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.     

The target minor H antigen for F1 cytotoxic T lymphocytes induced by Igh-congenic parental spleen cells is coded for by gene linked to H-2

Graft-vs-host reaction (GvHR) induced in (B10.BR X CWB)F1 (BWF1; H-2k/b, Ighb/b) by i.v. injection with CWB (H-2b, Ighb) spleen cells resulted in complete suppression of cytotoxic T lymphocyte (CTL) responsiveness of the F1 host spleen cells (GvHR-associated immunosuppression). In contrast, GvHR induced in BWF1 mice with CSW (H-2b, Ighj; Igh-congenic to CWB) spleen cells did not affect CTL responsiveness of the F1 host spleen cells at all. The BWF1 hosts undergoing the CSW-induced GvHR generated anti-CSW CTL in their spleens, and the subsequent culture of such BWF1 spleen cells with CSW stimulator cells, augmented the CTL activity. The BWF1 anti-CSW CTL lysed both Con A- and LPS-induced splenic blasts from mouse strains carrying the Ighj allele in the context of self H-2Kb. However, determination of the Igh haplotype in the serum IgG and of the susceptibility of the splenic lymphocytes to the BWF1 anti-CSW CTL on backcross mice, which carry either Ighb/j or Ighb/b in the context of H-2b/b or H-2b/k, showed clearly that Ighj and the gene coding for the target antigen for the BWF1 anti-CSW CTL segregated at ratios close to 1:1. The study in which linkage between the gene(s) coding for the target antigen for the BWF1 anti-CSW CTL and H-2 was examined on CWB X (C3H X CWB)F1 backcross mice and (B10.BR X CSW)F1 X B10 mice demonstrated that the gene, most likely a single gene, coding for the target antigen for the BWF1 anti-CSW CTL is located at 8.5 +/- 4.3 cross-over units to the right or left of the H-2 complex. We designated the minor H antigen to be recognized by the BWF1 anti-CSW CTL as H-X+, and we discuss the distinction between the H-X+ locus and the other minor H loci on chromosome 17.     

In vivo priming of mouse CTL precursors directed to product of a newly defined minor H-42 locus is under a novel control of class II MHC gene

In a previous study, we discovered a new mouse minor histocompatibility antigen encoded by a locus at 8.5 cM apart from the H-2 complex, and we have since named the locus H-42. One allele of H-42, which is named H-42a, had been elucidated, but the other alleles, which we tentatively named H-42b, have not been elucidated. In the present study, we explored MHC control on the anti-H-42a cytotoxic T lymphocyte (CTL) responsiveness in H-42b mice. In vivo immunization (i.v. injection) of H-42b mice with 5 to 30 X 10(6) spleen cells (SC) bearing allogeneic H-42a antigen but carrying H-2 complex (mouse MHC) matched with the H-42b mice failed to prime anti-H-42a CTL but induced stable and specific anti-H-42a CTL unresponsiveness, i.e., tolerance, in the H-42b recipient mice. In contrast, H-2 heterozygous H-42b F1 mice injected with SC bearing H-42a alloantigen on either of the parental H-2 haplotypes were effectively primed to generate anti-H-42a CTL. Exploration of the region or subregion in the H-2 complex of H-42a donor SC that should be compatible with H-42b recipient mice for the induction of their anti-H-42a CTL tolerance demonstrated that the compatibility at I region, most probably I-A subregion, but not at K, S, or D region, determined the induction of the tolerance. MHC class II compatible H-42a skin graft (SG) to H-42b mice, however, consistently primed the anti-H-42a CTL in the H-42b recipients. These results were discussed in several aspects, including uniqueness of MHC class II control on the CTL response to minor H-42a antigen, possibility of inactivation of responding anti-H-42a precursor CTL or helper T cells in H-42b mice by encountering the veto cells present in MHC class II-matched H-42a SC population, and significance of the present observations as a mechanism of CTL tolerance to self-components.     

Cytotoxic T-lymphocyte tolerance to minor H-43a alloantigen is induced exclusively in the context of the self major histocompatibility complex class I H-2Kb molecules

