Immunodominance in the T-Cell response to multiple non-H-2 histocompatibility antigens

Immunization of C57BL/6 mice with BALB.B spleen cells in vivo and subsequent boosting in mixed lymphocyte culture result in the generation of cytolytic T lymphocytes (CTLs) which are specific for a limited number of immunodominant antigens. Experiments are described which suggest the existence of a hierarchy of immunodominance in this donor: host combination. Two antigens, CTT-1.3 and CTT-2.3, are dominant in the C57BL/6 anti-BALB.B CTL response. The distribution of these antigens among CXB recombinant inbred (RI) strains suggests that they segregate as single gene traits. Elimination of the CTT-1.3 and CTT-2.3 antigens by complementation in the responder, or elimination from the priming and boosting stages by the selection.of CXB RI strain mice as responders or stimulators, reveals a second level of immunodominant antigens which include CTT-3.3 and CTT-4.3. CXB mice which express one of the CTT-1.3 or CTT-2.3 antigens will produce CTLs specific for the other antigen upon priming and boosting with BALB.B cells. Expression of both antigens in responders results in the generation of CTLs specific for the second level, dominant antigens. Immunodominance is not confined to the C57BL/6 anti-BALB.B system but can also be observed in the BALB.B anti-C57BL/6 and B10.D2 anti-DBA/2 systems. Finally, generation of CTLs following priming and boosting with dominant and dominated antigens presented on different cells confirmed that immunodominance can only be observed when the dominant and dominated antigens are presented on the same cells. These observations suggest that immunodominance is revealed at the level of antigen-presenting cells primarily involved in vivo priming.     

Immunodominance in the T cell response to multiple non-H-2 histocompatibility antigens. III. Single histocompatibility antigens dominate the male antigen

Immunization of mice with multiple non-H-2 histocompatibility antigens results in the generation of cytolytic T lymphocytes that are specific for a limited number of immunodominant antigens. The experiments presented in this communication were designed to reveal immunodominance in pairwise combinations of autosomal and sex-linked non-H-2 histocompatibility (H) antigens. Priming and boosting responders with the male antigen, H-Y, paired with the H-4.2, H-7.1, or H-3.1 antigens, resulted in the generation of cytolytic T cells specific for the autosomal H antigens but not the H-Y antigen. Furthermore, co-immunization and boosting of C57BL/6 female responder spleen cells with BALB.B male cells resulted in the generation of cytolytic T cells specific for the BALB.B immunodominant antigens but not H-Y. No dominance was observed in H-4-plus H-7-incompatible combinations. Co-immunization of three different H-3 congenic strains with H-3.1 plus H-Y demonstrated that an efficient anti-H-3.1 T cell response is required for observing H-3.1 immunodominance over H-Y. Co-expression of H-3.1 and H-Y on the same priming and boosting cells was required for immunodominance. In fact, immunization with H-3.1 and H-Y presented on different cells resulted in normal generation of H-Y-specific cytolytic T cells, but no generation of H-3.1-specific cytolytic T cells resulted unless H-Y-specific cells were stimulated in the mixed lymphocyte cultures. These observations suggest that in vitro T cell responses to paired, non-H-2 H antigens may be independent, competitive, or synergistic, depending on the identity of the antigens and the priming and boosting conditions.     

CTL and serologically defined antigens of B2m,H-3 region

The antigens of the B2m,H-3 region of 13 chromosome 2 congenic strains and seven inbred strains have been studied by using CML and serologic techniques. Nine patterns of cross-reactivity have been defined by CML assays. These results are in agreement with an extend previously described cross-reactivity studies. The reactivities of three monoclonal antibodies previously thought to be reacting with B2M-B are shown to differ: Ly-m11 and J-5 react with cells of strain B10-pa,at and clone 23 does not. Two H-3 region loci are hypothesized on the basis of CML and serologic activity: B2m and H-3. The CTL responses to the B2M antigens are H-2K restricted; the CTL responses to H-3 antigens are H-2D restricted. The restriction of the response to the H-3 antigen requires effector-target identity of the H-2D molecule but not the B2M molecule of the class I antigen. These loci have been separated by recombination from H-42 in the production of the congenic strain B10.FS-a. A gene order of B2m, H-3, H-42 is suggested.     

