CD4+ subset regulation in viral infection. Preferential activation of Th2 cells during progression of retrovirus-induced immunodeficiency in mice.

Progressive lymphoproliferation and increasingly severe immunodeficiency are prominent features of a syndrome, designated mouse AIDS, which develops in susceptible strains of mice infected with the mixture of murine leukemia viruses, termed LP-BM5. Development of splenomegaly and lymphadenopathy, caused primarily by increases in B cell immunoblasts, requires the presence of CD4+ T cells and is assumed to be mediated by lymphokines produced by these cells inasmuch as progression of disease is markedly inhibited by treatment of infected mice with cyclosporin A. Studies of spleen cells from infected mice revealed spontaneous production of cytokines (IFN-gamma, IL-2, IL-4, IL-5, and IL-10) characteristic of Th0 (or a mixture of Th1 and Th2) T helper cells at 1 wk after infection. At later times, IFN-gamma and IL-2, characteristic products of Th1 helper clones, were expressed poorly, either spontaneously or after stimulation of cells with Con A. In contrast, IL-4, IL-5, IL-6, and IL-10, cytokines typically synthesized by Th2 cells, were produced in response to Con A or spontaneously through 18 wk post-infection. Increased serum IgE levels and enhanced IL-10 mRNA expression were consistent with expression of Th2 cytokines at biologically significant levels in vivo. Selective depletion of T cell subsets before stimulation with Con A showed that CD4+ T cells were the primary source of IL-2, IL-4, IL-10, and, to a lesser extent, IFN-gamma in spleens and lymph nodes of normal or infected mice. These results suggest that persistent activation of CD4+ T cells with the lymphokine profile of Th2 helper clones is responsible for chronic B cell stimulation, down-regulation of Th1 cytokines, and impaired CD8+ T cell function in mouse AIDS. This provides the first demonstration that, like many parasitic infections, viruses encoding potent antigenic stimuli can markedly affect the balance of Th subset expression.     

Functional heterogeneity among human inducer T cell clones

Analysis of mouse CD4+ inducer T cells at the clonal level has established that a dichotomy among CD4+ T cell clones exists with regard to types of lymphokines secreted. Mouse T cell clones designated Th1 have been shown to secrete IL-2 and IFN-gamma, whereas T cell clones designated Th2 have been shown to produce IL-4 but not IL-2 or IFN-gamma. To determine if such a dichotomy in the helper inducer T cell subset occurred in man, we examined a panel of human CD4+ helper/inducer T cell clones for patterns of lymphokine secretion and for functional activity. We identified human T cell clones which secrete IL-4 but not IL-2 or IFN-gamma, and which appeared to correspond to murine Th2 clones. In marked contrast to murine IL-2 secreting Th1 clones which do not produce IL-4 or IFN-gamma, we observed that some human T cell clones secrete IL-2, and IFN-gamma as well as IL-4. Southern blot analysis indicated that these multi-lymphokine-secreting clones represented the progeny of a single T cell. IL-4 secretion did not always correlated with enhanced ability to induce Ig synthesis. Although one T cell clone which secreted IL-2, IL-4, and IFN-gamma could efficiently induce Ig synthesis, another expressed potent cytolytic and growth inhibitory activity for B cells, and was ineffective or inhibitory in inducing Ig synthesis. These results indicate that although the equivalent of murine Th2 type cells appears to be present in man, the simple division of T cells into a Th1 and Th2 dichotomy may not hold true for human T cells.     

A common factor regulates both Th1- and Th2-specific cytokine gene expression.

