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.     

Characterization and radiation hybrid mapping of expressed sequence tags from the canine brain

Abstract Maps of the canine genome are now developing rapidly. Most of the markers on the current integrated canine radiation hybrid/genetic linkage/cytogenetic map are highly polymorphic microsatellite (type II) markers that are very useful for mapping disease loci. However, there is still an urgent need for the mapping of gene-based (type I) markers that are required for comparative mapping, as well as identifying candidate genes for disease loci that have been genetically mapped. We constructed an adult brain cDNA library as a resource to increase the number of gene-based markers on the canine genome map. Eighty-one percent of the 2700 sequenced expressed sequence tags (ESTs) represented unique sequences. The canine brain ESTs were compared with sequences in public databases to identify putative canine orthologs of human genes. One hundred nine of the canine ESTs were mapped on the latest canine radiation hybrid (RH) panel to determine the location of the respective canine gene. The addition of these new gene-based markers revealed three conserved segments (CS) between human and canine genomes previously detected by fluorescence in situ hybridization (FISH), but not by RH mapping. In addition, five new CS between dog and human were identified that had not been detected previously by RH mapping or FISH. This work has increased the number of gene-based markers on the canine RH map by approximately 30% and indicates the benefit to be gained by increasing the gene content of the current canine comparative map.     

A cytogenetically characterized, genome-anchored 10-Mb BAC set and CGH array for the domestic dog

The generation of a 7.5x dog genome assembly provides exciting new opportunities to interpret tumor-associated chromosome aberrations at the biological level. We present a genomic microarray for array comparative genomic hybridization (aCGH) analysis in the dog, comprising 275 bacterial artificial chromosome (BAC) clones spaced at intervals of approximately 10 Mb. Each clone has been positioned accurately within the genome assembly and assigned to a unique chromosome location by fluorescence in situ hybridization (FISH) analysis, both individually and as chromosome-specific BAC pools. The microarray also contains clones representing the dog orthologues of 31 genes implicated in human cancers. FISH analysis of the 10-Mb BAC clone set indicated excellent coverage of each dog chromosome by the genome assembly. The order of clones was consistent with the assembly, but the cytogenetic intervals between clones were variable. We demonstrate the application of the BAC array for aCGH analysis to identify both whole and partial chromosome imbalances using a canine histiocytic sarcoma case. Using BAC clones selected from the array as probes, multicolor FISH analysis was used to further characterize these imbalances, revealing numerous structural chromosome rearrangements. We outline the value of a combined aCGH/FISH approach, together with a well-annotated dog genome assembly, in canine and comparative cancer studies.     

Analysis of the unassembled part of the dog genome sequence: chromosomal localization of 115 genes inferred from multispecies comparative genomics

The identification of dog genes and their accurate localization to chromosomes remain a major challenge in the postgenomics era. The 132 annotated canine genes with human orthologs remaining in the unassembled part (chrUnknown) of the dog sequence assembly (CanFam1) are of limited use for candidate gene approaches or comparative mapping studies. We used a two-step comparative analysis to infer a canine chromosomal interval for localization of the chrUn genes. We first constructed a human-dog synteny map, using 14,456 gene-based comparative anchors. We then mapped the 132 chrUn genes onto the reference (human) synteny map and identified the corresponding, orthologous segment on the canine map, based on conserved gene order. Our results show that 110 chrUn genes could be localized to short intervals on 18 dog chromosomes, whereas 22 genes remained assigned to 2 possible intervals. We extended this comparative analysis to multiple species, using the chimpanzee, mouse, and rat genome sequences. This made it possible to narrow down the intervals concerned and to increase the number of canine chrUn genes with an inferred chromosome location to 115. This study demonstrates that dog chromosomal intervals for chrUn genes can be rapidly inferred, using a reference species, and indicates that comparative strategies based on larger numbers of species may be even more effective.     

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).     

A radiation hybrid comparative map of ovine chromosome 1 aligned to the virtual sheep genome

Ovis aries chromosome one (OAR1) is the largest submetacentric chromosome in the sheep genome and is homologous to regions on human chromosomes 1, 2, 3 and 21. Using the USUoRH5000 ovine whole-genome radiation hybrid (RH) panel, we have constructed a RH map of OAR1 comprising 102 framework and 75 placed/binned markers across five linkage groups spanning 3759.43 cR5000, with an average marker density of 21.2 cR5000/marker. The alignment of our OAR1 RH map shows good concordance with the recently developed virtual sheep genome, with fewer than 1.86% discrepancies. A comparative map of OAR1 was constructed by examining the location of RH-mapped orthologues in sheep within the genomes of cow, human, horse and dog. Analysis of the comparative map indicates that conserved syntenies within the five ovine RH linkage groups underwent internal chromosomal rearrangements which, in general, reflect the evolutionary distances between sheep and each of these four species. The ovine RH map presented here integrates all available mapping data and includes new genomic information for ovine chromosome 1.     

