Distinct biochemical features of interferon gamma receptors on human T lymphocytes.

Recombinant human gamma interferon (IFN gamma) was used to study IFN gamma receptors (IFN gamma-R) on human CD4+ and CD8+ peripheral blood T lymphocytes. When cell-bound 125I-IFN gamma was cross-linked by disuccinimidyl suberate, the receptor-ligand complex migrated under nonreducing conditions as major bands of 155 kD and 90 kD and a minor band of 65-70 kD. Under reducing conditions, only the 90 and 65 kD complexes were found; the 155 kD band was not seen. In contrast, complexes from WISH and Raji human lines exhibited a single band of a 125 kD under both reducing and nonreducing conditions. The molecular pattern of the receptor ligand complex on WISH cells was not altered when these cells were mixed with T lymphocytes during the extraction procedure. The results suggest that the IFN gamma receptor on T lymphocytes differs from those previously described.

Prostaglandin E2 selectively increases interferon gamma receptor expression on human CD8+ lymphocytes.

We previously reported that prostaglandin E2 (PGE2) at a physiologic concentration (10(-8) M) and interferon gamma (IFN gamma), acting sequentially, were required for the differentiation of suppressor cells in mitogen-stimulated cultures. The present study was designed to test whether PGE2 might mediate IFN gamma-dependent effects on CD8+ cells by altering the number and/or affinity of their IFN gamma receptors. CD8+ and CD4+ cells when cultured for 18 h expressed comparable numbers of IFN gamma receptors of a single high affinity. Incubation with 10(-8) M PGE2 for 18 h, however, increased the number of IFN gamma receptors on CD8+ cells without affecting the binding affinity. Similar effects were not observed with CD4+ cells, nor when CD8+ cells were cultured in 10(-8) M PGD2. Concentrations of PGE2, which were ineffective in the induction of IFN gamma-dependent suppressor cell differentiation, also did not affect IFN gamma receptor expression on CD8+ cells. This observation of a specific stimulatory effect of PGE2 on the display of IFN gamma receptors of CD8+ cells suggests a novel mechanism for eicosanoid function through tissue-specific regulation of hormone receptors.

Sequential effects of prostaglandins and interferon-gamma on differentiation of CD8+ suppressor cells.

We have previously demonstrated that differentiation of CD8+ Tp44- suppressor cells in pokeweed mitogen (PWM)-stimulated cultures requires soluble factors elaborated by CD4+ cells and monocytes, and that the monocyte signal for such differentiation can be replaced by prostaglandin E2 (PGE2). In this study, we explored the ability of interleukin 2 (IL 2) and interferon-gamma (IFN-gamma) to replace the CD4+ signal. When IL 2 or IFN-gamma was used at concentrations equivalent to those present in supernatants of PWM-pulsed cultures of CD4+ cells, no effect on differentiation of CD8+ cells was observed. However, a potent suppressor inducing activity was detected when IFN-gamma, but not IL 2, was mixed with supernatants derived from cultures of PWM-pulsed purified monocytes (M phi sup) or with 10(-8) M PGE2. Differentiated CD8+ suppressor cells (Ts) inhibited both PWM-stimulated proliferative response of CD4+ cells and immunoglobulin production by B cells. The signals mediated by the M phi sup or PGE2 and IFN-gamma were shown to act sequentially. That is, M phi sup or PGE2 was required initially, followed by an IFN-gamma-dependent differentiative step. These studies thus suggest a cascade of cellular interactions involving monocytes, CD4+ cells, and CD8+ Ts precursors that are required for the differentiation of CD8+ suppressor effector cells.

T suppressor cell growth factor and anti-CD3 antibodies stimulate reciprocal subsets of T lymphocytes.

