Cyclosporin A inhibits the proliferative response and the generation of helper, suppressor and cytotoxic T-cell functions in the autologous mixed lymphocyte reaction

Chemical oxidation or reduction of lymphocyte cell surface thiol or disulfide groups, respectively, has been shown to alter the proliferative activity of murine T cells. S-2-(3-aminopropylamino)ethylphosphothioic acid, a compound containing no free thiol group until it is intracellularly dephosphorylated, did not enhance Con A-induced proliferation which suggested that thiols did not mediate proliferative enhancement via an intracellular mechanism. Glutathione, an impermeant thiol, enhanced T-cell proliferation 68% as effectively as 2-mercaptoethanol (2-ME), which suggested that the thiol-sensitive site was at the cell surface. A battery of structural analogs to 2-ME was employed to elucidate the chemical requirements for the biological activity of the thiols. The necessity for a hydrogen-binding moiety on the thiol reagent was determined by the use of non-hydrogen-binding analogs and by competitive inhibition of the thiol-enhancing activity of 2-ME by non-thiol-containing hydrogen-binding analogs. Pretreatment of cells with the copper:phenanthroline complex (CuP), an impermeant oxidant of thiol groups, reduced the Con A-induced response >79%; however, the presence of 2-ME in culture completely reversed the inhibitory effect of CuP pretreatment. Oxidation of T cells by high oxygen tension (17% O₂) also ablated the Con A response but did not alter the response to Con A + 2-ME. Protection from oxidative inhibition also was afforded T cells by sequential reduction and blockage of cell surface thiol groups. Finally, a model which correlates the chemical study of cell surface residues with T-lymphocyte responsiveness is presented.     

Oxidatively stressed lymphocytes remain in G0/G1a on mitogenic stimulation

Thiol modifiers and oxidants inhibit lymphocyte activation. To investigate which of the many cell functions sensitive to oxidation are critical in this inhibition, mouse splenic lymphocytes were treated with oxidants prior to exposure to mitogen, and progression into the cell cycle was assayed. Different treatments were used to chemically dissect different potential targets within the cell: copper phenanthroline (CuP), to oxidize surface sulfhydryls; N-ethyl maleimide (NEM), to alkylate extra- and intracellular thiols; and hydrogen peroxide, which generates the highly reactive hydroxyl radical within the cell. Progression into the cell cycle was assayed with acridine orange (AO) and assays of interleukin-2 (IL-2) production and IL-2 receptor (IL-2R) expression. The contribution of ADP-ribosylation to inhibition of mitogenesis was assessed using 3-aminobenzamide (3AB) to inhibit adenosine 5'-diphosphate (ADP)-ribose transferases. The results indicate that the CuP and NEM treatments both produce two independent inhibitory effects, that is, a failure in the production of and response to IL-2. Cells treated with these compounds were able to progress only through G1a upon mitogenic stimulation. H2O2 had more complex effects. Both ADP-ribosylation and modulations of cytosolic Ca2+ were involved in the inhibitory effects. With lower inhibitory doses of H2O2, lymphocytes were completely unresponsive to mitogen and failed to exit Go upon mitogenic stimulation. If intra- and extracellular Ca2+ were buffered before treatment with H2O2, higher concentrations were required, and under these conditions cells were able to enter G1a but could not progress into G1b. Under neither of these conditions could cells produce IL-2 or express IL-2R.     

