Expression of the I-E target antigen for T-cell killing requires two genes

The H-2Ik region encodes at least two different target antigens for unrestricted T-cell mediated killing. The first is controlled by the I-A region alone and the second depends on a pair of alleles, one located to the left of I-B (presumably in I-A) and the other to the right of I-J (presumably in I-E). Hence, effector cells nominally specific for a product of the I-E region do not kill target cells with the same I-E region as the stimulator unless the I-A region is also shared. Some effectors specific for H-2Ik, such as A.TH anti-A.TL and B10.A(4R) anti-B10.A(2R), cross-react with B10.A(3R) and B10.A(5R) target cells. A product of the H-2b haplotype was shown to complement products of the H-2d or H-2k haplotypes in forming this cross-reactive determinant. The results are consistent with recent biochemical data on the component chains of Ia antigens.     

Genetic analysis of the H-2D region using a new intra-D-region recombinant mouse strain

A rare D-region recombination event which gave rise to the B10.RQDB major histocompatibility complex haplotype has been examined to ascertain the nature of the crossover and to determine which class I genes are present in the new alignment of D-region genes. Serologic analysis have shown that the B10 . RQDB major histocompatibility complex recombinant mouse inherited the H-2Dd gene from the B10.T(6R) parental line and the H-2Db gene from the B10.A(2R) parental line, representing the first example of an intra-D-region crossover resulting from an intercross. Previous molecular genetic analyses of the d and b haplotypes revealed structural diversity in the organization of their D-region gene clusters. Hence, the D region is comprised of five class I genes in the d haplotype and only one in the b haplotype. Because allelic relationships among the various D-region genes are not defined, either a homologous or nonhomologous alignment of genes has generated the RQDB crossover. Therefore, the possibility that all three D-region antigen-presenting molecules (Dd, Ld, and Db) might be encoded by the RQDB haplotype was examined. Fluorescence-activated cell sorter and cytotoxic T lymphocyte analyses revealed no detectable levels of H-2Ld cell-surface expression, confirming earlier studies with antibody-mediated cytotoxicity and immunoprecipitation. Southern blot analysis localized the recombination point to within a 1-kb region at the centromeric end of the H-2Ld gene on the B10 . T(6R) chromosome in a region of high homology to the H-2Db gene on the B10 . A(2R) chromosome. Together, these studies define the D region of the RQDB haplotype as containing the five class I genes: Dd, D2d, D3d, D4d, and Db. In addition to providing insight into rare recombination events in the D region, the B10.RQDB mouse should be a useful tool for exploring the function of D-region genes.     

Genetic control of immune responses to the 18-kDa protein of Mycobacterium leprae. Different TH1 subsets may be involved in proliferative and delayed-type hypersensitivity responses.

In vitro and in vivo responses to the 18-kDa protein of Mycobacterium leprae have been analysed in different strains of mice. Lymphocytes from BALB/cJ (H-2d), BALB.B (H-2b), B10.BR (H-2k), and B10.M (H-2f) mice primed with 18-kDa protein yielded high T cell proliferative responses, while those from C57BL/10J (H-2b) mice yielded lower responses. Both H-2 and non-H-2 genes contributed to the magnitude of responsiveness. F1 mice from high and low responder strains showed high responsiveness to the 18-kDa protein. Supernatants from lymph node cell cultures prepared from 18-kDa protein-immunised BALB/cJ, B10.BR, and C57BL/10J mice contained IL-2 but no IL-4, indicating that activated T cells from both high and low responder mice were of a TH1 phenotype. Cell cultures from low responder C57BL/10J mice produced less IL-2 than those from high responders. The low responsiveness to the 18-kDa protein in proliferative assays might be due to a low frequency of antigen-specific T cells in the C57BL/10J mouse strain. BALB/cJ, C57BL/10J, and F1 (BALB/cJ x B10.BR) mouse strains were tested for in vivo DTH reactions to the 18-kDa protein. All strains, including C57BL/10J, were high DTH responders. Although DTH effector cells and 18-kDa protein-specific proliferative T cells belong to the TH1 subset, our data comparing high and low responder status indicate that distinct TH1 subpopulations are stimulated in response to the 18-kDa protein of M. leprae.     

