The cytotoxic T cell response to the male-specific histocompatibility antigen (H-Y) is controlled by two dominant immune response genes, one in the MHC, the other in the Tar alpha-locus

Interaction between certain major histocompatibility complex class II and T-cell receptor V beta alleles promotes the antibody production to extractable nuclear antigen-related peptides

Our objective was to study the interaction between major histocompatibility complex (MHC) class II and T-cell receptor (TCR) alleles in the recognition of extractable nuclear antigen-derived peptides in 32 patients with systemic lupus erythematosus and 173 of their family members. MHC genes were analyzed using sequence specific oligonucleotides, and TCR beta-chain gene polymorphism using restriction fragment-length polymorphism. One dominant peptide (as defined by enzyme-linked immunosorbent assay autoantibody reactivity) was identified in each antigen studied: peptide 1-20 in Sm-D, peptide 35-58 in U1-RNP-A, and peptide 304-324 in the Ro/SSA 60 Kd protein. None of the MHC class II and TCR beta haplotypes was directly associated with any of the autoantibodies. Twenty-six subjects had antibodies to the peptide Sm-D1-20; nine of them were DRB1*0101/DQB1*0501. Among subjects with this haplotype, the number of responders was higher (p < 0.028, p corrected, pc = 0.336) in those with the 2-25-9 TCR beta haplotype than in the remainder. Conversely, the number of DRB1*04/DQB1*0302 responders was lower (p < 0.030, pc = 0.360) among subjects with the 23-20-9 TCR beta haplotype than in those without. The odds ratios (OR) were 4.23 and 0.21, respectively. Of the 54 subjects positive for anti-U1-RNP-A 35-38, 13 were DRB1*0101/DQB1*0501 and eight DRB1*04/DQB1*0302. The percentage of responders was higher (p < 0.041, pc = 0.492, OR = 3.48) in the former group of subjects with the 2-25-9 TCR beta haplotype, and lower (p < 0.02, pc = 0.024, OR = 0.09) in the latter with the 23-20-9 TCR beta haplotype. Three of the 12 anti Ro/SSA 60Kd 304-324-positive subjects were DRB1*0101/DQB1*0501. All had the 2-25-9 TCR beta haplotype (p < 0.046, pc = 0.552, OR = 6.29) and none the 23-20-9 (p < 0.031, pc = 0.372, OR = 0.10). The same combinations of genes were associated with high/low response toward the three peptides. These data provide evidence for an interplay of the MHC class II and TCR beta alleles in the control of specific autoantibody response to well-defined nuclear Ag peptides.

Defective IgE production by SJL mice is linked to the absence of CD4+, NK1.1+ T cells that promptly produce interleukin 4

SJL mice produce little or no IgE in response to polyclonal stimulation with anti-IgD antibody and fail to express interleukin 4 (IL-4) mRNA in the spleen 5 days after injection of anti-IgD, in contrast to other mouse strains that produce substantial amounts of IgE and IL-4. Because IL-4 is critical in IgE production, the possibility that SJL mice are poor IgE producers because their naive T cells fail to differentiate into IL-4 producers must be seriously considered. IL-4 itself is the principal factor determining that naive T cells develop into IL-4 producers. A major source of IL-4 for such differentiation is a population of CD1-specific CD4+ T cells that express NK1.1. These cells produce IL-4 within 90 min of anti-CD3 injection. T cells from SJL mice fail to produce IL-4 in response to injection of anti-CD3. Similarly, SJL T cells and CD4+ thymocytes do not produce IL-4 in response to acute in vitro stimulation. SJL T cells show a marked deficiency in CD4+ cells that express the surface receptors associated with the NK1.1+ T-cell phenotype. This result indicates that the SJL defect in IgE and IL-4 production is associated with, and may be due to, the absence of the CD4+, NK1.1+ T-cell population.

