Immune response to the p-azobenzenearsonate (ABA)-GAT conjugate. II. Hapten-specific T cells induced with ABA-GAT in GAT responder X nonresponder F1 hybrids are restricted to the nonresponder haplotype

Immunization of mice with the ABA-GAT conjugate stimulates GAT-specific T helper cells in GAT-responder animals and ABA-specific helpers in nonresponders. Unexpectedly, immunization of (responder X nonresponder) F1 mice, which have the GAT-responder phenotype, leads to the recruitment of both ABA- and GAT-specific clones of T helper lymphocytes. The GAT-reactive population is restricted to the haplotype of the responder parent (Iak), whereas ABA-specific T cells are mostly restricted to the nonresponder one (Ias). This is demonstrated by the ability of monoclonal antibodies to parental la antigens to inhibit T cell proliferation to GAT or ABA-Tyr in vitro. Consistently, ABA-GAT-primed F1 T cells can only activate nonresponder B cells to proliferate in the presence of ABA-Tyr and responder B lymphocytes in the presence of GAT. Furthermore, F1 T cells seem to recognize both ABA and GAT epitopes only in association with molecules encoded by the I-A subregion. Analysis of ABA-specific F1 T cell lines generated by in vitro stimulation with ABA-Tyr or ABA-GAT demonstrates a competition between GAT- and ABA-specific T cells present in the hybrid T cell repertoire and restricted to the same parental I-Ak molecule. The results indicate that F1 macrophages can present both ABA and GAT epitopes to T cells in association with the two parental and hybrid Ia determinants. It seems unlikely that the absence of GAT-specific T cells restricted to the nonresponder I-A in the F1 is due to suppressor T cells. Thus, the competition model that we propose, to explain the selective F1 T cell response to ABA-GAT, leads us to believe that GAT nonresponder animals may lack clones capable of recognizing, with a high affinity, I-As + GAT.     

Induction of T15-specific suppressor T cells in mice with the CBA/N defect by neonatal injection with anti-T15 idiotype antibody

Mice with the CBA/N defect (xid) are unresponsive to phosphorylcholine (PC), To determine whether idiotype-specific suppressor T cells can also be generated in these defective mice, defective (CBA/N X BALB/c)F1 male and nondefective (CBA/N X BALB/c)F1 female or (BALB/c X CBA/N)F1 male mice were neonatally injected with antibodies specific for the major idiotype of anti-PC antibody, i.e., anti-TEPC-15 idiotype (T15id) antibody. Suppressor cell activity was examined by co-culturing spleen cells from neonatally treated F1 mice with spleen cells of normal nondefective F1 mice in the presence of antigen. Spleen cells from defective (CBA/NM X BALB/c)F1 mice treated with anti-T15id antibody demonstrated a level of suppressor activity (greater than 83% suppression) comparable to that of similarly treated nondefective F1 mice. This suppression was specific for the T15id of anti-PC response, and a Lyt-1-2+-bearing T cell population appeared to be responsible for the active suppression. These suppressor T cells recognized T15 but not PC, based on a functional absorption test. These results indicate that the CBA/N defects, including the deficiency in the anti-PC response by B lymphocytes and a possible T cell defect, do not influence the generation of T15id-specific suppressor T cells by neonatal injection with anti-T15id antibody.     

Effect of volatile excretions induced with thymus-dependent antigen in female mice on the behavioural responses of males

It was found that thymus-dependent antigen sheep red blood cells in the optimal immunogenic dose (1 x 10(8) cells/mouse) induced in female mice of CBA and B6 strain secretion of attractive urinary volatile components (VCs), and in the supraoptimal dose (1 x 10(9) cells/mouse)--aversive VCs for intact males CBA strain. In a direct comparison of the properties ofVCs-immunized mice of CBA and B6, a modification of the effect of constitutive chemosignalling: disturbance of ability of females VCs to attract allogeneic males, was observed. The role of thymus-dependent antigen dose and sex of animals in the mechanism of generation of antigen-induced chemosignals is discussed.     

