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     

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.     

H-2 antigen variants in a cultured heterozygous mouse leukemia cell line

An H-2 antigen variant, referred to as ?4 + 31 clone 1, was selected by its resistance to an anti-H-2D^d antiserum (BALB.G anti-BALB/c.H-2 ^g antiH-2 ^d ). When tested by cell-mediated cytolysis, this variant was found to be sensitive to cytolytic T lymphocytes raised in the same donor-host combination as that used in raising the antiserum. Further CML characterization of this variant, reported here, indicates that the cell line is in fact resistant to anti-H-2D^d killer cells raised in a more restricted immunization, viz. BALB.G anti-BALB/cH-2 ^db ,H-2 ^g anti-H-2 ^db . It is, however, sensitive to cytolytic cells raised in (BALB.B xBALB/c-H-2db) F¹ H-2 ^b /H-2 ^db ) against the BALB/c strain. These results suggest that the variant does not express H-2D^d itself, but probably expresses CML target antigens that are missing in theH-2 ^db mutation. This in vitro-isolated variant might thus be the complementary mutation to the in vivoobtainedH-2 ^db mutation.     

CML typing of serologically identicalH-2 mutants

Cell-mediated lympholysis (CML) reactions were studied among four strains of C57BL/6 (B6) mice carrying mutant alleles (H-2 ^ba ,H-2 ^bd ,H-2 ^bg , andH-2 ^bh ) at thez1 locus in theK end ofH-2 ^b and the original B6 (H-2 ^b ) strain. Cross killing of target cells from lines that had not participated in the mixed lymphocyte reaction (MLR) was extensive, but usually less intense than that of target cells of stimulator cell genotype. The extent of CML crossreactivity could be limited by using cells from F₁ hybrid mice as responders in MLR. In a comprehensive analysis of the cytotoxicity exerted by 20 MLR combinations with homozygous, and 10 MLR combinations with F₁ hybrid responder cells, 19 different CML cytotoxicity patterns were identified, corresponding to at least 19 different CML target specificites. When the number of CML mismatches of each mutant with the originalH-2 ^b was calculated,H-2 ^ba was found to be most distinct fromH-2 ^b ,H-2 ^bs andH-2 ^bd were closest toH-2 ^b , andH-2 ^bh occupied an intermediate position. The validity of this sequence of relatedness is supported by published reports on skin graft survival times and on the interaction of T lymphocytes with virus-infected target cells using cells fromz1 locus mutants.     

Study of H-2 mutations in mice. IV. A comparison of the mutants M505 and Hz1 by skin grafting and serological techniques

The line B6.M505 is congenic with C57BL/6JY and carries a mutant form of theH-2 ^b haplotype designatedH-2 ^bd . The mutant site 505 was located by the F₁ tests in theK end of theH-2 gene complex. The M505 mice are histoincompatible with the B6.C(Hz1) line (haplotypeH-2 ^ba ) carrying another mutation in theK end ofH-2 ^b . Inability of M505 to complement Hz1 in tests with B6 skin grafting is considered as an evidence that the same gene was altered by both mutations. The gained H antigens of two mutants can cross-react in vivo as revealed by accelerated rejection of Hz1 skin grafts by B6 recipients presensitized with M505 spleen cells. The lost antigenic determinants are not identical as shown by accelerated rejection of B6 skin grafts by Hz1 hosts preimmunized with M505 spleen cells. Absorptions of the antiserum ASY-015, (d×a) anti-i, anti-H-2.33 with M505 spleen cells did not clear forH-2 ⁱ ,H-2 ^b andH-2 ^ba , and absorptions with Hz1 did not clear forH-2 ⁱ ,H-2 ^b , andH-2 ^bd . These results show that changes of histocompatibility determinants may be accompanied by loss of some haptenic determinants in the Hz1 and M505 mutations.     

