Thymocyte-stimulating factor from peripheral blood cells.

Human peripheral blood leukocytes (HPBL) produce a thymocyte-stimulating factor (TSF-HPBL) that enhances the phytohemagglutinin (PHA) and concanavalin A (Con A) responsiveness of murine thymocytes. This activity is considerably specific for thymocytes. TSF-HPBL is not mitogenic by itself. Experiments with cell cultures pretreated with carbonyl iron particles showed that phagocytic cells are not involved in the production of mouse and rat TSF but are involved in the production of TSF-HPBL. The dose-response profile to PHA of murine thymocytes cultured in the presence of TSF-containing supernatants is similar to that of mature, immunocompetent spleen cells. TSF-HPBL, however, does not enhance the PHA responsiveness of murine thymocytes at low (<0.25 μg/microwell) concentrations of mitogen. TSF enhances the PHA and Con A responsiveness of the high-density subpopulations of thymocytes isolated on a Ficoll-Hypaque gradient. In general, the enhancing effect of TSF-HPBL on these subpopulations of thymocytes is smaller than that exerted by TSF. While supernatants containing TSF confer to thymocytes the ability to participate in a mixed lymphocyte reaction, this effect is not exerted by supernatants containing TSF-HPBL. A factor enhancing the PHA and Con A responsiveness of murine thymocytes is also produced by murine peripheral blood leukocytes (TSF-MPBL). This factor, similarly to TSF-HPBL, is produced by phagocytic cells and does not confer to murine thymocytes the ability to participate in a mixed lymphocyte reaction. Human T-cell lines do not enhance the PHA or Con A responsiveness of murine thymocytes. TSF-HPBL has a molecular weight of about 30,000 daltons, as measured by Sephadex filtration. Its half-time of inactivation as 56 °C is 162 ± 8 min.     

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.     

Some effects thymocyte-stimulating factor.

Thymocyte-stimulating factor (TSF) produced in supernatants of murine spleen cells stimulated with mitogens or with allogeneic cells confers to thymocytes the ability to respond to concanavalin A (Con A) with the dose-response characteristic of mature, immunocompetent T cells. No enhancement of the responsiveness of bone marrow cells to lipopolysaccharide (LPS) was found. Thymocytes from mice of different strains acquire, after treatment with TSF, a responsiveness to phytohemagglutinin (PHA) and Con A proportional to that shown by spleen or lymph node cells from mice of the same strain. It was also shown that murine thymocytes treated with TSF cause a graft-vs-host reaction when injected into an appropriate hybrid. All these activities are thermolabile and disappear from supernatants at the same rate, thus showing that they are, very probably, due to the same substance. Spleen cells of mice bearing tumors causing splenomegaly (C3HBA and H2712 adenocarcinomas) show a decreased production of TSF if judged on the basis of TSF produced per million spleen cells. Rat spleen cells produce a substance (rat TSF) which stimulates the PHA and Con A responsiveness of murine thymocytes. Rat TSF has a molecular weight similar or identical to that of murine TSF. However, on the basis of the different rates of thermodenaturation, it appears that rat TSF and murine TSF are two different molecules.     

Immunologic disparity in the hypopituitary dwarf mouse.

The Snell-Bagg hypopituitary dwarf mouse has been shown to be deficient in growth hormone, thyroxine, and prolactin. There are reports indicating that in addition to these neuroendocrine abnormalities, development of immune competence is also severely impaired in these animals. However, other studies indicate that the immunologic potential of these mice does not differ from their heterozygous littermate controls. Our data show that dwarf mice weaned at 21 days of age and killed at that time, or 7 days later, have reduced numbers of cells in both the spleen and thymus and the mitogen responsiveness of these cells is impaired. However, if mice weaned on day 21 are analyzed at 32 days of age or the mice are weaned at day 30 and analyzed 7 days later the ability to respond to mitogenic stimulation does not differ from controls. Further experiments show that dwarf mice weaned at 30 days of age have a normal complement of V-beta TCR as evidenced by immunofluorescence analysis as well as a primary antibody response to SRBC equivalent to that observed in normal littermates. Immunofluorescence analysis of CD4 and CD8 expression on thymocytes obtained from dwarf mice shows a distinct pattern dependent on the time of weaning and time of analysis. Initial analysis of thymocytes from dwarf mice weaned and killed at 21 days of age do not differ from controls. However, cells from dwarf mice weaned on day 21 and killed on day 28 are markedly different with a loss of immature CD4+/CD8+ cells and a corresponding increase in CD4+ and CD8+ mature thymocytes. In contrast, the phenotype of thymocytes obtained from dwarf mice weaned at 30 days of age and killed on day 37 did not differ from normal littermates. Collectively these studies indicate that hypopituitary dwarf mice lag behind their heterozygous littermates with respect to development of immunocompetence but normal immune responsiveness does develop by 32 days of age when the mice are weaned on day 21.     