Chromosomal assignment of 20 candidate genes for canine congenital sensorineural deafness by FISH and RH mapping

The analysis of inherited diseases in the domestic dog (Canis familiaris) provides a resource for the continued use of this species as a model system for human diseases. Many different dog breeds are affected by congenital sensorineural deafness. Since mutations in various genes have already been found causative for sensorineural hearing impairment in humans or mice, 20 of these genes were considered as candidates for deafness in dogs. For each of the candidate genes a canine BAC clone was isolated by screening with heterologous human or murine cDNA probes. The gene-containing BAC clones were physically assigned to the canine genome by FISH and the BAC-derived STS-markers were positioned with the RHDF5000 panel on the canine RH map. The mapping data, which confirm the established conservation of synteny between canine and human chromosomes, provide a resource for further association studies in segregating canine populations and the basis for new insights into this common canine and human disease.     

Chromosomal localization of ESTs obtained from human fetal liver via BAC-mediated FISH mapping.

A total of 55 expressed sequence tags (ESTs) randomly chosen from our collection of fetal liver ESTs were mapped to chromosomes by fluorescence in situ hybridization (FISH) mapping techniques. To generate FISH mapping probes, the genomic DNAs for each EST were selected by screening an arrayed human bacterial artificial chromosome (BAC) library. In total, 73 BACs were used for mapping of the 55 ESTs. Among them, 70 BACs representing 52 ESTs unequivocally mapped to single chromosomal regions. The remaining 3 BACs representing 3 ESTs were localized to multiple regions, suggesting that BACs may have very low chimerism. Our mapping results were compared with EST mapping databases deposited in NCBI. Thirty-six of 55 ESTs corresponded to previously mapped positions of ESTs, 2 ESTs mapped to different positions from previously determined ones, and it was found that 17 ESTs have been mapped on new locations from this study. These mapping data may be used for completing the framework of the human physical map, and also for providing a good starting point for searching disease-related genes.     

Comparative mapping between humans and pigs: localization of 58 anchorage markers (TOASTs) by use of porcine somatic cell and radiation hybrid panels

To increase the number of Type I markers that are directly informative for comparative mapping, 58 anchorage markers, TOASTs (Traced Orthologous Amplified Sequence Tags), were mapped in pig. With specific consensus primers, 76 TOASTs were tested in pig: 50 were regionally localized in pig on a somatic cell hybrid panel (SCHP), and 51 were mapped on the whole genome, INRA/University of Minnesota porcine Radiation Hybrid panel (IMpRH). Comparison of marker positions on RH and cytogenetic maps indicated general concordance except for two chromosomal regions. For RH mapping, all markers, apart from one, were significantly linked (LOD > 4.8) to a marker of the first-generation radiation hybrid map. Localization of new markers on the initial map is necessary for drawing a framework map as shown for Chromosome Sscr 14. The addition of four TOASTs has enabled us to propose an improved map, using a threshold likelihood ratio of 1000/1. At the whole-genome level, this work significantly increased (by 50%) the number of precisely mapped genes on the porcine RH map and confirmed that the IMpRH panel is a valuable tool for high-resolution gene mapping in pig. Porcine PCR products were sequenced and compared with human sequences to verify their identity. Most of the localizations made it possible to either confirm or refine the previous comparative data between humans and pigs obtained through heterologous chromosomal painting or gene mapping. Moreover, the use of TOASTs in mapping studies appears to be a complement to other strategies using CATS, human ESTs, or heterologous FISH with BACs which had already been applied to improve the gene density of comparative genomic maps for mammals. Received: 15 March 2000 / Accepted: 27 July 2000     

Chromosomal mapping of 18S-28S rRNA genes and 10 cDNA clones of human chromosome 1 in the musk shrew (Suncus murinus).

The direct R-banding fluorescence in situ hybridization (FISH) method was used to map 18S-28S ribosomal RNA genes and 10 human cDNA clones on the chromosomes of the musk shrew (Suncus murinus). The chromosomal locations of 18S-28S ribosomal RNA genes were examined in the five laboratory lines and wild animals captured in the Philippines and Vietnam, and the genes were found on chromosomes 5, 6, 9, and 13 with geographic variation. The comparative mapping of 10 cDNA clones of human chromosome 1 demonstrated that human chromosome 1 consisted of at least three segments homologous to Suncus chromosomes (chromosomes 7, 10, and 14). This approach with the direct R-banding FISH method is useful for constructing comparative maps between human and insectivore species and for explicating the process of chromosomal rearrangements during the evolution of mammals.     

