H-2-associated differences in androgen-influenced organ weights of a and C57BL/10 mouse strains and their crosses

The influence ofH-2 haplotypes (in three-month-old males) on body weight, vesicular gland, testes, and thymus weight was investigated in A, B10, and B10.A strains and their respective F₁, F₂, and Bc progeny. The influence of theH-2 haplotypes was found to contribute to heterosis in the body weight.H-2 ^a/H-2 ^a males have a smaller vesicular gland and larger testes and thymus weight thanH-2 ^b/H-2 ^b males when groups with an identical or comparable genetic background are compared.H-2 heterozygous classes are closer to the parental strain with higher values for absolute organ weight; for relative organ weight, the heterozygous classes are intermediate or closer to the parental strain with lower values. This complex situation results from the simultaneous action ofH-2 haplotypes on both organ weight (Hom-1 effect) and body weight (heterosis), which probably operate through different mechanisms. Coat color genes were found to modify the penetrance ofH-2 influence on quantitative traits.     

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

In previous studies on the emergence of H-2 antigen loss variants from an H-2^b/H-2^d heterozygous mouse leukemia cell line, it has been shown that stable variants could be obtained after a single-step selection procedure with antibody and complement. Selection against the K-end alleles revealed an asymmetry in the types of variant obtained. This paper deals with the results of selection against theD-end alleles. Once again, an asymmetry is noticed. Selection against the H-2D^d gene product results in the isolation of stable variants that have lost H-2D^d, either alone or in combination with the linked H-2K^d antigens. Selection against H-2D^b, on the other hand, has not, so far, resulted in the isolation of any stable variants. These experiments have not demonstrated unequivocally the mechanism by which these H-2 antigen loss variants are generated. However, certain preliminary considerations suggest the possibility that these variants may not, in fact, be true genetic mutants. The alternative -that these variants arose through some nongenetic, but stable mechanism — must be considered seriously.     

Involvement of <Emphasis Type="Italic">H</Emphasis>-2 Locus in a Multigenically-determined Immune Response

IT has been known for a number of years that specific immune responses can be under genetic control. In some cases the immunological phenotype is controlled by a single Mendelian genetic factor^1–3, while in other cases a more complex mode of inheritance determines the animal's ability to mount a specific immune response^4–7. An intriguing feature of this line of investigation is that in many cases a gene controlling a specific immune response is genetically linked to a histocompatibility locus^3,8–13. We now report that a specific immune response which has been shown to be under complex genetic control⁷ can be explained by the segregation of two genetic loci, one of which is closely linked or identical to the H-2 locus.     

A new cytotoxic lymphocyte-defined antigen coded by a gene closely linked to theH-3 locus

F₁ complementation results indicate that a new gene, putatively controlling a minor histocompatibility antigen, is closely linked to the minor histocompatibility gene,H-3, in the fifth linkage group of chromosome 2 of the mouse. This gene controls a product that was capable of inducing as well as acting as a target for cytotoxic lymphocytes (CTL). The lytic activity of CTL developed in B10.LP-H-3^b mice specific for the product of the new gene of B10 was restricted to target cells possessing H-2D^b antigens. This contrasts to the H-2K^b-restricted activity of H-3.1 specific CTL.     

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.     

Sex and H-2 haplotype control the resistance of CBA-BALB hybrids to the induction of T cell lymphoma by Moloney leukemia virus

CBA/N and CBA/CaHN have a significantly longer latent period than other inbred mouse strains between infection with Moloney murine leukemia virus and the appearance of T cell lymphoma. The genetic characteristics of this resistance have been analyzed in the F1 hybrids of CBA/N and CBA/CaHN with BALB H-2 congenic strains. Sexual phenotype and H-2 haplotype significantly influenced survival in the F1 hybrids of CBA/CaHN with BALB. In the F1 with BALB/cJ and BALB/cAnN (both H-2d), the males survived significantly longer than the females; but in the F1 with BALB.K (H-2k) and BALB.B (H-2b), the survival of males and females was the same. Survival was not prolonged by the recessive X-linked immunodeficiency gene xid or other genes on the CBA/N X-chromosome, because the (CBA/N X BALB/c)F1 male and the reciprocal (BALB/c X CBA/N)F1 male, which does not carry the CBA X-chromosome, were equally resistant. H-2 haplotype did not influence survival among the BALB H-2 congenics, and sex had little effect on the resistance of the CBA and BALB parents. These results demonstrate that a sex-dependent gene linked to H-2 significantly influences the expression of CBA genes for lymphoma resistance in the F1 hybrid with BALB.     