A possible maternal effect in the abnormal hyporesponsiveness to specific alloantigens in offspring born to neonatally tolerant fathers

Newborn CBA mice were inoculated i.p. with 1 X 10(8) adult (CBA X A)F1 lymphoid cells with 5 X 10(7) F1 hybrid lymphoid cells thereafter inoculated i.v. at 14-day intervals. The mice were subsequently grafted with A/J tail skin at 24 days of age. At 8 wk of age, individual tolerant males with intact skin grafts were each mated with similar tolerant skin-grafted females or with 8-wk-old control normal CBA females. Approximately 0.4 ml of peripheral blood from 7-wk-old progeny born to these crosses, along with the blood from age-matched progeny born to normal CBA incrosses, were used for in vitro mixed leukocyte cultures (MLC). All progeny received skin grafts of (CBA X A)F1 tail skin at 7 1/2 wk of age. In this study, we show i) that MLC hyporesponsiveness to histocompatible cells is an acquired phenotype expressed by lymphoid cells of the progeny of tolerant male mice, and ii) that these progeny also show delayed rejection of (CBA X A)F1 skin grafts. The continued breeding of the first generation animals established that a similar transmission of hyporesponsiveness can be observed in the second generation progeny. When putatively normal females, however, which had borne several litters after mating with neonatally tolerant males, were mated with "normal" (nontolerant) males; their offspring also exhibited a specific hyporesponsiveness in MLC to the initial tolerizing allodeterminants. This suggests that there may ultimately be a maternally derived origin for the transmission of characters from tolerant males.     

Evidence for Generation of Suppressor T Cells in Mycobacterium lepraemurium-Infected CBA/J Mice,a Mouse Strain Highly Susceptible to the Infection

Susceptibility to Mycobacterium lepraemurium (MLM) infection markedly differed between two mouse strains, CBA/J and C57BL/6. CBA/J mice showed high susceptibility to MLM infection and developed either very weak or no delayed-type hypersensitivity (DTH) to MLM antigen after the injection of MLM. In contrast, C57BL/6 mice, which were resistant to MLM infection, showed significant DTH reaction to MLM antigen after the injection. Treatment of CBA/J mice with cyclophosphamide (Cy) conferred significant resistance to MLM infection on the CBA/J mice, and the treated mice developed a strong anti-MLM DTH response after the MLM injection. When spleen cells from MLM-infected CBA/J mice were transferred to Cy-treated and MLM-infected syngeneic mice, the anti-MLM DTH reaction of the recipient mice was suppressed. Treatment of the spleen cells to be transferred with anti-Thy-1.2 antibody or anti-I-J^k antiserum plus complement abrogated the suppressive activity. Thus, it is suggested that the high susceptibility of CBA/J mice to MLM infection is due to the generation of Cy-sensitive, I-J^k-positive suppressor T cells after infection with MLM.     

Biophysical characterization of peyer’s patch lymphocytes in the B-cell deficient CBA/N mice and in their F1 hybrids

CBA/N mice bear an X-linked immunodeficiency involving abnormalities of their B lymphocytes. We investigated the electrophoretic mobility (EPM) distribution and the electronic volume of the Peyer's patch (PP) cells of these mice in comparison with those of the immunologically normal CBA/J mice. The same studies were also carried out on PP cells from the CBA/N×DBA/2 (CND2) F1 hybrid males and females that are, respectively, B-cell defective and normal. In all types of mice, PP cells could be separated by free-flow electrophoresis into a low-mobility (LM) population corresponding mainly to B cells and high-mobility (HM) population containing mostly T cells. However, while in the control mice LM (B) cells accounted for around 60–67% of PP lymphocytes, this population did not exceed 40% in the defective animals. Furthermore, LM (B) cells, but not HM (T) cells, of CBA/N and CND2 male mice were found to display abnormal physical characteristics. Thus, they possessed a higher anodic EPM (two electrophoretic fractions faster) and a slightly larger model size (134 μm³) than normal adult B cells (122–124 μm³). Similar differences were observed with PP lymphocyte preparations enriched for B cells by nylon wool adherence. These data suggest that CBA/N mice and their defective hybrids lack a population of small B lymphocytes with low anodic EPM.     

Role of antigen-specific T cell help in the generation of in vivo antibody responses. I. Antigen-specific T cell help is required to generate a polyclonal IgG1 response in anti-IgD antibody-injected mice.

