Activation and mechanism of action of suppressor macrophages

Intravenous administration of Corynebacterium parvum to alloimmunized mice activates splenic suppressor macrophages that effectively curtail primary and secondary generation of cytotoxic T lymphocytes (CTLs) in vitro. CTL generation was significantly inhibited in suppressed primary cultures by Day 3, the earliest time point that activity is first detected in control cultures. Suppressor macrophages had to be present during the first 24–48 hr of culture to effectively curtail the generation of CTLs. However, if suppressor macrophages were reactivated by 48-hr in vitro culture and then added to primary sensitizations that had been initiated 48 hr previously, they were capable of significant suppression. Suppressor cells produced a soluble factor that mediated the inhibition of CTL generation. The production or action of this factor could not be counteracted by indomethacin.     

Effects of antigen-feeding on intestinal and systemic immune responses. III. Antigen-specific serum-mediated suppression of humoral antibody responses after antigen feeding.

Feeding mice sheep erythrocytes (SRBC) caused a significant decrease in splenic IgM antibody responses to SRBC given ip. Reduced IgM responses were due to a suppressor factor in the serum of fed mice rather than due to a lack of IgM antibody-forming cell precursors or to the presence of suppressor T cells. Although feeding initially primed mice to produce greater IgA and IgG anti-SRBC responses after SRBC challenge, the initial primed state was transitory. Mice fed SRBC for longer than 8 weeks had significantly reduced splenic IgG and IgA responses after SRBC challenge.Suppression of IgM responses by serum from fed mice was antigen-specific and not H-2 restricted. Serum from fed mice inhibited the induction of IgM anti-SRBC responses but did not block the expression of already established responses. The size of the suppressor factor and the ability to remove suppressor activity from serum by anti-mouse immunoglobulin suggested that suppression was mediated by antibody. However, the determinants against which the antibody was directed appeared to differ among batches of suppressor sera. Suppressor activity did not appear to be mediated by immune complexes, or soluble antigen. Oral feeding of antigen can have a marked influence on host systemic immune responses when the antigen used for feeding is subsequently administered parenterally. Thus, oral antigen administration may provide a way for specifically manipulating systemic immune responses in vivo. In addition, antigen-feeding may provide a means for producing transferable factors that suppress humoral antibody responses.     

Immunosuppression induced by attenuated Salmonella. Reversal by IL-4

We previously demonstrated that an aroA- strain of Salmonella typhimurium, which provides excellent protection against virulent Salmonella challenge, also rendered immunized mice unable to mount in vivo and in vitro antibody responses to heterologous Ag. Coculture studies using transwell plates indicated that suppression was mediated by soluble factors. The suppressive cells were identified as belonging to the monocytic linkage. Macrophage precursors as well as mature adherent macrophages mediated the observed suppression. In the present study, the mechanism of immunosuppression was investigated. Suppression was found to be genetically nonrestricted as spleen cells from immunized C3HeB/FeJ mice (H-2k) suppressed the anti-SRBC plaque-forming cell (PFC) responses of normal spleen cells from two MHC noncompatible mouse strains, BALB/c (H-2d) and C57BL/6 (H-2b). Time course experiments demonstrated that the addition of spleen cells from immunized mice to normal splenocytes as late as day 4 of a 5-day assay was still markedly suppressive. Furthermore, suppression of the PFC responses was accompanied by a profound inhibition of the capacity of immune splenocytes to produce IL-2 in response to in vitro stimulation by Con A. Coculture studies showed that immune spleen cells were able to suppress IL-2 production by normal splenocytes in a dose-dependent fashion. However, the suppressed PFC responses of immune spleen cells could not be reversed by the exogenous addition of up to 200 U/ml of IL-2, suggesting that immune splenocytes are also defective in their ability to respond to IL-2. In marked contrast, suppression of PFC responses was reduced by more than 50% by the addition of as little as 1 U/ml of IL-4 and was completely abrogated when 5 U/ml of IL-4 were added to in vitro cultures of spleen cells from immunized mice. The antisuppressive action of IL-4 appeared to be via its inhibitory effect on activated macrophages. The implications of the above findings are discussed.     