The IE allogeneic response of T cells from C57Bl/6 mice is associated with genes in the TCRa locus

It has been demonstrated that induction of immune responses, infectious diseases and autoimmune manifestations can be associated with at least four gene loci: the major histocompatibility complex (MHC) locus; the immunoglobulin (Ig) heavy chain (Hc) locus; and the T-cell receptor (TCR) TCR-alpha or TCR-beta chain loci. In the present study, we have analysed whether T-cell responses of IE-negative C57Bl/6 (B6) mice to IE alloantigen (IE alpha transgenic B6 mice = B6.E alpha 16) or to trinitrophenylated (TNP) syngeneic spleen cells were influenced by changes in the Ig-Hc locus or the TCRa locus. Whereas the fine specificity of T-cell responses to IE alloantigen was the same in B6 mice and in Ig-Hc congenic B6.26a or TCRa congenic B6.10TCa mice, the latter strain of mice demonstrated much higher IE-specific T-cell responses against B6.E alpha 16 spleen cells than B6 or B6.26a mice. This high responsiveness was a dominant feature and associated with the TCRa locus. In addition, the TCRV alpha or V beta repertoire of the congenic strains of mice was polyclonal and very similar. The TNP-specific T-cell responses of B6 and B6.10TCa mice showed the same restricted TCRV alpha and V beta repertoire. It is concluded that in both an oligoclonal T-cell response (anti-TNP) and a polyclonal T-cell response (anti-IE), exchange of Ig-Hc or TCRa loci does not significantly influence the TCRV alpha or V beta repertoire in IE-negative C57Bl/6 mice.

Genetic control of Coxsackievirus B3-induced heart-specific autoantibodies associated with chronic myocarditis

Cardiac-specific autoantibodies to sarcolemmal and cardiac myosin antigens observed during the chronic phase of Coxsackievirus B3-induced myocarditis appear to be under autosomal recessive control. This observation is based on examination of F1 hybrids bred from A/J mice which develop chronic myocarditis and C57BL/6J mice which resolve the virus-induced lesions. Previous mouse studies demonstrated that the prevalence of heart-specific autoantibodies varied with the H-2 complex. However, in 25 H-2 congenic mouse strains the strain background was the predominant determinant of autoantibody presence. Recently, we extended our genetic evaluation of the chromosomal locations governing autoantibody responses by examining 25 AXB and BXA recombinant inbred strains. Two populations of heart-specific autoantibodies were demonstrated against sarcolemmal and cardiac myosin antigens. Analyses of the AXB/BXA strain distribution patterns for these two traits revealed that the anti-sarcolemmal response was controlled by a gene(s) linked to Np-2 and Ter alpha loci on chromosome 14. Linkage could not be assigned for the anti-cardiac myosin response.

Limitations in plasticity of the T-cell receptor repertoire

How constrained is T-cell recognition? Is a truncated T-cell receptor (TCR) repertoire, missing half of its V beta components (where V indicates variable), still broad enough to produce an antigen-specific T-cell response to all determinants? These questions can be answered for certain T-cell antigenic determinants whose response in the wild type is limited to specific gene segments. Our results show that mice with such a deletion in their TCR V beta genes (V beta truncated haplotype, Va beta) are unable to respond to two antigen determinants (sperm whale myoglobin 111-121/I-Ed and myelin basic protein 1-11/I-Au) whose response in the wild type is restricted to the missing V beta (V beta 8.2 in the case of 111-121/I-Ed and V beta 8.2 and V beta 13 in the case of 1-11/I-Au) gene segments. Fundamentally, this restriction could have been attributed to another aspect of immunodominance--that a favored TCR with high affinity would dominate the response, but in its absence, a hierarchy of T cells with lesser efficiency and expressing alternate TCR V genes could take over. However, from our experiments it has become evident that there is an absolute limit to the flexibility inherent in the TCR repertoire. Since it is clear that mouse populations have many ambient deletion ligands (such as self-superantigens) that can result in the loss of multiple V beta gene segments during normal T-cell development, these deletions can have serious consequences, such as unresponsiveness to the antigen as a whole--a hole in the repertoire--if a dominant determinant of that antigen normally shows restricted TCR V beta gene usage.

