Thymus dependency of neonatal tolerance induction in the absence of detectable suppressor cells

Neonatal thymectomy prevents tolerance induction with bovine serum albumin (BSA) in Wistar Furth (WF) rats whose thymus-derived (T) cell deficit is reconstituted with adult nonadherent peripheral blood lymphocytes (PBL). Sham-thymectomized (STx) rats given PBL become tolerant. To establish whether the adult T cells become tolerant in STx rats, their carrier-reactivity was studied in a cooperative immune response following challenge with methylated BSA (mBSA). The results indicate that carrier-reactive cells, derived from PBL, do become tolerant of BSA in the presence, but not in the absence, of the thymus. To determine whether thymic function during tolerance induction is mediated by suppressor T cells, attempts were made to replace the thymus with various populations of thymocytes or lymphoid cells from neonatal or adult normal rats or neonatal BSA-injected rats. No cell population tried could substitute for the thymus during tolerance induction. In addition, it was found that BSA-tolerant rats with intact thymi do not contain either nonspecific suppressor cells whose activity can be boosted with mBSA or specific suppressor activity demonstrable on transfer to normal rats. Timed thymectomy experiments showed that the thymus is required for more than 2, but less than 5 to 7 days after tolerogen injection for significant tolerance induction. These results imply that the thymus itself is necessary for tolerance induction in a peripheral T-cell population and that its effect is not mediated by suppressor cells. It is suggested that peripheral T helper cells may periodically recirculate through the thymus, at least in young rats, and become tolerant of antigen complexed with Ia antigens in the thymic epithelium. Such a mechanism may be of great importance in the development of self-recognition.     

Role of B7 in T cell tolerance

The induction of effective immune responses requires costimulation by B7 molecules, and Ag recognition without B7 is thought to result in no response or tolerance. We compared T cell responses in vivo to the same Ag presented either by mature dendritic cells (DCs) or as self, in the presence or absence of B7. We show that Ag presentation by mature B7-1/2-deficient DCs fails to elicit an effector T cell response but does not induce tolerance. In contrast, using a newly developed adoptive transfer system, we show that naive OVA-specific DO11 CD4+ T cells become anergic upon encounter with a soluble form of OVA, in the presence or absence of B7. However, tolerance in DO11 cells transferred into soluble OVA transgenic recipients can be broken by immunization with Ag-pulsed DCs only in B7-deficient mice and not in wild-type mice, suggesting a role of B7 in maintaining tolerance in the presence of strong immunogenic signals. Comparing two double-transgenic models--expressing either a soluble or a tissue Ag--we further show that B7 is not only essential for the active induction of regulatory T cells in the thymus, but also for their maintenance in the periphery. Thus, the obligatory role of B7 molecules paradoxically is to promote effective T cell priming and contain effector responses when self-Ags are presented as foreign.     

Functional activity of T and B lymphocytes of mice undergoing spontaneous loss of tolerance]

The functional activity of splenocytes and thymocytes of mice tolerant to sheep red blood cells was investigated one and four weeks after tolerance induction. The tolerance was achieved by cyclophosphamide. The immunocompetence of thymocytes was fully reversed in lfour week time. The functional activity of T and B lymphocytes of the spleen was also partially recovered four weeks after tolerance induction. Preliminary thymectomy weakened but did not prevent completely the immunocompetence of T cells of the spleen from being recovered. No Tsuppressants were found in the thymus or spleen of the tolerant animals.     

