Characteristics of the reaction of immunologically tolerant mice to the polyclonal stimulant salmozan

The nonspecific stimulant of the immune response salmozan (Sal) increases the number of PFC against SRBC in intact mice, B mice (thymectomized, irradiated and reconstituted with embryonic liver cells), and in mice pretreated with cyclophosphamide (CY). This effect was decreased in mice pretreated with SRBC and CY. The subsequent injections of SRBC and Sal into tolerant mice did not increase the response under study. It is concluded that the effect observed is due to partial alteration of antigen-specific B cells of tolerant mice and this alteration cannot be explained by the lack of the regeneration of membrane immunoglobulins.     

The immunological status of mice during the generation of cyclophosphamide-induced tolerance.

Tolerance to sheep erythrocytes (SRBC) has been induced by a combination of high doses of antigen and treatment with cyclophosphamide (CY). The influence of CY alone or in combination with SRBC has been investigated by using the treated animals as recipients for normal spleen cells. CY treatment appears to produce a mouse which is severely depleted of B cells. The injection of large doses of SRBC together with CY, in a schedule which induces tolerance, generates an environment which suppresses the production of antibody-forming cells by passively transferred normal spleen cells. However, transfer of cells from tolerant mice to irradiated mice failed to demonstrate the presence of suppressor cells.     

Structural and serological studies of lipopolysaccharides of Citrobacter O35 and O38 antigenically related to Salmonella

Abstract Lipopolysaccharide (LPS) was administered into sheep red blood cells (SRBC)-primed mice, and the effect of LPS on SRBC-specific memory cells was investigated. Spleen cells from SRBC-primed mice which were injected with LPS exhibited much lower in vitro secondary plaque-forming cells (PFC) responses to SRBC than those from untreated SRBC-primed mice. The in vitro anti-SRBC response of the spleen cells to LPS was also reduced. The combination experiments of B cells and T cells from SRBC-primed mice which were injected with or without LPS demonstrated that the reduction of immune responses to SRBC after administration of LPS was caused by the defect of SRBC-specific B memory cells, but not T memory cells. B cell type rosette-forming cells (RFC) for SRBC markedly decreased after injection of LPS, while PFC as antibody-forming cells did not increase subsequently. Therefore, the reduction of RFC was not due to their differentiation into PFC. The lymphoid follicles in the spleens from mice injected with LPS were stained positively by in situ nick end labeling specific for fragmented DNA. A large percentage of Ig⁺ spleen cells from SRBC-primed mice which were injected with LPS was also stained positively. The injection of glucocorticoids into SRBC-primed mice induced similar reduction of B memory cells. It was suggested that LPS might induce apoptosis of B memory cells and regulate B cell memory in antigen-nonspecific manner.     

Cyclophosphamide-induced specific suppression of the protective immune response to rodent malaria.

Nonspecific and specific chemosuppression of the immune response to Plasmodium berghei protective antigens were investigated. Specific immunosuppression was defined operationally as the selective suppression of the protective response to the parasite in mice injected with a combination of gamma-irradiated infected mouse erythrocytes (gammaPb) and cyclophosphamide (CY) with continued responsiveness to sheep erythrocytes (SRBC). After initial treatment (gammaPb + CY), mice were injected with gammaPb in potentially immunogenic doses. These and appropriate control animals were later challenged with nonirradiated infected mouse erythrocytes. The influence of the initial treatment regimens on the protective response was evaluated by parasitemia, and mortality was observed after challenge. Specificity of suppression was measured by evaluating the ability of mice to produce antibody to SRBC. Both specific and nonspecific suppression of the protective response to malaria were noted. Initial treatment with drug alone resulted in increased parasitemia and mortality and suppression of the SRBC antibody synthesis in drug-pretreated immunized mice as compared with immunized mice not pretreated with the drug. On the other hand, suppression of the response to the parasite, but not to SRBC, in animals pretreated with gammaPb + CY was clearly greater than that induced by drug alone. Thus, animals treated with malarial antigen and cyclophosphamide develop a measurable specific immunosuppression. These studies indicate that immunity to malaria is influenced by both cyclophosphamide alone (general immunosuppression) and cyclophosphamide in combination with antigen (specific immunosuppression) in a manner analogous to other immune responses.     