Because of the central role of IL-2 in clonal expansion of T cells, we have postulated that lymphocyte subpopulations with opposing regulatory functions might be independently regulated by differential requirements for expression of cell-surface IL-2-R. Purified CD4+ and CD8+ cells proliferated in an IL-2-dependent manner to crosslinked anti-T cell receptor antibodies (anti-CD3-Seph). Similarly, both CD4+ and CD8+ cells became IL-2 responsive after incubation in T suppressor cell growth factor (TsGF), a newly described approximately 8,000 Mr product of activated CD4+ cells. In support of our hypothesis, however, we observed that subpopulations of CD4+ and CD8+ cells, possessing distinct cell-surface antigens, showed differential responses to these stimuli. Those cells of suppressor-inducer or suppressor-effector phenotype failed to proliferate when cultured in anti-CD3-Seph plus IL-2, but did proliferate in an IL-2-dependent manner to TsGF. Furthermore, the suppressor-effector population was unresponsive to TsGF plus IL-2 when cocultured in anti-CD3-Seph, suggesting that functionally induced Ts may be refractory to growth stimuli. Conversely, cells with helper-inducer or cytolytic phenotype proliferated when incubated in anti-CD3-Seph and IL-2, while remaining essentially unresponsive to TsGF and IL-2. The results could not be explained by differences in the level of CD3 expression by the T cell subsets. Thus, cells within the helper and suppressor lineages appear to have distinct and reciprocal patterns for the induction of IL-2 responsiveness.

Human suppressor T cells: induction, differentiation, and regulatory functions.

T-cell-mediated suppression of human immune responses involves a complex interaction between distinct lymphocyte subsets with suppressor-inducer and suppressor-effector functions. Recent studies with subset-specific monoclonal antibodies have defined a characteristic phenotype of suppressor-inducer cells (CD4+ Leu8+ 2H4+ 4B4-) that can be distinguished from that of helper cells for antibody synthesis (CD4+ Leu8- 2H4- 4B4+). Similarly, suppressor-effector cells (CD8+CD11+Tp44-) can typically be defined as a subset separable from cytotoxic T cells (CD8+CD11-Tp44+). Both antigen-specific and nonspecific interactions are important in suppressor T-cell activation and function. Soluble signals required for differentiation of CD8+ suppressor cells include an indomethacin-sensitive monocyte product and interferon gamma. In contrast, proliferation of the CD8+ suppressor cell subset depends on stimulation first by a product of CD4+Leu8+ cells, T suppressor cell growth factor, and second by interleukin 2. Although the molecular basis of antigen-specific interactions between CD4+ and CD8+ cells in suppressor cell generation has not been defined, it may involve both conventional, presumably MHC-restricted, interactions between antigen and antigen receptors, as well as anti-idiotypic interactions of suppressor-effectors with determinants on suppressor-inducer receptors. Progress in elucidating requirements for activation, growth, and differentiation of suppressor cells should facilitate long-term culture of such cells and lead to clearer understanding of mechanisms of suppressor-cell mediated immunoregulation.

Opposing immunoregulatory functions of CD8+ lymphocytes: a requirement for monocytes in suppressor cell induction.

We have found that the induction of suppressor T cell (Ts) function in pokeweed mitogen (PWM)-stimulated cultures of peripheral blood mononuclear cels (PBMC) depends on the concentration of monocytes in inductive cultures. When cultured for 7 to 8 days in a physiologic concentration of monocytes (10 to 15%) suppressor cells differentiated with the surface phenotype CD8+ DR+ Leu-7- Leu-8+ Tp44-. Suppressor function, as assessed in secondary cultures of fresh PWM-stimulated CD4+ cells, was partially radiosensitive, and its induction could be partially inhibited by treatment with indomethacin. Culture supernatants of PWM-pulsed CD4+ cells could induce CD8+ suppressor cells only when monocytes were included in cultures for supernatant production. In marked contrast, if the monocyte concentration of PWM-stimulated T cells was reduced to less than 5%, CD8+ cells harvested from such cultures substantially augmented proliferation of PWM-stimulated CD4+ cells in assay cultures. Amplifier cells from monocyte-depleted cultures, were also DR+Tp44-. Suppressive activity of the CD8+ subset was restored simply by addition of monocytes to purified T cells, reconstituting the concentration present among unfractionated PBMC. Addition of IL 1 could not replace the requirement of monocytes for suppressor cell induction either in PWM-stimulated primary cultures or in culture supernatants. The data thus demonstrate that the regulatory activity of CD8+ lymphocytes is critically dependent on the conditions of cellular activation; at concentrations of monocytes normally present in peripheral blood, PWM stimulation induced potent suppressor activity, whereas under conditions of moderate monocyte depletion the regulatory activity of the same phenotypic subset of CD8+ cells was reversed. The experiments thus suggest that the functional consequences of an activating stimulus may depend on regulatory effects of monocytes in CD8+ suppressor cell induction.