Immunochemical analysis of a cell transfected with an HLA-DR gene reveals a new alloantigenic specificity within HLA-DRw52

Reassessing the role of HLA-DRB3 T-cell responses: evidence for significant expression and complementary antigen presentation

In humans, several HLA-DRB loci (DRB1/3/4/5) encode diverse beta-chains that pair with alpha-chains to form DR molecules on the surface of APC. While DRB1 and DRB5 have been extensively studied, the role of DRB3/4 products of DR52/DR53 haplotypes has been largely neglected. To clarify the relative expression of DRB3, we quantified DRB3 mRNA levels in comparison with DRB1 mRNA from the same haplotype in both B cells and monocytes, observing quantitatively significant DRB3 synthesis. In CD19+ cells, DRB1*03/11/13 was 3.5-fold more abundant than DRB3, but in CD14+ this difference was only two-fold. Monocytes also had lower overall levels of DR mRNA compared with B cells, which was confirmed by cell surface staining of DRB1 and DRB3. To evaluate the functional role of DRB3, tetramer-guided epitope mapping was used to detect T cells against tetanus toxin and several influenza antigens presented by DRB3*0101/0202 or DRB1*03/11/13. None of the epitopes discovered were shared among any of the DR molecules. Quantitative assessment of DRB3-tetanus toxin specific T cells revealed that they are present at similar frequencies as those observed for DRB1. These results suggest that DRB3 plays a significant role in antigen presentation with different epitopic preferences to DRB1. Therefore, DRB3, like DRB5, serves to extend and complement the peptide repertoire of DRB1 in antigen presentation.

Analysis of the fine specificities of sheep major histocompatibility complex class II-specific monoclonal antibodies using mouse L-cell transfectants

The fine specificities of two panels of monoclonal antibodies (mAbs) for sheep major histocompatibility complex (MHC) class II molecules were determined using five mouse L-cell transfectants, each expressing a defined sheep DQ or DR MHC class II A/B gene pair. Using the transfectants in an indirect fluorescence antibody assay, previous immunochemical characterization of the mAbs was confirmed for 16 of 23 mAbs tested. The MHC class II subtype specificity (DQ or DR) of each mAb was assigned without interference from the products of other expressed class II loci. This allowed the identification of both cross-locus specificities as well as defining fine specificities of mAbs previously only partially characterized by immunochemical techniques.

Monoclonal antibody definition of the DRB3 allele, HLA-Dw25

Monoclonal antibodies are powerful tools for analyzing HLA antigen polymorphism. We have investigated the serological and biochemical nature of the DRw52-related antigen defined by the monoclonal antibody NDS10. A detailed analysis of the population distribution of NDS10 reactivity revealed that the epitope was present on a subpopulation of DRw52 positive cells. A distinct pattern of reactivity was found within DR3 individuals: all of the B18,DR3 cells were NDS10 positive, whereas the A1,B8,DR3 cells were negative. All of the DR5(w11) cells and two of three DRw12 cells reacted with NDS10. NDS10 reactivity with DRw6 was not restricted to either of the serologically defined subtypes; three of 17 DRw13 and nine of 10 DRw14 cells were NDS10 positive. NDS10 was unreactive with all of the DRw8 cells tested. Two-dimensional gel analyses revealed that the NDS10 molecule precipitated from DR3, DR5(w11) and DRw6(w14) cell lines had an identical beta chain profile. These data indicate that NDS10 recognises the Dw25 allele of the DRw52 complex.

