Suppressor T cells and self-tolerance. Active suppression required for normal regulation of anti-erythrocyte autoantibody responses in spleen cells from nonautoimmune mice

Spleen cells from young, nonautoimmune strains of mice cultured with syngeneic E do not develop a significant anti-mouse E response in vitro, consistent with a state of self-tolerance to this Ag. In order to study the role of active suppression in regulating mouse RBC-(MRBC) specific cells in nonautoimmune cell populations, the effect of depleting T cell subsets on the generation of anti-MRBC autoantibodies by nonautoimmune spleen cells was determined. Spleen cells from young BALB/c and C57BL/6 mice were found to generate significant numbers of IgM and IgG anti-MRBC autoantibody-forming cells in culture with MRBC after depletion of Ly-2+ cells by anti-Ly-2 and C treatment. The response which develops is Ag dependent, Ag specific, and dependent upon L3T4+ Th. The magnitude and isotype of this response is similar to the anti-MRBC response generated by spleen cells from 12-mo-old, autoimmune NZB mice and young NZB mice also treated to remove Ly-2+ cells. Addition of isolated Ly-2+ T cells, but not L3T4+ or Ly-2- T cells, to spleen cells depleted of Ly-2+ cells restores apparently normal regulation of the anti-MRBC response in vitro. These data demonstrate that control of a specific autoantibody response to MRBC by nonautoimmune spleen cell populations requires active regulation by an Ly-2+ T cell subset.     

Development of self-tolerance in normal mice. Appearance of suppressor cells that maintain adult self-tolerance follows the neonatal autoantibody response

T cell populations from BALB/c mice at different ages were analyzed to determine when in development Ts cells specific for the anti-mouse RBC (MRBC) autoantibody response become activated. Previous studies have shown that adult CD8+ T cells actively suppress this autoimmune response and adult spleen cells depleted of CD8+ cells can generate an anti-MRBC response in culture with MRBC. The present results demonstrate that T cells from mice less than 1 wk of age do not suppress the in vitro anti-MRBC response of adult spleen cell populations depleted of CD8+ Ts cells. By 2 wk of age Ts cells are detectable in this anti-self response and reach adult levels by 3 wk of age. Non-specific "natural suppressor" cells normally present in neonatal spleen cell populations are unable to suppress this autoantibody response, although they are active in suppressing anti-SRBC responses in the same cultures. Before the appearance of Ts cells active in the anti-MRBC response, neonatal spleen cell populations can generate anti-MRBC antibody-forming cells, both spontaneously in vivo and in vitro. The in vitro anti-MRBC response of neonatal spleen cells was shown to be Ag driven and Ag specific. The ability of unfractionated spleen cells to generate this response in vitro declines with age and is relatively low by 3 wk. This decline in responsiveness occurs simultaneously with the appearance of suppression specific for the anti-MRBC response, suggesting that the two events may be causally related.     

In vitro regulation of the pathogenic autoantibody response of New Zealand black mice. I. Loss with age of suppressive activity in T cell populations

An investigation of the regulation of specific anti-self responses was initiated with the development of an in vitro system in which spleen cells from NZB mice were stimulated by syngeneic mouse erythrocytes (MRBC) to produce MRBC-specific autoantibody-secreting cells. The response was measured by a modification of the focus-forming cell (FFC) assay, which enumerates cells secreting IgG, which specifically bind MRBC. Spleen cells from 9- to 12-mo-old NZB mice developed MRBC-specific FFC after 3 to 5 days in culture with MRBC. Few FFC were detected in the absence of MRBC in culture. Spleen cells from young (1- to 4-mo-old) NZB mice developed few if any FFC. Spleen cell populations containing T cells from young NZB mice suppressed this anti-MRBC response, whereas B cell populations from these young mice did not. In contrast, spleen cells, including T cell-enriched populations from old, Coombs'-positive mice were not capable under the same conditions of producing equivalent suppression of this in vitro autoimmune response. These data suggest that a population of suppressor T cells that may control the autoimmune anti-MRBC response in young NZB mice is lost, or else its activity is masked in old NZB mice that are actively producing anti-MRBC antibody.     

