Expression of a protective gene-prolongs survival of T cells in human immunodeficiency virus-infected patients.

The resistance of acquired immunodeficiency syndrome (AIDS) to traditional drug therapy has prompted a search for alternative treatments for this disease. One potential approach is to provide genetic resistance to viral replication to prolong latency. This strategy requires the definition of effective antiviral genes that extend the survival of T cells in human immunodeficiency virus (HIV)-infected individuals. We report the results of a human study designed to determine whether a genetic intervention can prolong the survival of T cells in HIV-infected individuals. Gene transfer was performed in enriched CD4+ cells with plasmid expression vectors encoding an inhibitory Rev protein, Rev M10, or a deletion mutant control, deltaRev M10, delivered by gold microparticles. Autologous cells separately transfected with each of the vectors were returned to each patient, and toxicity, gene expression, and survival of genetically modified cells were assessed. Cells that expressed Rev M10 were more resistant to HIV infection than those with deltaRev M10 in vitro. In HIV-infected subjects, Rev M10-transduced cells showed preferential survival compared to deltaRev M10 controls. Rev M10 can therefore act as a specific intracellular inhibitor that can prolong T-cell survival in HIV-1-infected individuals and potentially serve as a molecular genetic intervention which can contribute to the treatment of AIDS.

Identification of inflections in T-cell counts among HIV-1-infected individuals and relationship with progression to clinical AIDS

Studies of circulating T (CD3+) lymphocytes have shown that on a population basis T-cell numbers remain stable for many years after HIV-1 infection (blind T-cell homeostasis), but decline rapidly beginning approximately 1.5–2.5 years before the onset of clinical AIDS. We derived a general method for defining the loss of homeostasis on the individual level and for determining the prevalence of homeostasis loss according to HIV status and the occurrence of AIDS in more than 5,000 men enrolled in the Multicenter AIDS Cohort Study. We used a segmented regression model for log10 CD3+ cell counts that included separate T-cell trajectories before and after a time (the T-cell inflection point) where the loss of T-cell homeostasis was most likely to have occurred. The average slope of CD3+ lymphocyte counts before the inflection point was close to zero for HIV− and HIV+ men, consistent with blind T-cell homeostasis. After the inflection point, the HIV+ individuals who developed AIDS generally showed a dramatic decline in CD3+ cell counts relative to HIV− men and HIV+ men not developing AIDS. A CD3+ cell decline of greater than 10 percent per year was present in 77% of HIV+ men developing AIDS but in only 23% of HIV+ men with no onset of AIDS. Our findings at the individual level support the blind T-cell homeostasis hypothesis and provide strong evidence that the loss of homeostasis is an important mechanism in the pathogenesis of the severe immunodeficiency that characterizes the late stages of HIV infection.