Suppressor T cell recognition of major and minor histocompatibility alloantigens: selected suppression of MHC-directed responses by minor alloantigen Ts

The induction of suppression by i.v. administered alloantigens in the murine host was analyzed as a model of the possible effects of blood transfusion on transplant survival. The results indicated that suppressor T cells (Ts) specific for minor histocompatibility alloantigens could be readily induced by the i.v. presentation of minor alloantigen-disparate spleen cells. In contrast, similar priming with cells differing solely at the H-2 major histocompatibility complex stimulated only positive T cell immunity, with no evidence of suppression. The induction of H-2 directed Ts activity could be accomplished only by i.v. priming with major plus minor incompatible donor cells, suggesting that suppressor cell recognition of minor alloantigens may have facilitated the generation of Ts against H-2-encoded major transplantation antigens. A role for minor histocompatibility antigens in the regulation of H-2-specific immunity at the effector level was also indicated. Ts induced by i.v. pretreatment with minor antigen-disparate donor cells not only suppressed the delayed-type hypersensitivity (DTH) response to the relevant minor alloantigens, but also inhibited DTH against unrelated H-2 alloantigens introduced during subsequent intradermal immunization. Suppression of H-2-directed T cell reactivity was specific in that the presence of the Ts-inducing minor alloantigens was also required and occurred only when the minor and unrelated major alloantigens were presented within the same inoculum, if not on the same cell surface. The capacity of Lyt-2+Ts or Ts-derived suppressive factors specific for one set of cell surface molecules to modulate responses to an unrelated group of surface antigens does not appear to represent a general phenomenon, because similar suppression of immunity to unrelated tumor-specific transplantation antigens by minor-specific Ts was not observed. These results are discussed with respect to the possible mechanism of H-2-directed suppression and the role of the I region in Ts recognition of antigen.     

Antigen-specific T cell-mediated suppression. II. In vitro induction by I-J-coded L-glutamic acid50-L-tyrosine50 (GT)-specific T cell suppressor factor (GT-T8F) of suppressor T cells (T82) bearing distinct I-J determinants.

The induction of new suppressor T cells (Ts2) by suppressive extracts (TsF) from L-glutamic acid50L-tyrosine50 (GT) nonresponder mice was examined. Incubation of normal spleen cells with allogeneic GT-TsF for 2 days in vitro led to the generation of Ts2 cells able to suppress subsequent responses to the immunogen GT-methylated bovine serum albumin (GT-MBSA) in vivo. This induction occurred efficiently when TsF donor and target cells differed at all of H-2, including the I-J subregion. B10.BR (H-2k) GT-TsF, adsorbed on, then acid eluted from GT-Sepharose and anti-I-Jk [B10.A (3R) anti-B10.A (5R)]-Sepharose in a sequential fashion could induce BALB/c (H-2d) spleen cells to become Ts2 only if nanogram quantities of GT were added to the purified GT-TsF. This indicates a requirement for a molecule or molecular complex possessing both I-J determinants and antigen (GT)-binding specificity, together with GT itself, for Ts2 induction. The induced Ts2 are I-J+, since their function can be eliminated by treatment with anti-I-Jk plus C. These I-J determinants are coded for by the precursor of the Ts2 and do not represent passively adsorbed, I-J coded TsF, since anti-Ijk antiserum [(3R X DBA/2)F1 anti-5R] which cannot recognize the BALB/c (I-Jd) TsF used for induction still eliminates the activity of induced A/J (I-Jk) Ts2. These data provide further evidence for and information about the minimum of two T cells involved in antigen-specific suppressor T cell systems.     

