Complex genetic effect of B10.D2 (M504) (H-2dm1) mutation

Serological and capping experiments show that the strain B10.D2 (M504) carrying the mutant haplotypeH-2 ^dm1 has two molecules in the products of theD region: H-2D^dm1 and H-2L^dm1 which are detectable by anti-H-2.4 and by anti-H-2.28 sera, respectively. Both these molecules differ serologically from the H-2D^d and H-2L^d molecules of the original (nonmutant) strain B10.D2. A third molecule, different from H-2D and H-2L, was detected inH-2 ^d ,H-2 ^dm2 but not inH-2 ^dm1 products.     

H-2-associated specificity of virus-immune cytotoxic T cells fromH-2 mutant and wild-type mice: M523 (H-2K ka ) and M505(H-2K bd ) do,M504 (H-2D da ) and M506(H-2K fa ) do not crossreact with wild-typeH-2K orH-2D

B10.A(3R) (H-2K ^b ) mice infected with lymphocytic choriomeningitis virus (LCMV) or vaccinia virus generate cytotoxic T cells capable of specifically lysing virus-infected macrophage target cells fromH-2K ^b mutant mice M505 (H-2K ^bd ), and vice versa. Similarly, virus-immune B10.A(4R) (H-2K ^k ) T cells specifically lyse infected targets from M523 (H-2K ^ka ), and vice versa. In contrast, virus-specific cytotoxic T cells from neither M504 (H-2D ^da ) and B10.A(5R) (H-2D ^d ) nor M506 (H-2K ^fa ) and B10.M(11R) (H-2K ^f ) mutually crossreact at the cytotoxic effector-cell level. As far as tested, the crossreactivity patterns between wild-type and mutantK orD specificities are identical for LCMV- and vaccinia virus-immune spleen cells. Although this finding is no proof for either the altered self nor the dual recognition concept of T-cell recognition, it may be compatible with the latter model.     

Genetic resistance to murine leukemia induced by different radiation leukemia virus variants; a comparative study on the role of theH-2 complex

Association of resistance to leukemogenesis with theH-2 complex was investigated. Three variants of the radiation leukemia virus: D-RadLV, RadLV and RS-RadLV were tested. Using congenic and recombinant mouse strains, the region includingH-2K andI-A/B was found to be involved with resistance to all three viruses. In addition,H-2D-region linked resistance was found in leukemogenesis in two of the three passages. The phenotypic expression of resistance associated withH-2D seemed to depend on the simultaneous presence ofH-2K-H-21-linked resistance alleles. TheH-2 haplotypes associated with resistance or sensitivity to the different RadLV variants were different for each passage, suggesting that there is a large degree of heterogeneity both inH-2-linked resistance and between the radiation-induced leukemia viruses.     

Experimental allergic orchitis in mice. VI. Recombinations within the H-2S/H-2D interval define the map position of the H-2-associated locus controlling disease susceptibility

Susceptibility to autoimmune orchitis is associated with an immune response (Ir) gene (now designated Orch-1) which was preliminarily shown to reside at or near the H-2D subregion of the major histocompatibility complex in the mouse (H-2). In this study, the role of H-2 in controlling both disease susceptibility and the phenotypic expression of infertility associated with autoimmune orchitis has been significantly extended. Of nine C57BL/10SnJ and three BALB/cAnN H-2 congenic strains, only those mice possessing the H-2 ^d, H-2 ^p haplotypes exhibited autoimmune orchitis accompanied by infertility. All other congenic strains, including those expressing the H-2 haplotypes v, q, b, s, r, f, and k were of the low responder phenotype. In addition, disease susceptibility was found to be inherited as a dominant trait in H-2 congenic F₁ hybrid mice. In order to map the precise location of the Orch-1 locus within H-2, 32 intra-H-2 recombinant congenic strains possessing defined crossovers in various locations throughout the H-2 region were studied. The results of the analysis indicate that Orch-1 maps within the interval between the H-2S and H-2D regions. Our results also indicate that class II genes, i.e., A and E region-encoded genes, have little discernable effect in controlling disease susceptibility and resistance despite the fact that testicular lesions can be adoptively transferred with Ia-restricted CD4⁺ effector T cells. A comparison of the Orch-1 alleles with the genotypes of two additional markers which map within the H-2S/H-2D interval suggests the following gene order: H-2S--TNP-Ficoll--Orch-1--Tnfa--H-2D. Address correspondence and offprint requests to: C. Teuscher.     

