Cim: an MHC class II-linked allelism affecting the antigenicity of a classical class I molecule for T lymphocytes

Two alleles at the major histocompatibility complex (MHC)-linked locus cim determine gain and loss changes in the rat RT1.A^a class I molecule which affect its structure both as an alloantigen and as a restriction element. Alleles at the cim locus also influence the post-translational modification of RT1.A^a. These effects may reflect the participation of the cim gene product in the processes of peptide loading or assembly of RT1.A^a. In this study we have used the discriminating RT1.A^a-specific monoclonal antibody JY3/84, as well as cytotoxic T cells raised in appropriate combinations, to determine the cim alleles of eight haplotypes in 15 independent inbred strains of rat. We have also employed the same techniques to analyse a panel of F1 hybrid animals derived from various MHC recombinant strains. These experiments map the cim locus to the class II region of RT1, probably between the DP-related genes (RT1.H) and the DQ-related RT1.B. Address correspondence and offprint requests to: G. W. Butcher.     

Molecular characterization of MHC class II antigens (β 1 domain) in the BB diabetes-prone and -resistant rat

The BB or BB/Worcester (BB/W) rat is widely recognized as a model for human insulin-dependent diabetes mellitus (IDDM). Of at least three genes implicated in genetic susceptibility to IDDM in this strain, one is clearly linked to the major histocompatibility complex (MHC). In an attempt to define the diabetogenic gene(s) linked to the MHC of the BB rat, cDNA clones encoding the class II MHC gene products of the BB diabetes-prone and diabetes-resistant sublines have been isolated and sequenced. For comparison, the ₁ domain of class II genes of the Lewis rat (RTl^L) were sequenced. Analysis of the sequence data reveals that the first domain of RT1.D and RT1.B chain of the BB rat are different from other rat or mouse class 11 sequences. However, these sequences were identical in both the BB diabetes-prone and BB diabetes-resistant sublines. The significance of these findings is discussed in relation to MHC class II sequence data in IDDM patients and in the nonobese diabetic (NOD) mouse strain.     

<Emphasis Type="Italic">RT1.L</Emphasis>: a family of MHC class Ib genes of the rat major histocompatibility complex with a distinct promoter structure

RT1.L class I antigens have originally been identified in LEW rats by LEW.1LV3-anti-LEW.1LM1 antisera and have been classified as nonclassical. We report now that LEW.1LV3-anti-LEW.1LM1 antisera react with three different antigens, termed RT1.L1, RT1.L2, and RT1.L3. This was found by serological analysis of a panel of transfectants expressing different class I genes of strain LEW with a LEW.1LV3-anti-LEW.1LM1 antiserum and two monoclonal antibodies (mAbs HT20 and HT21) generated in the same strain combination. The antiserum reacted with all three antigens: the two mAbs with RT1.L1 and RT1.L2, respectively. Sequence analysis showed that the genes encoding RT1.L1, RT1.L2, and RT1.L3 cluster together in a phylogenetic analysis of rat and mouse ₁-₂ sequences and that they share an unusual MHC class I promoter in which Enhancer A and B, as well as the interferon response element (IRE), are missing. Exchange of the promoter in RT1.L2 against the classical RT1.A promoter resulted in high surface expression in appropriate transfectants, indicating that the deviant promoter is responsible for the weak surface expression of the RT1.L2 gene. The very similar promoter structures of RT1.L1 and RT1.L3 are likely to contribute also to the weak expression of these genes. As RT1.L3 maps closely to the deletion in the mutant haplotype lm1, the RT1.L family can be located in the class I region extending from Bat1 to Pou5f1. Different from other allogeneic mAbs detecting known class I molecules encoded by genes of the RT1.C/E region, HT20 and HT21 react with a wide panel of strains carrying different RT1 haplotypes. This suggests that nonclassical class I genes of the RT1.L family are present in most RT1 haplotypes.Nucleotide sequences reported in this paper have been submitted to GenBank with accession numbers AF457139 (RT1.L1), AY397759 (RT1.L2) and AY445668 (RT1.L3)     