The contribution of non-MHC genes to susceptibility to autoimmune diseases

Genetic studies of experimental models of autoimmune diseases, including systemic lupus-like syndromes and organ-specific autoimmunity, provide major information on genetic control of autoimmune diseases. In addition to genes known to be linked to the major histocompatibility complex (MHC), these studies point to multiple genes located outside the MHC that influence the onset and the progression of autoimmune diseases. Identification of these genes and of their interrelationships is now a major task that will be facilitated by recent progress in molecular biology and gene mapping. Among candidate genes, antigen-receptor genes (i.e., immunoglobulin- and T-cell receptor genes) most likely contribute an important part of the autoimmune susceptibility in several of these animal models. Available linkage data suggest a similar involvement of these antigen-receptor genes in several human autoimmune diseases. In addition to a better understanding of pathogenic mechanisms associated with autoimmunity, the knowledge of these disease-predisposing genes is expected to permit a better classification of often complex syndromes as well as the design of new treatments.

Genetic differences in the T cell receptor alleles of LEW rats and their encephalomyelitis-resistant derivative, LER, and their impact on the inheritance of EAE resistance

Experimental allergic encephalomyelitis (EAE) is an animal model for the human disease, multiple sclerosis. The LEW rat strain is very susceptible to induction of EAE, whereas the closely related, major histocompatibility complex (MHC)-identical, inbred strain LER is resistant. In this report, the two rat strains have been compared for differences at a number of immunologically relevant loci by restriction fragment length analysis and by nucleotide sequencing. A major difference between the two strains was discovered at the T cell receptor beta chain locus (TcR beta). Both variable (V beta 8) and constant (C beta 1) region elements of TcR beta showed allelic variation between LEW and LER. The known genetic influences in rat models of autoimmunity are currently limited to those encoded by the rat MHC, RT-1. In this study we report our characterization of the allelic differences in TcR beta chains between two rats which differ in their susceptibility to induced EAE, with the goal of understanding the role played by these allelic forms of TcR in the pathogenesis of EAE. The importance of the TcR beta allelic difference in resistance or susceptibility to EAE was assessed in a study of backcross rats scored for both EAE and for the novel LER TcR beta allele. We found that the TcR beta allele from the susceptible strain was present in three out of four susceptible rats, suggesting that it is an important, but not the only, genetic factor in EAE. Supporting this conclusion were the observations that 12 of 13 rats with homozygous LER-derived TCR beta alleles were resistant to EAE.

Susceptibility to Coxsackievirus B3-induced chronic myocarditis maps near the murine Tcr alpha and Myhc alpha loci on chromosome 14

This study was undertaken to determine the genetic control of host susceptibility to coxsackievirus B3 (CVB3)-induced chronic myocarditis in a mouse model. An autosomal recessive autoimmune myocardial disease (amd) gene (possibly more than one gene), which determined susceptibility to CVB3-induced chronic myocarditis in the A/J and DBA/2J inbred mouse strains, was mapped to a segment of chromosome 14. Data from both the AXB/BXA recombinant inbred (RI) strains and the B10.D2(57N) H-8b congenic mice supported this linkage relationship. Analysis of the AXB/BXA RI strain distribution patterns suggested that amd maps distal to the Np-2, Tcr alpha, and Myhc alpha loci.