Tolerance defects in New Zealand Black and New Zealand Black X New Zealand White F1 mice

The susceptibility of autoimmune NZB and (NZB X NZW)F1 mice to the induction of tolerance by monomeric BSA was compared with several normal mouse strains. Unresponsiveness in T and B lymphocyte compartments was probed by challenging with DNP8BSA and measuring anti-DNP and anti-BSA antibodies separately. Tolerance induced by monomeric BSA was carrier specific, and there was no evidence of epitope-specific suppression. Normal NZW, NFS, and B10.D2 mice were easily rendered tolerant with monomeric BSA and did not produce anti-DNP or anti-BSA antibodies after challenge with DNP8BSA. By contrast, the lack of anti-DNP antibody response in similarly treated NZB mice was dependent on the dose of monomeric BSA, indicating that the helper T cells were partially resistant to tolerance induction. NZB mice treated with a high dose of monomeric BSA produced anti-BSA, but not anti-DNP, antibodies after immunization. Thus, the anti-carrier B cells in NZB mice may have been primed by monomeric BSA. The presence of the xid gene on the NZB background rendered the mice susceptible to induction of tolerance, suggesting that the tolerance defect in NZB mice involves the B cell compartment. This abnormal antibody response was a dominant trait: (NZB X NFS)F1 and (NZB X B10.D2)F1 mice had the same characteristics as NZB mice. These F1 hybrids do not develop autoimmune disease, indicating that resistance to experimental tolerance induction expressed at a B cell level may not be sufficient for disease development. In contrast to NZB and other NZB F1 hybrids, (NZB X NZW)F1 hybrids treated with monomeric BSA and challenged with DNP8BSA responded to both DNP and BSA. The contribution of a B cell defect to the tolerance abnormality of (NZB X NZW)F1 mice was examined by analyzing the effect of the xid gene on the progeny of (NZB.xid X NZW)F1 mice. Unlike the effect of the xid gene on NZB mice, both phenotypically normal heterozygous female and phenotypically xid hemizygous male mice produced anti-DNP and anti-BSA antibodies after tolerance induction and immunization, demonstrating that a major helper T cell abnormality was present in (NZB X NZW)F1 mice. The (NZW X B10.D2)F1 hybrid was rendered tolerant by this procedure, indicating that the helper T cell defect (NZB X NZW)F1 mice may have resulted from gene complementation with the NZB mice contributing partial resistance of T helper cells to tolerance induction.(ABSTRACT TRUNCATED AT 400 WORDS)     

The induction of peripheral T cell unresponsiveness in adult mice by monomeric human gamma-globulin

Monomeric human gamma-globulin (HGG), when injected into adult mice, induces a state of specific immunologic unresponsiveness to further challenge with immunogenic forms of HGG. In this report we have directly determined the role of the thymus in the induction of HGG tolerance and the proliferative responsiveness of T cells from normal and HGG-tolerant mice. Draining lymph node T cells were isolated from HGG-tolerized and -challenged mice, and tested for their proliferative response to HGG in vitro. T cells from untreated but challenged adult CBA/CaJ and A/J mice proliferate in response to HGG, whereas such mice given monomeric HGG before challenge fail to show an HGG-specific proliferative response. APC from tolerant or nontolerant mice were equally effective in the support of Ag-specific proliferation of primed T cells. The influence of the thymus gland on HGG-induced T cell unresponsiveness was assessed by determining whether thymectomized mice could be tolerized to HGG. The results suggest that the generation of T cell tolerance to HGG is independent of thymic function as assayed by both antibody production in vivo and T cell proliferation in vitro. Unresponsiveness of T cells from tolerant mice was not a result of the presence of CD8+ cells since removal of CD8+ cells from lymph node T cells did not alter unresponsiveness to HGG in vitro. Further, mixing tolerant T cells with normal HGG-primed T lymphocytes did not inhibit proliferation of the HGG-primed cells. The results of this investigation suggest that this mouse model of tolerance to HGG represents a thymus-independent unresponsiveness of mature peripheral T cells to a nonself-Ag. Understanding the regulation of tolerance to HGG may give additional insight into the mechanisms required for the maintenance and possibly the induction of tolerance to certain self-Ag in peripheral lymphoid organs.     

