Characterization of 463 type I markers suitable for dog genome mapping

Prevalence of the AMHR2 mutation in Miniature Schnauzers and genetic investigation of a Belgian Malinois with persistent Müllerian duct syndrome

Persistent Müllerian duct syndrome (PMDS) is a sex-limited disorder in which males develop portions of the female reproductive tract. Important consequences of PMDS are cryptorchidism and its sequelae of infertility and increased risk of testicular cancer. Anti-Müllerian hormone (AMH) and its receptor (AMHR2) induce the regression of the Müllerian ducts in male embryos. In Miniature Schnauzer dogs, the genetic basis has been identified as an autosomal recessive nonsense mutation in AMHR2, but the allele frequency of the mutation is unknown. Thus, the primary objective of this study was to estimate the prevalence of the AMHR2 mutation in North American Miniature Schnauzers, in order to ascertain the value of genetic testing in this breed. An additional objective was to determine whether mutations in AMH or AMHR2 were responsible for PMDS in a Belgian Malinois; this would aid development of a genetic test for the Belgian Malinois breed. Genomic DNA from 216 Miniature Schnauzers (including one known PMDS case) was genotyped for the AMHR2 mutation, and DNA from a single PMDS-affected Belgian Malinois was sequenced for all coding exons of AMH and AMHR2. The Miniature Schnauzer cohort had an AMHR2 mutation allele frequency of 0.16 and a carrier genotypic frequency of 0.27. The genetic basis for PMDS in the Belgian Malinois was not determined, as no coding or splicing mutations were identified in either AMH or AMHR2. These findings support a benefit to AMHR2 mutation testing Miniature Schnauzers used for breeding or with cryptorchidism.

Genetic variability of seven dog breeds based on microsatellite markers

The present study, compared the genetic variability of seven dog breeds and a test sample from Switzerland by means of 26 microsatellite markers. Five loci were excluded from further analyses because one was monomorphic, one not in Hardy-Weinberg equilibrium in all breeds and three in linkage disequilibrium with linked loci. The proportion of shared alleles at the individual level of the remaining 21 microsatellite markers combined with the neighbour-joining method allowed for the clustering of the large majority of the individuals in accordance to their breed. The results were confirmed by analyses using a Bayesian approach for clustering and a Monte Carlo re-sampling method for individual assignment or exclusion to a given population.

Le chien, un modèle pour la génétique des mammifères

Up to recently, studies on dog genetics were rather scare notwithstanding the enormous potential that the canine model can offer in the study of the genotype/phenotype relationship and the analysis of the causes of many genetic diseases, with simple or complex inheritance, that affect dogs but also the human population. This potentiality is essentially due to the natural history of dogs whose domestication from wolves dated back 15,000 years, at least. All modern dogs originated from a limited number of female wolves from Eastern Asia. By applying a combination of selections and strong inbreeding practices, humans have created over 350 breeds, each of them corresponding to a genetic isolate and altogether offering a unique panel of polymorphism never encountered in any other mammals. In this review we summarized what makes dogs an unavoidable model. Contrary to the classical models like the two yeasts, nematode, fish, fly, mouse, or rat mainly used to understand the function of genes, dog with the creation across the centuries of numerous breeds offers a unique opportunity to study the role of their alleles. We report recent data on the construction of genomic maps and on the sequencing program of the dog genome launched by the National Institute of Health (NIH). To take fully advantage of the canine model, we advocate for the systematic construction of a rich canine single nucleotide polymorphisms (SNP) ressource to perform linkage desiquilibrium studies of normal or pathological traits as well as to get insight into the genetic diversity of the canine species.