LPS-induced autoantibody response. I. Ontogenic development of PFC response to bromelain-treated syngeneic erythrocytes

Normal adult mice have been shown to contain a large number of cells secreting antibodies against bromelain-treated syngeneic erythrocytes (Br.MRBC) and the numbers remarkably increase by the stimulation with LPS. In this report development of the anti-Br.MRBC response during ontogeny was examined and it was shown that on the injection of LPS suckling mice responded little to generate splenic plaque-forming cells (PFC) against Br.MRBC in vivo and in vitro. The responsiveness of suckling mice to produce anti-Br.MRBC was shown to be less developed than the anti-TNP response or the mitotic response to LPS. The low responsiveness of suckling mice was analyzed in terms of suppressor activity in the spleen cell population, proliferative capacities of the precursors of anti-Br.MRBC PFC, and their frequencies in the spleen. In the coculture experiment of suckling and adult spleen cells or culture of anti-brain-associated Thy 1-treated, macrophage-depleted spleen cell population, no evidence was obtained to show that suckling spleen cells contained suppressor cells. Kinetic profiles studied in vitro showed that anti-Br.MRBC PFC in the suckling spleen did not increase during the culture as those in the adult spleen. Studies on the precursor frequencies revealed that spleen cells of 15-day-old mice contained precursors of anti-Br.MRBC PFC amounting to 20.5% of the adult precursors whereas the PFC response in vitro by the former was only 4% of the latter. From these experimental data, it was concluded that the low responsiveness of suckling mice was partly due to the low frequency of the precursors in the spleen and, in addition, to the defective nature of the precursors in proliferating to differentiate into PFC.     

Regulation of naturally occurring autoantibody-producing cells: detection of a suppressive substance which inhibits the secretion of antibodies directed against enzyme-treated isologous erythrocytes

Normal mice possess spleen cells capable of forming hemolytic plaques against bromelain-treated autologous red cells (Br MRBC). There is present in the serum of these same mice a substance which can inhibit the formation of these plaques. This substance is inhibitory to the secretion of these antibodies following incubation of spleen cells in 20% serum at 4 degrees C for 5 min. This substance is not inhibitory to the formation of anti-sheep erythrocyte plaques from mice either immunized or nonimmunized with sheep erythrocytes. Characterization of the substance indicates that it is neither soluble antigen nor specific antibody. However, inclusion of nanogram amounts of soluble antigen from bromelain-treated red cells in the assay mixture effectively neutralized the suppression. In addition, passage of serum through a mouse anti-Br MRBC antibody immunoadsorbent effectively removed the suppressive activity of the serum while suppression could be recovered in the acid eluate from such a column. This suggests that the mechanism of suppression brought about by incubation in serum is due to the action of a molecule possessing anti-idiotypic activity directed against the cell surface receptors of anti-Br MRBC B cells. Attempts to isolate the molecule based on the postulate that it is immunoglobulin in nature have been unsuccessful.     

The properties of plaque-forming cells from autoimmune and normal strains of mice with specificity for autologous erythrocyte antigens.

Treatment of mouse erythrocytes with the proteolytic enzymes, bromelain, reveals antigenic determinants not normally exposed on the erythrocyte surface. It was found that not only NZB mice, a known autoimmune strain, but also several normal strains of mice contain cells in small numbers in their spleens and in larger numbers in their peritoneal cavities which will form plaques against bromelain-treated MRBC. During in vitro culture the number of anti-BR-MRBC PFC increases slightly in the spleen cell populations whereas the number of these PFC in peritoneal cells increases dramatically to as many as 100,000 PFC/10(6) cells. The plaques detected in this assay contain a central lymphoid cell and their development, which requires the presence of complement and protein synthesis, is inhibited by anti-mouse immunoglobulin.     

Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

Golden hamsters were used as hosts in this work, and mice of various strains as donors of antigens. 1) There were no strain differences in immunogenicity of erythrocytes from C57BL/6, AKR, SL and CF1 mice. 2) Primary intravenous immunization with mouse erythrocytes (MRBC) induced the production of hemolysin plaque-forming cells (PFC) in a large number, but elicited only in a negligible titer production of 2-mercaptoethanol-resistant antibody. 3) 2-Mercaptoethanol-resistant antibody was produced more efficiently in hamsters pre-sensitized with mouse lymph node (MLN) cells rather than those pre-immunized with MRBC after a booster with MRBC. 4) Numbers of PFC in pre-sensitized hamsters were three-times that of the non-sensitized hamsters after a booster with MRBC, when pre-sensitization was performed intradermally with a small number of MLN cells. 5) Average diameter of the hemolysin plaques in pre-sensitized hamsters was one and a half times larger than that in non-sensitized hamsters. Conclusions agree well with the results in our previous papers that the reversed combination of hosts and antigen donors employed support the concept that certain processes required for delayed hypersensitivity contributed to antibody production under a condition suitable for antibody response.     

