Joint Report of the Fifth International Workshop on Lymphocyte Alloantigens of the Horse, Baton Rouge, Louisiana, 31 October-1 November 1987

Six laboratories participated in the Fifth International Workshop on Lymphocyte Alloantigens of the Horse, testing 132 alloantisera against lymphocytes of 880 horses chosen to represent different families and breeds. Most of the alloantisera were produced by lymphocyte immunization between horses matched at the ELA-A locus. All horses were also tested with antisera contributed to the workshop by participating laboratories which identified ELA specificities A1-A10 and W12-W21. Previously identified workshop specificities ELA-W14, W15 and W19 were accepted as products of the ELA-A locus based on family and population studies by the workshop. Their designations were changed to ELA-A14, ELA-A15 and ELA-A19, respectively. Two new specificities were identified, namely ELA-W22 (W22) and ELA-W23 (W23). Population and family studies indicated that W22 and W23 as well as W13 are products of an ELA locus other than ELA-A. The presence of these specificities was correlated with the presence of certain ELA-A locus specificities, e.g. W13 with A3, W22 with A2 and W23 with A5. However, the association was not complete and W13, W22 and W23 also segregated with other ELA-A specificities in some families. Evidence for recombination was found between the ELA-A locus and the locus or loci encoding these specificities resulting in seven recombinant haplotypes found among the data presented in this workshop. Further studies are required for definitive assignment of the specificities to a class I or class II locus.     

Analysis of a horse family with a crossing-over between the ELA complex and the A blood group system

A horse family in which a recombination occurred in the chromosome region coding for the serological specificities of the ELA complex and those of the A blood group system of a mare was further analysed by mixed lymphocyte reaction (MLR) and Southern blot hybridization. This family consisted of a stallion, a mare and five full sibs. The stallion and the mare were heterozygous for internationally recognized ELA specificities while only the mare was heterozygous for the A blood group system. MLR between all members of the family confirmed that the stallion possessed two different ELA haplotypes and suggested that recombination in the mare occurred outside the segment delimited by the ELA-A locus and the MLR region. DNA samples from all individuals were investigated by Southern blot analysis using three restriction enzymes (EcoRI, HindIII or TaqI), three human HLA probes (one of class I cDNA and two of class II probes), one cDNA (DR beta) and one genomic (DQ alpha). Class I and class II restriction fragments of the mare segregated in accordance to the ELA specificities and thus clearly confirming that the crossing-over did not occur between the ELA-A gene and the class I, class II region nor between DR beta and DQ alpha subsets. The A blood group genetic determinants would thus be situated outside the ELA region defined by class I and class II genes.     

Evidence of a second polymorphic ELA class I (ELA-B) locus and gene order for three loci of the equine major histocompatibility complex

Two antisera, B-442 and R-2046, were produced by immunizing offspring with purified peripheral blood lymphocytes from a parent matched for the ELA-A specificity carried on the unshared haplotype. Absorption analysis demonstrated that these antisera contained at least two families of cytotoxic antibodies, one directed against antigens present on T and B cells, and a second directed preferentially against antigens present on surface Ig positive cells. Immunoprecipitation studies using these antisera demonstrated that both antisera contain antibodies specific for glycoproteins with molecular weights characteristic of class I and class II MHC antigens. In lymphocyte typing tests of unfractionated lymphocytes, only the class I activity was readily detectable since the class II activity killed less than 25% of the cells. Family studies demonstrated that these antisera recognize products of genes linked to the ELA system. Based on two recombinants in an extended family it became apparent that the specificities detected by B-442 and R-2046 are not products of the ELA-A locus, but rather they are products of at least one other locus, defined in this paper as ELA-B. In this family a third recombinant was found between the A blood group system and the ELA-A locus. Based on these three recombinants, the most probable linear relationship of the following genes is: A blood group system/ELA-A/ELA-B.     