Acute hepatotoxin exposure effects lymphoid and accessory cell types in inbred mice

The effect of acute hepatotoxin exposure on in vivo and in vitro immune responses were investigated in inbred mice. Splenic anti-SRBC PFC responses were slightly enhanced by carbon tetrachloride or galactosamine administration 5 hr prior to immunization. Whereas splenic anti-SRBC PFC responses were slightly enhanced in euthymic mice exposed to carbon tetrachloride 5 hr prior to immunization, immune responses to the TI antigens, Fl-LPS, Fl-Ficoll, and TNP-LPS, were significantly suppressed. Athymic mice receiving similar hepatotoxin exposure elicited enhanced immune responses to the TI immunogens, thereby suggesting that the activities of B cells and macrophages are enhanced in treated animals and in euthymic mice, T suppressor cells are also activated. By admixture of purified B- and T-cell and macrophage populations from either carbon tetrachloride-treated or control animals, it was demonstrated that hepatotoxin exposure also induces suppressor T cells regulating immune responses to the T-dependent antigen, SRBC, and that macrophages from treated animals are more functional. Further, B-cell responsiveness is enhanced. In addition to these observations, an active factor could be demonstrated in sera from hepatotoxin-treated animals which augments immune responses to SRBC in normal mice and promotes immune responses to this antigen in athymic mice. These findings indicate that the effects of acute hepatotoxin exposure are multifocal, influencing the activity of lymphoid and accessory cells.     

Interleukin-4 causes delayed virus clearance in influenza virus-infected mice.

Two different subsets of T cells, Th1 and Th2 cells, have been demonstrated to secrete different profiles of cytokines and to influence various infections in different ways. Whereas cytokines secreted by Th1 cells, particularly gamma interferon, promote the generation of cell-mediated immunity, Th2 cells and their cytokines (interleukin-4 [IL-4], IL-5, IL-10, and IL-13) have been shown to function in recovery from parasitic infections and in antibody responses. In this study, we analyzed the effects of the dominant Th2 cytokine, IL-4, on immunity to virus infection. We assessed the effects of IL-4 on both secondary immune responses by an adoptive transfer assay and primary immune responses by in vivo treatment of influenza virus-infected mice with IL-4. The results demonstrated that IL-4 can function to inhibit antiviral immunity at both stages. We found that IL-4 treatment of sensitized cells during secondary stimulation in vitro had little effect on their ability to lyse virus-infected target cells in a 51Cr release assay. Nevertheless, the clearance of influenza A/PR/8/34 (H1N1) virus from the lungs of infected BALB/c mice was significantly delayed after the transfer of virus-specific T cells secondarily stimulated in the presence of IL-4 in comparison to virus clearance in recipients of cells stimulated in the absence of IL-4. In contrast to the adoptive transfer results, the treatment of PR8 virus-infected mice with IL-4 during primary infection greatly suppressed the generation of cytotoxic T-cell precursors, as assessed by secondary stimulation in vitro. In addition, culture supernatants of secondarily stimulated spleen cells from IL-4-treated mice contained significantly less gamma interferon and more IL-4 than did spleen cells from controls. More importantly, the treatment of mice with IL-4 resulted in an extremely significant delay in virus clearance. Thus, IL-4 can inhibit both primary and secondary antiviral immune responses.     

Effect of antigen priming on T-cell suppression. I. Activity of Ly 1+2+ feedback suppressor T-cell precursors after isolation from competing Ly 2-T cells

Previous experiments have demonstrated that feedback suppression of murine antibody responses occurs in vitro after exposure of unprimed T-cell subsets to suppression-inducing signals from primed cells, resulting in suppression of primary and secondary IgM as well as IgG anti-SRBC responses. However, following priming with antigen when cells appear which are capable of inducing feedback suppression, the ability of unfractionated splenic T-cell populations to mediate detectable feedback suppression in vitro rapidly disappears, suggesting that priming alters the expression of feedback suppression at the same time as providing for its induction. In the present study, we have succeeded in isolating active feedback suppressor T-cell precursors (preTs) in the Ly 1+2+ and L3T4- T-cell populations from SRBC-primed as well as from unprimed mice, demonstrating that preTs are not lost after priming. The preTs isolated from primed mice resemble those isolated from unprimed mice in Ly and L3T4 phenotype, cell dose requirements, kinetics, level of suppression, and requirement for in vitro activation by primed cells. These results imply that antigen priming neither significantly depresses nor enhances the ability of Ly 1+2+ preTs to participate in feedback suppression and that activated suppressor effector cells are not detectable in the Ly 1+2+ splenic T-cell subset. Priming does, however, induce an enhancing activity in Ly 2-, L3T4+ T cells which appears to compete with feedback suppression and thus may account for the absence of detectable feedback suppression when unfractionated T cells from primed mice are the only source of preTs.     