A self determinant recognizing T cell hybridoma

A T cell hybridoma (53(113)) obtained by fusion of BALB/c spleen cells and the BW 5147 lymphoma T cell line is described. This hybridoma recognizes mouse RBC (MRBC) and rat RBC, but not human, rabbit, guinea pig, or SRBC. The culture supernatant possesses hemagglutinating activity for the same indicator RBC. In addition to this, 53(113) cells are able to form protein A plaques in the presence of guinea pig complement and normal mouse serum (NMS) or purified mouse immunoglobulins (Ig). Because mouse Ig as well as sonicates from MRBC are able to inhibit the rosettes between the hybridoma cells and the MRBC, and because the sonicates inhibit protein A plaque formation, it seems likely that the same product can recognize a similar determinant expressed on MRBC and mouse Ig. The hypothesis that a 53(113) structure recognizes identical or cross-reactive carbohydrate determinants shared by murine Ig and C is considered.     

Analyses of acute graft-versus-host-like reaction in [MRL/lpr----MRL/+] chimeric mice using MRL/lpr-Thy-1. 1 congenic mice.

When MRL/Mp(-)+/+(MRL/+) mice are lethally irradiated and then reconstituted with MRL/Mp-lpr/lpr (MRL/lpr) bone marrow and/or spleen cells, these MRL/+ mice develop "lpr-GVHD" which is similar to acute graft-versus-host disease (GVHD). Using a Thy-1 congenic strain of MRL/lpr mice (MRL/lpr-Thy-1.1), we analyzed T cell subpopulations in the thymus and spleen of MRL/+ mice suffering from lpr-GVHD. lpr-GVHD was induced in MRL/+ mice by transplantation of bone marrow cells (BMC) from MRL/lpr-Thy-1.1 mice; severe lymphocyte depletion associated with fibrosis was observed in the spleens after 7 weeks of bone marrow transplantation (BMT). Thymocytes of the host MRL/+ thymus were replaced with donor-derived cells from the early stage of lpr-GVHD, whereas in the spleen, a small number of host T cells (Thy-1.2+) (4-5%) were retained until the late stage of lpr-GVHD. Donor-type (Thy-1.1+) T cell subsets were not different from those of nontreated MRL/+ mice in the thymus, whereas in the spleen. CD8+ T cells (Thy-1.1+) reached a peak at 5 weeks after BMT, and CD4+ T cells (Thy-1.1+), a peak at 6 weeks. The elimination of T cells from MRL/lpr BMC had no evident effect on the prevention of lpr-GVHD. T cell subpopulations showed a similar pattern to GVHD elicited by MHC differences. Analyses of autoreactive T cells expressing V beta 5 or V beta 11 revealed that autoreactive T cells were deleted from the peripheral lymph nodes. Interestingly, the levels of IgG anti-ssDNA antibodies markedly increased, and both IgM and IgG rheumatoid factors slightly increased 5 to 7 weeks after BMT. These findings are discussed in relation to not only GVHD elicited by MHC differences but also autoimmune diseases.     

Development of copper deficiency in neonatal mice

Dietary copper (Cu) deficiency was produced in Swiss albino mice to determine the temporal relationship between depletion of Cu and changes in the cardiovascular and nervous system. Dams were placed on a Cu-deficient diet 4 days after parturition. Half the dams were provided with deionized water and their offspring are referred to as Cu-deficient (-Cu). Half the dams were given cupric sulfate in their drinking water (20 microg Cu/mL) and their offspring are referred to as Cu-adequate (+Cu). At 6 weeks of age a sample of the -Cu mice were repleted with CuSO(4). Mice were sampled 1 day after birth and at weekly intervals for 7 weeks. Both +Cu and -Cu mice grew at the same rate: birth weight increased 16-fold at 6 weeks of age. Liver Cu more than doubled between 1 and 7 days of age. At 2 weeks of age -Cu mice were anemic (lower hematocrit and hemoglobin) and had lower liver Cu and plasma ceruloplasmin activity compared to +Cu mice. Liver Fe was not elevated in -Cu mice until 2 weeks after anemia developed. At weaning first signs of altered catecholamine metabolism included elevation of dopamine in both heart and spleen. Norepinephrine concentrations and content, in contrast, were not both lowered in -Cu mice until 5 weeks of age. Heart weight was first elevated in -Cu mice at 6 weeks of age and relative weight (mg/g body wt) at 4 weeks of age. Liver Cu concentration was lower in 1-week repleted mice than in +Cu mice. Anemia preceded the development of cardiac hypertrophy and altered catecholamine levels in -Cu mice.     

