Biochemical studies on the H-2K antigens of the MHC mutant bml

Biochemical analysis of the H-2K-gene product from the MHC mutant strain bml and from the C57BL/6 parent strain has been carried out in order to characterize the structural differences between parent and mutant K-gene products. Based on comparative tryptic peptide mapping of the cyanogen bromide fragments from these glycoproteins, two peptide differences were localized to the CN-Ia fragment. Partial amino-acid sequence analysis revealed two alterations in the primary structure of Kbml involving substitutions of tyrosine for arginine at position 155, and tyrosine for leucine at position 156. Both of these amino-acid replacements require a minimum of two nucleotide base changes at the nucleic acid level. These changes were the only alterations noted differentiating the Kbml and Kb glycoproteins. However, because our techniques allow us to analyze only 75 to 80 percent of the extra cellular portion of H-2Kb, it is possible there are other undetected changes. Nonetheless, the biochemical data are consistent with the hypothesis that the structural alterations noted in the Kbml mutant glycoprotein are directly related to the observed immunological specificity relative to the parent Kb molecule. Peptide comparisons of the Kb molecules of two C57BL/6 sublines and of the H-2b lymphoblastoid cell line, EL-4, disclosed no difference.     

Biochemical studies on the H-2K antigens of the MHC mutantsbm3 andbm11

Biochemical analyses of the H-2K-gene products of the C57BL/6 mutant strains, bm3 and bm11, have been carried out in order to characterize the structural relationships among these antigens. From comparative tryptic peptide mapping of cyanogen bromide fragments from the mutant and parent K^b glycoproteins and from preliminary amino-acid sequence analyses, a number of discrete differences have been discerned. Two sites of difference at amino residues 77 and 89 in the K^bm3 glycoprotein are noted relative to K^b. An alteration at residue 77 similar or identical to that seen in K^bm3 is present in the K antigen of thebm11 mutant. Because our techniques sample only 75 to 80 percent of the extracellular portion of H-2K^b, other undetected changes are possible. However, our present findings are most consistent with the conclusion that only very limited differences exist between mutant and parent molecules. Further, taken together with CML (cell-mediated-lymphocytotoxicity) reaction patterns (Melief et al. 1980), the biochemical data support the hypothesis that the proposed structural alterations in theK ^b mutant glycoproteins are directly related to their observed immunological specificity.     

Biochemical studies of H-2K antigens from a group of related mutants. I. Identification of a shared mutation in B6-H-2 bm5 and B6-H-2 bm16

Structural studies of the H-2 gene products from a group of five closely related but independent C57BL/6 H-2 mutant mice were undertaken. Each of the mutants exhibits reciprocal graft rejection with the parent. The group is remarkable, however, because each member of this group can accept skin grafts from any other member. The results of biochemical analysis of the H-2 glycoproteins from two of these related mutants, bm5 and bm16, are presented in this report. Evidence is given that the H-2K molecules from these two mutants are identical to each other based on comparative tryptic peptide mapping profiles with the parent. From partial amino acid sequence analysis, K products of both mutants have at least one common difference from the parental type located at residue number 116. Definitive studies established that in both bm5 and bm16 a tryosine found in the parent molecule is substituted with a phenylalanine in the mutant. These results show that a biochemical difference between the K products of the two mutants and of the parent can be detected, that the mutants appear to be identical with one another even though they arose independently, and that they differ from the other H-2K ^b mutants analyzed.Abbreviations used in this paper B6 C57BL/6Kh - bm5 B6-H-2^bm5 - bm6 B6-H-2 ^bm6 - bm7 B6.C-H-2 ^bm7 - bm9 B6.C-H-2 ^bm9 - bm16 B6-H-2 ^bm16 - D H-2D - K H-2K - MHC major histocompatibility complex     

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.     

