Role of mouse and human class II transgenes in susceptibility to and protection against mouse autoimmune nhyroiditis

 Mouse experimental autoimmune thyroiditis (EAT), a model for Hashimoto’s thyroiditis, is induced by immunizing with mouse thyroglobulin (MTg). To study the extent of H2A involvement in EAT, we introduced AaAb genes from susceptible k mice into resistant or intermediately susceptible strains which do not express H2E molecules. Thyroiditis was severe in resistant B10.M (H2 ^f ) mice carrying the double transgene Aa ^k Ab ^k . Likewise, thyroid infiltration was significantly extended in intermediate B10.Q (H2 ^q ) mice with the same transgene. To examine the effect of H2E molecules in the presence of H2A-mediated susceptibility, we introduced an Ea ^k transgene into E^– B10.S mice to express the Eβ^s molecule and observed significant reduction in EAT severity in B10.S(E⁺) mice. On the other hand, the presence of an Eb ^d transgene in B10.RQB3 (H2A ^q ) mice resulting in the expression of H2Eβ^d molecules did not alter EAT susceptibility, suggesting a role for Eb gene polymorphism in protection against EAT. We have shown recently that the HLA-DRB1 ^* 0301 (DR3) transgene conferred EAT susceptibility to B10.M as well as class II-negative B10.Ab⁰ mice. However, we report here that the HLA-DQB1 ^* 0601 (DQ6b) transgene in B10.M or HLA-DQA1 ^* 0301/DQB1 ^* 0302 (DQ8) transgene in class II-negative Ab⁰ mice did not. These studies show the differential effects of class II molecules on EAT induction. Susceptibility can be determined when class II molecules from a single locus, H2A or HLA-DQ, are examined in transgenic mice, but the overall effect may depend upon the presence of both class II molecules H2A and H2E in mice and HLA-DQ and HLA-DR in humans. Received: 28 January 1997 / 24 March 1997     

Mhc class I and non-class I gene organization in the proximal H2-M region of the mouse

 A bacterial artificial chromosome (BAC) contig was constructed across the proximal part of the H2-M region from the major histocompatibility complex (Mhc) of mouse strain 129 (H2 ^bc ). The contig is composed of 28 clones that span approximately 1 megabasepair (Mb), from H2-T1 to Mog, and contains three H2-T genes and 18 H2-M genes. We report the fine mapping of the H2-M class I gene cluster, which includes the previously reported M4-M6, the M1 family, the M10 family, and four additional class I genes. All but two of the H2-M class I genes are conserved among haplotypes H2 ^k , H2 ^b , and H2 ^bc , and only two genes are found in polymorphic HindIII fragments. Six evolutionarily conserved non-class I genes were mapped to a 180 kilobase interval in the distal part of the class I region in mouse, and their order Znf173-Rfb30-Tctex5-Tctex6-Tctex4-Mog was found conserved between human and mouse. In this Znf173-Mog interval, three mouse class I genes, M6, M4, and M5, which are conserved among haplotypes, occupy the same map position as the human HLA-A class I cluster, which varies among haplotypes and is diverged in sequence from the mouse genes. These results further support the view that class I gene diverge and evolve independently between species. Received: 27 April 1998 / Revised: 4 June 1998     

Histocompatibility gene mutation rates in the mouse: a 25-year review

 Mutation rates of H2 and non-H2 histocompatibility genes in the mouse are examined over a 25-year period. Detected by skin graft rejections, the mutations were screened in inbred and hybrid mice from a continuously maintained and monitored colony and from a regularly supplied set of mice provided from the National Cancer Institute for monitoring of genetic integrity. Twenty-five H2 mutations were recovered, involving the K, D, L, and Ab loci, as well as over 80 mutations of non-H2 histocompatibility genes. Aside from a single allele at a single locus (H2-K ^b ), the spontaneous mutation rate of H2 class I genes appears to be equivalent to that found estimated for non-H2 histocompatibility genes, and comparable to rates reported for a variety of mouse genes. This is in contrast with previous suggestions that H2 genes mutate at orders of magnitude greater than do “average” mammalian genes. The discrepancy is attributed to the H2-K ^b gene which accounts for over half of all reported H2 mutations and which mutates spontaneously at a rate of 1–2×10^–4 per gene per generation. Furthermore, over half of the spontaneous H2-K ^b mutations result in a single mutant phenotype (the “bg” group) which involve similar changes at amino acid residues 116 and 121. Thus, the high spontaneous mutation rate for H2-K ^b appears to be the exception among major histocompatibility genes, rather than the rule. Received: 18 April 1997 / Revised: 22 May 1997     