Linkage of the preimplantation-embryo-development (Ped) gene to the mouse major histocompatibility complex (MHC)

The preimplantation-embryo-development (Ped) gene influences the rate of cleavage division of preimplantation mouse embryos. The location of the Ped gene in the mouse major histocompatibility complex (MHC), the H-2 complex, has been inferred from the analysis of cleavage rates of embryos from mouse strains congenic at the H-2 complex. In this paper, formal genetic linkage studies were undertaken to evaluate linkage of the Ped gene to the H-2 complex. Co-segregation of Ped gene phenotype and H-2 haplotype was found in back-cross embryos. These data support the hypothesis that the Ped gene is linked to the H-2 complex.     

H-2 influences phenytoin binding and inhibition of prostaglandin synthesis

We have reported that susceptibility to glucocorticoid- and phenytoin-induced cleft palate and glucocorticoid receptor levels in mice are influenced by the H-2 histocompatibility complex on chromosome 17. Phenytoin competes with glucocorticoids for the glucocorticoid receptor and inhibits production of prostaglandins and thromboxanes. In this paper we have investigated whether, as in the case of glucocorticoids, phenytoin receptor levels and phenytoin-induced inhibition of prostaglandins are influenced by H-2 in a variety of mouse tissues. Using congenic strains varying only in the H-2 region, but otherwise having either the A/Wy(A) or B10(B) genetic background, we demonstrate here that phenytoin receptor content in the lung and liver is significantly higher in the strains with H-2 ^a (A/Wy and B 10.A) than in their corresponding H-2 ^b partners (A.BY and B 10). The H-2 complex also influences phenytoin-induced inhibition of the release of ³H-arachidonic acid and prostaglandin biosynthesis from thymocytes, prelabeled with ³H-arachidonic acid. Thus, these results suggest a similar genetic and biochemical pathway for the teratogenic action of both phenytoin and glucocorticoids.     

Variable spread of X inactivation affecting the expression of different epitopes of the Hya gene product in mouse B-cell clones

Cloned B-cell lines from a female T16H/XSxr mouse in which Tdy expression was suppressed due to X inactivation and from a male X/XSxr mouse, both of the (kxb)F₁ haplotype, were examined for H-Y expression. This was determined both by their ability to act as targets for H-2^k and H-2^b-restricted H-Y-specific cytotoxic T cells and by their ability to stimulate the proliferation of H-2K^k, H-2D^b (class I) and A^b (class II)-restricted T-cell clones. In B-cell clones from the T16H/XSxr mouse, expression of H-Y/D^b exhibited partial X inactivation and only a proportion ( 30%) of the cells were targets for or stimulated H-2D^b-restricted H-Y-specific T cells. In contrast, H-Y eiptopes restricted by H-2^k (H-Y/K^k, H-Y/D^k) and A^b (H-Y/A^b) exhibited no X inactivation. Furthermore, no inactivation of H-Y/D^b, H-Y/A^b, or H-Y^k was observed in the male X/XSxr mouse. These results indicate that the T16H/XSxr female is a mosaic, as a result of the variable spread of X inactivation into the Sxr region. They further suggest that the H-Y antigen recognized in association with H-2^k and H-2D^b class I molecules and A^b class II molecules may be the product of more than one gene.     

