Additional mapping of mouse chromosome 2 genes

The purpose of this work was to elucidate the genetic fine structure of the central portion of mouse chromosome (Chr) 2. Seven Chr 2 congenic mouse strains [B10.PA(L)-pa we un a ^t , B10.PA(L)-pa A ^w , B10.PA(L)-we un a ^t , B10.PA(J)-pa a, B10.FS-we A ^w , B10.C-we A ^w , and B10.YBR-a] were produced. Breeding studies were carried out using strains B10.PA(L)-pa we un a ^t and B10.LP-H-13 ^b to accurately determine the recombination frequencies between marker genes pa and we (1.9%±0.3), we and un (8.8%±0.5), and un and a ^t (4.5%±0.4) of strain B10.PA(L)-pa we un a ^t . These strains and other Chr 2 congenic strains were typed for immunologically defined loci using monoclonal antibody (mAb) C23 reactive with the gene product of B2m ^b T-lymphocyte clone C1 reactive with the gene product of H-3 ^a and H-3 ^c , and lymphocyte clone H1.8 reactive with the gene product of Hd-1 ^a . B2m and H-3 typing located a recombinational event separating [pa B2m H-3] from we (the order of bracketed genes is not known). Hd-1 typing indicated that Hd-1 maps distal to [H-42, H-44] and proximal to un. The gene order [pa, B2m, H-3], we, [H-42, H-45], Hd-1, un, H-13, a ^t , with H-44 mapping centromeric to Hd-1, is indicated by the data. Address correspondence and offprint requests to: R. J. Graff.     

MHC recognition by clones of Mls specific T-lymphocytes

To test whether M1s determinants, like other non-MHC or nominal antigens, are recognized by T-cells in association with H-2 determinants, the in vitro proliferative responses of T-cell lines and clones were studied. Lines and clones were prepared by soft agar cloning (B10.BR x BALB/c)F₁ (H-2^k/H-2^d, M1s^b/M1s^b) T-cells responding in a primary MLR to AKD2F1 (H-2^k/H-2^d, M1s^a/M1s^a) stimulator cells. All the T-cell clones obtained could respond equally well in a proliferative assay to the Mls^a determinant in association with the H-2 haplotype of either parent, i. e., DBA/2 (H-2^d, M1s^a), and AKR (H-2^k, M1s^a) both stimulated equally well. When the T-cell lines and clones were screened against stimulators from recombinant inbred (RI) strains, it became apparent that strains exhibiting the H-2^b, M1s^a genotype stimulated poorly or not at all. This shows that the T-cell response to M1s^a involves MHC recognition, and raises the possibility that the response to M1s^a can involve recognition of H-2 specificities shared between the H-2 ^k and H-2 ^d haplotypes.Abbreviations used in this paper MHC major histocompatibility complex - MLC mixed lymphocyte culture - IL-2 interleukin 2 - Con A concanavalin A - RI recombinant inbred Howard Hughes Medical Institute     

Soluble Mlsa antigens: Stimulatory effect in vitro versus suppressive effect in vivo