Immunodominance in the immune response to “multiple” histocompatibility antigens

Cytotoxic effector T cells putatively specific for multiple non-H-2 histocompatibility (H) antigens were generated by immunizing and boosting C57BL/6 and B6.C-H-2 ^dmice with BALB.B and BALB/c stimulator cells, respectively. The generated effectors were tested for cell-mediated lympholysis on a panel of targets whose BALB/c-derived non-H-2 H antigens were donated by CXB recombinant inbred mice. The spectrum of reactivity of cytotoxic effector T cells with CXB targets demonstrated that the effectors did not recognize multiple H antigens but rather preferentially recognized a single immunodominant non-H-2 H antigen. The identity of the immunodominant H antigen was determined by the H-2 genotype of the stimulator cells when (B6 × B6.C-H-2 ^d)F ₁ cytotoxic effectors were tested. These observations indicate that despite the fact that responders were challenged with more than 40 individual non-H-2 H antigens, they preferentially responded to a single immunodominant antigen.     

Endogenous xenotropic murine leukemia virus-related sequences map to chromosomal regions encoding mouse lymphocyte antigens.

DNAs of all inbred mouse strains contain multiple copies (18 to 28 copies per haploid mouse genome) of endogenous xenotropic murine leukemia virus-related sequences detectable by Southern analysis with a xenotropic murine leukemia virus env gene-specific probe. After PvuII digestion, we identified a subset of xenotropic murine leukemia virus-related sequences that are well resolved by agarose gel electrophoresis and can be mapped to specific chromosomes by using recombinant inbred mouse strains. Interestingly, three of six xenotropic proviral loci that we mapped were integrated near genes encoding mouse lymphocyte antigens (Ly-m22, chromosome 1; Ly-m6, chromosome 2; and Ly-m10, chromosome 19) and a fourth xenotropic proviral locus mapped near a gene on chromosome 4 that has a major influence on xenotropic virus cell surface antigen levels. These studies indicate that xenotropic proviral loci are located on many different mouse chromosomes and may be useful markers for molecularly cloning and characterizing regions of the mouse genome important in lymphocyte development.     

Distributions of single nucleotide polymorphisms in differential chromosome segments of congenic resistant strains that define minor histocompatibility antigens

Minor histocompatibility antigens (MiHAs) stimulate the rejection of allografts when donors and recipients are matched at the major histocompatibility complex (MHC). The majority of identified autosomal MiHAs were generated by non-synonymous (NS) substitutions that alter MHC class I-binding peptides. The mosaic distribution of single nucleotide polymorphisms (SNPs) that distinguish inbred mouse strains led us to hypothesize that MiHA genes defined by congenic strains on C57BL/6 and C57BL/10 backgrounds map to chromosomal regions with relatively high numbers of NS SNPs that distinguish C57 strains from other common inbred strains. To test this hypothesis, we mapped the ends of differential chromosome segments of congenic strains, which define 12 MiHAs, relative to microsatellites and SNPs. The lengths of differential segments ranged from 9.7 to 105.9 Mbp in congenic strains where no attempts were made to select recombinants within these segments. There was no apparent correlation between differential segment length and number of backcrosses, suggesting that factors other than the number of opportunities for recombination affected the differential segment lengths in these congenics. These differential segments included higher numbers of NS SNPs that distinguish C57BL/6J from A/J, DBA/2J, and 129S1/J than would be predicted if these SNPs were uniformly distributed along the chromosomes. The most extreme case was the H8 congenic that included 74% of the SNPs on chromosome 14 within its 9.7-11.1 Mbp differential segment. These results point toward a direct relationship between the level of genomic divergence, as indicated by numbers of NS SNPs, and numbers of MiHAs that collectively determine the magnitude of allograft rejection.     