Elicitation of antigen-induced primary and secondary murine IgE antibody responses in vitro

Described herein are methods for eliciting and quantitating primary and secondary murine IgE antibody responses in vitro, and the important role of antigen concentration in determining the level of IgE produced during an immune response. The methods for quantitating IgE antibody levels in culture supernatant fluids and in serum by ELISA are presented in detail. The specificity of such methods was confirmed in that (1) no other isotype of antibody registered in the IgE-ELISA, and (2) parallel determinations of IgE antibody concentrations could be obtained by independent analysis using Fc epsilon RI-dependent basophil degranulation. We examined various parameters of cell donor immunization and lymphoid cell culture which allow for optimal in vitro primary and secondary IgE responses. High relative antigen doses result in diminished IgE antibody responses in experimental animals, a finding confirmed herein. High antigen concentrations in vitro also result in relative suppression of IgE antibody synthesis. This was also true for in vitro production of IgG1 and IgA antibodies. Conversely, IgM and IgG2a responses were elicited at both low and high antigen concentrations; IgG2b and IgG3 were not produced under the conditions of priming and culture used herein. Finally, production of IgE in vitro depended on the presence of carrier-primed CD4+ T cells and hapten-specific B cells. Generation of maximal IgE antibody secretion, and hence elicitation of an allergic reaction, is thus dependent on the amount of antigen acting as stimulant for the immune response.     

Temperature-mediated processes in immunity: differential effects of low temperature on mouse T helper cell responses

A low culture temperature of 27 degrees C inhibited mouse primary in vitro anti-hapten plaque-forming cell responses to a thymus-dependent (TD) antigen (Ag) (trinitrophenyl-keyhole limpet hemocyanin, TNP-KLH). In contrast, the magnitudes of secondary responses to TNP-KLH or primary responses to a thymus-independent (TI) Ag (TNP-lipopolysaccharide (LPS)) were unaffected. The low-temperature-sensitive step in the primary TD response occurred relatively early and preceded interleukin 2 (IL-2) secretion. Furthermore, the low-temperature-induced suppression could be obviated (rescued) by recombinant IL-2 or IL-4, but not by IL-1. Thus, the low temperature appeared to inhibit the function of virgin Th cells by preferentially affecting T cell-derived interleukin synthesis/secretion and not other cellular activities. These results also imply fundamental differences between the activation requirements of memory and virgin Th cells.     

The enhancement of humoral and cellular immune responses by dimethyldioctadecylammonium bromide

Dimethyldioctadecylammonium bromide (DDA) produced marked enhancement of both cellular and humoral immune responses to SRBC when administered to mice intraperitoneally, or of cellular immunity when given subcutaneously. Stimulated cellular responses were seen as increased footpad swelling as a measure of delayed hypersensitivity and increased antigen-induced blastogenesis. Elevation of humoral response was reflected in increased numbers of splenic plaque-forming cells (PFC) and in circulating anti-SRBC antibody. Adjuvancy did not depend on addition of the lipid of DDA to antigen, as both humoral and cellular responses were enhanced whether DDA and SRBC were admixed or injected separately 4 hr apart intraperitoneally. DDA also enhanced the PFC response to the T-cell independent antigen TNP-LPS. The DDA effects are accompanied by macrophage activation, which may mediate at least in part the observed responses. DDA-activated macrophages exhibit fast spreading, are highly phagocytic, and elaborate significantly greater amounts of thymocyte mitogenic factor(s) than do normal resident peritoneal macrophages. This activation may effect the stimulation of antigen-specific primary lymphocyte responses by adjuvant and expansion of memory-cell populations which lead to the observed enhancement of secondary responses.     

Temperature-mediated processes in teleost immunity: differential effects of temperature on catfish in vitro antibody responses to thymus-dependent and thymus-independent antigens

An in vitro culture system was employed to ascertain the effects of different temperatures on the anti-hapten antibody-secreting cell responses of channel catfish leucocytes to murine thymus-dependent (TD) and thymus-independent (TI) antigens. The magnitudes of primary responses to a TI antigen (TNP-LPS) and secondary responses to a TD antigen (DNP-KLH) were relatively independent of in vitro culture temperature. The kinetics of each of these responses as a function of temperature was characterized by a Q10 of 2. In contrast, the magnitudes of primary responses to TD antigens (DNP-KLH and DNP-HoSA) were suppressed at lower in vitro temperatures. Furthermore, it was observed that some of the low temperature suppression of primary responses to TD antigens could be abrogated by appropriate low temperature in vivo acclimation. These findings are interpreted as supporting the hypothesis that low environmental temperatures immunosuppress fish by virtue of differential inhibitory effects on the generation of carrier-specific helper cells.     

