Property of class I H-2 alloantigen-reactive Lyt-2+ helper T cell subset. Abrogation of its proliferative and IL-2-producing capacities by intravenous injection of class I H-2-disparate allogeneic cells

The present study investigates the distinctiveness of Class I H-2 alloantigen-reactive Lyt-2+ helper/proliferative T cell subset in the aspect of tolerance induction. Primary mixed lymphocyte reactions (MLR) revealed that Lyt-2+ and L3T4+ T cell subsets from C57BL/6 (B6) mice were exclusively capable of responding to class I H-2 [B6-C-H-2bm1 (bm1)]- and class II H-2 [B6-C-H-2bm12 (bm12)]-alloantigens, respectively. Anti-bm12 MLR was not affected by i.v. injection of bm12 spleen cells into recipient B6 mice. In contrast, a single i.v. administration of bm1 spleen cells into B6 mice resulted in the abrogation of the capacity of recipient B6 spleen and lymph node cells to give anti-bm1 MLR. This suppression was bm1 alloantigen-specific, since lymphoid cells from B6 mice i.v. presensitized with bm1 cells exhibited comparable anti-bm12 primary MLR to that obtained by normal B6 lymphoid cells. Such tolerance was rapidly (24 h after the i.v. injection of bm1 cells) inducible and lasting for at shortest 3 wk. Addition of lymphoid cells from anti-bm1-tolerant B6 mice to cultures of normal B6 lymphoid cells did not suppress the proliferative responses of the latter cells, indicating that the tolerance is not due to the induction of suppressor cells but attributed to the elimination or functional impairment of anti-bm1 proliferative clones. The tolerance was also demonstrated by the failure of tolerant lymphoid cells to produce IL-2. It was, however, found that anti-bm1 CTL responses were generated by tolerant lymphoid cells which were unable to induce the anti-bm1 MLR nor to produce detectable level of IL-2. These results demonstrate that class I H-2 alloantigen-reactive Lyt-2+ Th cell subset exhibits a distinct property which is expressed by neither Lyt-2+ CTL directed to class I H-2 nor L3T4+ Th cells to class II H-2 alloantigens.     

Tolerance induction of allo-class I H-2 antigen-reactive Lyt-2+ helper T cells and prolonged survival of the corresponding class I H-2-disparate skin graft

C57BL/6 (B6) mice were i.v. presensitized with class I H-2-disparate B6-C-H-2bm1 (bm1) spleen cells. Such presensitization resulted in almost complete abrogation of bm1-specific Lyt-2+ T cell-mediated proliferative and IL-2-producing capacities as measured by MLC of lymphoid cells from presensitized B6 mice with stimulating bm1 cells. In contrast, comparable magnitude of CTL responses was generated in bulk cultures from presensitized B6 lymphoid cells to that obtained in unpresensitized B6 responding cultures. These differential influences of Lyt-2+ T cell functions were also demonstrated by limiting dilution assays; frequencies of proliferative and IL-2-producing T cell precursors were as low as undetectable in presensitized B6 lymphoid cells, whereas an appreciable frequency of CTL precursors in a portion of the same lymphoid cells was observed. When bm1 skin grafting was performed in B6 mice i.v. presensitized with bm1 cells, the strikingly prolonged survival of bm1 skin grafts was observed. It was also demonstrated that the bm1 skin graft-bearing B6 mice which had been presensitized with bm1 cells not only exhibited a continuing suppressive state of bm1-specific helper (proliferative and IL-2-producing) function but also failed to generate anti-bm1 CTL responses. These results indicate that 1) i.v. presensitization with class I H-2 alloantigens results in selective tolerance of Lyt-2+ Th cells which is adequate for inducing prolonged graft survival, 2) the induction of complete abrogation of CTL potential is not absolute requirement for the prolongation of graft survival, and 3) residual CTL potential is attenuated after grafting so far as Th cells are rendered tolerant.     