No recombinations between Tcra-V and Tcra-C gene segments in 669 backcross mice

Because T-cell receptor (Tcr) genes may possibly function as non-major histocompatibility complex (MHC) immune response genes or predispose for autoimmune diseases, it is important to know how these genes are inherited. We found that Bgl I-digested DNA of BALB/c, C3H, DBA/2, and C57BL/6 exhibited restriction enzyme fragment length polymorphisms (RFLPs) for the Tcra-V1, Tcra-V2, Tcra-V4, Tcra-V6, Tcra-V7, Tcra-V8, Tcra-V11, Tcra-V12, Tcra-V13, and Tcra-C gene segments. Inheritance of these RFLPs in 669 offspring from (BALB/c x C57BL/6) x BALB/c, (BALB/c x C57BL/6) x C57BL/6, (C57BL/6 x DBA2) x DBA/2, and (C57BL/6 x C3H) x C3H backcrosses was studied. Since we did not find any recombinations in the offspring, Tcra-V and Tcra-C gene segments are tightly linked and inherited as a haplotype. A peculiar finding was that 22 out of 103 (BALB/c x C57BL/6) x BALB/c offspring, heterozygous for Tcra-C, had deleted a C57BL/6 Tcra-V1 band as well as Tcra-V2 and Tcra-V4 bands. As will be discussed, this deletion is probably caused by heterogeneity in the C57BL/6 breeding stock of a commercial supplier. In seven BXD and BXH recombinant inbred strains with known recombinations between the Tcra-C and Es-10 loci, all Tcra-V RFLPs cosegregated with the Tcra-C RFLP. This finding agrees with the conclusion from our backcross studies; namely that Tcra-V and Tcra-C gene segments are tightly linked.

B lymphocytes from hyporesponsive SJL mice contain aberrant nucleoside binding sites

C8-substituted guanine ribonucleosides activate B cells by a novel pathway that apparently is independent of GTP-binding proteins and protein kinase C. B lymphocytes from SJL mice are hyporesponsive to antigen-independent inductive signals transmitted by these nucleosides. In the current studies, the basis for this observation was explored. Responses of normal murine strains to these agents have been dissociated into antigen-independent (inductive) and antigen-dependent (differentiative) types by use of the 7,8-disubstituted guanine ribonucleosides. Dose-response profiles for inductive responses appear to correlate with apparent Kd values for low-affinity nucleoside binding sites; dose-response curves for antigen-dependent differentiative responses correlate with apparent Kd values for high-affinity binding sites. It was found that the SJL low-affinity site exhibits an apparent Kd that is approximately 10- to 20-fold lower in affinity for 8BrGuo than that of normal CBA mice. Although the low-affinity site in normal murine strains displays nearly equivalent affinity toward C8-substituted and 7,8-disubstituted nucleosides, the low-affinity site of SJL mice binds 7,8-disubstituted compounds with approximately 5-fold higher affinity than it does monosubstituted compounds. The dissociation constant for high-affinity nucleoside binding sites of SJL mice was only slightly different from that of CBA mice, consistent with the observation of essentially normal antigen-dependent nucleoside-mediated activity in SJL mice. The current observations support (a) a role for low-affinity binding sites in antigen-independent inductive events, (b) a role for high-affinity binding sites in antigen-dependent differentiative events mediated by substituted guanine nucleosides, and (c) the existence of aberrant low-affinity binding sites in B cells from SJL mice.

Allelic variations in the human T cell receptor V beta 6.7 gene products

Polymorphisms of human TCR gene products have been suggested by the description of a mAb, OT145, that identifies a subset of TCRs in some individuals but not in others (6). Here we demonstrate that this mAb detects a TCR allotype of the V beta 6.7 gene. Two allelic products of this V gene differ by two nonconservative amino acid substitutions. The mAb OT145 appears to react with V beta 6.7 a gene products ("+" allele), but not with V beta 6.7b gene products ("-" allele). This represents the first direct demonstration that TCR V gene allotypes exist and provides a possible explanation for immune responses under the control of TCR V genes and for disease associations with TCR V genes.

Elimination of self-tolerogen turns nonresponder mice into responders

Two sets of genes control the immune response of H-2d mice to the synthetic antigen poly(Glu50Tyr50) (GT). One set involves class II major histocompatibility complex (Mhc) loci encoding an Ad product that serves as a recognition context to GT-reactive helper T cells (Th). The other one is a background gene, the product of which, in association with the same Mhc-restricting element, mimics the GT/Ad complex. Mice expressing the GT-mimicking background-encoded structure (Imgt), which is preferentially displayed on B lymphoblasts, do not respond to GT as a consequence of self-tolerance. On the other hand, elimination of cells bearing Imgt renders these mice responsive to GT, demonstrating that tolerance to self can impoverish the immune system. Imgt is probably not identical to GT, but resembles it in the way it forms complexes with Ad molecules of Mhc.