A system in which injection of mice with an antibody to mouse IgD that they recognize as foreign stimulates a large, T cell-dependent IgG response was used to study whether Ag-specific T cell help is required to stimulate polyclonal (non-Ag-specific) IgG production in vivo. Igha x Ighb allotype heterozygous mice were injected with a conjugate of a foreign Ag coupled to a mAb specific for one of the two IgD allotypes expressed in these mice. This conjugate cross-links mIgD on B cells that express the recognized allotype. These cells process the conjugate and present the foreign Ag to Ag-specific T lymphocytes, which become activated. Thus, B cells of the recognized allotype can be stimulated by cross-linking of their mIgD, Ag-specific T cell help, non-Ag-specific cytokines, and non-Ag-specific contact with activated T cells. In contrast, B cells that express the Igh allotype not recognized by the Ag-anti-IgD antibody conjugate (bystander B cells) can be stimulated in this system only by non-Ag-specific cytokines and non-Ag-specific contact with activated T cells. Although both recognized and bystander B cells in conjugate-injected mice demonstrated substantial increases in size and Ia expression, only the recognized B cells were induced to synthesize DNA and to make a substantial polyclonal Ig response. Bystander B cells still failed to secrete IgG when mice were injected with an anti-IgD-Ag conjugate specific for the other Igh allotype as well as a mAb that cross-linked IgD of the bystander B cell allotype. These observations demonstrate that although non-Ag-specific cytokine and contact-mediated T cell help are sufficient to induce B cells to increase in size and Ia expression in anti-IgD antibody-injected mice, Ag-specific T cell help is required to stimulate the generation of an IgG response in these mice.     

TCR V beta 8+ T cells prevent development of toxoplasmic encephalitis in BALB/c mice genetically resistant to the disease

BALB/c are genetically resistant to development of toxoplasmic encephalitis (TE) when infected with Toxoplasma gondii, whereas CBA/Ca mice are susceptible. We compared TCR Vbeta chain usage in lymphocytes infiltrated into brains between these animals following infection. TCR Vbeta8(+) cells were the most frequent T cell population in brains of infected, resistant BALB/c mice, whereas TCR Vbeta6(+) T cells were more prevalent than Vbeta8(+) T cells in brains of infected, susceptible CBA/Ca mice. Adoptive transfer of Vbeta8(+) immune T cells, obtained from infected BALB/c mice, prevented development of TE and mortality in infected athymic nude mice that lack T cells. In contrast, adoptive transfer of Vbeta6(+) immune T cells did not prevent development of TE or mortality in the nude mice. The protective activity of Vbeta8(+) immune T cells was greater than that of the total Vbeta8(-) population. In addition, Vbeta8(+) immune T cells produced markedly greater amounts of IFN-gamma than did the Vbeta8(-) population after stimulation with tachyzoite lysate Ags in vitro. Thus, Vbeta8(+) T cells appear to play a crucial role in the genetic resistance of BALB/c mice against development of TE.     

Delayed clearance of filarial infection and enhanced Th1 immunity due to modulation of macrophage APC functions in xid mice.

Bruton's tyrosine kinase (Btk) mutant CBA/N mice show delayed clearance of injected microfilaria (mf) compared with wild-type CBA/J mice. Anti-mf T cells from CBA/N mice make relatively more IFN-gamma than those from CBA/J mice. The anti-mf T cell proliferative responses are also greater in CBA/N mice. This CBA/N immune phenotype is not restricted to filarial Ags, because immunization with pure proteins also yields T cell responses of greater proliferative magnitude skewed away from Th2 cytokines in CBA/N compared with CBA/J mice. The increased magnitude of CBA/N T cell proliferative responses is reflected in increases in both precursor frequencies and clonal burst sizes of responding Ag-specific T cells, and is independent of the source of re-stimulating APCs. Transfer of CBA/J peritoneal resident cells (PRCs) into CBA/N mice before pure protein immunization leads to a wild-type immune phenotype in the recipient CBA/N mice, with a reduction in the proliferative response and a relative decrease in the IFN-gamma produced. When wild-type PRC subpopulations are similarly transferred, the wild-type immune phenotype is transferred by macrophages rather than by B cells. Transfer of wild-type PRCs into CBA/N mice before injection of mf also causes similar changes in the anti-mf T cell responses and enhances the clearance of mf. Thus, Btk is involved in critical macrophage APC functions regulating priming of T cells, and can modulate these responses in pathophysiologically relevant fashion in vivo.     

Generation of low-dose paralysis in the absence of the ability to secrete antibody.

