Role of Natural Pseudotyping with Other Viruses in HIV Transmission
Hildreth, James E.K.   
University of California Davis, Davis, CA, United States

The global AIDS pandemic continues to expand despite significant advances in understanding HIV-1 pathogenesis and the development of powerful antiviral drugs. HIV-1 is transmitted primarily through sexual contact and more than 30 million people are currently infected worldwide. In some regions of the world such as southern Africa the prevalence of HIV-1 infection exceeds 20%. The devastating spread of HIV-1 in young women in these countries appears out of proportion to the overall risk of infection. Thus it is possible that a biological co-factor contributes to virus spread. The hypothesis of this proposal is that acquisition by HIV- 1 of the envelope glycoprotein of gammaretroviruses (murine leukemia virus-related viruses) in a process we call natural pseudotyping expands the cellular tropism of HIV-1 enabling it to directly infect vaginal epithelial cells thereby dramatically increasing the risk of infection during sexual intercourse. We propose a molecular epidemiology study consisting of four major aims. 1) To complete in vitro studies of gammaretrovirus/HIV-1 pseudotyping; 2) To demonstrate gammaretrovirus/HIV-1 co-infections in local donors; 3) To demonstrate the effect of gammaretrovirus pseudotyping on vaginal transmission in an animal model; 4) To determine the prevalence of gammaretrovirus infection and HIV-1 co-infection in southern Africa. Natural pseudotyping of HIV-1 is predicted to occur in individuals co-infected with HIV-1 and a gammaretrovirus (XMRV/MLV) since the cellular tropism of these two viruses overlap to include T cells. The formation of XMRV-pseudoptyped HIV-1 (HIV-1/gp70) (now with the cell tropism of XMRV) in blood or lymphoid tissue would result in HIV-1 infection of normally resistant cells in the urogenital tract. Prior or subsequent infection of these cells with XMRV would result in the release of HIV-1/gp70 into seminal fluid or vaginal secretions. The potential implications of natural pseudotyping of HIV-1 are profound.