Minor transplantation antigens: their role in shaping the T cell repertoire

Minor transplantation, or histocompatibility (H), antigens are the targets of host-versus-graft (hvg) and graft-versus-host (gvh) reactions that occur when organs or tissues are exchanged between members of the same species who, although genetically not identical, are matched for their major histocompatibility complex (MHC) encoded transplantation antigens. Genes encoding minor H antigens map outside the MHC, on a number of different chromosomes. Whilst gvh and hvg reactions against individual minor H antigens are relatively weak, certainly in comparison with such reactions against MHC antigens, the presence of multiple minor H differences (the situation encountered in man) gives rise to very vigorous reactions that can endanger the survival of graft or host, or both. This is the pathological role of minor H antigens and, indeed, it was this role which was first designated to the MHC antigens, before their physiological role as guidance molecules for T lymphocytes was discovered. Recently, a potential physiological role for minor H antigens has been uncovered by the finding that the presence of certain minor H alleles in mice leads to removal in the thymus (negative selection) of all those T cells expressing a particular T cell receptor (TCR) gene. Such cells therefore never reach the periphery, where they might otherwise give rise to autoimmune reactions. The T cell repertoire is thus moulded by at least some minor H antigens, which may therefore be regarded as non-MHC immune response genes. Furthermore, T cell receptor usage by T cells specific for allogeneic minor H antigens appears not to be representative of T cell receptor usage in the peripheral pool.(ABSTRACT TRUNCATED AT 250 WORDS)

Unresponsiveness to a foreign antigen can be caused by self-tolerance

In mice, two sets of genes govern the immune response to the synthetic antigen GT. One maps to the major histocompatibility complex and behaves like a typical immune response gene. The second is a background gene encoding a cell surface structure found on B cells. Mice which express, and are therefore tolerant of, one form of this structure do not respond to GT. Thus, tolerance of self generates holes in the T-cell repertoire, partially crippling the immune system.

Antigraft responses to the H-28c antigen by B6 and B6D2F1 mice

The survival of minor H antigen-bearing skin grafts from donors congenic with C57BL/6 (B6) was compared in B6, B6D2, and AB6 hybrid recipients. In a case singled out for further study, B6 mice were found to reject HW110 skin (H-28c antigen) rapidly, whereas B6D2 mice rejected HW110 skin much more slowly and variably. Both major histocompatibility complex (MHC)-linked and non-MHC genes appeared to affect the survival of HW110 strain skin grafts on B6 and B6D2 recipients. Results of several experiments appear to rule out the sharing of H-28c epitopes between donors and recipients as an explanation for the relatively poor response of B6D2 mice to HW110 skin grafts. Experiments involving bone marrow chimeras produced by the reciprocal exchange of bone marrow between irradiated B6 and B6D2 mice suggest that bone marrow-derived donor cells and non-bone-marrow-derived host cells each contribute to the immune response phenotype with respect to the H-28c antigen. An attempt was made to determine whether B6D2 mice that failed to reject HW110 strain skin grafts possessed suppressor cells specific for the H-28c antigen. Spleen cells from poorly responsive B6D2 mice failed to suppress the rejection of HW110 skin grafts when assayed in immunodeficient mice that were provided with cells from immune B6D2 donors that were highly responsive to HW110 skin grafts.

HLA-restricted recognition of viral antigens in HLA transgenic mice

Cytotoxic T lymphocytes (CTL) recognize antigen in the context of the class-I products of the major histocompatibility complex (MHC). The extensive polymorphism of class-I molecules is thought to be linked to their capacity to present a large variety of foreign antigens. Whether a single T-cell receptor (TCR) recognizes two separate epitopes (the foreign antigen and an epitope on MHC molecules), or a single epitope resulting from the combination of a foreign antigen and an MHC molecule, has not yet been resolved. In view of the differences between species in primary structure of histocompatibility antigens, it might be predicted that the TCR repertoire would evolve in concert with the diversity of MHC antigens. The mouse and human TCR repertoire would be optimally adapted to engage in productive interactions only with mouse (H-2) and human (HLA) MHC antigens respectively, especially if the more conserved features of histocompatibility antigens, in addition to foreign antigen, were seen by the TCR. Alternatively, only the most variable segments of MHC antigens might be engaged in antigen presentation and thus in interaction with the TCR. In that case, interaction between MHC plus antigen and the TCR might not necessarily be limited by species-specific features. By analysis of the T-cell response against virus-infected cells in HLA-B27/human beta 2-microglobulin double transgenic mice, we report here that the mouse T-cell repertoire is perfectly capable of using the human HLA-B27 antigen as a restriction element.