Functional analysis of cloned macrophage hybridomas. V. Induction of suppressor T cell responses

It has been suggested that macrophage-like accessory cells are involved in suppressor T cell (Ts) induction. To further analyze this issue, we obtained several cloned macrophage hybridoma cell lines by somatic cell fusion of the macrophage tumor P388D1 of DBA/2 (H-2d) origin with splenic adherent cells of CKB mice (H-2k). Several cloned lines displayed the serological and functional characteristics of macrophages. We evaluated the ability of these hybridomas to induce third order or effector Ts (Ts3) to suppress the contact sensitivity response against the hapten 4-hydroxy-3-nitrophenyl acetyl (NP). In contrast to the parental P388D1 and two other macrophage hybridomas, one macrophage hybridoma clone, termed 63, when conjugated with NP, induced Ts3, which suppressed contact sensitivity responses against NP but not DNFB, showing that the Ts3 were antigen specific. Macrophage hybridoma 63 could specifically induce Ts3 activity in either H-2k, H-2d, or H-2k/H-2d heterozygous hosts. Thus, macrophage hybridoma 63 functionally expressed major histocompatibility complex-related restricting determinants, and the fusion with cells from a H-2k macrophage donor caused a functional complementation of H-2d-related, Ts-inducing elements. The genetic restriction governing induction of Ts3 was controlled by genes that mapped to I-J region. Furthermore, NP-conjugated macrophage hybridoma 63 could serve as a target for elicitation of suppressor responses after administration of I-Jk, but not I-Jb, restricted suppressor factor. The data suggest that macrophage hybridomas represent a means to dissect heterogeneity within the macrophage population. The data also imply that the I-J determinants expressed on macrophages represent a ligand for the antigen receptor of Ts.     

I-J restriction of T cells that suppress in vivo antibody responses to Thy-1

The contact-sensitizing haptens dinitrophenyl (DNP) and oxazalone (Ox) act as helper determinants for antibody responses to Thy-1 when conjugated to donor thymus cells. The helper effect is transferrable from primed to naive mice with spleen cells, producing specific augmentation of in vivo PFC responses to Thy-1. The helper cells are hapten-specific and require associative recognition of hapten and Thy-1, excluding a role for nonspecific B cell activation. The phenotype of the helper cells is Thy-1+ and Lyt-1+2-. Antigen-specific suppression could be readily generated by using an inoculum of DNP-modified syngeneic RBC. T cells from these suppressed donors (Ts) were shown to abolish the helper effects of TH in adoptive transfer experiments in vivo. These Ts were characterized as Thy-1+ and Lyt-1-2+. A requirement for MHC compatibility at the I-J subregion was necessary between the Ts and the recipient to obtain a transfer of suppression.     

Antibody inhibition of suppressor cell induction

The IJ genetic restrictions of suppressor T (Ts) cells are controlled by H-2-related determinants that are expressed on antigen-presenting cells. This has led to the hypothesis that Ts cells carry receptors for a self H-2-related ligand that is expressed on specialized antigen-presenting cells. We refer to this H-2-related ligand as the IJ interacting molecule. This report evaluates the ability of rabbit antibodies directed against idiotypes on monoclonal anti-IJ antibodies (the latter are presumably reactive with the Ts cell receptor) to bind IJ interacting molecule and to inhibit antigen presentation to Ts cells. Such anti-idiotypic reagents were prepared against T cell-reactive monoclonal anti-IJk and anti-IJd antibodies. The F(ab')2 fragments of these anti-idiotypic reagents blocked Ts cell induction. The inhibition was haplotype specific and mapped to the IJ region. The anti-idiotypic antibodies blocked the generation of Ts1, Ts2, and Ts3 cells. The cellular target of the blocking activity mediated by these anti-idiotypic antibodies is a macrophage. This was shown by using a cloned macrophage hybridoma line for both Ts induction and absorption of antibody activity. The combined data support the concept that macrophages express IJ interacting determinants that are responsible for Ts cell induction.     

Generation of the alloreactive T cell repertoire: K region homology between H-2b T cell precursors and T cell maturation environment is required for the generation of the Kbm6-specific cytotoxic T cell repertoire