Requirement of the thymus for the recovery of anti-alloantigen helper T cells from tolerance induced by intravenous presensitization with allogeneic cells

Intravenous presensitization of C57BL/6 (B6) mice with class I H-2-disparate B6-C-H-2bm1 (bm1) whole spleen cells and class II H-2-disparate B6-C-H-2bm12 (bm12) spleen cells depleted of APC resulted in almost complete elimination of the respective anti-bm1 and anti-bm12 reactivities. However, the reduced alloreactivities as assessed by Th cell capacities (proliferative responses and IL-2 production) were recovered around 8 wk after the i.v. presensitization in euthymic B6 mice. In contrast, background levels of bm1- or bm12-specific reactivities were revealed to last more than 12 wk after the presensitization in B6 mice which had been thymectomized prior to the i.v. presensitization. Such a reduced alloreactivity was also observed in the capacity to reject bm1 or bm12 skin grafts, and prolongation of graft survival was strikingly enhanced in the thymectomized group compared to that induced in the nonthymectomized group. However, there was an important difference in such prolongation in the thymectomized hosts between bm1 and bm12 grafts; a considerable percentage (greater than 80%) of bm12 skin grafts continued to take more than 5 mo, whereas about 90% of bm1 grafts were rejected by around 5 mo along with the emergence of weak, but detectable anti-bm1 Th and cytotoxic T cell activities. These results indicate that 1) i.v. presensitization regimen is capable of eliminating in vitro and in vivo alloreactive capabilities but these alloreactivities can be recovered in euthymic hosts with T cell repopulating potential and 2) there are differential requirements of the thymus for repopulating anti-bm1 (Lyt-2+) and anti-bm12 (L3T4+) T cell activities.     

Role of L3T4+ and Lyt-2+ donor cells in graft-versus-host immune deficiency induced across a class I, class II, or whole H-2 difference

The i.v. injection of parental T cells into F1 hybrid mice can result in a graft-vs-host (GVH)-induced immune deficiency that is Ag nonspecific and of long duration. The effect of the GVH reaction (GVHR) on the host's immune system depends on the class of F1 MHC Ag recognized by the donor cells. To determine the role of different subsets of donor-derived T cells in the induction of GVHR, donor spleen cells were negatively selected by anti-T cell mAb and C, and the cells were injected into F1 mice that differed from the donor by both class I and II MHC Ag or by class I or class II MHC only. The induction of GVHR across class I + II differences was found to require both L3T4+ and Lyt-2+ parental cells. Induction of GVHR across a class II difference required only L3T4+ parental T cells in the combination tested [B6-into-(B6 x bm12)F1]. In contrast, B6 Lyt-2+ cells were sufficient to induce GVHR across a class I difference in (B6 x bm1)F1 recipients. In addition, a direct correlation was observed between the cell types required for GVH induction and the parental T cell phenotypes detected in the spleens of the GVH mice. The number of parental cells detected in the unirradiated F1 hosts was dependent upon the H-2 differences involved in the GVHR. Induction of a class I + class II GVHR resulted in abrogation of both TNP-self and allogeneic CTL responses. In contrast, induction of a class II GVHR resulted in only a selective loss of TNP-self but not of allogeneic CTL function. Unexpectedly, the induction of a class I GVHR also resulted in the selective loss of the TNP-self CTL response. Thus, these class I and class II examples of GVH both result in the selective abrogation of L3T4+ Th cell function. The data are discussed in terms of respective roles of killer cells and/or suppressor cells in the induction of host immune deficiency by a GVHR, and of the selective deficiency in host Th cell function induced by different classes of GVHR.     

Heterogeneity of CD4+ T cells involved in anti-allo-class I H-2 immune responses. Functional discrimination between the major proliferating cells and helper cells assisting cytotoxic T cell responses.

MLR in various combinations with class I H-2 disparity revealed that there are three patterns of MLR in the aspect of responding T subset (CD4 vs CD8) dominance. Irrespective of the CD8 vs CD4 dominance, a single i.v. administration of class I-disparate allogeneic spleen cells resulted in almost complete abrogation of anti-class I proliferative capacity of both CD4+ and CD8+ T cells in six combinations. The suppression of proliferative responses was correlated with the striking reduction in the ability to produce IL-2 upon stimulation with the relevant class I alloantigens. In contrast, i.v. presensitized recipient mice exhibiting only marginal MLR/Il-2 production could generate comparable magnitudes of anti-allo class I CTL as well as graft rejection responses to those induced by normal unpresensitized mice. The administration in vivo of anti-CD4 antibody along with the i.v. presensitization not only suppressed the generation of CTL responses by spleen cells but also induced appreciable prolongation of allo-class I-disparate skin grafts under conditions in which neither alone did it. These results demonstrate that 1) the suppression of graft rejection responses is not necessarily reflected on the reduction of MLR; 2) CD8+ CTL precursors responsible for graft rejection can be activated by either allo-class I-reactive CD8+ or CD4+ Th cells; 3) i.v. presensitization induces functional elimination of CD8+ and CD4+ proliferative/IL-2-producing T cells but not of CD8+ CTL precursors and CD4+ Th whose capacity is expressed by assistance of CTL induction but not by their own proliferation. Thus, this study illustrates the heterogeneity of class I alloantigen-reactive CD4+ T cells in the aspect of their capacity to proliferate themselves vs contribute to CTL induction as well as graft rejection.     

