Specific neonatally induced tolerance to Mls locus determinants

Neonatal injection of CBA/HT6T6 (H-2k, Mlsb) mice with adult, Mls-incompatible (CBA/J [H-2k, Mlsd] X CBA/HT6T6)F1 spleen cells results in the abrogation of cell proliferation and interleukin 2 (IL 2) production in bulk mixed lymphocyte cultures, when spleen cells from the inoculated mice are tested at 6 to 8 wk of age with stimulator cells expressing the Mlsd of the tolerizing inoculum. In limiting dilution assays, this tolerant state was manifested in a 25- to 550-fold (280-fold average) decrease in the frequency of precursors of Mlsd-responsive IL 2-producing T cells. Tolerance was specific in that the frequencies of precursors of IL 2-producing cells responding to Con A, allogeneic H-2d, and self-Ia were not affected. The observed low frequency of Mls-responsive cells was due neither to extensive chimerism resulting in the dilution of Mlsd-responsive cells by the nonresponsive F1 cells of the inoculum, nor to the action of suppressor cells. These findings indicate that neonatal injection of Mls-incompatible spleen cells produces a state of specific tolerance by a clonal deletion or inactivation mechanism. This specific tolerance supports the view that 1) the Mls locus encodes or regulates the expression of defined alloantigenic determinants and 2) Mls-incompatible responder mice have specific receptors for Mls determinants on clonally distributed IL 2-producing responder T cells.     

Transient T and B cell activation after neonatal induction of tolerance to MHC class II or Mls alloantigens.

The neonatal injection of semiallogeneic F1 spleen cells into newborn parental mice results in the induction of tolerance to the corresponding alloantigen (alloAg) and chimerism. In these F1 cell-injected mice, we have previously observed that this state of specific tolerance is associated with the development of a transient lupus-like autoimmune syndrome. In this study, we show that neonatal injection of mice with spleen cells differing from the host at major histocompatibility complex (MHC) class I, class II, class (I + II), or minor lymphocyte stimulating (Mls) alloAg induced a state of specific tolerance characterized by the absence of alloreactive CTL and/or Th cell responses in the spleen and the thymus of 6- to 12-week-old injected mice. However, in mice rendered tolerant to MHC class II or class (I + II) alloAg, the presence of high levels of IgG1 antibodies, of circulating immune complexes, of anti-ssDNA autoantibodies, and of tissue lesions were transiently observed. In these mice, an increased Ia Ag expression on lymphoid spleen cells was also detected at 1 wk. The elevated production of IgG1 and the overexpression of Ia Ag were almost completely prevented by treatment with an anti-IL-4 mAb. Such manifestations of B cell activation and autoimmunity were not observed in mice neonatally injected with F1 cells differing from the host only at MHC class I Ag. In mice neonatally tolerized to Mls Ag, a transient increase in IgG2a production and an overexpression of Ia Ag were detected without features of autoimmunity, and were prevented by anti-INF-gamma mAb treatment. In mice rendered tolerant to MHC class II, class (I + II), or Mls alloAg at birth, the manifestations of B cell activation were associated with the presence of in vivo-activated alloreactive CD4+ T cells in the spleen--but not the thymus--of 1-wk-old injected mice. Together, these results suggest that in mice neonatally injected with semiallogeneic F1 cells, the process of tolerance induction is not efficient during the early postnatal period, and could allow the maturation and peripheralization of some alloreactive CD4+ T cells, leading to transient B cell activation and, depending on the alloAg, to autoimmunity.     