Expression of the J11d marker on peripheral T lymphocytes of MRL-lpr/lpr mice

MRL-lpr/lpr (lpr) mice spontaneously develop massive lymphadenopathy resulting from the expansion of a unique population of Thy-1+ cells which are CD4- and CD8- (double negative) and the nature of which is not clear. The antibody J11d has been shown to define a differentiation Ag found on immature thymocytes but not on mature and functional peripheral CD4+ or CD8+ T cells. To analyze the possible relationship between the lpr double-negative T cells and the thymocytes, we investigated the simultaneous expression of J11d and Thy 1 Ag on the double-negative lpr lymph node cells by using two-color immunofluorescent staining technique. We observed that lpr mice at 3 to 4 weeks of age, before the onset of lymphadenopathy, did not have significant numbers (less than 4%) of J11d+ T cells in the periphery, similar to the number found in the control MRL +/+ mice. However, with increasing age of approximately 8 to 10 weeks and coinciding with the appearance of lymphadenopathy, a significant number (approximately 35%) of J11d+ Thy-1+ cells started appearing in the periphery of lpr mice and was maintained until the mice died at 20 to 24 weeks of age. The J11d+ T cells belonged to the abnormal double-negative T cell pool, inasmuch as J11d+ CD4+ or J11d+ CD8+ cells were absent in the lymph nodes of 20-wk-old lpr mice. Furthermore, 20-wk-old lpr mice demonstrated increased numbers (approximately 41%) of double-negative T cells in the thymus, a significant proportion of which were J11d+. In contrast, the 20-wk-old +/+ mice or 4-wk-old lpr mice had only 4% double-negative T cells in the thymus. The present study suggests that a significant number of peripheral double-negative T cells of lpr mice bear the immature thymic differentiation Ag J11d. The possibility that the accumulation of double-negative T cells results from abnormal peripheralization of double-negative J11d+ thymocytes, before complete differentiation into CD4+ or CD8+ T cells, is discussed.     

Suppression of cell-mediated immunity by street rabies virus infection.

An attempt to define a severe suppression of cell-mediated immunity by street rabies virus infection was undertaken by using the mice lethally and peripherally infected with a street rabies virus (1088 strain). The cell-mediated cytotoxic (CMC) activity of the spleen cells from those mice once slightly increased until day 4 after infection but declined rapidly thereafter until their death on days 10 to 12 after infection. In parallel with a decrease of CMC response of the spleen cells from 1088-infected mice, proliferative response to Con A, IL-2 activity in the culture supernatants of Con A-induced proliferation, responsiveness to exogenously added IL-2 and to Con A to express IL-2R, of those cells became suppressed, and the marked decrease of the total number of spleen cells was observed. Selective depletion of CD4+ and CD8+ cells in the spleens, abnormalities of IL-1 and E-type prostaglandins (PGE2) production or production of inhibitory component able to block IL-2 activity by spleen cells were not observed and these factors did not appear to be associated with the suppression of proliferative response to Con A. However, an apparent association of CD8+ cells in the suppression of differentiation of pre-cytotoxic lymphocytes (CTL) into CTL was demonstrated in the co-culture experiments of the spleen cells from 1088-infected mice with spleen cells of mice infected with an attenuated rabies virus (ERA strain) which can induce higher levels of CMC response. There was no evidence of the productive replication of rabies virus in thymus and spleen of 1088-infected mice. The relationship of these observations to current theories on virus-induced immunosuppression was discussed.     

Ontogeny of Nk-1+ natural killer cells. I. Promotion of Nk-1+ cells in fetal, baby, and old mice