Immunosuppressive Effect of Bacterial Lipopolysaccharide on Antibody Response

Injection of endotoxins (bacterial lipopolysaccharide: LPS) several days prior to immunization causes the suppression of antibody response. The suppressive effects of several kinds of LPS preparations on the plaque-forming cell (PFC) antibody response in the spleen of mice were examined after immunization with sheep red blood cells (SRBC). Glycolipids obtained from heptoseless mutants (Re form) of salmonella or its lipid A preparation coupled artificially with bovine serum albumin (BSA) are capable, like LPS obtained from a wild type (S form) strain, of inducing suppression of the PFC response, while alkaline-detoxified LPS can not. The refractory periods of the PFC response induced by LPS injection last only a few days. However, the use of cyclophosphamide (CY) together with LPS can extend the refractory periods of antigenic stimulation for several weeks. Injections of LPS and CY can also induce unresponsive states of OH agglutinin antibody response to antigenic stimulation with formalin-killed organisms of Escherichia coli or Salmonella enteritidis (presumably both thymus-independent antigens). These unresponsive states induced by LPS and CY are easily terminated by a transfer of syngeneic bone marrow cells but not by thymocyte transfer.     

Relation between Enhanced Antibody Responses Elicited by Adjuvant Injection and Those Elicited by Secondary Antigenic Stimulation

An attempt was made to determine if there is any common mechanism in the enhanced antibody response caused either by injection of adjuvant, such as bacterial endotoxin (LPS) and complexed polynucleotides, or by secondary antigenic stimulation. LPS inoculated in mice 4 days before injection of sheep red blood cells (SRBC) and polyA:U invalidated the adjuvant effect of polyA:U injected together with SRBC, and the hemolysin plaque-forming cell (PFC) response of such mice was similar to that of the mice which received SRBC alone. When mice primed with SRBC 24 days in advance were injected with LPS and 4 days later re-stimulated with SRBC, their PFC response to the secondary stimulation was suppressed to less than one tenth of the normal secondary PFC response. The suppressive effect of LPS on the secondary antibody response was abolished if the serum collected from mice injected with LPS was given to the primed and LPS-injected mice at the time of the secondary antigenic stimulation. From these results we discussed the possibility that some common mediator might play a role in the enhanced antibody response elicited by either adjuvant injection or secondary injection of antigen.     

Delayed-type hypersensitivity (DTH) in BCG-sensitized mice I. Lack of suppressor T cell activity on DTH to sheep red blood cells.

Mice pretreated with an intravenous (i.v.) injection of BCG (BCG-sensitized mice) and then immunized intravenously with a high dose (10(8)--10(9)) of sheep red blood cells (SRBC) 2 weeks later developed strong delayed-type hypersensitivity (DTH) to SRBC, as in mice pretreated with cyclophosphamide (CY) (CY-treated mice) and then immunized with SRBC 2 days later; normal mice given the same dose of SRBC did not show such DTH. The mechanism of this strong DTH to SRBC which developed in BCG-sensitized mice was studied, by comparing it with that in CY-treated mice. The transfer of either whole spleen cells or thymus cells, but not serum, obtained from mice immunized with i.v. injections of 10(9) SRBC 4 days previously (hyperimmune mice) did not suppress either the induction or the expression of DTH to SRBC in BCG-sensitized mice, but suppressed those in CY-treated mice. The suppressor cells were SRBC-specific T cells. Adoptive transfer of DTH to SRBC by spleen cells from either BCG-sensitized mice of CY-treated mice to hyperimmune recipients failed. The adoptive transfer of DTH from BCG-sensitized mice to normal recipients also failed if the spleen cells from hyperimmune mice were cotransferred. Whole body irradiation (600 rad) of mice 2 hr before or after the time of immunization with SRBC reduced significantly DTH to SRBC in both BCG-sensitized and CY-treated mice. It was noticed that the total number of spleen cells in BCG-sensitized mice was 3--4 times larger than that in CY-treated mice. From these results, we conclude that the entity of effector T cells of DTH to SRBC induced in BCG-sensitized mice and in CY-treated mice was not different in terms of susceptibility to suppressor T cells and irradiation, but that the total numbers of effector T cells generated in these mice differed remarkably, resulting in the above-described different responsiveness to suppressor T cells transferred passively.     

Measurement and comparison of the proliferative and antibody response of neonatal, immature and adult murine spleen cells to T-dependent and T-independent antigens.