Using a pair of congenic strains of mice differing only at the Mls haplotype (Mls locus and closely linked genes), BALB/c (Mls ^b ) and BALB.D2-Mls ^a , we have compared the in vitro proliferative responses of M1s^b lymphocytes to M1s^a antigens presented on either lymph node cells (LNC) or peritoneal adherent cells (PAC). Results showed that M1s^a-PAC are stronger stimulators than M1s^a-LNC, and furthermore, that the supernatant from M1s^a-PAC may be effective in eliciting a lymphocyte proliferative response. The proliferation in response to PAC supernatant is partially due to activation by nonspecific factor(s); however, the response in the presence of M1s^a incompatible PAC supernatant is about three times greater than the response obtained in the presence of syngeneic M1s^b-PAC supernatant, suggesting an additional stimulation by soluble M1s^a antigens. Contrasting with the ability of PAC-supernatant to stimulate a primary proliferative response in vitro, the in vivo immunization of Mls^b mice with M1s^a-PAC supernatant abrogates the specific proliferative response in subsequent one-way mixed lymphocyte cultures. This abrogation of the specific response is comparable to that observed after immunization with intact M1s^a peritoneal or spleen cells, although in the latter case the anti-H-2 proliferative response is also decreased, regardless of whether the H-2 incompatible stimulating cells express an additional incompatibility for M1s^a. The proliferation of untreated, but not of M1s^a-immunized BALB/c LNC, is stronger in cultures with DBA/2 stimulating cells (incompatible for M1s^a and other non-H-2 antigens) than in cultures with BALBM-Mls ^a cells (incompatible for M1s^a alone), and is comparable in intensity to that activated by H-2 incompatibility. We conclude that M1s^a antigens are more efficiently recognized by unprimed helper T cells when presented on PAC than when presented on LNC. In the primary proliferative response, the effects of M1s^a and other non-H-2 antigens may be cumulative. In vivo immunization against M1s^a antigens results in suppression of the specific proliferative response and, to a certain extent, of the nonspecific proliferative response (directed against both H-2 and other non-H-2 antigens). Since M1s^a antigens are obtainable in soluble form, their physicochemical purification can now be envisaged.     

Responses against antigens encoded by theH-3 histocompatibility locus: Antigens stimulating class I MHC- and class II MHC-restricted T cells are encoded by separate genes

The purpose of this work was to study the genetic basis of histocompatibility antigens encoded by the mouse minor histocompatibility (H) locusH-3. Both class I major histocompatibility complex (MHC)-restricted cytotoxic T lymphocytes (CTL) and class II MHC-restricted helper T cells (TH) specific for antigens encoded by genes within theH-3 locus were isolated and analyzed. Typing a number of mouse strains for expression of antigens recognized by these TH and CTL suggested that there was a different strain distribution pattern of expression of the antigens recognized by TH compared with those recognized by CTL. Separation of the genes whose products stimulate TH from those whose products stimulate CTL was suggested by: (1) analysis of the strain B10.FS(92NX)/Grf that has undergone recombination within theH-3 region; (2) genetic segregation studies of (B10.UW-H-3 ^b/Sn×C57BL/10Sn)F₂ mice; and (3) F₁ complementation studies in which CTL specific for products of the TH-defined gene(s) could not be detected, even in the absence of immune responses to products of the CTL-defined genes. Taken together, these data suggest that in addition to two genes (B2m andCd-1) within theH-3 region whose products typically stimulate class I MHC-restricted CTL, there is at least one additional gene whose product selectively stimulates class II MHC-restricted TH. This new gene is located telomeric from the CTL-defined genes and between the lociwe andun on chromosome 2. These data demonstrate a novel degree of complexity of theH-3 “locus” and suggest selective presentation of minor H gene products in the context of class I or class II MHC proteins.     

High-resolution mapping of a minor histocompatibility antigen gene on mouse chromosome 2

Minor histocompatibility (H) loci are significant tissue transplantation barriers but are poorly understood at the genetic and molecular level. We describe the construction of a high-resolution genetic map that positions a class II MHC-restricted minor H antigen locus and orders 12 other genes and genetic markers within the we-un interval of mouse Chromosome (Chr) 2. An intersubspecific backcross between 10.UW/Sn-H-3 ^b and CAST/Ei, an inbred stock of Mus musculus castaneus, was used for this purpose. A total of 1168 backcross mice were generated, and 71 we-un recombinants were identified. Significant compression of the genetic map in males versus females and transmission distortion of CAST-derived we, un, and A ^w genes were observed. Monoclonal T cell lines specific for two minor H alloantigens, Hd-1^a and Hd2^a, encoded by gene(s) that map to the we-un interval were used to antigen type the backcross mice. The results suggest the Hd-1^a and Hd-2^a antigens are most likely encoded by a single gene, now referred to as H-3b. The determined gene order is we-0.09±0.09-Itp-0.62±0.23-D2Mit77-0.26±0.15[Evi-4, Pcna, Prn-p]-0.26±0.15-Scg-1-0.44±0.19-[Bmp2a, D2Mit70]-0.09±0.09-[D2Mit19, D2Mit46]-1.59±0.36-D2Mit28-0.97±0.28-D2Lerl-1.50±0.35-H-3b-0.26±0.15-un (% recombination±1 SE). Because the average resolution of the backcross is 0.09 cM, the backcross panel should facilitate the physical mapping and molecular identification of a number of genes in this chromosome region.     

