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.     

Possible mechanisms by which the H-2Kbm3 mutation may decrease cytotoxic T-lymphocyte recognition of vesicular stomatitis virus nucleoprotein antigen.

Spleen cells from C57BL/6 (B6) mice generate a strong in vitro cytotoxic T-lymphocyte (CTL) response specific for vesicular stomatitis virus (VSV). Spleen cells from VSV-primed B6-H-2bm3 (bm3) mice, which have a mutation in H-2Kb, require approximately 10-fold more UV-inactivated VSV to generate in vitro secondary anti-VSV CTL, compared with spleen cells from primed B6 mice. Anti-VSV CTL elicited in both bm3 and B6 mice are primarily specific for the viral nucleocapsid protein (N protein), as demonstrated by using recombinant vaccinia viruses that express the VSV N protein. bm3 CTL were found to exhibit only a very low level of lytic activity when tested against autologous VSV-infected concanavalin A spleen cell blasts as well as several H-2b tumor cell lines. The weak anti-VSV response of bm3 CTL was found to be the result of a combination of inefficient recognition of VSV-infected target cells and decreased elicitation of secondary effector cells. VSV-infected bm3 target cells were not killed as well as B6 targets by either bm3 or B6 effectors. This is because of the inefficient recognition of targets, as demonstrated by the fact that VSV-infected bm3 cells were unable to competitively inhibit the lysis of VSV-infected B6 target cells by either bm3 or B6 effectors. By using cells from recombinant mice, it was shown that the CTL response restricted by H-2Kb was low in the bm3 mice, compared with that of the B6 mice. However, the H-2Db-restricted CTL activity was similarly low in both the B6 and bm3 mice. The possibility that the low response to VSV-infected bm3 cells is caused by differences between the bm3 and B6 cells in expression of either viral antigens or H-2K was investigated by radiolabeling and immunoprecipitation. VSV-infected B6 and bm3 cells were found to express equivalent levels of both viral antigens and H-2K. These results indicate that the bm3 mutation alters a functional site on the H-2Kb molecule that is involved in the recognition of VSV-infected cells. The observation that elicitation of bm3 CTL can occur at high antigen doses further suggests that the bm3 mutation results in a lower affinity of H-2K either for viral antigen or for receptor sites on the CTL.     

H-2Kb mutations limit the CTL response to SV40 TASA

The cytotoxic T lymphocyte (CTL) responses directed towards SV40 tumor-associated specific antigen (TASA) in nine strains of spontaneously arising Kb mutant mice were analyzed. All nine mutants generated normal levels of H-2Db-restricted response, but the K-end-restricted CTL response varied. B6.C-H-2bm1 (bm1) did not produce K-end-restricted SV40 TASA-specific CTL upon immunization, and SV40-transformed bm1 cells were not lysed by intra-H-2 recombinant Kb [B10.A(5R)] CTL. Nonreciprocal cross-reactive lysis was seen between B6-H-2bm8 (bm8) and B10.A(5R). Strain B6-H-2bm8 mice produce highly specific Kbm8-restricted CTL that lyse SV40-transformed bm8 cells (Kbm8SV) but not B10.A(5R) target cells (K5RSV), although Kbm8SV targets can be partially lysed by B10.A(5R) CTL. The other seven Kb mutants cross-react with B10.A(5R). These experiments definitively show that genes mapping to the K and/or D region directly control the H-2-restricted CTL response to SV40 TASA.     

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.     