The distribution of terminal deoxynucleotidyl transferase (TdT) among subsets of thymocytes in the rat.

Terminal deoxynucleotidyl transferase (TdT), a unique DNA-polymerizing enzyme,has been shown to be present in a moderately dense subpopulation of rat thymocytes separated on discontinuous Ficoll density gradients. This subpopulation has been characterized by using antigenic and functional markers to identify directly and quantify cortical and medullary thymocytes. The TdT-positive thymocytes are depleted by cortisone administration, lack responsiveness to phytohemagglutinin, concanavalin-A, and histocompatibility alloantigens, bear surface antigens characteristic of cortical thymocytes (bone marrow lymphocyte antigen) and lack surface antigens characteristic of medullary thymocytes (rat-masked thymocyte antigen and histocompatibility antigens). The results indicate that TdT is present exclusively (or in markedly higher concentrations) in a subset of cells which comprised about 65% of cortical thymocytes. Two other major subsets of cortical thymocytes were identified which appeared to be TdT-negative. A minor subset of very low density cortical thymocytes was also defined. These observations have provided insight into the possible pathways of thymocyte ontogeny.     

Neonatal infection with mouse thymic virus. Differential effects on T cells mediating the graft-versus-host reaction.

Neonatal infection with mouse thymic virus (TA), a murine herpes virus, produced extensive but temporary necrosis of the thymus which was maximal at 10 to 14 days of age. Studies of precursor and amplifier cells mediating graft-vs-host (GVH) reactivity of thymocytes, spleen cells (SC), and lymph node cells (LNC) of normal and TA-infected mice were made at 4 and 8 weeks of age. Infection with TA resulting in a profound reduction (70 to 80%) in the direct GVH reactivity of thymocytes at both ages; by comparison, the capacity of thymocytes to produce synergy when combined with normal LNC was normal at 8 weeks. Direct GVH reactivity of SC was depressed 90% 4 weeks after infection with TA but returned to near normal at 8 weeks. Direct GVH reactivity of LNC from TA-infected mice was normal at 4 and 8 weeks of age, but amplifier T cell activity in LNC was markedly depressed at 8 wekks. These results demonstrate that TA has highly selective effects upon subpopulations of T cells in thymus and lymph node.     

The effect of rabbit anti-mouse brain-associated theta serum on the immunologic responsiveness of AKR mice

Rabbit anti-C3H mouse brain-associated antiserum (BA-θ) was tested for its effect on the immunologic responsiveness of preleukemic and leukemic AKR mice to sheep erythrocytes. This BA-θ antiserum was cytotoxic in vitro for both C3H and for AKR thymocytes, and was immunosuppressive in vivo. Greater immunosuppression was effected by the antiserum in preleukemic AKR mice than in leukemic animals. Control rabbit serum also was cytotoxic in vitro and immunosuppressive in vivo, but this activity was removed by absorption with homologous erythrocytes and liver tissue, and with agarose. Conversely, absorption of the rabbit anti-BA-θ serum had no effect on either the in vitro cytotoxic activity, or on the in vivo immunosuppression.     