Teratocarcinoma transplantation rejection loci: Genetic localization of the Gt-1 locus on chromosome 17 and the expression of alternate alleles

A series of congenic mice on the BALB/c genetic background have been employed to localize a teratocarcinoma transplantation rejection locus, Gt-1, to the K side of the H-2 locus on chromosome 17. Previous studies have placed the Gt-1 ^sv allele about 8 centimorgans away from the H-2 ^b or H-2 ^bv1 locus. Teratocarcinomas derived from 129/sv mice, Gt-1 ^sv (H-2K ^bv1/H-2D ^bv1), are rejected by BALB/c (H-2K ^d/H-2D^d) and BALB-G mice (H-2K ^d/H2D-^b, but form tumors in BALB-B (H-2K ^b/H2D ^b) and BALB/5R5 mice (H-2K ^b/H2D ^d). In the reciprocal tumor-rejection test, a BALB/c teratocarcinoma was rejected by immunized BALB·B mice, but formed tumors in the immunized isogenic BALB/c mouse. These studies demonstrate the reciprocal expression of two Gt-1 alleles, one Gt-1 ^c, in BALB/c mice, and the other, Gt-1 ^sv, in the congenic BALB·B mice. Shedlovsky and co-workers have placed the Gt-1 locus in a similar location on the K side of the H-2 locus on chromosome 17.     

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.     

Study ofH-2 mutations in mice

The serologically defined H-2.5 specificity was tested on spleen cells and red blood cells (RBC) of theH-2 ^b haplotype and a number of its mutants. Thebm8 (bh) mutant was barely distinguishable fromb in a variety of tests made. On spleen cells ofbm1 (ba) the H-2.5 specificity seemed to be unchanged, while it was virtually absent from RBC of this mutant. Mutantsbm4 (bf),bm5 (bg1), andbm6 (bg2) were similar tobm1, with slight differences between them. The mutantbm3 (bd) retained an unchanged quantity of H-2.5 on its spleen cells, while the specificity was substantially increased on its RBC. The H-2.5 ofbm3 is not identical to that ofH-2 ^a . Possible mechanisms causing differential serology of theH-2 ^b mutants are discussed.     

The genetic control of the immune response to murine histocompatibility antigens

The genetic control of the immune response to H-4 histocompatibility alloantigens is described. The rejection of H-4.2-incompatible skin grafts is regulated by anH-2-linkedIr gene. Fast responsiveness is determined by a dominant allele at theIrH-4.2 locus. TheH-2 ^b ,H-2 ^d , andH-2 ^s haplotypes share the fast response allele;H-2 ^a has the slow response allele. Through the use of intra-H-2 recombinants, we have mapped theIrH-4.2 locus to theI-B subregion of theH-2 complex; theH-2 ^h4 ,H-2 ¹⁵, andH-2 ^t4 haplotypes are fast responder haplotypes. These observations suggest that the strength of non-H-2 histocompatibility antigens is ultimately determined by the antigen-specific recipient responsiveness.     

Intra-H-2 recombination in the mouse

Serological characterization of threeK-S interval recombinant strains, TBR2 (H-2 ^at2 ), TBR3 (H-2 ^at3 ) and AIR1 (H-2 ^a2 ) was performed using anti-H-2, Ia, Ss and Slp antisera. The data presented here reveal that the crossover events in both TBR2 and TBR3 occurred between theI-A andI-E subregions. In both cases, theH-2K andI-A subregions were derived from theH-2 ^t1 chromosome, while theI-E, S andH-2D regions were derived from theH-2 ^b chromosome (K ^s A ^k E ^b S ^b D ^b ). TheH-2 ^a2 chromosome resulted from a crossover event between theH-2 ^a1 andH-2 ⁱ⁹ chromosomes. Ia and Ss typing of AIR1 suggested that theK toI-E regions originated fromH-2 ^a1 and theS andD regions originated fromH-2 ⁱ⁹ (K ^k A ^k E ^k S ^b D ^d ).     

Adoptive transfer of delayed-type hypersensitivity to sendai virus

TheH-2 restriction pattern of cytolytic T lymphocytes (Tc) and T lymphocytes which mediate a delayed-type hypersensitivity response (Td) directed against infectious Sendai virus was investigated usingH-2 mutant mice. Td and Tc lymphocytes exhibit the same fine specificity for self-recognition, for example, B6.C-H- 2^bm1 effector T cells were unable to recognize viral antigens in association with wild-type K^b and vice versa, B6.-H- 2^bm6 effector cells did not mediate a reaction against virus plus wild-type K^b but, on the other hand, T cells of wild-type K^b recognized virus plus K^bm6.BALB/c-H- 2^dm2 T cells lacked reactivity against virus in association with wild-type D^d, but again wild-type D^d effector cells recognized virus plus D^dm2.Abbreviations used in this paper DTH delayed-type hypersensitivity - EID₅₀ mean egg infective dose - FCS fetal calf serum - HAU hemagglutinating units - LPS lipopolysaccharide - Ly^(–) low amount of Ly antigens - MHC major histocompatibility complex - 2-ME 2-mercaptoethanol - PBS phosphate-buffered saline - Tc cytolytic T cell - Td T cell which mediates a delayed-type hypersensitivity reaction     