The influence of T cell genotype and T cell maturation environment on the generation of the T cell alloreactive repertoire was evaluated in the H-2b cytotoxic T lymphocyte response to Kb mutant determinants expressed by the strain B6-H-2bm6. Specifically, by constructing radiation bone marrow chimeras with B6 or B10 (H-2b) donor cells and B10.BR, B10.A(4R), B10.MBR, and B6.C-H-2bm1 irradiated mice as recipients, it was possible to investigate the major histocompatibility complex (MHC)-encoded gene products of the host environment required for the generation of a bm6-specific H-2b CTL response. The results of such experiments confirmed the previous finding that the alloreactive T cell repertoire is influenced both by T cell MHC genotype and by the MHC gene products of the T cell maturation environment. In addition, the results of the present study further demonstrated that in the chimeric donor and host genetic combinations used, it was both necessary and sufficient that there be a homology of K region-encoded determinants for the generation of a bm6-specific CTL response. Experiments utilizing a mixed responder population of unresponsive B6----B10.D2 spleen cells and responsive Lyt-2 congenic B6.Lyt-2.1 spleen cell suggested that the cellular defect(s) underlying the unresponsiveness of the chimeric cells to bm6-encoded determinants was at the level of the CTL precursor. Together, these findings indicate that an interaction of the K region-encoded gene products of the T cell and its maturation environment play a critical role in the generation of the CTL repertoire specific for bm6 mutant determinants. We discuss here the possibility that this interaction may reflect a requirement that T cells recognize such mutant allodeterminants in association with self restriction elements present on the same mutant K region-encoded molecule.     

Induction of helper and suppressor T cells by nonoverlapping determinants on the large protein antigen, beta-galactosidase

The fine specificity of the T cell repertoire directed against T helper (Th)-inducing and T suppressor (Ts)-inducing determinants was examined with cyanogen bromide and tryptic peptides of Escherichia coli beta-galactosidase (GZ), a large tetrameric protein (monomer molecular weight = 116 kDa). Immunization with cyanogen bromide fragment 2 [CB-2, amino acids (a.a.) 3-92] induced both specific Th and Ts cells. Study of the induction of these functionally opposite T cell subpopulations with tryptic peptides of CB-2 indicated that Th and Ts were activated by separate, nonoverlapping determinants. Th-inducing activity resided in a nonapeptide, T6 (a.a. 44-52), whereas T4 (a.a. 27-37) induced Ts cells. The presence of distinct helper and suppressor determinants suggests that the specificity repertoire in these T cell subpopulations may differ, perhaps owing to the expression of antigen-recognizing receptors that are coded by unique gene families. Alternatively, antigen presentation structures may be physicochemically quite different, and bind to distinct parts of the peptide antigen.     

Characterization of suppressor T cell clones derived from a mouse tolerized with conjugates of ovalbumin and monomethoxypolyethylene glycol.

The induction of antigen-specific tolerance in mice by conjugates of ovalbumin (OVA) and monomethoxypolyethylene glycol (mPEG) previously had been shown to be associated with the generation of antigen-specific suppressor T (Ts) cells. For the elucidation of the nature of these Ts cells, five nonhybridized OVA-specific Ts cell clones were generated from the spleen cells of a BDF1 mouse which had been immunosuppressed by the tolerogenic conjugate, OVA(mPEG)12. The cloned Ts cells were maintained in vitro by periodic stimulation with OVA and feeder cells and were able to suppress the in vitro antibody production in an OVA-specific and MHC class I (H-2Kd or H-2Dd)-restricted manner. All these Ts cell clones were shown to be Thy1.2+, CD4-, CD5-, CD8+, and to express CD3 and the alpha beta heterodimer of the T cell receptor. The cell-free extracts of these cells contained soluble suppressor factors which could mimic in vitro the suppressive activity of the intact cells. In contrast to cytotoxic T lymphocytes (CTL), none of the cloned Ts cells were endowed with cytolytic activity as revealed in the perforin-mediated microhemolysis and in the 18-hr51Cr release assays. These results demonstrate that (i) OVA-specific Ts cell clones can be generated from mice pretreated with OVA(mPEG)12 by employing conventional T cell culture techniques, and (ii) these Ts cells are functionally different from conventional CD8+ CTL.     

