Multigenic regulation of the primary immune response to ovalbumin in mice

At least four genes regulate the primary immune response to ovalbumin in mice. The ability to be sensitized to transfer delayed type hypersensitivity to ovalbumin is controlled by two genes. One gene,OVA-, is linked to theH-2 complex and maps to the left ofI-E. The linkage of the other gene,OVA-Bg1, has not been determined, but it segregates independently of theLy M locus, of the heavy chain allotype genes and of certain genes controlling coat color. At least two genes regulate the ability to respond with a primary antiovalbumin antibody response. One gene,OVA-, is linked to theH-2 complex and maps to the right ofI-E. Discordance of the minimum dose of antigen needed to elicit delayed type hypersensitivity response and antibody suggests that non-H-2 gene(s) regulating the primary antibody response are different fromOVA-Bg1.Abbreviations used in this paper BSA bovine serum albumin - DTH delayed type hypersensitivity - H-2 major histocompatibility complex of mouse - Ir gene — immune response gene - OVA ovalbumin - SRBC sheep red blood cells     

Adoptive transfer of delayed-type hypersensitivity to sendai virus

TheH-2 restriction pattern of cytolytic T lymphocytes (Tc) and T lymphocytes which mediate a delayed-type hypersensitivity response (Td) directed against infectious Sendai virus was investigated usingH-2 mutant mice. Td and Tc lymphocytes exhibit the same fine specificity for self-recognition, for example, B6.C-H- 2^bm1 effector T cells were unable to recognize viral antigens in association with wild-type K^b and vice versa, B6.-H- 2^bm6 effector cells did not mediate a reaction against virus plus wild-type K^b but, on the other hand, T cells of wild-type K^b recognized virus plus K^bm6.BALB/c-H- 2^dm2 T cells lacked reactivity against virus in association with wild-type D^d, but again wild-type D^d effector cells recognized virus plus D^dm2.Abbreviations used in this paper DTH delayed-type hypersensitivity - EID₅₀ mean egg infective dose - FCS fetal calf serum - HAU hemagglutinating units - LPS lipopolysaccharide - Ly^(–) low amount of Ly antigens - MHC major histocompatibility complex - 2-ME 2-mercaptoethanol - PBS phosphate-buffered saline - Tc cytolytic T cell - Td T cell which mediates a delayed-type hypersensitivity reaction     

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

Immune response (Ir) genes mapping in theI region of the mouseH-2 complex appear to regulate specifically the presentation of a number of antigens by macrophages to proliferating T cells. We have investigated the possibility that similarIr genes mapping in theH-2K andH-2D regions specifically regulate the presentation of target antigens to cytotoxic effector T cells. We report that the susceptibility of targets expressing specific non-H-2 H alloantigens to lysis by H-2-compatible, H-antigen-specific cytotoxic effector T cells is controlled by polymorphicH-2K/D genes. This control of susceptibility to lysis is accomplished through what we have defined operationally as antigen-specific regulation of non-H-2 H antigen immunogenicity. High immunogenicity of the H-4.2 alloantigen is determined by a gene mapping in theH-2K region ofH-2 ^b . However, high immunogenicity of H-7.1 is determined by a gene mapping in theH-2D region ofH-2 ^b . High immunogenicity of the H-3.1 alloantigen is determined by genes mapping in both theH-2K andH-2D regions ofH-2 ^b . Therefore, genes mapping in theH-2K andH-2D regions serve a function in presenting antigen to cytotoxic effector T cells. This function is analogous to that played byI-regionIr genes expressed in macrophages which present antigen to proliferating T cells. We present arguments for classification of theseH-2K/D genes as a second system ofIr genes and discuss the implications of twoH-2-linkedIr-gene systems, their possible functions, and their evolution.     

The influence of Igh-1 genes on the class and subclass distribution of oxazolone-specific antibodies