Neonatal tolerance induction in the thymus to MHC-class II-associated antigens. II. Significance of MHC antigens in anti-Mls tolerance

Specificity of anti-Mlsa tolerance induced in BALB/c (H-2d, Mlsb) neonates was investigated by a popliteal lymph node (PLN)-swelling assay for the local graft-versus-host (GVH) reaction by injecting tolerant thymus cells into the footpads of several types of F1 hybrid mice. When thymus cells were obtained from 1-week-old normal BALB/c, they evoked enlargement of PLNs of (BALB/c X DBA/2)F1 (H-2d, Mlsb/a) [CDF1] recipients and of other hybrid recipients, heterozygous in Mlsa,c,d alleles, irrespective of the major histocompatibility complex (MHC) haplotypes. The same thymus cells did not cause the response in MHC-heterozygous F1 hybrids when the hybrids were homozygous in Mlsb, identical with BALB/c mice. Therefore, the PLN response to Mls antigens, known to be closely associated with MHC-class II antigens, was not directed to the class II antigens themselves. This enabled us to examine the effects of MHC on tolerance induction to the Mls antigens. When BALB/c neonates were injected with CDF1 bone marrow cells, complete tolerance to Mlsa-H-2d antigens of CDF1 cells was induced in the thymus, while responsiveness to Mlsa antigens in the context of H-2k and H-2b antigens, was not affected. This indicates MHC-restriction of neonatal tolerance to Mls antigens. Furthermore, when Mls and H-2-heterozygous (BALB/c X AKR)F1 (H-2d/k, Mlsb/a) bone marrow cells served as the tolerogen, thymus cells of BALB/c neonates were also tolerized to Mlsa-H-2k antigens as well as to Mlsa-H-2d antigens, which suggests the involvement of MHC, probably class II antigens of tolerance-inducing cells.     

Neonatal tolerance induction in the thymus to MHC-class II-associated antigens. I. Preferential induction of tolerance to Mls antigens and resistance to allo-MHC antigens

Neonatal tolerance inducibility of self-major histocompatibility complex (MHC)-class II-associated antigens was compared with that of allo-class II antigens. BALB/c (H-2d, Mlsb) mice, less than 24 hr after birth, were intravenously injected with bone marrow cells of either (BALB/c X DBA/2)F1 (H-2d, Mlsb/a, semiallogeneic at the Mls locus) or (BALB/c X B10.BR)F1 (H-2d/k, Mlsb; semiallogeneic at the MHC), as antigens. The mice were tested for in vivo immune activity of class II-reactive T cells by means of the popliteal lymph node-swelling assay. They developed tolerance, irrespective of type of antigens, showing profoundly suppressed host-versus-graft reaction, and those tolerized to the allo-MHC antigens accepted skin grafts of the corresponding allogeneic mice. In the thymus and spleen of the Mls-tolerant mice, antigen-specific class II-reactive T-cell activity was completely abolished, without the apparent involvement of suppressor cells. In contrast, the activity in allo-MHC-tolerant mice was not reduced in either thymus or peripheral lymphoid organs, suggesting that systemic hyporesponsiveness is attributable to reversible suppression of immune competent cells. The resistance for cell-level tolerance induction to allo-class II antigens may not be ascribed to the active participation of allo-MHC antigens in prevention of or in escape from tolerance induction or both, since an injection of bone marrow cells of both Mls and H-2-semiallogeneic (DBA/2 X B10.BR)F1 (H-2d/k, Mlsa/b) mice could induce tolerance to Mlsa-H-2d antigens in newborn thymus cells.     

Activation requirements of cloned inducer T cells. III. Need for two stimulator cells in the response of a cloned line to Mls determinants

To gain insight into the nature of Mls determinants, we examined the stimulator cells responsible for the activation of inducer T cell clones by Mls determinants. Two types of clones responding to Mls determinants were identified. One type responded to purified B cells, but not to splenic adherent cells (SAC), from mice bearing Mls stimulatory determinants. The other type of Mls-reactive T cell clone, including the representative clone Ly1-N5, demonstrated a vigorous response to unfractionated spleen cells, but showed little or no response to B cells alone or to SAC alone from mice bearing the Mlsa or Mlsd stimulatory determinant. The response of these clones to Mls determinants required stimulation by two cell types. The failure of clone Ly1-N5 to respond to Mlsa-bearing B cells was reversed by the addition of SAC taken from mice bearing the Mlsa allele. In addition, SAC from mice bearing the nonstimulatory Mlsb allele could synergize with B cells from Mlsa-bearing animals. B cells were required to provide the Mlsa determinant, because the combination of Mlsa-bearing SAC and Mlsb-bearing B cells did not activate the clone. The response of clone Ly1-N5 to Mls is restricted by Ia determinants (shared by H-2b, H-2d, and H-2k haplotypes but not by the H-2q haplotype). The permissive H-2 alleles can be present either on the stimulator B cell or on the SAC. The optimal response of the clone was obtained by using B cells bearing Mlsa and the permissive Ia epitopes. However, a significant response of the clone to B cells bearing Mlsa but an inappropriate Ia (Iaq) was also seen in the presence of SAC bearing the nonstimulatory Mlsb allele but the permissive Ia epitopes.     