Independent gene duplications,not concerted evolution,explain relationships among class I MHC genes of murine rodents

It has been claimed that class I MHC loci are homogenized within species by frequent events of interlocus genetic exchange (concerted evolution). Evidence for this process includes the fact that certain rat class I loci (including RT1.A) located centromeric to class II and class III are more similar to each other than to the mouse K locus (also centromeric to class II/class III). However, a phylogenetic analysis showed that the rat RT1.A locus is in fact orthologous to the mouse K1 pseudogene (also centromeric to class II/class III). Thus, two independent events of translocation of genes centromeric to class II/class III have occurred in the history of the murine rodents, at least one of which (involving the ancestor of RT1.A and K1) occurred prior to the divergence of rat and mouse. It was also found that the rat nonclassical class I gene RT.BM1 is orthologous to the mouse nonclassical gene 37 ^d. These results argue that intelocus genetic exchange does not occur at a rate sufficient to cause within-species homogenization of class I MHC loci.     

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)     

Genomic organization of a mouse MHC class II region including theH2-M andLmp2 loci

The region encompassing theMa, Mb1, Mb2, andLmp2 genes of the mouse class II major histocompatibility complex (MHC) was sequenced. Since this region contains clusters of genes required for efficient class I and class II antigen presentation, it was interesting to search for putative additional genes in the 21 kilobase gap between theMb1 andLmp2 genes. Computer predictions of coding regions and CpG islands, exon trapping experiments, and cross-species comparison with the corresponding human sequence indicate that no additional functional gene is present in that stretch. However, computer analysis revealed the possible existence of an alternative 3 exon forMb1. Except for the fact that the mouse MHC contains twoMb genes, the genomic organization of theH2-M loci was found to be almost identical to the organization of the humanHLA-DM genes. The promoter regions of theMa andMb genes also resemble classical class II promoters, containing typical S, X, and Y boxes. Like the human genes, the threeH2-M genes displayed very limited polymorphism when we compared the cDNA sequences from six haplotypes. Finally, comparison ofDMB withMb1 andMb2, both at the genomic level and in their coding regions, suggests that theMb gene was recently duplicated, probably only in certain rodents.     

Peptide motif for the rat MHC class II molecule RT1.Da: similarities to the multiple sclerosis-associated HLA-DRB1*1501 molecule

Experimental autoimmune encephalomyelitis induced with myelin proteins in DA and LEW.1AV1 rats is a model of multiple sclerosis (MS). It reproduces major aspects of this detrimental disease of the central nervous system. MS is associated with the HLA-DRB1*1501, DRB5*0101, and DQB1*0602 haplotype. DA and LEW.1AV1 rats share the RT1^av1 haplotype. So far, no MHC class II peptide motif of RT1.D^a molecules has been described. Sequence alignment of the chain of the rat MHC class II molecule RT1.D^a with human HLA class II molecules revealed strong similarity in the peptide-binding groove of RT1.D^a and HLA-DRB1*1501. According to the putative peptide-binding pockets of RT1.D^a, after comparison with the pockets of HLA-DRB1*1501, we predicted the peptide motif of RT1.D^a. To verify the predicted motif, naturally processed peptides were eluted by acidic treatment from immunoaffinity-purified RT1.D^a molecules of lymphoid tissue of DA rats and subsequently analyzed by ESI tandem mass spectrometry. In addition, we performed binding studies with combinatorial nonapeptide libraries to purified RT1.D^a molecules. Based on these studies we could define a peptide-binding motif for RT1.D^a characterized by aliphatic amino acid residues (L, I, V, M) and of F for the peptide pocket P1, aromatic residues (F, Y, W) for P4, basic residues (K, R) for P6, aliphatic residues (I, L, V) for P7, and aromatic residues (F, Y, W) and L for P9. Both methods revealed similar binding characteristics for peptides to RT1.D^a. This data will allow epitope predictions for analysis of peptides, relevant for experimental autoimmune diseases.     