Previous studies have demonstrated that the level of the oxazolone-specific antibody response induced by contact sensitization is under the control of H-2 and Igh-1-linked genes. The aim of the present study was to clarify the role of H-2 and Igh-1 genes in the regulation of antibody affinity and isotype composition of oxazolone-specific antibodies. Analysis of the antibody response to oxazolone has revealed different ratios of IgG2a and IgG2b antibodies in mice carrying the Igh-1 ^b allele and in strains carrying alleles a, c, and e. The characteristic ratio of IgG2a and IgG2b isotypes persisted during the whole period of the primary and secondary antibody response of CBA and CBA-Ig ^b Igh-C congenic mice. The Igh-1-linked genes influenced the isotype distribution and not the affinity of oxazolone-specific antibodies induced by contact sensitization.Abbreviations used in this paper c.Ig chicken immunoglobulin - Igh-C constant region of immunoglobulin heavy chain - DNCB 2,4-dinitrochlorobenzene - DTH delayed-type hypersensitivity - FITC fluorescein isothiocyanate - Igh-1 cluster of structural heavy chain allotype genes of IgG2a - KLH keyhole limpet hemocyanin - KSCN potassium-sulfocyanid - MHC major histocompatibility complex - Ox oxazolone (4-ethoxymethylene-2-phenyl-5-oxazolone - Ox-BSA oxazolone-bovine serum albumin - Ox-cap oxazolone-capronic acid - Ox-MSA oxazolone-mouse serum albumin - NP 4-hydroxy-3nitrophenyl acetyl - PVP polivinylpirrolidon - RIA radioimmunoassay - SRBC sheep red blood cell - T_H T helper - T_S T suppressor - Igh-V variable region of immunoglobulin heavy chain     

Selective expression of murine lymphocyte alloantigens controlled by the X-chromosome

Alloantisera specific to X-chromosome linked lymphocyte membrane antigens (Ly-X) were prepared by immunizing F1 male mice with identical F1 female lymphocytes. Independent B cell specific (anti Lyb-X) and T cell specific (anti Lyt-X) antibodies were detected. The Lyt-X antigen was expressed on Lyt-2⁺, 3⁺, and on Tla^–, Lyt-1⁺, 2⁺, 3⁺ T cell subpopulations. The problem of X-chromosome inactivation and the relationship ofH-2-linkedIr genes and Ia antigens, with X-linkedIr genes and lymphocyte alloantigens are discussed.     

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.     

Immune responses to complex protein antigens I. MHC control of immune responses to bovine albumin

Murine T cell proliferative and antibody responses to the multi-determinant protein bovine serum albumin (BSA) are controlled by Ir genes mapping within the H-2 gene complex. Strains possessing the H-2k, H-2a, and H-2d haplotypes are classified as high responders to BSA. In contrast, H-2b strains are low responders to BSA. Genetic mapping experiments employing strains with recombinant H-2 haplotypes indicate that both T cell proliferative and antibody responses are at least in part regulated by genes within the I-A subregion. Studies on the inhibition of T cell proliferation by monoclonal anti-Ia antibodies are consistent with the assignment of an Ir gene for BSA to the I-A subregion and strongly suggest a role for genes within the I-E/C subregions as well. The MHC-mediated control of antibody responses did not affect the affinity or the isotype of the antibody produced. The relative quantities of antibody specific for each of the three domains of BSA appears to be regulated by H-2-linked BSA Ir genes, and domain III antigenic determinants were found to be dominant in the responses of low-responder mice and in the early response of high-responder mice. This domain III epitope dominance essentially disappears by the tertiary response of high-responder mice.     

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.     

Two distinct high immune response phenotypes are both controlled byH-2 genes mapping inK orI-A

Murine responses to immunization with 2, 4, 6-trinitrophenyl (TNP) conjugated to autogenous mouse serum albumin (MSA) in complete Freund's adjuvant (CFA) are controlled by a gene(s) in theK orI-A region of theH-2 complex. High immune responses of bothH-2 ^d andH-2 ^b mice have been mapped to this region of the major histocompatibility complex. No modifying effects were observed from genes to the right ofI-A in either responder haplotype. High responsiveness controlled byK ^b orI-A ^b is inherited with complete or partial recessivity, depending on the route of immunization and the sex of the responder. However, high responsiveness controlled byK ^d orI-A ^d is inherited dominantly. This unusual pattern of inheritance of immune responsiveness to TNP-MSA is consistent with the genetic mapping toK orI-A. TNP-MSA-specific T-cell reactivity following immunization with TNP-MSA in vivo was examined utilizing a T-cell-dependent proliferation assay in vitro with cells obtained from high or low responder mice. Genetic mapping and mode of inheritance in this assay for antigen-specific T-cell reactivity corresponded with results obtained from a plaque-forming cell (PFC) assay measuring antibody production by B cells. Both the proliferative and PFC responses are probably under the sameIr gene control. Both gene dosage effects and Ir-gene-product interaction could influence the generation of specific immune responsiveness in F₁ hybrids between high and low responders to TNP-MSA.     