Murine T helper cell clones are classified into two distinct subsets, T helper 1 (Th1) and T helper 2 (Th2), on the basis of cytokine secretion patterns. Th1 clones produce interleukin-2 (IL-2), tumor necrosis factor-beta (TNF-beta) and interferon-gamma (IFN-gamma), while Th2 clones produce IL-4, IL-5, IL-6 and IL-10. These subsets differentially promote delayed-type hypersensitivity or antibody responses, respectively. The nuclear factor NF-AT is induced in Th1 clones stimulated through the T cell receptor-CD3 complex, and is required for IL-2 gene induction. The NF-AT complex consists of two components: NF-ATp, which pre-exists in the cytosol and whose appearance in the nucleus is induced by an increase of intracellular calcium, and a nuclear AP-1 component whose induction is dependent upon activation of protein kinase C (PKC). Here we report that the induction of the Th2-specific IL-4 gene in an activated Th2 clone involves an NF-AT complex that consists only of NF-ATp, and not the AP-1 component. On the basis of binding experiments we show that this 'AP-1-less' NF-AT complex is specific for the IL-4 promoter and does not reflect the inability of activated Th2 cells to induce the AP-1 component. We propose that NF-ATp is a common regulatory factor for both Th1 and Th2 cytokine genes, and that the involvement of PKC-dependent factors, such as AP-1, may help determine Th1-/Th2-specific patterns of gene expression.     

Induction of antigen-specific antibody responses in primed and unprimed B cells. Functional heterogeneity among Th1 and Th2 T cell clones

CD4+ T cells have been recently divided into two subsets. The functions of these subsets are thought to be distinct: one subset (Th1) is responsible for delayed type hypersensitivity responses and another (Th2) is primarily responsible for induction of antibody synthesis. To more precisely define the roles of both subsets in humoral immune responses, we examined the ability of a panel of nominal antigen specific Th1 and Th2 clones to induce anti-TNP specific antibody synthesis in TNP-primed or unprimed B cells. Four of nine Th1 clones induced little or no antibody synthesis with TNP-primed B cells. However, five other Th1 clones were very effective at inducing IgG anti-TNP plaque-forming cell (PFC) responses in primed B cells. One of these Th1 clones was analysed in detail and found to also provide helper function for unprimed B cells. Cognate B-T cell interaction was required for induction of both primary and secondary responses with this clone, indicating that a Th1 clone could function as a "classical" Th cell. The seven IL-4 producing Th2 clones examined were also heterogeneous in their ability to induce antibody secretion by TNP-primed B cells. Although four of the Th2 clones induced IgG and IgM anti-TNP PFC responses, two Th2 clones induced only IgM and no IgG antibody, and another clone failed to induce any anti-TNP PFC. All Th2 clones failed to induce any anti-TNP PFC. All Th2 clones produced high levels of IL-4, but "helper" Th2 clones produced significantly greater amounts of IL-5 than "non-helper" Th2 clones. These studies indicate that some IL-2- and some IL-4-producing T cell clones can induce TNP-specific antibody in cell clones can induce TNP-specific antibody in primed and unprimed B cells, and that Th1 and Th2 clones are heterogeneous in their ability to induce Ig synthesis. Therefore, although T cell clones can be classified as Th1 or Th2 types according to patterns of IL-2, IFN-gamma, or IL-4 synthesis, the functional capacity to induce antibody synthesis cannot be predicted solely by their ability to secrete these lymphokines.     

Isolation and characterization of an IL-1-dependent IL-4-producing bovine CD4+ T cell clone.

An Ag-specific interleukin 1 (IL-1)-dependent bovine CD4+ Th cell clone, termed 300B1, was isolated and found to resemble the previously described IL-1-dependent murine CD4+ Th2 cell clone, D10.G4.1. Both the 300B1 and the D10.G4.1 T cell clones proliferated to bovine (Bo) IL-1 beta, human (Hu) IL-1 alpha and IL-1 beta, and murine IL-1 alpha when cells were costimulated with concanavalin A (Con A). Proliferation of the 300B1 clone, when costimulated with Con A, appeared to be IL-1-specific in that proliferation could not be promoted by BoIL-2, HuIL-3, HuIL-4, HuIL-5, or HuIL-6. The 300B1 clone produced interferon-gamma (IFN-gamma), but not IL-2 following stimulation with either Con A, Con A plus phorbol 12-myristate 13-acetate or Ag plus antigen-presenting cells. Upon stimulation with Con A, the 300B1 clone expressed IL-4 mRNA and produced an autocrine growth factor (AGF) that could be inhibited by anti-HuIL-4 but not by anti-HuIL-2 Ab. The clonal derivation of the 300B1 clone was confirmed by isolating five 300B1 subclones, all of which produced IFN-gamma and an AGF but not IL-2. Collectively, these results suggest the IL-1-dependent bovine 300B1 Th cell clone produces IL-4, but not IL-2, as an AGF. Furthermore, the bovine Th cell clone appeared to share many characteristics of previously described murine Th2 cell clones except that the bovine clone produced IFN-gamma.     

