Localization of the calcium release channel gene in cattle and horse by in situ hybridization: evidence of a conserved synteny with glucose phosphate isomerase

In situ hybridization techniques were used to localize regionally the calcium release channel (CRC) gene on cattle and horse chromosomes, using a porcine CRC cDNA probe. In cattle, the hybridization signal peaked on the 18q23-q26 bands and in horse on the 10pter region. Previous studies have shown that the glucose phosphate isomerase (GPI) gene localizes at the same site in both species, indicating that the two loci are syntenic. As CRC and GPI are syntenic in human, pig and mouse, the present results in cattle and horse represent another example of synteny conservation in the evolution of mammalian chromosomes.     

A synteny map of the horse genome comprised of 240 microsatellite and RAPD markers

To generate a domestic horse genome map we integrated synteny information for markers screened on a somatic cell hybrid (SCH) panel with published information for markers physically assigned to chromosomes. The mouse-horse SCH panel was established by fusing pSV2neo transformed primary horse fibroblasts to either RAG or LMTk mouse cells, followed by G418 antibiotic selection. For each of the 108 cell lines of the panel, we defined the presence or absence of 240 genetic markers by PCR, including 58 random amplified polymorphic DNA (RAPD) markers and 182 microsatellites. Thirty-three syntenic groups were defined, comprised of two to 26 markers with correlation coefficient (r) values ranging from 0.70 to 1.0. Based on significant correlation values with physically mapped microsatellite (type II) or gene (type I) markers, 22 syntenic groups were assigned to horse chromosomes (1, 2, 3, 4, 6, 9, 10, 11, 12, 13, 15, 18, 19, 20, 21, 22, 23, 24, 26, 30, X and Y). The other 11 syntenic groups were provisionally assigned to the remaining chromosomes based on information provided by heterologous species painting probes and work in progress with type I markers.     

Synteny-mapping horse microsatellite markers using a heterohybridoma panel

A panel of horse-mouse heterohybridoma cells was tested for genetic markers using biochemical and polymerase chain reaction-(PCR-) based tests. Biochemical markers included phospho-glucomutase ( PGM ), glucose phosphate isomerase ( GPI ) and 6-phosphogluconate dehydrogenase ( PGD ). Markers detected using PCR-based tests included microsatellite markers HTG2–15, HMS 1–3, 5–8, VHL20, ECA2 and genes for equine major histocompatibility gene ELA-DRA , tumour necrosis factor alpha (TNFA) and transferrin. The results were analysed for correlation and concordance. Based on the results, five synteny groups were identified, specifically between ELA-DRA, TNFA, HMS5 and HTG5 ; between HTG3 and HTG13 ; between HTG4, HTG8 and HMS3 ; between HTG6 and HMS1 ; and between HTG7, HTG9 and HMS6. Evidence was also found for synteny between HTG12, HMS7 and ECA2 , however, confirmation requires further testing. Cytogenetic evaluation of the cell lines making up the panel indicated that large metacentric chromosomes were preferentially lost or tended to break at the centromere. Consequently, the results from this analysis can be used to identify synteny, but not to exclude synteny.     

Cytogenetic mapping of immunity-related genes in the domestic horse

Chromosomal locations of 19 horse immunity-related loci (CASP1, CD14, EIF5A, FCER1A, IFNG, IL12A, IL12B, IL12RB2, IL1A, IL23A, IL4, IL6, MMP7, MS4A2, MYD88, NOS2A, PTGS2, TFRC and TLR2) were determined by fluorescence in situ hybridization. For IFNG and PTGS2, this study is a confirmation of their previously reported position. In addition, microsatellite (HMBr1) was localized in the same region as IFNG. All genes were assigned to regions of conserved synteny and the data obtained in this study enhance the comparative human-horse map. Cytogenetic localization of IL6 to ECA4q14-q21.1 suggested a new breakage point that changes the order of loci compared with HSA7. The map assignments of these loci serve as anchors for other loci and will aid in the search for candidate genes associated with traits in the horse.     