Genetic analysis of immune suppression

We have analyzed the genetic control of susceptibility to suppression by 1-J⁺, suppressor-T-cell derived factors (TsF) specific for the synthetic polymer L-glutamic acid⁵⁰-L-tyrosine⁵⁰ (GT). GT-TsF activity was measured as specific inhibition of proliferative responses to GT developed in cultures of lymph-node T cells from mice primed with GT complexed to methylated bovine serum albumin (GT-MBSA). These experiments demonstrated that there is no MHC-encoded genetic restriction between donors and recipients of GT-TsF in suppression of proliferative responses. We have also confirmed the observations that mice of the H-2 ^b, H-2 ^d, and H-2 ^khaplotypes can produce GT-TsF, whereas H-2 ^amice do not, and that H-2 ^b, H-2 ^d, and H-2 ^kmice are sensitive to GT-TsF from all producer strains, whereas H-2 ^bmice are not sensitive to GT-TsF from any strain. Analysis of the effect of GT-TsF on responses by mice bearing recombinant haplotypes suggests that at least two genes are required for susceptibility to GT-TsF and that these genes show coupled complementation.Abbreviations used in this paper GAT random linear terpolymer of L-glutamic acid⁶⁰-L-alanine³⁰-L-tyrosine¹⁰ - GAT-MBSA GAT complexed to methylated bovine serum albumin - GATTsF GAT-specific-T-cell derived suppressor factor - GT random linear copolymer of L-glutamic acid⁵⁰-L-tyrosine⁵⁰ - GT-MBSA GT complexed methylated bovine serum albumin - GT-TsF GT, specific, T-cell derived suppressor factor - ³H-TdR tritiated thymidine - Ir gene immune response gene - MBSA methylated bovine serum albumin - MEM minimal essential media - MHC major histocompatibility complex - PFC plaque-forming cell(s) - PPD purified protein derivative of M. tuberculosis H37Ra     

Genetic control of T-cell proliferative responses to poly(glu40ala60) and poly(glu51lys34tyr15): Subregion-specific inhibition of the responses with monoclonal Ia antibodies

The relationship betweenIr genes and Ia antigens was studied in the T-cell proliferative responses to two synthetic polypeptides poly(glu⁴⁰ala⁶⁰) (GA) and poly(glu⁵¹lys³⁴tyr¹⁵) (GLT¹⁵). The response to GA was found to be controlled by anIr gene in theI-A subregion, whereas the anti-GLT¹⁵ response was shown to be under dual control, oneIr gene mapping probably in theI-A subregion, and the other in theI-E subregion. We obtained two different lines of evidence suggesting identity ofIr and Ia genes. First, the presence of certain serologically identified allelic forms of the I-A-encoded A molecule correlated with the responder status to GA both in inbred strains and in B10.W lines, the latter carrying wild-derivedH-2 haplotypes. Thus the Ir and Ia phenotypes were not separable in strains of independent origin. Second, the anti-GA response was completely inhibited by monoclonal antibodies against determinants on the A molecule (Ia.8, 15, and 19), but not by a monoclonal antibody against a determinant on the E molecule (Ia.7). In contrast, the anti-GLT¹⁵ response was only inhibited by a monoclonal antibody against the E molecule, but not by antibodies against the A molecule. Our data support the hypothesis that Ia antigens, as restriction elements for T-cell recognition, may in fact be the phenotypic manifestation ofIr genes.     

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.     

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.     

Delayed-type hypersensitivity to allogeneic mouse epidermal cell antigens

Footpad swelling response was used to measure the alloantigenicity of epidermal cells (ECs) in delayed-type hypersensitivity (DTH). Strong footpad swelling was oberserved 3 h after the challenge, and it continued for 48 h after the challenge. Genetical incompatibility between the recipients and the ECs was required to induce significant footpad swelling. H-2 or non-H-2 incompatibility between mice and ECs in the sensitization phase sufficed to develop significant footpad swelling. Incompatibility caused by point mutation in the A region induced strong responses when B6. C-H-2 ^bm12 mice were immunized with B6/J ECs, but the disparity in immuno-globulin h (Igh) allotype genes was insufficient. H -Y antigen on ECs could also elicit the DTH response. Semiallogeneic F₁-derived ECs sensitized the parental recipients. The responses were successfully transferred by immune lymph node cells, but not by immune sera. Treatment of these immune lymph node cells with monoclonal antibodies plus complement revealed that the cells responsible for DTH transfer were Lyt-1⁺2^–, Ia^– T cells.Abbreviations used in this paper DNFB 2,4-dinitro-1-fluorobenzene - DTH delayed-type hypersensitivity - ECs epidermal cells - HBSS Hanks' balanced salt solution - MHC major histocompatibility complex - PBS phosphate-buffered saline     

