Complete sequence of an HLA-dR beta chain deduced from a cDNA clone and identification of multiple non-allelic DR beta chain genes

At least three polymorphic class II antigens are encoded in the human major histocompatibility complex (HLA): DR, DC and SB. cDNA clones encoding beta chains of HLA-DR antigen, derived from mRNA of a heterozygous B-cell line, were isolated and could be divided into four subsets, clearly distinct from cDNA clones encoding DC beta chains. Therefore, at least two non-allelic DR beta chain genes exist. The complete sequence of one of the DR beta chain cDNA clones is presented. It defines a putative signal sequence, two extracellular domains, a trans-membrane region and a cytoplasmic tail. Comparison with a DC beta chain cDNA clone revealed a homology of 70% between the two beta chains and that the two genes diverged under relatively little selective pressure. A set of amino acids conserved in immunoglobulin molecules was found to be identical in both DR and DC beta chains. Comparison of the DR beta chain sequence with the amino acid sequence of another DR beta chain revealed a homology of 87% and that most differences are single amino acid substitutions. Allelic polymorphism in DR beta chains has probably not arisen by changes in long blocks of sequence.     

Complete sequence of the HLA DQ alpha and DQ beta cDNA from a DR5/DQw3 cell line

The HLA-D region is composed of three subregions termed DR, DQ, and DP. We previously reported the sequence of a DR5 beta I and two DR5 beta III cDNA from the DR5 cell line Swei. We now report on the nucleotide and deduced amino acid sequence of the DQ alpha and DQ beta cDNA from the same DR5 cell line, which also types as DQw3. Comparison with other available DQ sequences indicates that DQ alpha has one region of major variability, whereas DQ beta appears to have four regions of variability. In addition, these comparisons indicate that DQw3 alpha from DR5 is different from DQw3 alpha from DR4, but identical to DQw2 alpha from DR3. In contrast, DQw3 beta from DR5 is very similar to DQw3 beta from DR4. These data indicate that at least for DQw2 and DQw3 it is the DQ beta chain that is responsible for DQ typing. Most sequence differences in DQ alleles can be attributed to point mutations; however, codon additions/deletions in the DQ alpha chain may contribute to variability. In addition, regions of possible gene conversion in the DQ alpha and DQ beta chains is suggested by the presence of a chi-like sequence in each chain. Finally, comparison of available haplotypes suggest recombination events may take place between DQ beta and DQ alpha, between DQ alpha and DR beta I, and between DR beta I and DR beta III.     

Direct identification of class II histocompatibility DR proteins in preparations of human T-cell lymphotropic virus type III

Class II histocompatibility DR antigen alpha and beta chains were isolated from preparations of human T-cell lymphotropic virus type III grown in human H-9 cells. The proteins were purified by reversed-phase high-pressure liquid chromatography and identified by direct N-terminal amino acid sequence analysis of each chain. The purified DR alpha chain had an N-terminal amino acid sequence identical to the known sequence of human DR alpha chain through the first 37 residues. The N-terminal amino acid sequence of the purified DR beta chain was identical to that of human DR4 beta chain. The DR alpha and beta chains appeared to be identical to the p34-36K and p30-32K proteins, respectively, concentrated in immunostimulatory complexes prepared from unfractionated virus and were the major immunogens in these complexes. These proteins represent a ready source of antigens which can cause false-positive enzyme-linked immunosorbent assay reactions in individuals previously exposed to allogenic histocompatibility antigens. The removal of the DR chains from virus preparations by use of available monoclonal antibodies or other means should result in a lower rate of initial false-positive enzyme-linked immunosorbent assay reactions.     

Analysis of DR beta and DQ beta chain cDNA clones from a DR7 haplotype

A cDNA library was constructed from a DR7, DRw53, DQw2 homozygous cell line, cDNA clones corresponding to DR beta and DQ beta chains were isolated, and the nucleotide sequences of the polymorphic first domains of these chains were determined. A novel screening strategy allowed rapid and simple identification of cDNA clones corresponding to both DR beta chains (DR7 beta1 and DR7 beta2): DR7 beta2 clones have a recognition site for the enzyme BssHII, whereas DR7 beta1 clones do not. The DR7 beta 1 sequence differs significantly from all previously described DR beta chains. As predicted by the presence of the BssHII site in DR7 beta 2 clones, the DR7 beta 2 sequence differs from the DR7 beta 1 sequence. The sequence of the DRw53-associated DR7 beta 2 chain is identical to the reported sequence of the DRw53-associated DR4 beta 2 chain. In addition, the sequence of the DQ beta chain from the DR7, DQw2 cell line is identical to the reported sequence of a DQ beta chain from a DR3, DQw2 cell. These findings raise interesting questions about the evolution of the DR3, DR4, and DR7 haplotypes.     

