Homopoietic histocompatibility (Hh-1) phenotype and the regulation of its expression

Hybrid resistance (HR) is primarily controlled by the genes of the Hemopoietic histocompatibility-1 (Hh-1) locus within the H-2 complex. HR is a consequence of the Hh-1-controlled target determinants in homozygous parental strain mice and their absence in heterozygous F₁ hybrid mice. To examine the mechanism that controls the Hh-1 phenotype, three independent clones of somatic cell hybrids between parental lines EL-4 (C57BL/6 origin, H-2 ^b ) and R1 (C58 origin, H-2 ^k ) were studied. The line EL-4 is Hh-1^b-positive and is subject to HR by H-2 ^b heterozygous F₁ mice, but R1 lacks the Hh-1 ^b allele and is not susceptible to HR. Of the three hybrid clones, F263.2 is Hh-1^b-positive, whereas the other two, F262.2 and F264.2, are Hh-1-negative, as judged by these cells' capacity to compete in vivo with the grafted parental C57BL/6 bone marrow cells in the resistant (C57BL/6 × C3H)F₁ mice. All three clones express the H-2^b and H-2^k class I antigens equally well, are susceptible to activated NK cells to the same extent, and all carry four copies of chromosome 17. However, Southern analysis reveals that clone F263.2 contains three copies of H-2 ^b chromosome and one H-2 ^k , whereas the other two clones carry two copies each of the parental chromosome 17. The results suggest that the relative copy number of specific alleles is the crucial determinanr of the Hh-1 phenotype, and render unlikely both the gene dosage hypothesis and the trans-acting dominant suppression hypothesis to account for the noncodominant expression of the Hh-1 phenotype.     

Polymorphism of Hh-1, the mouse hemopoietic histocompatibility locus

The major goal of these studies is to more fully assess the polymorphism of the hemopoietic histocompatibility (Hh) genetic system. H-2 homozygosity is required for optimal immunogenicity of bone marrow cell (BMC) grafts, and hybrid resistance to grafts of parental strain BMC by irradiated H-2 heterozygous F₁ hybrid mice suggests that Hh-1 antigens are inherited recessively. The Hh-1 antigens are also expressed on other normal hematopoietic cells and lymphoid tumors, and natural killer cells are the effectors which mediate the elimination of BMC grafts in an Hh-specific manner. Previous studies have demonstrated three different antigens mapping to the Hh-1 locus near H-2D. We test the expression of Hh-1 on BMC of all nonrecombinant H-2 haplotypes of independent origin and H-2 ^j , a presumed natural recombinant. Hh-1 typing is based on the pattern of growth and rejection in a panel of hosts. F₁ hybrids with H-2 ^b , H-2 ^d , and H-2 ^k are produced and used as donors and hosts to confirm the phenotype. Grafts of b-, d-, and j-haplotype marrow serve as prototypical examples of determinants that are provisionally designated as 1, 2, and 3, respectively. We describe a new determinant, 4, in the k haplotype. It is non-codominantly expressed, maps to H-2D, and is also expressed on H-2^b BMC. NZW, H-2^Z grafts exhibit a phenotype similar to k, but express a unique determinant 5 which can be distinguished from determinant 4. This additional determinant is also expressed by the b haplotype. The d, f, and p haplotypes all express determinant 2, and grafts of j-haplotype marrow are found to express determinants 2 and 5 in addition to determinant 3. The q and r haplotypes are null for all known determinants. Finally, we describe a phenotype which is a new combination of previously described determinants: s-haplotype grafts express determinants 1, 2, and 4. The polymorphism of Hh-1 detected thus far consists of seven alleles which are combinations of five distinct determinants.     

Murine responses to (Tyr-Glu-Ala-Gly)n: II. H-2 and non-H-2 gene effects

Mice of the H-2^b haplotype responded to the sequential polymer poly(Tyr-Glu-Ala-Gly) in the in vitro T-cell proliferative assay, irrespective of whether they were homozygous or heterozygous at the H-2^b locus. The antibody responses of the H-2^b congenic mice to this polymer were variable, with A.BY and BALB.B showing responses better than those of C57BL/6 and C57BL/10 strains. The antibody responses of the F₁ progeny of (responder × nonresponder) strains of mice to this polymer are generally lower than the responder parents. F₁ mice with C57BL/10 background were the poorest responders. Studies with F₂ mice and backcross progenies of selective breeding of high and low antibody responder (C57BL/6 × BALB/c) F₁ to high responder C57BL/6 mice indicated that both non-H-2 genes and H-2 gene dosage effects influenced the magnitude of the humoral antibody responses. Animals having low responder non-H-2 background and only half the dosage of the responder immune response genes has greatly diminished antibody responses.     

