Genetic analysis of the non-H-2-linked Ir genes controlling the cytotoxic T-cell response to H-Y in H-2 d mice

The T-cell mediated immune responses to the male specific minor histocompatibility antigen H-Y in mice have been studied extensively as a model for immune responses to other weak antigens like tumor antigens or autoantigens. In a recent analysis of the strain distribution of the cytotoxic T-cell (Tc-cell) responsiveness to H-Y, it has been found that genes both within and outside the H-2 complex exert an interactive control. Whereas the H-2 ^b strains all are high responders, independent of their non-H-2 background, other H-2 haplotypes (d, k, and s) only allow for a response if they are combined with certain non-H-2 genes. The H-2-linked immune response genes (Ir-genes) have been previously mapped to the I and K or D region of the H-2 complex, but the mapping of the non-H-2 genes has not yet been established. In this study evidence is presented, using recombinant inbred strains and immunoglobulin heavy chain (Igh) congenic strains of mice, to show that there is more than one non-H-2 Ir-gene involved, that the main controlling genes are not linked to the Igh complex, and that at least one non-H-2 Ir-gene is linked to the H-3 region on chromosome 2. This region includes genes for beta-2-microglobulin (2m), the Ly-mllalloantigen a polymorphic cell surface glycoprotein (Pgp-1), a B-cell specific antigen Ly-4, a transplantation antigen H-3, and genes (Ir-2) controlling the immune response to Ea-1 and H-13.     

Influence of H-2-linked genes on glucocorticoid receptors in the fetal mouse palate

The binding of ³H-dexamethasone to cytosolic receptors in fetal jaws and in cytosols and nuclei of primary cell cultures of fetal palates was studied in various congenic strains of mice. The amount of specific binding was greater in palatal tissues from B10.A and BlO.A(2R) mice than in B10 or B10.A(5R) preparations. These differences were not observed in the liver. Since the strains with higher levels of glucocorticoid receptor are known to be more susceptible to cortisone-induced cleft palate than the strains with low receptor levels, it is suggested that quantitative variation in receptor levels may be involved in determining H-2-linked differences in cleft-palate susceptibility. Whether or not this is the case, it appears that an H-2-linked gene affects the quantity of a cytosolic glucocorticoid-binding protein which translocates to the nucleus.     

H-2-linked murine factor B phenotypes

A hemolytic assay has been developed which is specific for Factor B (B) activity in murine EDTA-plasma. Three discrete levels of B activity were observed among B 10-congenic strains. Mice with standard H-2 haplotypes, b, d, k, r, f, q, s, and u, all exhibited the same mean level of activity. However, plasma from H-2 ^v (B10.SM) mice contained only 0.25 of that level, and those with standard haplotype H-2 ^ja (B10.WB) or wild haplotype H-2^wr7 (B10.WR) exhibited 2.5 times the H-2 ^b (1310) basal level of activity. These differences among B10 congenic lines suggested that the activity is H-2 controlled; further tentative mapping with intra-H-2 recombinants indicated that the gene is located in the S region. A fourth phenotype was found among progeny of backcross generations between B10.BR (H-2 ^k ) and mice of subspecies Mus musculus molossinus and M. m. bactrianus. This ultra-high activity was found also to be governed by a gene very closely linked to Ss, the primary S region marker. F₁ generations between disparate phenotypes yielded progeny with activity levels intermediate between the parents; progeny of parents of different strains with the same phenotype expressed B hemolytic titres equal to those of the parental strains. No differences in antigenic levels of the protein among the strains of different phenotypes could be detected by radial immunodiffusion. In mixing experiments, resultant activity levels were intermediate between the higher and the lower phenotype, ruling out independent inhibitors or activators of the reaction. These studies indicate that an H-2-linked S region-located single gene governs structural differences in allelic B molecules that lead to differences in specific activities.     

Female expression of the H-2-linked sex-limited protein (Slp) due to non-H-2 genes

Female mice of 15 inbred strains in which males express the H-2-linked sex-limited protein (Slp) were tested for the production of this protein. Four inbred strains (FM, LG/J, NZB, PL/J) were found in which females produce Slp in the absence of hormonal manipulation. Crosses have been made between strains FM, NZB, or PL/J and several Slp-negative strains. Slp-typing of the F₁, F₂, and backcross progeny, as well as of a number of recombinant inbred strains, indicates that production of Slp by normal females of these strains depends upon the concurrent presence of an Slp-positive,H-t2-linked allele and of permissive alleles of one or two non-H-2 autosomal genes. Complementation studies with two of the strains (FM and PL) indicate that an identical genetic mechanism mediates expression of Slp in females of these two strains. FM-derived animals carrying the testicular feminization mutation (tfm) also express Slp, as do castrated NZB mice, indicating that Slp expression in these instances is not dependent upon testosterone as it is in other inbred strains. It is concluded from these results that genes distinct from the putative structural gene for Slp influence the sex-limitation of its expression.     