Polymorphic class II sequences linked to the rat major histocompatibility complex (RT1) homologous to human DR and DQ sequences

Until recently, the analysis of Class II genes linked to the rat major histocompatibility complex, RT1, has been confined to serologic and electrophoretic analysis of their gene products. To obtain a more definitive estimate of the number and relative polymorphism of RT1 Class II sequences, we performed Southern blot analysis of rat genomic DNA employing human cDNA probes specific for Class II heavy and light chain genes. Southern blots of EcoRI and BamHI digests of genomic DNA from ten inbred strains, expressing eight RT1 haplotypes, were hybridized with the human DQ beta or DR beta cDNA that are homologous to Class II light chain sequences. Four to eight bands were observed to hybridize with the light chain cDNA: band sizes ranged from 2.5 to 28 kb. Restriction fragment patterns were polymorphic; the only identical patterns observed were those associated with RT1 haplotypes with identical RT1.B regions. The number and size of bands hybridizing with DQ beta and DR beta suggested a minimum of four light chain sequences in each haplotype. Southern blots of BamHI and EcoRI digests of genomic DNA from the same strains were hybridized with a DR alpha cDNA that is homologous to Class II heavy chain sequences. All RT1 haplotypes expressed either a 10.0-kb or 13.0-kb band when digested with BamHI, and either a 17-kb or 3.7-kb band when digested with EcoRI. Considerably less polymorphism was detected with the DR alpha probe; this observation is consistent with previously reported limited protein polymorphism of the rat equivalent of the I-E alpha subunit. The size and number of bands hybridizing with the DR alpha probe suggests a minimum of two heavy chain sequences. These observations suggest that the RT1 complex includes more Class II sequences than have been observed in serologic and electrophoretic analyses of Class II gene products. Furthermore, the level of polymorphism of RT1 Class II sequences appears to be comparable with mouse and human Class II sequences.     

Molecular studies of a rare DR2/LD-5a/DQw3 HLA class II haplotype. Multiple genetic mechanisms in the generation of polymorphic HLA class II genes

A cDNA library was constructed from a homozygous B lymphoblastoid cell line (REM) obtained from an individual of a long isolated American Indian tribe, the Warao. The REM cell line expresses serologically defined determinants, DR2 and DQw3, and the T lymphocyte-defined (Dw/LD) specificity, LD-5a. T cells can recognize differences between FJO (a DR2/DQw1 cell line that expresses the Dw specificity MN2) and REM for both DR and DQ molecules. cNDA clones encoding the polymorphic DR beta 1-, DR beta 2-, DQ beta-, and DQ alpha-chains were sequenced and compared with other DR and DQ gene sequences. The DR beta 1-sequence of REM is identical to the DR beta 1-sequence of FJO; the DR beta 2-sequence is also identical to that of FJO except for one amino acid difference at position 67 in the polymorphic first domain (Leu in REM, Phe in FJO) due to a single point mutation. The DQ beta-sequence is identical to that of DR4/DQw3 haplotype; the DQ alpha is different from the DQ alpha of DR4/DQw3 haplotype and identical to the DQ alpha of both the DR3/DQw2 haplotype of a Raji cell line and the DR5/DQw3 haplotype in deduced amino acid sequence. Taken together, these findings suggest that: 1) a single amino acid difference (position 67) in the third hypervariable region of the first domain of the DR beta 2-chain in the DR2 haplotype is apparently sufficient for stimulating T cell responses; 2) the DQw3 serologic specificity may be defined mainly by the DQ beta-rather than DQ alpha-chain; and 3) multiple genetic events have probably occurred to generate the rarely found REM (DR2/LD-5a/DQw3) haplotype.     