Antigen concentration determines helper T cell subset participation in IgE antibody responses.

A recently developed in vitro system for antigen-stimulated primary and secondary murine IgE antibody responses has been used to define (a) the relative participation of the Th1 and Th2 cell-derived lymphokines IFN-gamma and IL-4, respectively, in such responses, and (b) the role of antigen concentration in determining functional helper T cell activity. These studies confirm that IL-4 and IFN-gamma exert regulatory effects on IgE synthesis, but the nature and extent of their respective effects on primary and secondary IgE responses differ. Thus, primary IgE responses are considerably more sensitive to and dependent on IL-4 than are secondary IgE responses since (1) anti-IL-4 monoclonal antibody totally inhibited primary IgE responses, but only partially affected secondary responses; and (2) exogenously added IL-4 could stimulate primary IgE responses to optimal antigen concentrations, but had no effect on secondary IgE production. Likewise, antigen-stimulated primary IgE responses are about eightfold more sensitive than are secondary responses to the inhibitory effects of IFN-gamma. Studying the effect of antigen dose on the quantity of IgE antibody produced revealed that although IFN-gamma could be detected by ELISA in cultures exhibiting high-dose antigen-dependent diminution of IgE production, anti-IFN-gamma monoclonal antibody could not reverse this phenomenon. Thus, IFN-gamma is not solely responsible for decreased IgE synthesis associated with high-dose antigen exposure. IL-4 activity was detected in the fluid from cultures stimulated with low, but not high, levels of antigen. Moreover, addition of exogenous IL-4 restored IgE production to normal levels in cultures exposed to high antigen concentrations. Therefore, it appears that high levels of antigen result in selective stimulation of Th1 cells which produce IFN-gamma, and diminished activation of IL-4-producing Th2 cells. These results help explain observations regarding the influence of antigen dose on the generation of experimental and clinical IgE antibody responses in vivo.     

In vivo suppression of the primary immune response by a species of low density serum lipoprotein.

An apparent subspecies of normal human serum low density lipoprotein (LDL-In) has been identified with suppressive activity for early or facilitating events of human lymphocyte mitogen and allogenic cells stimulation in vitro. This report describes the effects of in vivo administration of LDL-In on the mouse anti-SRBC immune response. Human LDL-In is not species specific and was capable of suppressing the in vivo mouse anti-sheep erythrocyte (SRBC) hemagglutination response by 88% after the administration of 500 to 600 mug LDL-In IV, whereas human serum high density lipoproteins and fibrinogen had no effect. Maximal suppression occurred only when LDL-In was injected 24 to 48 hr before antigen administration. Simultaneous or subsequent injection of LDL-In had no effect. The activity of LDL-In was influenced by antigen dose and maximal at low antigen doses. The number of splenic plaque-forming cells was also reduced indicating a suppression of the clonal expansion of primary B cells to antibody-secreting cells rather than only suppression of antibody synthesis by differentiated B cells and their progeny. These observations suggest the hypothesis that endogenous LDL-In could play an important immunoregulatory role in the maintenance of immune homeostasis and the "natural" suppression of non-productive lymphocyte proliferation.     