Role of T cell subsets in lethal graft-versus-host disease (GVHD) directed to class I versus class II H-2 differences. II. Protective effects of L3T4+ cells in anti-class II GVHD

Detailed information was sought on the capacity of purified B6 L3T4+ cells to elicit lethal graft-versus-host disease (GVHD) in irradiated class II-different class I-identical (C57BL/6 (B6) x bm 12)F1 hosts. When B6 L3T4+ cells were transferred in small doses (10(5) to 10(6) together with donor bone marrow (BM) cells, the recipients all developed acute lethal GVHD and most of the mice died within 2 wk, probably from gut damage; this syndrome was conspicuous only in mice treated with very heavy irradiation, i.e., 1000 rad. In marked contrast to L3T4+ cells given in small doses, transfer of large doses of B6 L3T4+ cells to heavily irradiated (B6 x bm 12)F1 hosts paradoxically resulted in only limited mortality: most of the recipients survived for greater than 6 mo and manifested little or no evidence of ill health. It is suggested that the capacity of large doses of L3T4+ cells to protect mice against lethal GVHD is a reflection of T helper function: the cellular immunity provided by the donor L3T4+ cells enables the host to repel pathogens entering through damaged mucosal surfaces, with the result that GVHD becomes sublethal. The protective function of L3T4+ cells in the B6----bm 12 combination was only seen in hosts given donor BM. With transfer of donor L3T4+ cells plus host BM, even lightly irradiated recipients died rapidly from hemopoietic failure. Because this syndrome failed to occur in mice given a mixture of donor and host BM, it would appear that L3T4+ cells destroyed host lymphohemopoietic cells by direct cytotoxicity rather than via a bystander effect.     

Tumor allograft rejection is mainly mediated by CD8+ cytotoxic T lymphocytes stimulated with class I alloantigens in cooperation with CD4+ helper T cells recognizing class II alloantigens

Presence of the three major pathways (self-Ia restricted, allo-K/D restricted, and allo-Ia restricted pathways) in generating class I-restricted CTL has been reported. The present study was conducted in order to clarify which of the three is the main pathway in mediating tumor allograft rejection. One million EL-4 tumor cells derived from C57BL/6 (B6;H-2b) were inoculated into the various strains of mice that were genetically different from B6. Class I (K/D) Ag-disparate but IA Ag-matched B6.C-H-2bm1 (bm1;Kbm1, IAb, IE-, Db) mice or B10.A (5R) (5R; b, b, k, d) mice could not reject 1 x 10(6) EL-4 tumor cells in spite of the strong generation of CTL against the B6 Ag, suggesting the inability of the self-Ia restricted pathway and the allo-K/D restricted pathway in rejecting tumor allografts. The strains of mice being capable of rejecting EL-4 tumor were disparate from B6 mice in both class I and class II (IA) Ag, suggesting the importance of the allo-Ia restricted pathway in rejecting tumor allografts. To generate CTL against Kb Ag via the allo-Ia restricted pathway in the bm1 mice, 2 x 10(7) B6.H-2bm12 (bm12; b, bm12, -, b) spleen cells were injected into the bm1 mice as a supplementary source of allogeneic APC that possibly raise CTL through CD4+ Th cells of bm1 origin. These bm1 mice became capable of rejecting 1 x 10(6) EL-4 tumor cells. The same was observed in the combination of bm12----B10.A (5R) (b, b, k, d) mice. To further elucidate the role of the class II restricted CD4+ Th cells, anti-CD4 antibody was repeatedly i.v. administered into the C3H/He (C3H; H-2k) or the DBA/2 (DBA; H-2d) mice on days 0, 1, and 4. Injection of anti-CD4 antibody led 1 x 10(6) EL-4 tumor cells to grow and kill the C3H and DBA mice. These results suggest that the main effector CTL pathway involved in tumor allograft rejection is allo-Ia restricted pathway where CD8+ precursor CTL were stimulated by the class II-restricted CD4+ Th cells.     

Preferential use of a T cell receptor V beta gene by acetylcholine receptor reactive T cells from myasthenia gravis-susceptible mice.

