Serological and genetic identification of a bovine B lymphocyte alloantigen system

Production of alloantibodies against bovine B-lymphocyte antigens

A series of alloimmunizations were carried out between BoLA class I antigen typed bulls, with the aim of generating class II specific reagents. Of the antisera produced, seven demonstrated exclusively B cell reactivity. Another 19 sera reacted with both T and B cells from some animals and with B cells only in other cases. Suitable buffy coat absorptions removed T cell reactivity from some sera and shortened broader reactivities in certain B cell specific sera. Typing of separated T and B cells from related and unrelated animals permitted clustering of the sera into four groups. These groups behave as allelic specificities. The class II nature of the recognized structures was strongly indicated by two further pieces of evidence. The presence or absence of particular B cell antigens correlated with reactivity of cells in one-way mixed lymphocyte cultures. In addition, a number of the B cell specific sera were characterized by immunoprecipitation of radiolabelled lymphocytes. The precipitated products corresponded in molecular weight to alpha and beta chains of MHC class II dimers, as has been found in this and other species.

Production of alloantisera against class II bovine lymphocyte antigens (BoLA) by cross-immunization between class I matched cattle

This paper describes the production of alloantisera directed against bovine major histocompatibility complex (MHC) (BoLA) class II antigens in animals whose MHC phenotypes had been defined by one dimensional isoelectric focusing. Animals of closely matched BoLA class I types were selected by serology and subsequently typed for class I and class II by 1D-IEF of immunoprecipitated antigens. Those with similar class I type by both methods, but differing at the class II locus, were chosen for reciprocal immunization. Cross-immunization was by two skin implantations 6 weeks apart. The resulting antisera showed low titre after the first immunization and elevated titre 3 weeks after the second immunization. The sera reacted strongly with cells expressing specific BoLA class II antigens. The pattern of reactivity correlated well with IEF class II typing on a panel of animals representing all of the class II IEF types present in the Friesian population.

Mixed lymphocyte culture studies reveal complexity in the bovine MHC not detected by class I serology

The genetic structure of the bovine major histocompatibility complex (MHC) was investigated using the lymphocyte microcytotoxicity test for class I typing and the mixed lymphocyte culture (MLC) assay for class II typing. Using locally produced alloantisera and antisera from the Third International BoLA Workshop, 14 class I BoLA-A locus alleles were identified in the study population, a single herd of approximately 700 Holstein-Friesian cattle. Eleven of these were alleles recognized in the International Workshop and three were new alleles. An MLC titration assay was employed in conjunction with class I typing to define BoLA haplotypes and identify BoLA complex homozygotes. An embryo transfer family consisting of eight full sibling cattle including one BoLA complex homozygote was produced by half sibling mating. Five other BoLA complex homozygotes were subsequently identified in the herd. Six MLC defined class II haplotypes investigated in detail were designated BoLA-D1, D2, D3, D4, D5 and D7. BoLA-D1 was associated with the class I specificity BoLA-Aw6, D2 with Aw6 and the new class I specificity Ac3, D3 with Aw6 and Aw11, D4 with Aw10, D5 with Aw31 and Aw11, and D7 with Aw20. The discovery of four groups of class I identical-class II disparate haplotypes, and three pairs of class I disparate-class II identical haplotypes indicates the presence of considerable complexity in the BoLA complex that is not detected using class I serology.

Immunomagnetic isolation of cells for serological BoLA typing

This paper describes a totally new immunomagnetic (IM) technique adapted to serological BoLA typing. The basic technique has recently been developed by Vartdal et al. (1986) for serological HLA typing. The main advantage is that bovine mononuclear cells (e.g. T-cells and possibly their subsets, B-cells and monocytes) can be quickly and specifically isolated with high yield and viability from whole blood in a one-step procedure. This is achieved by magnetic separation of rosettes formed between the cells and superparamagnetic monosized polystyrene microspheres (Dynabeads TM) coated with cross-species reactive monoclonal antibodies (MAbs) specific for various human T-cell antigens or for HLA class II monomorphic epitopes. The cells are isolated within 5 min after a 5-min incubation at 4 degrees C. Magnetic separation of rosettes with a strong cobalt-samarium magnet eliminates all the laborious centrifugation steps necessary with conventional procedures. The isolated cells, still attached to the particles, are available for microcytotoxic assay. This is carried out within 55 min, including a two-step application of alloantiserum and complement and addition of acridine orange/ethidium bromide for the staining of viable (green) and dead (red) cells. The high viability of isolated cells gives a very low background kill compared with the conventional cytotoxic assay. The IM typing technique is also superior in sensitivity to the conventional technique as standardized for the international BoLA comparison test. The IM technique is likely to have its greatest impact on class II typing; class II positive cells being separated very efficiently. Polymorphic HLA class II MAbs detected likely polymorphic BoLA class II epitopes.