Natural resistance of irradiated 129-strain mice to bone marrow allografts: Genetic control by theH-2K region

A major genetic determinant of natural resistance to bone marrow allografts, designated asHh-3, was mapped to theH-2K region. This gene may code for or regulate the expression of cell surface structures selectively expressed on donor hemopoietic cells and recognized by naturally occurring cytotoxic effectors. Resistance was observed as failure of donor cell growth in the spleen of irradiated 129-strain (H-2 ^bc ) recipients of H-2^k bone marrow cells. The mapping was accomplished by substituting donor cells bearingk alleles throughout theH-2 complex with cells of recombinant mouse lines bearingk alleles at definedH-2 regions. The host antigraft reaction underlying resistance was abrogated by pretreating 129-strain mice with either rabbit antimouse lymphocyte serum or the antimacrophage agent silica. Grafting of H-2K^k cells into mice ancestrally unrelated to 129 but sharing theH-2 ^bc or the similarH-2 ^b haplotype, and intoH-2 ^b/k ,H-2 ^k/bc , andH-2 ^k/d F₁ hybrids revealed that resistance was unique to 129 mice, since mice of the other strains, including F₁ hybrids, were susceptible to the grafts. Thus,Hh-3 incompatibility was a necessary but insufficient condition for the manifestation of allogeneic resistance; other genetic factors not associated withH-2 conferred responder status to 129-strain mice and nonresponder status to D1.LP, B10.129(6M), B10, B6, and possibly to F₁ hybrid mice. The possible relationships between allogeneic resistance to H-2^k marrow grafts, hybrid resistance to H-2^k lymphomas, and F₁ hybrid antiparental H-2^k cytotoxicity induced in vitro are discussed.     

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.     

H-2 class I antigen expression on mouse teratocarcinoma cell lines

Immunity against PCC3 teratocarcinoma cells (129, H-2 ^b) was induced in allogeneic (C3H, H-2 ^k) mice by preimmunization with L cells (C3H, H-2 ^k) expressing cosmid-introduced K ^b or D ^b genes, but not with nontransfected L cells. In addition, the growth of PCC3 cells in sublethally irradiated (C3H × B6-H-2 ^bm1)F₁ and (C3H × B6-H-2 ^bm13 )F₁ mice bearing the K ^bm1 and D ^bm13 mutations, respectively, was either prevented, stopped, or delayed in comparison with the (C3H × B6)F₁ (k × b) mice, which failed to reject the PCC3 cells. The teratocarcinoma line OC15S was exceptional because it reacted specifically with K^b- and D^b-specific (but not I^b-specific) alloantisera, and because K^b- and D^b-specific antibodies could be absorbed by OC15S cells. The subpopulation of OC15S cells bearing the ECMA-7 antigen characteristic for embryonic carcinoma (EC) cells was isolated by the fluorescence-activated cell sorter and was shown to react specifically with K^b- and D^b-specific antisera. These experiments show that teratocarcinoma cells express antigens similar or identical to the K-and D-region products of differentiated cells. The lack of expression of class I antigens is thus neither a condition nor a consequence of the pluripotentiality of the EC cells. The exact nature of the major histocompatibility complex antigens on EC cells has yet to be established using the methods of molecular biology and biochemistry.     

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     

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.     

Bone-marrow-cell grafts involving theH-2D andH-2L mutant haplotypes

TwoH-2 ^d mutants,H-2 ^dm2 (H-2L loss mutation) andH-2dm1 (gainplus-loss mutation involving bothH-2L andH-2D) were evaluated for any change in the immunogenicity of marrow stem cells. Grafts of 2 or 4 × 10⁶ BALB/c(C) or BALB/c-H-2^dm2 (C-H-2 ^dm 2) marrow cells were accepted by lethally irradiated B10.D2(H-2 ^d ) recipients and were rejected by irradiated B10(H-2 ^b ) recipients. Moreover, both (B6 × C)F₁ and (B6 × C-H-2 ^dm 2)F₁ mice, as irradiated recipients, resisted the growth of parental-strain B6(H-2 ^b ) marrow cells but accepted grafts from C or C-H-2 ^dm 2 parental-strain donors. Thus, theH-2 mutation involvingH-2L but notH-2D did not affect the expression ofH-2 ^d -associated Hemopoietic or Hybrid(Hh) antigens of marrow stem cells. Grafts of 2 to 8 × 10⁶ B10.D2 or B10.D2-H-2 ^dm 1 marrow cells were rejected by B10.BR(H-2 ^k ) and B6 hosts and were accepted by B10.D2 hosts. However, B10.D2-H-2 ^dm 1 marrow cells grew to a much greater extent than B10.D2 cells in irradiated (B6 × B10.D2)F₁ or (B6 × B10.D2-H-2 ^dm 1)F₁ host mice. Therefore, theH-2 ^dm 1 mutation has altered the expression of Hh antigens at least quantitatively, resulting in a relative loss of hybrid resistance with the retention of Hh determinants recognized by allogeneic recipient mice which are notH-2 ^d . Since the Hh determinants of B10.D2 marrow cells have been mapped 16 cM to the right ofH-2, this mutation atH-2D/H-2L may have affected a regulatory gene.     