Functional clonal deletion and suppression as complementary mechanisms operative in adult hapten-induced cytotoxic T cell tolerance

Immunologic tolerance to the hapten TNP was induced in adult mice through the i.v. injection of reactive TNBS. To probe the cellular basis of the tolerant state, splenic cytotoxic T lymphocyte precursors (CTL-P) were stimulated in vitro with haptenated, x-irradiated syngeneic spleen cells in the presence or absence of exogenously added growth factors derived from Concanavalin A-stimulated spleen cell conditioned medium (CAS). The cultures were either conventional bulk cultures or limit dilution cloning cultures. For the latter, cytotoxicity was assessed through a semi-automated, radioautographic 111In-release assay. Suppressive potential was assessed by mixing spleen cells from tolerant mice with normal spleen cells before culture. In the absence of CAS, bulk cultures showed profound tolerance, and suppressive capacity was clearly evident. Suppression was dependent on the presence of TNP-self during culture and affected the generation of CTL from CTL-P and not the effector function of CTL. Cyclophosphamide treatment did not prevent tolerance induction. In the presence of CAS, bulk cultures still showed marked tolerance, but mixing experiments now yielded no evidence of suppression. As documented previously, limit dilution cultures of tolerant spleen cells in the presence of CAS showed a functional clonal deletion of hapten-specific CTL-P. In the absence of CAS, limit dilution cultures became dependent on helper T cells as the limiting element. Tolerant populations showed a diminution of activatable helper T lymphocyte precursors (HTL-P), which may have been due to a functional clonal deletion of HTL-P and/or a concomitant activation of suppressor T cells. Adoptive transfer studies showed that cells from tolerant mice did not detectably influence the number of hapten-specific CTL-P in the spleens of host animals. Taken together, the results suggest that both functional clonal deletion of CTL-P and suppression of HTL-P contribute to the tolerant state induced.     

Neonatally induced tolerance to soluble protein antigens. II. A role for the thymus in prolonging tolerance

Mice were rendered tolerant to bovine serum albumin (BSA) or fowl γ-globulin (FGG) by neonatal injection. Spleen and thymus cells from tolerant mice were able to suppress responsiveness of normal adult spleen cells, but only if tolerant donor mice were between the ages of 6 weeks and the age at which mice were no longer tolerant (10 weeks for BSA tolerance and 20 weeks for FGG tolerance). To determine whether T-cell-dependent suppression was obligatory for the maintenance of tolerance, neonatal nude and euthymic littermate mice were injected with tolerizing doses of FGG. FGG-specific B-cell tolerance in nude mice lasted until the mice were 8 weeks of age. In sharp contrast, B-cell tolerance in euthymic littermates lasted until 22 weeks of age. These results are consistent with a “fail-safe” role of T-cell-dependent immune suppression in the maintenance of tolerance.     

Neonatal splenic suppressor cells in the chicken. I. In vivo suppression of the immune response to bovine serum albumin by normal and tolerized neonatal spleen cells

The presence of active splenic suppressor cells in neonatal chickens, either normal or tolerant to bovine serum albumin (BSA), was examined by assessment of their effect on both primary and adoptively transferred secondary responses to BSA or sheep red blood cells (SRC). Both normal and BSA tolerized spleen cells were shown to be highly suppressive of secondary anti-BSA responses generated by specifically primed adult spleen cells in inert recipients. Suppression of the secondary anti-BSA response by normal spleen cells was slightly less effective than that seen with BSA tolerant spleen cells. Transfer of BSA tolerant spleen cells into normal recipients, followed by BSA challenge, prevented any significant primary anti-BSA response. In contrast, transfer of normal spleen cells into normal recipients, followed by BSA challenge, failed to show any suppression of the resulting primary response. Neither normal nor BSA tolerant neonatal spleen cells were capable of suppressing either primary or secondary responses to SRC. Thus, chickens tolerized to BSA have suppressor cells specific for the tolerizing antigen. We present evidence that both the tolerance associated suppressors and the suppressors detected in normal neonatal chickens are T cells.     

