Characterization of a subset of bovine T lymphocytes that express BoT4 by monoclonal antibodies and function: similarity to lymphocytes defined by human T4 and murine L3T4

We report the identification of a subset of bovine T cells by two monoclonal antibodies (mAb), IL-A11 and IL-A12, and some functional analyses of these cells. Both mAb precipitate two polypeptides, called BoT4, with apparent molecular mass of 52 and 55 kilodaltons. The epitopes recognized by these two mAb are different, however. BoT4 is found on approximately 70% of thymocytes and 30% of peripheral blood mononuclear cells (PBM), is not expressed by monocytes or B cells, and is found on cells in the T-dependent areas of lymph nodes. BoT4+ lymphocytes purified by a fluorescence-activated cell sorter proliferate in response to mitogenic and alloantigenic stimulation without addition of exogenous growth factors, whereas BoT4- lymphocytes do not. Monoclonal antibodies IL-A11 and IL-A12 have no effect on mitogen- (PHA and Con A) or alloantigen-induced proliferation of PBM. Monoclonal antibody IL-A12 has no inhibitory effect on the cytolytic activity of bulk populations of alloreactive T lymphocytes, and most of the cytolytic activity generated in mixed leukocyte culture is ascribable to the BoT4- population. Using cloned alloantigen-specific lymphocytes, we found that the ability of BoT4+ clones to proliferate to alloantigenic stimuli without exogenous growth factors is a characteristic of some clones, as is susceptibility to inhibition of proliferation by mAb IL-A12. These results implicate the BoT4 molecule in antigen recognition but indicate that the requirement for BoT4 is variable among clones. Our findings, together with those in the companion paper, which provides evidence that BoT4+ lymphocytes are class II restricted, indicate that BoT4+ lymphocytes are the bovine equivalent of Leu3/T4+ lymphocytes of humans and analogous lymphocytes of other species.     

A genomic prediction model for racecourse starts in the Thoroughbred horse

Durability traits in Thoroughbred horses are heritable, economically valuable and may affect horse welfare. The aims of this study were to test the hypotheses that (i) durability traits are heritable and (ii) genetic data may be used to predict a horse's potential to have a racecourse start. Heritability for the phenotype ‘number of 2‐ and 3‐year‐old starts’ was estimated to be  = 0.11 ± 0.02 (n = 4499). A genome‐wide association study identified SNP contributions to the trait. The neurotrimin (NTM), opioid‐binding protein/cell adhesion molecule like (OPCML) and prolylcarboxypeptidase (PRCP) genes were identified as candidate genes associated with the trait. NTM functions in brain development and has been shown to have been selected during the domestication of the horse. PRCP is an established expression quantitative trait locus involved in the interaction between voluntary exercise and body composition in mice. We hypothesise that variation at these loci contributes to the motivation of the horse to exercise, which may influence its response to the demands of the training and racing environment. A random forest with mixed effects (RFME) model identified a set of SNPs that contributed to 24.7% of the heritable variation in the trait. In an independent validation set (n = 528 horses), the cohort with high genetic potential for a racecourse start had significantly fewer unraced horses (16% unraced) than did low (27% unraced) potential horses and had more favourable race outcomes among those that raced. Therefore, the information from SNPs included in the model may be used to predict horses with a greater chance of a racecourse start.     

The CD45 locus in cattle: allelic polymorphism and evidence for exceptional positive natural selection

Cattle in Africa are a genetically diverse population that has resulted from successive introduction of Asian Bos indicus and European B. taurus cattle. However, analysis of mitochondrial genetic diversity in African cattle identified three lineages, one associated with Asian B. indicus, one with European B. taurus, and a third ascribed to an indigenous African sub-species of cattle. Due to their extended coevolution, indigenous African herbivores are generally tolerant to endemic African pathogens. We are interested in identifying alleles derived from the indigenous African cattle that may be associated with tolerance to African pathogens. An analysis of the locus which encodes the abundant plasma membrane-associated tyrosine phosphatase, CD45, identified three highly divergent allelic families in Kenya Boran cattle. Analysis of allelic distribution in a diverse range of cattle populations suggests a European B. taurus, an Asian B. indicus, and an African origin. This demonstrates not only significant allelic polymorphism at the CD45 locus in cattle but also convincing autosomal evidence for a distinct African sub-species of cattle. Furthermore, maximum-likelihood analysis of selection pressures revealed that the CD45 locus is subject to exceptionally strong natural selection which we suggest may be pathogen driven.     