Genetic dissection of intermale aggressive behavior in BALB/cJ and A/J mice

Aggressive behaviors are disabling, treatment refractory, and sometimes lethal symptoms of several neuropsychiatric disorders. However, currently available treatments for patients are inadequate, and the underlying genetics and neurobiology of aggression is only beginning to be elucidated. Inbred mouse strains are useful for identifying genomic regions, and ultimately the relevant gene variants (alleles) in these regions, that affect mammalian aggressive behaviors, which, in turn, may help to identify neurobiological pathways that mediate aggression. The BALB/cJ inbred mouse strain exhibits relatively high levels of intermale aggressive behaviors and shows multiple brain and behavioral phenotypes relevant to neuropsychiatric syndromes associated with aggression. The A/J strain shows very low levels of aggression. We hypothesized that a cross between BALB/cJ and A/J inbred strains would reveal genomic loci that influence the tendency to initiate intermale aggressive behavior. To identify such loci, we conducted a genomewide scan in an F2 population of 660 male mice bred from BALB/cJ and A/J inbred mouse strains. Three significant loci on chromosomes 5, 10 and 15 that influence aggression were identified. The chromosome 5 and 15 loci are completely novel, and the chromosome 10 locus overlaps an aggression locus mapped in our previous study that used NZB/B1NJ and A/J as progenitor strains. Haplotype analysis of BALB/cJ, NZB/B1NJ and A/J strains showed three positional candidate genes in the chromosome 10 locus. Future studies involving fine genetic mapping of these loci as well as additional candidate gene analysis may lead to an improved biological understanding of mammalian aggressive behaviors.     

The genetic origin of minor histocompatibility antigens

The purpose of this study was to elucidate the genetic origin of minor histocompatibility (H) antigens. Toward this end common inbred mouse strains, distinct subspecies, and species of the subgenus Mus were examined for expression of various minor H antigens. These antigens were encoded by the classical minor H loci H-3 and H-4 or by newly identified minor H antigens detected as a consequence of mutation. Both minor H antigens that stimulate MHC class I-restricted cytotoxic T cells (Tc) and antigens that stimulate MHC class II-restricted helper T cells (Th) were monitored. The results suggested that strains of distinct ancestry commonly express identical or cross-reactive antigens. Moreover, a correlation between the lack of expression of minor H antigens and ancestral heritage was observed. To address whether the antigens found on unrelated strains were allelic with the sensitizing minor H antigens or a consequence of antigen cross-reactivity, classical genetic segregation analysis was carried out. Even in distinct subspecies and species, the minor H antigens always mapped to the site of the appropriate minor H locus. Together the results suggest: 1 minor H antigen sequences are evolutionarily stable in that their pace of antigenic change is slow enough to predate subspeciation and speciation; 2 the minor H antigens originated in the inbred strains as a consequence of a rare polymorphism or loss mutation carried in a founder mouse stock that caused the mouse to percieve the wild-type protein as foreign; 3 there is a remarkable lack of antigenic cross-reactivity between the defined minor H antigens and other products.     

Induction and characterization of minor histocompatibility antigens. Specific primary cytotoxic T lymphocyte responses in vitro