Recognition of H-2Kb mutant target cells by Moloney virus-specific cytotoxic T lymphocytes from bm13 (H-2Db mutant) mice. I. Full recognition of Kbm11 by Kb-restricted CTL

In C57BL/6 (B6, H-2b) mice, the secondary in vitro CTL response against Moloney leukemia virus is restricted and regulated by the H-2Db locus. B6.C-H- 2bm13 ( bm13 ) mice, however, carrying a mutation at the Db locus, show an increased H-2Kb-restricted CTL response without a demonstrable CTL component restricted by the mutant Dbm13 molecule (D----K shift). These purely Kb-restricted bm13 virus-specific CTL were incubated with a series of Kb mutant virus-infected target cells to study the effect of the mutations at the target cell level. Of six Kb-mutant virus-infected target cells tested, bm1 cells were not recognized and bm8 cells were recognized only marginally by bm13 virus-specific CTL, whereas bm3 , bm5 , bm6 , and bm11 cells were fully recognized. Thus, the bm3 , bm5 , bm6 , and bm11 Kb mutants fully share the relevant H-2K restriction specificities with H-2Kb, whereas the bm1 mutant totally and the bm8 mutant almost completely lack these specificities. This result differs markedly from the restriction site relationships among B6 and these Kb mutants in other antigenic systems. The most striking example concerns the bm11 mutant, which is fully recognized by Moloney-specific CTL, but not at all by Sendai, minor H (H-3.1, H-4.2), and sulfhydryl hapten-specific CTL. Monoclonal anti-H-2Kb antibody B8-3-24 inhibited virus-specific lysis by bm13 CTL of all Kb virus-infected mutant target cells to which this antibody binds. Lysis of bm5 and bm11 but not of bm3 target cells was inhibited, in line with the fact that B8-3-24 antibody does not bind bm3 . On the other hand, not only bm5 and bm11 but also bm3 virus-infected target cells blocked virus-specific lysis to the same extent as syngeneic bm13 target cells. Therefore, bm13 virus-specific CTL populations do not recognize the discrete cluster alteration in the Kbm3 molecule, as identified by antibody B8-3-24. The bm1 and the bm8 mutations, which have structural alterations in completely different sites of the Kb molecule, show complete or almost complete loss, respectively, of Kb-Moloney restriction sites. This finding supports the notion that these virus-specific CTL recognize conformational determinants rather than linear amino acid sequences.     

Effect of anH-2 mutation on cytotoxic T cell recognition. Specific antigen can determine the pattern ofH-2 restriction

Hz1 (H-2 ^bm1 ) mice, an H-2 mutant strain derived from C57BL/6(H-2 ^b ), were either injected with vaccinia virus or had their spleen cells sensitized in vitro with syngeneic TNP-modified cells. The cytotoxic cells generated were tested for their activity against target cells that were either infected with vaccinia virus, TNP-modified, or both vaccinia infected and TNP-modified.Hz1 anti-TNP cytotoxic cells specifically lysed syngeneic target cells that were trinitrophenylated but not infected with vaccinia virus, while anti-vaccinia cells specifically lysed vaccinia infected target cells but not TNP-cells. Hz1 (H-2K ^bm1 D ^b ) anti-TNP effector cells killed B10.A(5R)-TNP (H-2K ^b D ^d ) targets, indicating that there is cross-reactivity between TNP-H-2K^b and TNP-H-2K^bm1. On the other hand, there is no cross-reactivity between vaccinia-H-2K^b and H-2K^bm1, since Hz1 anti-vaccinia effector cells did not kill vaccinia infected B10.A(5R) targets.Since Hz1 anti-TNP effector cells lysed B10.A(5R) target cells that were first infected with vaccinia virus and then derivatized with TNP, virus does not mask cross-reactive determinants shared by TNP-H-2K^b and H-2K^bm1. Additional experiments showed that Hz1 anti-TNP effector cells lysed TNP-modified and vaccinia infected B10.A(5R) target cells irrespective of the virus concentration used for infection or the time of addition of virus. Further, there are no detectable quantitative differences between C57BL/6 and Hz1 anti-TNP effector cells in their ability to kill TNP-5R targets.The cytotoxic effect of Hz1 anti-TNP effector cells on B10.A(5R)-TNP targets could not be blocked with TNP derivatized inhibitor cells that carry theH-2D ^d region allele. Thus, the ability of anti-TNP H-2K^b effector cells to cross-react with H-2K^bm1 cannot be explained by a cross-reaction between H-2K^bm1 and H-2D^d.Abbreviations used in this paper TNP trinitrophenol - PFU plaque forming unit - Con A Concanavalin A - BSS balanced-salt-solution - FCS fetal calf serum - TNBS trinitrobenzene sulfonic acid - PBS phosphate-buffered-saline     