Mouse spleen cell antigenic responses to the thymic-dependent antigen sheep red blood cells (SRBC), and the thymic-independent antigens, E. Coli lipopolysaccharide (LPS) and pneumococcal polysaccharides Type I and II (SI, SII) were studied as as a function of age, employing both in vitro spleen cell stimulation and plaque-forming cell (PFC) assay systems. Primary spleen cell proliferative and PFC responses to SRBC, were either absent or meager in comparison to adult (8–12 weeks) values for the first 3 weeks of life. Thereafter responses rose achieving adult values between 4 and 8 weeks of age. The inability of young mice to respond to SRBC was not because of a different immunizing dose requirement for SRBC, since immunization with SRBC over a 200-fold range did not enhance their capability to respond. Also, addition of adherent cells or macrophages from adult mice did not enhance the immune responses of young mice. Furthermore, immunization of 2–4 week old mice with SRBC inhibited the secondary response to SRBC. In contrast, young murine spleen cell proliferative and PFC responses to SI, SII, and LPS were approximately the same as the adult by 7–14 days of life. These data suggest that B-cell immunologic activity, as measured by immunologic assays utilized in this study, develops much earlier than does T-cell responsiveness.     

Lipopolysaccharide changes in smooth-type avirulent Shigella in comparison with initial virulent strains]

The comparative study of the lipopolysaccharides (LPS) of virulent and avirulent strains of S. sonnei, phase I (smooth colonies), has been made. Electrophoresis of LPS and subsequent densitometry of electrophoregrams have revealed the increase of the fraction of long 0-chains with a considerable number of recurring elements in 2 out of 3 LPS preparations obtained from avirulent shigellae. In mice immunized with these LPS preparations a considerably greater number of antibody-producing cells can be detected in Jerne's test on sheep red blood cells (SRBC) sensitized with the LPS of a virulent strain than on those sensitized with the above LPS preparations. Long 0-specific chains supposedly inhibit the fixation of individual complement components on the corresponding sensitized SRBC. The LPS of the third avirulent strain of S. sonnei, phase I, with transposon integrated into its genome, which has led to the formation of the avirulent variant of a previously virulent strain, seems to contain fine structural differences from the initial virulent strain. The immunogenicity of the LPS of this avirulent strain is greatly (3-4 times) decreased, which is manifested by the number of antibody-producing cells detected in Jerne's test on SRBC sensitized with LPS preparations obtained from these two strains.     

IgM complex receptors on subpopulations of murine lymphocytes.

Murine lymphocytes from spleen, lymph node, and thymus were examined for IgM complex receptors. Lymphocytes from all three organs were found to bind SRBC sensitized with IgM from various sources including: primary anti-SRBC serum, murine and rabbit anti-Escherichia coli LPS sera, and a murine IgM myeloma (MOPC 104E). Rosette formation by lymphocytes with IgM-sensitized SRBC was inhibited by soluble antigen-IgM complexes but not by IgM or antigen alone. Rosette formation was also inhibited by human IgM (Fc)5mu but not by Fab mu. Antiserum and complement treatment of the cells and subsequent recovery of the viable cells by trypsinization, filtration, and washing revealed the IgM rosette-forming cell (RFC) in the thymus to be a T cell. Spleen on the other hand was found to contain both B and T cells capable of binding IgM sensitized SRBC. Removal of both B and T cells from spleen cell suspensions eliminated all IgM RFC. The IgM complex receptor was found to be trypsin insensitive. Anti-Ig column fractionation enriched IgM RFC in spleen and lymph node suspensions passed through the columns, whereas cells bearing surface Ig, IgG complex receptors, and C3 receptors were retained in the columns.     

Role of T Cells in the Mitogen-Induced Proliferation and Polyclonal Antibody Response of Murine B Cells

The effect of thymus-derived lymphocytes (T cells) on the responsiveness of bone marrow-derived lymphocytes (B cells) to bacterial lipopolysaccharide (LPS) was determined in in vitro experiments. Radiation resistant splenic T cells obtained from euthymic nu/+ mice increased the number of proliferating cells in the cultures of splenic B cells from athymic nu/nu mice even in a nonstimulated state. The radiation resistant T cells augmented significantly the responsiveness of B cells to LPS, as determined by an increase in proliferating cells and polyclonally induced anti-sheep erythrocyte (SRBC) IgM hemolysin plaque-forming cells (PFC). Addition of the T cells to B cell cultures not only augmented the responsiveness of B cells to suboptimal doses of LPS but also enabled B cells to respond to supraoptimal doses of LPS. As is well documented, the radiation resistant T cells were unable to induce the generation of anti-SRBC PFC in B cell cultures, unless the cultures were simultaneously stimulated with SRBC. Colcemid, a specific inhibitor of cell mitosis, blocked almost completely the exponential generation of anti-SRBC PFC in B cell cultures responding to SRBC with the aid of radiation resistant T cells. In contrast, colcemid did not affect the exponential generation of anti-SRBC PFC of a polyclonal nature in B cell cultures responding to LPS, either in the presence or absence of radiation resistant T cells.     