A definite cytotoxic activity was developed in a BALB/c (H-2d) anti-DBA/2 primary mixed leukocyte culture (MLC), which received interleukin 2 (IL-2) on day 3 of culture. This cytotoxic activity was minor histocompatibility antigens (MIHA)-specific at the stimulator level, and was not developed in a syngeneic (BALB/c anti-BALB/c) MLC. The addition of IL-2 on day 3 of culture was crucial; no or very weak cytotoxic activity was developed in MLC receiving IL-2 on day 0 or on both day 0 and day 3. Only appropriate MIHA-allogeneic tumor cells were lysed as the target of the cytotoxic activity. The cytotoxic activity seemed MIHA-specific also at the target level; it lysed tumor cells of DBA/2 mouse origin but not those of BALB/c (syngeneic) origin. Phenotypes of the cytotoxic effector cell were Thy-1+ Lyt-2+. We concluded from these results that MIHA-specific cytotoxic T lymphocytes (CTL) were generated in the MIHA-allogeneic primary MLC. In this newly developed system, we studied genetic and antigenic requirements for primary anti-MIHA CTL responses in vitro. We demonstrated; among spleen cells (SC) of seven B10 H-2-congenic strains only SC of B10.D2 strain whose major histocompatibility complex (MHC) (H-2d) was compatible with the responder MHC effectively stimulated responder BALB/c (H-2d) SC for an anti-MIHA (DBA-C57BL-common) CTL response. Similarly, only SC of two out of seven C x B recombinant inbred strains (C x B.H and C x B.D), which were compatible at the MHC with responder SC, activated responder BALB/c SC for the response. The possibility that cells responding to H-2 alloantigens suppressed the anti-MIHA response was ruled out. Additional experiments showed that compatibility at the H-2K-end or the H-2D-end of the MHC was sufficient for a definite anti-MIHA response. These provided formal evidence that primary anti-MIHA CTL responses in vitro were MHC-restricted at the stimulator level. We then showed that sonication-disrupted SC or Sephadex G-10 column-passed nonadherent SC failed to stimulate responder SC for a primary anti-MIHA CTL response, whereas G-10-passed nonadherent SC responded well to adherent stimulator cells. Further study demonstrated that Ia+ adherent cells were the most active cell type as stimulator. Finally, we confirmed that the primary anti-MIHA CTL responses to adherent stimulator cells was MHC-restricted.     

Restriction in adoptive transfer of resistance to Listeria monocytogenes. I. Influence of non-H-2 loci

In vivo adoptive transfer of T-cell-mediated immunity to the facultative intracellular bacterium Listeria monocytogenes is restricted, not only by the H-2 haplotype of the mice, but also by incompatibilities at non-H-2 loci. Thus, transfer between H-2 identical strains of mice with different background genes was reproducibly and significantly less efficient than transfer between completely syngeneic mice, although the restriction was less marked than that across the H-2 barrier. Restriction also occurred when parental cells were injected into semisyngeneic F1 hybrids and when cells from F1 hybrids were injected into parental strains. Using congenic strains of mice differing only at defined minor histocompatibility antigens, it was found that, of those loci available for study, antigens arising from the H-4 and H-8 loci strongly restricted transfer, whereas those specified by H-1, H-3, and H-7 did not.     

A pseudogene homologous to mouse transplantation antigens: Transplantation antigens are encoded by eight exons that correlate with protein domains

We have isolated about 30 to 40 different BALB/c mouse sperm DNA genomic clones that hybridize to cDNA clones encoding proteins homologous to transplantation antigens. One of these clones (27.1) was selected for sequence analysis because it was polymorphic in Southern blot analyses of the DNAs from BALB/c and CBA mice. A fragment of 5.7 kilobases of this clone was completely sequenced and found to contain a pseudogene whose sequence is highly homologous to the sequences of known transplantation antigens. Pseudogene 27.1 is split into eight exons that correlate with the structurally defined protein domains of transplantation antigens. Using Southern blot hybridization on the DNAs of different inbred mouse strains, we mapped the pseudogene to the Qa-2,3 region, a part of the Tla complex on chromosome 17 that is adjacent to the major histocompatibility complex. The Qa-2,3 region encodes lymphoid differentiation antigens homologous to the transplantation antigens in size, in peptide map profiles and in their association with β2-microglobulin. These mapping studies suggest that gene 27.1 may be a pseudogene for either a Qa antigen or an as yet undefined transplantation antigen. Accordingly, we may have isolated genes encoding lymphoid differentiation antigens of the Tla complex as well as those encoding transplantation antigens among the 30 to 40 different genomic clones isolated from our sperm library.     