Experimental autoimmune myasthenia gravis (EAMG) is an important model for testing current concepts in autoimmunity and novel immunotherapies for autoimmune diseases. The EAMG autoantigen, acethylcholine receptor (AChR), is structurally and immunologically complex, a potential obstacle to the application of therapeutic strategies aimed at oligoclonal T cell populations. Inasmuch as we had previously shown that the clonal heterogeneity of T cell epitope recognition in EAMG was unexpectedly limited, we examined TCR V beta expression. AChR primed lymph node T cells and established AChR reactive T cell clones from EAMG-susceptible C57BL/6 (B6; H-2b, Mls-1b) mice showed preferential utilization of the TCR V beta 6 segment of the TCR. After in vivo priming and in vitro restimulation for 7 days with AChR or a synthetic peptide bearing an immunodominant epitope, V beta 6 expressing lymph node cells (LNC) were expanded several-fold, accounting for up to 75% of recovered viable CD4+ cells. The LNC of B6.C-H-2bm12 (bm12; H-2bm12, Mls-1b) mice, which proliferated in response to AChR but not to the B6 immunodominant peptide, failed to expand V beta 6+ cells. Inasmuch as nonimmune bm12 and B6 animals had similar numbers of V beta 6+ LNC (4-5%), this suggested that structural requirements for TCR recognition of Ag/MHC complexes dictated V beta usage. Results concerning peptide reactivity and V beta 6 expression among T cells from (B6 x bm12)F1 animals also suggested that structure-function relationships, rather than negative selection or tolerance, accounted for the strain differences between B6 and bm12. To examine the potential effects of thymic negative selection of V beta 6+ cells on the T cell response to AChR, CB6F1 (H-2bxd, Mls-1b; V beta 6-expressing) and B6D2F1 (H-2bxd, Mls-1axb; V beta 6-deleting) strains were analyzed for AChR and peptide reactivity and V beta 6 expression. Both F1 strains responded well to AChR but the response of B6D2F1 mice to peptide was significantly reduced compared to CB6F1. Short and long term cultures of peptide-reactive B6D2F1 LNC showed no expansion of residual V beta 6+ cells, although similar cultures of CB6F1 LNC were composed of more than 60% V beta 6+ cells. The results from the F1 strains further indicated that the T cell repertoire for peptide was highly constrained and that non-V beta 6 expressing cells could only partially overcome Mls-mediated negative selection of V beta 6+ TCR capable of recognizing peptide.(ABSTRACT TRUNCATED AT 400 WORDS)     

The role of H-2 in T cell recognition of Mls

The role of H-2 was evaluated in T cell recognition of Mls-encoded antigens during primary mixed lymphocyte responses (MLR). Mlsc was used as a stimulating determinant in MLR and its recognition by T cells was assessed by linear regression analysis under culture conditions in which (A x B)F1 responder cell number was the factor limiting total response. Results of such experiments indicated the presence of distinct (A x B)F1 responder T cell subpopulations capable of differentially recognizing the foreign Mls antigen in association with one or the other parental H-2 haplotype. These findings demonstrate that T cells do not recognize Mlsc products in isolation, but rather are restricted to recognition of Mlsc in the context of "self" H-2 determinants.     

Cytotoxic T lymphocyte response to minor H-43a alloantigen in H-43b mice. Privileged H-2Kb restriction to the response is not due to immunodominance or epistatic effect but due to Ir gene function of H-2Kb itself

Previous study demonstrated that anti-H-43a cytotoxic T lymphocyte (CTL) response of H-43b CWB (H-2b) stain carrying non-major histocompatability complex (MHC) genes of C3H and F1 strains raised by crossing CWB with various H-43b strains was restricted exclusively by self H-2Kb (Kb). In the present study, newly produced C3W strain (H-2k, H-43b), which is H-43-congenic to C3H/HeN (H-2k, H-43a), was used as H-43b mice, and possibility of immunodominance of Kb was examined. No anti-H-43a CTL response could be induced in C3W strain and F1 strains raised by crossing C3W with other H-43b strains not carrying Kb. Thus, the possibility of immunodominance of Kb over the other MHC class I alleles could not be supported. We also examined possibility of epistatic effect of I region genes and non-MHC genes on the Kb restriction. (C3W x C57BL/6)F1(I-Ak/b) and (C3W x B6.CH-2bm12)F1(I-Ak/bm12)mice showed equally anti-H-43a CTL response restricted exclusively by self Kb, and (C3W x B10.MBR)F1(Ik/k) mice also showed anti-H-43a CTL response restricted solely by self Kb. Cold target competition experiments demonstrated that H-43b C57BL/10 or A.BY mice, which do not have non-MHC genes of C3H mounted anti-H-43a CTL response restricted solely by self Kb. Thus, no relation of I region genes or non-MHC genes to the Kb restriction was shown. All the results indicate that H-43b mouse strains, including F1, can not achieve anti-H-43a CTL response unless they carry Kb allele. Notably, (C3W x C57BL/6)F1 mice mounted self Kb-restricted anti-H-43a CTL response, whereas (C3W x B6.CH-2bm1)F1 mice carrying mutated Kb could not mount anti-H-43a CTL response at all. These findings indicate strongly that Kb itself is classical Ir gene of anti-H-43a CTL response and directs self Kb restriction of the response.     

