Your search keyword '"Raudsepp, T"' showing total 230 results

201. A detailed physical map of the horse Y chromosome.

Author

Raudsepp T, Santani A, Wallner B, Kata SR, Ren C, Zhang HB, Womack JE, Skow LC, and Chowdhary BP

Subjects

Animals, Contig Mapping methods, Cricetinae, Crosses, Genetic, DNA Fingerprinting, Genetic Markers, Humans, Male, Mammals genetics, Rats, Species Specificity, Y Chromosome chemistry, Horses genetics, Physical Chromosome Mapping methods, Y Chromosome genetics

Abstract

We herein report a detailed physical map of the horse Y chromosome. The euchromatic region of the chromosome comprises approximately 15 megabases (Mb) of the total 45- to 50-Mb size and lies in the distal one-third of the long arm, where the pseudoautosomal region (PAR) is located terminally. The rest of the chromosome is predominantly heterochromatic. Because of the unusual organization of the chromosome (common to all mammalian Y chromosomes), a number of approaches were used to crossvalidate the results. Analysis of the 5,000-rad horse x hamster radiation hybrid panel produced a map spanning 88 centirays with 8 genes and 15 sequence-tagged site (STS) markers. The map was verified by several fluorescence in situ hybridization approaches. Isolation of bacterial artificial chromosome (BAC) clones for the radiation hybrid-mapped markers, end sequencing of the BACs, STS development, and bidirectional chromosome walking yielded 109 markers (100 STS and 9 genes) contained in 73 BACs. STS content mapping grouped the BACs into seven physically ordered contigs (of which one is predominantly ampliconic) that were verified by metaphase-, interphase-, and fiber-fluorescence in situ hybridization and also BAC fingerprinting. The map spans almost the entire euchromatic region of the chromosome, of which 20-25% (approximately 4 Mb) is covered by isolated BACs. The map is presently the most informative among Y chromosome maps in domesticated species, third only to the human and mouse maps. The foundation laid through the map will be critical in obtaining complete sequence of the euchromatic region of the horse Y chromosome, with an aim to identify Y specific factors governing male infertility and phenotypic sex variation.

Published

2004

202. Radiation hybrid mapping of 63 previously unreported equine microsatellite loci.

Author

Wagner ML, Goh G, Wu JT, Raudsepp T, Morrison LY, Alexander LJ, Skow LC, Chowdhary BP, and Mickelson JR

Subjects

Animals, Base Sequence, DNA Primers, Gene Frequency, Genetic Carrier Screening, Molecular Sequence Data, Sequence Analysis, DNA, Horses genetics, Microsatellite Repeats genetics, Radiation Hybrid Mapping

Published

2004

203. Natural killer cell receptors in the horse: evidence for the existence of multiple transcribed LY49 genes.

Author

Takahashi T, Yawata M, Raudsepp T, Lear TL, Chowdhary BP, Antczak DF, and Kasahara M

Subjects

Amino Acid Sequence, Animals, Antigens, Ly classification, Chromosome Mapping, DNA, Complementary isolation & purification, Lectins, C-Type, Molecular Sequence Data, Phylogeny, Protein Isoforms genetics, Protein Isoforms metabolism, Receptors, Immunologic classification, Receptors, KIR, Receptors, NK Cell Lectin-Like, Sequence Alignment, Transcription, Genetic, Antigens, Ly genetics, Horses immunology, Killer Cells, Natural immunology, Receptors, Immunologic genetics