Serological relationships among antigens of the BoLA and the bovine M blood group systems

Alloimmunizations with either lymphocytes or red cells from donor cows positive for BoLA w16 and blood group M' antigens into recipients negative for these antigens produced antisera reactive in the cytotoxic test with w16-positive lymphocytes and in the haemolytic test with M'-positive erythrocytes. Similarly, alloimmunizations of blood group M1-negative recipients with either lymphocytes or red cells from donor cows possessing the M1 blood group factor produced antisera specifically reactive with lymphocytes and erythrocytes from M1-positive cattle. Absorptions with either lymphocytes or erythrocytes from individual animals of the same M antigenic type as the donor removed all haemolytic and cytotoxic reactivity. The results indicate that blood group M' and BoLA w16 share a similar antigenic structure. Likewise, blood group M1 has an antigenically similar counterpart which is also part of the BoLA system.

A study of BoLA class II antigens with BoT4+ T lymphocyte clones

It has hitherto proved difficult to phenotype cattle for class II histocompatibility antigens using standard serological techniques because of problems of reagent specificity and antigen expression on peripheral blood mononuclear cells (PBMs). We recently described the production of class II-specific alloreactive bovine T cell clones characterized by the BoT4+ phenotype. In this report we describe studies of the application of four such clones, derived from a single mixed leucocyte culture (MLC), for class II phenotyping in proliferation and cytotoxicity assay systems. Proliferation assays used irradiated PBM as stimulator cells and cytotoxicity assays used Theileria parva-infected lymphoblastoid cells as targets. Proliferation assays revealed three distinct specificities among the four clones indicating that they detected three different class II determinants. Furthermore, in a family study, the genes encoding the determinants recognized by the clones were found to be linked to the gene encoding the w10 class I A locus product on one of the w10-bearing haplotypes in our study population. Two of the clones were studied in cytolysis assays. Lack of cytolysis of one of the targets, which was derived from the PBM of an animal carrying a class II determinant detected in proliferation assay, was explained by the total lack of expression of class II antigens on the target cell line in question, as determined with 4 class II-specific monoclonal antibodies (mAb). We conclude that BoT4+ alloreactive clones provide a potentially useful and particularly discriminating way of detecting polymorphic class II antigens of cattle, especially when applied in assays of proliferative response to PBM.

Genomic hybridization of bovine class II major histocompatibility genes: 1. Extensive polymorphism of DQ alpha and DQ beta genes

Class II genes of the bovine major histocompatibility complex (MHC) were investigated by Southern blot analysis using human cDNA probes for DQ alpha, DQ beta, DR alpha and DR beta. The presence of a DQ-like and a DR-like subregion in cattle was clearly indicated. Highly polymorphic restriction fragment patterns were obtained when genomic DNA, digested with any one of the BamHI, EcoRI or PvuII restriction enzymes, was hybridized with the DQ alpha and the DQ beta probe. The polymorphisms were interpreted genetically by analysing five paternal half-sib families of the Swedish Red and White breed. The material comprised, besides the bulls, 28 offspring and their dams. The analysis resolved 9 and 12 allelic variants of DQ alpha and DQ beta respectively. Thus, this investigation establishes a method for routine typing of MHC class II gene polymorphism in cattle. The results were entirely consistent with close linkage of DQ alpha and DQ beta since no recombinant was found and since alleles at these loci occurred in complete linkage disequilibrium in the material investigated. Close linkage between DQ and the blood group locus M, which has previously been found to be closely linked to the serologically defined BoLA-A locus, was also indicated. In this study DNA was isolated from frozen semen samples of dead bulls, which shows that this type of analysis will be useful in genetic investigations in cattle breeds, where artificial insemination is practised.

