Corticosteroid-induced suppression of murine B cell immune response antigens

The quantitative variation in expression of B cell surface immune response-associated antigens (sIa) that is induced by in vivo i.v. administration of dexamethasone was studied by flow microfluorometry. Injection of 40 micrograms of dexamethasone resulted in a 35 to 40% reduction in the expression of sIa within 3 hr, reached its maximum effect within 6 hr, which on average resulted in 75% suppression of control values of sIa, and by 12 hr after injection began returning towards baseline levels. The suppressive effect of dexamethasone on B cell sIa was dose dependent with respect to the length of time required to reach maximal suppression, as well as with respect to the duration of suppression that was attained. When injections of dexamethasone were repeated on consecutive days, no additional increase in the level of sIa suppression achieved was observed. B cell sIa was also diminished after injection of dexamethasone into athymic nude mice, which suggests that the suppressive effect of dexamethasone on B cell expression of sIa is not a T cell-dependent phenomenon. Taken together, these data suggest that the suppression of B cell sIa by corticosteroids may be a means whereby endogenous or exogenous corticosteroids are able to influence the normal as well as abnormal immunologic state.     

Selective effects of 2,3,7,8-tetrachlorodibenzo-p-dioxin and corticosteroid on in vitro lymphocyte maturation

The environmental contaminant 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) and the corticosteroid dexamethasone have potent effects on lymphocyte function, although the effects of the former have not been well characterized. In the present studies murine B cell maturation was used as a model system to examine and compare the effects of TCDD and dexamethasone on cell function. Immunosuppression by TCDD and dexamethasone is mediated by binding to specific intracellular R referred to as the Ah and glucocorticoid R, respectively. Although both compounds were comparable in their ability to inhibit antibody responses to the T-independent antigen TNP-LPS, the events responsible for suppression were found to be distinct. Dexamethasone, although affecting multiple stages of B cell maturation, had its primary effect very early, manifested by inhibition of the phosphoinositide signal transduction pathway. This was evidenced by a decrease in accumulation of inositol phosphate and surface Ia antigen expression as well as an inability to enter the cell cycle after stimulation with anti-Ig. In contrast, neither early signaling events nor proliferation were affected in B cells treated with TCDD. However, TCDD inhibited Ig secretion after stimulation of B cells with T cell-replacing factor, suggesting that TCDD modulates the differentiation of B cells into plasma cells. These differential results were confirmed by monitoring the expression of surface antigens that occur on B cells, including Ia, 7D4, and PC.2, during this maturational process. Whereas dexamethasone inhibited the expression of surface antigens that occur early in maturation (Ia and 7D4), TCDD blocked only the expression of the plasma cell marker PC.2. Although TCDD altered later stages of the B cell cycle, the presence of TCDD was required at the time of initial activation to be effective, suggesting that TCDD may interfere with early cell programming.     

In vivo administration of anti-I-A antibody induces the internalization of B cell surface I-A and I-E without affecting the expression of surface immunoglobulin

Injection of a hybridoma anti-Ia antibody into adult mice results in a dramatic reduction in the expression of B cell sIa without affecting the expression of sIgD or sIgM. This anti-Ia-mediated modulation of B cell sIa occurs within 3 hr and attains it maximum effect within 18 hr after injection of antibody. There is a rapid reexpression of B cell Ia when such sIa- B cells are cultured in vitro. Culture of B cells in vitro with anti-Ia antibody has no discernible effect on the expression of B cell sIa, nor does it prevent the reexpression of sIa on sIa- B cells obtained from anti-Ia-injected mice. Injection of anti-I-A antibody suppresses the expression of both I-A and of I-E, and similarly, injection of anti-I-E suppresses the expression of B cell I-E and I-A antigens. When fluorescein-labeled monoclonal anti-I-A antibody is injected into mice, a significant fraction of B cell sIa can be demonstrated to be internalized by the B cell. The potential immunologic significance of this phenomena of anti-Ia-mediated modulation of B cell sIa is discussed.     

Changes in the expression of B cell surface markers on complement receptor-positive and complement receptor-negative B cells induced by phorbol myristate acetate

The ability of phorbol myristate acetate (PMA) to induce changes in the expression of B cell surface markers on CR- and CR+ B cells from normal mice in an in vitro culture system was examined. The markers studied were CR, sIgM, sIgD, and sIa. CR- B cells acquired the CR after overnight incubation with PMA. A twofold increase in sIa expression on CR- and CR+ B cells was also noted, whereas the staining intensity of sIgM and sIgD decreased on both B cell populations. These changes in the expression of surface markers took place without detectable increases in cell proliferation, cell size, or RNA content. Furthermore, the same effects were observed when CR- and CR+ B cells were prepared from a small B cell population purified by elutriation. It therefore appears that PMA can exert its effect directly on small, resting B cells.     

