Isolation of virus-like (VL30) elements from theQ10 andD regions of the major histocompatibility complex

Previous studies from our laboratory have described two endogenous provirus-like sequences in a series of cosmids spanning theTL region of the major histocompatibility complex (MHC) of normal C57BL/10 mice. At least one of these viruses shares similarities withVL30 elements. To determine if additionalVL30-like retroviral elements are integrated in the MHC, we constructed a cosmid library using DNA from a radiation leukemia virus (RadLV)-transformed cell line derived from C57BL/6 mice. The library was first screened using theH-2III (5) probe, which detects Class I genes of theH-2 complex. In the primary screening 163H-2III positives were isolated. TheH-2III-positive isolates were then hybridized with an AKR-derived virus probe,EcoB/S, which contains sequences from both thepol and theenv genes of the virus. Nine virus-positive isolates were detected. Localization of these cosmid isolates containing viral sequences within theH-2 complex was done utilizing low-copy probes and confirmed using previously mapped cosmid isolates from other laboratories. We report here the isolation and characterization ofVL30-like elements from theQa andD regions of theMHC of several inbred mouse strains.     

Immune response of mice to Thy-1.1 antigen: Studies on congenic lines

The primary response to Thy-1.1 antigen was measured by a plaque assay that detected cells producing antibodies lytic for AKR thymocytes (PFC). TheH-2 congenic mice (B10.K and B10.BR) carryingH-2 complexes of high responders (CBA and C57BR) on the low-responder background (B10) were found to produce significantly fewer PFC than the corresponding donor of theH-2 complex. On the other hand, C3H.B10 mice carrying theH-2 complex of a low responder on the high-responder background produced significantly more PFC than the donor of theH-2 complex. These findings were interpreted as evidence that alleles at previously described loci believed to be components of theI region of theH-2 complex and controlling immune response to Thy-1.1 are influenced by alleles at another locus. Studies of segregating populations of theH-2 congenic lines supplied evidence that this locus, tentatively calledIr-5, is in chromosome 17 (linkage group IX).     

Immune response to calf collagen type I in mice: A combined control ofIr-1A and nonH-2 linked genes

The genetically controlled immune response to calf skin collagen type I in mice could be demonstrated to be governed by at least two genes. One is linked to theH-2 complex and located within theIA subregion. High-responder alleles areH-2 ^b ,H-2 ^f , andH-2 ^s . The other gene(s) is not linked to theH-2 complex and high-responder allele(s) are found in the genome of B10 mice but not in the genome of DBA mice. There are strong indications that theIr-1A gene controls the response at the T-cell level, whereas it is assumed that the background gene(s) control the immune response at a different level.     

Variable effect of anH-21 barrier on response to skin allografts in the mouse

(AQR×B10)F₁ mice were grafted with skin from donors differing in theK, I, KI, andISD regions of theH-2 complex. A dichotomy was observed in the fate of theH-2I-disparate grafts: either they were rejected acutely within the second week or were accepted indefinitely. Acceptances were much more common among male than female hosts. Acceptor status was limited to the I group, was unpredictable in occurrence, was not well-correlated with positive serum anti-Ia titers, and did not confer protection of grafts that were alike atH-2I but different atH-2K orH-2D. Since theH-2I barrier studied here elicited such divergent responses in genetically identical hosts, it is unlikely that any histocompatibility typing test could predict graft fate.Abbreviations used in this paper are MST median survival time - MHC major histocompatibility complex - CTL cytotoxic T lymphocyte - B10 C57 BL/10 - 6R BIO.T(6R) - B10.A BIO. ASn - H-2-Ia serologically detected antigens coded in theI region ofH-2 This term is used in preference toIa, since it has recently been shown that Ia-like alloantigens may be coded outside the MHC (Dickleret al. 1975).     