Modification of regression of virally xenogenized tumor cells by cyclophosphamide and busulfan

Summary Rat fibrosarcoma cells infected with Friend leukemia virus (FV-KMT-17) grow for a short time and then regress spontaneously in syngeneic hosts. This regression mechanism was examined by analyzing the immunomodulating action of the antitumor drugs busulfan (BU) and cyclophosphamide (CY). In preliminary experiments, the optimum dosages of BU and CY for the enhancement of DTH responses to SRBC were 10 mg/kg and 40 mg/kg respectively. Treatment of rats with BU (10 mg/kg) on day 5 induced the regression of KMT-17 cells, while in contrast, the same drug delayed the spontaneous regression of FV-KMT-17 cells. Pretreatment with CY (40 mg/kg) on day 5 did not affect the growth of KMT-17 or FV-KMT-17 cells. After the same treatment schedule, BU inhibited humoral antibody formation against SRBC and against virus-associated antigen (VAA), NK cell activity, and ADCC effector cell activity. On the other hand, CY did not affect the activities of NK cells or ADCC effector cells, although it significantly augmented the DTH responses to SRBC and the production of antibody to VAA but had no effect on production of antibodies to SRBC. These results suggest that NK cells and ADCC may play an important role in the initial stage of the spontaneous regression of FV-KMT-17 cells.Supported in part by a Grant-in-Aid for Cancer Research from the Japanese Ministry of Education Abbreviations used: BU, busulfan; CY, cyclophosphamide; PFC assay, plaque forming cell assay; VAA, virus-associated antigen; NK cell, natural killer cell; ADCC, antibody dependent cellular cytotoxicity; MuLV, murine leukemia virus; DTH, delayed type hypersensitivity; SRBC, sheep red blood cells; C.I., cytotoxic index; CRBC, chicken red blood cells; IL-1, interleukin 1; IL-2, interleukin 2; IFN, interferon     

Nonspecific Elicitation of Antibody-Forming Cells in the Mouse Spleen by Bacterial Lipopolysaccharide

Mechanisms of nonspecific elicitation of anti-sheep erythrocyte (SRBC) hemolytic antibody plaque-forming cells (PFC) in mouse spleens with an injection of bacterial endotoxin (lipopolysaccharide (LPS)) were studied in comparison with the genesis of naturally occurring ‘background’ PFC in normal mouse spleens and of rapidly arising PFC in mouse spleens after immunization with SRBC. The cytokinetic pattern of anti-SRBC PFC response after an injection of LPS was quite different from that of the response elicited after immunization with SRBC. In addition, even though LPS nonspecifically elicited anti-SRBC PFC response in mice, LPS could not confer any immunological memory on mouse immunocytes for a ‘secondary-type’ anti-SRBC PFC response to restimulation with LPS or SRBC. The administration of rabbit anti-mouse thymocyte immunoglobulin or anti-SRBC antiserum in mice markedly suppressed the PFC response after immunization with SRBC, but did not do so after stimulation with LPS. Neonatally thymectomized mice could still respond to stimulation with LPS, producing anti-SRBC PFC in their spleens. Injections of actinomycin D or cyclophosphamide into mice resulted in obvious reductions of the PFC responses elicited by either LPS or SRBC. However, injections of these immunosuppressive antisera or drugs did not affect the number of anti-SRBC PFC in normal mouse spleens. These results suggest that the geneses of anti-SRBC PFC developed under different conditions, i.e., background PFC, LPS-stimulated PFC, and antigen-stimulated PFC, are quite different from each other, and that the nonspecific elicitation of anti-SRBC PFC by LPS does not require the helper function of T lymphocytes. No obvious difference, however, was observed in the time of ontogenic maturation among these three different anti-SRBC PFC in the mouse spleens judging from when they were first manifested after birth.     