Active transformation of tolerogenic to immunogenic signals in T and B cells by 8-bromoguanosine

The injection of deaggregated human gamma-globulin (DHGG) into A/J mice results in the establishment of a state of unresponsiveness to subsequent challenge with immunogenic aggregated human gamma-globulin (AHGG). Administration of the B cell activator 8-bromoguanosine (8BrGuo) 3 hr after administration of DHGG converts the tolerogen to an immunogen and results in an antibody response of even greater magnitude than the primary response elicited by AHGG alone. Adoptive transfer studies with separated populations of T and B cells demonstrated that although transformation of the tolerogenic signal to an immunogenic signal involves effects of 8BrGuo on both T cells and B cells, the major effect appears to be activation of antigen-specific T cells that would otherwise become tolerant. Modulation of T cell tolerance could conceivably be mediated either by direct or indirect mechanisms. Interestingly, optimal responsiveness of B cells from animals treated with DHGG and 8BrGuo is not a T cell-independent event, but requires antigen-reactive T cells. 8BrGuo is not able to override unresponsiveness when given 10 to 20 days after tolerance induction, at a time point when both T and B lymphocytes are tolerant. However, when given at day 60, when T cells (but not B cells) remain tolerant to this antigen, the nucleoside is able to terminate the tolerant state prematurely, possibly by providing an alternate T helper-like signal directly to B cells or by recruiting nonspecific functional T helper cells.     

Studies on the resistance to tolerance induction against human IgG in DDD mice. III. Development of the resistance with age and cellular events.

Three-week-old DDD mice were easily rendered tolerant to human IgG while 12-week-old mice were tolerized only partially. Mechanisms of the development of the resistance with age were investigated. It was shown by the cell transfer experiments that spleen T cells, purified on a Tetron wool column, from older mice were responsible for the resistance, which was not associated with the loss of suppressor cells with age. To elucidate the possibility of whether tolerogen-sensitive spleen T cells differentiate into resistant ones, cell transfer experiments were carried out in which thymectomized, lethally irradiated mice were reconstituted with spleen cells from 3-week-old mice and then treated with the tolerogen on various days afterward. The results indicated that tolerance was inducible in these hosts to the same degree, irrespective of the timing of the tolerogen injection, while age-matched intact mice gradually acquired the resistance. Then the possibility of whether age of thymus affected tolerance inducibility of the hosts or not was examined. The tolerogen was injected into irradiated, bone-marrow-reconstituted mice which bore either 4- or 7-week-old thymus. It was shown that helper T cells newly generated under younger thymus acquired higher susceptibility to the tolerogen. There was no difference in tolerance inducibility irrespective as to whether bone marrow cells were prepared from younger or older mice. From these observations it was suggested that the resistance to tolerance induction in DDD mice is acquired through the appearance of resistant T cells which are generated from T-cell precursors in bone marrow under the influence of a radioresistant thymic constitution and predominantly located in the spleen.     

Cellular aspects of tolerance. VI. The effect of age on responsiveness and tolerance induceability of SJL mice

New born and 3-week-old SJL mice but not 8–12-week-old animals could be rendered tolerant to rabbit γ-globulin. Animals reconstituted with thymus cells from 12-week-old donors and bone marrow cells from 3-week-old donors showed resistance to tolerance induction. Animals reconstituted with bone marrow cells from 12-week-old animals and thymus cells from 3-week-old donors could be rendered tolerant. Earlier work has shown that tolerance could be induced in older animals, if they were deprived of competent accessory cells. It was suggested that a lesion in the thymus cell population is expressed through the mediation of accessory cells. The possibility of a relation between resistance to tolerance induction and lymphoid malignancies was discussed.     