Mechanisms of Allografted Tumor Rejection: The Roles of T Cells in Allograft Rejection Mediated by a Type of Bone Marrow-Derived Macrophage

Allografted tumor rejection does not occur in the absence of T cells, but the main effector cells responsible for the rejection are allograft-induced macrophages (AIM). We examined the roles of T cells in the AIM-mediated rejection of Meth A (H-2) tumor cells from C57BL/6 (H-2^b) mice. Irradiation of C57BL/6 mice abrogated both the induction of AIM and the allograft rejection. Reconstitution of the irradiated mice with F1 (C57BL/6 X C3H/He: H-2^b/k) bone marrow cells led to the appearance of H-2^b/k haplo-type of AIM exclusively in the rejection site and to allograft rejection, indicating that radiosensitive cells prerequisite for both the induction of AIM and allograft rejection were bone marrow-derived cells, and that the progenitors of AIM existed in the bone marrow cells to be activated into AIM in the rejection site. To understand the role of T cells in the induction of AIM, we used adult-thymectomized, X-irradiated C57BL/6 mice reconstituted with F1 bone marrow (ATXBM). The ATXBM mice could neither induce AIM nor reject allogeneic Meth A cells, whereas adoptive transfer of F1 lymph node T cells to the ATXBM mice restored not only the induction of AIM but also rejection of the allograft. Among the lymph node T cells, CD4⁺, but not CD8⁺, cells were found to be essential for the activation of AIM progenitors to AIM; and CD8⁺ T cells were further required for rejection, at least in part, to enhance the number of AIM in the rejection site.     

Evidence for differentiation of NK1+ cells into cytotoxic T cells during acute rejection of allogeneic bone marrow grafts

The ability of lethally irradiated C57BL/6 mice to acutely reject H-2^d bone marrow is due to a lymphocyte population that is NK1⁺, ASGM1⁺, CD4^–, CD8^–, CD3⁺. Transfer of spleen cells from C57BL/6 mice expressing these antigens into nonresponder 129 mice adoptively transfers the ability to reject H-2^d marrow grafts. The specificity of this rejection maps to the H-2D major histocompatibility complex (MHC) region. Transplantation of high doses of H-2^d marrow into C57BL/6 overrides the acute rejection mechanism leading to graft survival. During growth of the graft, a cytolytic activity develops that is due to ASGM1⁺, CD8⁺ cytolytic T lymphocytes (CTLs) with H-2L^d specificity. The possibility that the ASGM1⁺, CD8⁺ CTLs are descendents of the CD3⁺, NK1⁺, ASGM1⁺, CD8^– cells responsible for acute rejection is investigated by adoptive cell transfer experiments. We show that beige mice that lack NK1⁺ cells as well as the ability to acutely reject H-2^d marrow fail to generate specific CTLs after transplantation with a high dose of H-2^d marrow. Transfer of highly purified NK1⁺ cells from B6.PL-Ly-2 ^a /Ly-3 ^a (Lyt-2.1) into beige mice together with H-2^d marrow leads to generation of Lyt-2.1 CTLs from donor NK1⁺ cells. These results show that specific CTLs are generated from NK1⁺ cells during acute marrow graft rejection. Offprint requests to: G. Dennert.     

The genetic control of natural killer cell activity and its association with in vivo resistance against a moloney lymphoma isograft

Spleens of normal young mice of certain strains contain lymphocytes that can kill strain A-derived YAC-1 lymphoma cells in a⁵¹Cr release cytotoxic assay in vitro. We have previously classified mouse genotypes as high or low reactors, according to their responses in this test. In vivo resistance to small numbers of YAC ascites lymphoma cells is correlated with in vitro cytolytic activity. In vitro and in vivo tests were carried out on the same individual (A x C57BL)F₁ x A backcross mice. Natural in vitro killer cell activity appeared to be under polygenic control, including a strong H-2-linked factor. No linkage was found with five different isozyme loci, with theIg-l locus or with C5 serum activity. Also in vivo resistance showed strong linkage with theH-2 complex. In (A x CBA)F₁ x A backcross mice, a weak linkage was found with the coat color locusC. There was a correlation between in vitro killer activity and in vivo resistance in the same backcross mice. In vivo resistance was particularly strong in mice that combined theH-2 ^b -linked resistance factor with a high cytolytic activity in vitro.     