(CBA/N female x BALB/c male)F1 male mice carry an X-linked defect, originating from CBA/N mice, which renders them unable to generate an antibody response to SSS-III. Histocompatible (BALB/c female x CBA/N male) reciprocal F1 male hybrids do not carry the X-linked defect and therefore generate a readily detectable PFC response to SSS-III, which can be adoptively transferred into nonresponding reciprocal F1 male mice. In the present work, we show that this adoptive response could be inhibited in recipient (CBA/N female x BALB/c male)F1 male nonresponding mice in which low dose paralysis had been induced. Evidence is presented which indicates that such suppression is of host rather than donor cell origin. The capacity to develop low-dose paralysis, a phenomenon that is antigen specific and has been attributed to the action of suppressor T cells, indicates that nonresponding (CBA/N female x BALB/c male) F1 males (and presumably the CBA/N progenitor strain) have the ability to recognize this antigen. Furthermore, since these animals fail to make a serum antibody response to SSS-III, the signal that activates suppressor T cells cannot be circulating antibody or antigen-antibody complexes. These findings are most consistent with the view that low-dose paralysis of the response to SSS-III is not dependent on antibody-mediated feedback inhibition; rather, it is an active process mediated by suppressor T cells.     

Splenic and inguinal lymph node T cells of aged mice respond differently to polyclonal and antigen-specific stimuli.

Numerous changes have been reported to occur in T cell responsiveness of mice with increasing age. However, most of these studies have examined polyclonal stimulation of spleen cells from a limited number of mouse strains. This study investigated the influence of genetic background, source of lymphocytes, and type of stimulus on age-associated changes in T cells response. Con A-induced proliferation and IL-2 and IFN-gamma production by splenic lymphocytes (SL) was significantly greater in CBA/Ca mice compared to C57BL/6 mice, regardless of age. SL of both strains exhibited the predicted age-dependent decline in proliferative response and an increase in IFN-gamma production in response to Con A. In contrast, however, only SL from C57BL/6 mice demonstrated the predicted age-dependent decline in Con A-induced IL-2 production; Con A-induced SL of young and aged CBA/Ca mice produced comparable amounts of IL-2. Differences in age-associated responses to Con A were also observed between SL and inguinal lymph node (ILN) cells of CBA/Ca mice. In contrast to SL, ILN cells demonstrated an increased proliferative response to Con A. However, lymphokine production by Con A-stimulated ILN cells from aged CBA/Ca mice was similar to that of Con A-stimulated SL from aged CBA/Ca mice. To determine if aged ILN T cells respond similarly to polyclonal and antigen-specific stimuli, keyhole limpet hemocyanin (KLH) responses of T cells isolated from ILN of aged and young CBA/Ca mice were examined. KLH-specific T cells from aged mice cultured with KLH-pulsed macrophages (M phi) from aged mice were significantly reduced in their ability to proliferate compared to KLH-specific T cells of young mice cultured with young KLH-pulsed M phi. In contrast to the expected results, the defect was not at the level of the T cells; proliferation of young T cells cultured with aged KLH-pulsed M phi was equivalent to the proliferation of aged T cells cultured with aged M phi. These results suggest that aging has differential effects on polyclonal and antigen-specific T cell proliferation and on polyclonal stimulation of T cells isolated from different lymphoid organs and from different strains of mice.     

Cellular subsets involved in cell-mediated immunity to murine Plasmodium yoelii 17X malaria

Cell mediated immunity to nonlethal Plasmodium yoelli 17X (PY17X-NL) was examined in the CBA/CaJ mouse by adoptive transfer of sensitized T lymphocyte subsets. In intact mice, PY17X-NL causes a self-limiting infection with parasitemia levels ranging from 10 to 25% of total red blood cells. Upon recovery, mice are refractory to subsequent challenge with the homologous parasite. In T cell-depleted mice, PY17X-NL infections are extremely virulent and result in death of the host after parasitemia levels reach 50% or higher. The transfer of either Lyt-1 T cells or Lyt-2 T cells from immune animals into normal, naive animals produced accelerated recovery to subsequent infection. However, this adoptive transfer of immunity by either subset was dependent upon the presence of an I-J+, Lyt-null cell in the immune population. T cell deprivation precluded the ability of animals to control blood-stage infections. When T cell-depleted mice were reconstituted with naive, Ig-negative (T cell-enriched) spleen cells, parasitemia levels were controlled and the parasites were eliminated. When T cell-deprived animals were reconstituted with naive Lyt-1+2-, Ig-negative spleen cells, they experienced twofold higher parasitemias of longer duration than mice receiving unfractionated cells. Two of six of these Lyt-1 mice died of fulminant infections, suggesting that the presence of naive Lyt-2 cells enhances the degree of protection. Immune Lyt-2 T cells were highly protective in T cell-depleted animals. Protection by sensitized Lyt-1 T cells correlated with the induction of a monocytosis. On the other hand, protection by Lyt-2T cells occurred in the absence of monocytosis. The possibility that the immunity induced by each T cell subset is mediated by a different effector mechanism is discussed.     