Spontaneous autocytotoxicity against an unexpected H-2 d haplotype in MRL/lpr (H-2 k) autoimmune disease-prone mice

The MRL/lpr (H-2 ^k) inbred strain, a model for the autoimmune disease systemic lupus erythematosus, differs from the healthy inbred strain MRL +/+ (H-2 ^k) by only 0.1 % of its genome. Southern blot analysis using class I and class II probes confirmed the H-2 ^k genotype of both strains. Among the Ia^k-positive peritoneal cells, cells with an unexpected expression of Ia^d specificities were detected in a radioimmunoassay using several monoclonal antibodies and one conventional antiserum. This was only found in aged (6- to 9-month-old) mice both in the MRL/lpr strain (32 % Ia^d-positive mice) and in the MRL +/+ strain (42% Ia^d-positive mice). Furthermore, 24% of aged MRL/lpr mice exhibited strong spontaneous cytotoxic T lymphocyte (CTL) activities against P815 (H-2 ^d) target cells, and 57% had a weaker but still detectable level of cytotoxicity. In contrast, such a CTL activity has never been found in the MRL +/+ strain. These results suggest that the anti-H-2^d d CTL plays a role in the onset of the autoimmune process in MRL/lpr mice.     

Class I MHC molecules rather than other mouse genes dictate influenza epitope recognition by cytotoxic T cells

Influenza nucleoprotein (NP) is an important target antigen for influenza A virus cross-reactive cytotoxic T cells (Tc). Here we examine the NP epitope recognized by cloned and polyclonal BALB/c Tc and the genetics of this recognition pattern. We can define NP residues 147–161 as the epitope seen in conjunction with K ^d , the only H-2^d class I responder allele for NP restriction. H-2 ^d /H-2 ^b F₁ mice (C57BL × DBA/2) primed by influenza infection lyse only H-2^d target cells treated with peptide 147–161 while H-2^b targets are recognized only after treatment with NP residues 365–379 (previously found to be recognized by D^b restricted Tc cells). Tc cell recognition of NP peptide 147–161 is entirely dictated by expression of K ^d and not by other B10 or OH background genes of congenic mice. Restriction of a unique NP sequence by each responder class I major histocompatibility complex (MHC) allele suggests that antigen and class I MHC interact for Tc recognition.     

广东人禽流感H5N1毒株M基因特性、进化和变异

通过对人禽流感H5N1毒株M基因序列的变异分析,揭示毒株M基因特征与进化。检测广东地区人禽流感H5N1毒株M基因核苷酸序列,同时检索全球人禽流感H5N1毒株M基因序列,采用DNAStar5.0软件对检索的人禽流感H5N1毒株M基因核苷酸序列进行比对和分析;并结合流行病学资料对变异毒株进行进化速度分析。结果发现,1997~2006年53株毒株M1基因和51株毒株M2核苷酸序列同源性均分成两组,1997年毒株为第一组(GⅠ),2003~2006年香港、越南、泰国、印尼、中国大陆、土耳其、伊拉克、阿塞拜疆、埃及毒株为第二组(GⅡ)。M1基因20个氨基酸位点置换,占7.94%(20/252),其中2003~2006年毒株M1基因有9个氨基酸位点不同于1997年毒株;M2基因22个氨基酸置换,占22.7%,其中2003~2006年毒株M2基因有4个氨基酸不同于1997年毒株。M2基因Ks值为26.8×10-6~42.6×10-6Nt/d,Ka值为4.39×10-6~6.98×10-6Nt/d;而M1基因的同义突变速度均远高于错义突变速度,显示M1基因受到机体免疫压力较小;检验发现M1基因进化存在负选择性压力。2003~2006年毒株M1基因通过氨基酸S224N置换,增加一个糖基化位点NSS224-226;而来自印尼的8株毒株M2基因发生C50F置换,引起蛋白二级结构改变。1997年中国香港人禽流感毒株自当时出现后,便未在以后人禽流感疫情中出现。2003~2006年毒株M1基因增加糖基化位点NSS224-226,可能与毒株致病性有关。人禽流感H5N1毒株M基因在自然界变异频繁,可能影响H5N1毒株的人-人传播能力。     

