Animal and human lentiviruses elude host defences by establishing covert infections and eventually cause disease through cumulative losses of cells that die with activation of viral gene expression. We used polymerase chain reaction in situ double-label methods to determine how many CD4+ lymphocytes are latently infected by human immunodeficiency virus (HIV) in patient lymph nodes and whether the pool of infected cells is large enough to account for immune depletion through continual activation of viral gene expression and attrition of cells responding to antigens. We discovered an extraordinarily large number of latently infected CD4+ lymphocytes and macrophages throughout the lymphoid system from early to late stages of infection, and confirmed the extracellular association of HIV with follicular dendritic cells. Follicular dendritic cells may transmit infection to cells as they migrate through lymphoid follicles. Latently infected lymphocytes and macrophages constitute an intracellular reservoir large enough ultimately to contribute to much of the immune depletion in AIDS, and represent a difficult problem that must be resolved in developing effective treatments and protective vaccine.
The PBj14 isolate of simian immunodeficiency virus from sooty mangabey monkeys (SIVSMM-PBj14) is the most acutely pathogenic primate lentivirus so far described, always causing fatal disease in pig-tailed macaques (Macaca nemestrina) within 8 days of inoculation. As a first step in identifying viral genes and gene products that influence pathogenicity, the SIVSMM-PBj14 genome was amplified by the polymerase chain reaction as 5' and 3' genomic halves of 5.1 and 5.8 kilobases, respectively, and molecularly cloned. DNA sequence analysis revealed a high degree of conservation with other SIVs, except for a 22-base-pair duplication in the enhancer region of the viral long terminal repeat which included a second binding site for the transcription factor NF-kappa B. Of six genomic halves examined, four contributed to the formation of infectious virus that induced acute disease and death in pig-tailed macaques as early as 6 days post-inoculation, with pathology, disease syndromes and kinetics indistinguishable from those induced by the uncloned isolate. To our knowledge this is the first example of acute immunodeficiency disease induced by a molecularly defined lentivirus. Furthermore, the molecularly cloned SIVSMM-PBj14 viruses share with the uncloned virus cytopathicity for mangabey CD4+ cells, a property that may correlate with their observed pathogenicity in vivo.
Latent and productive viral infections are at the extremes of the spectrum of virus-cell interactions that are thought to play a major role in the ability of such important human pathogens as human immunodeficiency virus (HIV) to elude host defenses and cause disease. The recent development of PCR-based methods to amplify target sequences in individual cells in routinely fixed tissues affords opportunities to directly examine the subtle and covert virus-ceDl relationships at the latent end ofthe spectrum that are inaccessible to analysis by conventional in situ hybridization techniques. We have now used PCR in situ with in situ hybridization to document latent and permissive HIV infection in routinely fixed and paraffinembedded tissue. In one of the first specimens we examined, a tumor biopsy from an HIV-infected individual, we found many of the lymphocytes and lymphocytes infiltrating the tumor had HIV DNA that was detectable only by PCR in situ. The fraction of positive cells varied regionally, but there were foci where most of the cells contained HIV DNA. Most of these lymphocytes and macrophages are latently infected, as we could detect HIV RNA in fewer than one in a thousand ofthese cells. We also detected HIV RNA, surprisingly, in 6% of the tumor cells, where the number of copies of viral RNA per cell was equivalent to productively infected cell lines. The alternative states of HmV-gene expression and high local concentration of latently infected lymphocytes and monocytes revealed by these studies conceptually supports models of lentiviral pathogenesis that attribute persistence to the reservoir of latently infected cells and disease to the consequences of viral-gene expression in this population. The magnitude of infection of lymphocytes documented in this report is also consistent with the emerging view that HIV infection per se could contribute substantially to depletion of immune cells in AIDS.Human immunodeficiency virus (HIV), the etiological agent of AIDS, can establish productive or latent infections in CD4+ lymphocytes and monocytes in culture, and these alternative states of viral-gene expression could readily account for the devastating consequences of infection -and the formidable difficulties in developing a protective vaccine (1-3). Latently infected cells could escape detection and destruction by host defenses and disseminate infection in and between individuals in the face of natural or vaccine-induced immunity. With activation of viral-gene expression, the immune system will eventually be destroyed, and the individual will succumb to a variety of opportunistic infections and unusual tumors. One critical prediction of this reconstruction of pathogenesis is that in vivo one can show that there is a population of infected cells that harbor the HIV provirus in a transcriptionally silent state with no detectable viral RNA and a second population in which viral transcripts are abundant. We have now used PCR-based technologies with singlecell resolution, originally developed for studies o...