Antigen-presenting T cells. I. Class I alloantigen (bm1)-bearing T lymphoblasts efficiently stimulate a primary clonal response of Lyt-2+ cytotoxic lymphocyte precursors of B6 origin

The cytotoxic response of splenic Lyt-2+ T cells to class I H-2 alloantigen-bearing stimulator cells was analyzed under limiting dilution conditions. One of 50 to one of 200 nylon wool-nonadherent (FACS-purified), small Lyt-2+ spleen cells of B6 origin gave rise in vitro to a cytotoxic T lymphocyte clone that specifically lysed targets bearing bm1 alloantigen. This population of alloantigen-specific cytotoxic lymphocyte precursors (CLP) was activated by different types of bm1 stimulator cells with different efficiency: 2 X 10(5) nonfractionated spleen cells, 5000 normal peritoneal cells, 400 to 10(4) L3T4+ helper T blasts, or 2000 to 10(4) Lyt-2+ T blasts induced clonal growth of this CLP pool. Irradiated or mitomycin-treated small (L3T4+ or Lyt-2+) bm1-derived T cells were inefficient stimulator cells for this response. Supplementation of culture medium with (recombinant) interleukin 2 was necessary and sufficient to support clonal development of alloantigen-triggered CLP in the presence of allogeneic T blasts. Under these limiting dilution conditions, we observed comparable cloning efficiencies for (wild-type) Kb-allospecific splenic Lyt-2+ CLP from bm1 mice generated in response to either irradiated B6 spleen cells or inactivated B6-derived T cell lines (EL4 and RBL-5 lymphoma cells). The data indicate that normal T lymphoblasts as well as tumor T cell lines stimulate clonal development in vitro of class I H-2-allospecific cytotoxic T lymphocytes in the presence of interleukin 2.     

Cytotoxic T lymphocyte recognition of novel allodeterminants expressed on in vitro selected H-2Kb mutants

In the present study, in vitro derived H-2Kb mutants have been examined by alloreactive CTL. Two mutants, R8.24 and R8.246, have been shown to express novel determinants detected by CTL generated against some but not all in vivo derived Kb mutants. BDF1 anti-bm3, anti-bm11, anti-bm19, anti-bm23, and anti-bm6 CTL populations lyse the two R8 variants. The novel determinants expressed on the R8 mutants detected by the bm3 and bm23-specific CTL appear to differ from the determinant recognized by the bm6-specific CTL. No new serologically defined determinants were detected on any of 18 independent R8 variants. However, these results do not rule out the existence of new determinants which could be recognized by antibodies. Finally, the relationship between the T cell recognition of the in vivo and in vitro derived mutants and their use in understanding the structure/function relationships between the immune response and class I Ag based on recent crystallographic analyses is discussed.     

In vivo induction of cytotoxic T lymphocytes in H-2Kbm mutant mice and cross-reactivity of narrowly specific killer clones

Anti-wild-type (B6) H-2Kbm mutant (bm) CTL were induced in the regional lymph nodes by 2 injections (with 2 week interval) of bm mice into foot-pads with B6 irradiated splenocytes. CTL were tested 7 days after the boost, including 3 days precultivation in monoculture (required for high CTL activity in bm). Active bm4 CTL inducible in vivo but not in the mixed lymphocyte culture (MLC), while bm1, bm3 and their F1 hybrids with BALB/c were equally active in both models. In vivo induced bm3 CTL were cloned with B6 irradiated splenocytes stimulators in the presence of rat interleukine-2. Of 9 Thy1.2 positive narrow-specific CTL clones 2 displayed cross-reactivity to allogeneic target cells (TC): the 1st lysed H-2Kk [TC B10.A(2R)] and the 2nd H-2Kd [TC B10.D2(R101)]. The results witness for non-identity of the in vivo and in vitro induced CTL. The variable cross-reactivity of the narrow-specific CTL clones possibly occur because of receptors' affinity difference.     