Increased expression of I-region-associated antigen (Ia) on B cells after cross-linking of surface immunoglobulin

Both surface Ig (sIg) surface Ia (sIa) have been shown to have important roles in B lymphocyte activation. In order to investigate a possible relationship between these molecules, we studied the effects of cross-linking of sIg on the expression of sIa, as measured by fluorescence-activated cell sorter analysis of lymphoid cells stained with conventional anti-Ia anti-serum or with fluorescein-labeled anti-Ia antibodies. Exposure of cells for 24 hr in vitro to anti-delta, anti-mu, anti-kappa antibodies, or their F(ab')2 fragments induced a very dramatic increase in expression of sIa. Similarly, i.v. injection of anti-delta antibodies into adult mice induced a 2- to 3-fold increase in expression of B cell sIa on spleen, lymph node, and Peyer's patch lymphocytes. There was no increase under these conditions in expression of other B lymphocyte surface antigens, including H-2, 4B9, and 17C9. Furthermore, exposure of B lymphocytes to antibodies directed to B lymphocyte surface antigens other than sIg did not result in an increase in expression of sIa. The anti-Ig-induced increase in sIa expression appeared to be T independent, required cellular protein synthesis, and required more time to occur than did the cross-linking and removal of sIg. This increase in expression of sIa did not occur on B lymphocytes obtained from mice younger than 3 wk old. This increase in expression of sIa may reflect a proximal event in B lymphocyte activation that occurs after cross-linking of sIg by antigen and that may enhance subsequent cellular interactions involving B lymphocytes.     

Antibodies against cortisol block suppressive effects of corticosteroids on lymphocytes in vitro.

Lymphocyte transformation assays were used to test the ability of antibodies against cortisol to reduce bioactivity of corticosteroids in vitro. Mononuclear cells were separated from whole bovine blood and cultured in the presence of PHA alone, PHA + steroid, PHA + steroid + anticortisol, or PHA + steroid + anti-bovine serum albumin. Tritiated thymidine uptake was determined for all groups during the last 24 hr of a 72-hr culture period by scintillation counting. Polyclonal anticortisol against cortisol-bovine serum albumin conjugated in the 21 position was more effective in blocking cortisol activity than monoclonal anticortisol built against conjugates in the 3 position. The steroids that suppressed PHA-induced lymphocyte proliferation in a concentration-dependent manner were: cortisol, corticosterone, dexamethasone, prednisolone, 11-deoxycortisol, and 11-deoxycorticosterone. Aldosterone, cortisone, cholesterol, estradiol, and progesterone did not exhibit concentration-dependent effects and, thus, were not considered suppressive. These concentration-independent steroids were also the least suppressive (with the exception of aldosterone). Anticortisol was able to reduce bioactivity of suppressive corticosteroids that had an 11-hydroxy group, suggesting the antibody was primarily made against this site. Anti-BSA was not effective in blocking corticosteroid activity, but it did enhance proliferation of lymphocytes if added in combination with weakly suppressive steroids. Anticortisol also had an enhancing effect when added with some weakly suppressive steroids. We conclude that antibodies against cortisol are capable of reducing bioactivity of steroids that strongly suppress lymphocyte proliferation. Additionally, the 11-hydroxy group may be an important antigenic determinant of steroid molecules.     

Corticosteroids enhance the binding of recombinant interferon-gamma to cultured human monocytes

Human peripheral blood monocytes possess receptors on their surface for human interferon-gamma (IFN-gamma). Inasmuch as the biologic effects of IFN-gamma are thought to be mediated through binding of the molecule to this receptor, modulation of receptor number may be a means for enhancing the effect of IFN-gamma. We examined this possibility by treating human monocytes in culture with dexamethasone. At a dexamethasone concentration of 200 nM, there was a twofold increase in the number of 125I-recombinant IFN-gamma molecules bound to the cell. An effect was noted at concentrations of dexamethasone greater than 50 nM, and was observed as early as after 18 hr of treatment. The observed effect was the result of both a 50% decrease in receptor number in untreated cells and an increase to pretreatment levels or greater in cells incubated with dexamethasone. These results suggest that dexamethasone may modulate the effects of IFN-gamma on monocytes by changes in receptor number.     

