Relationships between private and public H-2 specificities on the cell surface

Differential redistribution was used to investigate relationships between private specificity H-2.4 and public specificity H-2.28, in the product of aD region allele of theH-2 complex. Monospecific anti-H-2 antisera and fluorochrome conjugated antimouse Ig antibodies were used to induce redistribution of H-2 antigens on the surface of peripheral T lymphocytes fromH-2 ^a andH-2 ^d mice. Results showed that redistribution of specificity H-2.4 into patches and caps did not induce concomittant redistribution of specificity H-2.28, which remain diffusely scattered on the cell surface outside the caps of H-2.4. Redistribution of H-2.28 induced redistribution of H-2.4, which was no longer detectable outside the caps of H-2.28. These data indicate that (a) at least some of the H-2.28 sites are expressed on polypeptide chains independent from those carrying H-2.4 and (b) other H-2.28 sites may be linked to molecules carrying H-2.4. Since, onH-2 ^a cells, both specificities are products of the D region of theH-2 gene complex, our results suggest that there are at least two genes in theD region.     

Further evidence for two separate loci (H-2D andH-2L) in theD region of theH-2 complex

The differential redistribution method was used to analyze the relationships between the antigens of the H-2.1 and H-2.28 families and the K- and D-region H-2 specificities on the lymphocyte surface. The experiments were performed on T peripheral lymphocytes of B10. AKM mice (H- 2^m), where the H-2.28 specificity is controlled by theD region; C3H.OL mice (H- 2^0l), where the H-2.28 specificity is controlled by theK region and the H-2.1 specificity by theD region; and B10.A mice (H- 2^a) where the H-2.1 specificity is controlled by theK region. The results show the following:

1. In the D-region products, the redistribution of the private specificities fails to induce the redistribution of the H-2.1 or H-2.28 specificity. Antibodies against the H-2.1 or H-2.28 specificity provoke the redistribution of the D-region private specificities.
2. In the K-region products, the H-2.1 or H-2.28 specificity cocaps with the private specificities.
3. In both K- and D-region products, the public specificity H-2.5 always cocapped by antibodies against the private specificity.

These data suggest that the D-region H-2.1 specificity is, like the H-2.28 specificity, controlled by gene(s) different from theH- 2.D gene for the private, and most of the public, specificities. However, in the K-region products, the H-2.1 or H-2.28 specificity and the private specificities are either controlled by the same gene or expressed on two different molecules associated on the cell surface. These results provide evidence for the existence of two separate loci in theD region: the classicalH-2D locus, controlling the expression of the private specificity and most of the public specificity, and theH-2L locus, controlling the expression of the H-2.1 or H-2.28 specificity.     

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).     

BALB/c-H-2 db : A newH-2 mutant in BALB/cKh that identifies a locus associated with theD region

A newH-2 mutant, BALB/c-H-2 ^db , is described. This mutant originated in BALB/c, is inbred, and is coisogenic with the parental BALB/cKh strain. The mutation is of the loss type since BALB/c-H- ^db rejects BALB/c, but not vice versa. Complementation studies have localized the mutation to theD region of theH-2 complex. A cross between BALB/c-H-2 ^db and B10.D2-H-2 ^da failed to complement for either BALB/c or B10.D2 skin grafts, indicating that these are two separate mutations at the same locus (Z2). Direct serological analysis and absorption studies revealed that, with one exception, theH-2 andIa specificities of BALB/c and BALB/c-H-2 ^db are identical. In particular,H-2.4, the H-2D^d private specificity, is quantitatively and qualitatively identical in the two strains. The exception is that of the specificities detected by antiserum D28b: (k×r)F₁ anti-h, which contains anti-H-2.27, 28, and 29. These specificities appear to be absent from theH-2 ^db mutant since they are not detected directly or by absorption. Other public specificities are present in normal amounts,e.g., the reaction with antisera to H-2.3, 8, 13, 35, and 36. The reaction with antiserum D28 (f×k)F₁ anti-s, which contains antibodies to H-2.28, 36, and 42, is the same in both strains. Antiserum made between the two strains (H-2 ^db anti-H-2 ^d ) reacts like an anti-H-2 serum, in that it reacts with both T and B cells by cytotoxicity, but is not a hemagglutinating antibody. The serum reacts as does the D28b serum in both strain distribution and in cross-absorption studies. We conclude that theH-2 ^db mutation occurred at a locus in theD region, resulting in the loss of the H-2.28 public serological specificity and of a histocompatibility antigen. Whether these are one and the same antigen is not yet known. The data, in view of other evidence, imply that the public and private specificities are coded for by separate genes.Abbreviations used in this paper are as follows CML cell-mediated lysis - MLR mixed lymphocyte reaction - GVHR graft-versus-host reaction - RFC rosette-forming cells - RAM-Ig rabbit anti-mouse IgG     

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.     