Oxidatively stressed lymphocytes remain in Go/Gla on mitogenic stimulation

Thiol modifiers and oxidants inhibit lymphocyte activation. To investigate which of the many cell functions sensitive to oxidation are critical in this inhibition, mouse splenic lymphocytes were treated with oxidants prior to exposure to mitogen, and progression into the cell cycle was assayed. Different treatments were used to chemically dissect different potential targets within the cell: copper phenanthroline (CuP), to oxidize surface sulfhydryls; N-ethyl maleimide (NEM), to alkylate extra- and intracellular thiols; and hydrogen peroxide, which generates the highly reactive hydroxyl radical within the cell. Progression into the cell cycle was assayed with acridine orange (AO) and assays of interleukin-2 (IL-2) production and IL-2 receptor (IL-2R) expression. The contribution of ADP-ribosylation to inhibition of mitogenesis was assessed using 3-aminobenzamide (3AB) to inhibit adenosine 5′-diphosphate (ADP)-ribose transferases. The results indicate that the CuP and NEM treatments both produce two independent inhibitory effects, that is, a failure in the production of and response to IL-2. Cells treated with these compounds were able to progress only through G1a upon mitogenic stimulation. H₂O₂ had more complex effects. Both ADP-ribosylation and modulations of cytosolic Ca²⁺ were involved in the inhibitory effects. With lower inhibitory doses of H₂O₂, lymphocytes were completely unresponsive to mitogen and failed to exit Go upon mitogenic stimulation. If intra- and extracellular Ca²⁺ were buffered before treatment with H²O², higher concentrations were required, and under these conditions cells were able to enter G1a but could not progress into G1b. Under neither of these conditions could cells produce IL-2 or express IL-2R.     

Evolution of the lymphoid system. I. Evidence for lymphocyte heterogeneity in rainbow trout revealed by the organ distribution of mitogenic responses.

Leukocytes from the various lymphoid tissues of rainbow trout (RBT) were tested for their capacity to respond to the lymphocyte mitogens concanavalin A (Con A), lipopolysaccharide (LPS), and purified protein derivative of tuberculin (PPD). Thymocytes responded to Con A but not to LPS or PPD. In contrast, leukocytes from anterior kidney were stimulated with LPS but not with Con A or PPD. Cells from spleen and peripheral blood were stimulated by each mitogen. However, the degree of stimulation at optimally stimulatory concentrations of each mitogen was distinctive. The finding that the patterns of mitogenic responses of cells from each tissue were significantly different suggested that there is lymphoid heterogeneity in the RBT with a unique tissue distribution. The species source of serum utilized as a medium supplement appeared to be capable of markedly affecting mitogenesis. Thus, LPS and PPD stimulation occurred in medium supplemented with rainbow trout serum (RBTS). On the other hand, LPS and PPD stimulation was not observed in medium supplemented with fetal bovine serum (FBS), with the exception of peripheral blood leukocytes which were stimulated by LPS in culture medium supplemented with FBS. Con A stimulated leukocytes from each lymphoid tissue in medium supplemented with RBTS and, with the exception of cells from anterior kidney, also stimulated cells from each tissue in medium supplemented with FBS. The kinetic profiles of the responses of peripheral blood leukocytes to Con A, LPS, and PPD suggested that the extent as well as the time required for maximal stimulation was dependent on the dose of mitogen.     

Alkaline phosphatase activity as a membrane marker for activated B cells

Alkaline phosphatase activity was assayed by a microtiter assay (with p-nitrophenylphosphate used as substrate) in the plasma membrane of mouse spleen cells activated in vitro by the B cell mitogen LPS and the T cell-dependent B cell mitogen, PWM. No activity was detected in spleen cells cultured in the presence of the T cell mitogens PHA and Con A. This alkaline phosphatase activity was detected in the blast-enriched 30 to 40% fraction of discontinuous Percoll gradients in LPS-treated cultures, and the enzymatic activity assayed was susceptible to inhibition by the alkaline phosphatase inhibitors EDTA and L-phenylalanine. These data support the idea that the membrane alkaline phosphatase activity could be used as a marker for activated B cells.     

A reappraisal of the effector cells mediating mitogen induced cellular cytotoxicity.