H-2-linked genetic control of the plaque-forming cell response to sheep red blood cells

The role of genes linked to the H-2 locus in effecting an immune response to SRBC was examined using strains of mice which differ in the classes of antibodies produced following multiple injections with SRBC. While H-2-linked gene action appeared to be at the level of regulating the number of plaque-forming cells (PFC) present in the spleens of different strains following two injections with SRBC, non-H-2-linked immune response genes seemed to determine whether an IgM-IgG switch occurred as well as how much of each antibody class was produced by the number of PFC available as a result of H-2-linked gene intervention. Mapping studies showed that the H-2-linked genetic effects were due to either the requirement for two genes or the presence of genes located between I-B and H-2D.     

Nematospiroides dubius: two H-2-linked genes influence levels of resistance to infection in mice

Strains of mice sharing common H-2 haplotypes but different genetic backgrounds, and H-2 congenic strains of mice differing only at H-2 genes were studied to assess the role of H-2 and non-H-2 genes in immunity to challenge infections with the nematode parasite Nematospiroides dubius. Strains of mice sharing the H-2k haplotype were uniformly more susceptible to challenge than strains expressing H-2q alleles, regardless of genetic background. However, in some cases strains of mice sharing the k or q haplotypes differed significantly in levels of resistance. Therefore, non-H-2 genes must influence the response observed. H-2 cogenic strains of mice differed markedly in their ability to resist challenge infections. Mice sharing the C57BL/10 background but expressing k alleles were very susceptible to challenge, while the H-2q, H-2f, and H-2s, haplotypes were associated with resistance. Studies of H-2 congenic recombinant strains of mice suggested that two H-2 genes influence the antiparasite response. One of these genes maps to the left of E alpha and the other to the D-end of the H-2 complex. It is concluded also that the unique configuration of H-2 genes in F1 hybrids contributes to increased resistance to challange.     

Immune response to the Slp alloantigen in the mouse:H-2-linked qualitative and quantitative control

Immunization of inbred mouse strains lacking the Slp allotype results in the production of Slp antibodies in some strains but elicits no detectable response in other strains. Analysis of standard inbred and congenic resistant strains reveals that both the qualitative and quantitative ability to respond to the Slp allotype is associated with theH-2 haplotype of the recipient. Three different response phenotypes can be identified utilizing complement fixation and quantitative immunodiffusion tests. Strains which carry theH-2 ^q haplotype are high responders,H-2 ^k strains are intermediate in response, whileH-2 ^b andH-2 ^v strains produce no detectable antibody. The characteristic response patterns of high and intermediate responders were manifest by day 35 of immunization and continued as discrete response types after a second booster. Quantitative data in the immune response of the intra-H-2 recombinant B10.A(4R) suggest that the recombination event which established theH-2 ^h4 chromosome disturbs the proper function of the genetic determinant controlling response to Slp.     

Regulation of the production of murine IgG2a by an H-2-linked gene and other unlinked genes

Alleles of at least two loci (rig-1 and Rig-2) regulate the levels of serum immunoglobulin of the Igh-1b class and allotype in BALB/c Ig^b (BAB/14) and (BALB/c × BAB/14)F₁ mice. The combined effect of the BALB/c alleles at these two loci is to lower Igh-1b levels significantly below those observed in other strains and below their own levels of Igh-1a in allotype heterozygous mice. The rig-1 locus is closely linked to or within the H-2 complex. Two alleles have been defined: rig-1 ^d and rig-1 ^b in H-2 ^d and H-2 ^b haplotypes, respectively. Homozygous rig-1 ^d d animals heterozygous for the BALB/c Rig-2 allele(s) have very low levels of Igh-1b. The designation of Rig-2 is provisional since it has not been mapped or defined as a single locus.     