Serological and complementation studies in four C57BL/6H-2 mutants

C57BL/6 (H-2 ^b ) mice, and four mutants (B6.C-H-2 ^ba , B6-H-2 ^bg1 , B6-H-2 ^bg2 , B6-H-2 ^bh ) derived from this strain after separate mutations had occurred at the same locus within theH-2 complex, were analyzed to determine whether the mutations had led to anyH-2 (or Ia) difference which could be detected serologically. The strains were typed directly with antisera specific for H-2K and H-2D public and private specificities and for the Ia specificities; quantitative absorption studies were also performed for the relevant H-2K^b, H-2D^d and Ia^b specificities. In no case was any quantitative or qualitative difference detected serologically between any of the strains. In addition, by using a variety of techniques to produce and assay for antibody, we failed to produce any antisera between the parental strains and the four mutants. TheH-2 mutations therefore appear to give rise to a type of antigenic specificity which is recognized byT cells and which generateT, but notB cell responses; nor are they recognized by H-2 or Ia alloantisera. The location of the mutating locus within theH-2 complex was shown by the complementation method to be within theK orIA region and not in theIB region, since crosses of the mutant strains with B10.A(4R) or D2.GD failed to complement for a subsequent C57BL/6 skin graft.     

Expression ofHistocompatibility-2 antigens on cultured cell lines derived from mouse blastocysts

Four cell lines derived from four-day-old SWR/J×SJL/J mouse blastocysts have been assayed for their expression of H-2 specificities with pauci- and monospecific H-2 typing sera. Direct microcytotoxicity and indirect absorption studies reveal many deviations from expected expression of particular H-2 specificities based on the cell lines' genotypes and onH-2 typing of adult F₁ lymphocytes. No pattern of selective expression of public or private specificities ofD-end orK- end specificities or of inclusion groups was noted. At least one public or private specificity of eachD ^q ,K ^q ,D ^s , andK ^s region is present, indicating that part of each product is expressed. The partial expression of H-2 specificities is discussed structurally, in terms of how incomplete H-2 molecules may be present on the cell surface, and developmentally, in terms of how the variant H-2 specificities may be involved in cell positioning during ontogenesis.     

Molecular heterogeneity of D-end products detected by anti-H-2.28 sera

In capping experiments with peripheral T lymphocytes, two anti-H-2.28 sera (AKR anti-AKR.L, anti-K^b, and C3H anti-0H.B10, k anti-b) that do not contain any Qa-2-specific antibodies are able to redistribute not only the H-2.28-positive H-2 molecules, but also Qa-2 molecules. This is due to the capacity of these sera to react with Qa-2 molecules because on cells where all known molecules of the H-2 ^d haplotype were capped (K1^d, K2^d, D^d, M^d, L^d, L2^d), both antisera still reacted when the cells came from a Qa-2 positive D^d strain (B10.A) but not when the cells were of Qa-2 negative strain (BALB/cByA). The reaction with la and non-H-2 antigens was excluded in these experiments. These data show that Qa-2 and H-2 antigens share some specificities of the H-2.28 family. Other anti-private and anti-public anti-H-2 sera failed to react with the Qa-2 molecules.     

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.     

Generation of cytotoxic lymphocytes in mixed lymphocyte reactions II. Importance of private and publicH-2 alloantigens on the expression of cytotoxicity

MLC were established to test for the generation of specific cytotoxic effector cells in CML. The target cell used to assay for CML in the five combinations tested was of a differentH-2 haplotype from the stimulating cell population. Cytotoxicity was observed against this target only when it shared private alloantigens (antigens that are specific for theH-2D andH-2K region of differentH-2 haplotypes) with the stimulating cell population. Very weak or no Cytotoxicity was found when such alloantigens were not shared, although cross-reactive publicH-2 specificities were. These findings indicate that T cells display a cytotoxic potential against privateH-2 antigens in a primary response in vitro and are not capable of responding to publicH-2 specificities to the same level.BSS balanced salt solution - CML cell-mediated lympholysis - GPC guinea pig complement - ¹²⁵IUdR ¹²⁵I-iodo-deoxyuridine - MLC mixed lymphocyte culture - SE standard error     

Studies of twoH-2D b mutants: B6.C-H-2 bm13 and B6.C-H-2 bm14

Two new C57BL/6H-2 mutants,B6.C-H- 2^bm13 and B6.C-H- 2^bm14 are described. They arose independently in C57BL/6 as spontaneous mutations of the gain and loss type. Complementation studies map the mutations in both bm13 and bm14 to theH-2D ^b gene. How ever, these two mutant strains are not identical, but occurred as independent mutations at the same locus, as shown by reciprocal graft rejection and by the inability of the (bm13 × bm114)F₁ hybrid to accept C57BL/6 grafts. Serological studies by direct testing (cytotoxicity and hemagglutination) and by quantitative absorption demonstrated a decrease in the H-2D^b private specificity H-2.2 in both bm13 and bm14 when compared to C57BL/6. This was confirmed by SDS-PAGE analysis using antisera detecting the H-2.2 specificity. Attempts to produce antibodies to either the gained or lost specificities of the two mutant strains failed.     

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.     