Abstract

In rodents, the Ly49 family encodes natural killer (NK) receptors interacting with classical MHC class I molecules, whereas the corresponding receptors in primates are members of the killer cell immunoglobulin-like receptor (KIR) family. Recent evidence indicates that the cattle, domestic cat, dog, and pig have a single LY49 and multiple KIR genes, suggesting that predominant NK receptors in most non-rodent mammals might be KIR. Here, we show that the horse has at least six LY49 genes, five with an immunoreceptor tyrosine-based inhibition motif (ITIM) and one with arginine in the transmembrane region. Interestingly, none of the horse KIR-like cDNA clones isolated by library screening encoded molecules likely to function asNK receptors; four types of clones were KIR-Ig-like transcript (KIR-ILT) hybrids and contained premature stop codons and/or frameshift mutations, and two putative allelic sequences predicting KIR3DL molecules had mutated ITIM. To our knowledge, this is the first report suggesting that non-rodent mammals may use LY49 as NK receptors for classical MHC class I. We also show that horse spleen expresses ILT-like genes with unique domain organizations. Radiation hybrid mapping and fluorescence in situ hybridization localized horse LY49 and KIR/ILT genes to chromosomes 6q13 and 10p12, respectively.

Published

2004

204. Exceptional conservation of horse-human gene order on X chromosome revealed by high-resolution radiation hybrid mapping.

Author

Raudsepp T, Lee EJ, Kata SR, Brinkmeyer C, Mickelson JR, Skow LC, Womack JE, and Chowdhary BP

Subjects

Animals, Chromosome Mapping, Chromosomes, Artificial, Bacterial, Female, Genetic Markers, Humans, In Situ Hybridization, Fluorescence, Male, X Chromosome radiation effects, Y Chromosome genetics, Horses genetics, X Chromosome genetics

Abstract

Development of a dense map of the horse genome is key to efforts aimed at identifying genes controlling health, reproduction, and performance. We herein report a high-resolution gene map of the horse (Equus caballus) X chromosome (ECAX) generated by developing and typing 116 gene-specific and 12 short tandem repeat markers on the 5,000-rad horse x hamster whole-genome radiation hybrid panel and mapping 29 gene loci by fluorescence in situ hybridization. The human X chromosome sequence was used as a template to select genes at 1-Mb intervals to develop equine orthologs. Coupled with our previous data, the new map comprises a total of 175 markers (139 genes and 36 short tandem repeats, of which 53 are fluorescence in situ hybridization mapped) distributed on average at approximately 880-kb intervals along the chromosome. This is the densest and most uniformly distributed chromosomal map presently available in any mammalian species other than humans and rodents. Comparison of the horse and human X chromosome maps shows remarkable conservation of gene order along the entire span of the chromosomes, including the location of the centromere. An overview of the status of the horse map in relation to mouse, livestock, and companion animal species is also provided. The map will be instrumental for analysis of X linked health and fertility traits in horses by facilitating identification of targeted chromosomal regions for isolation of polymorphic markers, building bacterial artificial chromosome contigs, or sequencing.

Published

2004

205. Radiation hybrid mapping of 75 previously unreported equine microsatellite loci.

Author

Wagner ML, Goh G, Wu JT, Raudsepp T, Morrison LY, Alexander LJ, Skow LS, Chowdhary BP, and Mickelson JR

Subjects

Animals, Base Sequence, DNA Primers, Gene Frequency, Molecular Sequence Data, Sequence Analysis, DNA, Horses genetics, Microsatellite Repeats genetics, Radiation Hybrid Mapping

Published

2004

206. A 1.4-Mb interval RH map of horse chromosome 17 provides detailed comparison with human and mouse homologues.

Author

Lee EJ, Raudsepp T, Kata SR, Adelson D, Womack JE, Skow LC, and Chowdhary BP

Subjects

Animals, Chromosomes, Artificial, Bacterial, DNA Primers, Genetic Markers, Genomics methods, Humans, In Situ Hybridization, Fluorescence, Mice, Sequence Alignment, Sequence Homology, Nucleic Acid, Chromosome Mapping methods, Chromosomes, Horses genetics