Suppression of Cytokine Production in T Helper Type 2 Cells by Nitric Oxide in Comparison with T Helper Type 1 Cells

We examined the effect of nitric oxide (NO) on cytokine production in T helper (Th) cell subsets, using murine splenic CD4⁺ T cells and two types of Th clones. Interferon-gamma-treated murine peritoneal exudate cells (IFN-PEC) suppressed DNA synthesis to 60% of the control level in CD4⁺ T cells stimulated with the anti-CD3 monoclonal antibody. The production of IL-2 and IL-4 in the CD4⁺ T cells decreased to 63.2% and 9.2%, respectively, of the control value by co-culture with IFN-PEC. The addition of N^G-monomethyl-L -arginine (L-NMMA) partially recovered the suppression of DNA synthesis. In the presence of indomethacin, the suppression of DNA synthesis was partially inhibited and the reduction in the cytokine production caused by IFN-PEC was partially recovered. The simultaneous addition of N^G-monomethyl-L -arginine (L-NMMA) and indomethacin completely inhibited not only the suppression of DNA synthesis but also the reduction in the cytokine production caused by IFN-PEC. Moreover, DNA synthesis in the Th2 clone was suppressed to a greater extent than that in the Th1 clone by co-culture with IFN-PEC. This suppression in the Th1 clone was inhibited by the addition of L-NMMA, whereas the DNA synthesis in the Th2 clone was not recovered by L-NMMA. In addition, sodium nitroprusside (SNP) suppressed IL-4 production in the Th2 clone but had no effect on IL-2 production in the Th1 clone. In the experiment of the co-culture with IFN-PEC, the inhibitory-effect of NO on T cell activation was not clarified by the influence of prostaglandins. However, in conclusion, cytokine production in Th2 cells may be more susceptible to NO than that in Th1 cells.     

Anti-CD3 antibody induces unresponsiveness to IL-2 in Th1 clones but not in Th2 clones

Culture of murine T cells with immobilized (platebound) anti-CD3 antibody results in autocrine growth factor secretion in both Th1 (IL-2 producing) and Th2 (IL-4 producing) cells. Using a panel of murine T cell clones, we demonstrate that the IL-2-induced proliferation of Th1 clones is dramatically inhibited by immobilized anti-CD3 antibody, whereas that of Th2 clones is not. This unresponsiveness of Th1 clones to IL-2 is not due to decreases in IL-2R expression. Supernatants from Th1 or Th2 cell cultures fail to alter the effects of anti-CD3 on the two types of clones, suggesting that unresponsiveness induced in Th1 clones or the lack thereof in Th2 clones is not mediated by a stable cytokine(s). Accessory cells enhance the proliferation of Th1 cells exposed to low concentrations of anti-CD3, but the unresponsiveness induced by high concentrations of anti-CD3 is not prevented by accessory cells. Finally, soluble anti-CD4 antibody prevents the induction of the unresponsive state even at high concentrations of anti-CD3. These experiments demonstrate that two subsets of cloned CD4+ T cells differ in their responses to anti-CD3, and that CD4 molecules may play a critical role in regulating the outcome of receptor-mediated stimulation.     