NK gene complex and chromosome 19 loci enhance MHC resistance to murine cytomegalovirus infection

An H-2^k MHC locus is critical for murine cytomegalovirus (MCMV) resistance in MA/My mice and virus control is abolished if H-2^k is replaced with H-2^b MHC genes from MCMV-susceptible C57L mice. Yet, H-2^k resistance varies with genetic background; thus, modifiers of virus resistance must exist. To identify non-MHC resistance loci, spleen and liver MCMV levels and genome-wide genotypes were assessed in (C57L × MA/My) and (MA/My × C57L) F₂ offspring (representing 550 meioses). Significantly, a non-Mendelian frequency of MHC genotypes was observed for offspring of the latter cross. Quantitative trait loci (QTL) and their interaction potential in MCMV resistance were assessed in R/qtl; QTL on chromosomes 17, 6, and 19 affected MCMV levels in infected animals. A chromosome 6 QTL was linked with the NK gene complex and acted in an additive fashion with an H-2^k MHC QTL to mitigate spleen MCMV levels. We provide biological confirmation that this chromosome 6 QTL provided MCMV control independent of H-2^k via NK cells. Importantly, both chromosome 6 and 19 QTLs contribute to virus control independent of H-2^k. Altogether, MHC and non-MHC MCMV-resistance QTL contribute in early resistance to MCMV infection in this genetic system.     

Genetics of life span in mice

Thymic involution that occurs earlier in some individuals than others may be the result of complex interactions between genetic factors and the environment. Such interactions may produce defects of thymus-dependent immune regulation associated with susceptibility to developing autoimmune diseases, malignancy, and an increased number of infections associated with aging.The major histocompatibility complex may be important in determining profiles of cause of death and length of life in mice. Genetic influences on life span involve interactions between loci and allelic interactions during life which may change following viral infections or exposure to other environmental factors. We have used different experimental protocols to study the influence of H-2 on life span and found that interactions between genetic regions, are inconsistent, particularly when comparing mice infected or not infected with Sendai virus.Genes important for life span need to be studied against many genetic backgrounds and under differing environmental conditions because of the complexity of the genetics of life span. Several genetic models were used to demonstrate that the MHC is a marker of life span in backcross and intercross male mice of the H-2^d and H-2^b genotypes in B10 congenic mice. Females lived longer than males in backcross and intercross mice, while males lived longer than females in B10 congenics. H-2^d was at a disadvantage for life span in backcross mice of the dilute brown and brown males exposed to Sendai infection, but intercross mice not exposed to Sendai virus of the same genotype were not at a disadvantage. H-2^d mice were not disadvantaged when compared to H-2^b in B10 congenics that had not been exposed to Sendai virus infection but the reverse was true when they were exposed. Overall, all our studies suggest that genetic influences in life span may involve interactions between loci and many allelic interactions in growing animals or humans. These genetic influences on life span may vary after they are exposed to infections or other environmental conditions. This paper emphasizes the need to use several genetic models, especially animals that have been monitored for infections, to study the genetics of life span.     

H-2 and non-H-2 interaction in expression of mutant histocompatibility geneH(KH-11)

H(KH-11) is a mouse mutant histocompatibility gene, the expression of which, as detected by skin graft rejection, requires the presence of a second gene in the graft donor which is associated with theH-2 ^b haplotype, but not withH-2 ^d. The mutant gene is not linked to theH-2 complex and may be carried and transmitted with or without expression, as predicted by classical Mendelian genetics.This research was supported by Grants CA 12662 and GM 18421 from the National Institutes of Health. We wish to express our gratitude to Dr. Ian McKenzie for performing the serological typing and to Ms. Geraldine Spencer and Mr. Ernest White for their faithful technical assistance.     

