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.     

Sex chromosomal abnormalities associated with equine infertility: validation of a simple molecular screening tool in the Purebred Spanish Horse

Chromosomal abnormalities in the sex chromosome pair (ECAX and ECAY) are widely associated with reproductive problems in horses. However, a large proportion of these abnormalities remains undiagnosed due to the lack of an affordable diagnostic tool that allows for avoiding karyotyping tests. Hereby, we developed an STR (single‐tandem‐repeat)‐based molecular method to determine the presence of the main sex chromosomal abnormalities in horses in a fast, cheap and reliable way. The frequency of five ECAX‐linked (LEX026, LEX003, TKY38, TKY270 and UCDEQ502) and two ECAY‐linked (EcaYH12 and SRY) markers was characterized in 261 Purebred Spanish Horses to determine the efficiency of the methodology developed to be used as a chromosomal diagnostic tool. All the microsatellites analyzed were highly polymorphic, with a sizeable number of alleles (polymorphic information content > 0.5). Based on this variability, the methodology showed 100% sensitivity and 99.82% specificity to detect the most important sex chromosomal abnormalities reported in horses (chimerism, Turner's syndrome and sex reversal syndromes). The method was also validated with 100% efficiency in 10 individuals previously diagnosed as chromosomally aberrant. This STR screening panel is an efficient and reliable molecular–cytogenetic tool for the early detection of sex chromosomal abnormalities in equines that could be included in breeding programs to save money, effort and time of veterinary practitioners and breeders.     

A 4,103 marker integrated physical and comparative map of the horse genome

A comprehensive second-generation whole genome radiation hybrid (RH II), cytogenetic and comparative map of the horse genome (2n = 64) has been developed using the 5000rad horse x hamster radiation hybrid panel and fluorescence in situ hybridization (FISH). The map contains 4,103 markers (3,816 RH; 1,144 FISH) assigned to all 31 pairs of autosomes and the X chromosome. The RH maps of individual chromosomes are anchored and oriented using 857 cytogenetic markers. The overall resolution of the map is one marker per 775 kilobase pairs (kb), which represents a more than five-fold improvement over the first-generation map. The RH II incorporates 920 markers shared jointly with the two recently reported meiotic maps. Consequently the two maps were aligned with the RH II maps of individual autosomes and the X chromosome. Additionally, a comparative map of the horse genome was generated by connecting 1,904 loci on the horse map with genome sequences available for eight diverse vertebrates to highlight regions of evolutionarily conserved syntenies, linkages, and chromosomal breakpoints. The integrated map thus obtained presents the most comprehensive information on the physical and comparative organization of the equine genome and will assist future assemblies of whole genome BAC fingerprint maps and the genome sequence. It will also serve as a tool to identify genes governing health, disease and performance traits in horses and assist us in understanding the evolution of the equine genome in relation to other species.     

Identification of Genetic Variation on the Horse Y Chromosome and the Tracing of Male Founder Lineages in Modern Breeds

The paternally inherited Y chromosome displays the population genetic history of males. While modern domestic horses (Equus caballus) exhibit abundant diversity within maternally inherited mitochondrial DNA, no significant Y-chromosomal sequence diversity has been detected. We used high throughput sequencing technology to identify the first polymorphic Y-chromosomal markers useful for tracing paternal lines. The nucleotide variability of the modern horse Y chromosome is extremely low, resulting in six haplotypes (HT), all clearly distinct from the Przewalski horse (E. przewalskii). The most widespread HT1 is ancestral and the other five haplotypes apparently arose on the background of HT1 by mutation or gene conversion after domestication. Two haplotypes (HT2 and HT3) are widely distributed at high frequencies among modern European horse breeds. Using pedigree information, we trace the distribution of Y-haplotype diversity to particular founders. The mutation leading to HT3 occurred in the germline of the famous English Thoroughbred stallion “Eclipse” or his son or grandson and its prevalence demonstrates the influence of this popular paternal line on modern sport horse breeds. The pervasive introgression of Thoroughbred stallions during the last 200 years to refine autochthonous breeds has strongly affected the distribution of Y-chromosomal variation in modern horse breeds and has led to the replacement of autochthonous Y chromosomes. Only a few northern European breeds bear unique variants at high frequencies or fixed within but not shared among breeds. Our Y-chromosomal data complement the well established mtDNA lineages and document the male side of the genetic history of modern horse breeds and breeding practices.     