Open reading frame sequencing and structure-based alignment of polypeptides encoded by RT1-Bb, RT1-Ba, RT1-Db, and RT1-Da alleles

MHC class II genes are major genetic components in rats developing autoimmunity. The majority of rat MHC class II sequencing has focused on exon 2, which forms the first external domain. Sequence of the complete open reading frame for rat MHC class II haplotypes and structure-based alignment is lacking. Herein, the complete open reading frame for RT1-B, RT1-B, RT1-D, and RT1-D was sequenced from ten different rat strains, covering eight serological haplotypes, namely a, b, c, d, k, l, n, and u. Each serological haplotype was unique at the nucleotide level of the sequenced RT1-B/D region. Within individual genes, the number of alleles identified was seven, seven, six, and three and the degree of amino-acid polymorphism between allotypes for each gene was 22%, 16%, 19%, and 0.4% for RT1-B, RT1-B, RT1-D, and RT1-D, respectively. The extent and distribution of amino-acid polymorphism was comparable with mouse and human MHC class II. Structure-based alignment identified the 65–66 deletion, the 84a insertion, the 9a insertion, and the 1a–1c insertion in RT1-B previously described for H2-A. Rat allele-specific deletions were found at RT1-B76 and RT1-D90–92. The mature RT1-D polypeptide was one amino acid longer than HLA-DRB1 due to the position of the predicted signal peptide cleavage site. These data are important to a comprehensive understanding of MHC class II structure-function and for mechanistic studies of rat models of autoimmunity.Nucleotide sequence data reported are available in the GenBank database under the accession numbers AY626180–AY626189 for all RT1-Bb sequences, AY626190–AY626199 for all RT1-Ba sequences, AY626200-AY626209 for all RT1-Db sequences and AY626210–AY626219 for all RT1-Da sequences.     

Class I and class II restriction pattern polymorphisms associated with independently derived RT1 haplotypes in inbred rats

This communication reports the DNA level identification of class I and class II sequences associated with 20 RT1 haplotypes which have been assigned previously to eight RT1 groups. Sixteen to 22 bands in genomic blots hybridized with the mouse pH-2III class I cDNA probe. Only the three RT1 ^khaplotypes associated with identical class I restriction fragment patterns. Differences in restriction bands between putatively identical RT1 haplotypes were either less than or equal to 6%, or greater than 50%, suggesting a relatively high level of recombination between serologically identified RT1.A genes and the majority of class I sequences. Restriction fragment patterns associated with three RT1 ^uhaplotypes differed by less than 6%. However, intra-RT1 ^a,intra-RT1 ^b,and intra-RT1 ^lrestriction fragment differences were between 50 and 64%. In specific cases, different RT1 haplotypes associated with identical class I restriction patterns, e.g., RT1 ^m(MNR) and RT1 ^d(MR); higher resolution confirmed the difference (two bands) between RT1 ^mand RT1 ^d.Results of hybridization with the human DC₁ probe confirmed that the AVN RT1 ^aand NSD RT1 ^bhaplotypes were generated by recombinations within the vicinity of the RT1.B : RT1.D regions. These results demonstrate that a previous classification of RT1 haplotypes was incomplete and did not include the majority of class I and class II sequences which distinguish RT1 haplotypes.     

