Genetic control of the immune response to the H-2 associated Slp alloantigen in the mouse.

A survey of sixteen standard inbred and congenic resistant strains of mice reveals that the ability to mount an immune response to the Slp allotype is associated with the H-2 type of the recipient. Strains carrying the H-2f, H-2k, and H-2q haplotypes are able to produce specific antibody whereas strains of the H-2b haplotype are non-responders. Analysis of F1-hybrids and four informative intra-H-2-recombinants demonstrates that the ability to respond to the Slp allotype is controlled by a dominant gene associated with the K end of the H-2 complex.     

Quantitative variations in the expression of the mouse serum antigen Ss and its sex-limited allotype Slp

A radial immunodiffusion assay for quantitation of the Ss and Slp serum antigens is described. Significant differences between the mean serum concentrations of Ss and Slp were found among various inbred strains. Some of these differences have been shown to be associated with the H-2 haplotype. The quantitative difference between Slp levels associated with the H-2 ^a and H-2 ^S haplotypes has been used as a marker for the S region in the analysis of certain H-2 recombinant strains [A.TH, B10.S(7R), B10.S(9R), and B10.BSVS]. Male mice of two strains with the H-2 ^b haplotype have been shown to have significantly lower levels of Ss compared to males of the other strains tested. Male mice of every strain examined were found to have significantly higher levels of Ss in their serum than females of the same strain. The molecular relationship and developmental patterns of the Ss and Slp antigens have also been investigated using the radial immunodiffusion assay.     

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.     

H-2-linked recessiveIr gene regulation of high antibody responsiveness to TNP hapten conjugated to autogenous albumin

The antibody response to the hapten 2,4,6-trinitrophenyl (TNP) conjugated to autogenous mouse serum albumin (MSA) is regulated by anIr gene(s) located within the major histocompatibility complex (MHC). Both the qualitative and quantitative ability of congenic strains to produce TNP-specific antibodies are functions of theH-2 haplotype. Thus, mouse strains may be classified as high (H-2 ^d), intermediate (H-2 ^b,H-2 ^s), and low responders (H-2 ^a,H-2 ^k,H-2 ⁿ,H-2 ^p,H-2 ^q). Antibody responses, as measured by antigen-binding capacities in modified Farr assays, were compared among strains carrying recombinantH-2 haplotypes and their hybrid progenies. Distinct high- and low-responder phenotypes were evident throughout the time course of both primary and secondary antibody responses. The gene locus controlling specific responsiveness to TNP-MSA, now designatedIr-6, was mapped within theI-B subregion of theH-2 complex. Recessive inheritance of high responsiveness was confirmed in hybrid progenies of three different low × high-responder crosses.     

H-2-Controlled polymorphism of the γ chain of Slp (sex-limited protein)

A genetic polymorphism detected by the O'Farrell two-dimensional technique (isoelectric focusing and SDS-PAGE) of the murine sex-limited protein (Slp) is described and shown to map to theH-2 complex. The Slp charge variation was found to be in the chains. Inbred strains carrying theH-2 ^w7 andH-2 ^wr7 haplotypes, which are derived from a wild mouse, had Slp- chains with pI = 6.55 (Slp-l^b). All other inbred strains, bearingH-2ij,H-2 ^s ,H-2 ^p ,H-2 ^d ,H-2 ^u , as well as three additional Slp-constituive wild females captured in Chile, had Slp- chain with pI = 6.71 (Slp-l^a).     

Multigenic control of immune responses of inbred mice against the terpolymers poly(Glu57Lys38Ala5) and poly(Glu54Lys36Ala10) and linkage withH-2 haplotype

Results of immunizations of recombinant inbred and congenic strains of mice with the random polymers poly(glu⁵⁷ lys³⁸ala⁵) or GLA⁵ and poly(glu⁵⁴lys³⁶ala¹⁰) or GLA¹⁰ indicate that there is an association of the responsiveness with theH-2 haplotype. Although the C57BL/6J mice (H-2 ^b haplotype) are “non responders”, the C57BL/6By originally derived from mice of the same haplotype are responders. The immune response pattern of recombinant strains carrying haplotypes derived by crossing over within theH-2 complex indicate that the responsiveness is under control of anIr gene which maps to the left of theIB subregion. Studies with the backcross mice indicated multigenic control of the responsiveness, with one locus beingH-2 linked and another locus segregating independently ofH-2.     