We elucidated previously that cytotoxic T lymphocyte precursors (CTLp) against H-43a allo-antigen, which we had discovered as a new mouse minor H antigen, were primed in H-43b mice only in the context of self H-2Kb restriction element, and that anti-H-43a CTLp tolerance was induced in H-43b mice by injection with H-43a spleen cells (SC) from H-43 congenic mice, i.e., under the condition of disparity at only the H-43 locus. The present study attempted to determine whether the H-2Kb restriction element for anti-H-43a CTLp priming is also implicated in the induction of anti-H-43a CTLp tolerance. For this purpose, we used a newly established H-43b C3W (H-2k) strain which is H-43 congenic to H-43a C3H/HeN. When (C3W X B10.MBR)F1 (H-43b, H-2Kk/b, Ik/k, Dk/q) mice were injected with H-43a-bearing (C3H/HeN X B10.AKM)F1 (H-43a/b;H-2Kk/k,Ik/k,Dk/q)SC, their selfH-2Kb-restricted anti-H-43a CTLp were were primed (cross-priming). By contrast, injection of H-43a-bearing (C3H/HeN X B10.MBR)F1 (H-43a/b; H-2Kk/b,Ik/k, Dk/q)SC, which differ from (C3H/HeN x B10.AKM) F1 SC solely at H-2K and possess H-2Kb molecules, did not prime but specifically inactivated the anti-H-43a CTLp of (C3W x B10.MBR)F1 mice. These results indicate clearly that anti-H-43a CTLp tolerance is induced exclusively in the context of the H-2Kb element expressed on the antigenic H-43a SC.     

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.     

Dissociation of H-2 recognition by antibody and cytotoxic T cells of a cloned murine leukemia cell line

The differential expression of H-2 specificities recognized by antibody and by cytotoxic T lymphocytes (CTL) has been studied using a clone (FY7) of the C57BL/6 leukemia cell line FBL-3 (H-2b/H-2b). Unlike C57BL/10 spleen cells, EL-4 lymphoma cells and Y57-2C leukemia cells (all H-2b/H-2b), FY7 failed to induce the primary in vitro generation of anti-H-2b CTL by (B10.A x A)F1 (H-2a/H-2a) or B10.D2 x BALB/c)F1 (H-2d/H-2d) responder spleen cells. In addition, FY7 was not lysed by, and did not competitively inhibit anti-H-2b CTL. Quantitative absorption tests with H-2Kb and H-2Db antisera revealed that FY7 expressed these antigens in quantitatively similar amounts to EL-4. The H-2Kb product of FY7 appeared to be identical with that of C57BL/10 spleen cells both in apparent molecular weight and isoelectric point. Yet FY7 failed to inhibit anti-H-2Kb CTL competitively in a cold target inhibition assay. Possible mechanisms are discussed for the lack of T-lymphocyte recognition of the H-2Kb-gene product expressed by FY7.     

Cytotoxic T lymphocyte responses to minor H-43 alloantigens in H-43a and H-43b mice. Both anti-H-43b and anti-H-43a CTL activities are generated exclusively in the context of the same H-2Kb restriction element

We have previously demonstrated that anti-H-43a CTL response of H-43b responder mice was exclusively restricted by self H-2Kb (Kb) but not by the other nine self MHC class I alleles from independent origins, i.e., Kbml,d,k,s and Db,d,k,q,s. In the present study, we verified that Kf,q,r and Df,r alleles could also not serve as restricting class I elements in the CTL response to H-43a alloantigen. Another notable observation made in the earlier study was the fact that, in H-43 incompatibility of the alternative combination, H-43a mice were incapable of generating CTL activity against H-43b alloantigen. However, by means of employing new in vivo immunization procedures, we discovered that some but not all genetically identical H-43a responder mice could mount anti-H-43b CTL response restricted by self Kb. Again, no anti-H-43b CTL activity could be generated in the context of self Kk, Kj, Db or Dk molecules. Although the number of class I alleles we examined is still limited, these results indicate that antigenic fragments derived from the processed H-43a and H-43b alloantigens possess an indistinguishable epitope (agretope), and that such agretope either interacts only with the privileged Kb molecules or allows to bestow the immunogenic conformation of allodeterminants on the fragments solely in the context of the restricting Kb element.     

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.     

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)     

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.     

The nature of hemopoietic histocompatibility determinants. Differential sensitivity of Hh-1b and H-2b determinants to tunicamycin

NK cell-dependent resistance of F1 hybrid mice to parental H-2b hemopoietic allografts is directed to cell surface structures controlled by the Hh-1 locus in or near the H-2D region. Crucial to an understanding of this enigmatic phenomenon is the information on the biochemical nature of the Hh-1 locus-controlled structures. Therefore, we examined the effect of tunicamycin (TM), an inhibitor of asparagine-linked glycosylation and ganglioside biosynthesis, on the expression of Hh-1 determinants in H-2b/Hh-1b lymphomas. The Hh-1b determinants on EL-4 and RBL-5 cells were no longer detectable after TM treatment, as demonstrated by the failure of the treated cells to inhibit hybrid resistance to parental H-2b bone marrow cells in vivo. This interpretation was supported by the unaltered ability of the TM-treated cells to localize in the spleens of irradiated F1 hybrid recipients. In contrast, TM caused only moderate reduction in H-2Kb and H-2Db expression as measured by binding of specific antibodies. This was accompanied by reduced susceptibility to alloimmune anti-H-2Db CTL, but not to anti-H-2Kb CTL. No decrease was found in the susceptibility to NK cell cytotoxicity in vitro. These data indicate that N-linked glycosylation or ganglioside synthesis is crucial for the expression of the Hh-1 locus-controlled target structures, but not for the H-2 class I molecules. The data also show that the Hh-1b determinants are substantially different from those which confer the susceptibility to NK cell-mediated in vitro cytotoxicity.     