Genetic and functional analyses of the primary in vitro CTL: Response of NZB lymphocytes toH-2-compatible cells

Spleen cells from NZB mice make an unexpected primary cytotoxic T lymphocyte (CTL) response to BALB/c cells in vitro. In this study, it is shown that this response is comprised of at least three independent components. These include a response to antigens recognized in association with H-2^d products, a response to Qa-1^b-associated antigens which is notH-2-restricted and a response directed toward antigens not associated with either H-2^d- or Qa-1^b-coded determinants. The last response appears to be the weakest of the three. In addition, cells from NZB F₁ mice which were either homozygous (Qa-1 ^a /Qa-1 ^a ) or heterozygous (Qa-1 ^a /Qa-1 ^b ) forQa-1 alleles, all responded to BALB/c cells. These data suggest that the NZB CTL response to BALB/c cells is not solely dependent on antigens coded for by genes in theH-2D-Tla region for either the sensitization or effector phases of the response. The ontogeny of the NZB anti-BALB/c CTL response coincides with that of a number of B-cell abnormalities but is shown in experiments with-suppressed NZB mice to be independent of B-cell dysfunction. Studies with (NZB x B10.D2)F₁ + B10.D2 mice demonstrated that the anti-BALB/cCTL response to antigens coded for outside ofQa-1 is governed by at least two genes. Finally, it is shown that another conventionallyH-2-restricted response, that to TNP-modified isologous cells, is neither significantly cross-reactive nor markedly elevated in NZB mice. — The foregoing observations suggest that some subsets of NZB T lymphocytes are intrinsically abnormal. The possibilities that the apparent hyperreactivity of NZB CTL precursors, evidenced in the response to BALB/c cells, is primary or results from the secondary effects of excess T-cell help are discussed.     

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.     

Organization and chromosomal locations of Rap1a/Krev sequences in the mouse

The human RAP1A gene encodes a protein that apparently can antagonize the function of oncogenic ras genes in gene transfer experiments, but its normal function is unknown. To understand the function of this gene, we have undertaken a study of the mouse homolog, Rap1a. The complete coding sequence of a mouse Rap1a cDNA has been determined, and genomic clones representing three distinct Rap1a species were recovered. We find that Rap1a is located on distal mouse Chromosome (Chr) 3 near Nras, Ampd-1, Tshb, Ngfb, and Atp1a1. Two related sequences (Rap1a-rs1 and Rap1a-rs2) were also characterized. Rap1a-rs1, which was not localized, has a sequence very similar to the Rap1a cDNA, suggesting that it has been recently acquired by the mouse genome. Rap1a-rs2 is more distantly related to the gene sequence and is located on Chr 2 near Actc-1.     

Chromosomal locations of the mouse fatty acid oxidation genes Cpt1a, Cpt1b, Cpt2, Acadvl, and metabolically related Crat gene

Mitochondrial β-oxidation of long-chain fatty acids (LCFA) is essential for mammalian life. Because portions of this metabolic pathway are composed of enzymes that are coordinately regulated and share structural and functional similarities, we evaluated five of these enzyme genes for possible chromosomal linkages. Regulation of LCFA catabolism influences cell signal pathways and apoptosis, as well as energy production from LCFA. Partial cDNA fragments of the mouse mitochondrial proteins carnitine acetyltransferase (Crat), very-long-chain acyl coenzyme A dehydrogenase (Acadvl), the liver and muscle isoforms of carnitine acyltransferase I (Cpt1a and Cpt1b respectively), and a genomic PCR product of mitochondrial protein carnitine acyltransferase II (Cpt2) were used in a previously established mapping panel to determine their chromosomal locations. No pseudogenes were detected for any of the genes in Mus musculus, and all of the genes mapped to different chromosome locations, including the tissue-specific isoforms of carnitine palmitoyltransferase. Crat mapped to Chromosome (Chr) 2, at a position approximately 18 cM from the centromere and 2 cM proximal to the gene Ass1. Acadvl mapped to the middle of Chr 11, 8.3 cM distal to Il4 and 2.8 cM proximal to Mpmv2. Cpt1a mapped to the centromeric region of Chr 19, 8.7 cM proximal to Pomc-ps1. Cpt1b mapped to Chr 15, 4.9 distal to Gpt1 and 3.5 cM proximal to Wnt1. Cpt2 mapped to Chr 4 near the locus Pmv19. Received: 29 January 1998 / Accepted: 25 March 1998     