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     

A mutant rat major histocompatibility haplotype showing a large deletion of class I sequences

The LEW.1LM1 inbred rat strain, which has been derived from a (LEW×LEW.1W) F₂ hybrid, carries a major histocompatibility (RT1) haplotype which is distinct from that of the LEW strain (RT1 ¹) in that certainRT1.C region-determined class I antigens are not expressed. Here we show that this phenotypic defect is due to genomic deletion of about 100 kb of theRT1.C region. Certain deleted DNA fragments have been cloned from the wild-type DNA into the EMBL4 vector. Five clones have been characterized and are shown to possess different restriction maps and to each carry a single stretch of class I cross-hybridizing sequences. Probes derived from the non-class I coding part of two clones detect fragments which are present in the wild-type but absent from thelm1 mutant. The type of deletion described here in the rat is discussed in the context ofH-2D/Q deletions in the mouse.     

Multiple divergent haplotypes express completely distinct sets of class I MHC genes in zebrafish

The zebrafish is an important animal model for stem cell biology, cancer, and immunology research. Histocompatibility represents a key intersection of these disciplines; however, histocompatibility in zebrafish remains poorly understood. We examined a set of diverse zebrafish class I major histocompatibility complex (MHC) genes that segregate with specific haplotypes at chromosome 19, and for which donor-recipient matching has been shown to improve engraftment after hematopoietic transplantation. Using flanking gene polymorphisms, we identified six distinct chromosome 19 haplotypes. We describe several novel class I U lineage genes and characterize their sequence properties, expression, and haplotype distribution. Altogether, ten full-length zebrafish class I genes were analyzed, mhc1uba through mhc1uka. Expression data and sequence properties indicate that most are candidate classical genes. Several substitutions in putative peptide anchor residues, often shared with deduced MHC molecules from additional teleost species, suggest flexibility in antigen binding. All ten zebrafish class I genes were uniquely assigned among the six haplotypes, with dominant or codominant expression of one to three genes per haplotype. Interestingly, while the divergent MHC haplotypes display variable gene copy number and content, the different genes appear to have ancient origin, with extremely high levels of sequence diversity. Furthermore, haplotype variability extends beyond the MHC genes to include divergent forms of psmb8. The many disparate haplotypes at this locus therefore represent a remarkable form of genomic region configuration polymorphism. Defining the functional MHC genes within these divergent class I haplotypes in zebrafish will provide an important foundation for future studies in immunology and transplantation.     

Ancestral haplotypes reveal the role of the central MHC in the immunogenetics of IDDM

The major histocompatibility complex (MHC) contains multiple and diverse genes which may be relevant to the induction adn regulation of autoimmune responses in insulin dependent diabetes mellitus (IDDM). In addition to HLA class I and II, the possible candidates include TNF, C4, and several other poorly defined polymorphic genes in the central MHC region. This study describes two approaches which take advantage of the fact that the relevant genes are carried by highly conserved ancestral haplotypes such as 8.1 (HLA-B8, TNFS, C4AQO, C4B1, DR3, DQ2). First, three diabetogenic haplotypes (two Caucasoid and one Mongoloid) have been compared and it has been shown that all three share a rare allele of BAT3 as well as sharing DR3, DQ2. In 43 sequential patients with IDDM the cross product ration for BAT3S was 4.8 (p<0.01) and 6.9 for HLA-B8 plus BAT3S (p<0.001). Second, partial or recombinant ancestral haplotypes with either HLA class I (HLA-B8) or II (HLA-DR3, DQ2) alleles were identified. Third, using haplotypic polymorphisms such as the one in BAT3, we have shown that all the patients carrying recombinants of the 8.1 ancestral haplotype share the central region adjacent to HLA-B. These findings suggest that both HLA and non-HLA genes are involved in conferring susceptibility to IDDM, and that the region between HLA-B and BAT3 contains some of the relevant genes. By contrast, similar approaches suggest that protective genes map to the HLA class II region.     