Virus-induced interferon alpha/beta (IFN-alpha/beta) production by T cells and by Th1 and Th2 helper T cell clones: a study of the immunoregulatory actions of IFN-gamma versus IFN-alpha/beta on functions of different T cell populations

Spleen cells, resting T cells, activated T cells, and T cell clones characterized as type 1 (Th1) and type 2 (Th2) were investigated for their ability to produce interferon (IFN) following in vitro culture with Newcastle disease virus (NDV). All of the above cell populations, including both Th1 and Th2 T cell clones, produced high levels of IFN following in vitro culture with NDV. This IFN was characterized as a mixture of IFN-alpha and IFN-beta with IFN-alpha being the predominate species of IFN contained in the mixture. IL-2 greatly enhanced the production of IFN-alpha/beta by all cell populations in response to NDV. These different T cell populations responded very differently to the immunoregulatory actions of IFN-gamma versus IFN-alpha/beta. IFN-alpha/beta was shown to be a potent inhibitor of Con A or IL-2-induced proliferation of different T cell populations. This inhibition was not associated with a reduction in lymphokine production since spleen cells or Th1 T cell clones cultured with Con A and IFN-alpha/beta had no decrease in IL-2 or IFN-gamma production when compared to Con A-stimulated control cultures. IFN-gamma had little to no inhibitory activity on Con A-induced proliferation of spleen cells. In fact, Con A-induced proliferation was usually enhanced by IFN-gamma when nylon wool-enriched T cells were assessed. Different results were observed when IFN-gamma and IFN-alpha/beta were investigated for their ability to inhibit IL-2-induced proliferation of different T helper cell clones. IFN-gamma and IFN-alpha/beta were both capable of inhibiting IL-2-induced proliferation of T cell clones characterized as type 2 (Th2). In contrast, IFN-gamma had no effect on IL-2-induced proliferation of Th1 clones. IFN-alpha/beta, however, inhibited IL-2-induced proliferative responses of both Th1 and Th2 T cell clones. These results document the facts that (1) IFN-gamma and IFN-alpha/beta differ in their immunoregulatory actions, (2) different T cell subpopulations vary in their susceptibility to IFN-gamma regulation, and (3) virus induction of IFN-alpha/beta appears to be a ubiquitous function associated with different T cell populations.     

Cytokine-modulated regulation of helper T cell populations

Helper T (Th) cells are a crucial component of the adaptive immune system and are of fundamental importance in orchestrating the appropriate response to pathogenic challenge. They fall into two broad categories defined by the cytokines each produces. Th1 cells produce interferon- gamma and are required for effective immunity to intracellular bacteria, viruses and protozoa whereas Th2 produce IL-4 and are required for optimal antibody production to T-dependent antigens. A great deal of experimental data on the regulation of Th1 and Th2 differentiation have been obtained but many essential features of this complex system are still not understood. Here we present a mathematical model of Th1/Th2 differentiation and cross regulation. We model Fas-mediated activation-induced cell death (AICD) as this process has been identified as an important mechanism for limiting clonal expansion and resolving T cell responses. We conclude that Th2 susceptibility to AICD is important for stabilizing the two polarized arms of the T helper response, and that cell-cell killing, not suicide, is the dominant mechanism for Fas-mediated death of Th1 effectors. We find that the combination of the anti-proliferative effect of the cytokine TGF- beta and the inhibiting influence of IL-10 on T cell activation are crucial controls for Th2 populations. We see that the strengths of the activation signals for each T helper cell subset, which are dependent on the antigen dose, co-stimulatory signals and the cytokine environment, critically determine the dominant helper subset. Switches from Th1- to Th2-dominance may be important in chronic infection and we show that this phenomenon can arise from differential AICD susceptibility of T helper subsets, and asymmetries in the nature of the cross-suppressive cytokine interactions. Our model suggests that in some senses a predominantly type 2 reaction may well be the "default" pathway for an antigen-specific immune response, due to these asymmetries.     