The histocompatibility-2 system in wild mice

The I-region gene products of 29 wild-derivedH-2 haplotypes on a B10 background (B10.W congenic lines) were typed with alloantisera which detect 17 inbred I-region antigens. Five new I-region antigens were defined by expanding the inbred line panel ofH-2 haplotypes to includeH-2 ^u , H-2^v, andH-2 ^j . Based on serological analyses of the inbred and B10.W lines, the polymorphism of theIA gene (or genes) is estimated to be at a minimum of 15 alleles and theIE gene (or genes) at a minimum of 4 alleles. These results indicate that theIA subregion is more polymorphic than theIE subregion. By combining the I-region typing data with theH-2K andH-2D region typing data reported previously, a total of 11 new natural recombinants of inbredH-2 alleles were detected among the B10.W lines.     

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.     

The role ofH-2 regions in overcoming tissue incompatibility

Neonatal transplantation tolerance to the products of theH-2 ^b complex was induced in B10.A (H-2 ^a ) mice. On the basis of the survival of skin allografts it was found that antigens determined by theD region of theH-2 ^b complex (of the B10.A(2R) strain) were most easily overcome and that tolerance to the products of theD end of theH-2 complex (of the B10.A(4R) strain) was also easy to induce. The antigens produced by theK end ofH-2 (of the B10.A(5R) and B10.A(3R) strains) represented a stronger incompatibility barrier and a difference in the entireH-2 ^b complex caused strongest resistance to tolerance induction. When tolerance to the products of the entireH-2 ^b complex was induced in newborn B10.A mice, and the neonatally treated animals were grafted simultaneously with five different grafts, those disparate at theK end ofH-2 and in the entireH-2 region were rejected in some animals, while the grafts disparate at theD end of H-2 remained intact in the same mice. No dependence on theI-J subregion was observed in this system. Furthermore, tolerance was more easily inducible in male than in female B10.A mice.     

Nonimmune thyroid destruction results from transgenic overexpression of an allogeneic major histocompatibility complex class I protein.

The overexpression of major histocompatibility complex (MHC) class I molecules in endocrine epithelial cells is an early feature of autoimmune thyroid disease and insulin-dependent diabetes mellitus, which may reflect a cellular response, e.g., to viruses or toxins. Evidence from a transgenic model in pancreatic beta cells suggests that MHC class I overexpression could play an independent role in endocrine cell destruction. We demonstrate in this study that the transgenic overexpression of an allogeneic MHC class I protein (H-2Kb) linked to the rat thyroglobulin promoter, in H-2Kk mice homozygous for the transgene, leads to thyrocyte atrophy, hypothyroidism, growth retardation, and death. Thyrocyte atrophy occurred in the absence of lymphocytic infiltration. Tolerance to allogeneic class I was revealed by the reduced ability of primed lymphocytes from transgenic mice to lyse H-2Kb target cells in vitro. This nonimmune form of thyrocyte destruction and hypothyroidism recapitulates the beta-cell destruction and diabetes that results from transgenic overexpression of MHC class I molecules in pancreatic beta cells. Thus, we conclude that overexpression of MHC class I molecules may be a general mechanism that directly impairs endocrine epithelial cell viability.     

Regulation of expression of mouseC4 andSlp genes by non-H-2-linked genes

C4 (the fourth complement component) and Slp (sexlimited protein) are two homologous plasma proteins encoded by genes in theS-region of theH-2 gene complex. We studied the genetic factors influencing the plasma levels of these proteins and their mRNA levels in liver. Considerable differences in both protein and mRNA levels were found between mouse strains carrying the sameS-region allele on different genetic backgrounds, indicating a pretranslational effect of non-H-2-linked genes on the expression of the twoS-region genes. The expression of Slp is androgen-dependent in the strains tested. However, testosterone treatment cannot increase the low levels of Slp caused by non-H-2-linked regulatory genes. In mice with Slp-negativeS-region alleles we found liver mRNA hybridizing with Slp-specific oligonucleotides, indicating expression of theSlp gene in Slp-negative strains. Our data demonstrate the complexity of the regulation of theC4 andSlp genes and pave the way for the analysis of the regulatory factors involved.     

Functional expression of a heterologous major histocompatibility complex class I gene in transgenic mice.