A third class I major histocompatibility complex antigen encoded by a gene in the D region of the H-2 d haplotype recognized by cytotoxic T lymphocytes

The D region of the H-2 ^d haplotype contains five class I genes: H-2D ^d , D2 ^d , D3 ^d , D4 ^d and H-2L ^d . Although previous studies have suggested the presence of D-end encoded class I molecules in addition to H-2D^d and H-2L^d, segregation of genes encoding such molecules has not been demonstrated. In this report we have used cãtotoxic T lymphocytes (CTL) to examine the D region of the H-2 ^d haplotype for the presence of additional class I molecules. CTL generated in (C3H × B6.K1)F₁ (K ^k D ^k , K ^b D ^b ) mice against the hybrid class I gene product Q10^d/L^d expressed on L cells cross-react with H-2L^d but not H-2D^d molecules, as determined by lysis of transfected cells expressing H-2L^d but not H-2D^d. Although H-2L^d-specific monoclonal antibodies (mAb) completely inhibit H-2L^d-specific CTL from killing B10.A(3R) (K ^b D ^d L ^d ) target cells, only partial inhibition of anti-Q10 CTL-mediated lysis was observed, suggesting the presence of an additional D-end molecule as a target for these latter CTL. To identify the region containing the gene encoding the Q10 cross-reactive molecule, we show that anti-Q10 CTL lyse target cells from a D-region recombinant strain B10.RQDB, which has H-2D ^d , D2 ^d , D3 ^d , D4 ^d , and H-2D ^b but not the H-2L ^d H-2 ^d , and H-2L ^d (including D2 ^d , D3 ^d , and D4 ^d , lacks this anti-Q10 CTL target molecule. Together, these data demonstrate that a class I gene mapping between H-2D ^d and H-2L ^d encodes an antigen recognozed by anti-Q10 CTL. A likely candidate for this gene is D2 ^d , D3 ^d or D4 ^d .     

Antiestrogen binding sites in rat liver nuclei

Isolated, intact rat liver nuclei have high-affiity (K_d=10⁻⁹ M) binding sites that are highly specific for nonsteroidal antiestrogens, especially for compounds of the triphenylethylene series. Nuclear [³H]tamoxifen binding capacity is thermolabile, being most stable at 4°C and rapidly lost at 37°C. More [³H]tamoxifen, however, is specifically bound at incubation temperatures of 25°C and 37°C than at 4°C although prewarming nuclei has no effect, suggesting exchange of [³H]tamoxifen for an unidentified endogenous ligand. Nuclear antiestrogen binding sites are destroyed by trypsin but not by deoxyribonuclease I or ribonuclease A. The nuclear antiestrogen binding protein is not solubilized by 0.6 M potassium chloride, 2 M sodium chloride, 0.6 M sodium thiocyanate, 3 M urea, 20 mM pyridoxal phosphate, 1% (w/v) digitonin or 2% (w/v) sodium cholate but is extractable by sonication, indicating that it is tightly bound within the nucleus. Rat liver nuclear matrix contains high-affinity (K_d=10⁻⁹ M) [³H]tamoxifen binding sites present in 5-fold higher concentrations (4.18 pmol/mg DNA) than in intact nuclei (0.78±0.10 (S.D.) pmol/mg DNA). Low-speed rat liver cytosol (20 000×g, 30 min) contains high-capacity (955±405 (S.D.) fmol/mg protein), low-affinity (K_d=10.9±4.5 (S.D.) nM) antiestrogen binding sites. In contrast, high-speed cytosol (100 000×g, 60 min) contains low-capacity (46±15 (S.D.) fmol/mg protein), high-affinity (K_d=0.61± 0.20 (S.D.) nM) binding sites. Low-affinity cytosolic sites constitute more than 90% of total liver binding sites, high-affinity cytosolic sites 0.3%–3.2%, and nuclear sites less than 0.5% of total sites.     