The ability of mitogens to induce cytotoxic effector reactions in vitro has been studied to investigate basic mechanisms of cell mediated cytotoxicity. The type of mitogen, the source of effector cells, and the nature of the target cell are all critical variables in determining the characteristics of the cytotoxic event in this system. Spleen cells and bone marrow cells from congenitally athymic nude mice as well as from their heterozygous control littermates were capable of mediating lysis of RBC targets in the presence of either PHA or Con A. Removal of macrophages from these effector populations by adherence columns, density gradient centrifugation, and carrageenan treatment failed to abrogate this cytotoxic capacity. However, purified macrophages themselves also were capable of mediating mitogen induced killing of RBC targets, although the kinetics of this cytotoxicity were substantially different from that induced by lymphocytes. In contrast to these observations, the capacity of mitogen stimulated cells to kill metabolically active complex targets like the P815 mastocytoma or cultured L cells appears to be exclusively a T lymphocyte dependent function. In addition, blastogenic transformation of the effector cells with the T cell mitogens PHA and Con A, but not with the B cell mitogen LPS, leads to enhanced killing of these complex targets. These data suggest that mitogen or lectin induced cellular cytotoxicity can detect at least three different active effector cell types (B cells, T cells, and macrophages) acting via at least four different mechanisms.     

Suppressor cells present in the spleens of Trypanosoma cruzi-infected mice.

Infection with Trypanosoma cruzi decreases the ability of spleen cells from mice to respond to either T cell, concanavalin A (Con A), or B cell, lipopolysaccharide (LPS), mitogens. The effect of infection on the mitogenic response depends on the elapsed time between the day of infection and the time of mitogen presentation. Responses early in infection are normal, whereas later responses to either mitogen are depressed. Spleen cells from late trypanosome-infected mice inhibit the ability of normal spleen cells to respond to Con A or LPS. The cell in the T. cruzi-infected spleen cells responsible for this effect is nonadherent, sensitive to treatment with anti-mouse thymus serum plus complement, but insensitive to treatment with anti-immunoglobulin plus complement. These data indicate that infection with T. cruzi elicits over time the generation of T cells suppressive to T and B cell mitogenic responses.     

Effect of T- and B-lymphocyte mitogens on interactions between lymphocytes and macrophages.

The mitogenic response of murine T cells ² to Con A, S-Con A and PHA was found to be macrophage-dependent. Optimal mitogenic responses were obtained when macrophage-depleted T-cell populations were reconstituted with 5% normal peritoneal macro-phages. Studies were carried out to investigate the effect of T- and B-cell mitogens on in vitro physical interactions between murine lymphocytes and macrophages. This was done by determining the number of T- or B cells binding to macrophages in the absence and in the presence of T- and B cell mitogens, and comparing the results of these experiments with the induction of lymphocyte proliferation. Con A increased the binding of T cells to macrophages when used in mitogenic doses (1–5 μg/ml). Dose response experiments showed that the same dose of Con A which produced maximal mitogenic stimulation also induced the greatest number of T cells to bind to macrophages. Nonmitogenic doses of Con A (20–50 μg/ml) did not enhance the binding of T cells, while identical doses of S-Con A both induced T cell mitogenesis and increased the number of T cells bound to macrophages. Similar results were obtained with PHA. None of the B-cell mitogens tested (LPS, EPO 127 and LAgl) increased the binding of either T or B cells to macrophages. PWM, which is mitogenic for both T and B cells, increased the binding of T cells to macrophages, but not that of B cells. In brief, the four T-cell mitogens tested (Con A, S-Con A, PHA, and PWM) induced specific physical interactions between T cells and macrophages, while none of the B-cell mitogens had any effect on the physical interactions between either B or T cells and macrophages when used in mitogenic doses.     