Detection of H-2Db antigen on osmotic shock-treated friend leukemia virus particles

Antisera specific for either H-2K^b, H-2D^b, H-2K^k or H-2D^k antigenic determinants were examined for their capacity to neutralize Friend virus (FV) collected from the serum of infectedH-2 ^b /H-2 ^k heterozygous mice. Neutralizing activity was detected (1) only withanti-H-2D ^b antisera, (2) only when the surface of virus particles had been mildly deranged by osmotic shock treatment and (3) only in the assay for the defective spleen focus-forming virus component of FV.     

Unexpected complexity of the dm1 mutation revealed in the structure of three H-2D/L-related antigens

The H-2L^dm1 and H-2D^dm1 MHC antigens of the B10.D2 (H-2 ^dm1 ) mutant mouse strain (formerly known as M504 or H-2 ^da ) have been compared to the H-2L^d and H-2D^d antigens of the B10.D2 (H-2 ^d ) mouse strain. L^dm1 and L^d are 45 000 M_r antigens and both are reactive with anti-H-2.28 (k/r anti-h2) serum and unreactive with anti-H-2.4 (k/b anti-a) serum which detects private determinants of the D^dm1 and D^d antigens. However, the tryptic peptide compositions of these two antigens are different and, based on the number of major tryptic peptides which coelute during ion-exchange chromatography, the estimated peptide homology between L^dm1 and L^d is 80 percent. A newly defined antigen (M_r = 39 000), designated gp39^dm1, was found in glycoprotein extracts of the ^dm1 strain but not of the d strain. This antigen coprecipitates with L^dm1 but does not coprecipitate with D^dm1 indicating that it lacks the H-2.4 determinant. In comparison with L^dm1, gp39^dm1 appears to contain far fewer Arg and Lys residues and is most likely not a simple proteolytic fragment of L^dm1. Finally, peptide maps of the D^dm1 antigen show that the majority of its Arg peptides are identical to D^d Arg peptides, whereas at least five of its Lys peptides and three of its Arg peptides correspond not to D^d peptides but to L^d and L^dm1 peptides. These data raise the possibility that the D^dm1 antigen is a hybrid molecule and they have also revealed an unexpected level of complexity in the dm1 mutant phenotype.     

H-2 effects on cell-cell interactions in the response to single non-H-2 alloantigens

Immune response (Ir) genes mapping in theI region of the mouseH-2 complex appear to regulate specifically the presentation of a number of antigens by macrophages to proliferating T cells. We have investigated the possibility that similarIr genes mapping in theH-2K andH-2D regions specifically regulate the presentation of target antigens to cytotoxic effector T cells. We report that the susceptibility of targets expressing specific non-H-2 H alloantigens to lysis by H-2-compatible, H-antigen-specific cytotoxic effector T cells is controlled by polymorphicH-2K/D genes. This control of susceptibility to lysis is accomplished through what we have defined operationally as antigen-specific regulation of non-H-2 H antigen immunogenicity. High immunogenicity of the H-4.2 alloantigen is determined by a gene mapping in theH-2K region ofH-2 ^b . However, high immunogenicity of H-7.1 is determined by a gene mapping in theH-2D region ofH-2 ^b . High immunogenicity of the H-3.1 alloantigen is determined by genes mapping in both theH-2K andH-2D regions ofH-2 ^b . Therefore, genes mapping in theH-2K andH-2D regions serve a function in presenting antigen to cytotoxic effector T cells. This function is analogous to that played byI-regionIr genes expressed in macrophages which present antigen to proliferating T cells. We present arguments for classification of theseH-2K/D genes as a second system ofIr genes and discuss the implications of twoH-2-linkedIr-gene systems, their possible functions, and their evolution.     

