DO beta: a new beta chain gene in HLA-D with a distinct regulation of expression

The HLA-D region of the human major histocompatibility complex encodes the genes for the alpha and beta chains of the DP, DQ and DR class II antigens. A cDNA clone encoding a new class II beta chain (designated DO) was isolated from a library constructed from mRNA of a mutant B-cell line having a single HLA haplotype. Complete cDNA clones encoding the four isotypic beta chains of the DR1, DQw1, DPw2 and putative DO antigens were sequenced. The DO beta gene was mapped in the D region by hybridization with DNA of HLA-deletion mutants. DO beta mRNA expression is low in B-cell lines but remains in mutant lines which have lost expression of other class II genes. Unlike other class II genes DO beta is not induced by gamma-interferon in fibroblast lines. The DO beta gene is distinct from the DP beta, DQ beta and DR beta genes in its pattern of nucleotide divergence. The independent evolution and expression of DO beta suggest that it may be part of a functionally distinct class II molecule.     

The nucleotide sequence of the murine I-E beta b immune response gene: evidence for gene conversion events in class II genes of the major histocompatibility complex.

We have determined the DNA sequence of the murine I-E beta b immune response gene of the major histocompatibility complex (MHC) of the C57BL/10 mouse and compared it with the sequence of allelic I-E and non-allelic I-A genes from the d and k haplotypes. The polymorphic exon sequences which encode the first extracellular globular domain of the E beta domain show approximately 8% nucleotide substitutions between the E beta b and E beta d alleles compared with only approximately 2% substitutions for the intron sequences. This suggests that an active mechanism such as micro gene conversion events drive the accumulation of these mutations in the polymorphic exons. The fact that several of the nucleotide changes are clustered supports this hypothesis. The E beta b and E beta k genes show approximately 2-fold fewer nucleotide substitutions than the E beta d/E beta b pair. The A beta bm12, a mutant I-A beta b gene from the C57BL/6 mouse, has been shown to result from three nucleotide changes clustered in a short region of the beta 1 domain, which suggests that a micro gene conversion event caused this mutation. We show here that the E beta b gene is identical to the non-allelic A beta bm12 DNA sequence in the mutated region and suggest, therefore, that the E beta b gene was the donor sequence for this intergenic transfer of genetic information. Diversity in class II MHC genes appears therefore to be generated, at least in part, by the same mechanism proposed for class I genes: intergenic transfer of short DNA regions between non-allelic genes.     

Class II genes of the human major histocompatibility complex. The DO beta gene is a divergent member of the class II beta gene family

A novel class II beta chain gene is described. This gene, tentatively called DO beta, displays considerably less polymorphism than beta genes of the DP, DQ, and DR loci. The nucleotide sequence of the DO beta gene is strikingly similar to that of the previously identified murine A beta 2 gene. The DO beta gene displays the same exon/intron organization as other beta genes although the fifth exon and the translated portion of the sixth exon are longer than in other genes. A striking feature of the amino acid sequence deduced from the DO beta gene sequence is the pronounced hydrophobicity of the NH2-terminal region. This feature distinguishes the putative DO beta chain from other class II beta chains and raises the possibility that DO beta chains may interact with an alpha chain that is structurally different from those of the DP, DQ, and DR loci. It further suggests that the putative DO molecule may have a function different from those of other class II antigens.     

Molecular basis for the defective expression of the mouse Ew17 beta gene

Four of the eleven independent H-2 haplotypes of inbred mouse strains and approximately 15% of wild mouse chromosomes 17 fail to express the E alpha E beta class II histocompatibility (Ia) Ag. These E- haplotypes are defective in the expression of the E alpha and/or the E beta chain. None of the E beta defects has previously been described at the molecular level. In this study, we report the molecular basis for the defective expression of the E beta gene from the w17 haplotype of the H-2 congenic strain B10.CAS2, derived from wild Mus musculus castaneus. Comparison of the Ew17 beta genomic sequence to those of the functional Eb beta and Ed beta genes reveals a single base insertion in the RNA donor splice site of the first intron. By DNA shuffling, we have corrected the single base mutation, and we show by FACS analysis and 2-D PAGE of immunoprecipitates that the corrected Ew17 beta is expressed in L cells when co-transfected with an Ed alpha gene. Conversely, an Eb beta gene construct containing the mutant RNA splice site from Ew17 beta is not expressed. We conclude that the single base insertion in the first RNA splice donor site is the sole molecular defect in the Ew17 beta gene.     