Analysis of D2 d : a D-region class I gene

The mouse major histocompatibility complex is composed of several genes arranged into the K, D, Qa, and Tla regions. The D region of the BALB/c mouse includes genes D2 ^d , D3 ^d , and D4 ^d , in addition to H-2D ^d and H-2L ^d . We have determined the DNA sequence of the D2 ^d gene and compared it with the known sequences of several class I genes. The exon/intron structure of the D2 ^d gene is similar to other class I genes. It also contains similar 5 regulatory elements. A frameshift occurs in exon seven, resulting in a gene product with a truncated cytoplasmic tail. To examine the surface expression of the D2^d molecule, we generated an exon-shuffled construct containing the promoter and exons 1–3, encoding the signal peptide, 1, and 2 external domains of the D2 ^d gene linked to exons 4–8, encoding the 3, transmembrane and cytoplasmic domains, of the H-2D ^d gene. The construct was transfected into mouse L cells, and a protein was detected at the cell surface by a monoclonal antibody (mAb) specific for the 3 domain of H-2D^d, as well as by other class I-specific mAbs. Although D2^d is expressed at low levels, it may be a functional class I gene that most probably evolved from a Qa region gene.     

Low responder MHC alleles for Tc recognition of influenza nucleoprotein

Since virus nucleoprotein is an important target antigen for antiinfluenza cytotoxic T cells (Tc), we examined the genetics of Tc responses to this single viral protein to find three nonresponder alleles (D ^d, D ^k, and K ^b) in three haplotypes and their recombinants so far tested. B10.A(5R) mice bearing nonresponder MHC class I antigen in the D and K regions show no anti-NP Tc responses, however they do show a strong A-virus cross-reactive anti-influenza cytotoxicity. The high frequency of nonresponsiveness to a single viral component, as compared with the entire virus, has implications for the development of simple vaccines.Abbreviations used in this paper DMEM/5 Dulbecco's modified Eagle's medium + 5% FCS + penicillin, streptomycin, L-glutamine - FCS fetal calf serum - HA influenza hemagglutinin - HAU hemagglutinating units - H1.VAC vaccinia recombinant containing a copy of the 1934 H1 gene - i. n. intranasally - MHC major histocompatibility complex - m. o. i. multiplicity of infection - NA influenza neuraminidase - NP influenza nucleoprotein - NP.VAC vaccinia recombinant containing a copy of the 1934 NP gene - p. f. u. plaque-forming units - RPMI/10 RPMI 1640 + 10% FCS + penicillin, streptomycin, L-glutamine, 5 × 10^–5 M 2-mercaptoethanol - Tc cytotoxic T cells     

Active MHC class Ib genes in rat are pseudogenes in the mouse

The most telomeric class I region of the MHC in rat and mouse is the M region, which contains about 20 class I genes or gene fragments. The central part carries three class I genes—M4, M5, and M6—which are orthologous between the two species. M4 and M6 are pseudogenes in the mouse but transcribed, intact genes in the rat. To analyze the pseudogene status for the mouse genes in more detail, we have sequenced the respective exons in multiple representative haplotypes. The stop codons are conserved in all mouse strains analyzed, and, consistent with the pseudogene status, all strains show additional insertions and deletions, taking the genes further away from functionality. Thus, M4 and M6 indeed have a split status. They are silent in the mouse but intact in the closely related rodent, the rat.GenBank accession numbers: AF057065 to AF057072 (exon 3 of H2-M4 of reported mouse strains), AF057976 to AF057985 (exon 3 of RT1.M4 of reported rat strains), AF058923 and AF058924 (exon 2 of RT1.M4 of strains PVG and BN), AY286080 to AY286092 (exon 4 of H2-M6 of reported mouse stains), and AY303772 (full-length genomic sequence of RT1.M6-1^l)     