Neonatal tolerance induction to Mlsa. I. Tolerance to Mlsa is restricted by shared MHC determinants

In this paper we have examined the influence of MHC (major histocompatibility complex) on neonatal tolerance to Mlsa (minor lymphocyte stimulating). By employing a novel approach we have shown that tolerance to Mlsa is restricted by shared MHC determinants. Thus, neonatal Mlsb mice, injected at birth with spleen cells from Mlsa mice, were tested as adults for Mlsa specific responses by interleukin-2 limiting dilution analysis, a technique which allows us to discriminate between responses to MHC + Mlsa and to MHC alone. Tolerance to Mlsa was in the context of any MHC type examined--donor, host, and third-party MHC products. These results show that tolerance to Mlsa is restricted by shared MHC determinants and extend previous studies indicating that activation of Mlsa responses is similarly restricted.     

Recognition and response to alloantigens in vivo. I. Negative and positive selection of MLR reactivity in murine peripheral blood lymphocytes to major histocompatibility complex and Mls antigens

Specific mixed lymphocyte reaction (MLR) responsiveness to allogeneic major histocompatibility complex (MHC), or minor lymphocyte-stimulating (Mls) determinants, was depleted in the peripheral blood lymphocytes (PBL) obtained from mice 24 to 48 hr after i.v. injection of 5 to 7.5 X 10(7) MHC or Mlsa-incompatible spleen cells, respectively. Results of cell mixture experiments suggest that the generation of suppressor cells was not the explanation for this specific reduction in MLR proliferation occurring with these PBL responder cells. To gain additional insight into parameters involved in the recognition of allodeterminants in vivo, experimental manipulations of the host environment and donor cell inoculum utilized in the negative selection procedure were employed. For example, removal of the spleen in the recipient animal, an anatomic site in which injected allogeneic cells and corresponding host antigen-reactive cells (ARC) are trapped, still permitted the specific depletion in murine PBL of host ARC for donor foreign MHC antigens. This finding may implicate other sites such as the liver where unprimed host alloreactive clones are trapped. In addition, irradiation of allogeneic donor cells significantly reduced their capacity to trap alloreactive T cell clones in vivo, whereas heat treatment of the donor cells completely eliminated this ability, even though the Ia determinants were still expressed, measured by flow cytometry. After the negative selection period, kinetic analysis of proliferation showed that 3, 4, or 5 days after injection of MHC-incompatible allogeneic spleen cells, the PBL of the recipient showed specific hyperresponsiveness to the MHC-haplotype of the donor cells. Interestingly, these primed PBL responder cells had the volume distribution of small resting cells; thoracic duct lymphocytes (TDL), positively selected by adoptive transfer of T cells to irradiated semiallogeneic recipients, are reported to be mainly blast cells. In contrast to the MLR hyperresponsiveness that results from priming with MHC-incompatible splenocytes, PBL, obtained at these later time points from mice primed with Mlsa-incompatible, H-2-compatible splenocytes, showed complete unresponsiveness in MLR to these Mlsa-bearing stimulator cells, as well as some nonspecific reduction in proliferation to MHC-incompatible stimulator cells regardless of their Mls genotype.(ABSTRACT TRUNCATED AT 400 WORDS)     

Neonatal tolerance induction in the thymus to MHC-class II-associated antigens. IV. Significance of intrathymic chimerism of blood-born Ia+ cells in Mls tolerance.