Abstract

Comparative genomics has served as a backbone for the rapid development of gene maps in domesticated animals. The integration of this approach with radiation hybrid (RH) analysis provides one of the most direct ways to obtain physically ordered comparative maps across evolutionarily diverged species. We herein report the development of a detailed RH and comparative map for horse chromosome 17 (ECA17). With markers distributed at an average interval of every 1.4 Mb, the map is currently the most informative among the equine chromosomes. It comprises 75 markers (56 genes and 19 microsatellites), of which 50 gene specific and 5 microsatellite markers were generated in this study and typed to our 5000-rad horse x hamster whole genome RH panel. The markers are dispersed over six RH linkage groups and span 825 cR(5000). The map is among the most comprehensive whole chromosome comparative maps currently available for domesticated animals. It finely aligns ECA17 to human and mouse homologues (HSA13 and MMU1, 3, 5, 8, and 14, respectively) and homologues in other domesticated animals. Comparisons provide insight into their relative organization and help to identify evolutionarily conserved segments. The new ECA17 map will serve as a template for the development of clusters of BAC contigs in regions containing genes of interest. Sequencing of these regions will help to initiate studies aimed at understanding the molecular mechanisms for various diseases and inherited disorders in horse as well as human.

Published

2004

207. Comparative mapping in the pig: localization of 214 expressed sequence tags.

Author

Cirera S, Jørgensen CB, Sawera M, Raudsepp T, Chowdhary BP, and Fredholm M

Subjects

Animals, DNA Primers, In Situ Hybridization, Fluorescence, Chromosome Mapping, Expressed Sequence Tags, Radiation Hybrid Mapping, Sus scrofa genetics

Abstract

In total, 214 ESTs (Expressed Sequence Tags) were assigned to the porcine gene map by using somatic cell hybrid mapping, radiation hybrid mapping, and FISH. The ESTs were isolated from a porcine small intestine cDNA library on the basis of significant sequence identity with human annotated genes. In total, 390 primer pairs were designed primarily in the 3' UTR of the sequences. Overall, 58.6% of the ESTs were successfully mapped by this approach. In total, 191 of the localizations are in agreement with the human comparative map, strongly indicating that these represent true orthologous genes. The remaining 23 ESTs provide new comparative mapping data, which should be considered as preliminary until confirmed by other studies. Our mapping efforts provide a significant contribution to the porcine map as well as to the comparative map for human and pig.

Published

2003

208. Remarkable synteny conservation of melanocortin receptors in chicken, human, and other vertebrates.

Author

Schiöth HB, Raudsepp T, Ringholm A, Fredriksson R, Takeuchi S, Larhammar D, and Chowdhary BP

Subjects

Animals, Chromosome Mapping, Humans, In Situ Hybridization, Fluorescence, Mice, Phylogeny, Chickens genetics, Multigene Family, Receptors, Melanocortin genetics, Synteny

Abstract

The melanocortin receptors (MCR) belong to the superfamily of G-protein-coupled receptors that participate in both peripheral and central functions, including regulation of energy balance. Genomic clones of the five chicken (GGA) MCRs were isolated and used to find the chromosomal location of each of the loci. The genes encoding MC2R and MC5R mapped to the middle part of the long arm of chromosome 2 (GGA2q22-q26) and MC4R proximally on the same chromosome arm, close to the centromere (2q12). This arrangement seems to be conserved on chromosome 18 in the human (HSA18). The MC1R and MC3R genes mapped to different microchromosomes that also appear to share homology with the respective human localization. The conserved synteny of the MC2R, MC5R, and MC4R cluster in chicken (GGA2), human (HSA18), and other mammals suggests that this cluster is ancient and was formed by local gene duplications that most likely occurred early in vertebrate evolution. Analysis of conserved synteny with mammalian genomes and paralogon segments prompted us to predict an ancestral gene organization that may explain how this family was formed through both local duplication and tetraploidization processes.

Published

2003

209. The first-generation whole-genome radiation hybrid map in the horse identifies conserved segments in human and mouse genomes.