Construction of a dense comparative map between human chromosome 1p36-->p35 and swine chromosome 6 by using human sequence-tagged sites

Construction of a comprehensive comparative map between swine and human chromosomes is a prerequisite, in order to select candidate swine genes for traits from the human genome database as well as to understand the evolutionary process of the two species. The present study attempted to use 910 sequence-tagged sites (STSs) localized in human chromosome (HSA) 1p36-->p35 (35 Mbp) for radiation hybrid (RH) mapping to swine chromosomes (SSCs). Out of the 910 STSs subjected to amplification of swine orthologues, primer pairs for 13 STSs were found to amplify the respective orthologues and the STSs were assigned to SSCs. Eleven STSs were assigned to SSC6 in the same order as that in HSA1: SSC6cen-(SHGC-150)-(A006H31)-(X82877)-(A007E03)-(IB404)-(stGDB:371372)-(stSG31658)-(A009Q18)-(stSG14201/A009C01)-(H08335)-qter. One of the remaining two STSs, WI-20819, was assigned to SSCX, and the other, R91D18R, was not linked to any first-generation markers of the IMpRH map with a lod score greater than 3.

Y chromosome conserved anchored tagged sequences (YCATS) for the analysis of mammalian male-specific DNA

Y chromosome haplotyping based on microsatellites or single nucleotide polymorphisms has recently proven to be a powerful approach for evolutionary studies of human populations, and also holds great promise for the studies of wild species. However, the use of the approach is hampered in most natural populations by the lack of Y chromosome markers and sequence information. Here, we report the large-scale development of Y chromosome conserved anchor tagged sequence (YCATS) markers in mammals by a polymerase chain reaction screening approach. Exonic primers flanking 48 different introns of Y-linked genes were developed based on human and mouse sequences, and screened on a set of 20 different mammals. On average about 10 introns were amplified for each species and a total of 100 kb of Y chromosome sequence were obtained. Intron size in humans was a reasonable predictor of intron size in other mammals (r2 = 0.45) and there was a negative correlation between human fragment size and amplification success. We discuss a number of factors affecting the possibility of developing conserved Y chromosome markers, including fast evolution of Y chromosome sequences due to male-biased mutation and adaptive evolution of male-specific genes, dynamic evolution of the Y chromosome due to being a nonrecombining unit, and homology with X chromosome sequences.

Chromosome-specific single-locus FISH probes allow anchorage of an 1800-marker integrated radiation-hybrid/linkage map of the domestic dog genome to all chromosomes

We present here the first fully integrated, comprehensive map of the canine genome, incorporating detailed cytogenetic, radiation hybrid (RH), and meiotic information. We have mapped a collection of 266 chromosome-specific cosmid clones, each containing a microsatellite marker, to all 38 canine autosomes by fluorescence in situ hybridization (FISH). A 1500-marker RH map, comprising 1078 microsatellites, 320 dog gene markers, and 102 chromosome-specific markers, has been constructed using the RHDF5000-2 whole-genome radiation hybrid panel. Meiotic linkage analysis was performed, with at least one microsatellite marker from each dog autosome on a panel of reference families, allowing one meiotic linkage group to be anchored to all 38 dog autosomes. We present a karyotype in which each chromosome is identified by one meiotic linkage group and one or more RH groups. This updated integrated map, containing a total of 1800 markers, covers >90% of the dog genome. Positional selection of anchor clones enabled us, for the first time, to orientate nearly all of the integrated groups on each chromosome and to evaluate the extent of individual chromosome coverage in the integrated genome map. Finally, the inclusion of 320 dog genes into this integrated map enhances existing comparative mapping data between human and dog, and the 1000 mapped microsatellite markers constitute an invaluable tool with which to perform genome scanning studies on pedigrees of interest.

Chromosome assignment of six dog genes by FISH, and correlation with dog-human Zoo-FISH data

Cross-species chromosome painting analyses have recently demonstrated the presence of regions of conserved synteny between the human and domestic dog genomes, aiding the search for candidate genes for inherited traits. Concerted efforts to subchromosomally assign substantial numbers of dog gene sequences are now needed in order to refine these comparative data, both in terms of marker density and resolution. We have developed novel PCR markers representing three dog genes (ALB, FOS, HNRPA2B1) for which no sequence or mapping data were previously available, to our knowledge. These, in addition to three gene markers previously described (ALDOA, RPE65, VCAM1), were used to isolate and chromosomally assign corresponding large insert genomic clones by fluorescence in situ hybridization (FISH). Chromosome assignments for these six dog genes are discussed in terms of those of the human orthologues, and correlated with existing comparative mapping information, identifying one apparent exception to existing Zoo-FISH data, and aiding refinement of the boundaries of conserved chromosome segments in both genomes.