Characterization of drug-specific T cells in phenobarbital-induced eruption

Phenobarbital has a high potential to elicit adverse reactions including severe skin eruptions and systemic involvements among the worldwide-prescribed drugs. Although phenobarbital hypersensitivity is thought to be mediated by T cells specific to the drug, its precise mechanism remains not fully elucidated. To characterize T cells reactive with phenobarbital, we generated drug-specific T cell clones and lines from PBMCs of patients with phenobarbital hypersensitivity showing various degrees of cutaneous and extracutaneous involvements. Although the TCR Vbeta repertoire and phenotype in the T cell clones/T cell lines were heterogeneous among the patients, Vbeta13.1(+) and Vbeta5.1(+) clones or lines were raised from the individuals examined who possessed different HLA haplotypes. Histopathological examination suggested that Vbeta5.1(+)CD8(+) T cells and Vbeta13.1(+) T cells played a role in cutaneous and extracutaneous involvements, respectively. A Vbeta13.1(+)CD4(+) clone was found to proliferate in response to the Ag with processing-impaired, fixed APCs. Most of the clones and lines belonged to the Th2 phenotype, producing IL-4 and IL-5 but not IFN-gamma upon phenobarbital stimulation. Clones/lines with Th1 or Th0 phenotypes also constituted minor populations. These observations clearly indicate the heterogeneity and a marked individual deviation of reactive T cell subsets among the patients in terms of CD4/8 phenotype, Vbeta repertoire, Ag recognition pattern, and cytokine production; and thus provide evidence whereby each pathogenic T cell subset contributes to special elements of clinical presentation.     

IL-10 inhibits mitogen-induced T cell proliferation by selectively inhibiting macrophage costimulatory function.

IL-10, a newly designated cytokine primarily produced by the Th2 subset of CD4+ T lymphocytes and Ly-1+ B lymphocytes, has recently been hypothesized to inhibit cytokine production by Th1 T cell clones by blocking accessory cell- (AC) dependent costimulatory function. To evaluate the effect of IL-10 on Con A-induced proliferative responses of resting murine T cells, purified T cells were cultured with different types of AC. The addition of IL-10 produced a 70 to 90% inhibition of resting T lymphocyte proliferation when purified populations of macrophages were used as AC, but had no effect on the AC function of T-depleted spleen cells, activated B cells, dendritic cells, or L cells. The inhibitory effects of IL-10 were inversely related to the concentration of mitogen and could be reversed by the addition of the neutralizing anti-IL-10 mAb, SXC1. The inhibition of macrophage AC function was not related to the induction of a suppressor cytokine as stimulation by mixtures of macrophages and limiting numbers of dendritic cells was not inhibited. The decrease in proliferative responses was primarily secondary to inhibition of IL-2 production although the failure of exogenous IL-2 to completely reconstitute the response suggested that IL-10 may also exert inhibitory effects on the induction of expression of a functional IL-2R. These results are most consistent with a model in which IL-10 inhibits the induction of expression on macrophages of a critical costimulatory molecule that may be constitutively expressed on other types of AC.     

Retrovirus-mediated immunosuppression. II. FeLV-UV alters in vitro murine T lymphocyte behavior by reversibly impairing lymphokine secretion

Murine splenocytes and cloned murine T cells were used to study the in vitro immunosuppressive effects of UV-inactivated feline leukemia virus (FeLV-UV) on lymphokine secretion. FeLV-UV can significantly depress the accumulation of IL 2 in cultures of Con A-stimulated C57BL/6 splenocytes and in cultures containing the alloreactive helper T cell clone B6D/2-2m plus Con A. Inhibition of lymphokine accumulation in these cultures could not be attributed to absorption or inactivation of IL 2 by the FeLV-UV or to the FeLV-UV-induced production of substances which interfere with the IL 2 bioassay. Thus, FeLV-UV appears to block production and/or secretion of IL 2 by a direct inhibitory effect on IL 2-secreting murine T lymphocytes. Additional studies indicate that FeLV-UV impairs IL 2 production only if added very soon after lymphocyte contact with lymphokine-inducing agents and that IL 2 secretion resumes when FeLV-UV is removed from the culture. FeLV-UV also impairs accumulation of MAF (interferon-gamma?) in cultures of Con A-stimulated C57BL/6 splenocytes and in cultures containing the alloreactive cytotoxic T lymphocyte clone B6D/2-7c plus Con A. The latter observation again suggests that FeLV-UV impairs lymphokine secretion by a direct effect on lymphokine-producing T lymphocytes. Furthermore, it suggests that FeLV-UV does not selectively impair production of IL 2 nor does it have selective inhibitory effects on helper T cells. Rather, FeLV-UV appears to have a general inhibitory effect on lymphokine production by T lymphocytes. Finally, concentrations of FeLV-UV which suppress MAF production by the CTL clone have little influence on the cytolysis mediated by the same cloned T cell population. Thus, the immunosuppressive influence of FeLV-UV is selective for phenomena associated with induction of new T lymphocyte functions, such as lymphokine secretion, and spares other immune functions already expressed by the same cells.     

