In vitro methods for assessing the susceptibility of HIV-1 infected individuals to cysteine-protease-mediated activation- induced programmed cell death

Calpain has been identified as a component of the biochemical pathway in programmed cell death. Calpain inhibitors are effective in preventing the progression to cell death and can restore cell function. T lymphocytes from HIV infected individuals undergo T cell receptor-triggered programmed cell death which can be treated by calpain inhibitors and immune function can be restored in affected cells. Methods for diagnosing cell populations or individuals susceptible to programmed cell death and for monitoring therapeutic effectiveness are provide

Apoptotic cell death and cytokine dysregulation in human immunodeficiency virus infection: pivotal factors in disease progression

The progressive loss of CD4 T lymphocyte is patognomonic of Human Immunodeficiency Virus (HIV) infection and results in immunodeficiency and the appearance of acquired immunodeficiency syndrome (AIDS)-defining pathologies. Although a percentage of CD4 T lymphocytes is destroyed directly by HIV infection, a much higher proportion of lymphocytes remains uninfected and therefore must be destroyed by mechanisms not directly involving viral infection. One such mechanism is apoptotic T cell death (ATCD). ATCD in HIV infection has been shown to be: 1) secondary to cross-linking of CD4 by viral proteins; 2) mediated by both APO-1/Fas and lymphotoxin (LT); and 3) differentially modulated by type 1 and type 2 cytokines. We will briefly analyze the experimental evidences suggesting that ATCD contributes significantly to the immunopathogenesis of HIV/AIDS via depletion of CD4+ T cells. apoptosis; programmed cell death; HIV; AIDS; immunology; cytokines; T lymphocytes

Inhibition of activation-induced programmed cell death and restoration of defective immune responses of HIV+ donors by cysteine protease inhibitors

In vitro activation of PBLs from HIV+ individuals resulted in programmed cell death (PCD) within 2 days in 58 of 95 HIV+ blood donors, in contrast to only two of 30 control HIV- donors. CD4+ and CD8+ T cells from HIV+ donors died under these conditions, and these cells showed apoptotic nuclear morphology and DNA fragmentation. To test the hypothesis that this cell death shares a common biochemical pathway with that induced by TCR cross-linking in normal dividing T cells, inhibitors of the calcium-activated cysteine protease calpain were tested for their ability to block the activation-induced PCD of HIV+ donors. The E-64 (epoxysuccinyl) class of cysteine protease inhibitors gave 40% to 60% inhibition of HIV+ PCD responses, while the aldehyde inhibitors, leupeptin and calpain inhibitor II, gave 60% to 67% inhibition. The involvement of this calpain-dependent death pathway in HIV-induced functional T helper cell deficiency was tested by examining the effect of calpain inhibitors on the defective Ag- and mitogen-dependent proliferative responses of HIV+ donors. Twenty to fifty percent of such defective responses were significantly restored toward normal levels by calpain inhibitors, whereas control responses by normal donors were largely unaffected. These data suggest that a calpain-dependent PCD pathway contributes to HIV-associated immunodeficiency and suggest the use of calpain inhibitors as a possible route to therapy of HIV infection

Antigen-stimulated apoptotic T-cell death in HIV infection is selective for CD4+ T cells, modulated by cytokines and effected by lymphotoxin

Objective: To characterize the mechanism of in vitro antigen-induced apoptotic T-cell death in the peripheral blood mononuclear cells (PBMC) of HIV-1-infected individuals. Design and methods: PBMC from HIV-1-infected and uninfected individuals were unstimulated or stimulated with HIV-1 envelope synthetic peptides (Env) or influenza A virus to determine the extent of antigen-stimulated apoptotic T-cell death, whether this death was limited to the CD4+ subset, and the effects of cytokines on T-cell death. Death was assessed by apoptotic nuclear morphology after 7 days of culture by fluorescence microscopy using a DNA-specific dye. Transwell cultures and supernatant transfers were utilized to test whether a soluble factor produced by HIV-positive PBMC induced death of HIV-negative T cells. Exogenous cytokines [interleukin (IL)-12, interferon (IFN)-\u3b3, IL-4 and IL-10], as well as antibodies against endogenously produced cytokines (IL-4, IL-10, IL-12, and lymphotoxin) were tested for their ability to modulate death. Results: Antigenic stimulation induced death in PBMC from HIV-positive donors, but not in PBMC from HIV-negative donors. Antigen-stimulated death was seen in CD4+ but not CD8+ T-cell subset from the HIV-positive patients. Apoptotic death was blocked by IL-12, IFN-\u3b3, anti-IL-4, anti-IL-10, and anti-lymphotoxin, but not by anti-IL-12. Transwell and supernatant transfer experiments indicated that antigen stimulated HIV-positive PBMC produced a factor that killed T-cell blasts. The factor was inhibited by anti-lymphotoxin, but not by anti-IL-10. Conclusions: Stimulation of HIV-positive PBMC with CD4-dependent antigens results in selective death of CD4+ T cells that is modulated by cytokines. Our results suggest that apoptotic death is not limited to HIV-infected or HIV-specific T cells, but occurs in bystander cells. Lymphotoxin is a mediator of antigen-stimulated T-cell death in this in vitro model