H-2-linked genes determine the level of the primary in vitro anti-Mls response

The level of cell proliferation and interleukin-2 (IL-2) production observed in an anti-Mls mixed lymphocyte reaction between spleen cells from H-2 compatible, Mls incompatible mouse strains is determined by the H-2 haplotype of the mouse combination. Thus, while AKR (H-2 ^k) spleen cells stimulated strong M1s^a responses in H-2^k responder cells, AKR H-2b spleen cells stimulated no or negligible M1s^a responses in responder cells from H-2 ^bmouse strains. This effect was observed at the levels of IL-2 production and cell proliferation. The magnitude of the response observed using F₁ (H-2 ^k/H-2 ^b) responder cells was found to be a function of stimulator rather than responder cells. The poor stimulatory capacity of AKRH-2 ^bspleen cells was also shown not to be due to the loss of the stimulatory Mls ^aallele during the construction of the congenic strain from AKR and C57BL/6 parental strains. Using stimulator cells from a second series of congenic mice, we found H-2 ^b(strain DLLP) again to represent a poorly Mls^a stimulatory H-2 haplotype. In addition, H-2^q (DBA/1) cells displayed very poor Mls^a stimulatory potential while H-2^d (D1.C) cells were efficient Mls^a stimulators. Again the effect was shown to be at the level of the stimulator cells. In toto, our findings indicate that the H-2 ^kand H-2 ^dhaplotypes encode strong Mls^a stimulatory potential while the H-2 ^band H-2 ^qhaplotypes determine poor Mls^a stimulatory potential in primary in vitro responses, measured as cell proliferation and IL-2 production.Abbreviations used in this paper: CTL cytotoxic T lymphocyte - IL-1 interleukin-1 - IL-2 interleukin-2 - MLR mixed lymphocyte reaction - NMS normal mouse serum     

Characterization of a new hybrid mink-mouse clone panel: chromosomal and regional assignments of the GLO,ACY, NP,CKBB, ADH2, and ME1 loci in mink (Mustela vison)

To expand the mink map, we established a new panel consisting of 23 mink-mouse clones. On the basis of statistical criteria (Wijnen et al. 1977; Burgerhout 1978), we developed a computer program for choice of clones of the panel. Assignments of the following mink genes were achieved with the use of the hybrid panel: glyoxalase (GLO), Chromosome (Chr) 1; acetyl acylase (ACY), Chr 5; creatine phosphokinase B (CKBB), Chr 10; alcohol dehydrogenase-2 (subunit B) (ADH2), Chr 8. Using a series of clones carrying rearrangements involving mink Chr 1 and 8, we assigned the gene for ME1 to the short arm of Chr 1 and that for ADH2 to Chr 8, in the region 8p12-p24. Mapping results confirm the ones we previously obtained with a mink-Chinese hamster panel. However, by means of an improved electrophoretic technique, we revised the localization of the gene for purine nucleoside phosphorylase (NP), which has been thought to be on mink Chr 2. It is reassigned to mink Chr 10.     