Serological detection and molecular localization of allelic HLA-DP supertypic epitopes

A DP serological allospecificity was identified using 125I-labeled preparations of HLA class II molecules isolated from cells of HLA homozygous typing cell lines, SLE (DRw6, DQw1, DPw3) and WT46 (DRw6, DQw1, DPw2), and depleted of DR molecules by absorption with an anti-DR monoclonal antibody. The specificity, provisionally called WT, was carried by class II molecules possessing the characteristics of DP molecules on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and detected primarily in DPw1, DPw3 and DPw5 cells and exceptionally in some DPw2 cells including WT46 and DPw4 cells on a large panel of DP-pretyped B cell lines mostly derived from the 10th International Histocompatibility Workshop B cell reference panel. It was apparently allelic to another DP serological specificity BUT previously defined on DP molecules isolated from cells of DPw2+ HLA deletion mutant cell line LCL 721.82. On the same cell panel; the BUT specificity was negative in all DPw1, DPw3 and DPw5 cells, and positive in all DPw2 and DPw4 cells and also in DPw2B and DPw4B cells except the cells typed WT+. This DP association pattern was similar to that of the known allelic sequences, GGPM and DEAV, in DP beta F segment, one of the six variable segments in the second exon of DP beta gene. Thus, genomic DNA from 22 B cell lines pretyped for BUT and WT specificities were enzymatically amplified for the second exon of DP beta gene by the use of locus-specific oligonucleotide primers and hybridized with 32P-labeled oligonucleotide probes corresponding to the F segment sequence variations. This oligonucleotide typing showed perfect one-to-one correlation with the BUT and WT serological typing. The typing also revealed that WT46 cells, although typed DPw2, have the DEAV sequence common to DPw1, DPw3 and DPw5.

DNA typing of an HLA-DR bilocus specificity by gene amplification and oligonucleotide hybridization

The structure of the DRB1*03 gene has been interpreted as the product of a gene conversion event involving a DRB3 gene as donor and resulting in the introduction of two short segments of the DRB3 sequence into the DRB1 locus. The serological counterpart of this double insertion is the TR81 specificity. Consequently, the TR81-specifying sequences can reside on either DRB1 or DRB3, or on both loci. Within each of the two sequence stretches a single nucleotide may be responsible for the generation of the TR81 alloantigen. Oligonucleotide probes corresponding to these stretches and to their allelic variants were constructed. They were used, under stringent hybridization conditions, to detect TR81-specifying sequences in the DNA of HLA-homozygous cell lines carrying different haplotypes of the DRw52 family. Prior to hybridization the DNA was amplified with either DRB1-specific or DRB3-specific primers. Using this approach it was possible to perform a "DNA typing" of the TR81-specifying sites separately on both the DRB1 locus and the DRB3 locus.

Variants of HLA-DRw52 defined by T lymphocyte clones

Polymorphism within the gene encoding the DRw52 allospecificity was studied with DRw52-specific proliferative T lymphocyte clones. Three clones, C6, E3 and ZUK16, were generated by intra-DRw52 priming in mixed lymphocyte culture and tested against an HLA-D homozygous reference cell panel. The reactivity of each clone could be specifically inhibited by anti-DR, but not anti-DQ or anti-DP, monoclonal antibodies. Clone C6 identified a DRw52 variant termed 52a that was predominantly expressed by HLA-B8,DR3+ and DRw13,Dw18+ cells. Clone E3 identified a variant termed 52b which was predominantly expressed by HLA-B18,DR3+,DRw11,Dw5+ and DRw14,Dw9+ cells. Clone ZUK16 identified a variant termed 52c which was predominantly expressed by DRw13,Dw19+ cells. The DRw52a, 52b and 52c variants correspond to the Dw24, Dw25 and Dw26 alleles defined by the WHO HLA 1987 Nomenclature Committee. Together, clones E3 and ZUK16 appeared to identify a fourth DRw52 variant termed 52d which was expressed by two cells, one DR3, Dw"3.3"+ and one DRw14,Dw"9.2"+. A fifth Drw52 variant termed 52e, expressed by a DRw13,Dw"OMW"+ cell, was suggested by the absence of reactivity with any of the three T cell clones. These data thus demonstrate the existence of three well-defined allelic variants of DRw52 and indicate that there are at least two additional variants. The recognition of these polymorphisms by alloreactive T cells provides one measure of their functional significance.