Non-H-2 and H-2-Linked immune response genes control the cytotoxic T-cell response to H-Y

The immunoregulation of cytotoxic T-cell responses to the male-specific antigen H-Y in mice has been found to be genetically controlled by genes of the major histocompatibility complex (H-2). Responsiveness was mainly confined to H-2 ^b strains, but it has also been found in recombinant strains, F₁ hybrids, and chimeras that carry at least part of the H-2 ^b haplotype. By using a different immunization procedure it has been shown recently that an H-2 ^k mouse strain (CBA) is also able to mount an equivalent H-Y-specific response. We investigate here, by applying this immunization technique, the responsiveness of other H-2 ^k strains and of strains of other independent H-2 haplotypes. Both responders and nonresponders are found in three haplotypes: k, s, and d. The strain distribution pattern of responsiveness shows a combined influence of non-H-2 and H-2 genes. In certain strains there is a high variability in responsiveness between genetically indentical individual animals. We discuss a model of immune response (Ir) gene function which could account for these observations.     

Insulin-specific tolerance induction. I. Abrogation of helper T cell activity is controlled by H-2-linked Ir genes

Murine antibody responses to heterologous insulins are under H-2-linked immune response (Ir) gene control. We have found that the immune response to insulin in adjuvant can be inhibited by prior i.v. injection of soluble insulin. The effect of i.v. injection of insulin is antigen-specific and dose-dependent and requires the same doses of insulin that are immunogenic if administered with adjuvant. In addition, the inhibitory effect of soluble insulin is dependent upon the route of injection; if soluble insulin is injected i.p., the subsequent response to insulin in adjuvant is augmented rather than inhibited. Unresponsiveness requires at least 4 days after i.v. injection to develop and once induced, it is maintained for 4 wk or more. Unresponsiveness is caused by T cell, but not B cell, tolerance, and we have been unable to demonstrate any role for suppressor T cells in this unresponsiveness. More importantly, analysis of the ability of numerous insulin variants to induce unresponsiveness in several H-2k and H-2b strains of mice has demonstrated that only the variants that were immunogenic in a given strain when administered with adjuvant were able to cause tolerance. This report is, to our knowledge, the first describing that induction of helper T cell tolerance, like the induction of immunity, is controlled by H-2-linked Ir genes.     

Analysis of H-2-linked immune responses involved in resistance to AKR tumor growth

H-2-associated immune response gene(s) govern resistance to growth of a spontaneous AKR lymphoma, BW5147. The antigenic specificities recognized by the anti-BW5147 humoral response have been characterized and include: Thy-1, a T -cell differentiation antigen; gp70, a retroviral envelope protein; and several previously uncharacterized proteins, including a 78 000 molecular mass protein, p78, which is restricted to expression on BW5147 cells and five phosphoproteins with molecular masses of 33 000, 29 000, 23 000, 17 000, and 16 000. Only mice which are able to respond to Thy-1, p78, and the phosphoproteins can survive an inoculation of BW5147. Thus, resistance to BW5147 is complex and involves multiple antigens with possible roles in tumor rejection.Abbreviations used in this paper DMEM Dulbecco's modified Eagle's medium - FCS fetal calf serum - Ir immune response - MuLV murine leukemia virus - NMS normal mouse serum - PBS phosphate-buffered saline - SDS sodium dodecyl sulfate - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis - TCA trichloroacetic acid     

H-2-linked control of resistance to Ectromelia virus infection in 1310 congenic mice

Several B 10 strains of mice, recombinant at theH-2 locus, have been shown to differ in their resistance to infection with ectromelia virus, a natural mouse pathogen. Of 10 strains, 1310, B 10.A(2R), B10.A(4R) and B10.D2 were the most resistant, while B10.G and B 10.A(5R) were the most susceptible. Other strains were intermediate between these extremes. Several genes conferring resistance have been mapped toD ^b in B10.A(2R),K ^k I-A ^k I-B ^k in B10.A,I-J ^b in B10.A(2R) and toD ^d in B 10.T(6R). In general, death among susceptible strains was not a consequence of acute liver necrosis as in other non-B10 strains, and occurred randomly from 8–14 days after infection. The exact cause of death is unknown but is characterized by persisting high titers of virus in the spleen and sometimes the liver, despite an ongoing immune response indicated by strong cytotoxic T-cell activity detectable in the spleens of all mice. The most resistant B10 and B10.A(2R) strains cleared virus from the spleen and liver by 8 days after infection. Analysis of infection in chimeric mice indicates thatH-2 genes, which determine susceptibility to virus persistence in the spleen, operate via radiosensitive cells of the lymphomyeloid system. This evidence, together with several examples ofH-2-linked differences in cytotoxic T-cell responsiveness between resistant and susceptible strains, is consistent with the hypothesis that the mechanism by whichH-2 genes control resistance to ectromelia virus in B10 strain mice is by their influence on the effectiveness of a cell-mediated immune response.     

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.