Hapten-specific murine colony-forming B cells. III. Delineation of functional B cell subpopulations grown under different conditions

The influence of anti-immunoglobulin M (IgM) and anti-IgD on the ability of fluorescein (FL)-specific B cells to proliferate in a colony-forming assay, and of their progeny to further differentiate in response to different FL-antigens was studied. Splenic FL-specific B cells were purified on FL-gelatin plates and were then cultured in semisolid agar in the presence or absence of anti-mu, and anti-delta, or both. Experiments were performed under conditions of either sheep red blood cell (SRBC)-potentiated or SRBC + lipopolysaccharide (LPS)-potentiated colony growth. The resulting colonies were then tested in secondary filler cell-dependent microcultures for the ability to be triggered by different classes of FL-antigens to yield plaque-forming cells (PFC). Anti-delta inhibited 47% of colony growth under both agar culture conditions. Anti-mu inhibited 55% of colony growth in SRBC + LPS-potentiated agar cultures, and inhibited 72% if only SRBC was present. If anti-delta and anti-mu were added together, inhibition was nearly additive. When anti-Ig-treated colonies were tested for PFC responses against FL-polymerized flagellin (POL), both normal and anti-delta resistant colonies, grown under both agar culture conditions, responded well. Anti-mu resistant colonies were refractory to FL-POL challenge. Only normal or anti-delta resistant colonies grown in SRBC + LPS agar cultures were able to respond well to FL-Ficoll, whereas even normal SRBC-potentiated colonies responded poorly. All except SRBC-potentiated, anti-mu treated colonies were able to respond to nonspecific signals present in cultures containing FL-KLH and activated T cell help. These data suggest that addition of specific anti-Ig antibodies, and variation of agar culture conditions, can select for B cell subpopulations responsive only to certain types of antigens.     

Difference in thymus dependency between effector and suppressor T cells for delayed footpad reaction to sheep erythrocytes in mice

Effects of thymectomy at various times after birth on effector and suppressor T cells for a delayed footpad reaction were determined in 6-week-old mice immunized intraperitoneally (ip) with sheep erythrocytes (SRBC). Mice thymectomized 1 day after birth (Tx-1 mice) gave delayed footpad reactions weaker than those of mice thymectomized 7 days after birth (Tx-7 mice) or sham operated (SH mice) after immunization with a low dose of SRBC. After immunization with a high dose of SRBC, on the other hand, Tx-1 mice showed reactions stronger than those of Tx-7 or SH mice. Pretreatment with cyclophosphamide (CY) augmented the delayed footpad reaction in Tx-7 or SH mice, but not in Tx-1 mice, immunized with a high dose of SRBC. The presence of T cells suppressive for the delayed footpad reaction in the spleen of Tx-7 or SH mice was confirmed by cell transfer experiments. These results suggest that effector T cells responsible for a delayed footpad reaction to SRBC are less thymus dependent and require the presence of the thymus for a shorter period in their development compared to suppressor T cells.     

Antigen-reactive cell opsonization: a mechanism of antibody-mediated immune suppression.

Antisera against sheep red blood cells (SRBC) specifically suppressed the direct anti-SRBC plaque-forming cell (PFC) response in mice when passively administered with the antigen. The suppressive activity of mouse and rabbit anti-SRBC sera was found to correlate with anti-SRBC opsonic activity but not with hemagglutination or hemolysin titers. Macrophage depletion of mice, using carrageenan treatment, inhibited antibody-mediated immune suppression. When mice immunized with SRBC were given ¹²⁵I-labeled Udr, radiolabeled spleen lymphocytes were obtained which specifically formed rosettes with SRBC. These radiolabeled antigen-reactive cells (1ARC) were specifically opsonized in mice treated with antigen-antibody complexes but not in mice treated with antigen or antibody alone. These results suggest that antibody-mediated immune suppression may be due to specific opsonization (and subsequent destruction) of ARC in the presence of antigen-antibody complexes.     

Morphological changes in the endocrine pancreas of mice after treatment with streptozotocin combined with cyclophosphamide and neurotropin.

The effect of neurotropin (NSP) in combination with streptozotocin (STZ) and cyclophosphamide (CY) on blood glucose and pancreatic histopathology on day 7 and day 14 after the initiation of the treatment was studied in C57Bl/6 male mice. STZ (40 mg/kg) and NSP (1 mg/kg) were applied intraperitoneally on five consecutive days and CY (150 mg/kg)--twice on day 1 and day 3. In single B cells dilatation of the endoplasmic reticulum was found. On day 7 in proximity to some endocrine cells in the mice treated with STZ, STZ + CY + NSP and STZ + CY macrophages were observed. On day 14 lymphocytic infiltration of the islets was demonstrated only in the groups of mice injected with STZ, STZ + CY while in the group treated with the combination STZ + CY + NSP no infiltration was seen. All experimental groups showed no biochemical evidence for hyperglycemia probably due to the mild destruction of a small number of B cells. The results indicate that NSP might possess a restorative action on insulitis induced by multiple low dose streptozotocin administration in mice.     