Biochemical evidence for structurally distinct H-2Dd antigens differing in serological properties

H-2D^d antigens, as defined by the private H-2.4 determinant, exist as two immunochemically distinct populations in H-2^a and H-2^dm2 splenocytes and in the transformed cell line, RADA1(H-2 ^a). The two populations are distinguishable by the anti-H-2.28 serum, k/r anti-h2, which is directed, in part, against the H-2.28 family of public determinants encoded by the D end of the b haplotype. Sequential precipitates of lentil-lectin-purified glycoprotein extracts metabolically labeled with radioactive amino acids reveal that approximately one-quarter to one-third of the H-2D^d antigens, designated H-2D^d (b28 ⁺), react with this antiserum, whereas two-thirds to three-quarters, designated H-2D^d(b28^–), do not. Paired-label tryptic peptide maps in this and a previous study indicate that H-2D^d(b28⁺) and H-2D^d(b28 ^–) are closely related structurally and are more likely to represent modified forms of the same gene product rather than products of different genes, although the existence of closely related genetic loci is not rigorously excluded. Together, H-2D^d(b28⁺) and H-2D^d(b28^–) have a radioactivity level seven times higher than H-2L^d, which also reacts with the anti-H-2.28 serum but which lacks the H-2.4 determinant. As yet unresolved, however, is the question of whether the observed quantitative differences between these three antigens reflect actual molar differences at the cellular level, or whether the variation is the result of metabolic or compositional factors. In any case, a complex serological and structural relationship is found to exist between antigens encoded by the D/L end of the MHC.     

Topographical relationships among H-2 specificities controlled by theD region

In the present work, we used the differential redistribution method to study the molecular expression of several H-2 specificities controlled by theD region of theH-2 ^a haplotype. We observed that: capping of the private specificity H-2.4 induced capping of the public specificities H-2.3, H-2.35, and H-2.36, and vice versa; capping of any one of these specificities did not induce capping of the public specificity H-2.28, controlled by the same region. By contrast, capping of the H-2.28 specificity induced capping of these specificities; redistribution of H-2K and H-2D private specificities or redistribution of H-2D private specificity and Ia specificities did not induce capping of the H-2.28 specificity. These data indicate that a part of a molecule carrying the H-2.28 specificity is linked to a molecule carrying H-2.4, H-2.3, H-2.35, and H-2.36 specificities and that a part of a polypeptide chain bearing the H-2.28 specificity is independent from that bearing other specificities controlled either by theD region (i.e., H-2.4, H-2.3, H-2.35, and H-2.36) or by theK andI regions. These results further strengthened the hypothesis of the existence of at least two genes controlling theD-region H-2 antigenic specificities.     

A new H-2.1-PositiveD region allele,D dx,controlling two molecules,H-2Ddx and H-2Ldx

The inbred strains GRS/A and LIS/A carry the haplotypeH-2 ^dx , which had earlier been shown to have theK ^d ,I ^f ,S ^f , andG ^f alleles and a previously unknownD region allele,D ^dx . We show here that theD ^dx allele determines a new private specificity, H-2.63, is H-2.28 negative, and determines at least one public specificity of the H-2.1 family. It is thus a second example (afterD ^k ) of a H-2.1-positive H-2.28-negativeD region allele. Capping experiments show that the D^dx product comprises two molecules: H-2D^dx bearing the private specificity H-2.63, and H-2L^dx, which is H-2.63-negative but reacts with sera against the H-2.1 family of specificities. SDS gel electrophoresis of detergent-solubilized immunoprecipitated D^dx products shows that the H-2L^dx antigen has a molecular weight of approximately 45,000 daltons and is associated with a smaller polypeptide (mol. wt. 12,000).     

A third class I major histocompatibility complex antigen encoded by a gene in the D region of the H-2 d haplotype recognized by cytotoxic T lymphocytes

The D region of the H-2 ^d haplotype contains five class I genes: H-2D ^d , D2 ^d , D3 ^d , D4 ^d and H-2L ^d . Although previous studies have suggested the presence of D-end encoded class I molecules in addition to H-2D^d and H-2L^d, segregation of genes encoding such molecules has not been demonstrated. In this report we have used cãtotoxic T lymphocytes (CTL) to examine the D region of the H-2 ^d haplotype for the presence of additional class I molecules. CTL generated in (C3H × B6.K1)F₁ (K ^k D ^k , K ^b D ^b ) mice against the hybrid class I gene product Q10^d/L^d expressed on L cells cross-react with H-2L^d but not H-2D^d molecules, as determined by lysis of transfected cells expressing H-2L^d but not H-2D^d. Although H-2L^d-specific monoclonal antibodies (mAb) completely inhibit H-2L^d-specific CTL from killing B10.A(3R) (K ^b D ^d L ^d ) target cells, only partial inhibition of anti-Q10 CTL-mediated lysis was observed, suggesting the presence of an additional D-end molecule as a target for these latter CTL. To identify the region containing the gene encoding the Q10 cross-reactive molecule, we show that anti-Q10 CTL lyse target cells from a D-region recombinant strain B10.RQDB, which has H-2D ^d , D2 ^d , D3 ^d , D4 ^d , and H-2D ^b but not the H-2L ^d H-2 ^d , and H-2L ^d (including D2 ^d , D3 ^d , and D4 ^d , lacks this anti-Q10 CTL target molecule. Together, these data demonstrate that a class I gene mapping between H-2D ^d and H-2L ^d encodes an antigen recognozed by anti-Q10 CTL. A likely candidate for this gene is D2 ^d , D3 ^d or D4 ^d .     