Effects of H-2 complex and non-H-2 background on urethane-induced chromosomal aberrations in mice

The incidence of in vivo urethane-induced chromosomal aberrations was examined in H-2 congenic strains of mice with B10 and A backgrounds. Chromosome analysis of bone-marrow cells could divide 7 lines of A.H-2 congenic strains into 2 groups: one with a higher frequency of chromosomal aberrations such as in A/Wy (haplotype H-2a), A/J (H-2a), A.AL (H-2al) and A.TL (H-2tl), and the other consisting of A.TH (H-2t2), A.CA (H-2f), A.BY (H-2b) and A.SW (H-2s). The same tendency was also observed in the spleen cells. Among B10.H-2 congenic mice, B10.A (H-2a), B10.BR (H-2k), B10.A(3R) (H-2i3), B10.A(5R) (H-2i5) and B10.S(9R) (H-2t4) exhibited significantly higher rates of induced chromosomal aberrations than those in B10 (H-2b), B10.S (H-2s), B10.A(2R) (H-2h2), B10.A(4R) (H-2h4) and B10.S(7R) (H-2t2). To determine the effect on non-H-2 genetic backgrounds on urethane-induced chromosomal aberrations, 4 pairs of strains which have the same H-2 haplotypes, such as in B10 vs. A.BY (H-2b), B10.A vs. A/Wy (H-2a), B10.S vs. A.SW (H-2s), and B10.S(7R) vs. A.TH (H-2t2), were compared. The strains with a B10 background exhibited significantly higher frequencies of deletions and lower frequencies of exchanges than the strains with an A background. These data suggested that at least two genes are involved in the regulation of urethane-induced chromosomal aberrations in mice, one of which is mapped between the S and D regions in the H-2 complex, and another not belonging to H-2.     

Characterization of the target cell antigen in I region-mediated lympholysis.

Cytotoxic T lymphocytes (CL) can be produced by culturing I region disparate spleen cells as previously reported. More recently, it was shown that these CL can lyse other target cells which shared only the I-A subregion with the stimulator cells, i.e., lysis of these target cells is not H-2K/D restricted. Since I region-mediated lympholysis represents the only strong exception ruling out the obligatory role for H-2K/D products in mediating cytolysis of target cells, it is important to characterize further the target antigen recognized by CL in this system.A.TH anti-A.TL or (A.TL × B10.A) Fl anti-B10.HTT CL were generated in a 4-day primary culture system. The CL, shown to be Thy-1⁺, are able to kill targets that share only the central region of H-2 with the stimulator cells. These I region-specific CL can also lyse target cells that express a cross-reacting Ia antigen with the stimulator cells. Incompatibilities at IA/IB and IE/IC gave stronger cell-mediated lympholysis than incompatibilities at IA/IB only. Experiments involving the use of cold target competition, inhibition by specific anti-Ia serum, and target cells containing different proportions of Ia⁺ cells, strongly suggest that the target antigens recognized by the CL are in fact Ia antigens.     

H-2 haplotype and the embryotoxicity of serum from nonpregnant congenic mice

Previous studies revealed a significant association between genes at or near the H-2 complex and fetal loss. Reasoning that the maternal serum might contain one or more unknown factors that are harmful to early embryonic or fetal development, or both, we performed an embryotoxicity screen using chick embryos and serum from nonpregnant C57BL/10Sn(H-2 ^b) and B10.A/SnSg (H-2 ^a) congenic mice. Serum from the strain with the higher frequency of fetal loss (C57BL/10 Sn) yielded a significantly greater frequency of chick abnormality, specifically neural tube malformation and death, than the serum from the strain with the lower frequency of fetal loss (B10.A/SnSg). Further, the C57BL/10 Sn serum demonstrated a highly significant dose-response. These results suggest that analogous studies may be profitable with women who have a history of chronic fetal wastage and/or offspring with neural tube defects.     

Cross reactions in the H-2 system of cytotoxic T-lymphocytes concentrated by the adsorption-elution method on target cell monolayers]

Cytotoxic T-lymphocytes (CTL) obtained by in vivo immunization were enriched by the absorption-elution technique, using the relevant allogeneic target cell (TC) monolayers. After the separation of C57BL anti-A (anti-KkDd) lymphocytes into anti-Kk and anti-Dd subpopulations they displayed cross killing cytotoxic effect on H-2d and H-2kTC, respectively. B10D2 anti-B10 (anti-KbDd) lymphocytes cross reacted to H-2a and H-2q TC. The results are discussed in the light of heterogeneity of CTL clones or their receptors.     