Alloreactive T cell responses and acute rejection of single class II MHC-disparate heart allografts are under strict regulation by CD4+ CD25+ T cells

Skin but not vascularized cardiac allografts from B6.H-2bm12 mice are acutely rejected by C57BL/6 recipients in response to the single class II MHC disparity. The underlying mechanisms preventing acute rejection of B6.H-2bm12 heart allografts by C57BL/6 recipients were investigated. B6.H-2bm12 heart allografts induced low levels of alloreactive effector T cell priming in C57BL/6 recipients, and this priming was accompanied by low-level cellular infiltration into the allograft that quickly resolved. Recipients with long-term-surviving heart allografts were unable to reject B6.H-2bm12 skin allografts, suggesting potential down-regulatory mechanisms induced by the cardiac allografts. Depletion of CD25+ cells from C57BL/6 recipients resulted in 15-fold increases in alloreactive T cell priming and in acute rejection of B6.H-2bm12 heart grafts. Similarly, reconstitution of B6.Rag(-/-) recipients with wild-type C57BL/6 splenocytes resulted in acute rejection of B6.H-2bm12 heart grafts only if CD25+ cells were depleted. These results indicate that acute rejection of single class II MHC-disparate B6.H-2bm12 heart allografts by C57BL/6 recipients is inhibited by the emergence of CD25+ regulatory cells that restrict the clonal expansion of alloreactive T cells.     

Lethal graft-vs-host disease induced by a class II MHC antigen only disparity is not mediated by cytotoxic T cells

Treatment of C57BL/6J (B6) murine splenocytes with L-leucyl-L-leucine methyl ester (Leu-Leu-OMe) selectively removes NK cells, CTL precursors, and the capacity to cause lethal graft-vs-host disease (GVHD) in irradiated B6 X DBA/2 F1 mice. In contrast, alloantigen-induced L3T4(+) Th cell function has been shown to be relatively preserved after exposure to this agent. The present studies assessed the effects of Leu-Leu-OMe treatment of donor cells on induction of lethal GVHD in other murine strain combinations. When irradiated B6 X CBAF1 mice were infused with T and NK cell-depleted B6 bone marrow cells and 3 to 30 X 10(6) B6 spleen cells, uniformly lethal GVHD was observed. However, B6 X CBAF1 recipients of T and NK-depleted B6 bone marrow cells and similar numbers of Leu-Leu-OMe-treated B6 spleen cells demonstrated 90 to 100% long term survival. In contrast, Leu-Leu-OMe treatment of B6 donor cells had no beneficial effect on mortality rates in irradiated (B6 X B6-C-H-2bm12)F1 (B6 X bm12F1) recipients. When B6 spleen cells were stimulated in vivo or in vitro with either B6 X CBAF1 or B6 X bm12F1 stimulator cells, the capacity to generate alloantigen-specific CTL was abolished comparably by Leu-Leu-OMe treatment. Thus, the dramatic difference between the effects of Leu-Leu-OMe treatment of B6 spleen cells on the course of GVHD in B6 x CBAF1 and class II MHC only disparate B6 x bm12F1 recipients could not be explained by unique resistance of bm12-specific CTL precursors to Leu-Leu-OMe. These findings indicate that T cell effector mechanisms distinct from classic cell-mediated cytotoxicity are sufficient to generate lethal GVHD in class II MHC only disparate B6----B6 X bm12F1 mice.     

Induction of linked suppression in addition to the donor H-2 class I-specific unresponsiveness in recipient T cells by transfusing class I plus class II-disparate, but not class I alone-disparate, bone marrow cells