The significance of thymus cell chimerism in the induction and maintenance of tolerance was investigated. Mls-1b BALB/c mice were neonatally tolerized by the intravenous administration of either bone marrow (BM) cells or peritoneal cavity (PerC) cells from Mls-1b/a (BALB/c x AKR) F1 mice. Tolerance was long-lasting in the BM cell group, but transient in the PerC cell group, probably because PerC cells lack hemopoietic stem cells required for a continuous supply of tolerance-inducing cells. The degree of anti-Mls-1a responsiveness of these BALB/c thymus cells was correlated with the degree of intrathymic distribution of the inoculated F1 cells. The effect of BM cell inoculation, resulting in a year-long deletion of Mls-1a-reactive V beta 6-bearing T cells is in marked contrast to that of PerC cell inoculation which causes only a transient loss of V beta 6+ mature thymocytes (for about 1 week after birth). This functional profile of the tolerant state correlates well with the degree and persistence of the intrathymic presence of F1 type Ia+ cells. The long-lasting presence of donor-derived cells throughout the thymus tissue in the BM cell group is also in marked contrast to the early disappearance of Ia+ cells (within 2-3 weeks) from the cortex and then from the medulla in the PerC cell group, although these Ia+ cells were once spread throughout the thymus tissue 4 days after the tolerance-inducing cell inoculation. Taken together with a failure to induce consistent unresponsiveness to Mls-1a determinants in Mls-1b thymocytes regenerating in Mls-1a-thymic epithelial environments, all the above data indicate that intrathymic chimerism caused by hemopoietic stem cell-derived MHC-class II-bearing cells is a requisite for the induction and maintenance of unresponsiveness by means of clonal deletion in experimentally as well as naturally induced tolerance to Mls determinants.     

Induction of tolerance against the Mls antigen in mice no need for Mls-bearing cells

Infusion of CBA mice with spleen cells from the H-2-compatible, but Mis antigen-incompatible, strain C3H leads to a specific reduction of the MLC reactivity of the host's lymphocytes. One explanation of the reduced reactivity could be that the specifically Mls antigen-responsive CBA T cells become exhausted by intense antigen stimulation or that the infused cells actively neutralize specifically responsive cells. In this investigation, we have shown that depletion of membrane Ig-positive cells from C3H × CBA spleen cell preparations strongly reduces their capacity to stimulate CBA lymphocytes in the MLC, indicating that the Mls antigen is expressed on B but not on T cells. However, such B-cell depleted cell preparations were fully capable of reducing the MLC response of CBA hosts. Cell preparations of spleen and lymph nodes exhibited high stimulatory and inhibitory effects. Thymic cells lacked both these characteristics, whereas bone marrow cells were weak stimulators but relatively strong inhibitors. The results support the proposal that the observed reduction of MLC reactivity is due to an active process of the injected cells. The cell type which is working as an inhibitor has not been clearly defined yet.     

Genetic analysis of the Mls system. Formal Mls typing of the commonly used inbred strains

In order to elucidate the biological role of minor lymphocyte stimulating (Mls) gene products, we have been investigating the fundamental immunogenetic characteristics of the Mls system. In this report, describe the distribution of stimulatory Mls products, Mls^a and Mls^c, in a panel of laboratory inbred strains based on the response pattern of H-2-compatible naive T-cell populations as well as monospecific Mls^a- or Mls^c-reactive T-cell clones. In addition, the expression of four different T-cell receptor (Tcr) b-V segment Tcrb-V3, –V6, –V8.1, and –V9, which were recently reported to be associated with T-cell recognition of Mls gene products in these strains, was examined. The results indicate that the majority of commonly used laboratory strains including those originally typed as Mls ^aare also expressing Mls^c determinants and that very few independent inbred strains are non-Mls ^c. Moreover, the pattern of Tcrb-V expression in spleen as well as in thymus suggests that the association between Mls expression and clonal deletion of self Mls-reactive T cells appears to be the general rule in inbred strains. Based on these results, implications for the nondetectable Mls-like gene products in other species besides the mouse are discussed.     