Modulation of the IgE immune response to BSA by fragments of the antigen. I. Suppression by free fragments and by fragments conjugated to homologous gamma-globulin

Nonimmunogenic peptic fragments of bovine serum albumin (BSA), Fraction Ia, suppressed immune response to BSA in mice. Splenic T lymphocytes from mice treated with these fragments suppressed the anti-DNP response in irradiated mice reconstituted with DNP-BSA-primed cells, indicating carrier-specific suppression. The conjugate of Fraction Ia with mouse γ-globulin (MGG) was found to be an effective suppressive substance but it did not induce suppressor T cells. B cells from mice given Ia-MGG were unresponsive to BSA when transferred to irradiated recipients along with either normal or BSA-primed T cells. Thus, unresponsiveness to BSA was mediated by either T or B lymphocytes, depending whether the inducing substance was a free fragment of the antigen or fragments conjugated to homologous γ-globulin.     

Glucocorticoids Enhance Histamine-Evoked Catecholamine Secretion from Bovine Chromaffin Cells

Abstract: The synthetic glucocorticoid dexamethasone enhanced histamine-evoked catecholamine secretion from cultured bovine chromaffin cells. Dexamethasone enhanced the effects of histamine on both adrenergic (epinephrine-rich) and noradrenergic (norepinephrine-rich) chromaffin cells but had a more dramatic effect on noradrenergic cells. Histamine-evoked secretion in noradrenergic cells appeared to become rapidly inactivated, whereas the rate of secretion in adrenergic cells was nearly constant for up to 2 h; dexamethasone treatment attenuated the inactivation seen in noradrenergic cells. The effect of dexamethasone appeared after a lag of several hours and was maximal by 24 h. The EC₅₀ for dexamethasone was ∼1 n M . The effect of dexamethasone was mimicked by the glucocorticoid agonist RU 28362 and was blocked by the antagonist RU 38486, indicating that the effects of these steroids were mediated by the glucocorticoid or type II corticosteroid receptor. Histamine-evoked catecholamine secretion in both dexamethasone-treated and untreated cells was blocked by the H₁ histamine receptor antagonist mepyramine but was not affected by the H₂ antagonist cimetidine; thus, dexamethasone appeared to enhance an H₁ receptor-mediated process. In the absence of glucocorticoids, H₁ receptor mRNA levels were higher in adrenergic than in noradrenergic cells. Dexamethasone increased H₁ receptor mRNA levels in both cell types. The increased expression of H₁ receptors presumably contributes to the enhancement of histamine-evoked catecholamine secretion by glucocorticoids. Glucocorticoids may play a physiological role in modulating the responsiveness of chromaffin cells to histamine and other stimuli.     

Stimulation and inhibition of human T cell subsets by wheat germ agglutinin

Wheat germ agglutinin (WGA), a tetravalent lectin, has both stimulatory and inhibitory effects on human T lymphocytes. It has been suggested that these actions are related and that WGA selectively stimulates a suppressive subset of T cells. We studied the ability of WGA to stimulate and inhibit subpopulations of human peripheral blood mononuclear cells (PBMC) known to have helper or suppressor activity. Fresh human PBMC were depleted of either T4+ or T8+ cells by using antibody-mediated complement lysis. The resultant cell populations were stimulated with WGA, and the proliferative response was assessed by [3H]thymidine incorporation, IL 2 receptor expression, the ability to elaborate IL 2 in culture supernatants, and the susceptibility to inhibition by the monoclonal antibody anti-Tac. Similar experiments with cells from a WGA-responsive continuous T cell culture were also performed. WGA inhibited phytohemagglutinin (PHA)-induced proliferation of PBMC depleted of either T4+ or T8+ cells. WGA also inhibited PBMC that had been depleted of adherent cells and Ia+ cells and then induced to proliferate with a combination of TPA and PHA. Our findings indicate that WGA induces IL 2-dependent proliferation in a small proportion of both T4+ and T8+ lymphocytes. We also provide evidence that the inhibitory activity of WGA is not mediated by a T4+, T8+, or Ia+ cell, suggesting that WGA acts directly on the proliferating cell rather than selectively stimulating a suppressive subpopulation.     