Effects of β2–microglobulin mutations on the alpha-1 helical region of H2-Ld

 Beta-2 microglobulin (β₂m)has been shown to have an effect on the structural and functional constraints that facilitate proper class I antigen presentation. To date, no evidence has pinpointed the β₂m-specific amino acids that play an integral role in affecting structure in and around the peptide binding region of class I. To delineate β₂m amino acid positions that affect the alpha-1 helical region, we generated a series of mutant β₂m proteins bearing precise amino acid substitutions. The amino acid positions chosen were based upon previous results which demonstrated that human β₂m association with H2-L^d altered the structure of the alpha-1/alpha-2 super-domain. β₂m mutant proteins were used in β₂m exchange assays with cells expressing H2-L^d. Following exchange, cells were assayed to determine whether mutant β₂m association resulted in structural alteration of class I extracellular domains. The alteration in H2-L^d structure was evidenced by an increase in the binding of an antibody (34-1-2), specific for the alpha-1 helical region of H2-L^d. Results demonstrated that amino acid substitutions in β₂m positions 33 and 53 led to a dramatic increase in the reactivity of the alpha-1 domain-specific antibody 34-1-2. Identifying β₂m amino acid positions that influence the structure of the peptide binding region may allow for a better understanding of cellular immune responses that center upon class I/β₂m expression. Received: 18 December 1997 / Revised: 19 February 1998     

Regulation of natural killer cell activity by anti-I-region monoclonal antibodies

The effects of a monoclonal antibody directed against immune response gene products on mouse NK activity were examined. In vivo administration of an anti-I-A^k antibody to C3H/He (H-2^k) mice modulated their peritoneal cell (PC) and spleen cell (SC) natural killer (NK) activity against YAC-1 lymphoma target cells in vitro. No such effect was observed when BALB/c (H-2^d) mice were treated with this antibody. Administration of anti-I-A^k antibody to mice before and after infection with Toxoplasma or treatment with poly(I:C) leads to suppression of NK activity in comparison to NK activity of mice infected with Toxoplasma or injected with poly(I:C) alone. A similar treatment regimen with M5/114 antibody which reacts with I-A^b, I-A^d, I-E^d, and I-E^k molecules resulted in decreased NK activity in B10.D2 (H-2^d) but not in B10.BR (H-2^k) mice. Serum and cell culture supernatant interferon (IFN) concentrations were not altered as a result of anti-I-A^k treatment. Removal of adherent cells did not restore NK activity of anti-I-A^k-treated Toxoplasma-infected mice to levels obtained with mice infected with Toxoplasma. In contrast, depletion of Ly 2.1⁺ cells from nylon-wool nonadherent SC of mice treated with anti-I-A^k antibody, before and after infection with Toxoplasma, resulted in restoration of NK activity to the same level as that observed in Toxoptasma-infected mice.     

A novel MHC class I-related molecule expressed on mouse thymic stroma cells and mature lymphocytes

A monoclonal antibody (mAb) TP-3 has been established by immunizing rats with the BALB/c mouse thymic epithelial cell line TEL-2. The TP-3 antigen is expressed on stroma cells of thymus, spleen, and lymph node in syngeneic BALB/c mice (H-2 ^d ). This antigen is also expressed at a low level on the cell surface of immature thymocytes, and at a high level on mature T and B cells. In allogeneic mice such as C57BL/6 (H-2 ^b ) or C3H (H-2 ^k ), no cells expressed the TP-3 antigen. Using H-2 congenic mice, reactivity with mAb TP-3 was found to map to a region of H-2D ^d L ^d or between D ^d and Qa, suggesting that TP-3 is a major histocompatibility complex (MHC) class I antigen. However, immunoprecipitation analysis indicated that this antigen is not identical to the classical mouse class I molecules in terms of molecular size, antigenicity, and tissue distribution.     