Report of the International Equine Gene Mapping Workshop: male linkage map

The goal of the First International Equine Gene Mapping Workshop, held in 1995, was the construction of a low density, male linkage map for the horse. For this purpose, the International Horse Reference Family Panel (IHRFP) was established, consisting of 12 paternal half-sib families with 448 half-sib offspring provided by 10 laboratories. Blood samples were collected and DNA extracted in each laboratory and sent to the Lexington laboratory (KY, USA) for dispatch in aliquots to 14 typing laboratories. In total, 161 markers (144 microsatellites, seven blood groups and 10 proteins) were tested for all families for which the sire was heterozygous. Genealogies and typing data were sent for analysis to the INRA laboratory (Jouy-en-Josas, France) according to a specific format and entered into a database with input verification and output processes. Linkage analysis was performed with the CRIMAP program. Significant linkage was detected for 124 loci, of which 95 were unambiguously ordered using a multipoint analysis with an average spacing of 14.2 CM. These loci were distributed among 29 linkage groups. A more comprehensive analysis including synteny group data and FISH data suggested that 26 autosomes out of 31 are covered. The complete map spans 936 CM.     

Comparative mapping of 18 equine type I genes assigned by somatic cell hybrid analysis

Polymerase chain reaction primers designed from horse cDNA sequences and from consensus sequences highly conserved in mammalian species were used to amplify markers for synteny mapping 18 equine type I genes. These markers were used to screen a horse–mouse somatic cell hybrid panel (UCDavis SCH). Fourteen primer sets amplified horse-specific fragments, while restriction enzyme digests of PCR products were used to distinguish the fragments amplified from horse and mouse with four primer sets. Synteny assignments were made based on correlation values between each marker tested and other markers in the UCDavis SCH panel database. The 18 horse genes were assigned to previously established synteny groups. Synteny mapping of two genes previously mapped in the horse by FISH was used to anchor two UCD synteny groups to horse chromosomes. Previous chromosome assignments of three equine loci by FISH were confirmed. Comparative mapping analysis based on published human–horse Zoo-FISH data and the synteny mapping of 14 horse genes confirmed the physical assignment of 12 synteny groups to the respective horse chromosomes and was used to infer the physical location of one synteny group. Received: 24 July 1998 / Accepted: 29 October 1998     

Assignment of the horse grey coat colour gene to ECA25 using whole genome scanning

The dominant grey coat colour gene of horses has been mapped using a whole genome scanning approach. Samples from a large half-sibling pedigree of Thoroughbred horses were utilized in order to map the grey coat colour locus, G. Multiplex groups of microsatellite markers were developed and used to efficiently screen the horse genome at a resolution of approximately 22 cM, based on an estimated map length for the horse genome of 2720 cM. The grey gene was assigned to chromosome 25 (ECA25), one of the smaller acrocentric horse chromosomes. Based on the current state of knowledge of conserved synteny and coat colour genetics in other mammalian species, there are no obvious candidate genes for the grey gene in the region.     

Construction of a medium-density horse gene map

A medium-density map of the horse genome (Equus caballus) was constructed using genes evenly distributed over the human genome. Three hundred and twenty-three exonic primer pairs were used to screen the INRA and the CHORI-241 equine BAC libraries by polymerase chain reaction and by filter hybridization respectively. Two hundred and thirty-seven BACs containing equine gene orthologues, confirmed by sequencing, were isolated. The BACs were localized to horse chromosomes by fluorescent in situ hybridization (FISH). Overall, 165 genes were assigned to the equine genomic map by radiation hybrid (RH) (using an equine RH(5000) panel) and/or by FISH mapping. A comparison of localizations of 713 genes mapped on the horse genome and on the human genome revealed 59 homologous segments and 131 conserved segments. Two of these homologies (ECA27/HSA8 and ECA12p/HSA11p) had not been previously identified. An enhanced resolution of conserved and rearranged chromosomal segments presented in this study provides clarification of chromosome evolution history.     