In vivo CD4+ T cell tolerance induction versus priming is independent of the rate and number of cell divisions

In vitro studies have suggested that tolerance induction (i.e., anergy) is associated with an inability of T cells to proliferate vigorously upon Ag recognition. In vivo, the relationship between T cell proliferation and tolerance induction is less clear. To clarify this issue, we have been studying a model system in which naive CD4+ T cells specific for the model Ag hemagluttinin (HA) are adoptively transferred into different transgenic founder lines of mice expressing HA as a peripheral self-Ag. When transferred into two lines whose HA expression differs by at least 1000-fold, HA-specific T cells undergo multiple rounds of cell division before reaching a nonresponsive (i.e., tolerant) state. While the proliferative response is more rapid in mice expressing higher levels of HA, the T cells become tolerant regardless of the level of peripheral HA expression. When the T cells encounter HA expressed as a viral Ag, they proliferate at a similar rate and undergo the same number of divisions as with self-HA, but they do not become tolerant. These results indicate that a tolerizing stimulus can induce similar T cell mitotic rates as a priming stimulus. Therefore, CD4+ T cell tolerance induction in vivo is not the result of an insufficient proliferative response elicited upon TCR engagement.     

Studies on the resistance to tolerance induction against human IgG in DDD mice. I. Organ differences of tolerogen susceptibility and cellular sites responsible for the resistance.

Cellular sites of the tolerogen resistance in DDD mice against human IgG (HGG) were examined by reconstitution experiments in which cells of various lymphoid organs from tolerized mice were transferred into lethally irradiated syngeneic recipients with or without the supplement of an excess number of untreated T or B cells. It was shown that T cells but not B cells in the spleen and bone marrow-locating B cells were tolerogen resistant. Kinetic profiles of tolerance induction were compared among thymus, lymph node, and spleen T cells. Thymus cells fall into unresponsive state as early as 2 days after the tolerogen (tHGG) injection when only partial tolerance was observed in lymph node T cells. By 1 week of tolerogen treatment, the tolerant state was completed in both thymus cells and lymph node T cells, while spleen T cells showed marked resistance. Tolerance induced in thymus cells and spleen T cells was of relatively short duration and responsiveness was completely recovered by 5 weeks after the injection of tHGG. At this time lymph node T cells still showed hyporesponsiveness. The differences in tolerance inducibility were also shown among different lymphoid organs in tolerogen dose response. Lymph node T cells were very sensitive to tolerance induction, giving no response even by the injection of 0.01 mg of tHGG. Thymus cells were much less sensitive with the gradual loss of responsiveness by increasing the amount of tHGG. In contrast, spleen T cells showed gradual resistance with increasing amount of tHGG, indicating that some positive response was evoked in spleen T cells by a relatively high dose of tHGG. These results seem to suggest that the tolerogen resistance of spleen T cells may be due to their capability of showing positive response against the tolerogenic material. This was also suggested by the fact that the treatment with cyclophosphamide following the tolerogen injection diminished completely the responsiveness against the subsequent challenge immunization.     

CD25+ immunoregulatory CD4 T cells mediate acquired central transplantation tolerance

Transplantation tolerance is induced reliably in experimental animals following intrathymic inoculation with the relevant donor strain Ags; however, the immunological mechanisms responsible for the induction and maintenance of the tolerant state remain unknown. We investigated these mechanisms using TCR transgenic mice (TS1) that carry T cells specific for an immunodominant, MHC class II-restricted peptide (S1) of the influenza PR8 hemagglutinin (HA) molecule. We demonstrated that TS1 mice reject skin grafts that have transgene-encoded HA molecules (HA104) as their sole antigenic disparity and that intrathymic but not i.v. inoculation of TS1 mice with S1 peptide induces tolerance to HA-expressing skin grafts. Intrathymic peptide inoculation was associated with a dose-dependent reduction in T cells bearing high levels of TCR specific for HA. However, this reduction was both incomplete and transient, with a full recovery of S1-specific thymocytes by 4 wk. Peptide inoculation into the thymus also resulted in the generation of immunoregulatory T cells (CD4+CD25+) that migrated to the peripheral lymphoid organs. Adoptive transfer experiments using FACS sorted CD4+CD25- and CD4+CD25+ T cells from tolerant mice revealed that the former but not the latter maintain the capacity to induce rejection of HA bearing skin allografts in syngeneic hosts. Our results suggest that both clonal frequency reduction in the thymus and immunoregulatory T cells exported from the thymus are critical to transplantation tolerance induced by intrathymic Ag inoculation.     