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.     

Failure or success in the restoration of virus-specific cytotoxic T lymphocyte response defects by dendritic cells

C57BL/6 (B6, H-2b) mice are CTL responders to both Sendai virus and Moloney leukemia virus. In the former response the H-2Kb class I MHC molecule is used as CTL restriction element, in the latter response the H-2Db molecule. B6 dendritic cells (DC) are superior in the presentation of Sendai virus Ag to CTL in comparison with B6 normal spleen cells. Con A blasts have even less capacity to present viral Ag than NSC, and LPS blasts show an intermediate capacity to present viral Ag. H-2Kb mutant bm1 mice do not generate a CTL response to Sendai virus, but respond to Moloney leukemia virus, as demonstrated by undetectable CTL precursors to Sendai virus and a normal CTL precursor frequency to Moloney virus. Compared to B6 mice, other H-2Kb mutant mice show decreased Sendai virus-specific CTL precursor frequencies in a hierarchy reflecting the response in bulk culture. The Sendai virus-specific CTL response defect of bm1 mice was not restored by highly potent Sendai virus-infected DC as APC for in vivo priming and/or in vitro restimulation. In mirror image to H-2Kb mutant bm1 mice, H-2Db mutant bm14 mice do not generate a CTL response to Moloney virus, but respond normally to Sendai virus. This specific CTL response defect was restored by syngeneic Moloney virus-infected DC for in vitro restimulation. This response was Kb restricted indicating that the Dbm14 molecule remained largely defective and that a dormant Kb repertoire was aroused after optimal Ag presentation by DC. In conclusion, DC very effectively present viral Ag to CTL. However, their capacity to restore MHC class I determined specific CTL response defects probably requires at least some ability of a particular MHC class I/virus combination to associate and thus form an immunogenic complex.     

Inhibition of cytolytic T lymphocyte clones reactive with Moloney leukemia virus-associated antigens by monoclonal antibodies: a direct approach to the study of H-2 restriction

H-2 restriction in cytolytic T lymphocyte (CTL)-mediated lysis of syngeneic murine Moloney leukemia virus (MoLV)-induced tumor cells was studied at the clonal level by testing the inhibitory effect of monoclonal anti-H-2 antibodies on the lytic interaction between CTL clones and target cells. Large numbers of MoLV-specific CTL clones were generated by placing limiting numbers of C57BL/6 regressor (responder) spleen cells into micro-mixed leukocyte-tumor cell cultures. The clonal CTL populations thus obtained were split into 5 aliquots and tested for lytic activity in the presence (or absence) of 1 of 3 monoclonal antibodies or of an anti-whole H-2b haplotype antiserum. Two of the monoclonal antibodies were directed against H-2Db and one against H-2Kb determinants. Specificity of these reagents had been verified by demonstrating inhibition of lysis by CTL populations directed against H-2Db and H-2Kb alloantigens. In 44 of a total of 51 clones tested, results showed selective inhibition by the anti-H-2Db (and the anti-whole haplotype) reagents, and lack of inhibition by the anti-H-2Kb antibody., Of the remaining 7 clones, none was inhibited by the anti-H-2Db antibody, and 3 were inhibited by the anti-whole haplotype antiserum. These studies show that the recognition of MoLV-associated antigens by the majority of CTL clones was restricted to the H-2Db region, and that there exists limited heterogeneity in the H-2 restriction of such clones.     

Idiotype-specific T lymphocytes. I. Regulation of antibody production by idiotype-specific H-2-restricted T lymphocytes

Cytotoxic T lymphocytes (CTL) specific for MOPC-104E myeloma cells of BALB/c origin could be induced in BALB/c, (BALB/c X BALB.B)F1, and (BALB/c X BALB.K)F1 mice. (BALB/c X BALB.B)F1 CTL activity specific for MOPC-104E was effectively inhibited by anti-H-2d but not by anti-H-2b alloantiserum. However, the activity was hardly blocked by specific anti-idiotypic antibodies to MOPC-104E. For further analysis of the recognition of idiotype on target cells by CTL, the effect of those lymphocytes on anti-dextran B1355S antibody-producing B lymphocytes, which have a cross-reactive idiotype to MOPC-104E, was investigated. Lymphocytes from the CTL population did inhibit antibody production by dextran-immune spleen cells, but those from the CTL population specific for irrelevant myeloma cells (MOPC-167) did not. The (BALB/c X BALB.K)F1 CTL population suppressed the antibody production of BALB/c but not of BALB.K. This indicates that F1 cells can preferentially see H-2 antigens of immunizing myeloma cells on target B lymphocytes. The inhibition of antibody production was antigen specific and was only restricted to the PFC that were inhibitable by anti-idiotypic antibodies. The surface phenotypes of the cells that inhibited the antibody production were Thy-1+, Lyt-1-, Lyt-2+, and I-J-. These results strongly suggest that CTL specific for MOPC-104E recognize self H-2 antigens simultaneously with idiotypic determinants on B lymphocytes. Possible immunoregulatory roles of idiotype-specific CTL on antibody production systems are also suggested.     