HEMOGLOBIN POLYMORPHISMS IN DEER MICE (PEROMYSCUS MANICULATUS): PHYSIOLOGY OF BETA-GLOBIN VARIANTS AND ALPHA-GLOBIN RECOMBINANTS

Wild populations of deer mice (Peromyscus maniculatus) contain hemoglobin polymorphisms at both alpha-globin (Hba, Hbc) and beta-globin (Hbd) loci. Population gene frequencies of beta-globin variants (d⁰ and d¹ haplotypes) are not correlated with altitude, whereas a¹c¹ alpha-globin haplotypes are fixed in low-altitude populations, and a⁰c⁰ haplotypes reach near fixation at high altitudes. We examined the effects of alpha- and beta-globin variants on blood oxygen affinity and on aerobic performance, measured as maximum oxygen consumption (). Exercise and cold exposure were used to elicit . Experiments were performed at low (340 m) and high (3,800 m) altitude to include the range of oxygen partial pressures encountered by wild deer mice. Beta-globin variants had little effect on blood oxygen affinity or . Oxygen-dissociation curves from a⁰c⁰ and a¹c¹ homozygotes and heterozygotes had similar shapes, but the P₅₀ of a⁰c⁰ homozygotes was significantly lower than that of other genotypes. Mice carrying a¹c¹/a¹c¹ genotypes had the highest at low altitude, but mice with a⁰c⁰/a⁰c⁰ genotypes had the highest at high altitude. Mice carrying rare recombinant alpha-globin haplotypes (a⁰c¹) had lower than nonrecombinant genotypes as a whole but in most cases were not significantly different from nonrecombinant heterozygotes (a⁰c⁰/a¹c¹). We conclude that genetic adaptation to different altitudes was important in the evolution of deer mouse alpha-globin polymorphisms and in the maintenance of linkage disequilibrium in the alpha-globin loci but was not a significant factor in the evolution of beta-globin polymorphisms.     

Genetic control of murine hemagglutinin formation to H-2.5

When B10.D2 (H-2^d) mice are immunized with lymphoid cells from C57B1/10 (H-2 ^d ) and their antisera tested against B10.A (H-2 ^a ) target cells, only antibodies to H-2.5 are measured. The same is true for immunization of DBA/2 (H-2 ^d ) mice when their antisera are absorbed with B10.D2 cells prior to testing. Irrespective of the dose of immunogen administered, the primary hemagglutinin response of B10.D2 mice is significantly lower than that of DBA/2 mice and (B10.D2 × DBA/2)F₁ hybrids, but the secondary responses are similar. The low responsiveness of B10.D2 mice appears to be determined by a single dominant gene with incomplete penetrance; the gene is not linked to eitherH- 2, Hc, or the immunoglobulin allotype loci. In addition, the H-2.5 hemagglutinin response is susceptible to nongenetic influences. When antisera from B10.D2, devoid of H-2.5 hemagglutinins, were assayed in a complement-mediated cytotoxic test, they contained almost as much anti-H-2.5 activity as did the antisera from DBA/2 mice or (B10.D2 × DBA/2)F₁ hybrids. The possibility is discussed that the locus responsible for the deficient primary hemagglutinin response of B 10.D2 may not be determinant-specific but may affect hemagglutinin responses in general.     

Loci controlling lymphocyte production of interferon γ after alloantigen stimulation in vitro and their co-localization with genes controlling lymphocyte infiltration of tumors and tumor susceptibility

Low infiltration of lymphocytes into cancers is associated with poor prognosis, but the reasons why some patients exhibit a low and others a high infiltration of tumors are unknown. Previously we mapped four loci (Lynf1–Lynf4) controlling lymphocyte infiltration of mouse lung tumors. These loci do not encode any of the molecules that are involved in traffic of lymphocytes. Here we report a genetic relationship between these loci and the control of production of IFNγ in allogeneic mixed lymphocyte cultures (MLC). We found that IFNγ production by lymphocytes of O20/A mice is lower than by lymphocytes of OcB-9/Dem mice (both H2 ^pz ) stimulated in MLC by irradiated splenocytes of C57BL/10SnPh (H2 ^b ) or BALB/cHeA (H2 ^d ) mice, or by ConA. IFNγ production in MLCs of individual (O20 × OcB-9)F₂ mice stimulated by irradiated C57BL/10 splenocytes and genotyped for microsatellite markers revealed four IFNγ-controlling loci (Cypr4-Cypr7), each of which is closely linked with one of the four Lynf loci and with a cluster of susceptibility genes for different tumors. This suggests that inherited differences in certain lymphocyte responses may modify their propensity to infiltrate tumors and their capacity to affect tumor growth.     