Determination of mitogenic properties and lymphocyte target sites of Dolichos lablab lectin (DLA): comparative study with concanavalin A and galactose oxidase cell surface receptors

A mannoside-directed lectin has been isolated and purified from the seeds of Dolichos lablab L. by affinity chromatography. We have established that this glycoprotein, which displays high erythroagglutinating activity without blood group specificity, highly activates murine T lymphocytes, and we have described for the first time its mitogenic properties. Although its main properties are close to those of concanavalin A (Con A), the well-known mannoside-directed mitogen devoid of sugar moiety, several differences were found in some of the early events triggered by the two lectins during lymphocyte mitogenic stimulation: higher level of interleukin-2 (IL-2) synthesis, optimal dose for IL-2 synthesis at suboptimal mitogenic concentration, lack of ecto-5' nucleotidase inhibition, and lack of mitogenic inhibition at high lectin concentration. Because the two lectins did not act on the cell surface in exactly the same way, we have compared their receptors involved in mitogenesis on the plasma membrane of murine lymphocytes. We had previously established that the polyclonal activation of these cells probably occurred through high-molecular-weight receptors (200-230 kDa). Since the mitogenic stimulation of lymphocyte by galactose oxidase (GO), like that of Con A, was inhibited by DLA, we analyzed the cell surface receptors that were common to these three polyclonal mitogens. After labeling the neuraminidase/GO-treated cell surface glycoproteins with NaB3H4, we immunoprecipitated the Con A and DLA receptors which are the target of GO mitogenic action. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the precipitates demonstrated that there exist on the lymphocyte cell surface receptors common to the polyclonal mitogens DLA, Con A, and GO. Because Con A and DLA sterically inhibit GO mitogenic stimulation, the common glycoproteins which represent the necessary sites of oxidative mitogenic action are probably those which are involved in DLA and Con A-triggered mitogenesis, despite the different properties of the two lectins. These differences could be explained by the lower molecular weight receptors of the two lectins which are not identical.     

电剌大鼠的血清中淋巴细胞转化抑制因子的作用机制分析

Previous reports showed that EA stimulation (3V, 2Hz, 30 min/d, 5 d) induced the production of one or more lymphocyte proliferation-inhibitory factor(s) in the rat serum. In this paper, the mechanisms of the action for the inhibitory factor(s) to suppress lymphocyte proliferation were studied. (1) the lymphocytes from different immune organs of the mice were prepared and cultured with the rat serum stimulated by EA. The results show that the serum not only inhibited the mouse lymph node T cell proliferation induced by Con A, but also inhibited the mouse thymocyte and spleen T cell proliferation induced by Con A. When B cells were stimulated by LPS, the proliferative effect can also be inhibited significantly by the rat serum stimulated by EA. This implies that the effect of the lymphocyte proliferation-inhibitory factor(s) has no specificity. (2) Incubation of the mouse lymph node cell with serum for one hour is enough to cause an inhibitory effect on Con A stimulated lymphocyte proliferation. However, no inhibitory effect was observed if the mouse lymph node cells were incubated with Con A for 15 min or 30 min before the addition of rat serum. The results demonstrate that the lymphocyte proliferation-inhibitory factor(s) act on the early events of T lymphocyte activation induced by Con A. (3) Protein kinase C (PKC) is a key link in the activation of T and B lymphocyte proliferation by Con A and LPS respectively. So it would be interesting to learn whether the inhibitory effect of the lymphocyte proliferation-inhibitory factor(s) is caused by the inhibition of PKC activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