Neonatal tolerance induction acrossH-2 mutational disparity: Induction and specificity of tolerance

Mutational disparities derived from alleles of theH-2K andH-2D loci vary widely in their ability to induce neonatal tolerance. The more subtle mutations, such asK ^bm5 andK ^bm8, proved to be excellent tolerogens, but theK ^bm3 mutant (M505) turned out to be the poorest tolerogen yet studied of all H-2 alloantigens. By challenging tolerant animals with skin grafts from related mutants, it was found that expression of tolerance was highly specific. Although a minority of tolerant animals failed to discriminate between the K^b, K^bm5 and K^bm8 antigens, they never failed to discern K^b, K^bml and K^bm3 as distinctly different alloantigens.     

Biochemical analysis of an MHC-linked hematopoietic cell surface antigen,Qa-2

The region of the murine 17th chromosome telomeric to H-2D encodes a group of serologically defined cell surface antigens termed Qa-1-5. These antigens are of interest because their expression is restricted to hematopoietic cells. In addition, the molecular weight and subunit structure (ie, association with β-2 microglobulin) of Qa-2 molecules are similar to H-2 and TL antigens. In the present studies, we have prepared isotopically labeled Qa-2 and H-2 molecules from mitogen-stimulated C57BL/6 spleen cells. Comparative peptide mapping of tryptic peptides from Qa-2 and H-2 molecules (K^b, D^bK^k, D^d) reveal that Qa-2 has a unique primary structure. However, considerable homology is indicated since 30–40% of the Qa-2 peptides cochromatograph with peptides derived from H-2K^b, H-2D^b, H-2K^k, and H-2D^d. Studies by other investigators have demonstrated that similar levels of structural homology are observed when H-2K, H-2D, and H-2L tryptic peptides are analyzed. We conclude from these studies that the Qa-2 alloantigen is structurally related to a class of cell surface molecules (ie, H-2) that play critical roles in immune recognition processes. These data further suggest that the genes encoding Qa-2 and H-2 molecules have arisen from a common primordial gene.     

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.     

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

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

Dissociation ofH-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-2 ^b /H-2 ^b ). Unlike C57BL/10 spleen cells, EL-4 lymphoma cells and Y57-2C leukemia cells (allH-2 ^b /H-2 ^b ), FY7 failed to induce the primary in vitro generation of anti-H-2^b CTL by (B10.A x A)F₁ (H-2 ^a /H-2 ^a or (B10.D2 x BALB/c)F₁ (H-2 ^d /H-2 ^d ) responder spleen cells. In addition, FY7 was not lysed by, and did not competitively inhibit anti-H-2^b CTL. Quantitative absorption tests with H-2K^b and H-2D^b antisera revealed that FY7 expressed these antigens in quantitatively similar amounts to EL-4. The H-2K^b 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-2K^b CTL competitively in a cold target inhibition assay. Possible mechanisms are discussed for the lack of T-lymphocyte recognition of the H-2K^b-gene product expressed by FY7.Abbreviations used in this paper CTL cytotoxic T lymphocytes - MHC major histocompatibility complex - MLC mixed lymphocyte culture - PAGE polyacrylamide gel electrophoresis     

Analysis ofH-2 mutants: Evidence for multiple CML target specificities controlled by theH-2K b gene

C57BL/6 (H-2 ^b ) mice and two mutants derived from this strain, B6.C-H-2 ^ba (Hz1) andE6-H-2 ^bd (M505), were studied in a number of functional tests, in vitro and in vivo, that assay for differences at theH-2 complex. All three strains give rise to reciprocal mixed lymphocyte reactivity (MLR) and cell-mediated lympholysis (CML) in vitro as well as graft-host reactivity (GVHR) and skin graft rejection in vivo. Analysis for cross-reactivity between these strains in CML revealed that the gained antigens in each mutant do not cross-react, and that Hz1 has lost an antigen shared by C57BL/6 and M505 strains. In addition, spleen cells from B10.A(4R) mice, which differ from theH-2 ^b haplotype only at theK end of theH-2 complex, recognize a common antigen shared by all three strains tested. Provided that the mutations occurred in theH-2K ^b gene, these data indicate that a) there are at least three antigenic specificities coded for by theH-2K ^b gene(s) that serve as targets for receptors on thymus-derived (T) cells in CML; b) since C57BL/6 strain mice and the mutants are serologically indistinguishable on a qualitative basis, the antigens recognized by the receptors on T cells and by humoral H-2 antibody are nonidentical; and c) mutation in theH-2K ^b locus itself can give rise to allogeneic recognition phenomena such as MLR and GVHR.     