Serological characterization of previously unknown H-2 molecules identified in the products of theK d andD k region

The molecular relationship between H-2 private and some public specificities was studied in C3H.OH (H-2 ⁰² ) mice using surface-antigen re-distribution methods. Besides the K^d- and D^k-region antigens, which can be capped by antisera against the private and public specificities characteristic for a given allele, a previously unknown type of molecule was found in the products of both theK ^d andD ^k regions. These can be capped by the respective anti-private serum but not by antisera against some public specificities. The two K^d-region molecules are provisionally named H-2K1^d and H-2K2^d. We detected them onH-2 ⁰² (K ^d ,I ^d ,S ^d ,D ^k ) and also onH-2 ^dx (K ^d ,I ^f ,S ^f ,D ^dx ) T lymphocytes. Similarly, the two types of molecules detected on the products of theD ^k region are provisionally named H-2D1^k and H-2D2^k. The serological characteristics of these molecules are described. When compared with the products of theD ^d region, in which we previously described three different molecules (H-2D^d, H-2M^d, and H-2L^d), the mutual relationship between H-2K1^d and H-2K2^d as well as between H-2D1^k and H-2D2^k appears to be similar to that between H-2D^d and H-2M^d. In the absence of relevant recombinants or informative biochemical data, it is, however, difficult to establish homology between molecules produced by differentK- andD-region alleles.     

Low H-2 polymorphism in some Israeli wild mouse populations

Two populations of the wild house mouse, Mus domesticus, found living close to each other (one inhabited a chicken coop and the other an open field at the Educational Farm of the Hebrew University of Jerusalem, East Talpiot, Jerusalem) were studied for their H-2 polymorphism. These two populations were selected because they are well characterized in terms of their ecological parameters; they have been under continuous surveillance for several years. Twenty-seven H-2 homozygous lines were produced by mating wild mice from these two populations with laboratory strains. The H-2 ^w homozygotes were then characterized by serological typing with monoclonal and polyclonal antibodies specific for the known allomorphs controlled by the class I H-2K and H-2D loci or the class II H-2A and H-2E loci. They were also used as donors for immunizations and for the selection of antisera defining the H-2 haplotypes carried by these lines. Four new H-2 haplotypes could be identified: H-2 ^w82 (K ^wl6 D^ws2) H-2 ^w83 (K ^w83 D^w16) H-2 ^w84 (K ^w84 D^w84) and H-2 ^w85 (K ^w83D^w84) the last haplotype being a recombinant derived from H-2 ^w83 and H-2 ^w84. Antinsera defining the new haplotypes were then used for a study of the wild populations. This study revealed that the populations contain only the four identified H-2 haplotypes, having three alleles at the H-2K locus (K ^w16 K^w83, K^w84) and three alleles at the H-2D locus (D ^w16, D^w82 and D ^w84). The alleles occur in the populations with a frequency of 0.12–0.54. There were no significant differences in gene frequencies between the two populations, and the allele frequencies remained more or less stable. There was a significant excess of heterozygotes for at least some of the genes, compared with the frequency expected from Hardy-Weinberg equilibrium. The same antisera were also used to type other populations in the vicinity of Jerusalem. In one population, located 30 km west of Jerusalem, the mice failed to react with any of the reagents. In the other two populations, located 15 km west and 40 km northeast of Jerusalem, three of the four H-2 haplotypes found in East Talpiot were present at high frequencies. It appears, therefore, that only three main H-2 haplotypes and two or three minor ones are present in the area around Jerusalem. This study thus provides the first example of a large mainland population in which the H-2 polymorphism is comparable to that of many other non-H-2 loci.     