Induction of alloreactive CD4 T cell tolerance in molecular chimeras: a possible role for regulatory T cells

Induction of molecular chimerism following reconstitution of mice with autologous bone marrow cells expressing a retrovirally encoded allogeneic MHC class I Ag results in donor-specific tolerance. To investigate the mechanism by which CD4 T cells that recognize allogeneic MHC class I through the indirect pathway of Ag presentation are rendered tolerant in molecular chimeras, transgenic mice expressing a TCR on CD4 T cells specific for peptides derived from K(b) were used. CD4 T cells expressing the transgenic TCR were detected in mice reconstituted with bone marrow cells transduced with retroviruses carrying the gene encoding H-2K(b), albeit detection was at lower levels than in mice receiving mock-transduced bone marrow. Despite the presence of CD4 T cells expressing an alloreactive TCR, mice receiving H-2K(b)-transduced bone marrow permanently accepted K(b) disparate skin grafts. CD4+CD25+ T cells from mice reconstituted with H-2K(b)-transduced bone marrow prevented rejection of K(b) disparate skin grafts when adoptively transferred into immunodeficient mice along with effector T cells, suggesting that induction of molecular chimerism leads to the generation of donor specific regulatory T cells, which may be involved in preventing alloreactive CD4 T cell responses that lead to rejection.     

Defining the requirements for peptide recognition in gene therapy-induced T cell tolerance

Expression of a retrovirally transduced MHC class I Ag, H-2K(b) (K(b)), in bone marrow-derived cells leads to specific prolongation of K(b) disparate skin grafts. To examine the extent to which peptides derived from K(b) contribute to the induction of tolerance, retroviruses carrying mutant K(b) genes designed to enter separate pathways of Ag presentation were constructed. Thymectomized and CD8 T cell-depleted mice that had been irradiated and reconstituted with bone marrow cells expressing a secreted form of K(b) showed prolongation of K(b) disparate skin graft survival. Skin graft prolongation was not observed when similar experiments were performed using mice that were not CD8 T cell depleted. This suggests that hyporesponsiveness can be induced in CD4 T cells, but not CD8 T cells by Ags presented via the exogenous pathway of Ag processing. Modest prolongation of skin allografts was observed in mice reconstituted with bone marrow cells transduced with retroviruses carrying a gene encoding a mutant K(b) molecule expressed only in the cytoplasm. Prolongation was also observed in similar experiments in mice that were thymectomized and CD4 T cell depleted following complete reconstitution, but not in mice that were reconstituted and then thymectomized and CD8 T cell depleted. Thus, hyporesponsiveness can be induced in a subset of CD8 T cells by recognition of peptides derived from K(b) through both the direct and indirect pathways of Ag recognition, while CD4 T cell hyporesponsiveness to MHC class I disparate grafts occurs only through the indirect pathway of Ag recognition.     

The Dermatophagoides pteronyssinus group 2 allergen contains a universally immunogenic T cell epitope

The use of T cell epitope-containing peptides for the induction of anergy in allergen sensitization is limited by genetic restriction that could be circumvented by using universally immunogenic epitopes. We attempted to identify such epitopes on Dermatophagoides pteronyssinus group 2 allergen (Der p 2), a major allergen of D. pteronyssinus T cells from BALB/c (H-2(d)), C57BL/6 (H-2(b)), C3H (H-2(k)), and SJL (H-2(s)) mice that were immunized with rDer p 2, recognized an immunodominant region encompassing residues 21-35. A synthetic 21-35 peptide (p21-35) induced strong dose-dependent in vitro T cell proliferation with cells of the four mouse strains and required processing for MHC class II presentation. Substitution of Ile(28) with Ala resulted in reduction of T cell proliferation in each strain. Ile(28) could represent an important MHC class II anchoring residue for T cell response to p21-35. An immunodominant T cell epitope of Der p 2 therefore behaves as a universal epitope and could be a suitable candidate for T cell anergy induction.     

Suppressor T cells, distinct from "veto cells," are induced by alloantigen priming and mediate transferable suppression of cytotoxic T lymphocyte responses in vivo

