Apoptosis induced in HIV-1-exposed, resting CD4+ T cells subsequent to signaling through homing receptors is Fas/Fas ligand-mediated.

The hallmark of HIV-1 disease is the gradual disappearance of CD4+ T cells from the blood. The mechanism of this depletion, however, is still unclear. Evidence suggests that lymphocytes die in lymph nodes, not in blood, and that uninfected bystander cells are the predominant cells dying. Our and others' previous studies showed that the lymph node homing receptor, CD62 ligand (CD62L), and Fas are up-regulated on resting CD4+ T cells after HIV-1 binding and that these cells home to lymph nodes at an enhanced rate. During the homing process, signals are induced through various homing receptors, which in turn, induced many of the cells to undergo apoptosis after they entered the lymph nodes. The purpose of this study was to determine how the homing process induces apoptosis in HIV-1-exposed, resting CD4+ T cells. We found that signaling through CD62L up-regulated FasL. This resulted in apoptosis of only HIV-1-presignaled, resting CD4+ T cells, not normal CD4+ T cells. This homing receptor-induced apoptosis could be blocked by anti-FasL antibodies or soluble Fas, demonstrating that the Fas-FasL interaction caused the apoptotic event.

CD4 lymphocytes in the blood of HIV(+) individuals migrate rapidly to lymph nodes and bone marrow: support for homing theory of CD4 cell depletion.

The mechanism(s) by which human immunodeficiency virus (HIV) causes depletion of CD4 lymphocytes remains unknown. Evidence has been reported for a mechanism involving HIV binding to (and signaling) resting CD4 lymphocytes in lymphoid tissues, resulting in up-regulation of lymph node homing receptors and enhanced homing after these cells enter the blood, and induction of apoptosis in many of these cells during the homing process, caused by secondary signaling through homing receptors. Supportive evidence for this as a major pathogenic mechanism requires demonstration that CD4 lymphocytes in HIV(+) individuals do migrate to lymph nodes at enhanced rates. Studies herein show that freshly isolated CD4 lymphocytes labeled with (111)Indium and intravenously reinfused back into HIV(+) human donors do home to peripheral lymph nodes at rates two times faster than normal. They also home at enhanced rates to iliac and vertebral bone marrow. In contrast, two hepatitis B virus-infected subjects displayed less than normal rates of blood CD4 lymphocyte migration to peripheral lymph nodes and bone marrow. Furthermore, the increased CD4 lymphocyte homing rates in HIV(+) subjects returned to normal levels after effective, highly active antiretroviral therapy treatment, showing that the enhanced homing correlated with active HIV replication. This is the first direct demonstration of where and how fast CD4 lymphocytes in the blood traffic to tissues in normal and HIV-infected humans. The results support the theory that the disappearance of CD4 lymphocytes from the blood of HIV(+) patients is a result of their enhanced migration out of the blood (homing) and dying in extravascular tissues.

Detection of antibodies to human immunodeficiency virus (HIV) that recognize conformational epitopes of glycoproteins 160 and 41 often allows for early diagnosis of HIV infection.

On the basis of human immunodeficiency virus (HIV) needlestick studies, the time to seroconversion for anti-HIV antibodies is 1-9 months (mean, approximately 2-3 months). However, an earlier marker of an immune response to HIV often occurs-serum anti-HIV antibodies reactive with live HIV-infected cells, termed "early HIV antibodies." The specificities of these antibodies are characterized by the recognition of type-specific conformational epitopes of the HIV envelope glycoprotein (gp) 160 and gp41. By use of a third-generation native HIV(IIIB) gp160 enzyme immunoassay (EIA), detection of HIV antibodies occurred, on average, 33 days earlier than did detection by commercial EIA and 25 days earlier than did detection by the reference antigen and reverse-transcription polymerase chain reaction (RT-PCR) assays in 3 of 5 HIV seroconversion panels. A fourth panel possessed early HIV antibodies that reacted with HIV(213) but not with HIV(IIIB), allowing for detection of HIV antibodies approximately 3 weeks earlier than by RT-PCR or other current tests.