Normal development in porcine thymus grafts and specific tolerance of human T cells to porcine donor MHC

The induction of T cell tolerance is likely to play an essential role in successful xenotransplantation in humans. In this study, we show that porcine thymus grafts in immunodeficient mice support normal development of polyclonal, functional human T cells. These T cells were specifically tolerant to MHC Ags of the porcine thymus donor and responded to nondonor porcine xenoantigens and alloantigens. Exogenous IL-2 did not abolish tolerance, suggesting central clonal deletion rather than anergy as the likely tolerance mechanism. Our study suggests that the thymic transplantation approach to achieving tolerance with restoration of immunocompetence may be applicable to xenotransplantation of pig tissues to humans.     

Tolerance induced by TNP-derivatized syngeneic erythrocytes: evidence for cooperation between hapten-specific T and hapten-specific B lymphocytes in the immune response.

Tolerance to the DNP haptenic determinant was induced with a single i.v. injection of trinitrophenylated syngeneic red blood cells. The tolerant state lasted 1 month and was stable on transfer to irradiated thymectomized syngeneic recipients. Suppressor activity was found soon after injection of tolerogen but was lost before the termination of tolerance. The unresponsive state could be reversed by adding normal thymus cells to tolerant spleen cells but not by normal bone marrow cells. LPS when given with immunogen restored the normal immune response in tolerant mice. Thus the injection of TNP-MRBC induced partial immune unresponsiveness which was characterized by the induction of T cell suppressor activity and by a hapten-specific helper T cells tolerance. Finally, these studies suggest a cooperative interaction between DNP-specific T lymphocytes and DNP-specific B lymphocytes in the immune response to DNP-BGG.     

T-Cell Tolerance: Central and Peripheral

Somatic recombination of TCR genes in immature thymocytes results in some cells with useful TCR specificities, but also many with useless or potentially self-reactive specificities. Thus thymic selection mechanisms operate to shape the T-cell repertoire. Thymocytes that have a TCR with low affinity for self-peptide–MHC complexes are positively selected to further differentiate and function in adaptive immunity, whereas useless ones die by neglect. Clonal deletion and clonal diversion (Treg differentiation) are the major processes in the thymus that eliminate or control self-reactive T cells. Although these processes are thought to be efficient, they fail to control self-reactivity in all circumstances. Thus, peripheral tolerance processes exist wherein self-reactive T cells become functionally unresponsive (anergy) or are deleted after encountering self-antigens outside of the thymus. Recent advances in mechanistic studies of central and peripheral T-cell tolerance are promoting the development of therapeutic strategies to treat autoimmune disease and cancer and improve transplantation outcome.T cells recognize pathogen fragments in the context of surface MHC molecules on host cells. As such, they have the potential to do enormous damage to healthy tissue when they are not appropriately directed, that is, when they respond to self-antigens as opposed to foreign antigens. T lymphocyte tolerance is particularly important, because it impacts B-cell tolerance as well, through the requirement of T cell help in antibody responses. Thus, failure of T-cell tolerance can lead to many different autoimmune diseases. The tolerance of T cells begins as soon as a T-cell receptor is formed and expressed on the cell surface of a T-cell progenitor in the thymus. Tolerance mechanisms that operate in the thymus before the maturation and circulation of T cells are referred to as “central tolerance.” However, not all antigens that T cells need to be tolerant of are expressed in the thymus, and thus central tolerance mechanisms alone are insufficient. Fortunately, additional tolerance mechanisms exist that restrain the numbers and or function of T cells that are reactive to developmental or food antigens, which are not thymically expressed. These mechanisms act on mature circulating T cells and are referred to as “peripheral tolerance.”     

