Interference with tolerance induction in vivo by inhibitors of prostaglandin synthesis

Prostaglandins (PG) have been implicated as modulators of both humoral and cellular immune responses. In order to evaluate a possible role for PG in tolerance, the effect of inhibitors of prostaglandin synthesis on tolerance induction and circumvention has been investigated. Injection of deaggregated human gamma-globulin (DHGG) into A/J mice leads to unresponsiveness to a subsequent challenge with immunogenic aggregated human gamma-globulin (AHGG). Administration of indomethacin (IM) or acetylsalicylic acid (ASA) shortly before and after DHGG injection prevents tolerance induction. PGE2 reverses the tolerance overriding effect provided by IM. IM is not able to overcome unresponsiveness when given 10 and 20 days after tolerance induction, at a time point when both T and B lymphocytes are tolerant. As previously shown, lipopolysaccharide (LPS) both inhibits the induction of tolerance to HGG and circumvents tolerant T helper cells late in tolerance when competent B cells are present. In contrast, IM is unable to circumvent T-helper cell tolerance when given at Day 60 after tolerogen, when B cells (but not T cells) are responsive. Furthermore, LPS acts as an adjuvant, B-cell mitogens, inducer of polyclonal Ig secretion, and primes mice when given with tolerogen, while IM has none of these properties. These results indicate a difference between the effects of IM and LPS on tolerance and a possible role of PG in DHGG-mediated tolerance induction.     

The induction of immunological unresponsiveness in previously immunized mice.

HGG unresponsiveness can be induced in primed A/J mice; however, such induction is difficult and requires multiple injections of large doses of soluble HGG (SHGG). Although single injections (1.5–25 mg) of deaggregated HGG (DHGG) did not result in a significant secondary immune response, an unresponsive state to a subsequent injection of aggregated HGG (AHGG) was not induced. When the dose of DHGG was even smaller (0.5 mg), a normal secondary response was obtained similar to that observed following injection of AHGG. Evidence is presented here which suggests that the difficulty encountered in inducing unresponsiveness may be in part due to partial aggregation of DHGG by persisting antibody in the circulation. The PFC to HGG produced after injection of either AHGG or DHGG or during induction of unresponsiveness to SHGG apparently involved cell division, since all three responses were inhibited by vinblastine. The reduction in PFC in primed mice injected with DHGG or SHGG was not due to selective inhibition of PFC secreting certain classes or subclasses of immunoglobulins.     

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. 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.     

Specific suppression of the immune response by HGG tolerant spleen cells. I. Parameters affecting the level of suppression.

After adoptive transfer, the spleen cells from mice made tolerant to human gamma-globulin (HGG) specifically suppress the immune response of normal spleen cells. However, this suppressive activity in the spleen cells of tolerant mice is only present for a brief period after treatment with tolerogen. Spleen cells from animals injected 10 days earlier with tolerogen reduce the immune response of an equal number of normal spleen cells by 75%. Spleen cells from mice made tolerant 40 days previously are, however, no longer suppressive, even though they remain completely unresponsive. These data suggest that active suppression of antigen-reactive cells is not the mechanism responsible for maintaining tolerance to HGG, but rather is only transiently associated with the tolerant state. Further evidence in favor of the separation of the tolerant state from suppressive activity is that complete suppression of the normal spleen cell response requires either a high ratio of tolerant to immune competent cells or a delay in the antigenic challenge of the reconstituted recipients. By contrast, such manipulations are not required to demonstrate the complete unresponsiveness of the tolerant cells after adoptive transfer.     

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.     