Using anti-Nk-1.1 serum, the alloantiserum specific for murine natural killer (NK) cells, we followed the ontogenetic development of Nk-1+ cells in fetal thymus, liver, and spleen. A transient population of Nk-1+ cells in fetal thymus was observed on day 14 but not on day 16 of gestation. On day 16 of gestation, Nk-1+ cells were detected only in liver and spleen. The proportion of Nk-1+ cells in spleen remained high (20 to 30%) at birth and persisted until 2 to 3 wk old. The Nk-1+ cells in "baby" (1 to 2 wk old) spleen bound to YAC cells but failed to lyse them in 51Cr-release assay. Upon induction with interferon (IF), the proportion of Nk-1+ cells increased, but the lytic activity remained low, suggesting that the "baby" NK-1+ cells are immature in lytic function. In old mice (12 to 14 mo), Nk-1+ cells were also detectable, even though NK activities were lower compared with those of the young adult (6 to 8 wk old) mice. The Nk-1+ cells of old mice were readily induced by IF to exhibit activities, and the induced NK cells were Nk-1+. We have thus established Nk-1.1 antigen as an early hemopoietic differentiation antigen. Splenic Nk-1- cells could be induce by IF to become NK-1+ cells, which could be inactive or active in NK assays, dependent on the age of the mice.     

Ontogeny of Cell-Mediated Immunity of Murine Thymocytes and Spleen Cells

The ontogeny of cell-mediated immunity of spleen cells and thymocytes from B10 mice was studied in both in vitro mixed leukocyte culture and cell-mediated lympholysis reactions. Results show that newborn spleens contain cells competent to respond to X-irradiated allogeneic spleen cells in mixed leukocyte culture. The mixed leukocyte culture response of spleen cells, in terms of both index of stimulation and increment of tritiated thymidine incorporation, seems to be higher for mice four weeks or older than for mice less than four weeks old. The cell-mediated lympholysis response of spleen cells is not detectable until two days postpartum. It reaches adult levels in terms of % cytolysis by day four after birth. Thus, the transition period of the ontogeny of cell-mediated lympholysis response of spleen cells is apparently 0–4 days of age.
Newborn and early postnatal thymocytes (0–7 days of age) respond in mixed leukocyte culture at least as strongly as adult thymocytes (2–3 months of age). The cell-mediated lympholysis response of thymocytes is already detectable at birth, but weaker in terms of % cytolysis when compared with the cell-mediated lympholysis response of thymocytes from two days to six weeks of age. The cell-mediated lympholysis response of thymocytes starts to decline at 6–8 weeks of age. Thus, around the time of birth, there is a transition period in the cell-mediated lympholysis response of thymocytes during which thymocytes start to show high cell-mediated lympholysis reactivity. There is a second transition period between six and eight weeks of age during which the cell-mediated lympholysis response of thymocytes diminishes. The early, as well as late, postnatal cell-mediated lympholysis response of both spleen cells and thymocytes seems to be specific in nature.     

Differences in thymus dependency among the alloreactive T-cell subpopulations in their development

Effects of thymectomy at various times after birth (Tx-1, Tx-3, Tx-7, Tx-14) on mixed lymphocyte reaction (MLR), cell-mediated cytotoxicity (CMC), and graft-versus-host reaction (GVHR) were examined by experiments with spleen cells obtained at 8 weeks of age. All of MLR, CMC, and GVHR were detected in spleen cells of Tx-14 mice. However, the ability of spleen cells to induce GVHR was abolished by thymectomy at 7 days after birth. On the other hand, MLR and CMC were not affected in such mice. In Tx-1 or Tx-3 mice, only MLR was detected in spleen cells. These results suggest that thymus dependency of T cells responsible for MLR are lower in their maturation than those for CMC and that thymus dependency of T cells responsible for GVHR are the highest among these T-cell subpopulations.     

Absence of mitochondrial uncoupling protein 3: effect on thymus and spleen in the fed and fasted mice

Mitochondrial uncoupling protein 3 (UCP3) is constitutively expressed in mitochondria from thymus and spleen of mice, and confocal microscopy has been used to visualize UCP3 in situ in mouse thymocytes. UCP3 is present in mitochondria of thymus and spleen up to at least 16 weeks after birth, but levels decrease by a half in thymus and a fifth in spleen after three weeks, probably reflecting the suckling to weaning transition. UCP3 protein levels increase approximately 3-fold in thymus on starvation, but expression levels in spleen were unaffected by starvation. Lack of UCP3 had little effect on thymus mass or thymocyte number. However, lack of UCP3 affected spleen mass and splenocyte number (in the fasted state) and results in reduced CD4+ single positive cell numbers and reduced double negative cells in the thymus, but as a 2-fold increase in the proportion of CD4(+), CD8(+) and DP cells in spleen. Starvation attenuates these proportionate differences in the spleen. A lack of UCP3 had no apparent effect on basal oxygen consumption of thymocytes or splenocytes or on oxygen consumption due to mitochondrial proton leak. Splenocytes from UCP3 knock-out mice are also more resistant to apoptosis than those from wild-type mice. Overall we can conclude that UCP3 affects thymocyte and spleen cell profiles in the fed and fasted states.     