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.     

mRNA abundance, rather than differences in subunit assembly, determine differential expression of HLA-DR beta 1 and -DR beta 3 molecules

The class II major histocompatibility molecules HLA-DR are formed by the association of a single DR alpha chain with two nonallelic DR beta chains. In DR3 cells one DR beta chain is severalfold more abundant than the other. We have studied the mechanism that controls the differential expression of these DR beta genes. We determined the amino-terminal sequences of the two expressed DR beta chains. Comparison of these sequences with the nucleotide sequences of the DR3B1 and DRB3a genes indicates that the abundant chain is the B1 gene product. Supporting this conclusion, an informative mutant, 9.4.3, was found to have lost the abundant beta chain and beta 1 mRNA. This mutant expresses normal cell surface levels of the DR beta 3 chain and exhibits no significant dosage compensation of its beta 3 chain. The unchanged level of DR beta 3 dimer on the cell surface suggests that free DR alpha chains are not the limiting factor in the surface expression of the beta 3 chain and, further, that the differential regulation of the surface expression of the two DR beta chains occurs at a step prior to DR assembly. Quantitation of DR beta mRNAs by locus-specific oligonucleotide probes showed that beta 1 mRNA is 4.5-fold more abundant than beta 3 mRNA, strongly indicating that the greater surface expression of DR beta 1 is a direct consequence of greater beta 1 mRNA abundance.     

Nucleotide sequence of a DRw10 beta chain cDNA clone. Identity of the third D region with that of the DRw53 allele of the beta 2 locus and as the probable site encoding a polymorphic MHC class II epitope

The nucleotide and inferred amino acid sequence of a DRw10 beta chain was obtained from cDNA clones isolated from a DR1, DRw10 heterozygous cell line. The sequence of this beta chain gene was distinctive, differing from those of all other defined DR types. The DRw10 beta chain gene was shown by transfection experiments to encode a polymorphic epitope recognized by mAb 109d6 that is also encoded by the DRw53 beta 2 chain gene. Comparison of the nucleotide sequence of both genes revealed that their third D regions (amino acids 67 to 73) were identical. This suggested first that the 109d6 epitope could be encoded by residues of this region, and second, that a putative gene conversion event transferred this sequence along with the information encoding the 109d6 epitope from a donor gene such as DRw53 beta 2. The sequence of the DRw10 beta chain gene was observed to be identical to that of clone pII beta 4 derived from the non-DR3 haplotype in the Raji cell line, which was also demonstrated to express the determinant recognized by antibody 109d6, suggesting that the typing of this cell line is HLA-DR3/DRw10. No evidence was found for the existence of a DR beta 2 chain gene product encoded by the DRw10 haplotype. The DRw10 haplotype was of particular interest because it was present along with a DR1 haplotype in the propositus who had rheumatoid arthritis, and was shared by the DR4-positive son of the propositus, who also had rheumatoid arthritis. This raised the possibility that the DRw10 haplotype, and most probably one or more specific conformations encoded by the DR beta chain, are involved in the definition of the disease susceptibility phenotype.     

cDNA cloning and sequencing reveals that the electrophoretically constant DR beta 2 molecules, as well as the variable DR beta 1 molecules, from HLA-DR2 subtypes have different amino acid sequences including a hypervariable region for a functionally important epitope

Two-dimensional gel electrophoresis (2D-PAGE) of DR molecules from three different Dw subtypes (Dw2, Dw12, and FJO) of the HLA-DR2 haplotype reveals that at least two DR beta genes are expressed. Protein mixing experiments demonstrate that one of the two expressed DR beta molecules is electrophoretically variable (referred to as DR beta 1), and the other (DR beta 2) migrates constantly among DR2 subtypes. We have constructed cDNA libraries from Dw12 and FJO homozygous typing cells (HTC DHO for Dw12 and HTC FJO for FJO) and isolated DR beta cDNA clones. Four of these clones (FJO-13, DHO-8, FJO-6, and DHO-7) were sequenced, and the deduced amino acid sequences were compared with each other and with two published amino acid sequences for the DR beta molecules derived from a DR2-Dw2HTC. Prediction of the migration patterns on 2D-PAGE from the amino acid sequences of these and other DR beta molecules allows the tentative designation of the two full-length cDNA (DHO-8 and FJO-13) as coding for DR beta 2 molecules and the other two cDNA (DHO-7 and FJO-6) for DR beta 1 molecules. Amino acid sequence comparisons also show that the constantly migrating DR beta 2 molecules, as well as the electrophoretically variable DR beta 1 molecules, from Dw2, Dw12, and FJO have different primary amino acid sequences, including a clustered difference in the third hypervariable region of the polymorphic first domain.     