Reciprocal chromosome painting illuminates the history of genome evolution of the domestic cat, dog and human

Domestic cats and dogs are important companion animals and model animals in biomedical research. The cat has a highly conserved karyotype, closely resembling the ancestral karyotype of mammals, while the dog has one of the most extensively rearranged mammalian karyotypes investigated so far. We have constructed the first detailed comparative chromosome map of the domestic dog and cat by reciprocal chromosome painting. Dog paints specific for the 38 autosomes and the X chromosomes delineated 68 conserved chromosomal segments in the cat, while reverse painting of cat probes onto red fox and dog chromosomes revealed 65 conserved segments. Most conserved segments on cat chromosomes also show a high degree of conservation in G-banding patterns compared with their canine counterparts. At least 47 chromosomal fissions (breaks), 25 fusions and one inversion are needed to convert the cat karyotype to that of the dog, confirming that extensive chromosome rearrangements differentiate the karyotypes of the cat and dog. Comparative analysis of the distribution patterns of conserved segments defined by dog paints on cat and human chromosomes has refined the human/cat comparative genome map and, most importantly, has revealed 15 cryptic inversions in seven large chromosomal regions of conserved synteny between humans and cats.

Use of flow-sorted canine chromosomes in the assignment of canine linkage, radiation hybrid, and syntenic groups to chromosomes: refinement and verification of the comparative chromosome map for dog and human

The mapping of the canine genome has recently been accelerated by the availability of chromosome-specific reagents and publication of radiation hybrid (RH), genetic linkage, and dog/human comparative maps, but the assignment of mapping groups to chromosomes is incomplete. To assign published radiation hybrid, linkage, and "syntenic" groups to chromosomes, individual markers found within each group have been amplified from canine and vulpine flow-sorted, chromosome-specific DNAs as templates. Here a further 102 type I genetic markers (previously mapped in human) and 21 further type II markers are assigned to canine chromosomes using marker-specific PCR. We have assigned all linkage, RH, and syntenic groups in the two most recently published canine genome maps to chromosomes. This demonstrates directly that there is at least one published mapping group for each of the 38 canine autosomes and thus that the coverage of the canine chromosome map is approaching completion. The dog/human comparative map is one of the most complex so far described, with 90 separate segments of chromosomal homology previously seen in dog-on-human cross-species chromosome-painting studies. The total of 142 type I markers now placed on canine chromosomes using this method of marker mapping has allowed us to confirm the placement of the great majority (83) of the 90 homologous segments. The positions of the remaining homologous segments were confirmed in new cross-species chromosome-painting experiments (dog-on-human, fox-on-human).

Zoo-FISH analysis of dog chromosome 5: identification of conserved synteny with human and cat chromosomes

Conserved segments of synteny between the human genome and chromosome 5 (CFA 5) of the domestic dog (Canis familiaris) have been identified by reciprocal chromosome painting analysis. A CFA 5 paint probe was applied to human metaphase spreads, revealing distinct hybridisation sites on human (HSA) chromosomes 1, 11, 16, and 17. Paint probes for these human chromosomes were then hybridised to dog metaphase spreads, identifying the regions of CFA 5 with which homology is shared with the corresponding human chromosome. Application of the CFA 5 paint probe to metaphase spreads of the domestic cat (Felis catus, FCA) demonstrated hybridisation to cat chromosomes C1, D1, E1, and E2. Dog PCR primers for type 1 markers known to lie in the corresponding regions of HSA 11, 16, and 17 were used to isolate dog BAC clones representing four genes. Fluorescence in situ hybridisation analysis confirmed their localisation to CFA 5 and suggested that two of the conserved segments lie in opposing orientations on CFA 5, compared to the human chromosome concerned. A third segment appears to lie in the same orientation on both human and dog chromosomes. No suitable gene markers were available for analysis of the fourth segment. The significance of these findings is discussed with reference to current and future dog genome mapping efforts.