Protection of peritoneal macrophages by granulocyte/macrophage colony-stimulating factor (GM-CSF) against dexamethasone suppression of killing of Aspergillus, and the effect of human GM-CSF

Murine peritoneal macrophages in vitro could kill Aspergillus fumigatus conidia, and this activity could be suppressed with dexamethasone. Treatment with granulocyte/macrophage colony-stimulating factor (GM-CSF) alone did not boost killing, but GM-CSF treatment concurrently with dexamethasone reversed the dexamethasone suppression. Both recombinant human and recombinant murine GM-CSF were equivalent in this activity, even though the human reagent reportedly does not stimulate differentiation of murine stem cells. Recombinant human GM-CSF could also reverse dexamethasone suppression of bronchoalveolar macrophage conidiacidal activity. Sequential studies with peritoneal macrophages indicated that recombinant human GM-CSF pretreatment also blocked dexamethasone suppression, but the GM-CSF treatment given after dexamethasone did not block the suppressive effect. Recombinant human GM-CSF did not boost spleen cell proliferation to a mitogenic stimulus, and did not reverse dexamethasone suppression of proliferation. These studies suggest GM-CSF treatment prior to and concurrent with steroid immunosuppression may ameliorate the steroid effect on tissue macrophage antifungal activity, but does not affect steroid suppression of T-cell immunity.     

Role of CD11a/CD18-CD54 interactions in suppression of human B cell responsiveness by CD4+ suppressor T cells.

The role of leukocyte function-associated Ag-1 (LFA-1, CD11a/CD18) and intercellular adhesion molecule 1 (ICAM-1, CD54) interactions in the suppression of human B cell function by immobilized anti-CD3-activated CD4+ T cells was examined by studying the effects of mAb to these determinants. The suppressive activity was assessed by the effects of CD4+ T cells without mitomycin C treatment activated by immobilized anti-CD3 for 72 hr on the differentiation into Ig-secreting cells of B cells activated for 72 hr with immobilized anti-CD3-stimulated CD4+ T cells that had been treated with mitomycin C (T4 mito). Suppression was not observed when activated CD4+ T cells and B cells were separated by filter membranes, indicating that the suppression requires the direct interactions between anti-CD3-activated CD4+ T cells and activated B cells. In this model system, mAb to either the alpha (CD11a) or beta (CD18) chain of LFA-1 or ICAM-1 (CD54) reversed the suppression of B cell function by suppressor CD4+ T cells significantly. Reversal of suppression of B cell function was most marked when activated B cells were treated with mAb to ICAM-1 and suppressor CD4+ T cells were treated with mAb to LFA-1, but not vice versa. Studies using fluorescence-activated cell sorter revealed marked increase of expression of ICAM-1 on B cells after 72 hr of activation with immobilized anti-CD3-stimulated T4 mito. These results indicate that the interactions between LFA-1 and ICAM-1 play an important role in mediating the suppressive activity of anti-CD3-activated CD4+ T cells to B cells. Moreover, the data are consistent with a model of T-cell-mediated B cell suppression in which interactions between LFA-1 on suppressor T cells and ICAM-1 on activated B cells play a central role in the suppression of B cell function.     

Nitric oxide production is required for murine resident peritoneal macrophages to suppress mitogen-stimulated T cell proliferation. Role of IFN-gamma in the induction of the nitric oxide-synthesizing pathway

Lymphocyte proliferation in Con A- or LPS-stimulated murine splenic cell (SC) cultures was suppressed by the addition of excess macrophages. In Con A-stimulated cultures, suppression was associated with the expression of nitric oxide-synthesizing pathway (NOSP) activity as demonstrated by the accumulation of nitrite, a degradation product of nitric oxide (NO), in the culture supernatants. That NO, a cytotoxic and anti-proliferative metabolite of l-arginine, or other reactive nitrogen intermediates generated through the NOSP mediated the suppressive effect was suggested by the reversal of suppression brought about by the addition of a specific inhibitor of the NOSP (NG-monomethyl-l-arginine acetate) to the culture media. No NOSP activity was detectable in LPS-stimulated SC/macrophage cocultures. The role of T cell-derived IFN-gamma in the induction of the NOSP was investigated by the use of anti-IFN-gamma-mAb. Antibody-treated Con A supernatants failed to induce the NOSP in macrophages, and the addition of the mAb to Con A-stimulated SC/macrophage cocultures obviated the suppressive effects. Indomethacin and catalase only partially restored proliferation in Con A-stimulated SC/macrophage cocultures but were remarkably efficient in preventing macrophage-dependent suppression when LPS was used as the mitogenic stimulus. These results demonstrate a regulatory system of potential relevance in sites of predominant macrophage infiltration by which T cell-derived IFN-gamma activates the production of the mediator, NO, that suppresses T cell proliferation. In addition, these data demonstrate that, although the suppressive effects of excess macrophages appear to be expressed nonspecifically toward both T and B cells, suppression is mediated through a different mechanism in each case.     