The Eb beta gene may have acted as the donor gene in a gene conversion-like event generating the Abm 12 beta mutant

At least two different class II histocompatibility antigens, I-A and I-E, are encoded by the murine major histocompatibility complex. Both types of class II antigens are composed of polypeptide chains called alpha and beta. Class II antigens display extensive genetic polymorphism, the main part of which resides in the NH2-terminal domains of the A alpha, A beta and E beta chains. Recently it was shown that the mutant gene Abm 12 beta differed from the wild-type gene Ab beta by three nucleotide substitutions, which all occur within a stretch of 14 nucleotides. Multiple substitutions of the type found in the Abm 12 beta gene suggest that the mutant arose by a gene conversion-like event. To examine whether the Eb beta gene may have served as the donor gene in the generation of the Abm 12 beta gene, we have isolated and sequenced a cDNA clone corresponding to the Eb beta gene. Comparisons of the Eb beta, the Ab beta and the Abm 12 beta nucleotide sequences revealed that the Eb beta sequence is identical to that of Abm 12 beta in the positions where the latter differs from the Ab beta sequence. This observation is consistent with the notion that the Abm 12 beta mutant gene arose by a gene conversion-like event involving the Eb beta gene.     

Marsupial MHC class II beta genes are not orthologous to the eutherian beta gene families

The major histocompatibility complex (MHC) class II DRB, DQB, DPB, and DOB gene clusters are shared by different eutherian orders. Such an orthologous relationship is not seen between the beta genes of birds and eutherians. A high degree of uncertainty surrounds the evolutionary relationship of marsupial class II beta sequences with eutherian beta gene families. In particular, it has been suggested that marsupials utilize the DRB gene cluster. A cDNA encoding an MHC class II beta molecule was isolated from a brushtail possum mesenteric lymph node cDNA library. This clone is most similar to Macropus rufogriseus DBB. Our analysis suggests that all known marsupial beta-chain genes, excluding DMB, fall into two separate clades, which are distinct from the eutherian DRB, DQB, DPB, or DOB gene clusters. We recommend that the DAB and DBB nomenclature be reinstated. DAB and DBB orthologs are not present in eutherians. It appears that the marsupial and eutherian lineages have retained different gene clusters following gene duplication events early in mammalian evolution.     

Analysis of gene structure and antigen determinants of DR2 antigens using DR gene transfer into mouse L cells

Three HLA class II DR beta genes and one DR alpha gene from the DR2 haplotype were cloned in cosmid vectors. The DR beta II gene might be a pseudogene lacking the first exon that encodes the leader peptide. The DR beta I and DR beta III genes were expressed, together with the DR alpha-chain, after transfection into mouse L cells. Restriction enzyme mapping of the DR beta genomic clones and reactivity of their products expressed on the L cell transfectant against mAb showed that the DR beta I and DR beta III genes encoded the nonpolymorphic and polymorphic DR beta chain, respectively. This arrangement is the reverse of that observed in other haplotypes, such as DR3, 4 and 6. The alignment of the HLA class II genes including the DR beta genes on the chromosome 6, however, was consistent with other haplotypes, e.g., centromere-DX beta-DX alpha-DV beta-DQ beta-DQ alpha-DR beta I-DR beta II- DR beta III-DR alpha-telomere. These results suggest that the susceptibility to mutations or gene conversions responsible for genetic polymorphisms depends on the gene itself and not on its location. Furthermore, absorption experiments of anti-DR2 allosera by the DR alpha/DR beta transfectants revealed that the so-called DR2 specificities were determined by multiple epitopes although both the DR beta I and DR beta III genes behaved similarly with DR2-specific antibodies.     

The A beta 6w302 gene and molecular mechanisms of resistance to the spread of radiation-induced lymphoma in a mouse mutant, survivor-27

Metastatic tumors escape from immune response and spread in the body; survivors are very rare. Novel single exon genes A beta 4-7 and a pseudogene A beta 8 psi have been cloned from survivors. Their protein coding sequences are similar to MHC class II beta H2-Ab cDNA while their promoter is different from MHC promoters. The A beta 4 protein was demonstrated on macrophages (antigen presenting cells). The A beta gene family is genetically unstable in germ line and somatic cells of survivors. Mutants S-27 and S-87/1 lost the A beta 5s5 and acquired the A beta 6w302 gene; the Ab gene mutated in S-27. The proposed mechanism of resistance is molecular instability of the A beta gene family resulting in somatic mutations and wandering immune responses that destroy the tumor in the survivor.     

Complete nucleotide sequence of a functional HLA-DP beta gene and the region between the DP beta 1 and DP alpha 1 genes: comparison of the 5'' ends of HLA class II genes.

The complete nucleotide sequence of an HLA-DP beta 1 gene and part of the adjacent DP alpha 1 gene, up to and including the signal sequence exon, were determined. The sequence of the DP beta 1 gene identified it as the DPw4 allele. The six exons of the DP beta 1 gene spanned over 11,000 bp of sequence. The arrangement of the gene was broadly analogous to genes of other class II beta chains. The beta 1 exon was flanked by introns of over 4 kb. Comparisons with published sequences of cDNA clones indicated that an alternative splice junction, at the 3' end of the gene, is used in at least one allele. Variation in choice of splice junction indicates an additional mechanism for allelic variation in class II genes. The sequence also indicated that the DP beta 1 and DP alpha 1 genes are separated by only 2 kb at their 5' ends. Comparison of the 5' ends of the DP alpha 1 and beta 1 genes with other class II sequences, including the DZ alpha gene, showed conservation of several blocks of sequences thought to be involved in control of expression. Some areas of the introns were partially conserved in the DQ beta gene, and several other intron sequences were homologous to sequences found in other unrelated genes.     