This study was undertaken to determine whether bone marrow (BM) cells contain a cell population with the capacity to induce an unresponsiveness of T cells specific to the BM self-H-2 class I antigens in vivo, i.e., veto cell population. Recombinant or congenic mice were infused intravenously with H-2-incompatible BM cells. One to several weeks later, donor H-2-and irrelevant H-2-specific responses in mixed lymphocyte reaction cultures of recipient T cells were assessed. Transfusion of H-2-incompatible BM of C57BL/10 (B10) recombinant strains caused a long-lasting cytotoxic T lymphocyte (CTL) unresponsiveness to the donor class I antigens in recipient lymph node cells. When class I plus class II-disparate BM cells were transfused, an anti-donor class I CTL response and a response against a third-party class I antigen, which was presented on the stimulator cells coexpressing the donor class I and class II, were significantly suppressed. This linked suppression lasted for less than 2 weeks after transfusion. Transfusion of class I-alone-disparate BM induced the donor class I-specific CTL unresponsiveness, but not the linked suppression. The induction of linked suppression was prevented considerably by transfusing nylon wool-nonadherent BM or by treating recipients with cyclophosphamide 2 days before transfusion. An anti-third-party class I CTL response, stimulated in vitro with fully allogeneic spleen cells, was not hampered by the BM transfusion. Coculturing the lymph node (LN) cells obtained from the class I plus class II-disparate BM recipient with normal LN cells interfered with the generation of both anti-donor class I and anti-linked third-party class I CTL, whereas, coculturing LN cells from the class I alone-disparate BM recipient inhibited neither specificity of CTL generation. Transfusion of class I plus class II-disparate BM resulted in a significant suppression of the donor class II-specific proliferative response. In contrast, transfusion of class I alone-disparate BM did not suppress any proliferative responses, including even a "linked" third-party class II-specific response. Transfusion of bm 1, (B6 X bm 1)F1, or (bm 1 X bm 12)F1 BM to B6 did not induce unresponsiveness in bm 1-specific CTL responses. However, the transfusion resulted in a significant suppression of bm 1-reactive proliferative response of recipient LN cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Cytotoxic T lymphocyte response to minor H-42a alloantigen in H-42b mice: clonal inactivation of the precursor cytotoxic T lymphocytes by veto-like spleen cells that express the H-42a antigen

When (B10.BR X CWB)F1 (BWF1; H-2k/b) mice carrying the H-42b allele at the minor H-42 locus were injected with H-42a C3H.SW (CSW; H-2b) or C3H (H-2k) spleen cells (SC), self-H-2Kb restricted anti-H-42a pCTL in the BWF1 recipients were primed and differentiated to anti-H-42a CTL after in vitro stimulation with (B10.BR X CSW)F1 (BSF1; H-2k/b, H-42b/a) SC. In contrast, anti-H-42a pCTL in H-42b mice were inactivated by injection with H-42-congenic H-42a SC, and stable anti-H-42a CTL tolerance was induced. Preference of H-2Kb restriction of anti-H-42a CTL was strict, and self-H-2Kb-restricted anti-H-42a CTL did not lyse target cells carrying H-42a antigen in the context of H-2Kbm1. Involvement of suppressor cells in the anti-H-42a CTL tolerance was ruled out by the present cell transfer study and the previous cell-mixing in vitro study. Notably, treatment with anti-Thy-1.2 antibody (Ab) plus complement (C) wiped out the ability of CSW SC in the priming of anti-H-42a pCTL of BWF1 mice but left that of C3H SC unaffected, and injection of the anti-Thy-1.2 Ab plus C-treated CSW SC induced anti-H-42a CTL tolerance in the BWF1 recipients. Furthermore, H-42a/b, I-Ab/bm12 [CSW X B6.CH-2bm12 (bm12)]F1 SC could not prime anti-H-42a pCTL in H-42b, I-Ab (CWB X B6)F1 recipients, whereas H-42a/b, I-Ab (CSW X B6)F1 SC primed anti-H-42a pCTL in H-42b, I-Ab/bm12 (CWB X bm12)F1 recipients. The unresponsiveness of anti-H-42a pCTL in H-42b mice to H-42-congenic H-42a SC was sometimes corrected by immunization of H-42b female mice with H-42-congenic H-42a male SC. Taking all of the results together, we propose the following. Unresponsiveness of anti-H-42a pCTL in H-42b mice to H-42-congenic H-42a SC is caused by "veto cells" contained in the antigenic H-42a SC. Anti-H-42a pCTL in the H-42b recipients directly interacting with H-42-congenic H-42a SC, which bear H-42a antigen and H-2Kb restriction element, are inactivated or vetoed.(ABSTRACT TRUNCATED AT 400 WORDS)     

Clonal analysis of H-2Kb + TNP recognition by T cells with the use of H-2Kbm mutants and H-2Kb-specific monoclonal antibodies