Differential alloreactivity at SLA-DR and -DQ matching in two-way mixed lymphocyte culture

The major histocompatibility complex (MHC) class II molecules are heterodimeric cell surface glycoproteins important for antigen presentation to CD4+ T lymphocytes. Class II molecules of the pig MHC, termed SLA, identified so far include DR and DQ. Thus far, functional differences between products of different loci in SLalpha class II have not been well characterized. For detailed research on this issue, SLalpha-DRbeta1 and -DQbeta typings were newly developed by restriction fragment length polymorphism (RFLP) of the reverse transcriptase-polymerase chain reaction (RT-PCR) products. Using this method, several RFLP types were chosen from 13 CSK miniature pigs, and alloreactivities in two-way mixed lymphocyte culture (MLC) derived from these pigs were examined by cell proliferation assay using flow cytometry. The responses in MLC varied according to the degree of phenotype difference. In MLC from individuals of the same RFLP type in both SLA-DRbeta1 and -DQbeta, the proliferative responses showed slight reaction indicating that they were not so stimulated by each other. On the other hand, for the RFLP type-mismatching combination, the responses were strong indicating that they recognized each others alloantigens. The reactivity of only the DQbeta mismatching combination was as strong as those of only the DRbeta1 mismatching combination. These data indicate the important role of the DQ as well as DR molecule on alloreactivity in MLC.

Complexity of the bovine MHC class-II specificity DW3 as defined by alloantisera

Alloantisera related to the bovine major histocompatibility complex (MHC) class-II specificity Dw3 were investigated by cross-absorption experiments and by application of the monoclonal antibody-specific immobilization of lymphocyte antigen assay (MAILA). The absorption study revealed antibodies specific for an antigenic determinant shared by all Ds03 (Dw3)-positive animals, and several other antibody populations recognizing the locally defined specificities Ds10, Ds11 and Ds15, that are closely associated with Ds03. The results of the MAILA-assay indicate that the Ds03 specificity is probably encoded by DQ, whereas specificities Ds10 and Ds 11 are more closely associated with DR molecules. The data presented here provide the first evidence that bovine DR and DQ specificities can be identified separately by serological methods using alloimmune antisera.

Preparation of B lymphocyte-specific alloantisera by skin implant immunization of cattle

B lymphocyte-specific antisera were prepared by immunizing cattle on either one or two occasions with a subcutaneous implant of allogeneic skin and subsequently absorbing the antisera with platelets. After absorption 15/26 antisera displayed B lymphocyte-specific activity. Titres against B-enriched cells were 8-64 while residual titres against B-depleted cells were 1-8. In comparison, 3-6 immunizations with allogeneic leucocytes produced antisera of similar peak cytotoxic titres against donor PBL, and after platelet absorption 8/15 antisera displayed B lymphocyte-specific activity. Titres against B-enriched cells were 8-64 while residual titres against B-depleted cells were 2-8. The skin implant method was less time-consuming than the leucocyte immunization method.

Studies on the bovine major histocompatibility class I and class II antigens using homozygous typing cells and antigen-specific BoT4+ blast cells

Animals were identified from two sire lines as being homozygous for the class I bovine lymphocyte antigen (BoLA-A) w23. These animals were also shown to be homozygous for class II antigens (BoLA-D) which, however, differed between the two sire lines. Lymphocytes from these animals were then used either as stimulator cells in one-way mixed lymphocyte reactions (MLR) with all animals in the herd carrying the w23 antigen or as antigen presenting cells to bovine T4+ cell blasts. It was shown that, within each sire line, the genes encoding the MHC class I and class II antigens were closely linked. There were no detected recombinations between the MHC class I and class II regions nor within the BoLA-D region responsible for mixed lymphocyte reactivity. MLR typing of MHC class II antigens correlated with the results from T-lymphocyte proliferation studies. Cells from these cattle, which are homozygous at the class I and II MHC loci but differ in the class II antigen expressed, could be used to type the BoLA-D of other cattle.

The definition of five B lymphocyte alloantigens closely linked to BoLA class I antigens

B lymphocyte alloantigens in cattle were identified by serological analysis. Alloantisera were raised by skin implant immunization or leucocyte immunization and were absorbed with platelets to reduce class I-specific antibody activity. Leucocyte absorptions were done to reduce the complexity of some antisera. A panning technique was used to prepare B-enriched and B-depleted lymphocytes. Antisera which displayed anti-B cell activity over a number of dilutions were tested against 115 Charolais cattle, and 13 antisera were used to define five B lymphocyte alloantigens. These antigens were present on B lymphocytes but did not appear to be present, at least at the same density, on the majority of T lymphocytes or platelets. Family studies suggested that these antigens are coded by one or two loci which are closely linked to the bovine class I loci. These results suggest the five antigens are class II antigens of the major histocompatibility complex (MHC) of cattle.