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.     

Immunogenetic analysis ofH-2 mutations

Spleen cells carrying theH-2K ^b allele and sensitized against TNP-modified stimulator cells in vitro displayed a cytotoxic effect against TNP-modified target cells carrying a mutation in theH-2K ^b allele (haplotypesH-2 ^ba ,H-2 ^bd , andH-2 ^bf ). Similar crossreactivity in TNP-CML was observed in the reciprocal direction. Spleen cells carrying theH-2K ^k allele and sensitized against TNP-modified stimulators displayed a cytotoxic effect against TNP-modified target cells carrying a mutation in theH-2K ^k allele (haplotypeH-2 ^ka ) and vice versa. The effector cells in these assays were sensitive to anti-T cell serum in the presence of complement, and supernatants from immune cultures did not induce nonimmune cells to display a cytotoxic effect. Titration of effector cells from mutant and wild-type strains of theH-2 ^b haplotype indicated no detectable quantitative differences in their activities. These data demonstrate that crossreactivity in TNP-CML occurs in closely related allogeneic strains that have recently undergone mutation in theH-2 complex.     

Preliminary evidence of genetic control of the immune response to the Thy-1.2 antigen in mice

The primary immune response to the Thy-1.2 antigen was measured by the plaque assay, detecting cells (PFC) producing antibodies lytic for thymocytes carrying this antigen. On the basis of statistically significant differences in response, the inbred strains studied could be classified as low (producing fewer than 10³ PFC/spleen) or high (producing more than 10³ PFC/spleen) responders. The data collected from these inbred strains and segregating generations were consistent with the concept that the primary immune response to the Thy-1.2 antigen is under genetic control. This control appeared to be exerted primarily by alleles at a locus linked to theH-2 complex but involvement of alleles at other loci could not be ruled out. Contrary to the commonly described experimental models, the high responsiveness to the Thy-1.2 antigen in some strain combinations seemed to be a recessive rather than a codominant trait.     

Immune suppression genes control the anti-F antigen response in F1 hybrids and recombinant inbred sets of mice

The immune response to the liver protein F antigen which, in the mouse, occurs in two allelic forms, is under sharp immunogenetic control in that only mice that possess the A^k molecule can respond to allo-F antigen. This response has been studied in a number of F₁ hybrids between inbred strains and with recombinant inbred lines all of which express A^k, and which thus enable immune suppression effects to be detected. In the AKXL and AKXD sets, the hybrids with CBA are responders if H-2 ^k/H-2^k, and usually nonresponders if H-2 ^k/H-2^b or H-2 ^k/H-2^d. Although this may be due to gene dosage effects, this cannot be the explanation for the low responsiveness of the H-2 ^k/H-2^b relative to the H-2 ^k/H-2^d mice found in CBA × BXD hybrids. For this, and other reasons, it seems likely that low responsiveness in any mouse possessing a responder A ^k allele is due to suppression, and that this is mediated by the immune suppression effects of the non-H-2 ^k haplotype. These H-2-mediated effects can be modified, both positively and negatively, by background genes. Thus, of the ten H-2^k/H-2^d members of the CBA × AKXD cross, seven are low responders and three are high responders. No other typed marker has the same strain distribution pattern at present. Major unresolved questions, therefore, concern the location and mechanism of action of the background genes and the mechanism of action of the H-2 immune suppression genes.     