Primary and secondary cytotoxic T lymphocyte responses to minor alloantigens can be suppressed by priming host mice with a high dose (10(8) cells) of alloantigenic donor spleen cells (SC). Such suppression is antigen specific and transferable into secondary hosts with T cells. One interpretation of this is that antigen-specific host suppressor T cells (Ts) are activated. Alternatively, donor Lyt-2+ T cells, introduced in the priming inoculum, may inactivate host CTL precursors (CTLp) that recognize the priming (donor) alloantigens. Donor cells that act in this way are termed veto T cells. The experiments described here exclude veto T cell participation in transferable alloantigen-specific suppression, and demonstrate the operation of an alloantigen-specific host-derived T suppressor (Ts) cell. The origin of the Ts has been studied directly by using Thy-1-disparate BALB/c mice. The cell responsible for the transfer of suppression of a secondary CTL response to B10 minors was of the host Thy-1 allotype, and so originated in the host spleen and was not introduced in the priming inoculum. Secondly, antigen-specific Ts generated in CBA female mice against B10 minors could act on CTL responses to an unequivocally non-cross-reactive-third party antigen (H-Y), provided the two antigens were expressed on the same cell membrane. Such third-party suppression is incompatible with the operation of veto T cells. Depletion of Thy-1.2+ or Lyt-2+ cells from the suppression-inducing donor SC inoculum did not abrogate suppression induction in BALB/c mice; instead, suppression was enhanced. The demonstration of veto cell activity in similarly primed mice by other groups of investigators indicates that both types of suppression may operate. However, our results show that only antigen-specific Ts can mediate the transferable suppression of CTL responses to alloantigens.     

Suppressor T cells regulating the cell-mediated immune response to Pseudomonas aeruginosa can be generated by immunization with anti-bacterial T cells

We previously demonstrated that immunization with low (10 micrograms) doses of high m.w. polysaccharide from the gram-negative bacterium Pseudomonas aeruginosa generates T cells that suppress the ability of antibacterial T cells (Tab) to protect against bacterial infection. The current studies indicate that Ts cells with properties identical to those elicited by low dose polysaccharide immunization can be generated by immunization with Tab. Tab-elicited Ts cells can abrogate in vivo induction and in vitro and in vivo expression of antibacterial T cell activity. Tab-elicited Ts are Ag-specific and H-2 restricted in their suppressor activity. Non-immune T cells fail to elicit suppressor activity. These studies provide additional evidence that the protective T cell response to P. aeruginosa is controlled by a network of T cells that are probably recognizing idiotypic determinants on P. aeruginosa-immune T and B cells.     

Peripheral tolerance induction using ethylenecarbodiimide-fixed APCs uses both direct and indirect mechanisms of antigen presentation for prevention of experimental autoimmune encephalomyelitis

MHC class II (MHC II)-restricted T cell responses are a common driving force of autoimmune disease. Accordingly, numerous therapeutic strategies target CD4(+) T cells with the hope of attenuating autoimmune responses and restoring self-tolerance. We have previously reported that i.v. treatment with Ag-pulsed, ethylenecarbodiimide (ECDI)-fixed splenocytes (Ag-SPs) is an efficient protocol to induce Ag-specific tolerance for prevention and treatment of experimental autoimmune encephalomyelitis (EAE). Ag-SPs coupled with peptide can directly present peptide:MHC II complexes to target CD4(+) T cells in the absence of costimulation to induce anergy. However, Ag-SPs coupled with whole protein also efficiently attenuates Ag-specific T cell responses suggesting the potential contribution of alternative indirect mechanisms/interactions between the Ag-SPs and target CD4(+) T cells. Thus, we investigated whether MHC II compatibility was essential to the underlying mechanisms by which Ag-SP induces tolerance during autoimmune disease. Using MHC-deficient, allogeneic, and/or syngeneic donor Ag-SPs, we show that MHC compatibility between the Ag-SP donor and the host is not required for tolerance induction. Interestingly, we found that ECDI treatment induces apoptosis of the donor cell population which promotes uptake and reprocessing of donor cell peptides by host APCs resulting in the apparent MHC II-independent induction of tolerance. However, syngeneic donor cells are more efficient at inducing tolerance, suggesting that Ag-SPs induce functional Ag-SP tolerance via both direct and indirect (cross-tolerance) mechanisms leading to prevention and effective treatment of autoimmune disease.     