Immunologic mechanisms in the pathogenesis of virus-induced leukemia. IV. Mechanism of target cell recognition by autoreactive thymocytes

Neonatal infection of mice with Moloney murine leukemia virus (MuLV-M) results in the establishment of a chronic virus-carrier state. Such MuLV-carrier mice exhibit several immunologic abnormalities including generalized immunosuppression and autoimmunity. Previously, we found thymocytes from MuLV-M-carrier mice to be cytotoxic for normal syngeneic and allogeneic fibroblasts but not for xenogeneic (hamster) target cells. However, when the same syngeneic or allogeneic target cells were infected with MuLV-M, they were "spared" from the autoreactivity, leading us to speculate that the MuLV receptor on the target cell membrane was involved in the autoreactivity. To address this question, we tested MuLV-carrier thymocytes for their ability to lyse hamster/mouse-hybrid target cells; some of which possessed chromosome 5 (which codes for the ecotropic MuLV receptor). Of the nine hybrid cell lines initially tested, only the five clones that carried chromosome 5 were killed by the autoreactive thymocytes. In additional experiments, we noted that the cytotoxic reaction was inhibited in the presence of a monoclonal antibody that reacts with an MuLV-M gp70 epitope. The results suggest that the autoreactive cytotoxicity is mediated, at least in part, through the formation of a "bridge" between MuLV budding from the membrane of the thymocytes and the ecotropic MuLV receptor on the target cells.     

CD4-CD8- thymocytes from MRL-lpr/lpr mice exhibit abnormal proportions of alpha beta- and gamma delta-TCR+ cells and demonstrate defective responsiveness when activated through the TCR.

MRL-lpr/lpr (lpr) mice develop profound lymphadenopathy resulting from the accumulation of CD4-CD8- (double-negative, DN) cells in the peripheral lymphoid organs. Earlier studies from our laboratory demonstrated an increased proportion of DN cells in the thymus of lpr mice with age. Inasmuch as the DN thymocytes constitute a heterogenous population of cells, in the present study, we investigated the TCR phenotype of DN thymocytes and their responsiveness to activation through the TCR. The DN thymocytes of young (1 month of age) lpr mice contained approximately 65% CD3+ cells of which approximately 60% were alpha beta-TCR+ and approximately 39% were gamma delta-TCR+ as detected by using pan anti-TCR mAbs. In old (4-6 months of age) or young MRL-(+/+) mice, similar proportions of CD3+, alpha beta- or gamma delta-TCR+ DN thymocytes were detected. Interestingly, however, in old (4-6 months of age) lpr mice, the CD3+ T cells increased to approximately 86% and the majority of these (approximately 81%) were alpha beta-TCR+ and only approximately 3% were gamma delta-TCR+. Also, in old lpr mice, there was a 10-fold increase in the absolute number of alpha beta-TCR+ DN cells in the thymus, whereas, the absolute number of gamma delta-TCR+ DN cells in the thymus did not alter significantly. Furthermore, a majority (approximately 84%) of the old lpr DN thymocytes expressed CD45R, similar to the peripheral DN T cells. In contrast, only a small number (approximately 1%) of DN thymocytes from young lpr or MRL-(+/+) mice expressed CD45R. The DN thymocytes from young lpr or MRL-(+/+) mice demonstrated strong and similar proliferative responsiveness to stimulation with PMA + calcium ionophore or PMA + IL-2, or to immobilized mAb directed against the TCRs (CD3, alpha beta and gamma delta). In contrast, the DN thymocytes and the DN peripheral T cells from old lpr mice demonstrated marked defect in responding to the above stimuli. The present study suggests that with the onset of lymphadenopathy, the DN cells in the thymus of old lpr mice are increasingly skewed toward the alpha beta-TCR repertoire, the majority of which express CD45R and respond poorly to mitogenic stimuli or when activated through the TCR. It is suggested that migration of such cells continuously to the periphery may result in severe lymphadenopathy seen in old MRL-lpr/lpr mice.     