Immunogenetic analysis ofH-2 mutations

A.BY, B10.LPa, and B10.129(5M) mice were presensitized in vivo against B10.A(5R) cells and then restimulated in vitro by the same cells in the standard CML assay. The effector cells thus generated lysed not only B10.A(5R), but also C57BL/6 targets, indicating that, in addition to anti-H-2D_d response [measured on the B10.A(5R) targets], response to minor histocompatibility (H) antigens (measured on the C57BL/6 targets) also occurred. The latter response was directed against multiple minor H antigens in the case of the A.BY effectors, and against H-1 and H-3 antigens in the case of B10.129(5M) and B10.LPa effectors, respectively. The sensitization against minor H antigens occurred in the context of H-2K^b H-2D^d antigens, but by testing the response on C57BL/6 targets, only cells reacting with minor H antigens in the context of H-2K^b were assayed. The same effector cells were then tested against H-2^b mutant strains, in which theH-2K ^b allele was replaced by a mutant one. All three effector types [A.BY, B10.LPa, and B10.129(5M)] behaved in a similar way: they all reacted with theH-2 ^bg1 mutant to the same degree as withH-2 ^b, they did not react at all or reacted only weakly with theH-2 ^bd andH-2 ^bh mutants, and they reacted moderately or strongly with theH-2 ^ba mutant. The degree of crossreactivity with the mutants reflects, with one exception, the degree of relatedness of these mutants toH-2 ^b, as established by other methods. The one exception is theH-2 ^ba mutant, which is the most unrelated toH-2 ^b, and yet it crossreacted strongly. Further testing, however, suggested that in this instance the crossreactivity was probably directed against H-2 antigens: the anti-H-2D^d effectors apparently crossreacted with the H-2K^ba antigens. This finding is an example of cell-mediated crossreactivity between the products of two differentH-2 genes (H-2K andH-2D). It is also an example of anH-2 mutation generating an antigenic determinant known to be present in another strain.     

Biochemical studies of H-2K antigens from a group of related mutants. II. Identification of a shared mutation in B6-H-2 bm6 , B6.C-H-2 bm7 , and B6.C-H-2 bm9

In an earlier paper, we presented evidence that two independent mutants of the bg series, B6-H-2 ^bm5 (bm5) and B6-H-2 ^bm16 (bm16) carry identical mutations such that tyrosine at residue number 116 of the H-2K^b molecule from the parent strain C57BL/6Kh is replaced by a phenylalanine in each of the two mutant molecules. In this paper, we demonstrate, using similar techniques, that the independent bg series mutants B6-H-2 ^bm6 (bm6), B6.C-H-2 ^bm7 (bm7), and B6.C-H-2 ^bm9 (bm9), which share biological properties with bm5 and bm16, can be grouped together because they share two identical mutations, one of which is common to bm5 and bm16, a Tyr to Phe interchange at residue number 116. In addition, a second mutation is at residue number 121, where a Cys in the H-2K molecule from 136 is substituted with an Arg in the mutant. Since all of the bg series mutants arose independently and share biological and biochemical characteristics, it is anticipated that study of these mutants could lead to some understanding of the high mutation rate in the K^b molecule.     

Immunoselection of structural H-2Kb variants: Use of cloned cytolytic T cells to select for loss of a CTL-defined allodeterminant

Functional studies concerning the unique interaction between class I H-2 allodeterminants and cytolytic T lymphocyte (CTL) antigen receptors have benefitted from the development of H-2K^b mutant mouse strains and somatic H-2 variants selected with monoclonal antibody. Here, we describe the development of a novel approach to immunoselection of somatic H-2K^b variants employing a K^b-specific CTL clone as the negative selective agent. The rationale for this method is that the use of an alloreactive CTL clone as the selective agent should enable us to detect the emergence of structural K^b variants based on their loss of the relevant CTL-defined allodeterminant. Thus, these structural variants are well suited to an in-depth analysis of the functional relationship between H-2 antigens and receptor recognition by CTL. Using this approach, we successfully isolated two types of structural K^b variants, as well as numerous Kb-loss variants. The functional studies described in this paper indicate that these structural variants exhibit alterations in expression of both CTL-defined and serologically defined H-2K^b allodeterminants. The structural characterization of such variants should enable us to identify the precise amino acid residues responsible for the creation of the relevant CTL-defined K^b allodeterminants.     