Remarkable sequence conservation of theHLA-DQB2 locus (DXβ) within the highly polymorphicDQ subregion of the human MHC

TheHLA-D region of the major histocompatibility complex (MHC) is characterized by a remarkable diversity. Most of theHLA class II genes are highly polymorphic, and in addition, the number and organization of individual loci in that region varies in different haplotypes. This extensive allelic polymorphism of immune response genes has well-known functional implications. Within theHLA-D region, two loci,DQA2 andDQB2 (formerly calledDX andDX), represent a very special case: the detailed structure of these two genes is entirely compatible with expression, yet their expression has never been demonstrated in any tissue. Consequently, there exists no known corresponding protein product. Pseudogenes are known to accumulate mutations, as observed for instance in the case ofHLA-DPA2,-DPB2, or-DRB2 genes. We have therefore investigated the extent of DQ2 genes' polymorphism by DNA sequence comparison and by oligonucleotide hybridization across a large number of different haplotypes, and compared it with other genes in theHLA-D region. We show here that, contrary to the adjacentDQ1 genes,DQ2 genes exhibit little and possibly no polymorphism. This conservation ofDQ2 genes in many haplotypes indicates that the DQ 1-DQ2 duplication event must have preceeded the extensive diversification ofDQ1 genes and raises the puzzling question of whyDQ2 genes have remained nonpolymorphic. This suggests that either these genes correspond to an unusually invariant region of the MHC or they are under a strong selective pressure for the conservation of the amino acid sequence of a putative DQ2 gene product. The latter would imply that theHLA-DQ2 genes are expressed into a protein product endowed with essential functional properties.     

Comparison of rat MHC class I antigens by peptide mapping

Monoclonal antibodies specific for the rat major histocompatibility complex (MHC) class I antigens RT1.Aⁿ, RT1.A^u, and RT1.E^u were used for immunoprecipitation of antigens biosynthetically radiolabeled with¹⁴C- or³H-labeled arginine, lysine, and tyrosine; with arginine or tyrosine alone; and with or without tunicamycin in the culture medium. Heavy chains of the glycosylated and unglycosylated antigens were purified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and their tryptic and chymotryptic peptides were compared by high performance liquid chromatography. The antigens coded by the same locus in two different haplotypes (Aⁿ and A^u) differed by 30%, whereas the products of two different loci in the same haplotype (A^u and E^u) differed only by 1–3%. Comparative analysis of the data for samples labeled with single amino acids indicated that two amino acids in A^u have been substituted by an arginine and probably by a tyrosine residue, respectively, in E^u. The high degree of homology between the products of theA andE loci in the same haplotype accounts for the difficulty in detecting recombinational events within the MHC of the rat by classical serological approaches.We dedicate this publication to Professor Paul Doty on the occasion of his sixty-fifth birthday     

The chimpanzee major histocompatibility complex class II DR subregion contains an unexpectedly high number of beta-chain genes

The major histocompatibility complex (MHC) class II DR subregion of the chimpanzee was studied by restriction fragment length polymorphism (RFLP) analysis. Genomic DNA obtained from a panel of 94 chimpanzees was digested with the restriction enzyme Taq I and hybridized with an HLA-DR probe specific for the 3' untranslated (UT) region. Such a screening revealed the existence of 14 distinct DRB/Taq I gene-associated fragments allowing the definition of 11 haplotypes. Segregation studies proved that the number of chimpanzee class II DRB/Taq I fragments is not constant and varies from three to six depending on the haplotype. Comparison of these data with a human reference panel manifested that some MHC DRB/Taq I fragments are shared by man and chimpanzee. Moreover, the number of HLA-DRB/Taq I gene-associated fragments detected in a panel of homozygous typing cells varies from one to three and corresponds with the number of HLA-DRB genes present for most haplotypes. However, a discrepancy is observed for the HLA-DR4,-DR7, and -DR9 haplotypes since a fourth HLA-DRB pseudogene present within these haplotypes lacks its 3' UT region and thus is not detected with the probe used. These results suggest that chimpanzees have a higher maximum number of DRB genes per haplotype than man. As a consequence, some chimpanzee haplotypes must show a dissimilar organization of the MHC DR subregion compared to their human equivalents. The implications of these findings are discussed in the context of the trans-species theory of MHC polymorphism. Address correspondence and offprint requests to: R. E. Bontrop.     