Author

Chowdhary BP, Raudsepp T, Kata SR, Goh G, Millon LV, Allan V, Piumi F, Guérin G, Swinburne J, Binns M, Lear TL, Mickelson J, Murray J, Antczak DF, Womack JE, and Skow LC

Subjects

Animals, Cell Line, Cricetinae, Genetic Markers genetics, Genetic Markers radiation effects, Humans, Hybrid Cells, In Situ Hybridization, Fluorescence methods, In Situ Hybridization, Fluorescence statistics & numerical data, In Situ Hybridization, Fluorescence veterinary, Mice, Microsatellite Repeats genetics, Microsatellite Repeats radiation effects, Molecular Sequence Data, Radiation Hybrid Mapping statistics & numerical data, Sequence Alignment methods, Sequence Alignment statistics & numerical data, Sequence Alignment veterinary, Statistical Distributions, Synteny genetics, Synteny radiation effects, Conserved Sequence genetics, Genome, Genome, Human, Horses genetics, Radiation Hybrid Mapping methods, Radiation Hybrid Mapping veterinary

Abstract

A first-generation radiation hybrid (RH) map of the equine (Equus caballus) genome was assembled using 92 horse x hamster hybrid cell lines and 730 equine markers. The map is the first comprehensive framework map of the horse that (1) incorporates type I as well as type II markers, (2) integrates synteny, cytogenetic, and meiotic maps into a consensus map, and (3) provides the most detailed genome-wide information to date on the organization and comparative status of the equine genome. The 730 loci (258 type I and 472 type II) included in the final map are clustered in 101 RH groups distributed over all equine autosomes and the X chromosome. The overall marker retention frequency in the panel is approximately 21%, and the possibility of adding any new marker to the map is approximately 90%. On average, the mapped markers are distributed every 19 cR (4 Mb) of the equine genome--a significant improvement in resolution over previous maps. With 69 new FISH assignments, a total of 253 cytogenetically mapped loci physically anchor the RH map to various chromosomal segments. Synteny assignments of 39 gene loci complemented the RH mapping of 27 genes. The results added 12 new loci to the horse gene map. Lastly, comparison of the assembly of 447 equine genes (256 linearly ordered RH-mapped and additional 191 FISH-mapped) with the location of draft sequences of their human and mouse orthologs provides the most extensive horse-human and horse-mouse comparative map to date. We expect that the foundation established through this map will significantly facilitate rapid targeted expansion of the horse gene map and consequently, mapping and positional cloning of genes governing traits significant to the equine industry.

Published

2003

210. Linkage and comparative mapping of the locus controlling susceptibility towards E. COLI F4ab/ac diarrhoea in pigs.

Author

Jørgensen CB, Cirera S, Anderson SI, Archibald AL, Raudsepp T, Chowdhary B, Edfors-Lilja I, Andersson L, and Fredholm M

Subjects

Animals, Animals, Domestic, Animals, Wild, Chromosome Mapping veterinary, Crosses, Genetic, Cytogenetic Analysis methods, Cytogenetic Analysis veterinary, Diarrhea genetics, Escherichia coli immunology, Escherichia coli Infections genetics, Female, Genotype, Humans, In Situ Hybridization, Fluorescence methods, In Situ Hybridization, Fluorescence veterinary, Male, Swine, Antigens, Bacterial immunology, Chromosome Mapping methods, Diarrhea microbiology, Diarrhea veterinary, Escherichia coli Infections veterinary, Escherichia coli Proteins immunology, Fimbriae Proteins immunology, Genetic Linkage genetics, Genetic Predisposition to Disease, Microsatellite Repeats genetics, Swine Diseases genetics, Swine Diseases microbiology