Cellular immune responses in mice infected with the intestinal nematode Trichuris muris.

CBA and B10.BR mice show variation in immune response to the intestinal nematode Trichuris muris. CBA mice develop strong resistance, eliminating worms from the intestine; B10BR mice are permissive and develop chronic infections. It is already known that resistance and permissiveness reflect differential T helper responses. The data reported here show that resistant CBA mice express good antigen-specific lymphocyte proliferative responses to infection, whereas cells from B10.BR mice are relatively anergic, although still responsive to Concanavalin A (ConA). The possibility that the altered proliferative responsiveness seen in infected B10.BR mice reflected quantitative or qualitative changes in T helper cells was examined by comparing cytokine production and expression of cell surface markers (CD4, CD8, and CD28) in mesenteric lymph node cells and spleen cells from both strains and comparing these with the characteristics of cells from resistant CBA mice and from CBA mice that had been rendered permissive to infection by a combination of irradiation and corticosteroid treatment. As expected, cells from B10.BR mice produced high levels of interferon-gamma (IFN-gamma), whereas those from CBA mice released high levels of IL-5, whether stimulated with adult worm somatic antigens, excretory/secretory antigens, or ConA. Immunosuppressed CBA mice produced high levels of both IFN-gamma and IL-5 throughout the experiment. FACS analysis revealed a decrease of CD4+ and an initial increase in CD8+ cells in all infected mice. No major changes occurred in the relative proportion of CD28(+) cells. Further evaluation of the CD28 costimulatory molecule, measured as mean fluorescence intensity, displayed down-regulation in permissive and immunosuppressed mice. The data obtained suggest that lymphocyte unresponsiveness and permissiveness to T. muris infection may be associated with a down-regulation or an initially reduced expression of costimulatory CD28 molecules.     

Synergistic effects of the xid gene in X chromosome congenic mice. I. Inability of C3.CBA/N mice to respond to thymus-dependent antigens in adoptive transfer assays

The xid gene, which causes a B lymphocyte immune defect in CBA/N mice, has been bred onto the C3H/HeN background. The resulting X chromosome congenic mice (C3.CBA/N) exhibit immunologic defects that are much more profound than the defect exhibited by CBA/N mice; thus, the B cells from C3.CBA/N mice not only fail to respond to thymus-independent (TI) type 2 antigens such as TNP-Ficoll, but they fail to respond in vitro to TI-type 1 antigens such as TNP-Brucella abortus (BA) and B cell mitogens such as LPS and Nocardia water-soluble mitogen. In this paper we show that the synergistic defect seen in C3.CBA/N B cells is also elicited in adoptive transfer assays to thymus-dependent (TD) antigens such as TNP-KLH and PC-KLH, antigens to which both parental strains respond. Thus, the secondary adoptive transfer response of C3.CBA/N spleen cells is generally less than 5% of the immune response produced by CBA/N or C3H/HeN spleen cells. This synergistic defect is restricted to the C3.CBA/N B cells, since C3.CBA/N T cells can provide help to CBA/N B cells that is equivalent to the help obtained with CBA/N T cells. The low responsiveness of C3.CBA/N spleen cells to TD antigens, which is elicited in adoptive transfer assays, is not seen when the intact animal is immunized with antigen in CFA; this, intact C3.CBA/N mice produce anti-PC-KLH and anti-TNP-KLH responses only slightly lower than the responses of CBA/N mice to these same antigens. In contrast, when these mice are immunized with phenol-extracted LPS, a TI-type 1 antigen, their antibody responses are severely depressed. These data suggest that under conditions in which T cell help may be limiting or in which the intact physiology of the T and B cells has been disrupted, C3.CBA/N B cells demonstrate profound immunologic impairment; however, when adequate T cell help is available and the splenic architecture is not disrupted, their immune responses appear to progress in a normal fashion.     