Immunodominance in the graft-vs-host disease T cell response to minor histocompatibility antigens

Immunodominance controls the generation of CTL in the C57BL/6By (B6) anti-BALB.B H-2b-matched strain combination. Despite the potential of responding to numerous individual minor histocompatibility (H) Ag on BALB.B APC, the focus of the CTL response is largely specific for only a limited number of target Ag. These minor H Ag could be distinguished by their differential expression on a panel of target cells from the CXB recombinant inbred strains, the E, G, I, J, and K (all H-2b), which express different composites of the original BALB minor H Ag. A hierarchy was observed in which first-order immunodominant Ag were present on both CXBK and CXBG cells, whereas second-order dominant Ag were found on CXBE, CXBJ, and CXBI cells. To test whether immunodominance also plays a role in the development of lethal graft-vs-host disease (GVHD) directed to multiple minor H Ag, B6 T cells were transplanted along with T cell depleted bone marrow, to irradiated (825 rad) recipients of either the BALB.B or CXB recombinant inbred strains. The results indicate that a hierarchy of immunodominance does exist in GVHD, but it differs from that predicted from the in vitro CTL studies. GVHD was observed in BALB.B, CXBE, CXBI, and CXBJ recipients, but not in CXBG and CXBK recipients. Presensitization of B6 donor mice to CXBG or CXBK splenocytes 3 wk before transplant did not significantly increase the overall GVHD potential in the corresponding CXBG or CXBK recipients. Evidence for second-order immunodominance was provided by the transfer of CXBE T cells and ATBM to irradiated CXBG and BALB.B recipients with resultant, potent GVHD.     

Non-H-2-linked genetic regulation of cytotoxic responses to hapten-modified syngeneic cells. I. Non-H-2-linked Ir gene defect expressed on T cells is not predetermined at the stage of bone marrow cells

Spleen cells from C3H/He or BALB.K mice immunized to the newly synthesized amino-reactive hapten 5-sulfo-1-naphthoxy acetic acid N-hydroxysuccinimide ester (AED-NH2) were stimulated in vitro with AED-NH2-modified syngeneic cells. After 5 days of culture, effector cells were assayed for their cytotoxic activity against AED-NH2-modified target blast cells. C3H/He and BALB.K mice exhibited the respective high and low anti-AED-NH2 cytotoxic T lymphocyte (CTL) responses. This contrasted with the observation that both of these H-2k strains generated potent CTL responses against aminoreactive haptens, e.g., trinitrophenyl (TNP). Because C3H.SW and BALB.B strains, which are the H-2b counterpart of the above two strains, also represented the respective high and low responders to AED-NH2 hapten, this hapten model enabled us to investigate cellular mechanisms underlying the above non-H-2-associated genetic regulation of CTL responses (C3H vs BALB non-H-2 backgrounds). The results demonstrated that there was no detectable difference between C3H/He and BALB.K strains in the lysability of target cells and the ability of stimulating cells to activate primed spleen cells. Anti-AED-NH2 CTL responses were only marginal when antigen-presenting cells (APC) were eliminated from the primed spleen cells of high responder C3H/He or (C3H/He X BALB.K)F1 mice. The addition of APC to cultures free of APC regained an appreciable CTL response in C3H/He or (C3H/He X BALB.K)F1 mice, irrespective of whether APC were derived from high (C3H/He) or low (BALB.K) responders. We have also demonstrated that allogeneic radiation bone marrow chimera (BALB.K----C3H/He) exhibited a CTL response comparable to that induced by C3H/He mice, whereas the reverse direction of allogeneic chimera (C3H/He----BALB.K) induced a marginal CTL response. These results indicate that this non-H-2-associated Ir gene defect is expressed on T cells (CTL precursors and/or helper T cells) rather than APC, and that this T cell defect is not predetermined at the level of bone marrow cells. The results are discussed in the light of the genetic and cellular mechanisms underlying non-H-2-linked Ir gene control.     