Mouse alloantibodies capable of blocking cytotoxic T cell function. V. The majority of I region-specific CTL are Lyt-2+ but are relatively resistant to anti-Lyt-2 blocking

In an attempt to solve the conflict concerning the correlation between the Lyt-2 phenotype of T cells subsets and the type of the MHC antigens involved in the recognition by T cells, class 2 (I region) antigen-specific CTL were studied for their Lyt phenotypes and the sensitivity to the blocking effects of anti-Lyt-2,3 antibodies. To avoid contamination by CTL to class 1 antigens such as Qa antigens, A.TH anti-A. TL attackers and A.TH anti-A attackers were tested on LPS blasts of the A strain and the A.TL stain, respectively. By using these combinations, it was shown that the majority of I region-specific killers were Thy-1+, Lyt-1+23+. Specific target cell lysis by these cells were, however, found to be far less sensitive to the blocking effects of various monoclonal antibodies to the Lyt-2,3 antigens than conventional class 1-specific CTL. This conclusion was drawn by directly comparing the sensitivity of the I region-specific and K region-specific killing by identical numbers of the same attacker cells (A.TH anti-A). No significant difference was seen between the primary and the hyperimmune CTL. Lyt-2-, Thy-1+ killer cells with I region specificity could be induced when Lyt-2-depleted A.TH responder cells were stimulated in vitro. Such Lyt-2- killer cells were not induced to the H-2K alloantigen.     

A new erythrocytic antigen of C57BL/10 (B10) mice

A new antigen, detectable on murine erythrocytes by hemagglutination assay with a (BALB/cCrl X SWR/J)F1 anti-B10.D2n/Sn alloantiserum, is described. Among the inbred and congenic mouse strains tested for reactivity with the antiserum, only the immunizing strain, B10.D2, and its congenic resistant partner, C57BL/10 (B10), reacted. Three other C57 strains, C57BL/6J, C57BL/6By, and C57L, were negative for the antigen. F1 hybrids between B10 and BALB/c, an antigen-negative strain, were positive for the antigen indicating that its expression is dominant. Typing of 39 (BALB/c X (BALB/c X B10)F1) and 62 [BALB/c X B10)F1 X BALB/c) backcross mice revealed that a single gene controls expression of the antigen. The gene is autosomal and not linked to H-2, Ly-4, or the c (albino) or b coat color genes.     

Evolution and expression of the transplantation antigen gene family

We have cloned 26 different class I genes that are located in the major histocompatibility complex of the C57BL/10 mouse. Two of the three class I genes found in the H-2 complex encode the H-2Kb and H-2Db antigens; the other 23 class I genes map to the adjacent Tla complex. We have grouped the cosmids containing these genes into three clusters: one cluster links the H-2K and I-A regions, one cluster links the H-2D and Qa-2 regions, and the final cluster maps to the TL region. The class I gene organizations in the Qa-2 and TL regions of the C57BL/10 and BALB/c mice are generally similar, but there are several polymorphic segments. The Qa-2 region of both mice seems to have evolved by the duplication of gene pairs; furthermore, the H-2K region may have been generated by the translocation of a gene pair from the Qa-2 region. We have evidence that several of the genes in the Qa-2 region are expressed.     

Comparison of immune responses to diphtheria and tetanus toxoids of various mouse strains

Immune responses of 11 mouse strains with known genetical characteristics and two outbred strains to diphtheria and to tetanus toxoids were compared. Both diphtheria and tetanus antitoxins were titrated by passive hemagglutination. From the pattern of the immune response, the mouse strains tested may be classified into four groups. [1] Strains ddY (SPF) and ddY (conv) and those with haplotype H-2b, such as C57BL/6 and C57BL/10, were high responders to both toxoids. [2] Strains with H-2d, such as BALB/c, B10.D2 and DBA/2Cr, were intermediate responders to both toxoids. [3] Strains with H-2k, H-2a or, H-2m, such as C3H/He, B10.BR, B10.BR/SgSn, B10.A/SgSnJ and B10.AKM/O1a, were high responders to diphtheria toxoid but low responders to tetanus toxoid. [4] The strain with H-2h4, B10.A (4R), was a poor responder to both toxoids.     

Histocompatibility antigens controlled by theI region of the murineH-2 complex

Spleen cells from A.TH mice, presensitized in vivo by skin grafting, were restimulated in vitro by A.TL lymphocytes, and A.TH anti-A.TL effector cells were generated. The effector cells lysed, in the CML assay, A.TL blasts. This reaction, which was againstI-region antigens, could be inhibited by the addition to the reaction mixture of anti-La sera directed against A.TL antigens. The inhibition was specific, since normal mouse serum, reciprocal antiserum (A.TL anti-A.TH), and anti-H-2 sera did not have a significant effect on the reaction. The Ia antibodies also specifically inhibited the reaction of A.TH anti-A.TL effector cells against CBA targets. Con A blasts were significantly poorer targets inI-region CML than LPS blasts. As CML targets, macrophages and cells of a mammary adenocarcinoma were as good as, if not better than, the LPS blasts. The experiments support the notion that Ia antigens are the targets in theI-region CML.     