Major histocompatibility complex class II-regulated immunity to murine leukemia virus protects against early T- but not late B-cell lymphomas

We studied the relative importance of class I and class II major histocompatibility complex (MHC) immunoregulation in the control of T- and B-cell lymphomas induced by murine leukemia virus. Previously, we have described a mink cell focus-inducing (MCF) murine leukemia virus, MCF 1233, which induces not only lymphoblastic T-cell lymphomas but also follicle center cell or lymphoblastic B-cell lymphomas. We now report that the outcome of neonatal infection with MCF 1233 in H-2-congenic C57BL/10 and C57BL/6 mice is decisively influenced by the H-2 I-A locus. A total of 64% of H-2 I-Ak, d mice [B10.BR, B10.D2, B10.A(2R), B10.A(4R), and B10.MBR] developed T-cell lymphomas after MCF 1233 infection (mean latency, 37 weeks). In contrast, H-2 I-Ab [B10, B10.A(5R), B6], H-2 I-Ab/k [(B10.A x B10)F1 and (B10 x B10.A)F1], and H-2 I-Abm12 (bm12) mice were resistant against T-cell lymphomagenesis, but 65% of these H-2 I-Ab, b/k, bm12 animals developed B-cell lymphomas (mean latency, 71 weeks). Animals of T-cell lymphoma-susceptible strains that escaped from T-cell lymphomagenesis developed B-cell lymphomas with similar frequency as animals of T-cell lymphoma-resistant strains, but with a shorter latency. H-2 class II-determined regulation of antiviral immunity was reflected in the presence of high titers of antiviral envelope antibodies in T-cell lymphoma-resistant B-cell lymphoma-susceptible H-2 I-Ab, b/k, bm12 mice, whereas in T-cell lymphoma-susceptible H-2 I-Ak,d mice no antiviral antibodies were found. At week 4 after neonatal MCF 1233 infection, a high percentage of thymocytes were virally infected in both T-cell lymphoma-susceptible and -resistant mice. However, T-cell lymphoma-resistant animals cleared the thymic infection between weeks 4 and 10 of age, coinciding with a sharp rise in serum levels of antiviral antibodies. We conclude that the pleiotropic effects of MCF 1233 infection in H-2-congenic mice result from MHC class II I-A-determined T-cell response differences.     

Tolerance induction of allo-class II H-2 antigen-reactive L3T4+ helper T cells and prolonged survival of the corresponding class II H-2-disparate skin graft

The present study investigates the effects of i.v. presensitization with class II H-2-disparate allogeneic cells on various L3T4+ T cell functions including the capability of rejecting the corresponding allogeneic skin graft. C57BL/6 (B6) mice were i.v. presensitized with class II H-2 disparate B6-C-H-2bm12 (bm12) spleen cells. Such presensitization did not affect the bm12-specific L3T4+ T cell-mediated proliferative and interleukin 2 (IL-2)-producing capacities. A single cell suspension of (B6 x bm12)F1 spleen cells was depleted of APC by two round-passages over Sephadex G-10 columns. This APC-depleted fraction of (B6 x bm12)F1 cells failed to stimulate B6 responding cells in mixed lymphocyte reactions (MLR). The addition of recombinant IL-1 to the MLR restored anti-bm12 MLR responses, indicating that APC-depleted (B6 x bm12)F1 cells bear bm12 alloantigens but are unable to stimulate B6 anti-bm12 L3T4+ T cells. A single i.v. administration of APC-depleted (B6 x bm12)F1 cells into B6 mice resulted in almost complete abrogation of the capacity of recipient B6 lymphoid cells to give anti-bm12 MLR and IL2 production. This suppression was bm12 alloantigen-specific and attributed to the elimination or functional impairment of anti-bm12 T cell clones rather than the induction of suppressor cells. The tolerance was also observed in graft-rejection responses. The strikingly prolonged survival of bm12 skin grafts was produced when grafts were implanted into B6 mice which had been presensitized with APC-depleted, but not with untreated (B6 x bm12)F1 spleen cells. These results indicate that allo-class II H-2 antigen-reactive L3T4+ T cells are rendered tolerant by i.v. presensitization with APC-depleted fraction of the corresponding allogeneic cells.     