Abstract

In 1995, Edfors-Lilja and coworkers mapped the locus for the E. COLI K88ab (F4ab) and K88ac (F4ac) intestinal receptor to pig chromosome 13 (SSC13). Using the same family material we have refined the map position to a region between the microsatellite markers Sw207 and Sw225. Primers from these markers were used to screen a pig BAC library and the positive clones were used for fluorescent in situ hybridization (FISH) analysis. The results of the FISH analysis helped to propose a candidate gene region in the SSC13q41-->q44 interval. Shotgun sequencing of the FISH-mapped BAC clones revealed that the candidate region contains an evolutionary breakpoint between human and pig. In order to further characterise the rearrangements between SSC13 and human chromosome 3 (HSA3), detailed gene mapping of SSC13 was carried out. Based on this mapping data we have constructed a detailed comparative map between SSC13 and HSA3. Two candidate regions on human chromosome 3 have been identified that are likely to harbour the human homologue of the gene responsible for susceptibility towards E. COLI F4ab/ac diarrhoea in pigs., (Copyright 2003 S. Karger AG, Basel)

Published

2003

211. Genetic mapping of GBE1 and its association with glycogen storage disease IV in American Quarter horses.

Author

Ward TL, Valberg SJ, Lear TL, Guérin G, Milenkovic D, Swinburne JE, Binns MM, Raudsepp T, Skow L, Chowdhary BP, and Mickelson JR

Subjects

Alleles, Americas, Animals, Genetic Linkage genetics, In Situ Hybridization, Fluorescence methods, In Situ Hybridization, Fluorescence veterinary, Microsatellite Repeats genetics, Radiation Hybrid Mapping methods, Radiation Hybrid Mapping veterinary, Sequence Analysis, DNA methods, Sequence Analysis, DNA veterinary, 1,4-alpha-Glucan Branching Enzyme genetics, Chromosome Mapping methods, Chromosome Mapping veterinary, Glycogen Storage Disease Type IV genetics, Glycogen Storage Disease Type IV veterinary, Horse Diseases genetics, Horses genetics

Abstract

Comparative biochemical and histopathological data suggest that a deficiency in the glycogen branching enzyme (GBE) is responsible for a fatal neonatal disease in Quarter Horse foals that closely resembles human glycogen storage disease type IV (GSD IV). Identification of DNA markers closely linked to the equine GBE1 gene would assist us in determining whether a mutation in this gene leads to the GSD IV-like condition. FISH using BAC clones as probes assigned the equine GBE1 gene to a marker deficient region of ECA26q12-->q13. Four other genes, ROBO2, ROBO1, POU1F1, and HTR1F, that flank GBE1 within a 10-Mb segment of HSA3p12-->p11, were tightly linked to equine GBE1 when analyzed on the Texas A&M University 5000 rad equine radiation hybrid panel, while the GLB1, MITF, RYBP, and PROS1 genes that flank this 10-Mb interval were not linked with markers in the GBE1 group. A polymorphic microsatellite (GBEms1) in a GBE1 BAC clone was then identified and genetically mapped to ECA26 on the Animal Health Trust full-sibling equine reference family. All Quarter Horse foals affected with GSD IV were homozygous for an allele of GBEms1, as well as an allele of the most closely linked microsatellite marker, while a control horse population showed significant allelic variation with these markers. This data provides strong molecular genetic support for the candidacy of the GBE1 locus in equine GSD IV., (Copyright 2003 S. Karger AG, Basel)

Published

2003

212. An ordered BAC contig map of the equine major histocompatibility complex.

Author

Gustafson AL, Tallmadge RL, Ramlachan N, Miller D, Bird H, Antczak DF, Raudsepp T, Chowdhary BP, and Skow LC

Subjects

Animals, Blotting, Southern methods, Blotting, Southern veterinary, DNA genetics, DNA Fingerprinting methods, DNA Fingerprinting veterinary, In Situ Hybridization, Fluorescence veterinary, Chromosomes, Artificial, Bacterial genetics, Contig Mapping methods, Contig Mapping veterinary, Horses genetics, Major Histocompatibility Complex genetics