Influence of the H-2 u haplotype on immune function in F1 hybrid mice

Recently we reported that antigen-primed T cells from (H-2 ^u × H-2 ^s)F₁ and (H-2 ^u × H-2 ^q)F₁ mice responded poorly in vitro to antigen in the context of antigen-presenting cells of the non-H-2 ^u parent. It was suggested that this effect might be due to unbalanced expression of parental antigens in the F₁ hybrid with the result that the non-H-2^u A antigens were greatly reduced or absent in these mice. If this were the case, non-H-2^u Ia-A cells might be expected to stimulate a mixed lymphocyte reaction (MLR) when cultured with Fl responder cells. When tested, (SJL × PL)F₁ responder cells reacted strongly to SJL stimulator cells. There was no significant reaction to PL stimulator cells. The use of major histocompatibility complex (MHC) congenic mice showed the stimulatory antigens to be associated with the MHC. The MLR could be blocked significantly by monoclonal A-specific antibody of the appropriate specificity. When a monoclonal antibody reactivewith a private epitope associated with A^s was used to probe for the presence of A^s on the surface of (SJL × PL)F₁ spleen cells, no antigen could be detected, indicating loss or alteration of this antigen. These findings suggest that an alteration of the expression of the parental A^s molecule may be responsible for this phenomenon.Abbreviations used in this paper APC antigen-presenting cells - BSS balanced salt solution - CTL cytotoxic T lymphocyte - IL-2 interleukin-2 - MHC major histocompatibility complex - MLR mixed lymphocyte reaction - T₂ suppressor T lymphocyte     

Biochemical evidence for structurally distinct H-2Dd antigens differing in serological properties

H-2D^d antigens, as defined by the private H-2.4 determinant, exist as two immunochemically distinct populations in H-2^a and H-2^dm2 splenocytes and in the transformed cell line, RADA1(H-2 ^a). The two populations are distinguishable by the anti-H-2.28 serum, k/r anti-h2, which is directed, in part, against the H-2.28 family of public determinants encoded by the D end of the b haplotype. Sequential precipitates of lentil-lectin-purified glycoprotein extracts metabolically labeled with radioactive amino acids reveal that approximately one-quarter to one-third of the H-2D^d antigens, designated H-2D^d (b28 ⁺), react with this antiserum, whereas two-thirds to three-quarters, designated H-2D^d(b28^–), do not. Paired-label tryptic peptide maps in this and a previous study indicate that H-2D^d(b28⁺) and H-2D^d(b28 ^–) are closely related structurally and are more likely to represent modified forms of the same gene product rather than products of different genes, although the existence of closely related genetic loci is not rigorously excluded. Together, H-2D^d(b28⁺) and H-2D^d(b28^–) have a radioactivity level seven times higher than H-2L^d, which also reacts with the anti-H-2.28 serum but which lacks the H-2.4 determinant. As yet unresolved, however, is the question of whether the observed quantitative differences between these three antigens reflect actual molar differences at the cellular level, or whether the variation is the result of metabolic or compositional factors. In any case, a complex serological and structural relationship is found to exist between antigens encoded by the D/L end of the MHC.     

The production of Non-H-2 histocompatibility alloantibodies in the mouse

Alloantibodies specific for non-H-2 histocompatibility antigens of the mouse have been produced. Immunization (BALB/cJ×DBA/2J)F₁ anti-B10.D2/n was conducted, followed by hemagglutination, immunofluorescence, and mixed hemabsorption tests on absorbed and unabsorbed sera. The results indicate that antibodies specific for H-3^a and H-8^a antigens are present. In addition, H-8^a antigenic determinants were detected on erythrocyte membrane surfaces, as well as on cells of other body tissues.     

Multiple cytolytic T-cell clones with distinct cross-reactivity patterns coexist in anti-self + hapten cell lines