Rapid deletional peripheral CD8 T cell tolerance induced by allogeneic bone marrow: role of donor class II MHC and B cells

Mixed chimerism and donor-specific tolerance are achieved in mice receiving 3 Gy of total body irradiation and anti-CD154 mAb followed by allogeneic bone marrow (BM) transplantation. In this model, recipient CD4 cells are critically important for CD8 tolerance. To evaluate the role of CD4 cells recognizing donor MHC class II directly, we used class II-deficient donor marrow and were not able to achieve chimerism unless recipient CD8 cells were depleted, indicating that directly alloreactive CD4 cells were necessary for CD8 tolerance. To identify the MHC class II(+) donor cells promoting this tolerance, we used donor BM lacking certain cell populations or used positively selected cell populations. Neither donor CD11c(+) dendritic cells, B cells, T cells, nor donor-derived IL-10 were critical for chimerism induction. Purified donor B cells induced early chimerism and donor-specific cell-mediated lympholysis tolerance in both strain combinations tested. In contrast, positively selected CD11b(+) monocytes/myeloid cells did not induce early chimerism in either strain combination. Donor cell preparations containing B cells were able to induce early deletion of donor-reactive TCR-transgenic 2C CD8 T cells, whereas those devoid of B cells had reduced activity. Thus, induction of stable mixed chimerism depends on the expression of MHC class II on the donor marrow, but no requisite donor cell lineage was identified. Donor BM-derived B cells induced early chimerism, donor-specific cell-mediated lympholysis tolerance, and deletion of donor-reactive CD8 T cells, whereas CD11b(+) cells did not. Thus, BM-derived B cells are potent tolerogenic APCs for alloreactive CD8 cells.     

Thymocyte antigens do not induce tolerance in the CD4+ T cell compartment.

Thymocytes fail to tolerize the developing T cell repertoire to self MHC class I (MHC I) Ags because transgenic (CD2Kb) mice expressing H-2Kb solely in lymphoid cell lineages reject skin grafts mismatched only for H-2Kb. In this study, we examined why thymocytes fail to tolerize the T cell repertoire to self MHC I Ags. The ability of CD2Kb mice to reject H-2Kb skin grafts was age dependent because CD2Kb mice older than 20 wk accepted skin grafts. T cells from younger CD2Kb mice proliferated, but did not develop cytotoxic functions in vitro in response to H-2Kb. Proliferative responses were dominated by H-2Kb-specific, CD4+ T cells rather than CD8+ T cells. Representative CD4+ T cell clones from CD2Kb mice were MHC II restricted and recognized processed H-2Kb. TCR transgenic mice were generated from one CD4+ T cell clone (361) to monitor development of H-2Kb-specific immature thymocytes when all thymic cells or lymphoid cell lineages only expressed H-2Kb. Thymocyte precursors were not eliminated and mice were not tolerant to H-2Kb when Tg361 TCR transgenic mice were intercrossed with CD2Kb mice. In contrast, all thymocyte precursors were eliminated efficiently in thymic microenvironments in which all cells expressed H-2Kb. We conclude that self MHC I Ags expressed exclusively in thymocytes do not induce T cell tolerance because presentation of processed self MHC I Ags on self MHC II molecules fails to induce negative selection of CD4+ T cell precursors. This suggests that some self Ags are effectively compartmentalized and cannot induce self-tolerance in the T cell repertoire.     

Suppressor T cell mechanisms in contact sensitivity. II. Afferent blockade by alloinduced suppressor T cells.

We investigated the mechanism(s) by which MHC-restricted suppressor T cells (Ts) induced by i.v. injection of allogeneic DNP-modified lymphoid cells (alloinduced Ts) suppress the DNFB contact sensitivity response. It was shown that alloinduced Ts acted only during the early phases (afferent limb) of sensitization. They were incapable of suppressing previously sensitized recipients or of inhibiting the expression of DNFB-immune LN cells when co-transferred into normal recipients. The target of alloinduced Ts seems to be cell proliferation, i.e., inhibition of antigen-induced cell proliferation (DNA synthesis) in Ts recipient mice. The failure of recipients of alloinduced Ts to generate DNFB-immune LN cells capable of transferring contact sensitivity to normal recipients also suggests that these Ts act by preventing the development of an expanded clone of mature immune T cells. The suppressive effects of alloinduced Ts also were inhibited by prior in vitro treatment with anti-TNP serum. The data are discussed in terms of current models of suppression, and are compared to mechanisms of suppression in other contact sensitivity models.     