VSIG4(+) peritoneal macrophages induce apoptosis of double-positive thymocyte via the secretion of TNF-α in a CLP-induced sepsis model resulting in thymic atrophy

Thymic atrophy in sepsis is a critical disadvantage because it induces immunosuppression and increases the mortality rate as the disease progresses. However, the exact mechanism of thymic atrophy has not been fully elucidated. In this study, we discovered a novel role for VSIG4-positive peritoneal macrophages (V4(+) cells) as the principal cells that induce thymic atrophy and thymocyte apoptosis. In CLP-induced mice, V4(+) cells were activated after ingestion of invading microbes, and the majority of these cells migrated into the thymus. Furthermore, these cells underwent a phenotypic shift from V4(+) to V4(−) and from MHC II(low) to MHC II(+). In coculture with thymocytes, V4(+) cells mainly induced apoptosis in DP thymocytes via the secretion of TNF-α. However, there was little effect on CD4 or CD8 SP and DN thymocytes. V4(−) cells showed low levels of activity compared to V4(+) cells. Thymic atrophy in CLP-induced V4(KO) mice was much less severe than that in CLP-induced wild-type mice. In addition, V4(KO) peritoneal macrophages also showed similar activity to V4(−) cells. Taken together, the current study demonstrates that V4(+) cells play important roles in inducing immunosuppression via thymic atrophy in the context of severe infection. These data also suggest that controlling the function of V4(+) cells may play a crucial role in the development of new therapies to prevent thymocyte apoptosis in sepsis.Subject terms: Imaging the immune system, Bacterial infection     

The critical role of LIGHT, a TNF family member, in T cell development.

Negative selection refers to the selective deletion of autoreactive thymocytes but its molecular events have not been well defined. In this study, we demonstrate that a cellular ligand for herpes virus entry mediator and lymphotoxin receptor (LIGHT), a newly identified member of the TNF superfamily, may play a critical role in negative selection. Using TCR transgenic mice, we find that the blockade of LIGHT signaling in vitro and in vivo prevents negative selection induced by peptide and intrathymically expressed Ags, resulting in the rescue of thymocytes from apoptosis. Furthermore, the thymi of LIGHT transgenic mice show severe atrophy with remarkably reduced CD4(+)CD8(+) double-positive cells caused by increased apoptosis, suggesting that LIGHT can delete immature T cells in vivo. Taken together, these results demonstrate a critical role of LIGHT in thymic negative selection of the T cell repertoire.     

Priming of immature thymocytes to CD3-mediated apoptosis by infection with murine cytomegalovirus.

Cytomegalovirus (CMV) causes severe clinical manifestations in immunocompromised hosts; however, it remains unclear whether the virus itself is a cause of immunosuppression or whether it is involved as an opportunistic bystander pathogen. This study was performed to elucidate the effect of CMV infection on the host's immune system. The double-positive thymocytes of BALB/c mice inoculated with a sublethal dose of murine CMV (MCMV) were extensively depleted by a 10-micrograms amount of anti-CD3 monoclonal antibody, while such an amount was unable to induce any apparent elimination of thymocytes in noninfected mice. In immature thymocytes of infected hosts, a markedly high level of susceptibility to apoptosis induction was found on treatment with anti-CD3 monoclonal antibody. Analysis of the signal transduction pathway of such double-positive thymocytes demonstrated a profound elevation of the intracellular Ca2+ level after anti-CD3 stimulation, implying that this aberrant mobilization of Ca2+ plays a crucial role in the signaling pathway leading these cells to an extensive apoptosis. Examination of the thymus by PCR was able to detect a low copy number of MCMV DNAs in thymic stromal cells but none at all in thymocytes. Therefore, it is suggested that a mechanism which is not associated with virus replication within the cells exerts a critical effect on rendering the thymocytes highly apoptosis sensitive in hosts infected with MCMV.     

The role of the thymus in maturational development of phytohemagglutinin and pokeweed mitogen responsiveness

A sensitive culture system for measuring lymphocyte transformation under physiological conditions by thymidine incorporation into DNA has been developed to study mouse and chick cell responses to mitogens. Both phytohemagglutinin (PHA) and pokeweed mitogen (PWM) stimulated thymus and spleen lymphocytes. Reduced but definite responses were obtained with lymph nodes, but negligible response with bone marrow cells.Thymocytes of newborn mice did not respond to PHA, but responded well to PWM. PHA responsiveness of thymocytes increased with aging until 12 weeks of postnatal life and then decreased in older animals. The level of background thymidine incorporation increased with advancing age. Spleen cells of 2-week-old mice were transformed by PHA and PWM, but in contrast to mouse thymus there was no decrease in older animals.Neonatal thymectomy of mice reduced the response of spleen cells to both PHA and PWM, especially in younger animals. The reduction was almost complete in the case of the PHA response, but only partial with the PWM response. Spleen cells from bursectomised chickens, checked for absence of B cell function, still responded well to both PWM and PHA.The results suggest PHA is a marker for T-lymphocytes in a certain “mature” stage of differentiation. PWM appears to stimulate a wider spectrum of cells.     