电针大鼠的血清中淋巴细胞转化抑制因子的作用机制分析

本室以前的工作表明:电针(2H_z,3V,30min/d)刺激 SD 大鼠双侧足三里-三阴交,5d后,大鼠血清中产生出淋巴细胞转化抑制因子,本工作对此抑制因子的作用机制进行了初步研究,主要结果如下:(1)电针大鼠的血清不仅显著抑制 Con A 刺激的小鼠淋巴结 T 淋巴细胞转化,还可显著抑制 Con A 刺激的小鼠胸腺细胞和脾脏 T 淋巴细胞转化;同时也发现电针大鼠的血清能显著抑制脂多糖(LPS)刺激的小鼠淋巴结 B 淋巴细胞转化。提示此淋巴细胞转化抑制因子对不同淋巴器官及不同类型的淋巴细胞无选择性作用。(2)将电针大鼠的血清同小鼠淋巴结细胞培养1h,电针大鼠的血清就可显著抑制 Con A 刺激的 T 淋巴细胞转化;将小鼠淋巴结细胞同 Con A 预培养30min,电针大鼠的血清的抑制作用便消失,提示电针大鼠血清中淋巴细胞转化抑制因子作用于 Con A 刺激 T 淋巴细胞活化的早期阶段,同时也排除了此抑制因子的细胞毒作用。(3)电针大鼠的血清显著抑制蛋白激酶 C(PKC)激活剂 PMA和 PMA 加 ca~(2+)通道 A23187刺激的小鼠淋巴结细胞转化,提示淋巴细胞转化抑制因子通过抑制 PKC 的活性或抑制 PKC 介导的细胞活化通路,抑制有丝分裂原刺激的淋巴细胞转化。     

Inhibition of the mitogenic response to lipopolysaccharide (LPS) in mouse spleen cells by polymyxin B.

The addition of low doses of the cationic polypeptide antibiotic, polymyxin B (PB), to cultures of mouse spleen cells inhibits lipopolysaccharide-(LPS) induced DNA synthesis but not that stimulated by PPD, PHA, or Con A. Inhibition is stoichiometric; the mitogenic response is suppressed by 50% at a weight ratio of PB:LPS of 0.055 to 1. Furthermore, PB-LPS complexes have a much reduced mitogenic capacity. These complexes inhibit the mitogenic response of spleen cells to unmodified LPS but not to PPD, Con A, or PHA. The inhibitory activity of PB is less effective when added after LPS is mixed with responding cells, achieving 50% inhibition when addition is made at 4 to 6 hr. Time course experiments indicate that partial inhibition is a reflection of a lower rate of DNA synthesis. Thus, PB inhibition of LPS mitogenesis apparently occurs as a result of formation of PB-LPS complexes with reduced mitogenic capacity. Specific inhibition by the complexes of mitogenesis induced by native LPS suggests that the inactive complex may bind to B cells but is unable to trigger them.     

Cytochalasin B enhances T cell mitogenesis by promoting expression of an interleukin 2 receptor

Low concentrations of cytochalasin B enhanced the T cell mitogenesis induced by concanavalin A (Con A) and interleukin 2 (IL-2). Mitogenesis was augmented by cytochalasin B given in the Con A-dependent early phase, or through T cell mitogenesis. Cytochalasin B did not enhance T cell mitogenesis when given only in the IL-2-dependent late phase. Use of the monoclonal antibody that directs the IL-2 receptor showed that cytochalasin B increased the expression of the IL-2 receptor induced by Con A. We concluded that cytochalasin b acts on an early phase of T cell mitogenesis and augments the expression of IL-2 receptor which enables certain nonresponsive T cells to respond to IL-2.     

Immunomodulating activity in supernatants from EBV immortalized lymphocytes

Summary Our earlier work has demonstrated that EBV immortalized B lymphocytes are involved in a factor dependent autostimulatory cycle. Soluble growth stimulating activity was released into culture supernatants by these growing B cells. Growth enhancing (GE) media from B lymphocyte lines, immortalized by EBV infection, contained soluble factor(s) which modulated the Con A response of normal human mononuclear cells. Conditioned media from these lines affected the Con A response in a biphasic manner, stimulating the blastogenic response at lower concentrations, while inhibiting at higher concentrations. At stimulatory concentrations, the blastogenic response to Con A began earlier than in controls and was markedly enhanced by day 2. GE media reduced the initial response of purified B cells to pokeweed mitogen. GE media did not support growth of IL-2 dependent cells. GE media from some EBV-carrying B cell lines had measurable IL-1 activity in the mouse thymocyte PHA response. GE media from LPS stimulated B lymphocyte lines produced significant IL-1-like effects on stimulated mouse thymocytes. These results suggested that these B cell lines may produce IL-1-like factors that cooperate in T cell responses. The possibility that such factors may play a role in B lymphocyte transformation by EBV is discussed.Supported by grants from the Concern Foundation and the Brigham Surgical Foundation     