Equine clinical cytogenetics: the past and future

Cytogenetic analyses of horses have benefited the horse industry by identifying chromosomal aberrations causing congenital abnormalities, embryonic loss and infertility. Technical advances in cytogenetics enabled the identification of chromosome specific aberrations. More recently, advances in genomic tools have been used to more precisely define chromosome abnormalities. In this report we review the history of equine clinical cytogenetics, identify historical landmarks for equine clinical cytogenetics, discuss how the current use of genomic tools has benefited this area, and how future genomics tools may enhance clinical cytogenetic studies in the horse.     

Isolation of Y chromosome-specific microsatellites in the horse and cross-species amplification in the genus Equus

Y chromosome polymorphisms such as microsatellites or single nucleotide polymorphisms represent a paternal counterpart to mitochondrial DNA (mtDNA) for evolutionary and phylogeographic studies. The use of Y chromosome haplotyping in natural populations of species other than humans is still hindered by the lack of sequence information necessary for polymorphism screening. Here we used representational difference analysis (RDA) followed by a screen of a bacterial artificial chromosome (BAC) library for repetitive sequences to obtain polymorphic Y-chromosomal markers. The procedure was performed for the domestic horse (Equus caballus) and we report the first six Y-chromosomal microsatellite markers for this species. Three markers were also useful for haplotyping taxa of the zebra/ass lineage. Y-chromosomal microsatellite markers show a single haplotype in the domestic horse, whereas notable variation has been observed in the other members of the genus Equus.     

Genetic variation in Przewalski's horses, with special focus on the last wild caught mare, 231 Orlitza III

In our continuing efforts to document genetic diversity in Przewalski's horses and relatedness with domestic horses, we report genetic variation at 22 loci of blood group and protein polymorphisms and 29 loci of DNA (microsatellite) polymorphisms. The loci have been assigned by linkage or synteny mapping to 20 autosomes and the X chromosome of the domestic horse (plus four loci unassigned to a chromosome). With cumulative data from tests of 568 Przewalski's horses using blood, hair or tooth samples, no species-defining markers were identified, however a few markers were present in the wild species but not in domestic horses. Inheritance patterns and linkage relationships reported in domestic horses appeared to be conserved in Przewalski's horses. A derived type for the last wild caught mare 231 Orlitza III provided evidence for markers apparently not found in (or not currently available by descent from) the other species founders that were captured at the end of the nineteenth century. This information has been critical to the development of parentage analyses in the studbook population of Przewalski's horses at Askania Nova, at one time the largest herd of captive animals and the source of stock for reintroduction efforts. Some horses in the study showed genetic incompatibilities with their sire or dam, contradicting published studbook information. In many cases alternative parentage could be assigned from living animals. To assist in identification of correct parentage, DNA marker types for deceased horses were established from archived materials (teeth) or derived from offspring. Genetic markers were present in pedigreed animals whose origin could not be accounted for from founders. Genetic distance analysis of erythrocyte protein, electrophoretic and microsatellite markers in Przewlaski's horses and ten breeds of domestic horse place the Przewalski's horse as an outgroup to domestic horses, introgression events from domestic horses not withstanding.     

Intrageneric amplification of horse microsatellite markers with emphasis on the Przewalski's horse (E. pmewalskii)

Primer sequences flanking 13 microsatellite loci isolated from the domestic horse (E. caballus) were successfully used to amplify homologous loci in the Przewalski's horse (E. przewalskii). The results demonstrate that the level of polymorphism at all 13 loci in the Przewalski's horse was comparable to that in the domestic horse and the overall exclusion probability in the Przewalski's horse was calculated to be 0.9994. The results suggest that it should be possible to use E. caballus-derived microsatellite markers to provide parentage verification and additional valuable information to the captive management of E. przewalskii. The ability to amplify corresponding loci in the remaining five species of the genus was also confirmed, illustrating the general application of markers isolated from the domestic horse to the evaluation of polymorphism in the other six species of the genus.     