The isolation of the beta A-, beta C-, and gamma-globin genes and a presumptive embryonic globin gene from a goat DNA recombinant library

As an approach to understand how the expression of globin genes are regulated during development, clones containing globin DNA sequences were selected from a recombinant library of goat genomic DNA. The type of globin gene present in each of the recombinants was determined by cross-hybridization to the DNA of mouse alpha- and beta-globin cDNA-containing plasmids. Of 11 clones isolated, eight hybridized specifically to the DNA of the mouse beta-globin plasmid, while one clone hybridized only to the DNA of the alpha globin plasmid. The location of each globin sequence within its DNA insert was determined by a combination of restriction enzyme mapping and Southern transfer-hybridizations. Selected fragments were sequenced; comparisons of the amino acids coded for by these regions with those of the goat globins identified clones carrying beta A-, beta C-, and gamma-globin genes. Another recombinant coded for amino acid sequences resembling, but not identical with, the known goat globins, and was identified tentatively as containing an embryonic or epsilon-gene. Detailed analysis of the clone containing the beta C gene and an overlapping clone revealed that three other beta-like sequences are located 6, 12, and 21 kilobases on the 5'-side of the beta C gene. The globin sequence of the locus nearest to the beta C gene has an altered translation termination codon and, if transcribed and translated, would give a globin chain seven amino acids longer than the normal goat beta C-globin. In addition, the sequence following this termination codon is very AT-rich, unlike that of other globin genes. The recombinants described contain extensive regions of DNA surrounding the globin genes, making them useful for identifying regulatory sequences as well as determining the sequence organization of the goat globin genes.     

Class II genes of the human major histocompatibility complex. Organization and evolutionary relationship of the DR beta genes

The genes of the polymorphic HLA-DR molecules are located within the human major histocompatibility complex. We have studied the HLA-DR genes of an HLA homozygous individual typed to be DR4, Dw4, and DRw53. Fourteen cosmid and phage clones from genomic libraries were isolated and grouped into three clusters comprising a total of 165 kilobases. These clusters contain four DR beta genes. Nucleotide sequence determination showed that two of the genes encode beta chains that carry the DR4 and DRw53 specificities, respectively, while the other two genes are presumably pseudogenes. Comparisons of the nucleotide sequences of all four DR beta genes of the DR4 haplotype show that the genes are extensively similar, approximately 90% in both exons and introns. All four genes are equally similar to each other. These observations are consistent with the notion that the genes arose by duplications that were followed by homogenization through gene conversion. The existence of more than one DR beta gene homologue but only a single DR alpha gene homologue in mouse, rabbit, and cattle suggests that the DR beta gene duplications occurred at or early during mammalian speciation.     

Both alpha and beta chains of HLA-DC class II histocompatibility antigens display extensive polymorphism in their amino-terminal domains

At least three class II antigens, all composed of an alpha and a beta subunit, are encoded in the human major histocompatibility complex, i.e., DR, DC and SB. Two cDNA clones, encoding a DC alpha and a DC beta chain, respectively, were isolated from a cDNA library of the lymphoblastoid cell line Raji (DR3,w6). The two polypeptides predicted from the nucleotide sequences of these clones are each composed of a signal peptide, two extracellular domains, a hydrophobic transmembrane region and a short cytoplasmic tail. Comparison of the DC alpha sequence with two previously published partial sequences shows that the majority of the differences is located in the amino-terminal domain. The differences are not randomly distributed; a cluster of replacements is present in the central portion of the amino-terminal domain. Likewise, the allelic polymorphism of the DC beta chains occurs preferentially in the amino-terminal domain, where three minor clusters of replacements can be discerned. The non-random distribution of the variability of DC alpha and beta chains may be due to phenotypic selection against replacement substitutions in the second domains of the polypeptides.     