Abstract

A physical map of ordered bacterial artificial chromosome (BAC) clones was constructed to determine the genetic organization of the horse major histocompatibility complex. Human, cattle, pig, mouse, and rat MHC gene sequences were compared to identify highly conserved regions which served as source templates for the design of overgo primers. Thirty-five overgo probes were designed from 24 genes and used for hybridization screening of the equine USDA CHORI 241 BAC library. Two hundred thirty-eight BAC clones were assembled into two contigs spanning the horse MHC region. The first contig contains the MHC class II region and was reduced to a minimum tiling path of nine BAC clones that span approximately 800 kb and contain at least 20 genes. A minimum tiling path of a second contig containing the class III/I region is comprised of 14 BAC clones that span approximately 1.6 Mb and contain at least 34 genes. Fluorescence in situ hybridization (FISH) using representative clones from each of the three regions of the MHC localized the contigs onto ECA20q21 and oriented the regions relative to one another and the centromere. Dual-colored FISH revealed that the class I region is proximal to the centromere, the class II region is distal, and the class III region is located between class I and II. These data indicate that the equine MHC is a single gene-dense region similar in structure and organization to the human MHC and is not disrupted as in ruminants and pigs., (Copyright 2003 S. Karger AG, Basel)

Published

2003

213. Molecular characterization of the equine testis-specific protein 1 (TPX1) and acidic epididymal glycoprotein 2 (AEG2) genes encoding members of the cysteine-rich secretory protein (CRISP) family.

Author

Giese A, Jude R, Kuiper H, Raudsepp T, Piumi F, Schambony A, Guérin G, Chowdhary BP, Distl O, Töpfer-Petersen E, and Leeb T

Subjects

Amino Acid Sequence, Animals, Base Sequence, Chromosome Mapping, Cloning, Molecular, DNA chemistry, DNA genetics, DNA, Complementary chemistry, DNA, Complementary genetics, Exons, Gene Expression, Genes genetics, In Situ Hybridization, Fluorescence, Introns, Male, Molecular Sequence Data, Sequence Alignment, Sequence Analysis, DNA, Sequence Homology, Amino Acid, Glycoproteins genetics, Horses genetics, Salivary Proteins and Peptides genetics, Seminal Plasma Proteins genetics

Abstract

The cysteine-rich secretory protein (CRISP) family consists of three members called acidic epididymal glycoprotein 1 (AEG1), AEG2, and testis-specific protein 1 (TPX1), which share 16 conserved cysteine residues at their C-termini. The CRISP proteins are primarily expressed in different sections of the male genital tract and are thought to mediate cell-cell interactions of male germ cells with other cells during sperm maturation or during fertilization. Therefore, their genes are of interest as candidate genes for inherited male fertility dysfunctions and as putative quantitative trait loci for male fertility traits. In this report, the cloning and DNA sequence of 137 kb of horse genomic DNA from equine chromosome 20q22 containing the closely linked equine TPX1 and AEG2 genes are described. The equine TPX1 gene consists of ten exons spanning 18 kb while the AEG2 gene consists of eight exons that are spread over 24 kb. The expression of these two genes was investigated in several tissues by reverse transcription polymerase chain reaction analysis and Western blotting. Comparative genome analysis between horse, human, and mouse indicates that all three CRISP genes are clustered on one chromosomal location, which shows conserved synteny between these species.

Published

2002

214. Conservation of gene order between horse and human X chromosomes as evidenced through radiation hybrid mapping.

Author

Raudsepp T, Kata SR, Piumi F, Swinburne J, Womack JE, Skow LC, and Chowdhary BP

Subjects

Animals, Biological Evolution, Gene Order, Genetic Markers, Horses genetics, Humans, Radiation Hybrid Mapping, Synteny, X Chromosome genetics

Abstract

A radiation hybrid (RH) map of the equine X chromosome (ECAX) was obtained using the recently produced 5000(rad) horse x hamster hybrid panel. The map comprises 34 markers (16 genes and 18 microsatellites) and spans a total of 676 cR(5000), covering almost the entire length of ECAX. Cytogenetic alignment of the RH map was improved by fluorescent in situ hybridization mapping of six of the markers. The map integrates and refines the currently available genetic linkage, syntenic, and cytogenetic maps, and adds new loci. Comparison of the physical location of the 16 genes mapped in this study with the human genome reveals similarity in the order of the genes along the entire length of the two X chromosomes. This degree of gene order conservation across evolutionarily distantly related species has up to now been reported only between human and cat. The ECAX RH map provides a framework for the generation of a high-density map for this chromosome. The map will serve as an important tool for positional cloning of X-linked diseases/conditions in the horse.