A study of the mechanism of Con A-induced immunosuppression in vivo

The plaque-forming cell (PFC) response to sheep erythrocytes (SRBC) is suppressed in a dose-related manner when concanavalin A (Con A) is administered intravenously to mice prior to or after immunization with antigen. The magnitude of suppression as well as the duration of the Con A effect greatly depends on the concentration of antigen used for immunization. Although profound suppression of the anti-SRBC PFC response is observed in intact mice pretreated with Con A for 4-24 hr, spleen cells from these mice do not exhibit suppressive activity when transferred into normal recipients or when cotransferred with normal spleen cells into irradiated recipients. Moreover, the cells from Con A-treated mice respond as normal spleen cells to SRBC when transferred alone into irradiated hosts. Suppression of the anti-SRBC PFC is only observed when adoptive hosts of cells from Con A-treated mice are also injected with Con A within 48 hr (but not 72 hr) of cell transfer and immunization. This time course of responsiveness to the suppressive effects of Con A is similar to that observed in normal mice and in irradiated recipients of normal spleen cells. The immune response to SRBC is also suppressed in adoptive hosts of normal spleen cells that are pretreated with Con A 4-24 hr prior to irradiation and cell transfer. Although functionally inactive when transferred into adoptive hosts, spleen cells from mice pretreated with Con A for 4-24 hr can suppress a primary antibody response to SRBC in vitro. The suppressive activity, which cannot be detected in the spleens of mice when the interval between pretreatment and assay is longer than 24 hr, is present in a subpopulation that bears the Thy 1.2 and Lyt 2 phenotype. Taken together the results obtained in in vivo and in vitro functional assays suggest that a suppressor cell population is activated following in vivo treatment with Con A, but that the cells rapidly lose their state of activation when removed from a Con A environment. This phenomenon is in all probability responsible for the failure to demonstrate suppressive activity in the spleens of Con A-treated mice using in vivo functional assays.     

Suppression of the cytotoxic T-lymphocyte response in mice by pertussis toxin

Pertussis toxin (PT), the major toxin produced by Bordetella pertussis, has been reported both to enhance and to suppress immune responsiveness. These findings suggested that PT contributes to the virulence of B. pertussis through mechanisms involving immune regulation. We report that PT suppressed both the primary and the secondary cytotoxic T-lymphocyte (CTL) responses of mouse spleen cells cultured against two different allogeneic stimulator spleen cells in vitro. This suppression was dependent on the dose of PT used. PT must be present during the initial stages (within the first 24 hr) of CTL generation. Soluble factor(s) obtained from spleen cells preexposed to PT did not suppress the CTL response. Suppression of the CTL response observed was not due to depletion of the antigen by PT. The cytotoxic activity of CTL clones could not be suppressed by PT. The analysis of responder spleen cells, fractionated by anti-immunoglobulin panning techniques, provided evidence that L3T4-, Lyt 2+ cells mediate the PT-induced immunosuppression. We propose that suppression of the CTL response by PT is generated through the activation of L3T4-, Lyt 2+ suppressor T lymphocytes.     

The distribution of the Qa-2 alloantigen on functional T lymphocytes

The expression of Qa-2 on functional lymphocytes was investigated in vitro and in vivo by using a monoclonal anti-Qa-2 antibody. In vitro treatment of T cells with antibody and complement demonstrated that T cells mediating help or delayed-type hypersensitivity for anti-SRBC responses were Qa-2+. In addition, cytotoxic T cells and either their precursors or cells involved in their generation were Qa-2+, as were anti-HGG suppressor T cells. Panning techniques were also used to show that secondary suppressor T cells were Qa-2+ and that there may be heterogeneity in suppressor T cells defined by Qa-2 expression. In vivo treatment of mice with anti-Qa-2 resulted in decrease in immune responsiveness seen by i) prolongation of skin grafts with either H-2D or I-A differences, ii) suppression of delayed-type hypersensitivity, and iii) inhibition of T cell-mediated suppression. Finally, IgG, but not IgM, anti-body-forming cells were Qa-2+.     

Suppression of cytotoxic lymphocyte responses in vitro by soluble products of alloantigen-activated spleen cells.

Suppression of in vitro cytotoxic lymphocyte (CL) responses was mediated by soluble factor(s) produced when in vivo alloantigen-activated suppressor cells were re-exposed to alloantigen in vitro. Elaboration of suppressor factor (SF) was T cell dependent and was optimal 7 days after alloantigen injection. Suppressor factor failed to inhibit CL generation when alloantigen-primed cells rather than normal spleen cells were used as responders. Moreover, SF added at day 3 of incubation rather than at culture initiation was also ineffective, suggesting that suppression probably occurs during antigen induction or early differentiation. Additionally, suppression was abrogated by the presence of 2-mercaptoethanol. Studies combining SF and CL responder cells from a variety of H-2 disparate mouse sdrains revealed that suppression of CL responses: 1) was not alloantigen specific; 2) did not require H-2 homology between responder and suppressor strains; and 3) could not be demonstrated with CBA/J mice. Although CBA/J CL responses were not suppressed by any SF preparation, allo-sensitized CBA/J spleen cells did elaborate SF that inhibited BALB/c CL responses.     