Characterization of Cell Growth-Inhibitory Factor in Inflammatory Peritoneal Exudate Cells of Rats

We characterized the nature and reaction mode of the cell growth-inhibitory factor (here designated CGIF) from rat peritoneal exudate cells (PEC). The soluble fraction separated from the lysate of Enterococcus faecalis-induced 24 hr PEC completely inhibited Con A-induced thymocyte mitogenesis. Gel filtration chromatography showed that CGIF has a molecular weight of approximately 23–25 kDa. Isoelectric focusing with Rotofor indicates that the factor has an isoelectronic point of 5.8–6.4. CGIF was inactivated by treatment at 70 C, for 30 min or by tryptic digestion, but the activity was not destroyed by the reduction with dithiothreitol. As well as thymocyte proliferation, CGIF completely suppressed ³H-thymidine incorporation of splenocytes which were stimulated by either Con A or LPS, suggesting the factor is effective on both T and B cells. The acting point of the inhibitor appeared to be a later stage of the lymphocyte activation sequence, since it was still effective when added 28.5 hr after the addition of Con A. CGIF also reduced the viability of these cells when added with mitogens such as Con A or LPS. CGIF thus appears to be distinct from interleukin-1 receptor antagonist or transforming growth factor-β.     

Increased mitogenic reactivity of normal spleen cells to T lectins induced by thymus humoral factor (THF)

When normal spleen cells were incubated for 24 hr in medium containing thymic humoral factor (THF) and then stimulated by phytohemagglutinin (PHA) or concanavalin A (Con A), a significant increase in the mitogenic reactivity of these cells was observed. When stimulation to T lectins was performed simultaneously with THF, a strong inhibition in cell reactivity was found. It seems that these opposite effects of THF on cell reactivity to T lectins are determined by the sequence of events which lead to maturation of lymphoid cells. Thymic humoral factor does not modify the response of cells to B mitogen lipopolysaccharide (LPS), thus suggesting that this maturative effect on lymphoid cells is exerted on T lymphocytes only.     

Phylogeny of lymphocyte heterogeneity. II. Differential effects of temperature on fish T-like and B-like cells.

Lymphocytes from the bluegill, a freshwater fish, were observed to undergo in vitro mitogenic responses to a variety of “classical” mitogens. Using cell fractionation approaches based upon surface markers and in vitro mitogenesis, bluegill lymphocytes could be divided into two populations. One population responded to PHA and Con A but not to LPS, contained surface antigens in common with bluegill brain, and did not form spontaneous rosettes with rabbit erythrocytes. The other population responded to LPS but not to PHA or Con A, did not appear to contain surface antigens in common with brain, and did form rosettes with rabbit erythrocytes. The former population responded to mitogenic stimulation very well at 32 °C, whereas the latter population responded better at 22 than at 32 °C. The pattern of mitogenic responses and brain antigen distribution coupled with the observation that mixed lymphocyte responses were obtained at 32 but not at 22 °C makes it likely that the 32 °C responsive population represents the fish equivalent of T cells. The other population may be B cells. These data suggest that the immunosuppressive effects of low temperatures on cold-blooded animals may be effects on the generation of functional T cells and not on B cells.     

Proliferation of murine thymic lymphocytes in vitro is mediated by the concanavalin A-induced release of a lymphokine (costimulator).