The analyses of antigen and DNA polymorphism within the bovine major histocompatibility complex: 1. The class I antigens

Summary. Serology, isoelectric focusing (IEF) of expressed antigens, and restriction fragment length polymorphisms (RFLP) were compared for the identification of BoLA class I haplotypes. Expressed antigens identified as bands by IEF correlated well with serological definition confirming and extending our earlier findings (Joosten et al. 1988). Comparison of serology and isoelectric focusing bands with restriction fragments was more complicated; fragments were found which correlated both with broadly reacting and antigen specific sera. We also found correlation of fragments with two or more sera which showed no cross-reactivity. Fragments unique to particular haplotypes were also observed.
Serology remains the simplest method of typing BoLA class I antigens. Isoelectric focusing generally agrees with serological definition of antigens and detects antigens not yet defined by serology. It may also be useful in defining the products of other expressed BoLA class I loci. In order to identify RFLPs which could be used for typing, comparison with serology or IEF is essential. Haplotype specific RFLPs could be useful in identifying genes linked to the MHC.     

The analyses of antigen and DNA polymorphism within the bovine major histocompatibility complex: 1. The class I antigens

Serology, isoelectric focusing (IEF) of expressed antigens, and restriction fragment length polymorphisms (RFLP) were compared for the identification of BoLA class I haplotypes. Expressed antigens identified as bands by IEF correlated well with serological definition confirming and extending our earlier findings (Joosten et al. 1988). Comparison of serology and isoelectric focusing bands with restriction fragments was more complicated; fragments were found which correlated both with broadly reacting and antigen specific sera. We also found correlation of fragments with two or more sera which showed no cross-reactivity. Fragments unique to particular haplotypes were also observed. Serology remains the simplest method of typing BoLA class I antigens. Isoelectric focusing generally agrees with serological definition of antigens and detects antigens not yet defined by serology. It may also be useful in defining the products of other expressed BoLA class I loci. In order to identify RFLPs which could be used for typing, comparison with serology or IEF is essential. Haplotype specific RFLPs could be useful in identifying genes linked to the MHC.     

One-dimensional isoelectric focusing and immunoblotting of bovine major histocompatibility complex (BoLA) class I molecules and correlation with class I serology

One-dimensional isoelectric focusing followed by immunoblotting and development of the immunoblots with the monoclonal antibody HC-10, raised against denatured HLA class I heavy chains, was used to demonstrate biochemical variation in cattle MHC (BoLA) class I molecules. The bands obtained correlated well with BoLA-A specificities. Two or three bands were identified for the specificities w7, w8, w16, w18, w21, cph43 and cph49, whereas no bands were observed for the specificity w2. Two serologically indistinguishable subtypes of specificity w18 were identified.     

Characterization of class I bovine lymphocyte antigens (BoLA) by one-dimensional isoelectricfocusing

BoLA class I antigens were characterized in a group of British and Dutch Friesian cattle by one-dimensional isoelectric focusing (1D-IEF) and the results compared with serology using alloantisera and microcytotoxicity. For IEF analysis, non-stimulated peripheral blood mononuclear cells (PBM) were metabolically labelled with 35S methionine, detergent lysates were prepared and MHC molecules precipitated with the monoclonal antibodies (mAbs) W6/32 or B1.1G6. Staphylococcus protein A precipitated antigens were separated on a vertical slab gel under denaturing conditions. The banding patterns seen for the W6/32 precipitated molecules obtained by 1D-IEF were compared with the serological specificities. Characteristic banding patterns were observed for most serological specificities as well as workshop undefined haplotypes. These patterns were seen both in families and the outbred population. In families IEF haplotypes segregated with serotypes. Additional MHC class I products were suggested by variable banding patterns for different w10 haplotypes and when using the different mAbs. A pulse chase experiment with a w12 animal also suggested more than one expressed product. The w2 and w5 specificities were not precipitated by either W6/32 or B1.1G6 and w6.2 and w6.4 were precipitated by W6/32 but not by B1.1G6. These results show that 1D-IEF is useful for BoLA typing. For the characterization of class I antigens, however, much depends on the mAbs used.     