Immunologic unresponsiveness after gastric administration of human gamma-globulin: antigen requirements and cellular parameters

Gastric administration of human gamma-globulin (HGG) into adult A/J mice leads to the establishment of an antigen-specific unresponsive state to subsequent parenteral challenge with HGG. An unresponsive state is induced in both helper T and B lymphocyte populations. Unresponsiveness in helper T cells is of longer duration than in B cells, lasting at least 9 wk after intragastric intubation. Adoptive cell transfer of spleen cells from gastrically inoculated mice into healthy irradiated, syngeneic recipients revealed that the unresponsive state is stable upon cell transfer and that suppressor cells are present in the spleens of gastrically tolerized mice. The establishment of HGG-specific unresponsiveness is dependent upon both the dose and the form of the antigen adminstered. Soluble and deaggregated HGG are both more efficient than is heat-aggregated HGG in inducing unresponsiveness gastrically. The administered HGG is rapidly eliminated from the animal and only a small fraction reaches the circulation as immunoreactive protein. Although the cellular parameters of the systemic unresponsiveness induced by intragastric intubation with HGG appear similar to the parameters of parenterally induced unresponsiveness, the precise mechanisms by which gastric unresponsive states are established remain to be resolved.     

Defective B cell tolerance induction in New Zealand black mice. I. Macrophage independence and comparison with other autoimmune strains

B cell unresponsiveness was examined in vitro by using spleen cells from autoimmune NZB, BXSB/Mp male, MRL/Mp-Ipr/Ipr (MRL/l), and control mice, and the tolerogen trinitrophenyl human gamma-globulin (TNP-HGG). The B cell subset responsive to TNP-Brucella abortus in each autoimmune and control strain that was tested was highly susceptible to tolerance induction with the use of high epitope density conjugates (TNP30HGG and TNP32HGG). When a tolerogen with a lower epitope density was used (TNP7HGG), several control strains were all rendered tolerant in a thymic-independent and hapten-specific manner. NZB B cells were resistant to all concentrations of TNP7HGG tested, whereas B cells from BXSB/Mp male and MRL/1 mice were resistant to low concentrations of this tolerogen. NZB mice were resistant in addition to tolerance induction with TNP9HGG, TNP10HGG, and TNP12.7HGG. Experiments were performed to determine whether splenic macrophages played a role in resistance to tolerance in NZB mice. The mixing of NZB and control DBA/2J T cell-depleted splenocytes revealed no modulatory effects by the accessory cells in culture. Moreover, B cells rigorously depleted of macrophages by double Sephadex G-10 column passage exhibited characteristic patterns of resistance or susceptibility in NZB and control strains, respectively. These findings support the conclusion that resistance to tolerance in NZB mice is determined at the B cell level and are consistent with the hypothesis that diverse immunoregulatory disturbances contribute in varying degrees to the development of systemic lupus erythematosus in different inbred strains of mice.     

A novel role for macrophages: the ability of macrophages to tolerize B cells

We investigated the ability of macrophages (M phi) to present the tolerogen fluoresceinated sheep gamma-globulin (FL-SGG) to B cells. M phi pulsed with FL-SGG or murine FL-IgG2 were able to tolerize normal spleen B cells specifically as assessed by the plaque-forming cell (PFC) response to the antigens FL-Brucella abortus (FL-BrA) and FL-polymerized flagellin (FL-POL). Tolerance was not induced when M phi were pulsed with a variety of other FL antigens or the synthetic tolerogen FL-D-glutamic acid-D-lysine (FL-D[G,L]). The ability of M phi to tolerize B cells was not T cell-dependent, because populations of both T-depleted B cells and hapten-specific B cells were tolerizable. M phi-induced B cell tolerance did not exhibit genetic restriction with regard to the H-2 haplotype of the presenting M phi or the responding B cells. A variety of different types of peritoneal M phi, including normal resident M phi and those elicited by thioglycollate or concanavalin A (the latter are predominantly la+), could tolerize B cells after being pulsed with FL-SGG. We compared tolerogen-pulsed M phi to soluble tolerogen for the ability to tolerize B cells and found that tolerogen bound to M phi was more than 10 times as potent as an equivalent amount of soluble tolerogen. In contrast to the ability of M phi to present FL-SGG in a tolerogenic fashion to B cells, the P388AD lymphoid dendritic cell-like tumor line presented FL-SGG in an immunogenic mode to B cells. Tolerogen bound to P388AD cells could specifically augment a PFC response to both FL-BrA and FL-POL. We suggest that certain types of M phi may play a role in unresponsiveness by enhancing the tolerogenicity of soluble antigen, whereas other accessory cells may present the same moieties in an immunogenic fashion.     