C57BL/10 T cells sensitized with TNBS-treated syngeneic cells and maintained in culture by repeated stimulations exhibit high cytolytic activity toward syngeneic TNBS-treated target cells with marked cross-reactivity on TNBS-treated target cells from mice of independent H-2 haplotypes (ten tested). The analysis of the reactivities of 48 T-cell clones derived by limiting dilution from such T-cell populations revealed three types of cytotoxic T-cell clones: (1) clones restricted by H-2K^b + TNP without cross-reaction on TNBS-treated or untreated target cells of other tested mouse haplotypes; (2) clones that lysed H-2^b + TNP and also TNBS-treated target cells from not more than one, two or three different H-2 haplotypes; (3) clones that lysed untreated H-2^k target cells. No T-cell clone was found to exhibit the wide pattern of cross-reactivity on any TNBS-treated mouse cell, characteristic of the original T-cell populations, indicating that these were composed of individual T-cell clones specific for TNP + private or for TNP + distinct public H-2 determinants. Correlation with described serological public H-2 specificities was possible for some cytotoxic T-cell clone reactivity, but not for others. The general pattern of T-cell reactivity as revealed by clonal analysis in this study, as well as in published work, includes cross-reactions between self H-2^a + X and allogeneic H-2ⁿ + X, between self H-2^a + X and unmodified allogeneic H-2ⁿ, or between allogeneic H-2ⁿ and allogeneic H-2^m + X, and is consistent with the hypothesis that MHC-class restriction is the main rule in T-cell recognition.Abbreviations used in this paper CTL cytotoxic T lymphocyte - TNBS trinitrobenzene sulfonate - TNP trinitrophenyl - TNCB trinitrochlorobenzene - H-2 mouse major histocompatibility complex - IL-2 interleukin 2 - Con A concanavalin A - FCS fetal calf serum - SCA IL-2 containing supernatant - LPS E. coli lipopolysaccharide - X a non-H-2 conventional antigen     

Fine specificity and T-cell receptor β-chain gene rearrangements of five H-2Db-specific cytotoxic T-cell clones

A panel of cytotoxic T lymphocyte clones that recognize H-2^b target cells has been established. Six different clones were distinguished according to the following criteria. First, the fine specificity of the clones was determined by testing proliferation and cytotoxicity on target cells of recombinant mice. Clone 221 recognized H-2K^b, and five other clones recognized H-2D^b. Clone 433 distinguished itself from the other five D^b-specific clones by cross-reacting with an antigen on H-2^k cells. Second, the presence of an idiotypic determinant as defined by the 3179 clone-specific monoclonal antibodies was investigated in cytotoxicity inhibition experiments. One of the D^b-specific clones, 653, was inhibited by these antibodies and was therefore clearly different from the other D^b-specific clones. The third criterion involved the rearrangement pattern of the DNA coding for the chain of the T-cell receptor. Southern blot analysis showed that each clone had a unique pattern. Interestingly, clone 653 , which expresses the same idiotypic determinant as clone 3F9, had deleted the C 1 gene cluster, whereas this gene is functionally expressed in clone 3179.Abbreviations used in this paper C constant gene segment - Con A concanavalin A - CTLs cytotoxic T lymphocytes - D diversity gene segment - ³H-dThd tritiated thymidine - J joining gene segment - kb kilobase pairs - LPS lipopolysaccharide - MHC major histocompatibility complex - MLC mixed lymphocyte culture - SDS sodium dodecyl sulfate - V ariable gene segment     

Genes encoding the H,K-ATPase α and Na,K-ATPase α3 subunits are linked on mouse Chromosome 7 and human Chromosome 19

We have used linkage analysis and fluorescence in situ hybridization to determine the chromosomal organization and location of the mouse (Atp4a) and human (ATP4A) genes encoding the H,K-ATPase subunit. Linkage analysis in recombinant inbred (BXD) strains of mice localized Atp4a to mouse Chromosome (Chr) 7. Segregation of restriction fragment length polymorphisms in backcross progeny of Mus musculusxMus spretus mating confirmed this assignment and indicates that Atp4a and Atp1a3 (gene encoding the murine Na,K-ATPase 3 subunit) are linked and separated by a distance of 2 cM. Analysis of the segregation of simple sequence repeats suggested the gene order centromere-D7Mit21-D7Mit57/Atpla3-D7Mit72/Atp4a. A human Chr 19-enriched cosmid library was screened with both H,K-ATPase and Na,K-ATPase 3 subunit cDNA probes to isolate the corresponding human genes (ATP4A and ATP1A3, respectively). Fluorescence in situ hybridization with gene-specific cosmid clones localized ATP4A to the q13.1 region, and proximal to ATP1A3, which maps to the q13.2 region, of Chr 19. These results indicate that ATP4A and ATP1A3 are linked in both the mouse and human genomes.     