Correlations between polymorphisms at the DNA and at the protein level of DRw52 haplotypes, revealed with a variety of techniques

LB-Q1 and LB-Q4 are two subtypes of DRw52, defined by proliferative T-cell clones. These subtypes represent a polymorphism of the DR beta III gene. Similar subtypes of DRw52 can be defined by oligonucleotide typing, serology and RFLP analysis. In the present study we compared these typing techniques on a panel of 22 HLA-D homozygous, DRw52-positive typing cells. All typing techniques correlated very well. Three subtypes of DRw52 could be identified. Our results show that typing for cellularly defined structures can be done with a variety of noncellular techniques. This observation has important implications for matching in unrelated bone marrow transplantation and for disease association studies.

Serological recognition of HLA-DR allodeterminant corresponding to DNA sequence involved in gene conversion

HLA class II molecules were isolated from mouse L cells transfected with a DR alpha gene and an allele, 52a, of locus DR beta III from an HLA-homozygous cell line, AVL, of the DR3 haplotype. The isolated molecules were found to possess a new allospecificity, named TR81. This specificity behaved allelic to the previously described specificity TR22 encoded by another allele, 52b, of the DR beta III locus. The TR81 specificity was also present on the DR beta I gene product of the DR3 haplotype. The nucleotide sequence of the gene encoding TR81 differs from TR81-negative DR beta genes of the DRw52 family in only two codons, both located in the regions known to be involved in a gene conversion event. Consequently, the following conclusions can be formulated. (a) TR81 is a bi-locus specificity and allelic to TR22 only in its DR beta III locus localization. (b) The TR81 specificity is the phenotypic counterpart of the gene conversion event which led to the generation of the DR beta I gene of the DR3 haplotype. (c) One or both individual amino acid substitutions in the first domain of the DR beta chain are responsible for the TR81 allospecificity. (d) Since TR81 is expressed on the DR beta I chain of the DR3 haplotype, it is possible that TR81 and DR3 represent the same serological specificity.

Functional polymorphism of each of the two HLA-DR beta chain loci demonstrated with antigen-specific DR3- and DRw52-restricted T cell clones

HLA-DR3- and HLA-DRw52-associated functional polymorphism was investigated with selected tetanus toxoid (TT)-specific T cell clones. We have shown earlier that HLA-DR antigens are encoded by two distinct loci, DR beta I and DR beta III. The alloantigenic determinant(s) defined by the serological HLA-DR3 specificity map to the former, while the supratypic HLA-DRw52 determinants map to DR beta III. Furthermore, we have recently recognized by DNA sequencing three alleles of HLA-DRw52 at locus DR beta III, referred to as 52 a, b, and c. Our objective was to correlate the pattern of T cell restriction with the gene products of individual DR beta chain loci and with the three newly described alleles of locus DR beta III. Among the selected T cell clones, 5 reacted exclusively when TT was presented by HLA-DR3+ APCs (TT-DR3-APC). In contrast, two T cell clones were stimulated by TT-DRw52-APC. More specifically, these two T cell clones (Clones 10 and 16) were stimulated by different subsets of TT-DRw52-APC. Clone 16 responded to some DR3 and TT-DRw6-APC, while clone 10 was stimulated by other TT-DR3 and TT-DRw6, and all TT-DR5-APC. This same pattern of DRw52 restriction was found in panel, as well as in family studies. Because this suggested a correlation with the pattern of DRw52 polymorphism observed earlier by DNA sequencing and oligonucleotide hybridization, the APC used in these experiments were typed for the 52 a, b, and c alleles of locus DR beta III by allele-specific oligonucleotide probes. This distribution overlapped exactly with the stimulation pattern defined by the T cell clones. Clone 16 responded to TT-52a-APC, clone 10 to TT-52b-APC, and both clones to a TT-52c-APC. The response of the T cell clones was inhibited differentially by mAbs to DR. Raising TT concentration, or increasing HLA-class II expression with INF-gamma both affected the magnitude of response of the TT-specific clones but did not modify their specificities. These results demonstrate that a restriction specificity can be attributed to the DR beta III locus and illustrate the functional relevance of the polymorphism observed at this locus. This is of special interest in view of the striking difference in the pattern of structural diversity among alleles of DR beta I and DR beta III.