T cell responses to Mls determinants are restricted by cross-reactive MHC determinants

The studies presented here investigated the relationship between T cell recognition of MHC-encoded products and non-MHC-linked Mls determinants. The first aspect addressed whether Mls-reactive T cells recognize Mls-encoded products alone or in association with MHC-encoded determinants. Initial studies used Mlsa-specific T cell clones that were generated by repeated stimulation of C57BL/6 or B10.A(5R) spleen cells with DBA/2 lymphoid cells. These clones recognized Mlsa on cells expressing MHC products of the H-2b, H-2d, and H-2k haplotypes, but not the H-2q haplotype. Thus, these cloned T cells were found to recognize Mlsa products in association with public but demonstrably polymorphic H-2 determinants. The question of whether T cell clones that were specific for self-H-2 determinants (autoreactive) or soluble antigen plus syngeneic H-2 (antigen-specific) could also be stimulated by Mlsa determinants was also addressed. A substantial proportion of the antigen-specific or autoreactive T cell clones tested were stimulated by Mlsa determinants. Furthermore, stimulation of these clones by Mlsa was H-2 restricted. The pattern of H-2-restricted recognition of Mlsa by these clones was not distinguishable from that observed in the Mlsa-specific T cell clones, nor was it influenced by the primary specificity or H-2 restriction pattern of a given clone. Although these findings provide a means of explaining the observation that Mls-reactive T cells exist at extremely high precursor frequencies, they also raise questions regarding the nature of the receptor structures which are used by a single T cell in the recognition of two or more apparently distinct stimuli.     

T cell lines with dual specificity for strong Mls and H-2 determinants

To examine the relationship of T cell specificity for Mls vs H-2 determinants, BALB/c (H-2d,Mlsb)(d,b) T cells were stimulated repeatedly in vitro with H-2-compatible, Mls-incompatible DBA/2(d,a) stimulators. This line of T cells gave strong mixed-lymphocyte reactions to the priming Mlsa determinants but, in addition, gave appreciable responses to various foreign H-2 determinants. When this T cell line was subsequently stimulated over a period of 2 mo with Mlsa-negative cells of a particular foreign H-2 haplotype, e.g., H-2k, the cells gave high responses to H-2k determinants but only very low responses to third-party H-2 determinants. Significantly, the cells retained high reactivity for Mlsa determinants. In other experiments, BALB/c T cells positively selected to Mlsa,d-negative H-2-incompatible stimulator cells retained high reactivity for Mlsa determinants. The implications of these findings are discussed.     

The expression of Mls c determinants on Mls a,Mls b,and Mls x prototypic strains

In the mouse sytem, specific determinants other than major histocompatibility complex (MHC) gene products are capable of inducing strong primary proliferative responses in naive T cells. These determinants are encoded by at least two gene loci designated as minor lymphocyte stimulatory (Mls) loci. In order to elucidate the biological role of the Mls system, an effort has been initiated to clarify the fundamental immunogenetic characteristics of the Mls system. In this report, we describe the unexpected finding that Mls ^c determinants are expressed on splenocytes of strains including those which have been used as prototypic examples of three other Mls types: Mls ^a (DBA/2, DBA/1), Mls ^b , (BALB/c), and Mls ^x (PL/J). The expression of Mls ^c by these strains was demonstrated both by the response patterns of unprimed T cells from MHC-identical inbred or F₁ hybrid strains and by the responses of a panel of Mls-specific T-cell clones. The experimental results reported here also suggest that the expression of Mls determinants may be influenced by multiple other genes, including MHC-linked genes.Abbreviations used in this paper MHC major histocompatibility complex - MLR mixed lymphocyte reaction - Mls minor lymphocyte stimulating locus antigen - MMC mitomycin C - NNT nylon wool nonadherent T cells     

T cell recognition of Mls. T cell clones demonstrate polymorphism between Mlsa, Mlsc, and Mlsd