Induction of immunological tolerance in neonatal and adult rabbits. Differences in the cellular events

A transient production of antibody does not occur in the induction of specific immunological tolerance to soluble BSA in neonatal rabbits. The newborn rabbit, however, has the immunologic potential to respond to BSA when it is given in adjuvant. These results suggest that a normal complement of specific B cells is present in the newborn rabbit and that the immunoincompetence to the soluble protein, that permits the induction of tolerance without a phase of antibody formation, may be a function of either T cells or macrophages. In contrast to the newborn, the induction of tolerance in adult rabbits following daily injections with large doses of BSA is preceded by a transient production of antibody-producing cells. In this situation, at least, one of the events involved in the induction of unresponsiveness appears to be interpretable as an exhaustive differentiation of competent cells capable of being stimulated. Therefore, two differing cellular patterns can be observed in the completion of seemingly identical end states of immunological tolerance.     

Allo-I-J determinants participate in maintenance of neonatal H-2 tolerance

To evaluate the role of IJ antigens in maintenance of the tolerant state in adult H-2 tolerant mice, we have attempted to abolish tolerance by injecting monoclonal antibodies (mab) specific for host, donor, or third party IJ antigens into adult H-2 tolerant mice. Abolition of tolerance was evidenced by the rejection of fresh test skin grafts bearing the tolerated antigens. Whole H-2 tolerant mice treated with anti-IJ mab specific for donor (allo) IJ antigens rejected their test skin grafts, indicating that tolerance had been abolished. When two other types of tolerant mice were tested, we found that mice tolerant of class II antigens alone, but not mice tolerant of an IJ thru D disparity, were susceptible to the anti-donor IJ mab treatment. In addition, adult tolerant mice were unaffected by treatment with either anti-host or anti-third party IJ mab. When tested in vitro, lymphoid cells from tolerant mice, the tolerance of which was abolished by anti-IJ mab, remained unresponsive to the tolerogen, just as untreated (control) tolerant mice, in several in vitro assays (e.g., mixed lymphocyte reaction, cytotoxic T cell precursor frequency and bulk cell-mediated lysis without growth factor). Mice treated with antidonor IJ mab, however, unlike mice treated with anti-host or third party IJ mab, were capable of generating tolerogen-specific T cells in the absence of exogenous growth factor. Thus in the strain combinations we used, adult mice tolerant of either the entire H-2 region or of the class II major histocompatibility complex region alone are susceptible to abolition of the tolerant state by treatment with anti-donor IJ mab. Coincidentally, lymphoid cells from these mice generate sufficient endogenous T helper activity to activate the tolerogen-specific cytotoxic T cells. We suspect that these latter cells may be responsible for rejection of grafts bearing the tolerated antigens.     

Induction of immune tolerance to thymus-dependent antigen (sheep erythrocytes) in the absence of T-cells]

The role of T cells in B cell tolerance induction to sheep red blood cells (SRBC) was studied in intact adult mice, in lethally irradiated mice injected with singeneic embryonic liver cells and thymocytes (TB-mice) and in animals functionally deprived of T cells--thymectomized, letally irradiated mice reconstituted with embryonic liver cells only (B-mice). Tolerance was obtained by treatment of mice with SRBC and cyclophosphamide (Cy). Cy-induced tolerance to SRBC was shown to be the result of the absence of specific T cells and partially of immunocompetent B cells. Suppression of immunoreactivity was observed not only in TB-mice but also in B-mice subjected to tolerogenic treatment. Splenocytes of tolerant TB-mice did not suppress the immune response of intact spleen cells to SRBC. The results obtained suggest the conclusion that B cells tolerance could be formed in absence of T cells.