Identification of two independent MHC class II antigens in a bovine lymphoblastoid cell line

Bovine major histocompatibility complex (MHC) class II antigens were investigated using monoclonal antibodies (MoAbs) with known MHC class II specificities in other species. Thirty-four MoAbs were tested for reactivity with bovine peripheral blood mononuclear (PBM) cells and the bovine lymphoblastoid cell line, BL3, by flow cytometry. Twenty-seven of 31 MoAbs tested, reacted with BL3 cells, and 22 of 25 MoAbs tested with PBM cells were reactive. MoAbs that reacted with BL3 cells were used to immunoprecipitate class II molecules from BL3 lysate labeled with [35S]methionine. Using sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) and autoradiography, many MoAbs were found to immunoprecipitate a single band of approximately 31,000 relative mass (Mr). MoAbs yielding successful immunoprecipitations and with known antigen specificity in other species were then used in sequential immunoprecipitations and two dimensional (2-D) non-equilibrium pH gradient electrophoresis (NEPHGE). The HLA-DR specific MoAb H4 and the predominantly HLA-DQ specific MoAb CC11.23 were used to identify the presence of two independent antigens in BL3 cell lysate. These class II molecules consist of alpha and beta chains.

Class I alleles of the bovine major histocompatibility system and their association with economic traits

A total of 179 Holstein cows from the Agriculture Canada Research Branch herd at Ottawa and 271 progeny-tested Canadian Holstein bulls were typed for 37 lymphocyte antigens. Each antigen appears to be controlled by a distinct, codominant allele of the bovine lymphocyte antigen (BoLA)-A locus, which is a class I locus of the bovine major histocompatibility system. Only 10 and 16 alleles were present in Holstein cows and bulls, respectively. The association between bovine lymphocyte antigens and economically important traits was examined in gene substitution models. Separate models were used for the cow and bull data. The substitution of the W6.1 allele for the W10 allele was associated with increased protein yield in the milk in both analyses. The results were also consistent with a previous report that the presence of the W10 allele was associated with increased fat percentage compared with some, but not all, of the other alleles. However, more research is necessary to confirm these findings and to determine the biological mechanisms underlying these associations.

Disease resistance and immune response genes in cattle: strategies for their detection and evidence of their existence

The possibility of breeding or genetically engineering cattle for resistance to disease has tremendous potential for increasing the efficiency of milk and meat production. In cattle and other species, major genes that control humoral and cellular immune responses to a variety of antigens have been mapped to a chromosomal region known as the major histocompatibility complex. However, resistance or susceptibility to viral, bacterial, and parasitic diseases in noninbred species is often a complex phenotype, with age, stress, and physiologic status all being important factors in the outcome of infection. This paper reviews the function of major histocompatibility complex gene products and the relationship between polymorphism of these genes and infectious diseases. A discussion of strategies for detecting immune response genes and disease associations is presented, with particular reference to the problems and advantages of working with cattle. The present knowledge of the bovine major histocompatibility complex and its relationship to immune responsiveness and disease resistance are also reviewed, with special consideration given to enzootic bovine leukosis because of the significant relationship between alleles of the bovine lymphocyte antigen system and resistance or susceptibility to subclinical progression of bovine leukemia virus infection. Finally, potential applications of this research to genetic improvement and animal health are considered.

The influence of the BoLA-A locus on reproductive traits in cattle

Associations between the major histocompatibility complex (MHC) and reproductive performance have been reported in humans, mice, rats, pigs and chickens. Only the A locus of the bovine major histocompatibility complex (BoLA-A) has been well characterized, and 42 alleles of this locus have been identified in American cattle. Four studies were conducted to examine the association between alleles of the BoLA-A locus and reproductive performance. Testis size, which is an indicator of early puberty and increased fertility in young bulls, was examined in 440 yearling bulls from nine breeds with a gene substitution model that included the effects of breed, sire, age of dam and age or weight of the bull. Estimated breeding value for twinning was examined with a gene substitution model with 204 cattle from a herd with a high frequency of twinning. Fertility of potential partners having BoLA-A locus alleles in common was examined in a prospective study involving 101 pure-bred Hereford cows mated by artificial insemination to four pure-bred Hereford bulls. The effect of homozygosity on birth weight, preweaning weight gain and post-weaning weight gain was estimated in a sample of 683 calves from nine breeds; 22% of the calves were apparently homozygous and 78% were heterozygous at the BoLA-A locus. There were significant and large effects of some BoLA-A locus alleles on paired testicular volume, but the analyses on the other traits did not show significant associations. Substitution of the W6.1 allele for the W9A allele reduced paired testicular volume by 150 +/- 44 cm3. The W6.1 allele has now been shown to influence a reproductive trait, a production trait and susceptibility to an economically important disease. Selection for these traits may influence the frequency of the large number of alleles at the BoLA-A locus.