A cytotoxic human-human hybridoma antibody (TrH6) specific for HLA-DRw52

TrH6 is a new human-human hybridoma antibody (Ab) of IgM, lambda isotype. At concentrations of 17-5000 ng IgM/ml, TrH6 killed twelve out of fourteen lymphoblastoid cell lines that expressed DRw52, but none of the nine DRw53 homozygous lines. Both DRw52+ cells (LUY, TAB) not killed by TrH6 were DR8+, suggesting that these lines express a structural variant of DRw52 linked to DR8. The murine cytotoxic DRw52-specific mAb 7.3.19.1 (Koning et al. 1984) exhibited the same pattern of reactivity with DRw52+ cells as TrH6. However, unlike TrH6, 7.3.19.1 cross-reacted weakly with two DR7+DRw53+ homozygous cell lines, suggesting that the TrH6 epitope has a more limited distribution. The reactions with a panel of cells with known deletions in the HLA-region supported the conclusion that TrH6 is specific for DRw52. Further evidence was obtained in a competition RIA, where the murine mAbs L243 (anti-DR monomorphic) and 7.3.19.1 (anti-DRw52) inhibited binding of radiolabeled TrH6 to DRw52 homozygous cells. TrH6-coated magnetic beads provided a simple rosette-assay for typing of "buffy-coat" leukocytes for the TrH6 epitope.

Monoclonal antibody definition of multiple polymorphic epitopes on human leukocyte antigen-DRw52

Monoclonal antibodies have revealed complexity within the human leukocyte antigen class II antigens. We have studied epitopes present on a DR3 homozygous B-lymphoblastoid cell line using five polymorphic monoclonal antibodies produced and characterized in our laboratory. Serological analysis on a panel of B-cell lines revealed that the antibodies have different, but related, specificities (NDS9-anti-DR3, NDS10-anti-DR5, less than 3, less than w6, NDS11-anti-DR3, 5, w6, NDS12-anti-DR3, 5, w6, w8, NDS13-anti-DR3, 5, w6, w8+). Competitive radioimmunoassays and two-dimensional gel analyses demonstrated that whereas the epitopes recognized by the broadly reactive antibodies NDS10, 11, 12, and 13 reside on the same molecule, the epitope detected by NDS9 is present on a molecule with different electrophoretic mobility. Thus, using polymorphic monoclonal antibodies, we have defined multiple epitopes associated with DR3, which have different distributions at the population level.

Oligonucleotide genotyping shows that alleles at the HLA-DR beta III locus of the DRw52 supertypic group segregate independently of known DR or Dw specificities

Using locus- and allele-specific oligonucleotide probes, we have studied the polymorphism of the HLA-DR beta III locus within the haplotypes of the DRw52 supertypic group. DNA from a number of homozygous typing cells typed for both Dw and DR was used. The DR beta III polymorphisms, DRw52a and DRw52b, do not segregate with Dw typing, or with DR typing, indicating that the determinants responsible for Dw-defined T-cell response and for DR haplotypic recognition are not encoded by the DR beta III locus. Hence, we can conclude that these DR specificities are encoded by the other functional DR locus, DR beta I, while the DR beta III locus encodes only the supertypic product.

Immunochemistry of the HLA class II molecules isolated from a mouse cell transfected with DQ alpha and beta genes from a DR4 haplotype

Cells from a mouse B lymphoma were transfected by DQ alpha and DQ beta genes derived from a DR4 haplotype. Quantitatively, the resulting expression of human class II molecules was similar to that of human B lymphoblastoid cell lines. Qualitatively, the transformant class II molecules differed from "normal" class II molecules in their carbohydrate moiety. As for their antigenic specificity, they were shown to carry two determinants previously identified on DQ molecules controlled by DR4 haplotypes, i.e., DQw3 and DCHON. The transformant molecules did not carry a third DR4-associated specificity, DC5 (equivalent to TA10), and must possess a structure allelic to DC5. However, no corresponding alloantigenic specificity was detected by a screening of relevant alloantisera.