H-2 antigen expression: Loss in vitro,restoration in vivo,and correlation with cell-mediated cytotoxicity in a mouse lymphoma cell line

The susceptibility to cell-mediated cytolysis of cells of the recently developed C57BL/Ka(H-2 ^b ) lymphoma cell line, BL/VL₃, was investigated in allogeneic assays with thymus-dependent lymphocytes (T cells). Compared to EL4, the widely used C57BL/6(H-2 ^b ) lymphoma cell line, BL/VL₃ cells were found to be insensitive to T-cell-mediated lysis as detected by the use of⁵¹Crrelease methods. When used as immunogens in alloreactive combinations with BALB/c(H-2 ^d ) splenocytes as responder cells, BL/VL₃ cells failed to elicit sensitization. Serological tests showed that this cell line had profoundly reduced levels of H-2^b antigens on its surface. When BL/VL₃ cells were reinjected into C57BL/Ka and BALB/c mice, full recovery of H-2^b antigen expression at the cell surface was observed in both syngeneic and allogeneic hosts after only 11 days of in vivo growth. Concomitantly, they acquired the ability to induce cytotoxic responses in allogeneic T cells and became susceptible to their lytic activity. The expression of H-2 antigens on the surface of BL/VL₃ cells is a reversibly modulated function that depends on in vivo growth conditions and is lost in vitro in the absence of immunoselective pressure.     

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.     

Experimental allergic orchitis in mice

Inbred strains of mice were studied for their susceptibility to the induction of experimental allergic orchitis after sensitization with mouse testicular homogenate in complete Freund's adjuvant accompanied by injections of extract from Bordetella pertussis. Susceptibility to autoimmune orchitis was found to be linked to the major histocompatibility complex in BALB/c and C57BL/10 mice and mapped to genes encoded within the H-2D ^dregion. In five of six groups of bidirectional (susceptible × resistant) F₁ hybrids, H-2D ^d-linked susceptibility was inherited as a dominant autosomal trait. However, in (BALB/cByJ × DBA/2J)F₁ and (DBA/2J × BALB/cByJ)F₁ hybrids, dominant autosomal resistance to the induction of autoimmune orchitis was observed. Backcross analysis between the resistant F₁ hybrid and the susceptible BALB/cByJ parent suggests that a single independently segregating DBA/2J locus is capable of negating H-2D ^d-linked susceptibility, and controls resistance to the induction of autoimmune orchitis.Abbreviations used in this paper BP extract Bordetella pertussis extract - CFA complete Freund's adjuvant - EAO experimental allergic orchitis - Ir immune response - MHC major histocompatibility complex - MLH mouse liver homogenate - MTH mouse testis homogenate - PI pathology index     

B-Cell responses to male-specific antigen(s) in mice

It has been found that B-cell responses to male-specific antigen(s) can be clearly demonstrated by reversed plaque assays. Female mice injected with syngeneic male spleen cells showed significant increases (greater than 100 × in some strains) in the number of immunoglobulin-secreting cells in lymph nodes draining the injection site. There was a variation in B-cell responsiveness between strains and this correlated only partially with previously reported T-cell responsiveness to the H-Y antigen. C57BL (H-2 ^b ) mice were among the most responsive, while CBA (H-2 ^k ), (CBA × C57BL)F₁, and BALB/c (H-2 ^d ) were all much less responsive. These results apparently open up a new approach to the investigation of B-cell responses to male-specific antigen(s).     

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.     