An assessment of feral horse impacts on treeless drainage lines in the Australian Alps

The feral Horse (Equus caballus) is widespread across the Australian Alps. Feral horses degrade alpine and sub‐alpine ecosystems and damage habitat of a range of threatened species. Despite this, there is little published work to document the extent and severity of these impacts. This study investigated impacts of feral horses on treeless drainage lines at 186 sites across the Australian Alps. The study included sites in the Australian Capital Territory, New South Wales and Victoria. We assessed nine variables related to soil and stream stability and vegetation cover, which in turn influence ecosystem function and habitat quality. We found significant differences among horse‐occupied and horse‐free sites for all soil and stream stability variables assessed. For all variables assessed, the average score (and hence, condition) was worse in horse‐occupied areas. The sites in poorest condition were occupied by horses. Impacts from other mammalian herbivores species appeared to be minor. Management intervention is necessary if these impacts of feral horses are to be addressed.     

Evolutionary movement of centromeres in horse, donkey, and zebra

Centromere repositioning (CR) is a recently discovered biological phenomenon consisting of the emergence of a new centromere along a chromosome and the inactivation of the old one. After a CR, the primary constriction and the centromeric function are localized in a new position while the order of physical markers on the chromosome remains unchanged. These events profoundly affect chromosomal architecture. Since horses, asses, and zebras, whose evolutionary divergence is relatively recent, show remarkable morphological similarity and capacity to interbreed despite their chromosomes differing considerably, we investigated the role of CR in the karyotype evolution of the genus Equus. Using appropriate panels of BAC clones in FISH experiments, we compared the centromere position and marker order arrangement among orthologous chromosomes of Burchelli's zebra (Equus burchelli), donkey (Equus asinus), and horse (Equus caballus). Surprisingly, at least eight CRs took place during the evolution of this genus. Even more surprisingly, five cases of CR have occurred in the donkey after its divergence from zebra, that is, in a very short evolutionary time (approximately 1 million years).These findings suggest that in some species the CR phenomenon could have played an important role in karyotype shaping, with potential consequences on population dynamics and speciation.     

Rapid detection of trisomies 21 and 18 and sexing by quantitative fluorescent multiplex PCR

Aneuploidies involving chromosomes 21, 18, 13, X and Y account for over 95% of all chromosomal abnormalities in live-born infants. Prenatal diagnosis of these disorders is usually accomplished by cytogenetic analysis of amniotic or chorionic cells but this is a lengthy procedure requiring great technical expertise.In this paper, we assess the diagnostic value of using a quantitative fluorescent polymerase chain reaction (PCR) suitable for the simultaneous and rapid diagnosis of trisomies 21 and 18 together with the detection of DNA sequences derived from the X and Y chromosomes. Samples of DNA, extracted from amniotic fluid, fetal blood or tissues, and peripheral blood from normal adults were investigated by quantitative fluorescent PCR amplification of polymorphic small tandem repeats (STRs) specific for two loci on each of chromosomes 21 and 18. Quantitative analysis of the amplification products allowed the diagnosis of trisomies 21 and 18, while sexing was performed simultaneously using PCR amplification of DNA sequences derived from the chromosomes X and Y. These results indicate the advantages of using two sets of STR markers for the detection of chromosome 21 trisomies and confirmed the usefulness of quantitative fluorescent multiplex PCR for the rapid prenatal diagnosis of selected chromosomal abnormalities. Received: 23 January 1996 / Revised: 21 February 1996     

Cytogenetic abnormalities in Tunisian women with premature ovarian failure

To identify the distribution of chromosome abnormalities among Tunisian women with premature ovarian failure (POF) referred to the department of Cytogenetic at the Pasteur Institute of Tunis (Tunisia), standard cytogenetic analysis was carried out in a total of 100 women younger than 40 affected with premature ovarian failure. We identified 18 chromosomal abnormalities, including seven X-numerical anomalies in mosaic and non-mosaic state (45,X; 47,XXX), four sex reversal, three X-structural abnormalities (terminal deletion and isochromosomes), one autosomal translocation and one supernumerary marker. The overall prevalence of chromosomal abnormalities was 18% in our cohort. X chromosome aneuploidy was the most frequent aberration. This finding confirms the essential role of X chromosome in ovarian function and underlies the importance of cytogenetic investigations in the routine management of POF.     