The regulated expression of major histocompatibility complex class I antigens is essential for assuring proper cellular immune responses. To study H-2 class I gene regulation, we have transferred a foreign class I gene to inbred mice and have previously shown that the heterologous class I gene was expressed in a tissue-dependent manner. In this report, we demonstrate that these mice expressed the transgenic class I molecule on the cell surface without any alteration in the level of endogenous H-2 class I antigens. Skin grafts from transgenic mice were rapidly rejected by mice of the background strain, indicating that the transgenic antigen was expressed in an immunologically functional form. As with endogenous H-2 class I genes, the class I transgene was inducible by interferon treatment and suppressible by human adenovirus 12 transformation. Linkage analysis indicated that the transgene was not closely linked to endogenous class I loci, suggesting that trans-regulation of class I genes can occur for class I genes located outside the major histocompatibility complex.     

H-2D end confers dominant protection from IL-10-mediated acceleration of autoimmune diabetes in the nonobese diabetic mouse.

BALB/c mice that express IL-10 as a transgene in their pancreatic beta cells (Ins-IL-10 mice) do not develop diabetes, even after crossing to nonobese diabetic (NOD) mice ((Ins-IL-10 x NOD)F(1) mice). However, backcross of F(1) mice to NOD mice (NOD.Ins-IL-10 mice) results in N2 and N3 generations that develop accelerated diabetes. In this study, we found that NOD.Ins-IL-10 mice that expressed BALB/c-derived MHC molecules (NOD.Ins-IL-10(H-2(g7/d)) mice) were protected from diabetes. This protection associated with peri-islet infiltration and preserved beta cell function. Moreover, expression of I-A(d) and I-E(d) MHC class II molecules of BALB/c origin was not responsible for protection, but NOD.Ins-IL-10 mice that expressed BALB/c MHC class I D(d) molecules (NOD.Ins-IL-10(H-2(g7/d)) mice) did not develop diabetes. To directly test the possibility of a protective role of H-2D(d) in the development of accelerated diabetes, we generated transgenic mice expressing D(d) under the control of the MHC class I promoter. We found that double transgenic NOD.Ins-IL-10-D(d) mice developed accelerated diabetes in a fashion similar to NOD.Ins-IL-10 mice that were D(d) negative. Microsatellite analysis of H-2D(d)-linked loci confirmed association between BALB/c-derived alleles and protection of NOD.Ins-IL-10(H-2(g7/d)) mice. These results suggest a control of H-2D(d)-linked gene(s) on IL-10-mediated acceleration of autoimmune diabetes and dominant protection of the D(d) region in NOD.Ins-IL-10 mice.     

The expression ofI-region gene products on lymphocytes

Mixed lymphocyte reaction (MLR) stimulation by purified T and B lymphocytes and thymocytes was studied. The MLR gene products involved were localized to theH-2 complex by the use of congenic mice differing atH-2, and to loci within theH-2 complex through the use of congenic mice bearing recombinant chromosome 17. Stimulation by T cells was investigated in detail. The role of small amounts of contaminating B lymphocytes, and that of backstimulation, was found to be of minor importance. T cells and thymocytes stimulated as well as or better than B cells in combinations differing in theI, S, and possibly parts of theD end, thus suggesting that these genetic regions control cell-surface products expressed on both T and B lymphocyte populations.Abbreviations used in this paper are MLR mixed lymphocyte reaction - GVHR graft-versus-host reaction - CML cell-mediated lympholysis - Thy-1 the gene for the T-cell antigens, synonymous with - Thy-1.1 synonym for ^AKR - Thy-1.2 synonym for ^C3H - MHC major histocompatibility complex - Ir genes immune response genes linked to the MHC - LPS E. coli 055.35 lipopolysaccharide For the genetic nomenclature of theH-2 complex (H-2K, H-2D, I, S, D regions,Ia, etc.) see Kleinet al. 1974, and Shreffleret al. 1974.     

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.     