T cell recognition of Mlsc. I. Influence of MHC gene products in Mlsc-specific T cell recognition

Monospecific T cell clones have been proven to be powerful tools for the characterization of T cell recognition in many Ag-specific as well as allo-specific T cell responses. In this report, in order to elucidate the mechanism of T cell recognition of minor stimulating locus Ag (Mlsc) determinants, Mlsc-specific cloned T cells were employed together with primary T cell responses to clarify the role of MHC-gene products in Mlsc-specific T cell recognition. The results indicated that T cells recognize Mlsc determinants in conjunction with I-region MHC gene products. Moreover, certain MHC haplotypes (e.g., H-2a and H-2k) appear to function efficiently in the "presentation" of Mlsc, whereas other haplotypes (e.g., H-2b and H-2q) function poorly if at all in presenting Mlsc. Experiments with the use of stimulators derived from F1 hybrids between the low stimulatory H-2b, Mlsc strain, C3H.SW, and a panel of Mlsb, H-2-different or intra-H-2 recombinant strains strongly suggested that expression of E alpha E beta molecules on stimulators plays a critical role for Mlsc stimulation. The functional importance of the E alpha E beta product in Mlsc recognition was further demonstrated by the ability of anti-E alpha monoclonal antibody to inhibit the response of cloned Mlsc-specific T cells. Inhibition of the same Mlsc-specific response by anti-A beta k antibody suggests that the A beta product may also play a role in T cell responses to Mlsc.     

Alloantigenic sites on class I major histocompatibility complex antigens: 61-69 region in the first domain of the H-2Kb molecule induces specific antibody and T cell responses

The most polymorphic residues in the first domain of class I major histocompatibility complex (MHC) molecules are in the 61-69 region. We have chosen the H-2Kb molecule for determining the role of this region in the induction of alloimmune responses. A synthetic peptide, Glu-Arg-Glu-Thr-Gln-Lys-Ala-Lys-Gly corresponding to this region was synthesized. T cells enriched from the lymph nodes of allostrain mice that were previously primed with H-2Kb containing cells or with the synthetic peptide in complete Freund's adjuvant undergo extensive in vitro proliferation in response to the synthetic (61-69)H-2Kb peptide. The response was dependent on the presentation of the (61-69)H-2Kb peptide by the syngeneic antigen-presenting cells and was blocked by anti-class II MHC monoclonal antibodies. This peptide fragment of class I MHC molecule activates only helper/inducer type T cells that are involved in the primary responses but not the effector cytotoxic T cells. When coupled to a carrier protein, (61-69)H-2Kb peptide induced antibodies in allostrain mice that bind to intact H-2Kb molecule. No antibodies or T cell responses could be induced in syngeneic H-2b mice. The antigenic site on the H-2Kb molecule recognized by two H-2Kb-specific monoclonal antibodies B8 X 3 X 24 and Y-25 was also mapped in the 61-69 region by direct binding to the synthetic peptide. Therefore the 61-69 region on the H-2Kb molecule represents the first defined sequence on a class I molecule that is directly involved in the induction of alloimmune responses.     

The role of adherent accessory cells in the generation of effector suppressor T cells

The role of accessory cell populations in the generation of effector suppressor (Ts3) cells was studied. By using an in vitro culture system, it was previously determined that the induction of NP-specific effector suppressor activity requires T cells, antigen, and an anti-idiotypic B cell population. We now demonstrate that the generation of Ts3 cells in this system also requires accessory cells. The accessory population appears to play a role in the processing and presentation of antigen. These antigen-presenting accessory cells are required early in the induction phase of Ts3 generation. These accessory cells can present NP coupled to immunogenic or non-immunogenic polypeptide carriers, including polymers of L-amino acids. However, NP coupled to polymers of poorly metabolized D-amino acids fail to induce suppressor T cell generation. Furthermore, the data demonstrate that an H-2 homology must exist between the Ts3 precursors and the antigen-presenting cell population if suppressor activity is to be generated. We also characterize the differential genetic restrictions that govern the induction of Ts3 cells that control suppression of either T cell or B cell responses. The data suggest that although I-J region encoded gene products control the induction and effector phases of suppressor cell activity as measured on T cell responses, the suppression of B cell responses appear to be controlled by I-A gene products. Possible cellular mechanisms that might explain these findings are discussed.