The determinants encoded by the minor lymphocyte stimulating locus (Mls) are defined as determinants that induce strong T cell proliferative responses in primary mixed lymphocyte reactions. Although the Mls locus was originally described as having four alleles, a, b, c, and d, a number of recent observations have led several investigators to challenge the idea that Mls is truly a polymorphic system. To better define this system of determinants recognized at high frequency by T cells, the present studies were undertaken to evaluate the polymorphism of Mls products. In the present study, the in vitro proliferative responses of Mlsa- and Mlsc-specific T cell clones were employed to analyze Mls products. The identification of determinants recognized by Mlsa- and Mlsc-reactive clones was established by the pattern of responses to stimulators derived from congenic strains, recombinant inbred strains, and backcross mice. T cell clones and unprimed T cells gave concordant responses that confirmed the Mlsa or Mlsc specificity of the cloned populations. With the use of these two sets of Mls-specific T cell clones, the existence or absence of polymorphism of Mls-encoded gene products was examined. It was found that Mlsa-specific cloned T cells responded to Mlsa but not Mlsc stimulators, whereas Mlsc-specific clones responded to Mlsc but not Mlsa. This reciprocal pattern of specificity indicates that the Mls system as currently defined is therefore truly polymorphic. In addition, it was observed that both Mlsa- and Mlsc-specific clones were stimulated by Mlsd stimulators. In particular, the possibility that Mlsa and Mlsc are not alleles but products of different loci and that Mlsd strains are those that express both Mlsa and Mlsc is considered.     

Bidirectionality of mixed lymphocyte stimulation (Mls) response. Effects of Mlsb stimulator cells on Mlsa helper cells

The activation of BALB/c lymphocytes in the mixed lymphocyte reaction to Mls-disparate APC has been shown to encompass up to 20% of the mature resting helper T lymphocyte population. In addition to these overtly Mls-responsive cells, our studies have revealed a second population that respond to the Mls difference of DBA/2 spleen cells in conjunction with the mitogen Con A. This part of the Mls response is therefore latent. As mitogen and Mls-stimulating effect act in synergy, it is likely that both stimuli act on the same cell, and hence the Mls effect can be regarded as a regulatory interaction between APC and Th cell. By use of congenic BALB.Mlsa mice, the regulatory effect has been mapped to the Mls locus. The regulatory influence has also been demonstrated in DBA/2 Th cells (Mlsa) stimulated simultaneously with mitogen and Mls-disparate (Mlsb) APC, consistently causing inhibition of mitogen-induced proliferation in this reverse Mls direction. This antagonistic effect has also been linked to the Mls locus. We conclude that the Mls reaction governed by the a and b alleles is bidirectional, producing synergy with class II-dependent activation signals in the direction of Mlsa----Mlsb, and antagonism in the direction Mlsb----Mlsa. Both the classical Mls and the reverse Mls effects have been demonstrated at the clonal level. These results are in accord with the previously proposed hypothesis that the Mls molecule serves as a down-regulatory stimulus in the activation of Th cells. Mls responses of Mlsb T cells are explained as the consequence of a diminished down-regulation by Mlsa APC. Conversely, the reverse Mls response described here can be considered a consequence of inordinately high down-regulation of the Mlsa T cell responses by Mlsb APC.     

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.     

Immunologic effects of whole-body ultraviolet (uv) irradiation. III Defective splenic adherent cell function in alloantigen-stimulated T-cell proliferation

The daily exposure of a mouse to ultraviolet (uv) radiation causes a selective depletion of Ia-bearing adherent cells in that animal's spleen. This depletion manifests itself in functional deficiencies in the presentation of protein antigens and haptens to T cells. The present studies demonstrate a defect in splenic adherent cells (SAC) from uv-irradiated mice resulting in defective alloantigen presentation. We show that unfractionated splenocytes and SAC from uv-irradiated mice show decreased stimulatory activity in allogeneic MLR. We then utilize this phenomenon induced by uv radiation to characterize the stimulator cell in the M locus (Mls) determinant-driven MLR. We show that the stimulator cell in Mls determinant-driven MLR is an adherent cell and demonstrate that this stimulator cell bears Ia determinants by showing that whole spleen cells and SAC from mice treated with uv radiation are inefficient stimulators of the Mls determinant-driven MLR. The importance of the Ia determinant on the stimulator cells in Mls determinant-driven MLR is corroborated by the demonstration that a monoclonal antibody directed at this determinant fully blocks the Mls determinant-driven MLR. The significance of these studies to the problem of alloreactions in vivo is discussed.     