A high-resolution physical map of equine homologs of HSA19 shows divergent evolution compared with other mammals

A high-resolution (1 marker/700 kb) physically ordered radiation hybrid (RH) and comparative map of 122 loci on equine homologs of human Chromosome 19 (HSA19) shows a variant evolution of these segments in equids/Perissodactyls compared with other mammals. The segments include parts of both the long and the short arm of horse Chromosome 7 (ECA7), the proximal part of ECA21, and the entire short arm of ECA10. The map includes 93 new markers, of which 89 (64 gene-specific and 25 microsatellite) were genotyped on a 5000-rad horse × hamster RH panel, and 4 were mapped exclusively by FISH. The orientation and alignment of the map was strengthened by 21 new FISH localizations, of which 15 represent genes. The approximately sevenfold-improved map resolution attained in this study will prove extremely useful for candidate gene discovery in the targeted equine chromosomal regions. The highlight of the comparative map is the fine definition of homology between the four equine chromosomal segments and corresponding HSA19 regions specified by physical coordinates (bp) in the human genome sequence. Of particular interest are the regions on ECA7 and ECA21 that correspond to the short arm of HSA19—a genomic rearrangement discovered to date only in equids/Perissodactyls as evidenced through comparative Zoo-FISH analysis of the evolution ofancestral HSA19 segments in eight mammalian orders involving about 50 species.     

Chromosomal assignment of the canine melanophilin gene (MLPH): a candidate gene for coat color dilution in Pinschers

Pinschers affected by coat color dilution show a specific pigmentation phenotype. The dilute pigmentation phenotype leads to a silver-blue appearance of the eumelanin-containing fur and a pale sandy color of pheomelanin-containing fur. In Pinscher breeding, dilute black-and-tan dogs are called "blue," and dilute red or brown animals are termed "fawn" or "Isabella fawn." Coat color dilution in Pinschers is sometimes accompanied by hair loss and a recurrent infection of the hair follicles. In human and mice, several well-characterized genes are responsible for similar pigment variations. To investigate the genetic cause of the coat color dilution in Pinschers, we isolated BAC clones containing the canine ortholog of the known murine color dilution gene Mlph. RH mapping of the canine MLPH gene was performed using an STS marker derived from BAC sequences. Additionally, one MLPH BAC clone was used as probe for FISH mapping, and the canine MLPH gene was assigned to CFA25q24.     

Chromosome mapping of MHC class I in rainbow trout (Oncorhynchus mykiss)

The major histocompatibility complex (MHC) is well-studied in mammals. Much research has addressed the genomic organisation of MHC genes and it is well established that human MHC class I genes are located on chromosome 6. However, information on the organisation of the MHC complex in rainbow trout is only beginning to become available. In the present study it was determined that rainbow trout MHC class I sequences are located on chromosome 18. This is the first reported use of fluorescence in situ hybridisation (FISH) to identify the chromosomal location of genes involved in the immune system of fish.     

Comparative mapping of human chromosome 10 to pig chromosomes 10 and 14

Identification of predictive markers in QTL regions that impact production traits in commercial populations of swine is dependent on construction of dense comparative maps with human and mouse genomes. Chromosomal painting in swine suggests that large genomic blocks are conserved between pig and human, while mapping of individual genes reveals that gene order can be quite divergent. High-resolution comparative maps in regions affecting traits of interest are necessary for selection of positional candidate genes to evaluate nucleotide variation causing phenotypic differences. The objective of this study was to construct an ordered comparative map of human chromosome 10 and pig chromosomes 10 and 14. As a large portion of both pig chromosomes are represented by HSA10, genes at regularly spaced intervals along this chromosome were targeted for placement in the porcine genome. A total of 29 genes from human chromosome 10 were mapped to porcine chromosomes 10 (SSC10) and 14 (SSC14) averaging about 5 Mb distance of human DNA per marker. Eighteen genes were assigned by linkage in the MARC mapping population, five genes were physically assigned with the IMpRH mapping panel and seven genes were assigned on both maps. Seventeen genes from human 10p mapped to SSC10, and 12 genes from human 10q mapped to SSC14. Comparative maps of mammalian species indicate that chromosomal segments are conserved across several species and represent syntenic blocks with distinct breakpoints. Development of comparative maps containing several species should reveal conserved syntenic blocks that will allow us to better define QTL regions in livestock.     