The HLA-DQ beta gene upstream region contains an immunoglobulin-like octamer motif that binds cell-type specific nuclear factors

A method is described for scanning relatively large fragments of DNA for sequences which bind nuclear factors. This method was used to identify an octamer (ATTTGTAT) in the DQ beta gene upstream region which differs from the immunoglobulin gene octamer (ATTTGCAT) by only 1 bp. The DQ beta gene octamer binds two proteins, one (B2) appears to be B cell specific while the other (B1) is not. These factors are either similar or identical to factors which bind to the octamer motif in immunoglobulin genes. All other class II MHC genes for which sequence information is available contain an octamer motif in their upstream region. Thus, the possibility that these sequences regulate B cell specific expression of class II MHC genes requires careful evaluation.     

Differential expression of mouse beta/goat beta c, mouse beta/goat beta F, and mouse beta/goat epsilon II hybrid globin genes in murine erythroleukemia cells.

We assembled three hybrid beta-globin genes by fusing the mouse beta-major promoter and initial transcribed region to one of three goat beta-like globin gene bodies: beta c (preadult), beta F (fetal), or epsilon II (embryonic). Thymidine kinase (tk)-deficient murine erythroleukemia (MEL) cells were cotransformed with one of these constructs and a separate plasmid bearing the tk gene. Half of the 24 cell lines containing either the mouse beta/goat beta c or mouse beta/goat beta F genes expressed the transferred genes at significant levels; in many cases the hybrid genes were, like the endogenous beta-globin genes, inducible with dimethyl sulfoxide. We obtained 13 cell lines containing the mouse beta/goat epsilon II hybrid gene, 6 of which were cotransfected with a mouse beta/human beta fusion gene known to function in MEL cells. In contrast to the results with the other fusion genes, the mouse beta/goat epsilon II hybrid was very poorly expressed: in two separate experiments, 0 of 13 and 2 of 13 lines showed significant mouse beta/goat epsilon II RNA levels after induction. In all these lines the endogenous mouse beta and cotransfected mouse beta/human beta genes were expressed. As an initial test of possible reasons for the inactivity of the mouse beta/goat epsilon II hybrid, we recloned this fusion gene into a tk-bearing plasmid, adjacent to the tk gene. Of 12 cell lines transformed with this plasmid, 11 produced mouse beta/goat epsilon II RNA; in 6 cases the expression was both strong and dimethyl sulfoxide inducible.     

N-terminal amino acid sequence analyses of the alpha and beta polypeptides from four distinct subsets of sheep major histocompatibility complex class II molecules

Four monoclonal antibodies, SBU.II 28-1, 37-68, 38-27, and 42-20, each recognizing a distinct, non-overlapping subset of sheep class II molecules, were used to purify class II molecules from a single sheep. Four class II alpha subunits designated 28-1 alpha, 37-68 alpha, 42-20 alpha, and 38-27 alpha and five class II beta subunits designated 28-1 beta, 37-68 beta 1, 37-68 beta 2, 42-20 beta, and 38-27 beta were compared by N-terminal sequence analyses. Two distinct alpha subunits were identified; the 28-1 alpha, 37-68 alpha, and 42-20 alpha subunits all had identical N-terminal amino acids sequences, which exhibited about 75% homology with HLA-DR alpha and mouse E alpha polypeptides. In contrast, the 38-27 alpha sequence exhibited about 80% sequence homology with HLA-DQ alpha and mouse A alpha polypeptides. In general, sheep beta subunits displayed insufficient sequence homology to enable correlation with human beta-chain sequences; however, the 38-27 beta-chain sequence showed homology with the HLA-DQ beta sequence. The conserved sequence surrounding the site for N-linked glycosylation within human/mouse beta polypeptides (residues 19 to 21) was not present in sheep beta sequences and in contrast with the beta-chains of mouse and man, sheep beta polypeptides contained between 1 and 3 positionally variable cysteine residues (residues 13 to 15 inclusive). Individual sheep beta subunits exhibited extensive sequence heterogeneity and each consisted of a unique population of beta polypeptide species. At least 16 different beta polypeptide sequences were identified from a single sheep and the existence of no fewer than nine non-allelic beta genes was inferred from the sequence data. We have previously provided evidence suggesting that the sheep has multiple major histocompatibility complex class II alpha and beta genes related to those of all three HLA-D subregions. The present results suggest that a number of these genes encode HLA-DQ-like heterodimers and that a sheep DR-like alpha gene product is shared with the products of a large and heterogeneous sheep beta gene family.