Primary structural variation among serologically indistinguishable DS antigens: the MB3-bearing molecule in DR4 cells differs from the MB3-bearing molecule in DR5 cells

HLA-DS molecules bearing the MB3 supertypic specificity have been isolated from two DR4 and two DR5 homozygous cell lines by using the monoclonal antibody IVD12 . Limited amino-terminal amino acid sequence analysis of these molecules demonstrates polymorphism of the HLA-DS subregion. Although the distribution of amino-terminal tyrosine residues in the alpha-chains of all IVD12 -reactive molecules was identical, amino-terminal amino acid sequence differences existed between DS beta-chains isolated from these two groups of cell lines bearing different DR specificities. These studies indicate that two DS molecules bearing the same serologic determinant ( MB3 ), although similar to one another, may be structurally distinct.     

T cell receptor gene segment utilization by HLA-DR1-alloreactive T cell clones.

Transplantation of histoincompatible tissues leads to allograft rejection, which involves recognition of allogeneic MHC molecules by Ag-specific receptors expressed on T cells. The interaction of these molecules is highly specific yet poorly understood. We have investigated the relationship between TCR gene utilization and allo-MHC restriction patterns by using a one-way polymerase chain reaction to amplify the alpha- and beta-chain mRNA from a panel of 10 HLA-DR1-alloreactive T lymphocyte clones. Two previously unreported V alpha and five J alpha gene sequences were obtained. Although a few V alpha, V beta, and J alpha genes were utilized more than once, no correlation between TCR gene usage and DR1 alloreactivity was identified. At the sequence level, the presumed TCR alpha- and beta-chain CDR1 and CDR2 regions displayed limited diversity, whereas the CDR3 or junctional sequences were highly variable. Although most TCR probably interact with subtly different surface features of the DR1 alloantigen, we predict that TCR with similar CDR1 and CDR2 sequences would contact essentially identical regions of the DR1 molecule. The lack of sequence conservation in the junctional regions suggests that different endogenous peptides also may be recognized. Thus, alloreactive T cells may recognize not only allogeneic MHC molecules but perhaps also bound endogenous peptides.     

Primary structure of pregnancy zone protein. Molecular cloning of a full-length PZP cDNA clone by the polymerase chain reaction

A full-length cDNA clone of the human pregnancy zone protein (PZP) was cloned from the hepatocellular carcinoma cell line Hep3B. Based on the exon sequences of the PZP gene (Devriendt et al. (1989) Gene 81, 325-334; Marynen et al., unpublished data), primer pairs were designed to amplify six overlapping fragments of the PZP cDNA. The obtained cDNA is 4609 bp long and contains an open reading frame coding for 1482 amino acids, including a signal peptide of 25 amino acid residues. Comparison with the published partial PZP amino acid sequence (Sottrup-Jensen et al. (1984) Proc. Natl. Acad. Sci. USA 81, 7353-7357) and the PZP genomic sequences confirmed the identity as a PZP cDNA. 71% of the corresponding amino acid residues in PZP and human alpha 2-macroglobulin (alpha 2M) are identical and all cysteine residues are conserved. A typical internal thiol ester site and a bait domain were identified. A Pro/Thr polymorphism was identified at amino acid position 1180, and an A/G nucleotide polymorphism at bp 4097.     

Molecular variation of human major histocompatibility complex DQw3 beta-chains

Histocompatibility leukocyte antigen DQ molecules exhibit polymorphism of both DQ alpha- and beta-chains. Histocompatibility leukocyte antigen-DQw3 is associated with both DR4 and DR5 and can be further subdivided by reactivity with the monoclonal antibody TA10. To determine the molecular nature of the DQ polymorphic alleles associated with the DR4 haplotype, we have sequenced and analyzed DQ alpha and beta cDNA clones obtained from a DR4, Dw4, DQw3 cell line which is TA10-positive. The DQ alpha-chain sequence was identical to previously published sequences from the DR4 haplotype, but the DQ beta sequence differed from published DR4-DQ beta sequences obtained from DQw3-positive TA10-negative cell lines by eight amino acids, six of which were located in the beta 1 domain. Thus, the TA10 serologic determinants reside on the DQ beta-chain. A TA10-specific oligonucleotide probe was constructed based on the DQ beta sequence, and its specificity was confirmed in a panel of TA10-positive and TA10-negative cell lines. An additional band was observed in Southern blotting experiments which may indicate a donor sequence for gene conversion.