H-2 antigen variants in a cultured mouse leukemia cell line

We have investigated the effect of immune selection against a single gene product on a cultured mouse Friend leukemia cell line. The clonal cell line used is heterozygous at theH-2 complex and expresses theH-2 ^d andH-2 ^b haplotypes. The genes selected against were theH-2K locus alleles. Variants were obtained after a single-step selection using either antiH-2K^b or anti-H-2K^d serum. The phenotypes of the variants obtained showed an interesting asymmetry between the two haplotypes. Selection against theH 2K ^b allele resulted in the isolation of the two expected types of variant-those that had lost only H-2K^b and those that had lost both H-2K^b and the linked H-2D^b. Selection against H-2K^d yielded, exclusively, variants that had lost both the selected antigen and the linked H-2D^d. None of the variants showed an alteration in expression of antigens intrans configuration. Karyotypic analyses of the variants revealed that all the cells had retained both copies of chromosome 17 present in the wild-type cells. The results suggest that the variants did not emerge through chromosome loss.     

Glyoxalase I activity inH-2 b andH-2 d cells

Erythrocytes and thymocytes of theH-2 ^d genotype express between 1.6 and 2.6 times as much glyoxalase I activity per milligram of protein as those of theH-2 ^b genotype; the activity in theF ₁ (H-2^b/H-2^d) cells is intermediate between these two values. Activity of glyoxalase II is not affected by the H-2 genotype. The H-2^d:H-2^b ratio of glyoxalase I activity is higher in the BALB background where it is 2.6:1 than in the B10 background where it is 1.6:1. Thermal denaturation kinetics of enzymes from the H-2^b and H-2^d genotype cells are the same.     

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.     

Time course study of H-2 and other antigen expression by hybrids of a myeloma cell line with inflammatory macrophages

The hybrids (the CANS lines) between inflammatory macrophages from C57BL/6N (B6) mice (H-2^b) and BALB/c mouse (H-2^d)-derived myeloma cell line NS1 in the early period after cell fusion showed no macrophage functions. However, most of the hybrids expressed these functions after prolonged cultivation accompanied with chromosome loss. In contrast, the hybrids initially displaying myeloma functions ( light chain production) lost this function when they exhibited macrophage functions. We studied the expression of cell-surface antigens in these hybrids and found that hybrids in the early period after cell fusion codominantly expressed both parental cell H-2 antigens (H-2K^b, H-2K^d, and H-2D^d) but not the H-2D^b antigen. On the other hand, aged hybrids strongly expressed the H-2 d antigen but lacked the H-2K^b antigen. Alternatively, these aged hybrids with macrophage functions expressed antigen(s) as detected with antiaged CANS-196 cell sera and asialo GM1 antigen, both of which were thought to be found exclusively on macrophages. Thus, the expression of cell-surface antigens in these hybrids was greatly altered after cell fusion.     

Dermal histocompatibility and in vitro lymphocyte reactions of three newH-2 mutants

Histocompatibility of skin grafts and in vitro lymphocyte reactions of three new H-2 mutants (B6-H-2 ^bg1, B6-H-2 ^bg2, and B6-H-2 ^bh ) are described. Complementation tests indicated thatH-2 ^bg1,H-2 ^bg2, andH-2 ^bh were mutations at the same locus (z-1) and allelic withH-2 ^ba . Two of the lines, B6-H-2 ^bg1 and B6-H-2 ^bg2, appeared identical, although they were of spontaneous and independent origin. The third line, B6-H-2 ^bh , was unique. Such graft rejection was paralleled by reactivity in the MLR and by the generation of cytotoxic lymphocytes in vitro. The pattern of crossreactivity among antigens specified by these mutant genes supports the notion that thez-1 locus controls multiple specificities. The results indicate that a single point mutation can simultaneously affect histocompatibility, MLR, and CML reactions.The genetic nomenclature for theH-2 complex is that of Kleinet al. (1974a).     

