contained the entire env and nef genes and the 3' long terminal repeat of SIV/17E-Br in the SIVmac239 backbone, was also macrophage tropic. Six of nine macaques inoculated with SIV/17E-Fr developed SIV encephalitis ranging from mild to moderate in severity, indicating a significant (P = 0.031) difference in the neurovirulence of the two recombinants. In both groups of macaques, CD4+ cell counts declined gradually during infection and there was no significant difference in the rate of the decline between the two groups of macaques. This study demonstrated that macrophage tropism alone is not sufficient for the development of neurological disease. In addition, it showed that while sequences in the surface portion of the envelope gene determine macrophage tropism, additional sequences derived from the transmembrane portion of envelope and/or nef confer neurovirulence.

Characterization of equine infectious anemia virus dUTPase: growth properties of a dUTPase-deficient mutant.

The putative dUTPase domain was deleted from the polymerase (pol) gene of equine infectious anemia virus (EIAV) to produce a recombinant delta DUpol Escherichia coli expression cassette and a delta DU proviral clone. Expression of the recombinant delta DUpol polyprotein yielded a properly processed and enzymatically active reverse transcriptase, as determined by immunoblot analysis and DNA polymerase activity gels. Transfection of delta DU provirus into feline (FEA) cells resulted in production of virus that replicated to wild-type levels in both FEA cells and fetal equine kidney cells. In contrast, the delta DU virus replicated poorly (less than 1% of wild-type levels) in primary equine macrophage cultures, as measured by reverse transcriptase assays. Preparations of delta DU virus contained negligible dUTPase activity, which confirms that virion-associated dUTPase is encoded in the pol gene region between the RNase H domain and integrase, as has been demonstrated previously for feline immunodeficiency virus (J. H. Elder, D. L. Lerner, C. S. Hasselkus-Light, D. J. Fontenot, E. Hunter, P. A. Luciw, R. C. Montelaro, and T. R. Phillips, J. Virol. 66:1791-1794, 1992). Our results suggest that virus-encoded dUTPase is dispensable for virus replication in dividing cells in vitro but may be required for efficient replication of EIAV in nondividing equine macrophages, the natural host cells for this virus.

The surface envelope protein gene region of equine infectious anemia virus is not an important determinant of tropism in vitro.

Virulent, wild-type equine infectious anemia virus (EIAV) is restricted in one or more early steps in replication in equine skin fibroblast cells compared with cell culture-adapted virus, which is fully competent for replication in this cell type. We compared the sequences of wild-type EIAV and a full-length infectious proviral clone of the cell culture-adapted EIAV and found that the genomes were relatively well conserved with the exception of the envelope gene region, which showed extensive sequence differences. We therefore constructed several wild-type and cell culture-adapted virus chimeras to examine the role of the envelope gene in replication in different cell types in vitro. Unlike wild-type virus, which is restricted by an early event(s) for replication in equine dermis cells, the wild-type outer envelope gene chimeras are replication competent in this cell type. We conclude that even though there are extensive sequence differences between wild-type and cell culture-adapted viruses in the surface envelope gene region, this domain is not a determinant of the differing in vitro cell tropisms.

Immune-mediated thrombocytopenia in horses infected with equine infectious anemia virus.

An adult horse infected with a virulent, cell culture-adapted strain of equine infectious anemia virus (EIAV) developed cyclical thrombocytopenia in which the nadir of platelet counts coincided with peak febrile responses. In order to investigate the mechanism of thrombocytopenia during acute febrile episodes, four adult horses were experimentally infected with the wild-type Wyoming strain of EIAV. Platelet counts decreased from baseline as rectal temperature increased. Serum reverse transcriptase activity increased above background levels in all horses, coincident with increase in rectal temperature. All horses developed an EIAV-specific immune response detectable by Western immunoblot by postinfection day 10. Increases in platelet-associated immunoglobulins G and M were detectable by direct fluorescent-antibody test and flow cytometric assay. Viral replication in bone marrow megakaryocytes was not detectable by in situ hybridization. Results suggest an immune-mediated mechanism of thrombocytopenia in horses infected with EIAV. Despite an inability to identify virion particles in association with platelet-bound antibody, the cyclical nature of the thrombocytopenia and the occurrence of a marked cell-free viremia concomitant with fever and thrombocytopenia suggest immune complex deposition on platelets. We propose that clearance of virus and antibody-coated platelets from the peripheral circulation by hepatic Kupffer cells and splenic macrophages may target infectious virus particles, in the form of immune complexes, to host cells most permissive for in vivo viral replication.