One mechanism for expanding the cellular tropism of a virus is through the formation of phenotypically mixed particles or pseudotypes, a process commonly occurring during viral assembly in cells infected with two or more viruses. We report here that dual infection of cells with human immunodeficiency virus (HIV) and a murine amphotropic retrovirus leads to the production of HIV pseudotypes that have acquired the host range of the amphotropic retrovirus and are capable of infecting not only CD4human cells but also mouse cells. The replication of the HIV pseudotypes in the various CD4-cells was determined by measuring the appearance of HIV antigens in the supernatants, by cocultivation of CD4+ CEM cells with the infected CD4-cells, and in some cases by assaying the culture supernatants directly for infectious virus. Of the cells tested, human foreskin fibroblasts were the best host cells, and by in situ cytohybridization, we were able to document that all cells in the culture were infected. In addition, the temporal appearance of HIV-specific proteins in the HIV pseudotype-infected fibroblasts was similar to that seen in CD4+ CEM cells. If the human fibroblasts were first infected with the amphotropic retrovirus, they demonstrated the property of superinfection exclusion and were resistant to subsequent infection by the HIV pseudotype. In other cell lines, including the human glioblastomaderived cell line U373MG, HeLa cells, BALB/c mouse embryo cells, and SC-1 wild mouse cells, although the HIV pseudotype infection appeared to be less efficient, substantial amounts of HIV were nevertheless produced. These results indicate that the HIV (amphotropic retrovirus) pseudotypes may be useful for studying the molecular biology of HIV infections in a wide range of cells.
We have been studying the role of human cytomegalovirus (HCMV) as a potential cofactor in human immunodeficiency virus (HIV)-related disease. The clinical relevance of HCMV is highlighted by the fact that it is a principal viral pathogen in patients with AIDS and is known to infect the same cells as HIV. In this study, we focused on the molecular interactions between HIV and HCMV in human fibroblasts and in the human glioblastoma/astrocytoma-derived cell line U373 MG, cells which can be productively infected by both viruses. Because these cells are CD4-, we used HIV pseudotyped with a murine amphotropic retrovirus as described previously (D.
Human cytomegalovirus (HCMV) has been implicated as a potential cofactor in human immunodeficiency virus type 1 (HIV-1)-related disease. Previously, we reported that HCMV inhibits HIV-1 RNA and protein synthesis in cells productively infected with both viruses but, in transient assays, activates an HIV-1 long terminal repeat-chloramphenicol acetyltransferase (LTR-CAT) construct introduced into the cell by transfection (V. Koval, C. Clark, M. Vaishnav, S. A. Spector, and D. H. Spector, J. Virol. 65:6969-6978, 1991). We show here that HCMV can also activate an infectious proviral HIV-1 genome transiently transfected into a cell. To ascertain whether integration of the HIV-1 provirus plays a role in these differential effects, we generated monoclonal and polyclonal cell lines that each contain a single integrated copy of an HIV-1 LTR-CAT construct and compared the regulatory effects of HCMV and HIV-1 infection in these cells with those occurring in the same type of cell transiently transfected with the HIV-1 LTR-CAT construct. We find that HCMV activates the transfected HIV-1 promoter 230-fold but activates the integrated promoter only 2.8-to 54-fold. In contrast, HIV-1 stimulates the integrated HIV-1 promoter 2,700-to 6,000-fold but stimulates the transfected promoter only 80-fold. Thus, the relative response of the HIV-1 promoter to HCMV and HIV-1 regulatory proteins depends upon whether it is integrated. To determine if HIV-1 gene products are necessary for the HCMVmediated repression, we constructed cell lines containing two different stably integrated HIV-1 proviruses: one is tat-and nef-minus and transcriptionally inactive, while the other is env-and nef-minus but actively expresses the other HIV-1 gene products. Upon infection with HCMV, HIV-1 antigen production was stimulated from the inactive HIV-1 genome but inhibited from the active genome. We propose that HCMV has two separate effects on HIV-1 replication during a coinfection. One is a slight stimulatory effect which would be undetectable during an active HIV-1 infection, while the other is a net inhibitory effect that is mediated by an interaction between HCMV and HIV-1 gene products.
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