Published

2002

215. Construction of a 5000(rad) whole-genome radiation hybrid panel in the horse and generation of a comprehensive and comparative map for ECA11.

Author

Chowdhary BP, Raudsepp T, Honeycutt D, Owens EK, Piumi F, Guérin G, Matise TC, Kata SR, Womack JE, and Skow LC

Subjects

Animals, Cell Line, Genetic Markers, Chromosomes genetics, Genome, Horses genetics, Radiation Hybrid Mapping

Abstract

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.

Published

2002

216. Interstitial telomeric sites and NORs in Hartmann's zebra (Equus zebra hartmannae) chromosomes.

Author

Santani A, Raudsepp T, and Chowdhary BP

Subjects

Animals, Base Sequence, Chromosome Banding, Conserved Sequence, Evolution, Molecular, In Situ Hybridization, Fluorescence, Karyotyping, Male, RNA, Ribosomal genetics, RNA, Ribosomal metabolism, Repetitive Sequences, Nucleic Acid, Equidae genetics, Nucleolus Organizer Region genetics, Telomere genetics

Abstract

Interstitial telomeric sites (ITSs) are considered as signatures of chromosomal rearrangements that take place during karyotype evolution. Understanding that equids have undergone rapid karyotype evolution compared with the average in other mammals, a search of these signatures was carried out in the Hartmann's mountain zebra (Equus zebra hartmannae; EZH) chromosomes. Six consistent ITSs were identified on five of the zebra chromosomes (EZH1p, 1q, 2q, 5q, 6q and 11q). The location of these ITSs coincided with fusion points of some of the evolutionarily conserved human-Hartmann's zebra chromosomal segments suggesting that the sequences are remnants of fusion events between ancestral chromosomes. Incidentally, three of the ITSs also matched with the presence of constitutive heterochromatin. Further, ribosomal gene clusters were localized on five zebra chromosomes and the data were compared with those in other equid species. The findings offer preliminary evidence on the likely evolution of some of the Hartmann's zebra chromosomes and add to the current search for clues that lead to the ancestral chromosomal configuration in equids.

Published

2002

217. Cytogenetic analysis of California condor (Gymnogyps californianus) chromosomes: comparison with chicken (Gallus gallus) macrochromosomes.

Author

Raudsepp T, Houck ML, O'Brien PC, Ferguson-Smith MA, Ryder OA, and Chowdhary BP

Subjects

Animals, California, Chromosome Banding, In Situ Hybridization, Fluorescence, Karyotyping, Birds genetics, Chickens genetics, Chromosome Mapping

Abstract

The California condor is the largest flying bird in North America and belongs to a group of New World vultures. Recovering from a near fatal population decline, and currently with only 197 extant individuals, the species remains listed as endangered. Very little genetic information exists for this species, although sexing methods employing chromosome analysis or W-chromosome specific amplification is routinely applied for the management of this monomorphic species. Keeping in mind that genetic conditions like chondrodystrophy have been identified, preliminary steps were undertaken in this study to understand the genome organization of the condor. This included an extensive cytogenetic analysis that provided (i) a chromosome number of 80 (with a likelihood of an extra pair of microchromosomes), and (ii) information on the centromeres, telomeres and nucleolus organizer regions. Further, a comparison between condor and chicken macrochromosomes was obtained by using individual chicken chromosome specific paints 1-9 and Z and W on condor metaphase spreads. Except for chromosomes 4 and Z, each of the chicken (GGA) macrochromosomes painted a single condor (GCA) macrochromosome. GGA4 paint detected complete homology with two condor chromosomes, viz., GCA4 and GCA9 providing additional proof that the latter are ancestral chromosomes in the birds. The chicken Z chromosome showed correspondence with both Z and W in the condor. The homology suggests that the condor sex chromosomes have not completely differentiated during evolution, which is unlike the majority of the non-ratites studied up till now. Overall, the study provides detailed cytogenetic and basic comparative information on condor chromosomes. These findings significantly advance the effort to study the chondrodystrophy that is responsible for over ten percent mortality in the condor., (Copyright 2002 S. Karger AG, Basel)

