Cytotoxicity is mandatory for CD8(+) T cell-mediated contact hypersensitivity.

Contact hypersensitivity (CHS) is a T cell-mediated skin inflammation induced by epicutaneous exposure to haptens in sensitized individuals. We have previously reported that CHS to dinitrofluorobenzene in mice is mediated by major histocompatibility complex (MHC) class I-restricted CD8(+) T cells. In this study, we show that CD8(+) T cells mediate the skin inflammation through their cytotoxic activity. The contribution of specific cytotoxic T lymphocytes (CTLs) to the CHS reaction was examined both in vivo and in vitro, using mice deficient in perforin and/or Fas/Fas ligand (FasL) pathways involved in cytotoxicity. Mice double deficient in perforin and FasL were able to develop hapten-specific CD8(+) T cells in the lymphoid organs but did not show CHS reaction. However, they did not generate hapten-specific CTLs, demonstrating that the CHS reaction is dependent on cytotoxic activity. In contrast, Fas-deficient lpr mice, FasL-deficient gld mice, and perforin-deficient mice developed a normal CHS reaction and were able to generate hapten-specific CTLs, suggesting that CHS requires either the Fas/FasL or the perforin pathway. This was confirmed by in vitro studies showing that the hapten-specific CTL activity was exclusively mediated by MHC class I-restricted CD8(+) T cells which could use either the perforin or the Fas/FasL pathway for their lytic activity. Thus, cytotoxic CD8(+) T cells, commonly implicated in the host defence against tumors and viral infections, could also mediate harmful delayed-type hypersensitivity reactions.

Apoptosis without decrease of cell DNA content.

Apoptosis of human B cells and murine T and B cells was analyzed by DNA agarose gel electrophoresis, clamped homogeneous electric field, measurement of cell DNA content by flow cytometry, transmission electron microscopy and by UV microscopy. Apoptosis was induced by etoposide (an inhibitor of topoisomerase II), by the calcium ionophore ionomycin or by cross-linking of membrane immunoglobulins (Ig) with anti-Ig-antibodies. Two types of apoptosis could be defined. Apoptosis resulting in small DNA fragments (180-200 base pairs and multiples thereof) was associated with a typical 'ladder' in agarose gel electrophoresis and a decrease in cell DNA content assessed by flow cytometry. Conversely apoptosis with large DNA fragments (100-150 kilobase pairs) was only demonstrated by clamped homogeneous electric field but was not associated with decreased cell DNA content or the observation of DNA ladders. Nuclear condensation without fragmentation was more frequent when apoptosis generated large DNA fragments. The type of apoptosis appears to be an intrinsic property of each cell type.

CD4 mAbs prevent progression of alloactivated CD4+ T cells into the S phase of the cell cycle without interfering with early activation signals.

Knowing that several CD4 mAbs may delay allograft rejection in the absence of circulating CD4+ lymphocyte depletion in vivo, we investigated the mechanisms whereby CD4 mAbs can interfere with the development of alloreactive T cells in the mixed lymphocyte reaction (MLR). In agreement with previous reports, CD4 mAbs of different species (mouse, rat, humanized), isotypes (IgG1, IgG2a, and IgG2b) and different epitope specificities decreased 3H-TdR incorporation in MLR, using monocyte-depleted or CD4+ T lymphocyte-enriched blood mononuclear cells as responders. Those effects were achieved at nonsaturating mAb concentration and were still demonstrable upon delayed addition of CD4 mAbs. However, CD4 mAbs decreased neither the number of blast cells nor the expression of CD25 (the alpha chain of IL-2 receptor), indicating that initial activation events leading to blast transformation were not affected. Determination of cytokine gene expression by non competitive quantitative RT-PCR and measurement of protein concentration in supernatants demonstrated that CD4 mAbs did not decrease IFN-gamma induced by alloactivation. However IL-2 concentration was decreased in all supernatants whereas IL-2 mRNA expression, only slightly decreased at 24 hr, and dropped after 72 hr. IL-5 and IL-10 mRNAs, equally expressed by stimulated or nonstimulated responder cells, were not affected by CD4 mAbs. IL-4 mRNA was not detectable. Furthermore, addition of rIL-2, rIFN-gamma or rIL-4 did not overcome proliferation inhibition. The data provide a novel insight into the mechanisms of CD4 mAbs immunosuppresssion that associates a decrease of IL-2 expression with an IL-2 resistant blockade of the progression of activated CD4+ T cells from the G1 to the S phases of the cell cycle.