A common precursor for CD4+ T cells producing IL-2 or IL-4.

To investigate whether CD4+ T cells are predetermined to produce a given pattern of lymphokines, we have used a culture system that allows the controlled induction of either IL-2- or IL-4-producing CD4+ T cells. Single, freshly isolated murine CD4+ T cells were activated with Con A, rIL-2, and APC; the developing clones were split and then cultured for an additional 14 days with either rIL-2 alone or with rIL-2 and anti-CD3 stimulation. Subclones expanded in the presence of rIL-2 alone produced predominantly IL-2, although subclones derived from the same precursor and expanded in the presence of rIL-2 and a mitogenic antibody to CD3 released predominantly IL-4. Subclones expanded for 2 wk in the presence of rIL-2 plus a mitogenic mAb to CD3 released up to 60 times more IL-4 but only 1/90 the amount of IL-2 released by subclones derived from the same precursor cell and expanded with rIL-2. Both phenotypes can be derived from IL-2-producing precursor cells. These results demonstrate that IL-2-producing clones can be derived from the same cells as IL-4-producing clones and are most consistent with the view that the IL-2-producing Th1 or the IL-4-producing Th2 phenotype of a T cell clone is acquired during T cell differentiation and is not secondary to the expansion of distinct subpopulations that are predetermined to produce a specific cytokine pattern.     

Thymic stroma-derived T cell growth factor (TSTGF). I. Functional distinction of TSTGF from interleukins 2 and 4 and its preferential growth-promoting effect on helper T cell clones

A recently established thymic stroma-derived cell line (TSCL) supported the growth of the interleukin (IL) 2-dependent, antigen-specific helper T cell (Th) clone, 9-16, without requirement for IL-2 and antigen, and such growth was substituted by a factor produced into cultures by this established TSCL. This substance, thymic stroma-derived T cell-growth factor (TSTGF), was capable of inducing the proliferation of various Th clones including 9-16 Th clone, but not of cytotoxic T cell clones. TSTGF-induced growth promotion was obtained in a dose-dependent fashion and in maintaining antigen specificity of Th clones. The culture supernatant from the TSCL did not contain detectable level of IL-1, IL-2, IL-3, IL-4, or interferon activity. The proliferation of 9-16 Th clone was stimulated by recombinant IL-2 and IL-4 as well as TSTGF, but not by IL-1, IL-3, or interferons. However, the proliferation of this Th clone by IL-2 or IL-4 was almost completely inhibited by anti-IL-2 receptor or anti-IL-4 monoclonal antibody, respectively, whereas TSTGF-induced growth of 9-16 Th clones was not affected by either type of antibody, demonstrating that TSTGF is functionally distinct from IL-2 and IL-4. In addition, TSTGF activity was also obtained from the culture supernatant of the primary thymic explant, which was freshly prepared. These results indicate that the primary thymic explant as well as an established TSCL produce factors capable of promoting the growth of helper but not cytotoxic type of T cells in the absence of T cell growth factors thus far defined.     