The cream dilution gene, responsible for the palomino and buckskin coat colours, maps to horse chromosome 21

The colour locus historically referred to as C in the horse is linked to microsatellites markers on horse chromosome 21. Preliminary results demonstrated linkage of Ccr, thought to be the cream dilution variant of the C locus, to HTG10. An analysis of horse chromosome 21 using additional families confirmed and established a group of markers linked to Ccr. This work also improved the resolution of previously reported linkage maps for this chromosome. Linkage analysis unambiguously produced the map order: SGCV16-(19.1 cM)-HTG10-(3.8 cM)-LEX60/COR73-(1.3 cM)-COR68-(4.5 cM)- Ccr-(11.9 cM)-LEX31. Comparative and synteny data suggested that the horse C locus is not tyrosinase (TYR).     

Identification of putative homology between horse microsatellite flanking sequences and cross-species ESTs, mRNAs and genomic sequences

In this study the flanking sequences of 1534 horse microsatellites were used in a BLAST search to identify putative human-horse homologies. BLAST searches revealed 129 flanking sequences with significant blastn matches [alignment scores (S) > or = 60 and sum probability values (E) < or = 3.0E-6], also, 25 of these produced significant blastx matches. To provide a reference point in the human genome the flanking sequences with matches were subjected to a BLAT search of the University of California Santa Cruz (UCSC) human genome assembly (July 2003 freeze). Eighty-three of the flanking sequences showed high similarity to sequence of known or putative human genes and the remaining 46 demonstrated high similarity to human intragenic regions. Interestingly, 87 of the microsatellites showed conservation of the tandem repeat in addition to flanking regions. Overall, 41 of the microsatellites had been mapped in the horse and of these 37 localized to the expected syntenic location. The other four did not and represent new putative regions of human-horse synteny. The results of this study contribute 79 new putative human-horse homologies, increasing the density of markers on the human-horse comparative map.     

Chromosome homologies between man and mountain zebra (Equus zebra hartmannae) and description of a new ancestral synteny involving sequences homologous to human chromosomes 4 and 8

Using human chromosome painting probes, we looked for homologies between human and mountain zebra (Equus zebra hartmannae, Equidae, Perissodactyla) karyotypes. Except for two very short segments, all euchromatic regions were found to have a human homologous chromosome segment. Conserved syntenies previously described in various mammalian orders were detected. Each synteny corresponded to a chromosomal region homologous to two parts of human chromosomes: HSA3 and HSA21, HSA7 and HSA16, HSA12 and HSA22, and HSA16 and HSA19. Chromosomal segments homologous to a part of HSA11 and HSA19p are found syntenic in zebra, horse and donkey, suggesting that this group of synteny has been inherited from an Equidae or Perissodactyla common ancestor. A synteny of segments homologous to parts of HSA4 and HSA8 was observed in zebra and horse. It also exists in the rabbit (Lagomorpha) and several Carnivora species. A second group of taxa which does not have this region of synteny is composed of primates, Chiroptera and Insectivora, and possibly also Cetacea and Scandantia. Thus, the presence or absence of this region of synteny may separate two groups of eutherian mammals.     

Zoo-FISH with microdissected arm specific paints for HSA2, 5, 6, 16, and 19 refines known homology with pig and horse chromosomes

Microdissected arm specific paints (ASPs) for human (HSA) chromosomes (Chrs) 2, 5, 6, 16, and 19 were used as probes on pig (SSC) and horse (ECA) metaphase chromosomes. Regions homologous to individual human arms were delineated in the two species studied. Of the ten ASPs used, HSA6 and 16 ASPs showed complete synteny conservation of individual arms as single blocks/arms both in pig and horse. A similar trend was, in general, also observed for HSA19 ASPs. However, contrary to these observations, synteny conservation of individual arms of HSA2 and HSA5 was not observed in pig and horse. The arm specific painting data, coupled with the available gene mapping data, showed that, although HSA2 corresponded to two arms/chromosomes each in pig and horse, the breakpoint of this synteny in humans was not located at the centromere, but at HSA2q13 band. Similarly, arm specific paints for HSA5 showed that of the two blocks/chromosomes painted in pig and horse, one corresponded to HSA5q13-pter, the other to HSA5q13-qter. The findings suggest that 5q13 band may also be an evolutionary break point, similar to the one detected on HSA2q13. The microdissected human arm specific painting probes used in the present work provide more accurate and refined comparative information on pig and horse chromosomes than that available through the use of human whole chromosome specific paints. Received: 1 June 1997 / Accepted: 5 September 1997     