Gene order in the major histocompatibility complex of the rat

The loci in the major histocompatibility complex (MHC) of the rat which code for class I and class II antigens—RT1.A and RT1.B, respectively — have previously been separated by laboratory-derived recombinants and by observations in inbred and wild rats. Closely linked to the MHC is the growth and reproduction complex (Grc) which contains genes influencing body size (dw-3) and fertility (ft). These phenotypic markers were used in this study to orient the A and B loci of the MHC. Two recombinants were used for mapping. The BIL(R1) animal is a recombinant between the MHC and Grc, and it carries the haplotype RT1.A ^lB^lGrc⁺. The r10 animal is an intra-MHC recombinant, and it has the haplotype RT1.A ⁿB¹ Grc. These recombinants were characterized serologically, by mixed lymphocyte reactivity, by immune responsiveness to poly (Glu⁵²Lys³³Tyr¹⁵) and by the presence of the dw-3 gene. The data demonstrate that the gene order of the loci is: dw-3-RT1.B-RT1.A.     

Genetic definition of a further gene region and identification of at least three different histocompatibility genes in the rat major histocompatibility system

Two new recombinant haplotypes of the rat major histocompatibility system,RT1, have been detected in [LEW.1A (RT1 ^a ) ×LEW.1W (RT1 ^u )] × LEW 1N(RT1 ⁿ ) segregating hybrids. Recombinantr3 carries theRTL1. A region (determining classical transplantation antigens) and theRT1.B region (determining strong mixed lymphocyte reactivity and genetic control of antipolypeptide immune responsiveness) of the RT1^a parent, bur rejects RT1^a skin grafts. Recombinantr4 carries theA andB regions of the RT1^u parent, but rejects RT1^u skin grafts. The two histocompatibility genes detected are allelic to each other. The relevant locus, designated asH-C, maps to theB-region side of theRT1 system and appears to mark a thirdRT1 gene region,RT1.C. Availability of haplotypes r3 andr4 allowed the definition of a histocompatibility locus in theB region,H-B. The products ofH-C, H-B and of the previously describedH-A gene vary in antigenic strength.     

Genomic DNA sequence and organization of a TL-like gene in the grc-G/C region of the rat

Genes in the grc-G/C region, which is linked to the rat major histocompatibility complex, influence the control of growth, development, and susceptibility to chemical carcinogens. As an initial approach to analyzing the structure and organization of these genes, a class I hybridizing fragment designated RT(5.8) was isolated from an R21 genomic DNA library and sequenced from overlapping restriction enzyme fragments. The RT(5.8) clone has 5788 base pairs and contains the eight exons characteristic of a class I gene. There are CAAT and TATA boxes upstream of the signal peptide, and the recognition sequence that precedes the site of polyadenylation is located downstream from the third cytoplasmic domain. Comparison of the RT(5.8) gene with respect class I genes from the rat and other species shows that the nucleotide sequences of RT(5.8) have a high level of similarity to those of TL region genes of several strains of mice. The peptide sequence deduced from the RT(5.8) clone is distinct from all previously published class I gene sequences, and at many positions there are amino acid residues that are unique to the RT(5.8) sequence. Probes have been isolated from the third exon and from the 5 and 3 flanking regions of the RT(5.8) clone, and Southern blot analysis with genomic DNA of various rat strains shows that these probes are specific for the RT(5.8) fragment. Northern blot analysis shows that the gene is transcribed in the thymus but not in the liver or spleen. The RT(5.8) sequence is more similar to some mouse TL genes (especially in the 2 and cytoplasmic domains and in the 5 and 3 untranslated regions) than it is to other rat class I genes. Hence, TL-like genes are not restricted to the mouse.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession number M74822. Address correspondence and offprint requests to: T. J. Gill III.