H-2 effects on cell-cell interactions in the response to single non-H-2 alloantigens

Individual mice were tested for their proliferative T-cell response to H-Y- and H-3-incompatible stimulator cells in secondary mixed lymphocyte culture. Responders expressing the H-2 ^bhaplotype were restricted in their response to stimulators presenting H-Y and H-3 in the context of H-2 ^b. Lymphocytes from individual B10 females proliferated in response to H-Y presented with I-A ^band D ^b. The ratio of I-A ^b/D ^b-restricted responses varied between individual responders, indicating significant qualitative variation between genetically identical responders. The majority of the proliferative response in all tested mice was restricted to the entire H-2 ^bhaplotype suggesting complementation of I-A ^b- and D ^b-region genes in presenting the H-Y antigen. Similar observations were made in the response of individual B10.LP mice to the H-3 antigen. H-3-specific, proliferating T cells were restricted to H-3 antigen presented with K ^bA^band D ^bwith significant variation between individuals in their preference for H-3 plus K ^bA^band D ^b. In contrast to the response to H-Y, the proliferative response to H-3 plus H-2 ^bcould be accounted for by the summation of the proliferative responses to H-3. plus K ^bA^band D ^b. These observations demonstrate that the proliferative response to non-H-2 H antigens in the context of I-region determinants is not a sine qua non for the T-cell response to these antigens. Further, the individual qualitative and quantitative variation observed with individual genetically identical mice has strong implications for our knowledge of intrastrain variation in immune responsiveness and the characterization of inbred strains for immune responsiveness.     

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.     

Syngeneic sensitization of mouse lymphocytes on monolayers of thyroid epithelial cells: IV. Correlation with H-2 haplotypes

In vitro primary syngeneic sensitization on monolayers of thyroid epithelial cells was performed with 21 inbred strains of mice representing 11 original H-2 haplotypes. Significant differences in the proliferative responses, assessed by thymidine uptake, were found to be related to the major histocompatibility complex haplotype. This result was further confirmed using congenic resistant strains of mice. In comparison with the experimental autoimmune thyroiditis induced by syngeneic thyroglobulin and adjuvant, primary syngeneic sensitization on monolayers of thyroid epithelial cells appeared to be under the same genetic control (H-2^k strains being good responders, while H-2^b mice are poor responders).     

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.     

H-2 and Background influences on tissue grafts across the H-Y barrier

Male liver was grafted to kidney beds in syngeneic female mice. Relative influences ofH-2 haplotype, genetic background or interaction ofH-2 haplotype with genetic background on anti-H-Y response were evaluated using 27 inbred strains carrying eightH-2 haplotypes of independent origin and three naturally occurring recombinants. Females ofH-2 ^b haplotype acutely rejected the male graft as is reported for other tissue graft systems. AnH-2 haplotype influence was found for all haplotypes studied, with a greater variation of immunologic response revealed by histological analysis of liver grafts than is demonstrated by skin grafts. Strains carryingH-2 ^k ,H-2 ^j andH-2 ^p haplotypes expressed the greatest range of immunological variability with responses ranging from graft proliferation to graft rejection. Strains carrying theH-2 ^d haplotype had the most consistent responses with little reaction to the graft. The strong immune response by SJL/J (H-2 ^s ) female mice to the H-Y antigen is not typical of otherH-2 ^s strains, but is compatible with the reported hyperresponsiveness of this strain to alloantigens.     

TheH-2 class II genes and the susceptibility to the development of pulmonary adenoma in mice

To determine the locus in theH-2 complex that affects susceptibility to the development of pulmonary adenomas in mice,H-2 congenic and recombinant strains of mice with A/Wy, BALB/c, C3H, and B10 backgrounds were subjected to treatment with urethane. The average number and the incidence of adenoma foci were recorded five months after the treatment. InH-2 congenic strains on the A/Wy background, the average number of adenoma foci per mouse was significantly higher in mice of the A/Wy, A/J, and A-Tla ^b (H-2 ^a ) strains than in A.BY (H-2 ^b ) mice. In BALB/c and C3H congenic strains, the strains carrying theH-2 ^k haplotype were more susceptible than those carrying theH-2 ^b haplotype. InH-2 congenic strains on the B 10 background, the average number and incidence of foci was also higher in haplotypesa, h2, k, andj than in haplotypesb, s, f, d, r, h4, i3, i5, and4. The average numbers of adenoma foci in (A/J × A.BY)F₁ (H-2 ^a /H-2 ^b ) and (B10 × B10.A)F₁ (H-2 ^b /H-2 ^a ) were intermediate between the numbers in the parental strains. In [B10.A (4R) × B10.A (3R)]F₁ (H-2 ^h4 /H-2 ⁱ³ ) and [B10.A (4R) × B10.A (5R)]F₁ (H-2 ^h4 /H-2 ⁱ⁵ ), the numbers of adenoma foci were higher than in resistant parental recombinants. These patterns of response to urethane matched the patterns of the immune response to lactate dehydrogenase-B (LDH-B) and immunoglobulin gamma 2a (IgG2a) proteins. These differences between mice in their susceptibility to the development of pulmonary adenomas is probably due to the polymorphism of the class II genes in theH-2 complex.     