Participation of the H-2 system in regulating the sensitivity of mice to morphine

The pain susceptibility of congenic-resistant mouse strains A/Sn, C3H/Sn and C57BL/10 Sn after the injection of morphine was studied. Strains sensitive and resistant to this narcotic were distinguished among congenic-resistant A/Sn and C3H/Sn mice. The morphine sensitivity inheritance is characterized by dominance. The possibility of the major histocompatibility mouse system (H-2) participation in the genetic control of mouse susceptibility to morphine is discussed.     

Genetic control of acquired resistance to visceral leishmaniasis in mice

A series of H-2 and non-H-2 congenic resistant (CR) strains on a C57BL/10Sn background were infected with 10(7) amastigotes of Leishmania donovani. Non-H-2 congenic strains B10.LP-H-3b and B10.CE(30NX) and (B10.LP-H-3b x B10)F1 hybrids showed a very rapid decrease in liver-parasite burdens beyond day 21. Parasite counts for these strains at day 35 were significantly lower than for all other strains tested. The rapid decrease in parasite numbers, massive lymphocellular infiltration into the liver and strong delayed hypersensitivity reactions to parasite antigens in strains congenic for a portion of chromosome 2 indicated that acquired immunity to L. donovani was controlled by a dominant gene at or near the Ir-2 locus. In addition, B10.129(10M) mice, which differ from C57BL/10Sn at the H-11 locus, showed highly significant increases in parasite numbers at day 35. Other observations supporting the absence of acquired immunity in B10.129(10M) included negative delayed hypersensitivity tests to parasite antigens and the absence of lymphocellular infiltrate into the liver. Although the differences were not as pronounced, H-2 CR strains with H-2b, H-2a, and H-2k haplotypes also showed significantly greater decreases in parasite numbers by day 35 as compared to other H-2 CR strains.     

Dissociation of H-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-2b/H-2b). Unlike C57BL/10 spleen cells, EL-4 lymphoma cells and Y57-2C leukemia cells (all H-2b/H-2b), FY7 failed to induce the primary in vitro generation of anti-H-2b CTL by (B10.A x A)F1 (H-2a/H-2a) or B10.D2 x BALB/c)F1 (H-2d/H-2d) responder spleen cells. In addition, FY7 was not lysed by, and did not competitively inhibit anti-H-2b CTL. Quantitative absorption tests with H-2Kb and H-2Db antisera revealed that FY7 expressed these antigens in quantitatively similar amounts to EL-4. The H-2Kb 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-2Kb CTL competitively in a cold target inhibition assay. Possible mechanisms are discussed for the lack of T-lymphocyte recognition of the H-2Kb-gene product expressed by FY7.     

Evidence for more than one Ia antigenic specificity on molecules determined by the I-A subregion of the mouse major histocompatibility complex.

Ia antigenic specificities determined by the I-A subregion of the mouse major histocompatibility complex have been examined in strain B10.D2 (H-2d), C57BL/10 (H-2b), and in a (C57BL/6xDBA/2) hybrid (BDF1; H-2b/d). Detergent solubilized, 3H-leucine-labeled antigen preparations were mixed with appropriate alloantisera and precipitation was induced either by addition of goat anti-mouse gamma-globulin or by addition of protein A-bearing Staphylococci. Sequential precipitation analysis showed that in strain B10.D2, Ia specificities 8 and 11 were co-precipitable, and that in strain C57BL/10, Ia specificities 8 and 9 were co-precipitable. In contrast, precipitation of specificities 9 and 11 from a BDF1 antigen preparation showed that these two Ia specificities were on separate molecules. The genetic implications of these data are discussed.     

Serological cross-reactivity of murine A.TH anti-A.TL antibody (anti-l-Ek antibody) with La-like molecules of human antigen-presenting cells

The purified protein derivative (PPD)-specific proliferative responses of T cells from human peripheral blood are shown to be dependent on antigen-presenting cells (APC) which bear HLA-DR antigen detected by the monoclonal anti-HLA-DR antibody. The serological cross-reactivity of murine A.TH anti-A.TL antibody was observed in human APC. By absorption experiments using H-2 congenic mice, the serological cross-reactivity of A.TH anti-A.TL antibody with human APC is mapped in the I-E subregion. Thus, anti-I-Ek antibody reacts with the Ia-like molecule(s) on human APC. Murine allo-anti-I-Ek antibody does not always react with determinants of Ia-like molecule(s) on human APC, since this antibody did not eliminate PPD-specific proliferative responses in one particular case. Thus, anti-I-Ek antibody seems to react some type of the polymorphic determinants but not of the shared determinants of human Ia-like molecule(s) on APC. The relationship between the cross-reactive molecule detected by murine allo-anti-I-Ek antibody and the HLA-DR antigen remains to be analyzed.     