Regulation of T cell proliferation by IL-7

The regulation of murine T cell proliferation by IL-7 was investigated. Highly purified resting splenic T cells were induced to proliferate in a short term assay by IL-7 in the presence of the comitogen, Con A. The proliferation of these resting T cells showed both IL-2-dependent and -independent components as determined by the susceptibility of the response to the blocking effects of anti-IL-2 mAb. Furthermore, IL-7 was found to augment the Con A-induced production of IL-2 and expression of IL-2R by resting splenic T cells. In contrast, Con A blasts and long term, Ag-dependent cloned T cells proliferated in response to IL-7 independently of any involvement of IL-2. Finally, differences were observed between IL-7 and IL-6 with regard to the regulation of T cell growth and activation. As with IL-7, IL-6 stimulated resting splenic T cells to proliferate in the presence of comitogen. However, in contrast to IL-7, IL-6 failed to stimulate the proliferation of Con A blasts or T cell clones and did not augment the Con A-induced expression of IL-2R on resting T cells.     

Identification of profound peripheral T lymphocyte immunodeficiencies in the spontaneously diabetic BB rat

The BB rat is presently the best available animal model for human insulin dependent diabetes (IDD). Because of the extreme susceptibility of the strain to opportunistic infections and because current studies suggest that they have an autoimmune diathesis, of which IDD is but one result, aspects of the immune system of the BB rat were studied. Severe T lymphopenia was observed in all BB rats, irrespective of sex or the presence of IDD, while numbers of B cells and serum immunoglobulin levels were normal. Both the helper T lymphocyte and cytotoxic/suppressor T lymphocyte subsets, defined by reactions with monoclonal antibodies, were depressed, and an inversion of the helper T cell subset to cytotoxic/suppressor T lymphocyte subset ratio occurred in all BB rats with increasing maturity. Concomitantly, severe impairments of T cell-mediated immune responses were noted. BB rats poorly rejected allografts across both major and minor histocompatibility barriers, and BB splenic or peripheral blood lymphocytes had markedly defective proliferative responses to mitogens and to allogeneic cells in MLC. Irradiated and nonirradiated BB spleen cells did not inhibit WF mitogenic or MLC responses, which suggests that the T cell defect in BB rats is not solely due to increased suppressor activity. Because irradiated WF cells and Con A supernatants did not restore BB proliferative responses, and BB lymphocytes were able to produce IL-2 normally, a reduced ability of BB lymphocytes to respond to helper factors such as IL-2 is suggested. In contrast to T lymphocytes from spleen or peripheral blood, BB thymocytes responded as well as did WF thymocytes to Con A or Con A supernatants. Percentages of T lymphocyte subsets and histology of BB thymuses were also normal when compared to WF thymuses. However, spleens and lymph nodes from BB rats were severely depleted of T lymphocytes, and thymocytotoxic autoantibodies were detected in many BB rat sera. The above findings indicate that BB rats have T lymphocyte immunoincompetence, which appears to be a post-thymic or peripherally acquired maturational defect.     

Regulatory role of CD4/L3T4 molecules in IL-2 production by affecting intracellular Ca2+ concentration of T cell clone stimulated with soluble anti-CD3

To elucidate the role of CD4 molecule in T cell activation, the effect of anti-CD4 on T cell IL-2 production was examined by using an alloreactive Th clone. The alloreactive T cell used in the present experiments produced IL-2 in response to soluble anti-CD3 epsilon-chain (anti-CD3) without accessory cell or insoluble antibody carrier. The IL-2 production was suppressed by the addition of anti-CD4 in cultures. An intracellular free Ca2+ concentration ([Ca2+]i) of the T cell clone was elevated by anti-CD3 stimulation, but the elevation was suppressed in the presence of anti-CD4. When the clone was stimulated in Ca2(+)-free medium, the elevation of [Ca2+]i was not observed. When Ca2+ influx was induced by calcium ionophore A23187 or ionomycin, the clone produced IL-2 in response to anti-CD3 in the presence of anti-CD4. When polyclonal T cell line or several other alloreactive T cell clones were examined for their anti-CD3 response, essentially the same results as mentioned above were obtained. Taken together, these results suggest that the slow and sustained elevation of [Ca2+]i is an essential signal for IL-2 production of T cells, and that anti-CD4 suppresses the IL-2 production by interfering the [Ca2+]i elevation. The significance of CD4 molecules in murine T cell activation was discussed.