Immune response to the H-X antigen on P815-X2

In a preceding report, the detection of an H-2-linked immune response to the H-X ^d antigen on the P815-X2 mastocytoma was demonstrated by the significantly increased survival of (C57BL/6 × DBA/2)F₁ (B6D2F1) male hybrids (H-X ^b ) compared with female siblings (H-X ^{b/H-X d} ) after injection with the histocompatible tumor (H-X ^d ). This interpretation was supported by the absence of this sex effect in reciprocal D2B6F1 hybrids (H-X ^d and H-X ^{d/H-X b} ). Additional findings presented in this paper support the conclusion that this sex effect is due to a true immunological response to H-X ^d : (a) Reciprocal (DBA/2 × C57BL/6 H-2 mutant)F₁ hybrids, as well as D2B6F1, failed to exhibit the sex effect: (b) the demonstration of the sex effect in (BALB/c × DBA/2)F₁ and (BALB/c-H-2 ^dm2 × DBA/2)F₁ hybrids and in (C57BL/10 × DBA/2)F₁ hybrids was consistent with the known H-X incompatibilities between the strains BALB/c and DBA/2 and C57BL/10 and DBA/2, respectively, previously demonstrated by skin grafting; and (c) the sex effect was not abrogated by castration of male B6D2F1 hybrids. Variability in the presence or absence of the sex effect was observed in various [recombinant inbred (RI) × DBA/2]F₁ hybrids and may be attributed to the influence of a regulatory non-H-2 gene which is closely linked to the gene coding for mouse kidney-androgen-regulated protein (KAP) but androgen-independent, or to variability in inheritance of the H-X ^b allele among the RI lines. It is proposed that the P815-X2 model may be utilized to type RI lines derived from a cross between C57BL/6 and DBA/2 for their H-X genotypes.Abbreviations B C57BL/6 origin allele - B6 C57BL/6 - B10 C57BL/10 - B6D2F1 (C57BL/6 × DBA/2)F₁ - B6 ^m D2F1 (C57BL/6 H-2 mutant × DBA/2)F₁ - bm10 B6.C-H-2 ^bm10 - C BALB/c - D DBA/2 origin allele - D2 DBA/2 - dm2 BALB/c-H-2 ^dm2 - H-X X chromosome-determined histocompatibility antigen of the mouse - Ir gene, immune response gene - KAP kidney androgenregulated protein - MST median survival time - RI recombinant inbred - SDP strain distribution pattern     

Susceptibility to a mouse acquired immunodeficiency syndrome is influenced by theH-2

The development of a mouse acquired immunodeficiency syndrome (MAIDS) induced following LP-BM5 MuLV infection depends on host genetic factors. Susceptible mice, such as C57BL/6J mice, develop a profound impairment of lymphoproliferative response to mitogens and hyperplasia of lymphoid organs and succumb to infection within 6 months. These changes do not occur in resistant mice, such as A/J mice. Resistance to MAIDS is a dominant trait since (C57BL/6JxA/J)F₁ hybrid mice did not develop any immune dysfunctions following infection. Genetic regulation of the trait of resistance/susceptibility to MAIDS was determined in AXB/BXA recombinant inbred (RI) mouse strains (derived from resistant A/J and susceptible C57BL/6J progenitors). Two different criteria were used to determine their resistance or susceptibility to developing MAIDS: the gross pathologic evaluation of lymphoid organs at 13–15 weeks of infection, and survival. RI mouse strains segregated into two non-overlapping groups. The first group did not develop any significant pathology, and these mouse strains were considered as resistant to MAIDS. The second group showed the virus-induced pathological changes as well as an immunological dysfunction as seen in C57BL/6J progenitor mice, and these strains were thus considered as susceptible to MAIDS. This bimodal strain distribution pattern of resistance/susceptibility to MAIDS among the RI strains suggests that this phenotype is controlled by a single gene. Linkage analysis with other allelic markers showed a strong association between resistance/susceptibility to MAIDS and theH-2 complex. Possession of theH-2 ^b haplotype derived from C57BL/6J mice was associated with susceptibility to MAIDS, while theH-2 ^a haplotype conferred resistance to the disease. This finding was confirmed by demonstrating thatH-2 ^a congenics on the susceptible C57BL/10 background were as resistant to MAIDS as A/J mice which donated theH-2 ^a locus. Gene(s) within theH-2 complex thus represent the major regulatory mechanism of resistance/susceptibility to MAIDS.     

Genetic studies of murine catalase: Regulation of multiple molecular forms of kidney catalase

Starch gel electrophoresis of kidney catalase in inbred strains C3H and C57BL/6, their F₁ hybrid, and first and second backcross generations demonstrated that single-component (type A) v. multiple-component (type B) electrophoretic patterns are controlled by a single locus. The type A electrophoretic pattern is dominant. Twenty-five inbred strains of mice were classified according to their kidney catalase electrophoretic pattern. The data indicate that the segregating genetic factor determines a specific substance in the type A kidney which affects the electrophoretic mobility of catalase. A comparison of the F₁ hybrid enzyme with a 1:1 mixture of C3H and C57BL/6 enzyme showed that the alteration of electrophoretic mobility is the result of posttranslational modification of the catalase molecule. An association of kidney catalase electrophoretic pattern and the H-2 ^k haplotype indicates that the locus controlling the electrophoretic pattern is most likely located on chromosome 17 in close proximity to the H-2 complex.