Study of anH-2K d mutant strain: C.B6-H-2 dm4

A new-H-2 mutant involving theH-2 ^d haplotype is described — C.B6-H- 2^dm4 (dm4). This mutant strain carries a gain and loss mutation which maps to theK ^d gene of theH-2 complex. Serological testing comparing the mutant and the parental BALB/cKh strain failed to detect any difference between the two strains and no antibodies could be produced, although a reciprocal mixed lymphocyte reaction was observed between mutant and parent.     

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.     

Genetic control of immune responses of inbred mice: Responses against terpolymers poly(glu57lys38ala5) and poly(glu54lys36ala10)

The immune response patterns of inbred and congenic strains of mice against terpolymers poly(glu⁵⁷lys³⁸ala⁵) and poly(glu⁵⁴lys³⁶ala¹⁰) have been studied. Initial recognition of the polymers is ascribed to ‘GA’ receptors (Ir-GA gene product) on T cells of mice ofH-2 haplotypes,a,b,f,k ands, and ‘GL’ receptors (Ir-GL gene product) of mice ofH-2 ^p,H-2 ^q andH-2 ^j haplotypes, and to GA and/or GL receptors of mice ofH- 2^d andH- 2^r haplotypes. The specificity of the antibody is directed predominantly against GL. The inability to elicit antibody with GA specificity has been ascribed to the lack of significant concentrations of GA sequences in the polymers to interact with appropriate receptors on B cells. The weakest responders were mice of H-2^b haplotype. F¹ hybrids (responders×nonresponders) were all responders demonstrating the dominant character of responsiveness. Wide variations in antibody levels produced among strains of mice of theH-2 ^k andH-2 ^b haplotypes are ascribed to genes not linked toH-2.     

Genetic and immunological characterization of naturally occurring recombinant B3 rats

The B-stock population of rats was bred for homozygosity at the loci controlling coat color. In this process, theAg-B1 andAg-B3 haplotypes became fixed in Hardy-Weinberg equilibrium. Extensive immunization and absorption studies showed that the specificities in the B-stock rats homozygous for theAg-B1 haplotype were the same as those found in the inbred F344 strain (Ag-B1), and that the specificities in the rats homozygous for theAg-B3 haplotype were the same as those found in the inbred BN (Ag-B3) strain. A homozygous line derived from the rats carrying theAg-B3 haplotype (B3) has the mixed lymphocyte reactivity and antibody responsiveness to poly (Glu⁵²Lys³³Tyr¹⁵) characteristic of the inbred strains in theAg-B4 group. Thus, it represents a naturally occurring recombination between the loci controlling MLR and immune responsiveness, on the one hand, and those controlling the Ag-B antigens on the other. Antibody responsiveness segregated with theAg-B3 haplotype in crosses between the B3 homozygotes and the low responder BUF and M520 strains; hence, this recombination is a stable one. There was no linkage of antibody formation or haplotype to coat color. The finding of a strain with a naturally occurring recombination in the major histocompatibility complex between the loci controlling mixed lymphocyte reactivity and the Ag-B histocompatibility antigens provides evidence for the separateness of these loci. Since the portion of the genetically determined mechanism controlling antibody responsiveness which is linked to the MHC was that characteristic of the MLR type, it too must lie outside the region defined by the serological specificities of theAg-B haplotype.