Steroid control of steroidogenesis in isolated adrenocortical cells: molecular and species specificity

The molecular and species specificity of glucocorticoid suppression of corticosteroidogenesis was investigated in isolated adrenocortical cells. Trypsin-isolated cells from male rat, domestic fowl and bovine adrenal glands were incubated with or without steroidogenic agents and with or without steroids. Glucocorticoids were measured by radioimmunoassay or fluorometric assay after 1-2 h incubation. Glucocorticoids suppressed ACTH-induced steroidogenesis of isolated rat cells with the following relative potencies: corticosterone greater than cortisol = cortisone greater than dexamethasone. The mineralocorticoid, aldosterone did not affect steroidogenesis. Suppression by glucocorticoids was acute (within 1-2 h), and varied directly with the glucocorticoid concentration. Testosterone also suppressed ACTH-induced steroidogenesis. Glucocorticoid-type steroids have equivalent suppressive potencies, thus suggesting that these steroids may induce suppression at least partly by a common mechanism. Although corticosterone caused the greatest suppression, testosterone was more potent. The steroid specificity of suppression of cyclic AMP (cAMP)-induced and ACTH-induced steroidogenesis were similar, suggesting that suppression is not solely the result of interference with ACTH receptor function or the induction of adenylate cyclase activity. Exogenous glucocorticoids also suppressed ACTH-induced steroidogenesis of cells isolated from domestic fowl and beef adrenal glands, thus suggesting that this observed suppression may be a general mechanism of adrenocortical cell autoregulation.     

Growth regulation of transformed T cells by nonactivated macrophages: the role of Ia expression

We studied the influence of unactivated mouse peritoneal macrophages on the proliferative capacity of a spontaneously transformed MRL-lpr/lpr T cell clone. Macrophages, 25%, induced a reduction in proliferative rate from 20% to 95% measured by [3H]thymidine incorporation and microscopic cytometry. MHC-compatible (H-2k) macrophages caused growth inhibition reciprocal to the amount of Ia expression on the macrophage. Thus, with increasing preculture of the macrophages there was both decreasing Ia and increasing suppression. H-2-incompatible macrophages had maximal inhibitory capacity without preincubation. Macrophages derived from the peritoneum of MRL-lpr/lpr mice were less suppressive than macrophages from other H-2k mice. In contrast to the case of activated macrophages in other studies, in the present system there was no killing of T cells, only reduction in proliferation. The inhibitory effect of the macrophages correlated with the spontaneous formation of rosettes between the macrophages and the T cell clone. The number of rosettes forming a single layer of T cells around the macrophages, but not the number of rosettes with multiple layers of cells, was reciprocally related to the amount of Ia expression. The results suggest that macrophages bear a surface structure that influences and modulates the growth of T cells.     

Prevention of the in vitro myelosuppressive effects of glucocorticosteroids by interleukin 1 (IL 1)

We investigated the effects of dexamethasone on the formation of granulocyte/macrophage colonies by murine bone marrow cells cultured with colony-stimulatory factors (CSF) in semisolid agar. Dexamethasone (10(-7) M) completely inhibited the formation of colonies in response to L929 CSF but had no effect on the response to CSF in the culture supernatants of the murine macrophage cell line, PU5-1.8. We postulated that a cofactor, interleukin 1, present in the PU5-1.8 supernatants was responsible for protecting colony formation against steroid suppression. Interleukin 1, isolated from culture supernatants of PU5-1.8 and from culture supernatants of human acute monocytic leukemia cells, blocked the inhabitory effects of dexamethasone on colony formation in response to L929 CSF. Moreover, dexamethasone inhibited colony formation in response to PU5-1.8 culture supernatants when interleukin 1 was absent. We also examined interleukin 2 for possible protective effects. Although crude interleukin 2 preparations (supernatants of spleen cells cultured with concanavalin A) blocked dexamethasone inhibition, purified interleukin 2 had no protective effects. These data indicate that interleukin 1 protects colony formation by a pathway that is independent of interleukin 2 and that supernatants of spleen cells activated with concanavalin A probably contain significant amount of interleukin 1.