Cross-reactivity patterns of vaccinia-specific cytotoxic T lymphocytes from H-2K b mutants

Limit-dilution cultures were used to select vaccinia-immune T-cell populations from bml and bm3 mutant mice that were not lytic for virus-infected targets expressing the K^b and D^b MHC glycoprotein. Approximately 30% of virus-immune CTL were restricted in each case to K^bm1 and K^bm3, rather than to D^b. Evidence of extensive cross-reactivity was found for these virus-immune CTL. Bm3 and bmll mice sharing one amino acid mutation from wild-type but differing by a second mutation seen only in bm3 are the most cross-reactive pair in their presentation of vaccinia. The bm1 and bm10 pair with dissimilar mutations from wild-type affecting the same CNBr fragment are also largely cross-reactive. However, 30% cross-reactivity is also found for bm1 and bm3, which differ in separate CNBr fragments. That mutants expressing amino acid substitutions in the same region of the peptide tend to show more evidence of cross-reactivity does not necessarily mean the T cells see linear arrays of amino acids on the MHC glycoprotein. For instance, K^bm1 and K^bm10 differ for three amino acids, but bm1 T cells are highly lytic for bm10 virus-infected targets. However, there is no cross-reactivity for K^bm1 and K^b, which differ at only two amino acids. The key to further understanding may rest with defining the nature of the conformational differences among the K^bm1, K^bm10, and K^b glycoproteins.     

CD8+ T-Cell Epitope Mapping for Pneumonia Virus of Mice in H-2b Mice

The paramyxovirus pneumonia virus of mice (PVM) is a rodent model of human respiratory syncytial virus (hRSV) pathogenesis. Here we characterized the PVM-specific CD8⁺ T-cell repertoire in susceptible C57BL/6 mice. In total, 15 PVM-specific CD8⁺ T-cell epitopes restricted by H-2D^b and/or H-2K^b were identified. These data open the door for using widely profiled, genetically manipulated C57BL/6 mice to study the contribution of epitope-specific CD8⁺ T cells to PVM pathogenesis.     

Co-expression of immunogenic determinants by the same cellular immunogen is required for the optimum immunotherapeutic benefit in mice with melanoma

 Tumor-associated T cell epitopes are recognized by T cells in the context of determinants specified by class I loci. Since the rejection of foreign histocompatibility antigens is known to enhance tumor immunity, immunization with a cellular vaccine that combined the expression of both syngeneic and allogeneic class I determinants could have important immunological advantages over a vaccine that expressed either syngeneic or allogeneic determinants alone. To investigate this question in a mouse melanoma model system, we tested the immunotherapeutic properties of B16 melanoma × LM fibroblast hybrid cells in C57BL/6J mice with melanoma. Like C57BL/6J mice, B16 cells expressed H-2K^b class I determinants and (antibody-defined) melanoma-associated antigens. LM cells, of C3H mouse origin, formed H-2K^k determinants along with B7.1, a co-stimulatory molecule that can activate T cells. The B16 × LM hybrid cells co-expressed H-2K^b and H-2K^k class I determinants, B7.1 and the melanoma-associated antigens. C57BL/6J mice with melanoma, immunized with the semi-allogeneic hybrid cells, developed CD8-mediated melanoma immunity and survived significantly (P<0.005) longer than mice with melanoma immunized with a mixture of the parental cell types. The failure of melanoma immunity to develop in mice injected with the mixture of parental cells indicated that co-expression of the immunogenic determinants by the same cellular immunogen was necessary for an optimum immunotherapeutic effect. Augmented immunity to melanoma in mice immunized with the semi-allogeneic hybrid cells points toward an analogous form of therapy for patients with melanoma. Received: 19 May 1997 / Accepted: 23 July 1997     