Maturation of the lymphoid system. II. Characterization of the cellular levels of unresponsiveness induced in neonates by a T-dependent antigen that is an obligate immunogen in adults.

It has previously shown that AHGG, a form of HGG that is highly immunogenic in euthymic adult mice, is capable of inducing specific unresponsiveness when injected into neonatal animals. This report extends this finding and indicates that such a neonatal treatment results in the induction of tolerance in T as well as B cells. Furthermore, a similar conclusion was reached regarding specific T lymphocyte function in animals treated as neonates with OVA. The ability of LPS to modulate responses of neonatal animals to AHGG or DHGG was also examined. It appeared that such mice were not susceptible to the adjuvant effects of LPS until the 4th week of life. Furthermore, LPS was incapable of inhibiting the unresponsiveness induced in mice by either DHGG or AHGG until the 3rd or 4th week of life.     

Induction of tolerance in athymic mice with an antigen which is highly immunogenic in euthymic mice.

Adult congenitally athymic (nu/nu) mice were found to be unable to respond to aggregated human γ-globulin (AHGG), the normally immunogenic form of HGG, unless first reconstituted with specific T cells. However, pretreatment of nude mice with AHGG prior to T-cell reconstitution resulted in the induction of unresponsiveness. This state of tolerance was specific since pretreated animals responded normally to the noncross-reacting antigens turkey γ-globulin or DNP-Ficoll. Transfer of spleen cells from nude mice pretreated with AHGG into normal littermates did not significantly affect a subsequent anti-HGG response of the recipients. Conversely, nude mice pretreated with AHGG and reconstituted with normal littermate spleen cells were hyporesponsive to challenge with AHGG. The results of these experiments are discussed in reference to various models for the induction of B-cell unresponsiveness.     

Transfer of immunity to Babesia microti of human origin using T lymphocytes in mice

Lymph node and spleen cells from mice infected with Babesia microti of human origin developed the ability to transfer adoptive immunity to naive mice within 25 days after infection. This protective activity was greater in cells obtained at 32 days than in cells obtained at 25 days postinfection and remained stable up to 52 days postinfection. Recipients of lymph node cells and spleen cells displayed similar peak parasitemias although 2 days after peak parasitemia, immune spleen cell recipients had significantly lower parasitemias than immune lymph node cell recipients. Strong protective activity was demonstrated when cells were transferred 1 day postinfection, while equal numbers of cells, transferred 3 days postinfection did not confer significant protection over nonimmune cells. There was also a suggestion that the number of immune spleen cells necessary for significant protection was directly related to the number of parasites inoculated. The subpopulation of lymphocytes responsible for the transfer of adoptive immunity to B. microti of human origin was then studied in BALB/c mice depleted of T lymphocytes by thymectomy and lethal irradiation. One day after infection with B. microti, T-cell-depleted mice were given complement-treated immune spleen cells, anti-θ serum-treated immune spleen cells, nonimmune spleen cells, or no cells. Similar experiments were performed comparing the effects of anti-immunoglobulin serum-treated and unfractionated immune spleen cells on B. microti parasitemia. Treatment with anti-θ serum abrogated the protective activity of immune spleen cells while anti-immunoglobulin serum treatment had no effect. These results suggest that immunologic memory of B. microti in BALB/c mice is modulated by T rather than B lymphocytes.     

Cell surface antigens and other characteristics of T cells regulating the antibody response to type III pneumococcal polysaccharide

The administration of a subimmunogenic dose of type III pneumococcal polysaccharide (SSS-III) produces an antigen-specific T cell-dependent phenomenon termed low-dose paralysis (immunologic unresponsiveness). This form of unresponsiveness can be transferred by spleen cells obtained 5 to 24 hr after priming, and the suppressive activity of the transferred cells is abolished by prior treatment with monoclonal anti-Lyt-2 and anti-I-J antibody in the presence of complement, indicating that suppression is mediated by a distinct subset of T cells (suppressor T cells). If primed spleen cells are transferred 24 to 72 hr after immunization with SSS-III, however, the resulting antibody response of immunized recipients is enhanced. Greater enhancement is noted when transferred cells, pretreated with monoclonal anti-Lyt-2 antibody plus complement to remove suppressor T cells, are used; such enhancement is attributed to amplifier T cells. These findings indicate suppressor T cells regulate the antibody response to SSS-III by influencing the expansion of SSS-III-specific clones of B cells as well as the expression of amplifier T cell activity; the latter causes B cells to proliferate further in response to SSS-III.     