Histocompatibility-2 system in wild mice

Ninety-six wild mice trapped at 13 localities in the state of Texas were tested in the dye-exclusion cytotoxic test with a battery of 49 oligospecific H-2 antisera. The antisera detected 36 class I (K and D) and 10 class II (Ia) antigens. The phenotypic frequencies of private class I antigens ranged from 1 to 20%, the majority of them being in the range between 1 and 5%. At least some of the higher frequencies resulted from the presence of more than one antibody in the typing reagents, and from other factors complicating the typing. We estimate that the frequencies of most of the class I alleles among Texas wild mice are 1% or less. This estimate leads to the prediction that at least 200 alleles exist in Texas mice at theH-2K locus, and another 200 alleles exist at theH-2D locus. Frequencies of most of the class I public antigens were in excess of 20%. In the sample of 96 mice, 46 different phenotypic combinations of private class I antigens were found, and the frequency of blanks (mice unreactive with any of the antibodies to private class I antigens) was 27%. The frequencies of private class II antigens ranged from 5 to 15%. Some of the public class II antigens, in particular those controlled by theE region, occurred with frequencies of 80% or higher. The class II antigens were found in 26 phenotypic combinations. No striking linkage disequilibrium was found either between K and D antigens, or between class I and class II antigens. The polymorphism of theK, A, andD region appears to be higher than that of the corresponding regions of the human or rat major histocompatibility complex. The polymorphism of theE region is significantly lower than that of theA, K, andD regions. The polymorphism of theA region is extensive.     

High-resolution one-dimensional isoelectric focusing of mouse MHC class I antigens

A method is described for a biochemical comparison of mouse class I antigens utilizing antisera with a monomorphic pattern of reaction and high-resolution one-dimensional isoelectric focusing (1D-IEF). The most commonly occurring and studied H-2K and D alleles were identified in a comparison of over 40 mouse strains. By comparing H-2 mutant mouse strains, cell lines transfected with defined class I genes, or mice transgenic for a mouse class I gene and H-2 recombinant mouse strains, unambiguous identification of class I alleles was possible. The complex pattern presented by H-2-heterozygous mice was readily resolved into the contribution by the individual parental alleles. The H-2 ^b bm series of mutants was analyzed, and for those mutants where a charge difference was predicted based on their known sequence, a change in isoelectric point (IEP) was indeed observed. Based on analysis by IEF, the bm8 mutant may contain (an) amino acid substitution(s) in addition to those reported. The present method further appears useful in elucidating defects in class I antigen synthesis and post-translational modifications, as these cannot be easily characterized when using surface staining with monoclonal antibodies (mAbs).     

MHC class I-Ly49 interactions shape the Ly49 repertoire on murine NK cells

This study aims to determine how the interaction of Ly49 receptors with MHC class I molecules shapes the development of the Ly49 repertoire. We have examined the percentage of NK cells that expressed Ly49A, Ly49G2, and Ly49D in single and double Ly49A/C-transgenic mice on four different MHC backgrounds, H-2(b), H-2(d), H-2(b/d), and beta(2)-microglobulin(-/-). The results show that the total numbers of NK cells were not different among the strains. The prior expression of a Ly49 receptor capable of binding to self MHC class I altered the percentage of NK cells expressing endogenous Ly49A, Ly49G2, and Ly49D even in mice in which no MHC ligand was present for the latter receptors. The NK cells in the Ly49-transgenic mice expressed the same level of endogenous Ly49 receptors as wild-type mice of a similar MHC background. In contrast, the number of NK T cells was reduced in mice in which the Ly49 transgene could bind to a MHC class I molecule. The onset of Ly49 receptor expression on NK cells during ontogeny was not altered in the presence of transgenic Ly49 receptors. These data support a sequential model and argue against a selection model for Ly49 repertoire development on NK cells.     

Responses against antigens encoded by theH-3 histocompatibility locus: Antigens stimulating class I MHC- and class II MHC-restricted T cells are encoded by separate genes