Linkage of the gene for equine combined immunodeficiency disease to microsatellite markers HTG8 and HTG4; synteny and FISH mapping to ECA9

Equine combined immunodeficiency disease (CID) is caused by homozygosity for an autosomal recessive gene. To identify linked markers for the disease, we studied a family segregating for the equine CID gene. A stallion and 19 of his CID-affected offspring were tested for marker segregation at 23 microsatellite DNA loci. His CID-affected offspring inherited only one of his two alleles at the HTG8 and HTG4 loci, namely HTG8–186 and HTG4–124 , respectively. Lod scores for linkage to the CID gene using a Θ of 0·01were 5·34 for HTG8 and 2·37 for HTG4. The apparent genotypes also suggested linkage disequilibrium between the HTG8–186 allele and the gene for CID. The gene for the DNA protein kinase catalytic subunit ( DNA-PK ) was recently suggested as a candidate gene for equine CID. A defect of this gene causes a disease in mice that is similar to equine CID. Therefore, we investigated whether this gene might be associated with the microsatellite markers. Analysis of a somatic cell hybrid panel demonstrated synteny of DNA-PK with HTG4 and HTG8 (Kentucky Synteny Group 3). Fluorescence in situ hybridization (FISH) studies demonstrated that DNA-PK is located on horse chromosome ECA9p12. This work supports the hypothesis of DNA-PK as the probable cause of equine CID.     

Equine synteny mapping of comparative anchor tagged sequences (CATS) from human Chromosome 5

Comparative anchor tagged sequences (CATS) from human Chromosome 5 (HSA5) were used as PCR primers to produce molecular markers for synteny mapping in the horse. Primer sets for 21 genes yielded eight horse-specific markers, which were mapped with the UC Davis horse–mouse somatic cell hybrid panel into two synteny groups: UCD14 and UCD21. These data, in conjunction with earlier human chromosome painting studies of the horse karyotype and synteny mapping of horse microsatellite markers physically mapped by FISH, confirm the assignment of UCD21 to ECA21 and suggest that UCD14 is located on ECA14. In addition, our results can be used to substantiate previously published data which indicate that ECA21 contains material orthologous to HSA5p and HSA5q, and to propose an approximate region for an evolutionary chromosomal rearrangement event. Received: 1 February 1999 / Accepted: 12 July 1999     

Physical anchorage and orientation of equine linkage groups by FISH mapping BAC clones containing microsatellite markers

A horse bacterial artificial chromosome (BAC) library was screened for 19 microsatellite markers from unassigned or non-oriented linkage groups. Clones containing 11 (AHT20, EB2E8, HMS45, LEX005, LEX014, LEX023, LEX044, TKY111, UCDEQ425, UCDEQ464 and VIASH21) of these were found, which were from eight different linkage groups. The BAC clones were used as probes in dual colour FISH to identify their precise chromosomal origin. The microsatellite markers are located on nine different horse chromosomes, four of which (ECA6, ECA25, ECA27 and ECA28) had no previously in situ assigned markers.     

Horse domestication and conservation genetics of Przewalski's horse inferred from sex chromosomal and autosomal sequences

Despite their ability to interbreed and produce fertile offspring,there is continued disagreement about the genetic relationshipof the domestic horse (Equus caballus) to its endangered wildrelative, Przewalski's horse (Equus przewalskii). Analyses havediffered as to whether or not Przewalski's horse is placed phylogeneticallyas a separate sister group to domestic horses. Because Przewalski'shorse and domestic horse are so closely related, genetic datacan also be used to infer domestication-specific differencesbetween the two. To investigate the genetic relationship ofPrzewalski's horse to the domestic horse and to address whetherevolution of the domestic horse is driven by males or females,five homologous introns (a total of 3 kb) were sequenced onthe X and Y chromosomes in two Przewalski's horses and threebreeds of domestic horses: Arabian horse, Mongolian domestichorse, and Dartmoor pony. Five autosomal introns (a total of6 kb) were sequenced for these horses as well. The sequencesof sex chromosomal and autosomal introns were used to determinenucleotide diversity and the forces driving evolution in thesespecies. As a result, X chromosomal and autosomal data do notplace Przewalski's horses in a separate clade within phylogenetictrees for horses, suggesting a close relationship between domesticand Przewalski's horses. It was also found that there was alack of nucleotide diversity on the Y chromosome and highernucleotide diversity than expected on the X chromosome in domestichorses as compared with the Y chromosome and autosomes. Thissupports the hypothesis that very few male horses along withnumerous female horses founded the various domestic horse breeds.Patterns of nucleotide diversity among different types of chromosomeswere distinct for Przewalski's in contrast to domestic horses,supporting unique evolutionary histories of the two species.     