Expression and regulation of a recurrent anti-erythrocyte autoantibody idiotype in spleen cells from neonatal and adult BALB/c mice.

BALB/c spleen cells depleted of CD8+ T cells generate an autoantibody response to mouse RBC (MRBC) when cultured 5 days in the presence of syngeneic RBC. More than 80% of the cells secreting anti-MRBC antibody are blocked by an antiidiotypic mAb that recognizes the G8 Id. This G8 Id was originally identified in an autoimmune NZB mouse derived anti-MRBC mAb and later characterized as a dominant Id in NZB anti-MRBC autoantibodies. Furthermore, the CD8+ regulatory T cells that control this autoimmune response in BALB/c mice are specifically eliminated by cytotoxic treatment with the G8 mAb + C, suggesting that the regulatory cells recognize the G8 Id. Spleen cells from neonatal BALB/c mice, which lack those regulatory cells can generate an in vitro antibody response to MRBC without depletion of CD8+ cells. More than 80% of these AFC were also found to express the G8 Id. We propose that Id determinants on autoantibodies that are produced neonatally induce Id-specific regulatory cells that maintain peripheral tolerance to self-RBC throughout the life of normal animals.     

Spontaneous clones of cytotoxic T cells in culture. I. Characteristics of the response.

A culture system has been developed which allows segregation of individual clones of cytotoxic lymphocytes (CLs). When CBA, DBA, or (CBA × DBA)F₁ spleen cells from adult mice were cultured, clones of CLs able to lyse P815 target cells were generated in the absence of stimulating cells. The effector cells are sensitive to anti-Thy-1 serum and include cells with anti-self reactivity. The maximum number of CL clones was detected on Day 4, while the largest size of clones occurred 1 or 2 days later. In contrast to stimulated cultures, there was a nonlinear relationship between the number of clones and the concentration of spleen cells in the culture. The generation of spontaneous cytotoxicity is a characteristic of adult spleens and does not develop until mice are 4 weeks old.     

Wild mouse ecotropic murine leukemia virus infection of inbred mice: dual-tropic virus expression precedes the onset of paralysis and lymphoma.

NFS/N mice inoculated at birth with an ecotropic murine leukemia virus (Cas-Br-MuLV) obtained from wild mice developed hind limb paralysis beginning at 7 weeks of age and nonthymic lymphomas beginning at more than 20 weeks of age. Studies of 1- to 7-week-old Cas-Br-M MuLV-infected mice showed the following: (i) a marked increase in nonecotropic MuLV-related antigens on spleen cells but not thymocytes beginning at 2 weeks; (ii) the appearance of dual-tropic mink cell focus-forming (MCF) MuLV-related gp70 in spleen but not thymus or brain cells at 4 weeks; and (iii) the isolation of infectious MCF MuLV from spleen cells of 7-week-old mice. A role for MCF MuLV in Cas-Br-M MuLV-induced nonthymic lymphomas is indicated by these studies, and a role for recombinant MuLV in neurological disease is considered.     

Effects of inositol, LiCl, and heparin on the antibody responses to SRBC by normal and immunodeficient XID mice

Spleen cells from na?ve adult immunocompetent and immunodeficient XID mice were cultured on agar containing sheep red blood cells (SRBC) with and without myo-inositol, scyllo-inositol, lithium chloride, or heparin, and after 1 or 2 days the number of colonies of antiSRBC antibody-forming cells (PFC) were determined. It was found that myo-inositol and scyllo-inositol at one-tenth the concentration were equally effective in increasing the number of specific PFC. Myo-inositol, scyllo-inositol, and lithium chloride accelerated the appearance of direct foci in cultures of spleen cells from normal and XID mice. When heparin was added to cultures of XID spleen cells, PFC were found to be increased on Day 1; however, PFC and foci were not increased in cultures of spleen cells from competent mice until 1 day later. The addition of combinations of these agents to cultures of spleen cells had no positive or negative effect on the generation of foci or PFC. Normal mice given heparin intraperitoneally with SRBC had increased splenic PFC on Days 3 and 4 but not on Day 7. The results suggest that these agents modulate B-cell responses by increasing the rate of proliferation and/or secretion through a signaling pathway(s) distal to, or more likely, independent of Bruton's tyrosine Kinase (BTK). It is not clear that the mechanism is the same with each agent.