A requirement for helper T cells in the induction of delayed-type hypersensitivity

This paper describes a model system for studying the role of helper T cells in the induction of delayed-type hypersensitivity (DTH). Cyclophosphamide- (CP) treated mice sensitized with antigen 3 days later develop high levels of delayed-type immunity; however, DTH cannot be demonstrated in mice that are sensitized with antigen 1 day after drug treatment. The inability to respond to antigen 1 day after CP treatment can be restored if either normal or low-dose primed spleen cells are transferred at the time of sensitization. Although irradiated (1500 rad) normal spleen cells are unable to restore DTH, such treatment has no effect on the primed spleen cell population. The lymphocytes responsible for restoring the DTH response were identified as T cells, in that treatment with anti-Thy-1.2 serum and C abrogated their effect. Furthermore, restoration of the DTH response was dependent on the presence of antigen at the time of lymphocyte transfer; irradiated primed cells could not transfer DTH alone. The DTH effector cells in reconstituted mice were identified as originating from the host and not from the transferred cell population. This was accomplished by using anti-H-2 serum to identify the source of the DTH effector cells after transferring parental (H-2b) irradiated primed spleen cells into CP-treated F1 mice (H-2b,k). Thus, the irradiated transferred cells are behaving as helper T cells and promoting the development of DTH effector cells in the host.     

The role of hapten-reactive T lymphocytes in the induction of autoimmunity in mice. I. Establishment of the experimental conditions for the termination of immunological tolerance to human gamma globulin.

In order to study the role of hapten-reactive helper T cells in the induction of autoimmunity in mice, an attempt was made to establish an experimental model for the development of hapten-reactive helper T cells and the termination of immunological tolerance against heterologous proteins. Spleen cells taken from mice which were immunized with hapten-isologous protein conjugates (PAB-MGG) demonstrated helper activity for the anti-DNP antibody response of DNP-primed B cells responding to DNP and PAB-conjugated protein, but spleen cells from hapten-heterologous protein conjugate (PAB-HGG)-primed mice could not respond to PAB-determinant. Thus, hapten-reactive helper T cells can develop in mice by the immunization with hapten-isologous protein conjugate, but not with hapten-heterologous protein conjugate. However, spleen cells from mice which had been rendered tolerant by treatment with 2.5 or 0.2 mg of DHGG and then immunized with PAB-HGG could demonstrate helper activity responding to PAB-determinant. This helper activity was PAB-specific, because these spleen cells did not demonstrate helper activity if PAB-determinant was omitted in the primary and the secondary antigen. This helper activity was abrogated by the treatment of spleen cells with anti-θ serum and complement. Thus, hapten-reactive helper T cells were successfully induced by the challenge with hapten-heterologous protein conjugate in carrier-protein tolerant mice. When mice were treated with 2.5 or 0.2 mg of DHGG, no anti-HGG antibody response was induced by the challenge with HGG or PAB-HGG. However, the termination of HGG-tolerance was demonstrated only when the mice were preimmunized with PAB-MGG to raise PAB-rcactive helper T cells, treated with 0.2 mg of DHGG, and then challenged with PAB-HGG. This termination of immunological tolerance was not observed when the mice were preimmunized with PAB-BαA to raise PAB-specific B cells and anti-PAB antibody, or when the mice were treated with 2.5 mg of DHGG. Thus, if HGG-specific B cells remain intact in mice such as treated with low dose of DHGG, these B cells can be activated by some bypass mechanisms in the presence of PAB-reactive helper T cells through the PAB-determinant even in the absence of HGG-reactive helper T cells. These data clearly showed the role of hapten-reactive helper T cells in the termination of immunological tolerance and provide experimental supports to the hypothesis on the termination mechanism proposed by Weigle. The cellular mechanism for the development of hapten-reactive helper T cells in tolerant animals and the cellular mechanism of autoantibody production were discussed on the basis of T-B cell collaboration.     