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.     

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.     

Cell-mediated lympholysis responses against autologous cells modified with haptenic sulfhydryl reagents. IV. Self-determinants recognized by wild-type anti-H-2Kb and H-2Db-restricted cytotoxic T cells specific for sulfhydryl and amino-reactive haptens are absent in certain H-2 mutant strains

Virus-specific H-2-restricted cytotoxic T cells (CTL) have been found to discriminate between wild-type and mutant class I molecules. The only results reported concerning a hapten-self model, however, indicate that TNP-specific CTL do not discriminate between wild-type and mutant self determinants (7). In the present study, hapten-specific CTL generated against N-iodoacetyl-N'-(5-sulfonic-1-naphthyl) ethylene diamine-modified syngeneic cells (AED-self) were used to determine whether a hapten that is known to react with different cell surface sites than TNP can induce CTL that distinguish mutant H-2K and D molecules from those of wild type. The findings of this study indicate that H-2Kb-AED-self cytotoxic effector cells can discriminate between self-determinants of H-2Kb wild-type and the H-2bm1 and H-2bm11 mutants, but not between wild-type and the H-2bm6 and H-2bm9 mutants. H-2Db-AED-self effector cells were also found to discriminate between self-determinants of H-2Db wild-type and the H-2bm13 and H-2bm14 mutants. Furthermore, cold target competition experiments indicated that the bm1 and bm11 Kb products also lack some determinants recognized by anti-wild-type Kb TNP-specific CTL. These findings provide the first demonstration that hapten-self-specific effectors can detect alterations in H-2 mutant class I molecules. The results in the present report also support the hypothesis that haptens do not have to derivatize H-2 molecules in order to form antigens recognized by H-2-restricted CTL. These findings are discussed with respect to the involvement of self-determinants on MHC and non-MHC cell surface molecules.     

Induction in vivo of specific T suppressors in mice of mutant lines H-2KbT

The differences in the generation of specific suppressor T cells (SSTC) against H-2Kb wild type were investigated in H-2Kbm1, H-2Kbm3 and H-2Kbm4 mutants. Anti-Kb SSTC were produced only by bm3 mutant and F1(BALB/c X bm3) hybrid. T-cell nature of SSTC of bm3 mutant was confirmed by anti-Thy 1.2 monoclonal antibodies described in the same study.     

Cross-reactive recognition of mouse cells expressing the bm3 and bm11 mutations within H-2Kb by H-2Kb-restricted herpes simplex virus-specific cytotoxic T lymphocytes

Cytotoxic T lymphocytes, generated in C57BL/6 mice in response to herpes simplex virus type 1 (HSV) and known to be restricted in their recognition of HSV-encoded antigen(s) in association with the class I H-2Kb gene product, were consistently found to contain a subpopulation that recognized and lysed uninfected, SV40-transformed cells that expressed the H-2Kbm3 and H-2Kbm11 mutant class I gene products on their cell surface. The mutant cell lines, designated Lgbm3SV and Kbm11SV, share a common amino acid substitution at position 77, with the bm3 mutation having an additional amino acid substitution at position 89. Cross-reactive lysis was observed only after in vivo priming with HSV, suggesting an important role for an antigen-dependent driving step in the expansion of these cross-reactive CTL. The phenotype of the cross-reactive effector population was further confirmed as a T lymphocyte by negative-selection techniques. Limiting dilution analysis of the frequency of cross-reactive CTL precursors suggested that cross-reactivity was mediated by a subpopulation of HSV-specific CTL, and this was confirmed by clonal analysis of the reactivity patterns of short-term, HSV-specific CTL clones. However, analysis of the specificity of the cross-reactive CTL population by cold-target inhibition of bulk culture-derived CTL, or by Spearman ranking analysis of limiting dilution-derived CTL, indicated that the specificity of the cross-reactive population for HSV-infected H-2b target cells and for uninfected bm3 or bm11 target cells was quite distinct. These findings suggested that the cross-reactive CTL population played little, if any, role in the HSV-specific CTL response as measured in vitro. The findings also suggested that the HSV-specific CTL clones able to mediate cross-reactive recognition of the bm3 and bm11 targets had a higher intrinsic avidity for the foreign target than for the inducing antigen.