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.     

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.     

Anti-MHC immunity detected prior to intentional alloimmunization

Cell fusion was performed between spleen cells from young BALB/cBy (H-2 ^d) mice which have never been immunized and SP2/0 mouse plasmacytoma cells. A monoclonal H-2-specific cytotoxic IgM antibody was obtained (By-1) which detected a new public biregional H-2 specificity, H-2.m210. The mcAb By-1 reacted strongly with H-2K^d, D^d, and H-2^s antigens, gave weak cross-reactions with H-2K^k, D^q, H-2^r, and H-2^v antigens and was negative with H-2^b, H-2^f, H-2^p, and H-2L^d antigens. A polymorphic reaction pattern was also observed on a panel of lymphocytes from B 10.W strains. The intriguing finding on this reaction pattern was the reactivity on H-2^d cells, including the syngeneic BALB/cBy and truly autologous cells. As shown by capping and immunoprecipitation experiments on H-2^d cells and by studies on H-2^d-transfected mouse L cells, the target molecules for McAb By-1 were H-2K^d and H-2D^d molecules. The BALB/cBy mouse, from whose spleen cells the McAb By-1 was obtained, survived after the fusion experiment, and serum was examined for the presence of cytotoxic H-2-specific antibodies during the rest of its life. At the time of the fusion, no autoreactive serum antibodies were found, but about 4 months later, we found in the serum of this mouse autoreactive H-2-specific cytotoxic IgM antibodies. The serum antibodies followed the same reaction pattern as that of the McAb By-1. As far as we know, this is the first report of autoreactive H-2-specific antibodies in serum of a mouse which has never been immunized and of the first natural autoreactive H-2-specific monoclonal antibody.Abbreviations McAb monoclonal antibody - MHC major histocompatibility complex - H-2 major histocompatibility complex of mice - CTLs cytotoxic T cells - FMF flow microfluorometry - FITC fluorescein isothiocyanate - LPS lipopolysaccharide W.E. coli 0111:134 - PBS phosphate-buffered saline - Iodogen 1,3,4,6,-tetrachloro-3,6-diphenylglycoluril - GAMIg goat-antimouse immunoglobulin - Staph-A Staphylococcus aureus Cowan I     

Fine specificity of cytotoxic T lymphocytes directed againstH-2L d

The fine specificity of cytotoxic T lymphocytes (CTL) directed againstH-2L ^d was analyzed by studying the lytic activity of BALB/cH- 2^dm2 (H-2L ^d loss mutant) anti-BALB/c-H-2 ^d CTL, generated in secondary mixed lymphocyte culture (MLC) against a panel of target cells of differentH-2 haplotypes. Target cells of allH-2 haplotypes tested, except that of the MLC responder, were lysed by anti-L^d CTL, although to a widely varying extent. The genes coding for antigens detected by anti-L ^d CTL were mapped to distinct regions in theH-2 ^d ,H- 2^dm1,H-2 ^q ,H-2 ^k , andH-2 ^b haplotypes. The sequence of lysis intensity against the variousH-2 haplotypes and theH-2 regions involved were as follows:L ^d ,D ^q L ^q ,D ^dm1 L^dm1,K ^k ,D ^b L ^b ,r, p, f, s, C3H.OH (K ^d D ^k L ^k ), strong lysis occurring againstL ^d and weak lysis againstH-2 ^s and C3H.OH.By monolayer adsorption and cold target inhibition experiments, it was shown that anti-L ^d CTL contained a CTL subset directed against a private L^d specificity, hitherto undetected by anti-L ^d antibodies. This subset of CTL was separate from the CTL subsets reacting againstH-2 ^q and against the mutant haplotypeH- 2^dm1. The reactions against the latter two haplotypes were also mediated by separate CTL subsets. It is concluded that the L^d molecule, to a varying extent, shares target antigens for CTL with K- and/or D-end H-2 molecules of all haplotypes tested. These antigens are detected by multiple subsets of anti-L ^d CTL. One CTL subset is directed against a target structure unique forL ^d (L^d private specificity).