CD30 overexpression enhances negative selection in the thymus and mediates programmed cell death via a Bcl-2-sensitive pathway.

The biological function of CD30 in the thymus has been only partially elucidated, although recent data indicate that it may be involved in negative selection. Because CD30 is expressed only by a small subpopulation of medullary thymocytes, we generated transgenic (Tg) mice overexpressing CD30 in T lymphocytes to further address its role in T cell development. CD30 Tg mice have normal thymic size with a normal number and subset distribution of thymocytes. In vitro, in the absence of CD30 ligation, thymocytes of CD30 Tg mice have normal survival and responses to apoptotic stimuli such as radiation, dexamethasone, and Fas. However, in contrast to controls, CD30 Tg thymocytes are induced to undergo programmed cell death (PCD) upon cross-linking of CD30, and the simultaneous engagement of TCR and CD30 results in a synergistic increase in thymic PCD. CD30-mediated PCD requires caspase 1 and caspase 3, is not associated with the activation of NF-kappaB or c-Jun, but is totally prevented by Bcl-2. Furthermore, CD30 overexpression enhances the deletion of CD4+/CD8+ thymocytes induced by staphylococcal enterotoxin B superantigen and specific peptide. These findings suggest that CD30 may act as a costimulatory molecule in thymic negative selection.     

Lymphocyte function in experimental African trypanosomiasis. III. Loss of lymph node cell responsiveness

The relationship between immunosuppression and suppressor cell activity in the lymphoid organs of animals with experimental African trypanosomiasis has been examined further. In the present study we measure the primary in vitro PFC response to SRBC by spleen and lymph node cells from Trypanosoma rhodesiense infected or drug-cured C57BL/6 mice. Passive transfer experiments with this culture system tested for the presence or absence of suppressor cells. We demonstrate that infected mice exhibit immunosuppression in the spleen cell population several weeks before becoming suppressed at the level of the lymph node cell populations. Although suppressor cells are present in immunosuppressed spleen cell populations, suppression of lymph node cell responsiveness was not attributable to suppressor cells detectable withi, lymph nodes. After Berenil treatment of terminally infected mice immunocompetence was restored gradually, first to the lymph node cells and subsequently to the spleen cell population. Recovery of spleen cell responsiveness was attributable to the loss of detectable suppressor cell activity within spleens. These results demonstrate that there is anatomical restriction of the suppressor cell population to trypanosome-infected mouse spleen and that loss of immunocompetence in the lymph nodes may be due to factors unrelated to suppressor cell effects.     

B-cell suppression of antibody response to sheep red blood cells in mice of high- and low-responding genotypes.

CBA and C57B1 mice (high and low responders to sheep red blood cells, respectively) were injected intravenously with syngeneic lymph node, marrow, spleen, or thymus cells together with sheep red blood cells (SRBC), and the production of antibody-forming cells (AFC) was assayed in the spleen. Transfer of lymph node, marrow, spleen, or thymus cells led to a significant enhancement of immune responsiveness in low-responding C57B1 mice. In contrast, transfer of marrow, lymph node, or spleen cells to high-responding CBA mice was accompanied by a decline in AFC production. These effects were magnified if syngeneic cell donors had been primed with SRBC; suppression in CBA mice and stimulation in C57B1 mice were especially pronounced after transfer of SRBC-primed lymphoid cells. Pretreatment of CBA donors with cyclophosphamide in a dose causing selective B-cell depletion completely abrogated the suppression of immune responsiveness. A large dose (10⁷) of syngeneic B cells injected together with SRBC suppressed the accumulation of AFC in both CBA and C57B1 mice. No suppression of immune responsiveness was observed after transfer of intact thymus cells, hydrocortisone-resistant thymocytes, or activated T cells. We conclude that suppression of the immune response to SRBC is induced by B cells. At the same time, there is a possibility that the addition of “excess” B cells acts as a signal, triggering suppressor T cells.     