The Mouse H-2A Region Influences the Envelope Gene Structure of Tumor-Associated Murine Leukemia Viruses

C57BL/10 (B10) strains congenic at the mouse major histocompatibility locus (H-2) were injected with a modified ecotropic SL3-3 murine leukemia virus (MuLV) to determine the effect of the H-2 genes on the envelope gene structure of recombinant MuLVs. All tested strains rapidly developed T-cell lymphomas, and recombinant proviruses were detected in the tumor DNAs by Southern blot. The B10.D2 (H-2^d), B10.Br (H-2^k), B10.Q (H-2^q), and B10.RIII (H-2^r) strains exhibited a TI phenotype in which almost all tumors contained type I recombinants. These recombinants characteristically acquire envelope gene sequences from the endogenous polytropic viruses but retain the 5′ p15E (TM) gene sequences from the ecotropic virus. The parental B10 (H-2^b) strain, however, had a novel phenotype that was designated NS for nonselective. Only 30% of the B10 tumors had detectable type I recombinants, whereas a proportion of the others appeared to contain type II recombinants that lacked the type I-specific ecotropic p15E gene sequences. Studies of other B10 congenic strains with hybrid H-2 loci and selected F₁ animals revealed that the NS phenotype was regulated by a dominant gene(s) that mapped to the A region of H-2^b. These results demonstrate that a host gene within the major histocompatibility complex can influence the genetic evolution of pathogenic retroviruses in vivo.     

Expression of the H-Y Antigen on thymus cells and skin: Differential genetic control linked toK end ofH-2

The strength of the H-Y antigen on thymus cells and on skin was compared in differentH-2-congenic mouse strains using a host-versus-graft reaction popliteal lymph node assay, and skin grafts from males of parental strains grafted to F₁ hybrid females. The results revealed considerable differences in the strength of the H-Y antigen among different congenic strains; these differences demonstrate the effect of theH-2-linked gene on the expression of the H-Y antigen. The linkage withH-2 was also confirmed in tests with segregating F₂ generations. In the strains bearing recombinantH-2 haplotypes, the strength of the H-Y antigen is similar to that of parental strain from which the recombinant received itsK end, and the responsible gene (or genes) map to the left ofI-C. The effect of theH-2-linked gene(s) on thymus cells and skin is different. The gene linked to theK end ofH- 2^b determines a strong H-Y antigen on thymus cells, but a relatively weak H-Y antigen on skin. The gene linked to theK end ofH- 2^k determines a weak H-Y antigen on thymus cells, but a strong H-Y antigen on skin. The gene linked to theK end ofH- 2^d determines a weak H-Y antigen on both thymus cells and skin. Our observations raise the possibility that the structural gene for the H-Y antigen is linked toH-2. Alternative (but not exclusive) explanations invoke regulatory effects ofH-2 on the expression of the H-Y antigen, possibly by means of the control of the cellular andogen receptors.     

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.     

Biologic effects of microwave exposure. II. Studies on the mechanisms controlling susceptibility to microwave-induced increases in complement receptor-positive spleen cells

In attempting to evaluate the mechanisms responsible for susceptibility to the inductive increase in splenic complement receptor-positive (CR⁺) cells following exposure to 2450-MHz microwaves, it was found that sensitivity to microwave-induced CR⁺cell increases was under genetic control. In particular, evidence was accumulated suggesting that regulation was under the control of a gene or genes closely associated with but outside of the mouse major histocompatibility complex (H-2). All responsive strains of mice tested were of the H-2^k haplotype, while mice of the H-2^a, H-2^b, H-2^d and H-2i⁵ haplotypes were refractory to the microwave-induced increases in CR⁺ cells. By utilizing certain H-2^k strains of mice that were genetically unable to respond to endotoxin, we were able to show that these strains of mice responded to microwaves, but not to endotoxin, by increasing CR⁺ cells. Microwave-induced increases in CR⁺cells were not mimicked by the intraperitoneal injection of hydrocortisone. Athymic mice responded to microwave exposure, indicating that this event was not regulated by the T-cell population. Mice less than eight weeks old were found not to be susceptible to exposure to 2450-MHz microwaves. These studies indicate that microwaves do induce changes in the population of cells with specific cell-surface receptors, that susceptibility to these changes is under genetic control, and that it is unlikely that endotoxin, corticosteroids, or regulatory T cells play a significant role in the mechanisms regulating these increases.     