Human‐horse sensory engagement through horse archery

The Mongol horse stems from ancient stock, similar to the first horses ridden on the Central Asian grassland steppe. Mongol horses subsequently migrated with their human counterparts throughout Eurasia, as far to the east as Japan. During archery festivals in Japan, horses gallop along a narrow runway within a temple complex in the heavily populated city of Kyoto. In Mongolia, with the recent re‐emergence of the ancient practice, horse and rider still gallop across the expansive grassland steppe. The euphoria one feels in riding fast on horseback with the wind against one's face can be symbolised by the concept of khii mor’ in Mongolia, which is connected with the vitality between human and horse in the practice of horse archery. Through sensory ethnography, in combination with multi‐species ethnography, this article explores embodiment between horse and rider in two quite different socio‐ecological contexts.     

Syntenic assignment of dopamine tautomerase (DCT) to bovine chromosome 12

Heterologous primers were used to amplify an exon and intron-containing segment of the bovine homologue of the human dopachrome tautomerase gene. After confirmation of homo-logy by sequence analysis (exon sequence similarity greater than 90%), bovine-specific primers were developed for synteny mapping purposes. The dopachrome tautomerase gene was assigned to bovine chromosome 12 (BTA12) with 97% concordance to the coagulation factor 10 locus. Together with previous synteny mapping of bovine chromosome 12 genes, fms-related tyrosine kinase, esterase D and 5-hydroxytryptamine receptor 2, this assignment further indicates conservation between human chromosome 13q and bovine chromosome 12.     

Colombian Creole horse breeds: Same origin but different diversity

In order to understand the genetic ancestry and mitochondrial DNA (mtDNA) diversity of current Colombian horse breeds we sequenced a 364-bp fragment of the mitocondrial DNA D-loop in 116 animals belonging to five Spanish horse breeds and the Colombian Paso Fino and Colombian Creole cattle horse breeds. Among Colombian horse breeds, haplogroup D had the highest frequency (53%), followed by haplogroups A (19%), C (8%) and F (6%). The higher frequency of haplogroup D in Colombian horse breeds supports the theory of an ancestral Iberian origin for these breeds. These results also indicate that different selective pressures among the Colombian breeds could explain the relatively higher genetic diversity found in the Colombian Creole cattle horse when compared with the Colombian Paso Fino.     

Characterization, genetic and physical mapping analysis of 36 horse plasmid and cosmid-derived microsatellites

Thirty-six new horse microsatellites (11 from plasmid libraries and 25 from a cosmid library) were isolated and characterized on a panel of four horse breeds. Thirty were found to be polymorphic with heterozygosity levels ranging between 0.20 and 0.87. Twenty-two of the cosmids were physically mapped to R-banded single horse Chromosomes (Chrs) 1, 3, 4, 9, 11, 12, 13, 15, 18, 19, 21, 22, 23 and three to pericentromeric regions. Furthermore, linkage analysis between a selection of 42 DNA markers, including those presented in this study, and 16 conventional markers of the horse hemotype was performed on six paternal half-sib horse families. Five linkage groups were detected, of which four were assigned to Chr 10, 11, 15, and 18. This work increased by one-third the number of published polymorphic DNA markers suitable for horse mapping and approximately doubled the number of known linkage groups. Our cosmids labeled 14 out of the 31 horse autosomes. Moreover, the physical anchoring of part of these markers will orient linkage and synteny groups on the chromosomes and will contribute to their assignment. Received: 17 March 1997 / Accepted: 25 May 1997