Eleven long-term cytotoxic T lymphocyte (CTL) clones derived from C57BL/10 T cells sensitized in vivo and in vitro with trinitrobenzene sulfonate- (TNBS) treated syngeneic cells were all restricted to the K end of H-2b. The fine specificity of these CTL clones was analyzed by using H-2Kbm mutant target cells and H-2Kb-specific monoclonal antibodies (mAb). Seven distinct patterns of reactivity of the T cell clones could be observed with the use of six H-2Kbm mutant target cells. Further heterogeneity could be detected in terms of the ability of anti-Lyt-2 mAb to inhibit CTL activity. Cross-reactivity between H-2Kb + TNP and H-2Kbm + TNP was observed for all clones tested for bm5 and bm6, but less frequently for bm3 (8/11), bm8 (7/10), bm4 (4/11), and bm1 (3/11). It was further observed that amino acid substitutions located in the first domain only (one clone), or in the second domain only (six clones), or in either the first or the second domain (three clones) of the H-2Kb molecule could affect target cell recognition by a given T cell clone. the latter type of reactivity suggested that some clones recognized "conformational" determinants of the H-2 molecule, or that amino acid substitutions in one domain might influence the structure of the next domain. One H-2Kb + TNP-reactive clone exhibited a heteroclitic behavior with decreasing avidities for target cells expressing H-2Kbm8 + TNP, H-2Kb + TNP, and H-2Kbm8, which further extends the various patterns of T cell cross-reactions observed within a given class of MHC products. The use of H-2Kb-specific mAb in blocking studies as an attempt to define further the H-2Kb epitopes recognized by CTL clones indicated that: a) TNBS treatment may affect the antigenicity of the H-2Kb molecule as assessed by some mAb; and b) that the T cell clone-target cell interaction may or may not be inhibited by a given mAb, depending on structural variations of the H-2Kb molecule (use of H-2Kbm mutants) that do not affect the interaction itself. These results indicate that this type of analysis does not permit correlation of serologic- and T cell-defined epitopes.     

Specificity repertoire of splenic Lyt-2+/F23+ cytotoxic lymphocyte precursors from B6 mice

As revealed by flow cytometric analysis, about 30% of nylon wool nonadherent Lyt-2+ B6 spleen cells were F23+, i.e., were stained with the monoclonal antibody F23.1 directed against an allotypic T-cell receptor determinant. The specificity repertoire of splenic Lyt-2+/F23+ cytotoxic lymphocyte precursors (CLP) from B6 mice was investigated in a limiting dilution (LD) system designed to support clonal expansion in vitro of a representative fraction of this T-cell subset: in highly purified Lyt-2+ responder cells cocultured with mitomycin-treated F23 hybridoma cells in the presence of (recombinant) interleukin 2 under LD conditions, one out of three Lyt-2+/F23+ CLP gave rise to a functional cytotoxic T lymphocyte (CTL) clone. The split-well analysis of individual CTL populations demonstrated a clear-cut segregation of the lytic reactivities toward different allogeneic Con A blast targets. A large fraction of B6-derived CTL clones (3-10%) specifically lysed fully H-2 allogeneic (H-2k, H-2d), or H-2K mutant (bm1) targets. Self-reactive and allorestricted lytic patterns were not found.     

Graft-vs-host reaction limited to a class II MHC difference results in a selective deficiency in L3T4+ but not in Lyt-2+ T helper cell function

Hybrid mice of the (B6 X bm12)F1 combination were inoculated i.v. with parental B6 spleen cells to induce a class II graft-vs-host disease (GVH). Such mice failed to generate in vitro cytotoxic T lymphocyte (CTL) responses that were dependent upon L3T4+ T helper cell (Th) function (e.g., anti-B6-TNP) but were capable of generating in vitro CTL responses that could be mediated by Lyt-2+ Th cells (anti-allo class I). When Th function was assayed directly by interleukin 2 (IL 2) secretion, class II GVH animals were found to be deficient in L3T4+ but not Lyt-2+ IL 2-secreting Th cells. This selective deficiency in L3T4+ Th function correlates with a selective decrease in class II GVH mice of host-derived derived L3T4+ T cells. In addition, it was found that the spleens of class II GVH mice contained cells capable of selectively suppressing L3T4+ Th function. In contrast, mice in which a class I + II GVH occurred were depleted of both L3T4+ and Lyt-2+ Th function as assessed by IL 2 production. The findings that class II GVH selectively depletes L3T4+ T cells and T cell functions are discussed with respect to the immune function of distinct T cell subsets in normal and diseased states.