T cell derived IL-6 is differentially required for antigen-specific antibody secretion by primary and secondary B cells

IL-6 (formerly PCTGF, HP-1, BSF-2, HGF, IFN-beta 2, 26 kDa) is a recently defined lymphokine demonstrating activity on multiple cell types, including hepatocytes, thymocytes, T cells, plasmacytomas, and B cells. The biologic effects of IL-6 on lymphocytes, particularly B cells, suggest this factor may be involved in the regulation of normal immune responses. Accordingly, we have investigated the role of IL-6 in Ag-specific responses of B cells from both naive and Ag-primed mice. When Ag-primed splenic T cells were used as a source of help, naive (primary) B cell responses specific for the hemagglutinin molecule of the influenza A virus (PR8) were fully inhibited by the addition of an anti-IL-6 antiserum, and are thus IL-6 dependent. In contrast, secondary B cell responses were essentially IL-6 independent, being unaffected by this antiserum even at concentrations 10-fold higher than required to completely inhibit primary responses. This differential IL-6 requirement was further investigated by using a panel of hemagglutinin molecule-specific Th clones. Consistent with the above findings, a Th1 clone secreting biologically active IL-6 enables antibody secretion by both primary and secondary B cells, whereas Th1 clones that do not produce IL-6 support secondary responses, but fail to help primary B cell responses unless exogenous IL-6 is added. These results provide the first instance of differential lymphokine requirements among primary vs secondary B cell responses, and suggest T cell-derived IL-6 plays a critical role during the regulation of humoral immune responses. Moreover, functionally distinct Th1 clones were identified that differed in IL-6 secretion and their corresponding ability to induce Ig secretion by primary and secondary B cells.     

Immunity to herpes simplex virus type 2. Suppression of virus-induced immune responses in ultraviolet B-irradiated mice

Ultraviolet B irradiation (280 to 320 nm) of mice at the site of intradermal infection with herpes simplex virus type 2 increased the severity of the herpes simplex virus type 2 disease and decreased delayed-type hypersensitivity (DTH) responses to viral antigen. Decrease in DTH resulted from the induction of suppressor T cells, as evidenced by the ability of spleen cells from UV-irradiated mice to inhibit DTH and proliferative responses after adoptive transfer. Lymph node cells from UV-irradiated animals did not transfer suppression. DTH was suppressed at the induction but not the expression phase. Suppressor T cells were Lyt-1+, L3T4+, and their activity was antigen-specific. However, after in vitro culture of spleen cells from UV-irradiated mice with herpes simplex virus type 2 antigen, suppressor activity was mediated by Lyt-2+ cells. Culture supernatants contained soluble nonantigen-specific suppressive factors.     

Alloantiserum-mediated supperssion of Ir gene controlled antigen-induced lymphocyte activation: effect on uridine and leucine incorporation.

Antisera to guinea pig histocompatibility antigens specifically suppress Ir gene-controlled antigen-stimulated, DNA-synthetic responses in vitro. To define further the mechanisms of alloantiserum-mediated suppression and to utilize this suppression as a probe of the cellular events occurring during lymphocyte activation, we have examined the effects of alloantisera on 14C-leucine and 3H-uridine incorporation, earlier events after antigen stimulation. The RNA and protein synthetic responses of peritoneal exudate lymphocytes from immunized guinea pigs to DNP-GL (controlled by a strain 2-linked Ir gene) are 40 to 50% of maximum by 24 hr in culture and at or near maximum by 48 hr. DNA synthesis was only 2% of maximum at 24 hr and maximum at 72 hr. Comparisons of the degree of stimulation of the incorporation of all three precursors reveals an excellent correlation between leucine and uridine but poor correlation between leucine and thymidine. Despite the observed differences in time course of incorporation and magnitude of response, the susceptibility to suppression by alloantisera of all three responses was virtually identical. Anti-2 sera, added at the initiation of culture, completely suppress all three responses. If addition was delayed 8 hr, 50 to 60% suppression was still demonstrated, whereas only minimal suppression was evidenced if addition was delayed 18 hr. These results suggest that by 8 to 10 hr of incubation with antigen, the responding cells have undergone the necessary biochemical and structural changes to eventuate in an immune response; and, furthermore, that alloantisera do not suppress by blocking antigen access to, or release from, its lymphocyte membrane receptor, but rather by a dynamic alteration of the lymphocyte membrane surface which interferes with the stimulus being generated by the antigen-receptor complex.