Mitogen-induced proliferation of lymphocytes may in theory result directly from the interaction of mitogen with the cells, or indirectly as a result of the mitogen-stimulated release of lymphokines. In the case of murine thymic lymphocytes exposed to concanavalin A (Con A) in tissue culture, we have determined that mitogenesis depends upon a lymphokine. Interaction of the thymic lymphocytes with lectin is necessary, but not sufficient, for mitogenesis. A lymphokine, or costimulator for mitogenesis, is released by normal spleen or thymus cells during the first 16 hr of their exposure to Con A, and in the presence of a phytomitogen it stimulates thymic mitogenesis. Under conditions of low costimulator levels, no mitogenesis follows the interaction of Con A with cells. The response of adult CBA/J mouse thymocytes to phytohemagglutinin (PHA) is very low, compared to their response to Con A. When costimulator is added to PHA, the cells respond as well as they do to Con A. Costimulator does not act through Con A-binding sites on thymus cells. Its production is dependent on both cells carrying omega surface antigen (T lymphocytes) and adherent cells of the macrophage-monocyte series. The adherent population, but not the T cells, may be heavily irradiated without affecting production of costimulator. Costimulator is not a mitogen on its own.     

Possible mechanism of the preventive effect of BCG against diabetes mellitus in NOD mouse. I. Generation of suppressor macrophages in spleen cells of BCG-vaccinated mice.

With the aim of clarifying the mechanism of the suppressive action of BCG against insulitis and overt diabetes in NOD mice, we studied the effects of BCG on spleen cell populations and on the in vitro immune responses of spleen cells. The spleen cells of BCG-vaccinated mice showed much lower responsiveness to various mitogens such as Con A, PHA, PWM, and LPS than those of saline-treated mice. Low responsiveness to alloantigens was also observed. Flow cytometric analysis of the spleen cells revealed that Mac-1+ and Mac-2+ cells had increased while T and B cells had decreased in the BCG-vaccinated mice compared with the saline-treated mice at the time when the maximum level of inhibition of mitogen responses of BCG-vaccinated mice was observed. This suggests that the decreased in vitro immune response was due to the increase in macrophages which suppress lymphocyte functions. Support for this interpretation comes from the following two findings: (1) the restoration of mitogen responses of spleen cells when macrophages were eliminated by plastic adhesion or FACS sorting and (2) resuppression of PHA and Con A responses of plastic-nonadherent spleen cells by addition of adherent cells or flow cytometrically sorted Mac-1+ cells obtained from BCG-vaccinated mice. These results indicate the generation of suppressor macrophages after BCG vaccination and suggest that these macrophages prevent the autoimmune pathogenesis leading to diabetes in NOD mice.     

Inhibition of mitogen-stimulated T lymphocyte proliferation by calcitonin gene-related peptide

The effect of calcitonin gene-related peptide (CGRP) on mouse lymphocyte proliferation stimulated by mitogens was studied. CGRP (10(-10)-10(-7) M) dose-dependently inhibited the proliferative response of mouse lymph node cells and spleen cells stimulated by T cell mitogens concanavalin A (Con A) and phytohemagglutinin (PHA), whereas a B cell mitogen lipopolysaccharide (LPS) did not inhibit this response. The maximal inhibition by this peptide was 50% to 80% at 10(-8) and 10(-7) M. The addition of 10(-8) and 10(-7) M CGRP to lymph node cell cultures 24 hr after stimulation with Con A or PHA also had a significant inhibitory effect on the proliferative response. Furthermore, in the same concentration range (10(-10)-10(-7) M) CGRP increased intracellular cyclic AMP concentration in nylon wool nonadherent cells, but not in nylon wool adherent cells. CGRP had no significant effect on intracellular cyclic GMP concentration. In addition, specific binding of CGRP was observed in mouse spleen cells. Our present study suggests that CGRP inhibits the proliferative response of T lymphocytes to the mitogens by interacting with cell receptors coupled with adenylate cyclase. CGRP may be implicated in the regulation of T cell function.