Polyclonal activation of xid B cells by auto-Ia-reactive T cell clones

The mechanism of T cell-dependent activation of xid B cells into Ig-producing cells was studied by employing H-2-restricted, antigen-specific T cell clones. Helper factors (B cell stimulatory factors, BSF) released from KLH-specific T cell lines could induce polyclonal Ig production in B cells from (CBA/N X BALB/c)F1 (NBF1) female mice but not from CBA/N or NBF1 male mice. Direct addition of helper T cell lines induced Ig production in xid B cells from CBA/N or NBF1 male mice. A T cell clone, MK6, which was derived from NBF1 male mice and specific against Iad determinant, could activate NBF1 male but not CBA/N B cells. Another clone, CK4, derived from CBA/N mice and having specificity against KLH plus I-Ak determinant could activate both CBA/N and NBF1 male B cells into IgM- and IgG-producing cells in the absence of KLH, and monoclonal anti-I-Ak antibody specifically blocked such activation. These results suggest that xid B cells are able to be activated by the signal provided by the recognition of Ia molecules on B cells by auto-Ia-reactive T cells. Xid B cells from CBA/N mice that had been co-cultured with a T cell line specific against I-Ak determinant for 24 hr became reactive to BSF and capable of differentiating into Ig-producing cells in the presence of BSF. The results showed that even xid B cells could be responsive to BSF if they were in a certain activation stage.     

Model system for study of cell interactions and mechanisms of immune response to T-independent antigens of type 2 in vitro

Cellular mechanisms of immune response to type 2 T-independent antigens (TI-2 antigens) are not fully elucidated up till now. In vitro system is the most convenient model for such studies. However, in vitro model requires relatively high cell density in the cultures. It hampers the study of minor lymphocyte subsets like CD5+ B-1 splenocytes, which play the main role in the immune response to TI-2 antigens. The use of cell mixtures of normal and immunodeficient congenic animals may help to resolve this problem. In this work, immune responses to TI-antigens of type 1 (TI-1 antigens) and to TI-2 antigens in vitro were studied in the mixtures of cells of normal (CBA) and congenic xid-mice (CBA/N). CBA/N mice lack CD5+ B-1 cells and do not respond to TI-2 antigens. Therefore, their splenocytes can be used as “filler” cells to create the optimal cell density in the cell cultures. Spleen and peritoneal cells of CBA mice and B-1 and B-2 lymphocytes isolated from peritoneum and spleen, respectively, were cultured in different proportions with CBA/N splenocytes with or without antigens. LPS and polyvinylpyrrolidone (PVP) were used as TI-1 and TI-2-antigens, respectively. Antibody- and immunoglobulin-forming cells (AFC and IFC, respectively) were determined by the ELISPOT method on the 4th day of cultivation. It was shown that CBA and CBA/N cells in mixed cell cultures retained their functional activity. Splenocytes of CBA mice responded to both TI-antigens. Splenocytes of CBA/N mice responded to TI-1 antigen (LPS) only. It means that in vitro B-1 cells play the main role in the immune response to TI-2 antigens, as they do in vivo. Thus, the developed model system can be used to study cellular mechanisms of immune response to TI-1 and TI-2 antigens in vitro.     

The Lyb-3+5+ subset of B cells is not required for lupus-like autoantibody formation caused by graft-vs-host reaction

We asked the question whether or not the Lyb-3+5+ B cell subset, which is lacking in CBA/N immune defective mice, is required for the lupus-like autoantibody formation caused by graft-vs-host reaction (GVHR). (CBA/N X DBA/2)F1 male defective mice injected with DBA/2 T cells produced IgG autoantibodies to the same extent as did nondefective F1 mice suffering from GVHR. Although a very small number of DBA/2 B cells might have contaminated the T cell inocula, it was shown that these were B cells of the defective F1 mice that produced autoantibodies during the GVHR. This was demonstrated by detecting autoantibodies carrying an immunoglobulin allotype of the F1 recipient. Furthermore, the defective F1 male mice injected with CBA/N lymphoid cells, which were lacking Lyb-3+5+ B cells, also produced autoantibodies. Isotype analysis of antinuclear antibodies revealed that some of them belonged to IgG3 isotype. It was concluded that the ontogenically late-appearing B cell subset is not required for GVH autoimmunity.     