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.     

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)     

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.     

Class I MHC genes and CD8+ T cells determine cyst number in Toxoplasma gondii infection

To determine roles of MHC class I and II genes in protection against Toxoplasma gondii, H-2 congenic and mutant mice were infected perorally with bradyzoites of T. gondii and brain cysts were enumerated 30 days later. As B10 mice (H-2b) are cyst susceptible and B10.A mice (H-2a) are cyst resistant, B10 congenic mice having the same alleles but different H-2 haplotypes were used to locate the controlling gene. Genes located at H-2L (i.e., class I genes) were found to regulate the number of brain cysts which form following peroral infection with T. gondii (p less than 0.001) with Ld being resistant and Lb being susceptible. The regulatory function of the H-2L gene product was confirmed through the study of D mutant (dm) mice. B10.D2-H-2dm1 (dm1) mice have a gain-loss mutation in Dd and Ld (i.e., recombination of Ld and Dd) and BALB/c-H-2dm2 (dm2) mice have a deletion of the Ld gene. Both these dm strains were cyst susceptible (p less than 0.001). These results provide the first direct evidence that class I genes regulate numbers of T. gondii cysts that form. In vivo ablation of CD8+ T cells with mAb YTS 169.4 converted cyst resistant B10.BAR12 mice to cyst susceptible. This result is consistent with a role for MHC restricted CD8+ cytotoxic (or suppressor) T cell regulation of cyst formation. A mutation in Ia in B6.C-H-2bm12 (bm12) mice amplified cyst numbers in susceptible mice, which is consistent with the importance of helper/inducer T cells in the induction of cytotoxic T cells. These findings are relevant to understanding the complex immunologic mechanisms that protect against T. gondii infection, development of protective preparations, and provide a conceptual basis for determining whether similar immunogenetic regulation of susceptibility is also operative in humans.     

The BM12 mutation and autoantibodies to dsDNA in NZB.H-2bm12 mice

Molecular and genetic tools have been used to shed light on the genes that contribute to susceptibility to murine lupus and the mechanisms that lead to immunopathology. The MHC genes and their products have been consistently shown to contribute toward the development of disease. To understand the contribution of MHC-class II genes, our laboratory had derived two inbred strains of mice, NZB.H-2bm12 and NZB.H-2b. These new colonies of mice were studied and compared in the 10th generation backcross; inbreeding was serially followed by H-2 typing, responses to beef/porcine insulin, and the presence of the B6 Ig allotype, IgG2ab. Of great interest is the finding that NZB.H-2bm12, in contrast to NZB.H-2b or NZB (H-2d), mice develop high titer autoantibodies to dsDNA. This result is unique because NZB (H-2d) mice, unliked NZB x NZW (NZB/W F1) or NZB x SWR (SNF1) hybrids do not develop autoantibodies to dsDNA, even after immunization. NZB mice, in contrast, are characterized only by autoantibodies to ssDNA. Our observation is also striking because the gene conversion that resulted in the I-A beta bm12 mutation occurred at amino acid residues 68, 71, and 72 of I-E beta b. Recently the contribution of NZW to accelerated autoimmunity in the NZB x NZW F1 hybrid has also been linked to H-2 and a single amino acid change at amino acid 72 of I-E beta. Thus, amino acid residue 72 may be a hot spot for disorders of immune regulation when superimposed on the appropriate genetic background. NZB mice expressing the I-Abm12 mutation will allow specific dissection of the requirements for autoantibody production to dsDNA uncomplicated by heterozygosity.     