Studies of the relationship between adenosine deaminase and immune function.

The relationship between adenosine deaminase deficiency and immunologic responsiveness was studied in mice treated in vivo with deoxycoformycin to produce very low levels of adenosine deaminase activity in tissues. Effects of such treatment on thymocyte response to concanavalin A in vitro and on mixed cultures of splenic cells were determined. Under the conditions used, inhibition of adenosine deaminase by deoxycoformycin had no effect on the viability or responsiveness of either thymocytes or splenic cells.     

Sera from both normal and thymectomized animals produce elevations of cyclic AMP in thymocytes.

Cyclic AMP content in mouse thymocytes has been measured after incubation either with sera or serum fractions from normal or thymectomized (Tx) mice and pigs or with a synthetic circulating pig thymic factor. Sera from both Tx and normal pigs and mice induced an increase in cyclic AMP in mouse thymocytes, whereas the synthetic pig thymic factor did not. It is concluded that the increase in cyclic AMP in mouse thymocytes should be used with caution for the evaluation of circulating thymic hormone levels.     

Images of mitochondrial UCP 1 in mouse thymocytes using confocal microscopy

The aim of this study was to demonstrate the constitutive expression of mitochondrial uncoupling protein 1 (UCP 1) in pure thymocytes using laser scanning confocal microscopic imagery. To that end we probed thymocytes from UCP 1 knock-out and wild-type mice. Mitochondrial location in thymocytes was determined using Mitotracker Red and the nucleus was labelled using Hoescht stain. We demonstrate that all cells investigated were thymocytes as determined by a monoclonal antibody specific for the thymocyte surface marker Thy 1 (CD90) pre-coupled to a fluorescent labelled (Alexa 448, green). Using a primary peptide antibody specific to UCP 1, and secondary fluorescently labelled (Alexa 647, magenta) antibody, we were able to demonstrate that UCP 1 is associated with mitochondria in thymocytes from UCP 1 wild-type mice but not thymocytes from UCP1-knock-out mice. These are the first images demonstrating the presence of UCP 1 in thymocyte mitochondria, in situ, and the first to clearly demonstrate UCP 1 expression in cells other than brown adipocytes. We conclude that mouse thymocytes contain UCP 1 in their mitochondria.     

Suppression of antibody responses in allogeneic mice by products of lymphoid tissue. I. Allogeneic suppressive factor (ASF) from spleens repopulated with thymus cells.

A cellfree extract prepared from the spleen cells of C3H mice is capable of suppressing antibody responses to SRBC when extract material is exposed to alloantigens. The observed immunosuppression was attributed to a soluble factor in the extract. This allogeneic suppressive factor (ASF) was detected in extracts prepared from the spleen cells of unirradiated mice as well as those of irradiated mice repopulated with thymocytes, provided that mice were previously immunized with SRBC. Donors of actively suppressive ASF preparations did not need to be previously exposed to alloantigens. Extracts from thymus and marrow cells of unirradiated mice and the spleen cells of irradiated mice repopulated with marrow cells (or no cells) did not contain ASF. C3H thymocytes stimulated with SRBC generated more ASF activity in spleens of C3BF1 hosts than in those of C3H hosts, indicating that alloantigenic stimulation enhances the production or activity of ASF. Once produced, C3H ASF was able to suppress antibody responses in cell transfer experiments only if exposed to C3BF alloantigens of either donor lymphoid cells or irradiated hosts. Once exposed to alloantigens, ASF appears to be capable of suppressing antibody responses of syngeneic C3H or semi-allogeneic C3BF cells. When both donor lymphoid cells and hosts were syngeneic with the donor of the ASF, there was enhancement of antibody formation in cell transfer experiments. C3H ASF did not interfere with education of C3BF thymocytes to SRBC or with the generation of precursors of anti-SRBC antibody-forming cells by C3BF1 marrow cells. ASF may interfere with cellular cooperative events necessary for humoral immune responses or with terminal differentiation of B cells. Production of ASF could partially account for the suppression of antibody responses observed during graft-vs-host reactions.