DNA sequence analysis of serologically detected ELA class II haplotypes at the equine DQP locus

The genetic diversity at the ELA DQβ locus was investigated using polymerase chain reaction and DNA sequencing. Based upon serological methods 16 class II homozygous animals were selected and their genomic DNA was used. A DQβ gene from an equine cDNA library was also sequenced. Our methology and the similarity between the genomic and the cDNA sequences suggest that the studied locus is expressed on equine lymphocytes. In the predicted amino acid sequence the most extensive variation is located at residues 56–60. The pattern of these five amino acids is strongly correlated to the serological ELA class II specificities (W13, W22, W23, Be200). The alleles corresponding to the W23 specificity are the most divergent among the equine DQβ alleles and also from other mammalian DQβ sequences.     

At least two loci encode polymorphic class I MHC antigens in the horse

Summary. Six monoclonal antibodies and ten alloantisera were used to precipitate cell surface molecules of approximately 44kDa (class I MHC antigens) from radiolabelled equine peripheral blood lymphocytes. All ten antisera were raised against antigens of a single donor horse (horse 0834, ELA-A2,-A2). Four methods of producing antisera were compared: one or two pregnancies, skin allografting, and skin grafting followed by pregnancy. Immunization by pregnancy appeared to produce antibodies against class I products only, while skin grafting raised antibodies to class II antigens as well. Nine of the antisera were raised across an entire MHC haplotype barrier, while one recipient carried the ELA-A2 antigen of the donor. The pregnancy antiserum raised across this barrier probably identifies a second polymorphic class I locus in the horse. Sequential immunoprecipitation using this antiserum in the first stage and an anti-MHC haplotype antiserum or monoclonal antibody reagent in the second stage supported this hypothesis. Gene products of this second ELA class I locus are immunogenic in pregnancy.     

Joint Report of the Fourth International Workshop on Lymphocyte Alloantigens of the Horse, Lexington, Kentucky, 12–22 October 1985

Summary. The workshop consisted of 12 monthly cell exchanges of full-sibling families among the 10 participating laboratories. A total of 33 parents, 52 offspring and five unrelated horses were typed by each laboratory using local antisera. The raw data were submitted for central analysis before any identification of the animals was revealed.
Confidence derived from the consistent agreement between the laboratories on the assignment and segregation of the first 10 ELA-W specificities led to the removal of the W (workshop) notation and acceptance of full status as locus A antigens. The seemingly supertypic W11 specificity, however, remained unchanged.
Ten additional specificities were seen to segregate with the ELA system, suggesting either splits of previously described specificities or products of linked loci. The workshop (W) notation was given to the 10 specificities W12-W21, befitting their status as specificities under study.
The previously described ELY-1.1 specificity, characterized by segregation independent from the ELA system, was confirmed along with a new specificity, ELY-1.2, which behaves as an allele of ELY-1.1. For informative families, the two specificities showed codominant expression and appeared to constitute a closed, autosomal system.
The ELY-2.1 specificity was confirmed to segregate independently from the ELA-A and ELY-1 loci.     

A single amino acid difference within the alpha-2 domain of two naturally occurring equine MHC class I molecules alters the recognition of Gag and Rev epitopes by equine infectious anemia virus-specific CTL

Although CTL are critical for control of lentiviruses, including equine infectious anemia virus, relatively little is known regarding the MHC class I molecules that present important epitopes to equine infectious anemia virus-specific CTL. The equine class I molecule 7-6 is associated with the equine leukocyte Ag (ELA)-A1 haplotype and presents the Env-RW12 and Gag-GW12 CTL epitopes. Some ELA-A1 target cells present both epitopes, whereas others are not recognized by Gag-GW12-specific CTL, suggesting that the ELA-A1 haplotype comprises functionally distinct alleles. The Rev-QW11 CTL epitope is also ELA-A1-restricted, but the molecule that presents Rev-QW11 is unknown. To determine whether functionally distinct class I molecules present ELA-A1-restricted CTL epitopes, we sequenced and expressed MHC class I genes from three ELA-A1 horses. Two horses had the 7-6 allele, which when expressed, presented Env-RW12, Gag-GW12, and Rev-QW11 to CTL. The other horse had a distinct allele, designated 141, encoding a molecule that differed from 7-6 by a single amino acid within the alpha-2 domain. This substitution did not affect recognition of Env-RW12, but resulted in more efficient recognition of Rev-QW11. Significantly, CTL recognition of Gag-GW12 was abrogated, despite Gag-GW12 binding to 141. Molecular modeling suggested that conformational changes in the 141/Gag-GW12 complex led to a loss of TCR recognition. These results confirmed that the ELA-A1 haplotype is comprised of functionally distinct alleles, and demonstrated for the first time that naturally occurring MHC class I molecules that vary by only a single amino acid can result in significantly different patterns of epitope recognition by lentivirus-specific CTL.     