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.     

Abrogation of hybrid resistance to bone marrow engraftment by graft-vs-host-induced immune deficiency

Lethally irradiated F1 mice, heterozygous at the hematopoietic histocompatibility locus Hh-1, which is linked with H-2Db, reject bone marrow grafts from H-2b parents. This hybrid resistance (HR) is reduced by prior injection of H-2b parental spleen cells. Because injection of parental spleen cells produces a profound suppression of F1 immune functions, we investigated whether parental-induced abrogation of HR was due to graft-vs-host-induced immune deficiency (GVHID). HR was assessed by quantifying engraftment of H-2b bone marrow in F1 mice with the use of splenic [125I]IUdR uptake; GVHID, by the ability of F1 spleen cells to generate cytotoxic T lymphocytes (CTL) in vitro. We observed a correlation in the time course and spleen cell dose dependence between loss of HR and GVHID. Both GVHID and loss of HR were dependent on injection of parental T cells; nude or T-depleted spleen cells were ineffective. The injection of B10 recombinant congenic spleens into (B10 X B10.A)F1 mice, before grafting with B10 marrow, demonstrated that only those disparities in major histocompatibility antigens that generated GVH would result in loss of HR. Thus, spleens from (B10 X B10.A(2R]F1 mice (Class I disparity only) did not induce GVHID or affect HR, whereas (B10 X B10.A(5R))F1 spleens (Class I and II disparity) abrogated CTL generation and HR completely. GVHID produced by a class II only disparity, as in (B10 X B10.A(5R))F1 spleens injected into (B6bm12 X B10.A(5R))F1 mice, was also sufficient to markedly reduce HR to B10 bone marrow. This evidence that GVHID can modulate hematopoietic graft rejection may be relevant to the mechanisms of natural resistance to marrow grafts in man.     

Cross-reactivity patterns of influenza-specific cytotoxic T lymphocytes from H-2Kb mutant mice

Limit dilution cultures were used to test for influenza immune T cell populations from bm1 and bm3 mutant mice that were not lytic for virus-infected targets expressing the Kb and Db major histocompatibility complex glycoproteins. Both Kbm3- and Kbm1-restricted cytotoxic T cells were detected. Such effectors showed minimal cross-recognition of influenza on other mutant targets, except for the case of bm1 and bm10 targets. This is dissimilar to previous findings concerning vaccinia presentation in which bm3+bm11, bm1+bm9, and bm3+bm9 pairs each showed high cross-reactivity. These differences illustrate the role of the H-2K glycoprotein in immune responsiveness. Not only are multiple determinants on each H-2K glycoprotein involved in antigen presentation, they appear to play differential roles in the presentation of different viral antigens.     

Studies ofH-2K b mutant mice

Three newH-2 ^b mutant strains, B6.C-H-2 ^bm9 , B6.C-H-2 ^bm10 and B6.C-H–2 ^bm11 , are described. The three mutant strains are of the gain and loss type as they reject skin grafts reciprocally with the parental C57BL/6Kh. The mutations, which arose independently, are all allelic at the same locus as 11 other mutant strains already described. By complementation and other studies the mutated gene has been shown to beH-2K ^b . The strains were typed directly and by absorption with antisera specific for H-2K^b and H-2D^b private and public specificities and for Ia^b specificities. Each strain typed differently with these sera. The strain B6.C-H-2 ^bm9 was found to be serologically identical with C57BL/6. The strains B6.C-H-2 ^bm10 and B6.C-H-2 ^bm11 were found to have alterations in the private H-2K^b specificity, H-2.33, and in the public specificity, H-2.5, but to a different extent. B6.C-H- 2^bm10 had a marked decrease in the amount of H-2.33 expressed on the splenic cell surface as compared to C57BL/6 and also has a marked decrease in the expression of H-2.5 on both spleen and red blood cells. In comparison, B6.C-H-2 ^bm11 has a decrease in the expression of H-2.33 but an increase in the expression of H-2.5 on both splenic and red blood cells. The other H-2^b specificities appeared to be unaltered as compared with C57BL/6.     