Immunogenetic analysis ofH-2 mutations

A.BY, B10.LPa, and B10.129(5M) mice were presensitized in vivo against B10.A(5R) cells and then restimulated in vitro by the same cells in the standard CML assay. The effector cells thus generated lysed not only B10.A(5R), but also C57BL/6 targets, indicating that, in addition to anti-H-2D_d response [measured on the B10.A(5R) targets], response to minor histocompatibility (H) antigens (measured on the C57BL/6 targets) also occurred. The latter response was directed against multiple minor H antigens in the case of the A.BY effectors, and against H-1 and H-3 antigens in the case of B10.129(5M) and B10.LPa effectors, respectively. The sensitization against minor H antigens occurred in the context of H-2K^b H-2D^d antigens, but by testing the response on C57BL/6 targets, only cells reacting with minor H antigens in the context of H-2K^b were assayed. The same effector cells were then tested against H-2^b mutant strains, in which theH-2K ^b allele was replaced by a mutant one. All three effector types [A.BY, B10.LPa, and B10.129(5M)] behaved in a similar way: they all reacted with theH-2 ^bg1 mutant to the same degree as withH-2 ^b, they did not react at all or reacted only weakly with theH-2 ^bd andH-2 ^bh mutants, and they reacted moderately or strongly with theH-2 ^ba mutant. The degree of crossreactivity with the mutants reflects, with one exception, the degree of relatedness of these mutants toH-2 ^b, as established by other methods. The one exception is theH-2 ^ba mutant, which is the most unrelated toH-2 ^b, and yet it crossreacted strongly. Further testing, however, suggested that in this instance the crossreactivity was probably directed against H-2 antigens: the anti-H-2D^d effectors apparently crossreacted with the H-2K^ba antigens. This finding is an example of cell-mediated crossreactivity between the products of two differentH-2 genes (H-2K andH-2D). It is also an example of anH-2 mutation generating an antigenic determinant known to be present in another strain.     

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     

Murine MHC class Ib gene,<Emphasis Type="Italic"> H2-M2,</Emphasis> encodes a conserved surface-expressed glycoprotein

We have determined the genomic sequence of H2-M2 in seven haplotypes from nine inbred strains of mice and in five wild-derived haplotypes. Except for the spretus haplotype sp1 with a premature stop codon, we found only limited polymorphism. Four of the five amino acid substitutions in the -helices are at positions that would point out from the antigen-binding groove, indicating that the polymorphism might influence receptor recognition rather than antigen binding. The rat homologue, RT1.M2^lv1, has 89% identity to H2-M2 at the nucleotide level and 91% at the amino acid level, and it also encodes an intact MHC class I glycoprotein. Chimeric proteins with ₁₂ or ₃-transmembrane domains encoded by H2-Q9 were detectable on the surface of transfectants with monoclonal antibodies against Qa2, and the full-length M2 protein, labeled by fusion with green fluorescent protein, was detectable with S19.8 monoclonal antibodies. The H2-M2 protein was thus expressed on the cell surface, even in TAP-deficient RMA-S cells at 37 °C, suggesting that it is TAP-independent. We conclude that H2-M2 is a conserved mouse class Ib gene that is translated to a surface-expressed MHC class I molecule with a function still to be elucidated.The nucleotide sequences reported in this paper have been submitted to GenBank with the accession numbers AY302188–AY302217 for all H2-M2 sequences and AY302218 for RT1.M2, AY326271 for RT1.M2-2, and AY327254 for the RT1.M2 microsatellite marker