Use of isoelectric focusing to define major histocompatibility complex class I polymorphism in goats

We have used biochemical methods to extend and improve serological class I typing using a panel of 77 Swiss goats of the Saanen breed, comprising dam-offspring combinations from six half-sib sire families and several unrelated animals. Of these animals class I molecules were precipitated from cell lysates with the mAb B1.1G6 and HC10. Immunoprecipitates were analysed by SDS-PAGE and 1D-IEF. There was a good agreement between class I serological types and IEF banding patterns. We have identified three new class I specificities and subdivided the Bel 7 specificity. IEF has enabled us to make planned immunizations to produce antisera to the new specificities. New evidence for the expression of a second class I locus product in the Be7 haplotype has been found.     

Serological and genetic study of the ELA W21 specificity

Investigations on the W21 specificity showed that this antigen is expressed on lymphocytes and platelets but not on erythrocytes. The molecule carrying the antigen W21 moves in the cell membrane independently from ELA locus A and B encoded antigens, as observed in 'lysostripping'. The W21 specificity occurs with very different gene frequencies in various breeds. In informative families it segregates together with defined gene products of the MHC region. The data suggest strongly that the W21 specificity belongs to the ELA system as a class I gene product, but is governed by a separate locus than the known locus A and locus B allelic series.     

An analysis of class I antigens of man and other species by one-dimensional IEF and immunoblotting

A procedure for the molecular identification of MHC class I products based on 1-D IEF and subsequent immunoblotting is described. Optimal conditions for 1-D IEF, the electrophoretic transfer of proteins out of denaturing, nonionic detergent-containing gels to nitrocellulose, and the requisite antibodies, both polyclonal and monoclonal, for the visualization of class I heavy chains have been established. Cross-reactivity of antibodies has enabled the biochemical analysis of class I heavy chains in the dog. The procedure reported here requires modest amounts of cells and allows a rapid molecular characterization of class I heavy chain polymorphisms in man and other species without the need for radiochemical methods.Abbreviations used in this paper FCS fetal calf serum - MHC major histocompatibility complex - NP-40 Nonidet P-40 - PBL peripheral blood lymphocytes - PHA phytohemagglutinin - RaHC rabbit anti-heavy chain serum - TX-114 Triton X-114 - 1-D IEF one-dimensional isoelectric focusing     

Serological identification of HLA-B13 subtypes.

A serological approach is used to confirm subtypes of HLA-B13 originally observed by one-dimensional isoelectric focusing (1D-IEF). Sixty anti-B13 alloantibody sera were screened against Chinese panel cells. Two clusters of sera showing distinct reactive patterns were identified. One is a shorter reactive pattern than the other. Using these serological reaction patterns, the B13 antigen can be divided into two subtypes, B13.1 and B13.2, in the Chinese population. These serological subtypes appear to correlate well with the 1D-IEF patterns of B13 subtypes. The serological subtyping is also in agreement with the differences in nucleotide sequence previously determined to exist in B13 antigen subtypes. Family studies show that both B13.1 and B13.2 segregate as HLA-B locus alleles. Gene frequencies for B13.1 and B13.2 were 0.0676 and 0.0612, respectively, in our study population of 337 southern Han Chinese.     