Mechanisms of genetic control of immune responses

We examined multiple genetically regulated Immoral and cell-mediated immune (CMI) responses to poly(glu⁶⁰ala³⁰tyr¹⁰) (GAT) using a panel of mouse strains. We show that assignment of responder/nonresponder status depends upon the assay method. In addition, two distinct categories of nonresponder mice were found: (1) those which are unresponsive by all parameters tested (H-2 ^q and H-2 ^s haplotypes) and (2) those which are partially nonresponsive [H-2 ^bm12 mutant strain—a low/nonresponder by splenic plaque-forming cell (PFC) and delayed-type hypersensitivity (DTH) responses, but exhibits B6 parental levels of high GAT-specific T-cell proliferation (Tprlf) and interleukin-2 production]. The distinction between these two nonresponder types was confirmed by complementation tests in which significant GAT-specific PFC and DTH responses were seen in (H-2 ^q × H-2 ^bm12)F₁ hybrids, but not in (H-2 ^q × H-2 ^s )F₁ hybrids. Suppressor T cells (Ts) also play a selective role in nonresponsiveness to GAT. Cyclophosphamide treatment of nonresponders (to eliminate Ts activity) as well as immunization with GAT coupled to the immunogenic carrier MBSA result in the development of GAT-specific humoral, but not CMI responses. Our results indicate that the T cell is the cellular site of Ir gene expression and that Tprlf responses do not correlate with functional helper T-cell activity and suggest distinct, multi-step Th/Ts regulatory pathways in the development of humoral and CMI effector functions.     

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.     

Transfection of murine LMTK− cells with purified HLA class I genes

The individual contributions of the first two external domains of the HLA-B7 heavy chain to the expression of allele-specific (B7) and locus-specific (B and C) antigenic determinants were investigated using hybrid class I genes. Hybrid genes were constructed in vitro by exon shuffling between the parent genes HLA-B7, HLA-Cw3, HLA-A3, and H-2K ^d, and their expression was monitored following transfection into mouse L cells. The results show that most allele-specific antigenic determinants are associated with the first external domain of the 137 heavy chain, whereas all the locus-specific antigenic determinants tested map to the second external domain.Abbreviations used in this paper BSA bovine serum albumin - FCS fetal calf serum - mAb monoclonal antibody - PBL peripheral blood lymphocytes - PBS phosphate-buffered saline     

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.     

Mechanisms of genetic control of immune responses

The mechanisms underlying Ir gene control of CMI were addressed by examining the DTH and Tprlf responses specific for the synthetic polymers GT, GAT, and GA. We show that BALB/c mice (GAT/GA responders, GT nonresponders) primed with GT fail to develop DTH and Tprlf responses specific for GT, GAT, or GA. GAT immunization resulted in DTH responses that could be elicited not only with GAT and GA but also with GT, demonstrating that GT-specific T_DH are present in nonresponder mice. GT-specific DTH was transferred with Thy-1⁺ Lyt-1⁺2^–, H-2 Irestricted, nylon wool nonadherent cells. GA-primed BALB/c mice developed GAT- and GA-, but not GT-apecific DTH responses, indicating that GA and GT do not cross-react at the T-cell level. The ability of GAT [but not a mixture of GA plus GT, or GT electrostatically complexed to the immunogenic carrier MBSA (GT-MBSA)] to induce GT-specific DTH suggested a requirement for covalent linkage of stimulatory GA and nonstimulatory GT determinants present on the GAT molecule. Similarly, GT-specific in vitro Tprlf responses could be demonstrated in GAT-primed mice exhibiting significant levels of GT-specific DTH but not in GT- or GT-MBSA-primed mice. Tolerization experiments also suggested that GT-specific Th were involved in the development of GT-specific DTH in GAT-primed mice. The GT nonresponsiveness of BALB/c mice for DTH and Tprlf responses could not be reversed by treatments designed to abrogate Ts activity (priming with GT-MBSA and CY injection), nor could GT-primed cells be shown to inhibit the development or elicitation of GT-specific CMI in GAT-primed mice during the afferent and/or efferent stages of DTH. Our results suggest that GT nonresponsiveness does not result from the absence of GT-specific T cells or preferential induction of Ts. The results are discussed in the context of hole-in-the-repertoire and antigen presentation (determinant selection) models of Ir gene control.Abbreviations used in this paper APC antigen-presenting cells - BSA bovine serum albumin - BSS Mishell-Dutton balanced salt solution - CFA complete Freund's adjuvant - CMI cell-mediated immunity - CY cyclophosphamide - DTH delayed-type hypersensitivity - GA poly(Glu⁶⁰Ala⁴⁰) - GAT poly (Glu⁶⁰Ala³⁰Tyr¹⁰) - GT poly(Glu⁵⁰Tyr⁵⁰) - GT-MBSA GT complexed to methylated bovine serum albumin - It immune response - LN lymph node - PPD purified protein derivative of tuberculin - TDH DTH T cells - Th helper T cells - Tprlf T-cell proliferation - Ts suppressor T cells - TsF T-cell suppressor factor(s)     

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.