Biochemical evidence for a separate,MHC-linked locus encoding H-2.28 antigens

In comparing the tryptic peptide maps of the H-2L and H-2D glycoprotein antigens isolated from NP-40 lysates of RADA1 (H-2 ^a ) leukemic cells, no more than 37% of the observed arginine-containing tryptic peptides are found to be homologous. Thus, the primary amino-acid sequences of these two antigens are probably less than 90% homologous. This constitutes the strongest evidence to date that the MHC-linkedH-2L region encodes H-2L antigens separately from theH-2D region, even though H-2L antigens bear D-end-associated antigenic determinants of the H-2.28 family. The anti-H-2.28 alloantiserum (k×r anti h2) used to precipitate H-2L antigens in this investigation was the NIH contract antiserum D28b. As the tryptic peptide maps also surprisingly revealed, D28b precipitates H-2D antigens as well and, thus, anti-H-2.4 immunoadsorbants were employed to isolate H-2L free of H-2D antigens. In light of the dual specificity of D28b, its reactivity with BALB/c-H-2 ^dm2 mutant cells was re-examined. Even though mutant lymphocytes, which lack H-2L but not H-2D antigens, are not cytotoxically lysed by D28b (as are parental H-2^d cells), D28b appears to precipitate H-2D antigens from NP-40 extracts of mutant splenocytes.     

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.     

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.     

A new locus (H-2T) at theD end of theH-2 complex

A.TH (H-2 ^t2) anti-A.TL (H-2 ^t1) effectors, obtained after in vitro restimulation of in vivo sensitized cells, react in the CML assay not only withH-2 ^t1, but also with a number of other targets carrying unrelatedH-2 haplotypes. The broad cross-reactivity can be explained by postulating the presence among the effectors of at least two populations of cells, one reacting with antigens controlled by theI region, and the other directed against antigens controlled by a locus at theD end, outside theH-2 complex. The existence of the two cell populations is also supported by cold-target inhibition data. The locus coding for the D-end CML antigens maps betweenQa-2 andTla. The locus is assigned the symbolH-2T. TheH-2T-locus CML is seen only after in vivo presensitization, but the killing is not K/D-restricted.     

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.     

Aberrancy in immunogenicity and cell-surface expression of H-2 antigens on erythrocytes

Immunogenicity for T cell-independent B-cell response assessed by splenic plaque-forming cell (PFC) response and cell-surface expression measured by laser flow cytometry of various class I H-2 antigens on mouse red blood cells (RBC) were compared. It was found that the order of magnitude of both immunogenicity and cell-surface expression on RBC is H-2D^d H-2D^b > H-2K^d, H-2K^b. Furthermore, H-2^d public antigens and H-2L^d antigens were neither immunogenic nor easily demonstrable on RBC. These findings contrasted with poor immunogenicity for PFC response (Nakashima et al. 1982, 1983) and proportionally strong expression of H-2 antigens on lymphoid cells. Immunogenicity and cell-surface expression of H-2D^d antigen on RBC were not shown to be controlled by the action of genes outside H-2D. It was therefore suggested that a number of H-2 antigens, including H-2K^d private, H-2K^b private, and H-2^d public specificities are at least functionally defective on RBC. This is possibly due to the structural characteristics of the antigens. Since immunogenicity and cell-surface expression were in parallel, the expression of H-2 antigens on RBC must be dictated by a subset of B cells whose activity was assessed by PFC response. This finding supports the view that the H-2 molecules display a new category of activity which is different from their ability to activate T cells and depends on their expression on RBC.     

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.     

The relationship between theH-2 loss mutations ofH-2da andH-2db in the mouse

The mouse strain B10.D2-H-2^da carries the mutantH-2^da allele, derived after chemical induction, and this has been shown to be a gain and loss mutation involving theH-2D^d locus.BALB/c- H-2^db, derived spontaneously, is a loss mutation only, and appears not to involve theH-2D^d, but rather theH-2L^d locus. The two mutations effectboth graft rejection and serologically detected H-2 specificities (Type II mutation). In the experiments described in this study, theloss mutations in theH-2^da andH-2^db mutants have been compared by skin grafting, and by direct and absorption serological techniques: (1) By skin grafting, using the well established complementation method, it has been shown thatH-2^da andH-2^db do not complement each other, i.e., the mutation in both occurred at the same locus. However, by appropriate selection of donor and recipient, it has become clear thatH-2^da had a greater loss than didH-2^db, althoughH-2^da includes the loss found inH-2^db. (2) Serological studies have demonstrated that H-2D.4 was altered inH-2^da, but not inH-2^db; H-2.28 (detected by D-28b and D-29) was decreased or lost in both mutants;H-2^db anti-BALB/c failed to react withH-2^da; both mutants reacted similarly with D-28 sera. In addition, sera made usingH-2^da as donor did not contain an anti-H 2.28 antibody. The loss mutation involvingH-2^da therefore appears to have led also to the loss of H-2.28 as found inH-2^db. We conclude that theH-2^da strain arose after a complex mutation or recombination event which involvedboth theH-2D^d locus and the closely linkedH-2L^d locus, whereasH-2^db affects only theH-2L locus.