Detection of two equine trisomies using SNP-CGH

Chromosomal aberrations in the horse are known to cause congenital abnormalities, embryonic loss, and infertility. While diagnosed mainly by karyotyping and FISH in the horse, the use of SNP array comparative genome hybridization (SNP-CGH) is becoming increasingly common in human diagnostics. Normalized probe intensities and allelic ratios are used to detect changes in copy number genome-wide. Two horses with suspected chromosomal abnormalities and six horses with FISH-confirmed aberrant karyotypes were chosen for genotyping on the Equine SNP50 array. Karyotyping of the first horse indicated mosaicism for an additional small, acrocentric chromosome, although the identity of the chromosome was unclear. The second case displayed a similar phenotype to human disease caused by a gene deletion and so was chosen for SNP-CGH due to the ability to detect changes at higher resolutions than those achieved with conventional karyotyping. The results of SNP-CGH analysis for the six horses with known chromosomal aberrations agreed completely with previous karyotype and FISH analysis. The first undiagnosed case showed a pattern of altered allelic ratios without a noticeable shift in overall intensity for chromosome 27, consistent with a mosaic trisomy. The second case displayed a more drastic change in both values for chromosome 30, consistent with a complete trisomy. These results indicate that SNP-CGH is a viable method for detection of chromosomal aneuploidies in the horse.     

Comparative analysis of the informativeness of ISSR markers for estimating genetic diversity of horse breeds

The informativeness of six different types of ISSR markers was compared in order to evaluate genetic diversity of Mongolian, Buryat and Tuvinian horse breeds (Equus caballus). The dinucleotide-based ISSR primers ((GA)₉C, (AG)₉C, and (CA)₉G) proved to be of little use to examine genetic polymorphism among horses due to the low number of amplified and polymorphic fragments. The polymorphism information content (PIC) for the dinucleotide-based ISSR primers was 2.88 times lower than that for trinucleotide-based ISSR markers. Among the trinucleotide-based ISSR markers, CAC ISSR marker was also found to be noninformative, due to the low number of polymorphic loci identified. The highest values of the polymorphism information content (PIC) were obtained for two types of ISSR markers, based on (GAG)₆C (PIC, 3.61) and on (ACC)₆G (PIC, 2.50). Thus, the results of the present study showed that GAG and ACC ISSR markers were most informative for evaluation of genetic diversity among horses.     

Construction of a 5000<Subscript>rad</Subscript> whole-genome radiation hybrid panel in the horse and generation of a comprehensive and comparative map for ECA11

A 5000_rad whole-genome radiation hybrid (RH) panel was created for the horse. The usefulness of the panel for generating physically ordered maps of individual equine chromosomes was tested by typing 24 markers on horse Chromosome 11 (ECA11). The overall retention of markers on this chromosome was 43.6%. Almost complete retention of two of the typed markers—CA062 and AHT44—clearly indicated the location of thymidine kinase gene on the short arm of ECA11. Seven of the typed markers were FISH mapped to align the RH and cytogenetic maps. With the RH-MAPPER approach, a physically ordered map comprising four linkage groups and incorporating all the markers was obtained. The study provides the first comprehensive map for a horse chromosome that integrates all available mapping data and adds new information that spans the entire length of the equine chromosome. The map clearly underlines the resolving power and utility of the panel and emphasizes the need to have uniformly distributed cytogenetic markers for appropriate alignment of RH map with the chromosome. A comparative status of the ECA11 map in relation to the corresponding human/mouse chromosome is presented. Received: 7 June 2001 / Accepted: 4 October 2001     

Peeling Back the Evolutionary Layers of Molecular Mechanisms Responsive to Exercise-Stress in the Skeletal Muscle of the Racing Horse