Association between BoLA and subclinical bovine leukemia virus infection in a herd of Holstein-Friesian cows

The role of the bovine major histocompatibility system (BoLA) in subclinical bovine leukemia virus (BLV) infection was investigated in a herd of Holstein-Friesian cows (n = 240). The BoLA W8.1 allele was negatively associated with the presence of antibodies to the major BLV envelope glycoprotein, BLV-gp51 (corrected P less than 0.001, relative risk = 0.31). These results suggest that a BoLA-linked gene(s) may influence the early spread of BLV infection. Since B cells are the primary target of BLV infection, we then determined the relationship between BoLA-A locus phenotypes and B-cell numbers in peripheral blood of seropositive and seronegative cows. There were no significant differences between BoLA-A alleles for any hematological parameter in seronegative cows. Seropositive cows with the W12.1 allele had significantly greater absolute numbers of lymphocytes per microliter and B cells per microliter than did seropositive cows with other BoLA-A phenotypes (P less than 0.01, respectively). The average effect associated with the W12.1 allele in BLV-infected cows was an increase of 2010 B cells per microliter of whole blood relative to BLV-infected cows with other BoLA-A phenotypes. These results demonstrate that susceptibility to the polyclonal expansion of BLV-infected B lymphocytes is associated with the W12.1 allele in Holstein-Friesian cattle. Compared with results of a previous study in a herd of Shorthorn cattle, it appears that resistance and susceptibility to subclinical progression of BLV infection are associated with different BoLA-A locus alleles in different cattle breeds.

A method of purifying sheep sIg+ lymphocytes as a tool for class II MHC antigen analysis

A method is described for the purification of sheep lymphocytes carrying class II MHC antigens. After incubation of purified blood lymphocytes on anti-IgM-coated petri dishes, the adherent fraction contained 95% sIg-positive cells determined by immunofluorescence. When tested with cross-reacting anti-class II (bovine and human) monoclonal antibodies, more than 95% of these cells were positive either by immunofluorescence or cytotoxicity. This technique will permit studies of the polymorphism of sheep class II antigens.

Cross reaction of monoclonal antibodies to human MHC class I and class II products with bovine lymphocyte subpopulations

Peripheral blood lymphocytes (PBL) from cattle have been separated into T & B cell subpopulations using a panning technique. These T and B cell preparations have then been tested by direct and indirect complement mediated cytotoxicity tests with a series of monoclonal antibodies (Moabs) reacting with HLA class I and class II products. The anti-class I monoclonals were monomorphic or non-reactive and where reactive killed both B and T cells. The anti-class II monoclonals reacted only with B lymphocytes. There was no relationship between their reactivity pattern and any BoLA specificity.

The antibody response to bovine lymphocyte alloantigens

Antibodies were raised against lymphocyte cell-surface antigens by multiple immunisations with purified lymphocytes or by the exchange of skin allografts. Eighteen of 21 cattle immunised with lymphocytes raised a detectable cytotoxic antibody response. The serum antibody from 10 responders recognized only common lymphocyte antigens, those antigens which are present on all peripheral blood lymphocytes. One animal responded only to B lymphocyte antigens while 7 others responded to both classes of antigens. The amount of antibody produced varied greatly between individuals; antibody titres ranged from 1 to 1028. Antibody raised early in the response was sensitive to treatment with 2-mercaptoethanol (2-ME) suggesting that IgM was the predominant class of immunoglobulin. Subsequently antibody became resistant to this treatment suggesting the appearance of IgG. The antibody responses following the exchange of skin grafts were very similar in all 12 cattle studied. High titred antibody to common lymphocyte antigens was detected in the serum 14 days after grafting. The early antibody activity was sensitive to 2-ME treatment but became totally resistant within 14 days. Total peak antibody titres ranged from 128-2048. Antibody to B lymphocyte antigens was identified in 8 of the 12 cattle. The responses to B lymphocyte antigens were similar to those against the more widely distributed common lymphocyte antigens with respect to time of antibody appearance, time of peak titre and sensitivity to 2-ME. Peak titres ranged from 2 to 32. The change in antibody specificity with time was also studied. Sera from 11 of the 18 cattle which had responded against lymphocytes showed an increase or broadening in reaction frequency as immunisations increased, suggesting the production of antibody to secondary specificities. In the cattle which had been skin grafted, the broadest reaction patterns were seen 14 to 21 days after grafting. The broadest reaction patterns were seen when the antibody responses were at their highest titre levels and narrowed as titres decreased.