Non-H-2 histocompatibility antigens encoded by Moloney-murine leukemia virus in Mov mouse strains are detectable by skin grafting and cytolytic T lymphocytes

The integration and expression of Moloney-murine leukemia virus (M-MuLV) into the germ line of Mov mouse strains on the C57BL/6 background results in the expression of a cell-surface Ag with characteristics expected from non-H-2 histocompatibility Ag: the ability to stimulate graft rejection and generation of CTL. However, both the previously studied Mov-3 and Mov-14 strains differ from the coisogenic C57BL/6 strain by different length segments of chromosome derived from the ICR strain in addition to the integrated M-MuLV genome. To conclusively demonstrate that an Ag encoded by M-MuLV is solely responsible for rejection of Mov skin grafts by coisogenic recipients, we have studied additional Mov strains that differ from coisogenic 129 or BALB/c backgrounds only by integration of an M-MuLV genome. A total of 129 strain recipients reject skin grafts from two viremic Mov strains, Mov-17 and Mov-18. A total of 129 strain hosts primed with either 1) multiple sets of Mov-17 and Mov-18 skin grafts or 2) single injections of Mov-17 and Mov-18 spleen cells produce M-MuLV-specific CTL that could be boosted in primary mixed lymphocyte culture. Generated CTL were reactive with Con A-stimulated lymphoblasts from all tested viremic Mov strains on the B6 and 129 backgrounds as well as B6 lymphomas. Further, we have observed that 129 strain mice reject Mov-9 skin grafts if these skin grafts are transplanted to virgin 129 recipients which have not received prior skin grafts from non-viremic Mov donors. In addition, skin grafts were transplanted from two viremic Mov strains, Mov-15 and Mov-16, to coisogenic BALB/c recipients; rejection of both sets of grafts was observed. However, BALB/c responders did not generate specific CTL after priming in vivo, with either multiple sets of allogeneic grafts or spleen cell injections, and boosting in vitro. These observations confirm the ability of integrated and expressed M-MuLV genomes to encode what is operationally defined as a non-H-2 histocompatibility Ag.     

Hybrid resistance to BALB/c plasmacytomas. I. Resistance to MPC-11 controlled by a locus not linked to H-2.

Genetic control of hybrid resistance to the BALB/c plasmacytoma MPC-11 was investigated. The results indicate that a single dominant autosomal gene or gene complex, which segregates independently of H-2 and the coat color c and b-loci, controls resistance to this tumor. This gene has the same strain distribution pattern in the CXB Bailey recombinant inbred strains as three unlinked genes, H-2, Ly-4, and Ea-4. It is possible, therefore, that it could be linked to either of the latter two loci. Strains that carry a positive allele for resistance are C57BL/10 and all of its congenic resistant partners tested, C57BL/6, C57L, C57BL/Ks, AKR, and DBA/1. BALB/c and its congenic resistant partners are presumed to carry a negative allele of the gene for resistance to MPC-11. Strains such as SJL, DBA/2, and A and its congenic resistant partners, which form susceptible hybrids with BALB/c, could carry either the negative allele of the gene for resistance, like BALB/c, or could carry both a positive allele of the gene and some other gene conferring susceptibility on the hybrids. Heterozygosity within the H-2 complex increases resistance only in the presence of this non-H-2 linked gene for resistance, and the effect maps to the left of the H-2D region.     

Strain-dependent IgG subclass response patterns

Previous studies have shown that antigens preferentially stimulate IgG subclasses. However, the immunologic processes responsible for the patterns of IgG subclasses stimulated by antigens are probably complex and are certainly unclear. To define some of the genetic controls of IgG subclass expression in mice, we have studied the patterns of IgG subclasses elicited by antigens in BALB/cAn, C57BL/6N, derived recombinant inbred strains, and derived Ig congenic strains. This study shows that both thymus-independent antigens and thymus-dependent antigens stimulate different patterns of IgG subclasses in BALB/cAn and C57BL/6N. Furthermore, analysis using recombinant inbred strains and Ig congenic strains shows that the patterns of IgG subclasses stimulated by all antigens are linked to Ig allotype. In contrast, only the IgG subclass patterns stimulated by thymus-dependent antigens are linked to major histocompatibility complex haplotype. This study also shows that the Ig allotype-linked controls of IgG subclass response patterns are located telomeric to a BAB14 intra-heavy chain variable region recombinant site. Therefore, this region of mouse chromosome 12 may contribute to the control of IgG subclass selection in the B cell.     