Chromosomal localization of phospholipase A2 activating protein, an Ets2 target gene, to 9p21

A murine Ets2 target gene isolated by differential display cloning was identified as the phospholipase A2 activating protein (PLAA) gene. A 2.7-kb human cDNA demonstrating high homology to mouse and rat Plaa genes was then isolated and characterized. Human PLAA contains six WD-40 repeat motifs and three different protein kinase consensus domains. Fluorescence in situ hybridization (FISH) mapping placed PLAA on chromosome 9p21, a region frequently deleted in various cancers. A comprehensive mapping strategy was employed to define further the chromosomal localization of PLAA relative to CDKN2A within the 9p21 locus. Radiation hybrid mapping placed the gene 7.69 cR from WI-5735 (LOD >3.0), a marker in close proximity to CDKN2A and CDKN2B. Yeast artificial chromosome (YAC) mapping localized PLAA proximal to the CDKN2A/CDKN2B genes and to a region flanked by D9S171 and INFA commonly deleted in many neoplasms. Two YACs contained both PLAA and D9S259, a marker present in a second more proximal minimal deleted region observed in cutaneous melanoma and squamous cell lung carcinoma. Double-color fiber FISH mapping confirmed the location of PLAA centromeric to D9S171 and CDKN2A/CDKN2B. The mapping data suggest a possible tumor suppressor role for this gene.     

Characterization of a human chromosome 22 enriched bacterial artificial chromosome sublibrary

Selection of chromosomal sublibraries from total human genomic libraries is critical for chromosome-based physical mapping approaches. We have previously reported a method of screening total human genomic library using flow sorted chromosomal DNA as a hybridization probe and selection of a human chromosome 22-enriched sublibrary from a total human bacterial artificial chromosome (BAC) library (Nucleic Acids Res 1995; 23: 1838–1839). We describe here further details of the method of construction as well as characterization of the chromosome 22-enriched sublibrary thus constructed. Nearly 40% of the BAC clones that have been mapped by fluorescence in situ hybridization (FISH) analysis were localized to chromosome 22. By screening the sublibrary using chromosome 22-specific hybridization probes, we estimated that the sublibrary represents at least 2.5 × coverage of chromosome 22. This is in good agreement with the results from FISH mapping experiments. FISH map data also indicate that chromosome 22-specific BACs in the sublibrary represent all the subregions of chromosome 22.     

Canine-derived cosmid probes containing microsatellites can be used in physical mapping of Arctic fox (Alopex lagopus) and Chinese raccoon dog (Nyctereutes procyonoides procyonoides) genomes

Rapid development of the canine marker genome map facilitates genome mapping of other Canidae species. In this study we present chromosomal localization of 18 canine-derived cosmid probes containing microsatellites in the arctic fox (Alopex lagopus) and Chinese raccoon dog (Nyctereutes procyonoides procyonoides) genomes by the use of fluorescence in situ hybridization (FISH). The chromosome localizations in the arctic fox are in general agreement with data obtained from comparative genome maps of the dog and the fox. However, our studies showed that the order of the loci on some chromosomes was changed during karyotype evolution. Therefore, we suggest that small intrachromosomal rearrangements took place.     

A marker set for construction of a genetic map of the silver fox (Vulpes vulpes)

The silver fox, a variant of the red fox (Vulpes vulpes), is a close relative of the dog (Canis familiaris). Cytogenetic differences and similarities between these species are well understood, but their genomic organizations have not been compared at higher resolution. Differences in their behavior also remain unexplained. Two silver fox strains demonstrating markedly different behavior have been generated at the Institute of Cytology and Genetics of the Russian Academy of Sciences. Foxes selected for tameness are friendly, like domestic dogs, while foxes selected for aggression resist human contact. To refine our understanding of the comparative genomic organization of dogs and foxes, and enable a study of the genetic basis of behavior in these fox strains, we need a meiotic linkage map of the fox. Towards this goal we generated a primary set of fox microsatellite markers. Four hundred canine microsatellites, evenly distributed throughout the canine genome, have been identified that amplify robustly from fox DNA. Polymorphism information content (PIC) values were calculated for a representative subset of these markers and population inbreeding coefficients were determined for tame and aggressive foxes. To begin to identify fox-specific single nucleotide polymorphisms (SNPs) in genes involved in the neurobiology of behavior, fox and dog orthologs of serotonin 5-HT1A and 5-HT1B receptor genes have been cloned. Sequence comparison of these genes from tame and aggressive foxes reveal several SNPs. The close relationship of the fox and dog enables canine genomic tools to be utilized in developing a fox meiotic map and mapping behavioral traits in the fox.     

A cryptic RRY(i) microsatellite from Atlantic salmon (Salmo salar): characterization and chromosomal location.

In this article we describe the isolation and characterization of a cryptic RRY(i) microsatellite from an Atlantic salmon genomic cosmid library. The chromosomal location of the microsatellite-containing cosmid was performed by fluorescent in situ hybridization (FISH) showing a single-locus signal located on an interstitial position of an acrocentric pair. The suitability of this type of microsatellite marker for population genetic analysis and for the development of a genetic map in this species is discussed. In addition, the usefulness of cosmid libraries for physical mapping of microsatellite markers and therefore for the integration of physical and genetic maps is pointed out.