Subdivision of the S region of the mouse major histocompatibility complex by identification of genomic polymorphisms of the class III genes

The S region of the mouse major histocompatibility complex (MHC) encodes the class III proteins, the second (C2) and fourth (C4) components of complement, and factor B. Previously, the assignment of S-region haplotypes was based on analysis of protein polymorphisms. The recent availability of C2, C4, and factor B cDNA probes prompted a search for restriction fragment length polymorphisms which would serve as additional genetic markers for these loci. DNA was isolated from livers of mice of all standard inbred H-2 haplotypes and of haplotypes pz and bs. These DNA samples were digested with restriction endonucleases and analyzed by Southern blot. By the pattern of restriction fragment length polymorphism observed, specific markers have been identified in factor B of haplotypes f, u, z, bs, r, and v, and in C4 of haplotypes b, q,f,j,p,s, pz, r, and v. These genetic markers were used in the analysis of S-region composition in strains B10.TFR5 (H-2 ^ap5) and C3H.LG (H-2 ^dx), and a possible intra-S-region recombinant was revealed in the H-2 ^dxhaplotype. The genetic markers identified here subdivide the S region and will be of value in defining further the composition of the complement gene complex of the mouse MHC.     

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.     

Genetic structure and contrasting selection pattern at two major histocompatibility complex genes in wild house mouse populations

The mammalian major histocompatibility complex (MHC) is a tightly linked cluster of immune genes, and is often thought of as inherited as a unit. This has led to the hope that studying a single MHC gene will reveal patterns of evolution representative of the MHC as a whole. In this study we analyse a 1000-km transect of MHC variation traversing the European house mouse hybrid zone to compare signals of selection and patterns of diversification at two closely linked MHC class II genes, H-2Aa and H-2Eb. We show that although they are 0.01 cM apart (that is, recombination is expected only once in 10 000 meioses), disparate evolutionary patterns were detected. H-2Aa shows higher allelic polymorphism, faster allelic turnover due to higher mutation rates, stronger positive selection at antigen-binding sites and higher population structuring than H-2Eb. H-2Eb alleles are maintained in the gene pool for longer, including over separation of the subspecies, some H-2Eb alleles are positively and others negatively selected and some of the alleles are not expressed. We conclude that studies on MHC genes in wild-living vertebrates can give substantially different results depending on the MHC gene examined and that the level of polymorphism in a related species is a poor criterion for gene choice.     

Cytotoxic T lymphocytes recognize determinants on the BALB/c-H-2Ld molecule controlled by α1 and α2 but not α3 external domains

We have shown that cytotoxic T lymphocytes (CTL) raised in H-2 ^dmice use H-2L^d but not H-2D^d or H-2K^d antigens as restricting elements in lymphocytic choriomeningitis virus (LCMV) and vesicular stomatis virus (VSV) infections. To localize the regions of H-2L^d protein recognized by CTL, we constructed a recombinant H-2L ^d/D ^dgene encoding a hybrid antigen with 1 and 2 external domains of H-2L^d and 3, transmembrane and cytoplasmic domains of H-2D^d. The recombinant gene was transfected into mouse cells and the hybrid molecules were characterized serologically, biochemically and functionally. In all assays, H-2L^d/D^d molecules were recognized by LCMV- and VSV-specific H-2L^d-restricted CTL in a manner similar to that of wild-type H-2L^d antigens. Analogous results were obtained with alloreactive CTL. Hybrid antigens containing the 3 domain of H-2L^d fused to 1 and 2 domains of a Qa-2,3 region-encoded antigen were not used as restricting elements by LCMV-specific CTL. These results suggest that H-2L^d-restricted CTL directed against LCMV and VSV recognize determinants controlled by the 1 and/or 2 domains of the H-2L^d molecule.Abbreviations used in this paper CTL cytotoxic T lymphocytes - VSV vesicular stomatitis virus - LCMV lymphocytic choriomeningitis virus - tk thymidine kinase - HAT hypoxanthine, aminopterine, thymidine - HSV herpes simplex virus - FCS fetal calf serum - SAC Staphylococcus aureus Cowan I strain - TM transmembrane - CYT cytoplasmic