Genetic regulation of the antibody response to H-2Db alloantigens in mice. IV. Antigens that activate helper T cells for IgG, coded for by the non-H-2 genome

When B10.A(5R) mice are immunized with congenic C57BL/10 cells only 2-ME-sensitive antibodies (IgM type) are found directed against H-2Db. To obtain 2-ME-resistant antibodies (IgG type) 5R mice must be immunized with noncongenic cells (e.g., A.BY); in this case non-H-2 cell surface antigens will activate helper T cells to induce anti-Db IgG antibody production by B cells. An attempt was made to define helper antigens that activate helper T cells. Neither N-2 antigens of seven H-2Db recombinant strains nor a limited set of non-H-2 cell surface antigens were able to serve as helper antigens. By using individual backcross mice as antigen, one helper antigen was found on the background of strain A under the conditions used, whereas other backgrounds may carry more than one antigen. The helper antigen is dominantly expressed in F1 mice and has to be presented on the same cell as H-2Db to induce the switch from IgM to IgG.     

A new cross-reactive idiotype-defined family in the phthalate humoral immune response of mice. I. Linkage of VH-Xmp to IgCH allotype locus and mapping with respect to other known VH genes

A cross-reactive idiotype family was previously identified from a very large library of phthalate-specific hybridoma clones. The prototype of this idiotype family is the hybridoma, 2E9, secreting an IgM antibody with phthalate specificity. A portion of both primary and secondary anti-phthalate antibodies elicited in all BALB/c mice tested expresses the 2E9 cross-reactive idiotype. This idiotype has now been found in the anti-phthalate antibodies of several other inbred strains of mice (A/HeHa, DBA/2, and C3Hf/HeHa) tested but not in C57BL/6 mice. Anti-phthalate antibodies elicited from congenic mice BC.8, which express the same IgCH allotype as BALB/c mice but possess C57BL/6 genetic background, contain the 2E9 cross-reactive idiotype, whereas this idiotype is not expressed on the anti-phthalate antibodies derived from another congenic mouse CB.20, which expresses a C57BL/6 IgCH allotype and a genetic background of the BALB/c strain. These results indicate that the gene controlling the 2E9 idiotype is closely linked to the IgCH allotype locus. The 2E9 cross-reactive idiotype was also found in all of the F1 mice (BALB/c X C57BL/6) tested, and the level of expression of this idiotype in the F1 mice was quantitatively equivalent to the allotype/idiotype homozygous mice. The expression of the 2E9 idiotype in the phthalate repertoire has been followed in 12 different wild mouse populations. As expected, the 2E9 idiotype was observed in a large proportion of the wild mouse strains. Surprisingly, several examples of nonconcordance in the expression of idiotype and allotype were observed in these mice. One likely explanation for the linkage breakdown is a crossing over of the heavy chain constant and variable region gene complexes. In the SM/J inbred strain of mice, where such a crossover has occurred, nonconcordance between allotype and 2E9 idiotype expression was demonstrated. By using the recombinant inbred BXD strains of mice, the VH gene encoding the 2E9 idiotype has been mapped with respect to other known VH gene families. Relative to other VH genes the VH-Xmp is situated very close to the IgCH gene region.     

Mouse H2 congenic intervals: analysis and use for mapping

In this study we exploit the unique genetic resource of inbred mouse major histocompatibility complex (H2) congenic and recombinant strains to construct a high-resolution map of microsatellite loci in and around the H2 region, as well as an independent genetic map of other loci on mouse Chromosome (Chr) 17. Microsatellite loci were analyzed in 11 C57BL/10 (B10) strains to determine the size of the congenic interval in each. The length of the congenic interval found in each strain varied widely. Interestingly, the intervals were generally smaller than statistical expectations. However, the observed congenic intervals were still sufficiently long that these strains and probably wild-derived H2 congenics are an important source of genetic variability. The staggered ends of the various congenic intervals and the recombinants were used to construct the map. This map will be useful for physical cloning and to help localize novel genes. As evidence of the mapping application of congenic strains, locational information was derived about Trp53-ps and Stl.Deceased, Aug. 8, 1994.