TNF-alpha production as an in vitro assay predictive of cytokine-mediated toxic reactions induced by monoclonal antibodies.

When administered to patients, various biotechnology products may induce early toxic effects mediated by a cytokine cascade in which Tumor Necrosis Factor-alpha (TNF-alpha) plays a central role. The mechanisms of these toxic reactions have been extensively documented in the clinical model of the CD3 monoclonal antibody (mAb), OKT3. In order to develop a preclinical test for assessing the potential of mAbs or recombinant molecules to induce acute reactions when administered to patients, we investigated different in vitro culture systems for TNF-alpha secretion, using human blood cells. OKT3 and bacterial lipopolysaccharide (LPS) were used as positive controls. By comparing different culture conditions and kinetics, we concluded that 6-h supernatants of plasma-depleted whole blood contained high amounts of TNF-alpha in cultures stimulated by OKT3 or LPS, but not in those performed in the absence of exogenous stimulant or in the presence of mAbs which do not induce toxic reactions in vivo. This in vitro assay may be applied to the preclinical evaluation of the risk of cytokine-mediated toxicity in vivo. Owing to its simplicity, it could be used for preclinical investigation of inter-individual differences in the susceptibility to 'activation syndrome'.

Induction of Fas (Apo-1, CD95)-mediated apoptosis of activated lymphocytes by polyclonal antithymocyte globulins.

Polyclonal horse antilymphocyte and rabbit antithymocyte globulins (ATGs) are currently used in severe aplastic anemia and for the treatment of organ allograft acute rejection and graft-versus-host disease. ATG treatment induces a major depletion of peripheral blood lymphocytes, which contributes to its overall immunosuppressive effects. Several mechanisms that may account for lymphocyte lysis were investigated in vitro. At high concentrations (.1 to 1 mg/mL) ATGs activate the human classic complement pathway and induce lysis of both resting and phytohemagglutinin (PHA)-activated peripheral blood mononuclear cells. At low, submitogenic, concentration ATGs induce antibody-dependent cell cytotoxicity of PHA-activated cells, but not resting cells. They also trigger surface Fas (Apo-1, CD95) expression in naive T cells and Fas-ligand gene and protein expression in both naive and primed T cells, resulting in Fas/Fas-L interaction-mediated cell death. ATG-induced apoptosis and Fas-L expression were not observed with an ATG preparation lacking CD2 and CD3 antibodies. Susceptibility to ATG-induced apoptosis was restricted to activated cells, dependent on IL-2, and prevented by Cyclosporin A, FK506, and rapamycin. The data suggest that low doses of ATGs could be clinically evaluated in treatments aiming at the selective deletion of in vivo activated T cells in order to avoid massive lymphocyte depletion and subsequent immunodeficiency.

A noncomitogenic CD2R monoclonal antibody induces apoptosis of activated T cells by a CD95/CD95-L-dependent pathway.

Clonal expansion of activated T and B cells is controlled by homeostatic mechanisms resulting in apoptosis of a large proportion of activated cells, mostly through interaction between CD95 (Fas or Apo-1) receptor and its ligand CD95-L. CD2, which is considered as a CD3/TCR alternative pathway of T cell activation, may trigger activation-induced cell death, but the role of CD95/CD95-L interaction in CD2-mediated apoptosis remains controversial. We show here that the CD2R mAb YTH 655.5, which does not induce comitogenic signals when associated with another CD2 mAb, triggers CD95-L expression by preactivated but not resting T cells, resulting in CD95/CD95-L-mediated apoptosis. The critical role of CD95/CD95-L interaction was supported by complete inhibition in the presence of the antagonist CD95 mAb ZB4 and by blocking CD95-L synthesis and surface expression by cycloheximide, cyclosporin A, EGTA, or cytochalasin B. YTH 655.5 was shown to stimulate p56lck phosphorylation and enzymatic activity. However, p56lck activation is not sufficient to trigger apoptosis, because other CD2R and CD4 mAbs that activate p56lck do not induce apoptosis. In conclusion, CD2 can mediate nonmitogenic signals, resulting in CD95-L expression and apoptosis of CD95+ cells.