IL-1 gene expression in lymphoid tissues

We examined the expression of IL-1 mRNA in vivo by in situ hybridization. RNA probes for murine IL-1 alpha and IL-1 beta were used to detect IL-1 mRNA in frozen sections of spleen, lymph node, and thymus of mice injected with Salmonella typhi LPS or SRBC. No IL-1 was detected in lymphoid tissues from un-injected mice. This lack of expression correlated with the absence of IL-1 biologic activity. However, after LPS injection, IL-1 alpha and beta mRNA expression was found in macrophages of the red pulp and marginal zone of the spleen. The periarteriolar lymphoid sheath contained cells that only expressed IL-1 beta mRNA. These cells were not lymphocytes and did not stain with the macrophage marker F4/80. A similar cellular response was found after SRBC injection. Scattered macrophages in lymph nodes and thymus were positive, but only after LPS or SRBC injection. The spleens of mice injected with LPS had megakaryocytes containing IL-1 mRNA.     

B memory cells in the thymus: part of the pool of potentially circulating memory cells.

Immunization of mice with sheep red blood cells (SRBC) or Escherichia coli lipopolysaccharide (LPS) induces the appearance of B memory cells in the thymus. In this paper the origin of these B memory cells was investigated. Therefore, mice primed with either SRBC or LPS 6 months previously and nonprimed mice were joined for parabiosis. Four weeks later the parabiotic mice were separated from each other. Another 3 weeks later thymus cells from the primed and nonprimed mice were transferred separately into lethally irradiated mice in order to determine the adoptive PFC response. It was found that the 4-week period of parabiosis could account for the appearance of a distinct population of B memory cells in the thymus of the nonprimed mice. This result suggest that the B memory cells which appear in the thymus belong to the pool of potentially circulating memory cells.     

Different effects of the capsular polysaccharide of Klebsiella pneumoniae on the functions of various subpopulations of B cells in the immune response of mice to T-dependent antigen.

Using the capsular polysaccharide of Klebsiella pneumoniae (CPS-K) as a polyclonal B-cell activator (PBA) and sheep red blood cells (SRBC) as a T-dependent antigen, we studied the effects of PBA on the functions of various subpopulations of B cells in the immune response of mice to T-dependent antigen. Antibody-forming cells (AFC) of IgM and IgG types were estimated as anti-SRBC direct and indirect plaque-forming cells (PFC), and the B cells with precursor activities involving generation of AFC and supplementing new B cells as rosette-forming cells (RFC) of the B-cell type. Stimulation of normal mice by CPS-K caused a definite increase in the number of direct PFC but not in that of indirect PFC and RFC in the spleens. The responsiveness of spleen cells of CPS-K-treated mice to generate PFC and RFC responses to a subsequent injection of SRBC was lower than that of CPS-K-untreated normal mice. In this case, the responsiveness to generate RFC and indirect PFC was inhibited more strongly by CPS-K than that to generate direct PFC. When CPS-K was injected into normal mice simultaneously with SRBC, CPS-K never decreased but increased the levels of PFC and RFC responses to SRBC. In the spleens of SRBC-primed mice, the number of RFC was markedly decreased following injection of CPS-K, the number of direct PFC was increased only slightly and the number of indirect PFC was increased very slightly. The responsiveness of spleen cells of these CPS-K-treated SRBC-primed mice to generate secondary PFC and RFC responses to a subsequent injection of SRBC was much lower than that of CPS-K-untreated SRBC-primed mice. In this case, the responsiveness to generate the secondary RFC and indirect PFC responses was more strongly inhibited by CPS-K than that to generate the secondary direct PFC response. When CPS-K was injected into SRBC-primed mice simultaneously with the secondary injection of SRBC, there were marked decreases in the level of the secondary RFC response and slight decreases in that of the secondary indirect PFC response, but little change in that of the secondary direct PFC response. From these results it has been concluded that CPS-K provides the positive signal (the minor action) and the negative signal (the major action) to various subpopulations of B cells functioning at various stages of the immune response to T-dependent antigen in different ways, and acts to regulate the levels of B-cell responses to the antigen-mediated positive signal.