Turning (Ir gene) low responders into high responders by antibody manipulation of the developing immune system

The ability of helper T cells directed against trinitrophenyl-modified syngeneic spleen cells to recognize low-hapten densities on target cells is under major histocompatibility complex-linked Ir gene control. Thus, BALB/c (H-2d) mice are low responders while H-2 congenic BALB.C3H (H-2k) mice are high responders. Immunization of adult BALB/c mice with the monoclonal antibody F6(51), directed to shared idiotopes by anti-trinitrophenyl antibodies and clonal receptors on anti-trinitrophenyl-self helper T cells, leads to the production of high titers of circulating idiotype, has no influence on helper T cell idiotypic profiles, but shifts to a high-responder phenotype the ability of helper T cells to recognize low-hapten densities. These effects on Ir gene phenotype are even more striking in untreated progenies from F6(51)-immunized BALB/c females, which are better responders than genetically high-responder BALB.C3H mice, although completely different in the expression of the F6(51)-defined clonotype. The general significance of these findings on Ir gene-directed T-cell repertoire selection is discussed, for they constitute formal evidence against antigen-presentation as a mechanism of Ir gene effects and strong support for the importance of maternal influences on the development of T-cell repertoires.

Induction of H-2-specific antibodies by injections of syngeneic Sendai virus-coated cells

The capacity of the B cell immunoglobulin receptor to recognize complexes of Sendai viral and H-2b antigens was investigated by studying the antibody response to injections of syngeneic Sendai virus-coated (SV+) spleen cells in C57BL/6 (B6) mice. Almost all mice produced alloreactive anti-H2 lymphocytotoxic antibodies. In contrast, such antibodies were found very exceptionally in mice injected with normal (SV-) cells or with Sendai virus (SV) only. The reaction pattern of the cytotoxic antibodies induced was variable and ranged from almost anti-private to widely cross-reactive serotypes. The results of reactions on H-2-congenic, -recombinant and -mutant mouse strains, and of capping and immunoprecipitation experiments showed that the cytotoxic antibodies were directed against H-2 class I molecules. The anti-H-2 antibodies exhibited enhanced binding for SV+ target cells, but absorption experiments showed that this was not the result of cross-reactions with cell surface Sendai viral determinants or with a molecular complex of H-2 plus SV. This conclusion was supported by the observation that syngeneic SV+ cells were not the predominant targets for the induced lymphocytotoxic antibodies. Our results do not support the existence of MHC-restricted antiviral antibodies, but show the induction of anti-class I H-2 alloantibodies by injections with syngeneic SV-coated cells. We present a model for regular induction of anti-H-2 antibodies without intentional alloimmunization.

Restriction fragment length polymorphism of the human T cell receptor alpha gene. I. Two polymorphic restriction sites localized to different regions of the gene

Previous studies have demonstrated restriction fragment length polymorphisms (RFLP) in the vicinity of the alpha and beta genes of the human T-cell receptor. In the course of experiments designed to discover additional polymorphic restriction sites, we found a new RFLP of the T-cell alpha gene recognized by the restriction enzyme Taq I. The site was localized to the interval between the most 3' joining (J) exon and the most 5' constant (C) region exon, about 7 kb distant from the previously described Bgl II polymorphic site which mapped to the vicinity of the 3' untranslated exon. With the use of these two polymorphic markers, four Ti-alpha alleles could be identified, allowing unambiguous assignment of all Ti-alpha genes in some families. These markers may be useful in identifying possible immune response genes or disease predisposition genes associated with the genes of the T-cell receptor for antigen.