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.     

Tolerance induction in antigen-specific helper T cell clones and lines in vitro

The induction of T cell tolerance in vitro was investigated by using HGG-specific murine helper T cell (Th) clones and cell lines. It was found that exposure of Th to monomeric HGG (tolerogen) for 18 hr rendered the Th unable to reconstitute the PFC response of HGG-primed B cells. The tolerant state was not a result of Th cell death, as up to 100% of Th could be recovered after exposure to the monomer, and in addition, the recovered cells proliferated in response to IL2. B cells were shown not to be significantly affected by the presence of monomeric HGG in amounts calculated to be carried over from the tolerization cultures into the assay cultures. Consequently, it was concluded that interaction between Th and monomeric HGG induced unresponsiveness at the T cell level. A comparison of the tolerogenic potential of monomeric, soluble, and aggregated HGG revealed that only the monomer could induce tolerance in Th. Monomeric HGG was also shown to induce tolerance in an antigen-specific manner. Th reactive to HGG could be tolerized by monomeric HGG, but not Th reactive to FGG or OVA. Helper function of Th was also shown to be antigen specific in that HGG-reactive Th helped only HGG-primed B cells. Certain HGG-specific Th clones were found to be refractory to tolerization with monomeric HGG, whereas other clones derived from the same uncloned cell line were tolerizable.     

Immunologic tolerance to HGG in mice. I. Suppression of the HGG response in normal mice with spleen cells or a spleen cell lysate from tolerant mice.

Adoptive transfer of spleen cells or spleen cell lysates from mice tolerant to human-gamma-globulin (HGG) specifically suppressed the response of normal syngeneic recipients to HGG. The suppressive activity could be transferred for over 100 days after tolerance induction. The suppression induced by both spleen cells and spleen cell lysate was found to be specific as evidenced by a normal response to a challenge with turkey-gamma-globulin or goat erythrocytes. The activity of the suppressive lysate could be removed by passing the material through an HGG immunoadsorbent column but not by passing it through an anti-HGG column or a BSA column. These results indicated that the factor had antigen specificity and was probably not antigen-antibody complexes. That this suppression was not due to a shifting of the kinetics of the antibody response has also been demonstrated. The antigen-specific suppressor factor in the tolerant spleen cell lysates was a protein with a m.w. of approximately 45,000 daltons. The kinetics of the appearance of both suppressor cells and suppressor factor were consistent with a mechanism of active suppression functioning in the maintenance of tolerance to HGG.     

Effect of cyclophosphamide on suppressor cell activity in mice unresponsive to EAE.

Protection against experimental allergic encephalomyelitis (EAE) was induced in susceptible mice of (SJL/J X BALB/c)F1 hybrid, by injection of either mouse spinal cord homogenate, the small mouse basic protein, or Cop 1 in incomplete Freund's adjuvant, before EAE induction. It was demonstrated that the unresponsiveness induced by the three antigens is mediated by suppressor T cells residing in the spleen cell population and can be adoptively transferred to normal syngeneic recipients. Low dose of cyclophosphamide (20 mg/kg) administered 2 days before the encephalitogenic challenge abrogated the unresponsiveness to EAE and reverted the protected mice sensitive to disease induction. Cyclophosphamide was also active on adoptively transferred unresponsiveness, thus donors that had been treated with cyclophosphamide were unable to further transfer unresponsiveness to EAE. These results indicate the elimination by cyclophosphamide of suppressor cells that interfere with the effector mechanisms leading to EAE.     

Neonatally induced tolerance to HGG: duration in B cells and absence of specific suppressor cells.

A specific, long lasting, tolerant state to human gamma-globulin (HCG) was established in neonatal A/J mice. These suckling mice received the tolerogen in the colostrum of their mother who had been injected with DHGG. The tolerant state could not be accounted for by "factors" other than HGG in the colostrum. The duration of this tolerance in the intact animal and in the B cell population was 16 to 18 weeks. Naturally occuring nonspecific suppressor cells were evident but specific suppressor cells could not be demonstrated. These results are discussed in relation to possible mechanisms of the induction of tolerance to self.