Separation of the immune response genes for LDH-B and MOPC-173. I. Description of an immune response defect in B10.BASR1

By using the intra-I-region recombinant mouse strain, B10.BASR1 (H-2as4), the immune response (Ir) genes for LDH-B and MOPC-173 were genetically and serologically separated, as assayed by T cell proliferation. Previous work demonstrated that the H-2s and H-2b strains respond to LDH-B and MOPC-173, whereas the H-2a and H-2k strains failed to respond due to haplotype-specific suppression of I-Ak-activated T helper cells by I-Ek-activated T suppressor cells. In the experiments reported here, B10.BASR1 mice, which lack I-Ek expression, mounted a significant T cell proliferative response to MOPC-173 but not to LDH-B. Separation of the Ia determinants used in restricting these two antigen responses was further confirmed when pretreatment of B10.S(9R) (A alpha sA beta sE beta sJk) macrophages with A.TL anti-B10.HTT (anti-A beta sE beta sJs) serum absorbed with B10.BASR1 spleen cells blocked the LDH-B response but not the MOPC-173 response. Unabsorbed serum blocked both antigen responses. The primary immunogenic determinant recognized by LDH-B or MOPC-173 immune T cells was not present on both antigens, as MOPC-173-primed T cells and LDH-B-primed T cells responded only to the priming antigen. Lastly, by using the A beta mutant strain, B6CH-2bm12, it was shown that the Ir gene and Ia determinants affected by this mutation had no effect on the LDH-B and MOPC-173 proliferative responses. These results suggest the possibility of an intragenic recombinatorial event in either the A alpha or A beta chain resulting in the separation of these two immune response gene functions.     

Restriction in adoptive transfer of resistance to Listeria monocytogenes. II. Use of congenic and mutant mice show transfer to be H-2K restricted

Adoptive transfer of cell-mediated immunity to the facultative intracellular bacterium Listeria monocytogenes is restricted by the H-2 complex of mice. Using C57BL/10 and C57BL/6 congenic strains of mice it was shown that compatibility of the H-2K locus, not the I region, was essential and sufficient for adoptive transfer and that H-2D compatibility was not relevant. Mutation at the H-2K locus prevented adoptive transfer, while mutation at the Ia-1 locus, as in the B6.C-H-2bm12 mutant of C57BL/6, did not affect adoptive transfer. The contrast between these findings and the previously accepted I region restriction of adoptive transfer of Listeria immunity is discussed.     

Reactivity of the B6.C-H-2bm−1 mutant to the wild-type tumor EL4: Characterization of the serological response

Hyperimmunization of B6.C-H-2^bm?1 (H-2^bm?1), a congenic mutant of C57Bl/6J (B6), with the C57Bl lymphoma EL4 resulted in the induction of antibodies with apparent EL4 specificity. EL4 reactivity was demonstrable in H-2^bm?1 anti-EL4 sera by complement-mediated cytotoxicity, absorption, and enzyme-linked immunosorbent assay. By these same serological tests, H-2^bm?1 anti-EL4 serum was found to be nonreactive with B6 normal lymphoid cells, embryonic fibroblasts, and two fibrosarcomas previously induced in B6 mice by methylcholanthrene. These data suggest that the serological response of H-2^bm?1 to EL4 is directed against tumor-associated antigens on EL4. These findings indicate that congenic mutants which differ from the wild-type strain at MHC Class I subloci, but which do not evoke serological responses to MHC components, may provide convenient sources for preparing serological reagents directed against tumor-specific antigens.