The role ofH-2 regions in overcoming tissue incompatibility

Neonatal transplantation tolerance to the products of theH-2 ^b complex was induced in B10.A (H-2 ^a ) mice. On the basis of the survival of skin allografts it was found that antigens determined by theD region of theH-2 ^b complex (of the B10.A(2R) strain) were most easily overcome and that tolerance to the products of theD end of theH-2 complex (of the B10.A(4R) strain) was also easy to induce. The antigens produced by theK end ofH-2 (of the B10.A(5R) and B10.A(3R) strains) represented a stronger incompatibility barrier and a difference in the entireH-2 ^b complex caused strongest resistance to tolerance induction. When tolerance to the products of the entireH-2 ^b complex was induced in newborn B10.A mice, and the neonatally treated animals were grafted simultaneously with five different grafts, those disparate at theK end ofH-2 and in the entireH-2 region were rejected in some animals, while the grafts disparate at theD end of H-2 remained intact in the same mice. No dependence on theI-J subregion was observed in this system. Furthermore, tolerance was more easily inducible in male than in female B10.A mice.     

Genetic control of contact sensitivity in mice: Effect ofH-2 and nonH-2 loci

The genetic control of delayed-type hypersensitivity in mice was investigated by contact sensitization with picryl chloride. Distribution patterns of contact sensitivity in 11 inbred strains of mice showed significant differences among strains. Comparison of levels of response between congenic-resistant lines and their inbred partners, at 9 to 11 weeks of age, revealed a clear association betweenH-2 haplotype and the magnitude of response. Testing ofH-2 recombinants further suggested the influence of two genes mapping at either end of theH-2 complex. While theH-2K ^d andH-2D ^k alleles were associated with a high response, theH-2K ^k ,H-2K ^b ,H-2D ^d , andH-2D ^b alleles were associated with a low response. Analysis of the ontogeny of response suggested that theH-2 haplotype manifests its effect through the maturation of contact sensitivity. On both the C57BL/6By and C57BL/10Sn backgrounds, theH-2 ^d haplotype was associated with early maturation of response, while theH-2 ^b haplotype was associated with late maturation. Analysis of the response of congenic lines with different genetic backgrounds and of CXB recombinant-inbred lines further revealed the marked effects of yet other genes on this trait.     

Genetic control of the target structures recognized in hybrid resistance

Hybrid resistance of lethally irradiated (C57BL/6 × DBA/2)F₁ and (C57BL/10 × C3H)F₁ hybrid mice to the engraftment of parental C57BL/6 or C57BL/10 bone marrow cells is controlled by the H-2-linked Hh-1 locus. This resistance can be specifically blocked or inhibited by the injection of irradiated spleen cells from lethally irradiated, marrow reconstituted donor mice of certain strains. By testing the ability of regenerating spleen cells from various donor strains to block the resistance, we studied the genetic requirements for the expression of putative cell-surface structures recognized in hybrid resistance to H-2^b marrow cells. Strains of mice bearing informative intra-H-2 or H-2/ Qa-Tla recombinant haplotypes provided evidence that the Hh-1 locus is located telomeric to the H-2S region complement loci and centromeric to the H-2D region class I locus in the H-2 ^b chromosome. Two mutations that affect the class I H-2D ^b gene have no effect on Hh-1 ^b gene expression. The H-2D region of the H-2 ^S haplotype contains an allele of the Hh-1 locus indistinguishable from that of the H-2D ^b region, as judged by the phenotypes of relevant strains and F₁ hybrids. Collectively these data indicate that the Hh-1 locus is distinct from the class I H-2D (L) locus in the H-2 ^b or H-2 ^s genome, and favor the view that the expression or recognition of the relevant determinants is not associated with class I gene products.Abbreviations used in this paper BM(C) bone marrow (cells) - CML cell-mediated lympholysis - CTL cytotoxic T lymphocytes - FBS fetal bovine serum - HBSS Hanks' balanced salt solution - SC spleen cells from irradiated, bone marrow-reconstituted mice Address correspondence to: Dr. I. Najamura, Department of Pathology, School of Medicine, State University of New York at Buffalo, Buffalo, NY 14214, USA     