Chromosomal assignment of four genes encoding Na/H exchanger isoforms in human and rat

The plasma membrane Na/H exchanger plays an essential role in regulating intracellular pH and Na⁺ concentration and has been implicated in several pathophysiological conditions, including essential hypertension and congenital secretory diarrhea. Four isoforms of the Na/H exchanger encoded by separate genes have recently been identified by cDNA cloning. To map their locations in the human and rat genomes, rat isoform-specific cDNA probes were hybridized to Southern filters containing panels of somatic cell hybrids that segregate either human or rat chromosomes. The rat Nhe1 gene was assigned to Chromosome (Chr) 5, extending the homology with human chromosome 1p that has previously been shown to contain the human NHE1 gene. The genes encoding the NHE-2 and NHE-4 isoforms were syntenic in the two species and assigned to rat Chr 9 and human Chr 2. A single Nhe3 gene was detected in rat and assigned to Chr 1. In contrast, although evidence to date has suggested a single human NHE3 gene on Chr 5, two NHE3 genes, NHE3A and NHE3B, were identified and assigned to Chrs 10 and 5, respectively. Interestingly, rat Chr 1 has recently been found to carry a gene controlling systolic blood pressure upon sodium loading in stroke-prone, spontaneously hypertensive rats. Thus, this and other evidence implicates rat Nhe3 as a possible candidate gene in this disease process.     

The histocompatibility-2 system in wild mice

The I-region gene products of 29 wild-derivedH-2 haplotypes on a B10 background (B10.W congenic lines) were typed with alloantisera which detect 17 inbred I-region antigens. Five new I-region antigens were defined by expanding the inbred line panel ofH-2 haplotypes to includeH-2 ^u , H-2^v, andH-2 ^j . Based on serological analyses of the inbred and B10.W lines, the polymorphism of theIA gene (or genes) is estimated to be at a minimum of 15 alleles and theIE gene (or genes) at a minimum of 4 alleles. These results indicate that theIA subregion is more polymorphic than theIE subregion. By combining the I-region typing data with theH-2K andH-2D region typing data reported previously, a total of 11 new natural recombinants of inbredH-2 alleles were detected among the B10.W lines.     

Homopoietic histocompatibility (Hh-1) phenotype and the regulation of its expression

Hybrid resistance (HR) is primarily controlled by the genes of the Hemopoietic histocompatibility-1 (Hh-1) locus within the H-2 complex. HR is a consequence of the Hh-1-controlled target determinants in homozygous parental strain mice and their absence in heterozygous F₁ hybrid mice. To examine the mechanism that controls the Hh-1 phenotype, three independent clones of somatic cell hybrids between parental lines EL-4 (C57BL/6 origin, H-2 ^b ) and R1 (C58 origin, H-2 ^k ) were studied. The line EL-4 is Hh-1^b-positive and is subject to HR by H-2 ^b heterozygous F₁ mice, but R1 lacks the Hh-1 ^b allele and is not susceptible to HR. Of the three hybrid clones, F263.2 is Hh-1^b-positive, whereas the other two, F262.2 and F264.2, are Hh-1-negative, as judged by these cells' capacity to compete in vivo with the grafted parental C57BL/6 bone marrow cells in the resistant (C57BL/6 × C3H)F₁ mice. All three clones express the H-2^b and H-2^k class I antigens equally well, are susceptible to activated NK cells to the same extent, and all carry four copies of chromosome 17. However, Southern analysis reveals that clone F263.2 contains three copies of H-2 ^b chromosome and one H-2 ^k , whereas the other two clones carry two copies each of the parental chromosome 17. The results suggest that the relative copy number of specific alleles is the crucial determinanr of the Hh-1 phenotype, and render unlikely both the gene dosage hypothesis and the trans-acting dominant suppression hypothesis to account for the noncodominant expression of the Hh-1 phenotype.