We constructed recombinant reticuloendotheliosis virus (Rev)-derived and murine leukemia virus-derived vectors to characterize the specificity of packaging retroviral RNAs in Rev proteins. Using this approach, we further localized the Rev encapsidation sequence (E) to a 144-nucleotide region and determined that there are sequences in both the 5' and 3' halves of this region which are necessary in cis for viral replication. We found that the Rev E, like the murine leukemia virus E (psi), is position independent (R. Mann and D. Baltimore, J. Virol. 54:401-407, 1986). Also, a 156-nucleotide region of the Rev intron enhanced replication in a cis-acting fashion in the presence, but not in the absence, of helper virus. Finally, we showed that packaging of Eand heterologous retroviral genomes occurred efficiently in the Rev helper cell in the absence of competing E-containing (E') viral RNAs.
Molecularly cloned simian immunodeficiency viruses capable of inducing acute, fatal disease in pig-tailed macaques had been derived previously from a biological clone (bcl-3) of the PBj14 isolate of SIV from sooty mangabey monkeys (SIVsmmPBj14). The present study was undertaken in order to characterize virus from a second biological clone of SIVsmmPBj14, bcl-1, which fails to induce acute or fatal disease. Polymerase chain reaction was used to amplify 5' and 3' viral genome halves. The DNA sequence of two 3' halves was determined, and an infectious recombinant generated using a bcl-3-derived 5' half and a bcl-1-derived 3' half. Overall, bcl-1- and bcl-3-derived viruses displayed close homology, differing by a total of 2% at the DNA level and 1-6% at the amino acid level within the 8 open reading frames examined. In contrast to the bcl-3-derived viruses, the bcl-1-derived viruses encode a truncated transmembrane envelope glycoprotein. Another consistent difference was the presence of a 22 bp duplication in the U3 portion of the long terminal repeat (LTR) of bcl-3-derived viruses that includes the NF-kappa B transcriptional enhancer binding site. To assess the importance of this duplication, virus chimeras were generated which removed the duplication from the 3'-LTR or from both LTRs of a bcl-3 clone. The former virus was unstable, reacquiring the duplication through recombination with the 5' LTR. No consistent difference were observed, however, between viruses with or without the duplication in the in vitro studies conducted to date.(ABSTRACT TRUNCATED AT 250 WORDS)
Reticuloendotheliosis viruses (Rev) replicate in chicken and dog cells, but not in rat cells. Amphotropic murine leukemia viruses (Am-MLV) replicate in chicken, dog, and rat cells. Transcription from the Rev long terminal repeat, determined by the chloramphenicol acetyltransferase assay, was not significantly different from transcription from the MLV long terminal repeat in rat cells. To determine further the step(s) in the retroviral life cycle that is blocked for Rev replication in rat cells, we took advantage of the wide host range of Am-MLV (S. Rasheed, M. B. Gardner, and E. Chan, J. Virol. 19:13-18, 1976) and the ability to form Rev-Am-MLV pseudotypes. Data from these pseudotypes indicate that the block to Rev replication in rat cells is posttranscriptional.
To determine the block(s) to spleen necrosis virus (SNV) replication in mouse cells, we studied the expression of a dominant selectable marker, neo, or a gene whose product is easily assayed, the chloramnphenicol acetyltransferase (cat) gene, in SNV-derived and murine leukemia virus-derived vectors. Using transient (CAT) and stable (Neor phenotype) transfection assays, we showed that the SNV promoter was used in mouse cells only when the 3' SNV long terminal repeat (LTR) was absent. Infection of mouse cells with recombinant SNV viruses was 1% as efficient as infection of permissive dog (D17) cells. The SNV proviruses in mouse cells appeared normal by Southern blot analysis, indicating that their integration probably occurred by normal mechanisms. S1 nuclease analyses of Neor mouse cell clones, each harboring a single recombinant SNV provirus, showed that the selected (internal) promoter was active, but that the 5' SNV LTR promoter was not. However, in the rare (<10-6) Neor colonies in which expression of the 5' LTR was selected, both promoters were active. Thus, the block to SNV infection of mouse cells is at least at two levels; one is a 100-fold-decreased efficiency at some step(s) up to and including integration, and the other is at transcription.
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