A new mouse cell-surface antigen (Ly-m20) controlled by a gene linked to Mls locus and defined by monoclonal antibodies

Five monoclonal antibodies were established by the fusion of mouse myeloma cells (NS.1) with spleen cells from A and (A x C3H/An)F₁ mice hyperimmunized with 70Z/3 tumor cells. These antibodies recognized a new antigenic specificity provisionally called Ly-m20.2. In direct cytotoxicity assays, 60 percent of cells in spleen, 40 percent in lymph node, 50 percent in bone marrow and less than 5 percent in thymus were found to react with three of the five antibodies, whereas the two others yielded somewhat lower cytotoxicity indices. The Ly-m20.2 antigen was also expressed on cells derived from liver and kidney but not on cells derived from brain. As judged from cytotoxicity assays with separated T and B cells, Ly-m20.2 antigen is carried preferentially on B lymphocytes. Direct plaque-forming cells (PFC) were completely eliminated by Ly-m20.2-specific antibody and complement. Linkage tests by analysis in 20 (CBA/J x C3H/An) x C3H/An backcross mice and by segregation analysis of BXH and SWXL recombinant inbred strains indicate close association of the loci controlling Ly-m20.2 and Mls antigens on chromosome 1.Abbreviations used in this paper MLR mixed lymphocyte reaction - MHC major histocompatibility complex - Mls minor lymphocyte-stimulating antigen - Ia I-region associated - PFC plaque-forming cell - SRBC sheep red blood cell - Con A concanavalin A - LPS lipopolysaccharide - GVH graft-versus-host - HVG host-versus-graft - CML cell-mediated lympholysis - LD lymph ocyte-defined - SD serologically defined The prefix m (monoclonal) is used following a suggestion by Klein and co-workers (1979).     

Tolerance to host minor histocompatibility antigens after allogenic bone marrow transplantation. Specific donor-host unresponsiveness is maintained by peripheral tolerizing cells.

The development of graft-host tolerance after allogeneic bone marrow (BM) transplantation is more demanding than the acquisition of self-tolerance because both donor-derived mature T cells and immature thymocytes encounter host Ag. The mechanism involved in tolerization of mature T cells, contained in unmanipulated BM, remains undefined. In previous experiments, we showed in vivo unresponsiveness to host minor histocompatibility Ag (MiHA) in immunocompetent chimeras obtained after MiHA-incompatible BM transplantation. In this study, we wanted to determine: first, what was the specificity of this graft-host unresponsiveness, and second, whether peripheral cells were involved in tolerization? LP recipients were irradiated (9, 5 Gy), injected with 10(7) undepleted BM cells from B10 donors and studied 100 to 150 days later. (B10-->LP) chimeras were immunized in vivo and restimulated in vitro with cells displaying one or multiple incompatible MiHA. In bulk culture experiments, chimeras demonstrated specific CTL unresponsiveness to host MiHA but responded normally to third party MiHA. In limiting dilution analysis conditions, chimeras showed a profound deficit, but not a complete absence of anti-host CTL precursor. Studies with congenic stimulators/targets showed that graft-host tolerance was induced against both immunodominant (e.g., H-3.2) and nonimmunodominant (e.g., H-8.2) MiHA although at the CTL precursor level, it was more complete against the former. Furthermore, chimera spleen cells inhibited the generation of CTL activity against host- and donor-type MiHA but not against third party Ag. This specific suppressor activity was not T cell dependent, and was mediated by radiosensitive cells that are not found in freshly explanted organs from normal mice. Taken together, our results suggest that peripheral tolerization can be a remarkably efficient process to maintain tolerance to MiHA after BM transplantation. Thus, peripheral tolerizing mechanisms may contribute not only to the induction of tolerance to Mls superantigens or to the product of transgenes (if expressed at high levels) but also to a wide array of MiHA.