Evidence for the control of Eosinophilia by the major histocompatibility complex in mice

The genetic control of eosinophilia has been studied in congenic strains of mice. Eosinophilia was induced with cyclophosphamide followed by keyhole limpet hemocyanin in complete Freund's adjuvant. After this treatment, BALB/c mice developed a high eosinophil response, whereas CBA, C57BL and A/J mice developed a low one. The major histocompatibility complex (M-HQ was found to exert a control on eosinophilia, as B 10.D2 mice developed a higher eosinophil response than B10, B10.A, or B10.BR. BALB/c-H-2 ^k mice had a lower response than BALB/c, and A.TL mice had a higher response than A/J or A.TH. If a single gene within the MHC is responsible for these effects, the most likely position for it is in the vicinity of the Tla locus. Splenectomy reduced eosinophilia in BALB/c and A.TL mice, but not in A/J mice,indicating that the spleen is a significant site of eosinophil production in high responder strains.     

Major histocompatibility complex class II-regulated immunity to murine leukemia virus protects against early T- but not late B-cell lymphomas

We studied the relative importance of class I and class II major histocompatibility complex (MHC) immunoregulation in the control of T- and B-cell lymphomas induced by murine leukemia virus. Previously, we have described a mink cell focus-inducing (MCF) murine leukemia virus, MCF 1233, which induces not only lymphoblastic T-cell lymphomas but also follicle center cell or lymphoblastic B-cell lymphomas. We now report that the outcome of neonatal infection with MCF 1233 in H-2-congenic C57BL/10 and C57BL/6 mice is decisively influenced by the H-2 I-A locus. A total of 64% of H-2 I-Ak, d mice [B10.BR, B10.D2, B10.A(2R), B10.A(4R), and B10.MBR] developed T-cell lymphomas after MCF 1233 infection (mean latency, 37 weeks). In contrast, H-2 I-Ab [B10, B10.A(5R), B6], H-2 I-Ab/k [(B10.A x B10)F1 and (B10 x B10.A)F1], and H-2 I-Abm12 (bm12) mice were resistant against T-cell lymphomagenesis, but 65% of these H-2 I-Ab, b/k, bm12 animals developed B-cell lymphomas (mean latency, 71 weeks). Animals of T-cell lymphoma-susceptible strains that escaped from T-cell lymphomagenesis developed B-cell lymphomas with similar frequency as animals of T-cell lymphoma-resistant strains, but with a shorter latency. H-2 class II-determined regulation of antiviral immunity was reflected in the presence of high titers of antiviral envelope antibodies in T-cell lymphoma-resistant B-cell lymphoma-susceptible H-2 I-Ab, b/k, bm12 mice, whereas in T-cell lymphoma-susceptible H-2 I-Ak,d mice no antiviral antibodies were found. At week 4 after neonatal MCF 1233 infection, a high percentage of thymocytes were virally infected in both T-cell lymphoma-susceptible and -resistant mice. However, T-cell lymphoma-resistant animals cleared the thymic infection between weeks 4 and 10 of age, coinciding with a sharp rise in serum levels of antiviral antibodies. We conclude that the pleiotropic effects of MCF 1233 infection in H-2-congenic mice result from MHC class II I-A-determined T-cell response differences.     

Histocompatibility-2 system in wild mice. VI. Histogenetic analysis of sixteen B10.W congenic lines.

Sixteen B10.W congenic lines carrying wild derived H-2 haplotypes on C57BL/10Sn or B10 background were typed by the allogeneic cell-mediated lymphocytotoxicity (CML) assay; in addition, selected lines were also typed by the TNP-CML assay and by skin grafting. The analysis revealed similarity or identity of two strain pairs: SNA57 (H-2w21) ssems to carry a similar haplotype as B10.SM (H-2v), and STA10 and STA12 seem to share the same H-2K and H-2D alleles. All other B10.W strains were different from each other and from B10 congenic lines carrying inbred-derived H-2 haplotypes. These results agree with the results of the serologic typing with two exceptions: the KPA42, KPA132, and SNA57 lines, which were serologically indistinguishable from each other and from B10.SM, were distinguished by histogenetic typing. The presence among wild mice of a haplotype (H-2u21) that appears to be very similar to a haplotype (H-2v) carried by an inbred strain (B10.SM) has some interesting implications for considerations of H-2 gene mutability. The finding that haplotypes derived from different localities are different provides further evidence that the H-2 polymorphism is extensive, indeed.