Biochemical evidence of the expression of two major histocompatibility complex class I genes on bovine peripheral blood mononuclear cells

For a long time, the bovine major histocompatibility complex (MHC) (BoLA) class I region was characterized, rather uniquely among mammalian species, as having one expressed locus. Recent reports have suggested otherwise. Selective immunoprecipitation and molecular characterization of products enable a decisive answer to the question of whether there is indeed more than one locus expressed. Therefore, we characterized serologically defined w10 encoding haplotypes in European and African cattle by immunoprecipitation of [35S]-methionine-labelled peripheral blood mononuclear cells (PBMC), followed by one- and two-dimensional isoelectric focusing (1D/2D-IEF) of cell lysates. Monoclonal antibodies (mAb) used were directed against either human class I monomorphic determinants (W6/32 and B1.1G6) or bovine polymorphic determinants expressed on products encoded by serologically defined w10 encoding haplotypes of Boran and Friesian cattle. Sequential immunoprecipitations with W6/32 and B1.1G6 using lysates of PBMC of British Friesian cattle, revealed that from this haplotype W6/32 precipitated one product, whereas B1.1G6 precipitated two products. The product precipitated in addition appeared to be the one that was selectively precipitated by the mAb directed against polymorphic determinants on a product of w10 encoding haplotypes. Additionally, peptide maps of protease V8-digested precipitates showed that this particular 'w10' associated product was distinctly different from the product recognized by W6/32. Thus, we suggest that the two products are distinct gene products and that the product with higher pI is associated with the serologically defined A-locus product, whereas the product with lower pI is the putative second locus product. In the African Boran breed, variants of the serologically defined w10 specificity were found on the basis of IEF typing. These variants appeared to be associated with different second locus products. Therefore, we conclude that serologically defined w10 encoding haplotypes encode at least two independent class I locus products, expressed on normal bovine PBMC. In IEF analysis the additional use of mAb recognizing polymorphic determinants on serologically defined A-locus products highly facilitated the detection and typing of second locus products.     

Joint Report of the Fourth International Bovine Lymphocyte Antigen (BoLA) Workshop, East Lansing, Michigan, USA, 25 August 1990

Blood samples from 54 animals were exchanged between 15 laboratories in nine countries to improve and expand BoLA class I and class II typing. A total of 27 out of 33 (82%) of previously accepted BoLA-w specificities were represented within the cell panel. Seventeen new serum-defined BoLA specificities were accepted by the workshop participants, thus expanding the number of internationally recognized BoLA specificities to 50. The large number of new specificities detected resulted from the number of serological reagents used (n = 1139) and the genetic diversity of the cell panel. Confidence derived from the high percentage of agreement between the laboratories on antigen detection (97.3%; r = 0.84) permitted the removal of the workshop (w) notation from 23 BoLA-w specificities and their acceptance as full status BoLA-A antigens. Two new non-BoLA antigens were also detected, one completely included within the red blood cell factor S' (BoLy-S'), whereas a second (BoLy-w1) did not show any association with tested red blood cell factors. A comparison between serological, isoelectric focusing (IEF) and DNA typing for BoLA class II polymorphism was conducted with a subset of workshop cells. Correlation between the three methods was significant for three combinations of alleles. Three other serologically defined class II specificities were correlated with DR and/or DQ restriction fragment length polymorphism (RFLP) types, whereas six additional IEF types were correlated with DR and/or DQ RFLP types (r greater than or equal to 0.50). Several new IEF, DRB, DQA and DQB RFLP patterns were identified. In 46 animals that were typed for BoLA-DR and DQ genes by RFLP analysis, 46 different BoLA haplotypes were tentatively defined. These 46 haplotypes were distinguished by 31 serologically-defined BoLA-A alleles (and 2 'blanks'), 15 DRB RFLP types (plus up to 10 new DRB RFLP patterns) and 23 DQA-DQB haplotypes.     

Joint Report of the Second International Workshop on Lymphocyte Alloantigens of the Horse, held 3–8 October 1982

The Second International Workshop on Lymphocyte Alloantigens of the Horse was held 3–8 October 1982. At this workshop, the 6 specificities identified at the first workshop were confirmed and an additional 5 new specificities were identified and given workshop nomenclature. Four of the new specificities, products of the ELA locus, were named ELA-W7, W8, W9, and W10. An additional specificity, designated ELY-2.1, is the product of a locus independent of the ELA locus.
Cell isolation methods were compared at this workshop, Technical variation in methods clearly affected reactivity of many reagents. However, when highly selected reagents were used, antigen assignment did not differ regardless of the cell isolation method. Based on the comparison of methods, isolation procedures in which thrombin was used were more effective than those relying on carbonyl iron or slow centrifugation.