Host-determined T cell fine specificity for self-H-2 in radiation bone-marrow chimeras of standard C57BL/6 (H-2b) mutantHz1 (H-2ba), and F1 mice

Reciprocal radiation bone-marrow chimeras were produced between the standard C57BL/6 (=B6) and the mutant B6.C-H-2 ^ba (=Hz1) strain. When infected with vaccinia virus, these chimeras, as well as an (Hz1 × B6)= Hz1 chimera, produced cytotoxic cells that killed vaccinia-infected H-2K^kH-2D^b target cells but failed to kill virus-infected H-2K^bH-2D^d cells. Virus-infected (Hz1 × B6)F₁ B6 chimeras, however, killed both types of target. These experiments demonstrate strict T-cell specificity capable of differentiating between two molecules that apparently differ by a single amino acid substitution.     

Biochemical studies on the H-2K mutant B6.C-H-2 bm10

The H-2K glycoprotein from the MHC mutant bm10 was analyzed biochemically to determine where primary structural differences distinguished it from the parental standard molecule, K^b. Comparative peptide maps showed differences in two peptides known to be part of the parental CNBr fragment spanning amino acids 139 to 228. Partial sequence analyses of CNBr fragments and tryptic peptides identified two tightly clustered amino acid substitutions at amino acids 165 (Val to Met) and 173 (Lys to unknown). The substitutions in bm10 represent the most carboxy-terminal substitutions characterized in the K^b molecules of the spontaneous, histogenically active H-2 mutants.     

Do histocompatibility antigens recognize themselves?

In the Simonsen spleen weight assay, theH-2K ^ba mutant does not respond against theH-2K ^bd mutant orH-2K ^bd /H-2K ^b hybrid, while the parentalH-2K ^b haplotype does respond. TheH-2K ^ba /H-2K ^b hybrid reacts strongly to bothH-2K ^bd andH-2K ^bd /H-2K ^b , indicating that the donor genotype could influence the reactivity against the same antigenic difference. The response of theH-2 ^ba mutant against a number of unrelated H-2 antigens does not differ from that of the parental haplotype. TheH-2K ^bd mutant reacts againstH-2K ^b andH-2K ^ba , and theH-2K ^b parent reacts against both theH-2K ^ba andH-2K ^bd mutants. The specific defect of reactivity in theH-2K ^ba mutant is effectively complemented by crossing with a number of unrelatedH-2 haplotypes. TheH-2 ^ka andH-2 ^fa mutants complement poorly compared to corresponding parental strains CBA and A.CA, while the B10.M (H-2 ^f ) strain does not complement at all (which is probably attributable to an undetectedH-2 mutation in the last strain). The data strongly suggest that the product of theH-2K locus-which is known to function as a transplantation antigen, lymphocyte activating determinant, and serologically defined antigen-also influences the immune response capacity against a mutant histocompatibility determinant.     

Class I MHC molecules rather than other mouse genes dictate influenza epitope recognition by cytotoxic T cells

Influenza nucleoprotein (NP) is an important target antigen for influenza A virus cross-reactive cytotoxic T cells (Tc). Here we examine the NP epitope recognized by cloned and polyclonal BALB/c Tc and the genetics of this recognition pattern. We can define NP residues 147–161 as the epitope seen in conjunction with K ^d , the only H-2^d class I responder allele for NP restriction. H-2 ^d /H-2 ^b F₁ mice (C57BL × DBA/2) primed by influenza infection lyse only H-2^d target cells treated with peptide 147–161 while H-2^b targets are recognized only after treatment with NP residues 365–379 (previously found to be recognized by D^b restricted Tc cells). Tc cell recognition of NP peptide 147–161 is entirely dictated by expression of K ^d and not by other B10 or OH background genes of congenic mice. Restriction of a unique NP sequence by each responder class I major histocompatibility complex (MHC) allele suggests that antigen and class I MHC interact for Tc recognition.