H-2 class I loci determine sensitivity to MCMV in macrophages and fibroblasts

Peritoneal (PM) and bone marrow-derived (BMM) macrophages and lung fibroblasts (LF) from inbred, intra-H-2 recombinant, H-2 mutant, and hybrid mice were infected with murine cytomegalovirus (MCMV) under centrifugal enhancement. At the concentration of virus employed, peritoneal macrophages from strains carrying Kd, Kb, D^d, KS and/or D^s, K4 and/or D4 alleles could be infected to a level of 80%–100%, as assessed by viral antigen expression or loss of Fc receptors. Cells lacking these haplotypes and carrying K^k, K^f, D^k, Df, or Db were resistant, yielding levels of infection below 20% . The background (non-H-2) and class II genotype and the S allele did not influence the proportions of cells infected. Furthermore, sensitivity was dominant in the F, progeny of H-2 b x H-2 k and H-2d x H-2 k crosses, and was not compromised by thebm1, bm3, bm10, or bm14 mutations in the al or2 regions of Kb orD ^b. The proportions of cells able to release infectious virus were low, but paralleled the frequencies of viral antigen expression. The class I genotype also determined susceptibility to MCMV infection in BMM and LF, although up to 35% of H-2 k BMM and 46% of H-2 k LF could be infected. The findings are consistent with an association between K and D antigens and a cellular receptor for MCMV on all three cell types.     

Histocompatibility-2 system in wild mice

Ninety-six wild mice trapped at 13 localities in the state of Texas were tested in the dye-exclusion cytotoxic test with a battery of 49 oligospecific H-2 antisera. The antisera detected 36 class I (K and D) and 10 class II (Ia) antigens. The phenotypic frequencies of private class I antigens ranged from 1 to 20%, the majority of them being in the range between 1 and 5%. At least some of the higher frequencies resulted from the presence of more than one antibody in the typing reagents, and from other factors complicating the typing. We estimate that the frequencies of most of the class I alleles among Texas wild mice are 1% or less. This estimate leads to the prediction that at least 200 alleles exist in Texas mice at theH-2K locus, and another 200 alleles exist at theH-2D locus. Frequencies of most of the class I public antigens were in excess of 20%. In the sample of 96 mice, 46 different phenotypic combinations of private class I antigens were found, and the frequency of blanks (mice unreactive with any of the antibodies to private class I antigens) was 27%. The frequencies of private class II antigens ranged from 5 to 15%. Some of the public class II antigens, in particular those controlled by theE region, occurred with frequencies of 80% or higher. The class II antigens were found in 26 phenotypic combinations. No striking linkage disequilibrium was found either between K and D antigens, or between class I and class II antigens. The polymorphism of theK, A, andD region appears to be higher than that of the corresponding regions of the human or rat major histocompatibility complex. The polymorphism of theE region is significantly lower than that of theA, K, andD regions. The polymorphism of theA region is extensive.     

Antigen-specific helper T cells recognize determinants encoded in the H-2D region of the H-2 gene complex

Observations have frequently been interpreted as showing that the helper T cells which collaborate with alloantigen-specific cytotoxic T-cell precursors can only recognize antigens encoded in the I region of the H-2 gene complex. An experimental system is described here that allows analysis of the recognition repertoire of these helper cells. CBA helper T-cell precursors can be primed in vitro to antigens encoded in the H-2 ^b gene complex. These helpers can then be tested for the existence of a subset of helper cells which recognize antigens encoded in the D region of H-2 ^b haplotype. CBA thymocytes were used as a source of cytotoxic T-cell precursors that respond poorly in the absence of exogeneous helper activity. The source of alloantigen was varied by using irradiated spleen cells from various (BALB/c × recombinant)F₁ hybrid mice as stimulator cells. When the stimulator cell bears BALB/c determinants recognized by the cytotoxic T-cell precursor and also bears only the D region antigens of the H-2 ^b haplotype, an anti-BALB/c cytotoxic response is generated only if the anti-H-2^b helper population contains cells able to recognize H-2D^b. A positive cytotoxic response was obtained, indicating that helper cells are not limited to recognition of I region antigens and can efficiently recognize antigens encoded in the D region of the H-2 gene complex. This was confirmed by the demonstration of helpers specific for H-2D^d. We were unable to detect any evidence for Ia-restricted recognition of the H-2D alloantigens, suggesting that, as for cytotoxic T lymphocytes (CTL), helper cell recognition of class I alloantigens is an unrestricted event.