Evolution of alloantibodies and suppressor cells in allografted mice treated for passive enhancement

The kinetics and quality of the alloimmune reaction were studied in CBA (H-2k) mice treated for passive enhancement of tumor allografts (Sa 1 indigenous of A/J (H-2a or H-2k/d) mice). Serum samples of treated animals were tested for their biological properties relevant to different antibody isotypes in vitro (hemagglutination, complement-dependent cytotoxicity, and anaphylaxis, i.e., mast cell degranulation involving all main Ig isotypes; IgM, IgG2, and IgG1, IgE, respectively) as well as in vivo (allograft enhancement). Spleen cells from these treated animals were examined for their capacity to interfere with the rejection of tumor allografts by adoptive transfers into syngeneic recipients. In vitro, 51Cr release cytolysis assays were performed in order to test their cytolytic and regulatory activities in comparison to rejecting control animals. It has been shown that: grafted mice, pretreated for passive enhancement, kept their grafts longer and synthetized anaphylactic antibodies (mainly IgG1) earlier and at higher titers than normal serum controls, which rejected the same Sa 1 allografts. Mice with enhanced tumors synthetized cytotoxic antibodies (mainly IgG2) later than rejecting controls. Serum samples from treated and control animals, harvested 10 days (early sera) and 30 days (late sera) after grafting, were injected with a "normal dose" (0.2 ml) and a "high" dose (0.4 ml) to new CBA recipients grafted with Sa 1. Early immune sera were only enhancing at high doses when derived from animals previously treated for enhancement (at the low dose both immune sera were enhancing). Late sera, presenting both complement-fixing, cytotoxic (predominantly IgG2), and IgG1 anaphylactic alloantibodies in the two groups, induced enhancement in all cases, but more strongly when derived from the group treated for Sa 1 enhancement. Adoptive transfer of spleen cells from animals treated for passive enhancement were able either to inhibit the accelerated rejection (Day 10) or to promote enhancement of Sa 1 allogeneic cells (Day 30) while similar cells taken (Day 10 and Day 30) from control graft-rejecting mice transferred accelerated rejection. Among the transferred T-cell sub-populations, the suppressive effect was mediated by Lyt 2 T cells. In vitro, these spleen cells showed a weaker cytolytic activity than those of allograft-rejecting mice. Moreover, they were able to regulate the cytolytic activity of cytotoxic effector cells from specifically immunized CBA mice.     

Mycobacterium genavense infection in normal and immunodeficient mice

Mycobacterium genavense is a recently described microorganism causing disseminated infections in AIDS patients. In this study, we investigate its pathogenicity in mice and some mechanisms of the host response to this bacterium. Following an intravenous challenge of 10(6) organisms, M. genavense grew progressively in the spleens and livers of BALB/c and CBA mice over at least an 8-month period. Granulomas were present in the spleens, livers and lungs of the animals. The numbers of bacteria recovered from the spleens and livers were higher in BALB/c (Bcg(s)) than in CBA (Bcg(r)) mice from day 30. The role of the Bcg gene, in the early phase of infection, was supported by the fact that the bacterial load, on day 15, was higher in BALB/c than in the congenic C.D2 (Bcg(r)) mice. The role of T cells in the host response was suggested by the high susceptibility of nude mice to M. genavense infection. In vivo depletion experiments in CBA mice indicated that gamma interferon and both CD4(+) and CD8(+) T cells participate in the containment of the bacterial load.     

Suppressors of the graft vs graft reaction in tolerance to alloantigens

Immune response and suppressor cell activity of CBA (H-2k) mice made tolerant to allogeneic C57B1/6 (H-2b) heart graft were studied in graft-versus-graft reaction (GvGR). Intact CBA spleen cells inhibited response of (CBA X C57B1/6)F1 cells to antigenic stimulus (sheep red blood cells--SRBC), when injected together into lethally irradiated (CBA X C57B1/6)F1 mice. Spleen cells of tolerant mice were unable to decrease immune response of (CBA X C57B1/6F1 lymphocytes to SRBC and suppressed specifically the inhibition induced by intact CBA spleen cells. Spleen cells from tolerant mice were also capable of suppressing GvGR induced by CBA lymphocytes immune to C57B1/6 cells. Pretreatment of tolerant spleen cells with rabbit antithymocyte globulin and complement before adoptive transfer diminished markedly the suppression. The results obtained in the study suggest that suppression of transplantation immunity in this model is mostly due to T suppressor cells.