The modern horse (Equus caballus) is the product of over 50 million yrs of evolution. The athletic abilities of the horse have been enhanced during the past 6000 yrs under domestication. Therefore, the horse serves as a valuable model to understand the physiology and molecular mechanisms of adaptive responses to exercise. The structure and function of skeletal muscle show remarkable plasticity to the physical and metabolic challenges following exercise. Here, we reveal an evolutionary layer of responsiveness to exercise-stress in the skeletal muscle of the racing horse. We analysed differentially expressed genes and their co-expression networks in a large-scale RNA-sequence dataset comparing expression before and after exercise. By estimating genome-wide d_N/d_S ratios using six mammalian genomes, and F_ST and iHS using re-sequencing data derived from 20 horses, we were able to peel back the evolutionary layers of adaptations to exercise-stress in the horse. We found that the oldest and thickest layer (d_N/d_S) consists of system-wide tissue and organ adaptations. We further find that, during the period of horse domestication, the older layer (F_ST) is mainly responsible for adaptations to inflammation and energy metabolism, and the most recent layer (iHS) for neurological system process, cell adhesion, and proteolysis.     

Genetic and physical maps of human chromosome 4 based on dinucleotide repeats.

Characterization of inherited variations within tandem arrays of dinucleotide repeats has substantially advanced the construction of genetic maps using linkage approaches over the last several years. Using a backbone of 10 newly identified microsatellite repeats on human chromosome 4 and 6 previously identified short tandem repeat element polymorphisms, we have constructed several genetic maps and a physical map of human chromosome 4. The genetic and physical maps are in complete concordance with each other. The genetic maps include a 15-locus microsatellite-based linkage map, a framework map of high support incorporating a total of 39 independent loci, a 25-locus high-heterozygosity, easily used index map, and a gene-based comprehensive map that provides the best genetic location for 35 genes mapped to chromosome 4. The 16 microsatellite markers are each localized to one of nine regions of chromosome 4, delineated by a panel of somatic cell hybrids. These results demonstrate the utility of PCR-based repeat elements for the construction of genetic maps and provide a valuable resource for continued high-resolution mapping of chromosome 4 and of genetic disorders to this chromosome.     

The role of chromosomal rearrangements in the evolution of <Emphasis Type="Italic">Silene latifolia</Emphasis> sex chromosomes

Silene latifolia is a model plant for studies of the early steps of sex chromosome evolution. In comparison to mammalian sex chromosomes that evolved 300 mya, sex chromosomes of S. latifolia appeared approximately 20 mya. Here, we combine results from physical mapping of sex-linked genes using polymerase chain reaction on microdissected arms of the S. latifolia X chromosome, and fluorescence in situ hybridization analysis of a new cytogenetic marker, Silene tandem repeat accumulated on the Y chromosome. The data are interpreted in the light of current genetic linkage maps of the X chromosome and a physical map of the Y chromosome. Our results identify the position of the centromere relative to the mapped genes on the X chromosome. We suggest that the evolution of the S. latifolia Y chromosome has been accompanied by at least one paracentric and one pericentric inversion. These results indicate that large chromosomal rearrangements have played an important role in Y chromosome evolution in S. latifolia and that chromosomal rearrangements are an integral part of sex chromosome evolution.     

Cytogenetic localization of genetic markers on porcine chromosome 7q

Four microsatellite markers ( S0078, SWR1210, SW732, and SW304 ) taken from the linkage map of porcine chromosome 7 were assigned to the cytogenetic map of pig chromosome 7 by fluorescence in situ hybridization (FISH) analysis of selected yeast artificial chromosomes (YACs). These four new polymorphic cytogenetic markers provide additional anchor points for integrating the linkage and cytogenetic maps of chromosomal region 7q.     

Characterisation of a bovine/murine hybrid cell panel informative for all bovine autosomes

A bovine/murine hybrid cell panel consisting of 57 cell lines was typed with 124 markers by PCR, Southern hybridisation and isozyme analysis in order to establish its utility as a resource for genome mapping. All bovine chromosomes, including the sex chromosomes were represented in the panel. Computerised analysis of syntenies indicated that there are no cell lines containing only a single bovine chromosome. The panel was used to map 10 new bovine microsatellite markers, and the MYL6 and CPE genes. This panel is informative for all bovine chromosomes other than the sex-specific region of the X chromosome and can be used in synteny mapping studies. At present, due to the relatively small number of markers typed, the resolution of the panel does not go beyond the chromosomal level.