Phylogenetic analysis of the tribe Bovini using microsatellites

The objective of the present study was to determine if the generally accepted phylogenetic relationships in the tribe Bovini correspond to a phylogenetic scheme derived from polymorphisms at 20 bovine microsatellite loci. This study comprises 17 representative populations: eight Bos taurus, two Bos indicus, one Poëphagus, one Bibos, one Bison, three Bubalus and one Syncerus. Phylogenetic analyses using (δμ)² and chord (D_C) distances revealed substantial divergence among species. Neighbor‐joining trees with both distance measures showed only minor differences. Bos taurus and Bos indicus grouped first, followed by Bos frontalis (Mithan) and Bos grunniens (Yak), Bison bison branched off next and Bubalus bubalis and Syncerus caffer emerged as the two most divergent species from the Bos clade. These findings would suggest that Bos, Poëphagus, and Bibos should be integrated into the Bos genus with each group classified as a subgenus. On the other hand, Bison, Bubalus and Syncerus should each be considered a separate genus. Direct estimates of the divergence times were calculated using the (δμ)² genetic distance. Bos taurus and Bos indicus were estimated to have diverged 0·31–0·82 MYA, Bos and Poëphagus: 0·57–1·53 MYA, Bos and Bibos: 0·57–1·52 MYA, Bos and Bison: 0·46–1·23 MYA, Bos and Bubalus: 1·85–4·93 MYA and Bos and Syncerus: 0·98–2·61 MYA.     

Taurine and zebu admixture in Near Eastern cattle: a comparison of mitochondrial, autosomal and Y-chromosomal data

Eight Bos taurus cattle breeds from the Near East region were screened with a Bos indicus (zebu)-diagnostic Y-specific microsatellite (INRA124) to estimate the proportion of zebu Y chromosomes in each population. This value was compared with previously published values for zebu introgression for both the mitochondrial and autosomal gene pools of the same breeds. All breeds revealed considerable levels of introgression from B. indicus cattle when the autosomal data were taken into consideration; this was particularly apparent in cattle populations from Iraq in the east, and declined in the populations further west towards Anatolia. This non-random pattern of introgression and admixture is suggestive of the introduction of zebu cattle from the region corresponding to present-day Iran and northern Pakistan. In addition, the maternal and paternal markers demonstrate that the movement of cattle into and within the Near East was complex.     

Evidence for biogeographic patterning of mitochondrial DNA sequences in Eastern horse populations

Equine mitochondrial DNA (mtDNA) phylogeny reconstruction reveals a complex pattern of variation unlike that seen in other large domesticates. It is likely that this pattern reflects a process of multiple and repeated, although not necessarily independent, domestication events. Until now, no clear geographic affiliation of clades has been apparent. In this study, amova analyses have revealed a significant non-random distribution of the diversity among equine populations when seven newly sequenced Eurasian populations were examined in the context of previously published sequences. The association of Eastern mtDNA types in haplogroup F was highly significant using Fisher's exact test of independence (P = 0.00000). For the first time, clear biogeographic partitioning has been detected in equine mtDNA sequence.     

Mitochondrial DNA sequence diversity in extant Irish horse populations and in ancient horses

Equine mitochondrial DNA sequence variation was investigated in three indigenous Irish horse populations (Irish Draught Horse, Kerry Bog Pony and Connemara Pony) and, for context, in 69 other horse populations. There was no evidence of Irish Draught Horse or Connemara Pony sequence clustering, although the majority of Irish Draught Horse sequences (47%) were assigned to haplogroup D. Conversely, 31% of the Kerry Bog Pony sequences were assigned to the rare haplogroup E. In addition to the extant population analyses, ancient DNA sequences were generated from three out of four Irish archaeological specimens, all of which were assigned to haplogroup A.     

Generation and maintenance of diversity in the cattle MHC class I region

Major histocompatibility complex (MHC) class I genes play a crucial role in the immune defence against intracellular pathogens. An important evolutionary strategy is to generate and maintain a high level of diversity in these genes. Humans express three highly polymorphic classical MHC class I genes (HLA-A, HLA-B and HLA-C). In contrast, some species, for example rat and rhesus macaque, maintain diversity by generation of haplotypes that vary considerably with regard to the number and combination of transcribed genes. Cattle appear to use both strategies. We show that various combinations of six apparently classical genes, three of which are highly polymorphic, are transcribed on different haplotypes. Although additional sequences were identified in both cDNA and gDNA, it was not possible to assign them to any of these defined genes. Most were highly divergent or were non-classical class I genes. Thus, we found little evidence for frequent duplication and deletion of classical class I genes as reported in some other species. However, the maintenance of class I diversity in cattle may involve limited gene shuffling and deletion, possibly as a result of unequal crossing-over within the class I region.The first two authors made an equal contribution to this work.