The purpose of this work was to study the genetic basis of histocompatibility antigens encoded by the mouse minor histocompatibility (H) locusH-3. Both class I major histocompatibility complex (MHC)-restricted cytotoxic T lymphocytes (CTL) and class II MHC-restricted helper T cells (TH) specific for antigens encoded by genes within theH-3 locus were isolated and analyzed. Typing a number of mouse strains for expression of antigens recognized by these TH and CTL suggested that there was a different strain distribution pattern of expression of the antigens recognized by TH compared with those recognized by CTL. Separation of the genes whose products stimulate TH from those whose products stimulate CTL was suggested by: (1) analysis of the strain B10.FS(92NX)/Grf that has undergone recombination within theH-3 region; (2) genetic segregation studies of (B10.UW-H-3 ^b/Sn×C57BL/10Sn)F₂ mice; and (3) F₁ complementation studies in which CTL specific for products of the TH-defined gene(s) could not be detected, even in the absence of immune responses to products of the CTL-defined genes. Taken together, these data suggest that in addition to two genes (B2m andCd-1) within theH-3 region whose products typically stimulate class I MHC-restricted CTL, there is at least one additional gene whose product selectively stimulates class II MHC-restricted TH. This new gene is located telomeric from the CTL-defined genes and between the lociwe andun on chromosome 2. These data demonstrate a novel degree of complexity of theH-3 “locus” and suggest selective presentation of minor H gene products in the context of class I or class II MHC proteins.     

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.     

Selective loss of mouse embryos due to the expression of transgenic major histocompatibility class I molecules early in embryogenesis

Among the numerous hypotheses proposed to explain the absence of fetal rejection by the mother in mammals, it has been suggested that regulation of expression of the polymorphic major histocompatibility complex (MHC) at the fetal-maternal interface plays a major role. In addition to a lack of MHC gene expression in the placenta throughout gestation, the absence of polymorphic MHC molecules on the early embryo, as well as their low level of expression after midgestation, could contribute to this important biologic phenomenon. In order to test this hypothesis, we have produced transgenic mice able to express polymorphic MHC class I molecules early in embryogenesis. We have placed the MHC class Ia gene H-2K^b under the control of a housekeeping gene promoter, the hydroxy-methyl-glutaryl coenzyme A reductase (HMG) gene minimal promoter. This construct has been tested for functionality after transfection into mouse fibroblast L cells. The analysis of three founder transgenic mice and their progeny suggested that fetoplacental units that could express the H-2K^b heavy chains are unable to survive in utero beyond midgestation. We have shown further that a much higher resorption rate, on days 11 to 13 of embryonic development, is observed among transgenic embryos developing from eggs microinjected at the one-cell stage with the pHMG-K^b construct than in control embryos. This lethality is not due to immune phenomena, since it is observed in histocompatible combinations between mother and fetus. These results are discussed in the context of what is currently known about the regulation of MHC expression at the fetal-maternal interface and in various transgenic mouse models. Mol. Reprod. Dev. 50:35–44, 1998. © 1998 Wiley-Liss, Inc.     

Expression of human HLA-B27 transgene alters susceptibility to murine Theiler's virus-induced demyelination

Infection of certain strains of mice with Theiler's murine encephalomyelitis virus results in persistence of virus and an immune-mediated primary demyelination in the central nervous system that resembles multiple sclerosis. Because susceptibility/resistance to demyelination in B10 congeneic mice maps strongly to class I MHC genes (D region) we tested whether expression of a human class I MHC gene (HLA-B27) would alter susceptibility to Theiler's murine encephalomyelitis virus-induced demyelination. Transgenic HLA-B27 mice were found to co-express human and endogenous mouse class I MHC genes by flow microfluorimetry analysis of PBL. In the absence of the human transgene, H-2stf, or v mice but not H-2b mice had chronic demyelination and persistence of virus at 45 days after infection. No difference in degree of demyelination, meningeal inflammation, or virus persistence was seen between transgenic HLA-B27 and nontransgenic littermate mice of H-2f or H-2v haplotype. In contrast, H-2s (HLA-B27+) mice showed a dramatic decrease in extent of demyelination and number of virus-Ag+ cells in the spinal cord compared with H-2s (HLA-B27-) littermate mice. In addition, none of the eight H-2s mice homozygous for HLA-B27 gene had spinal cord lesions even though infectious virus was isolated chronically from their central nervous system. Expression of HLA-B27 transgene did not interfere with the resistance to demyelination normally observed in B10 (H-2b) mice. These experiments demonstrate that expression of a human class I MHC gene can modulate a virus-induced demyelinating disease process in the mouse.