Published

2002

218. Comparative mapping in equids: the asine X chromosome is rearranged compared to horse and Hartmann's mountain zebra.

Author

Raudsepp T, Lear TL, and Chowdhary BP

Subjects

Animals, Chromosome Banding, Chromosome Mapping, Chromosomes, Artificial, Bacterial genetics, Genetic Markers, Genetic Variation, Metaphase genetics, Equidae genetics, Gene Rearrangement genetics, Horses genetics, X Chromosome

Abstract

The X chromosomes of the extant equids, in general, share morphology and banding pattern similarities. However, the donkey X is, in part, an exception because of significantly different centromeric index and variant banding patterns in the pericentromeric region. To verify the underlying molecular basis of this difference, twelve equine BAC clones were FISH mapped to donkey (EAS) and Hartmann's mountain zebra (EZH) metaphase spreads. Loci from the terminal region of Xp and distal to terminal regions of the Xq showed the same order and relative position in all three species, implying cross-species conservation of these chromosomal segments. However, loci from the proximal/pericentromeric regions of either arms showed similar FISH locations in horse and zebra but a slightly deviant location and relative position in the donkey. Three of the markers (tel-OTC, TRAP170 and (ps)ALDH2- cen) located on the short arm of ECAX and EZHX were found inverted on the long arm of EASX, along with the transposition of the centromere. This molecular evidence of a pericentromeric inversion helps define the likely evolutionary breakpoints causing the rearrangement. The breakpoints most likely correspond to the region between Xp16-->q12 in the horse and Xp12-->q13 in the donkey. The findings coupled with the highly conserved X-chromosome gene order between horse and outgroup species, human and cat, suggest that the equine type X is ancestral while the asine type X arose as a result of an independent inversion event. The study adds two new markers to horse, 11 to donkey and 12 to Hartmann's zebra gene maps, thus contributing to the expansion of comparative maps in the equids., (Copyright 2002 S. Karger AG, Basel)

Published

2002

219. Correspondence of human chromosomes 9, 12, 15, 16, 19 and 20 with donkey chromosomes refines homology between horse and donkey karyotypes.

Author

Raudsepp T and Chowdhary BP

Subjects

Animals, Chromosome Painting, Chromosomes, Human, Pair 12, Chromosomes, Human, Pair 15, Chromosomes, Human, Pair 16, Chromosomes, Human, Pair 19, Chromosomes, Human, Pair 20, Chromosomes, Human, Pair 9, Genome, Human, Humans, Karyotyping, Nucleic Acid Hybridization, Physical Chromosome Mapping, Sequence Homology, Nucleic Acid, Species Specificity, Chromosomes, Chromosomes, Human, Equidae genetics, Horses genetics

Abstract

Whole chromosome paints for human (HSA) chromosomes 9, 12, 15 and 20 and arm-specific paints for HSA16p, 19p and 19q were applied on donkey metaphase spreads. All probes, except HSA19p, gave distinct hybridization signals on donkey chromosomes/chromosomal segments. The results show direct segmental homology between human and donkey genomes, and enable refinement of correspondence between donkey and horse karyotypes. Of specific interest is the identification of hitherto unknown correspondence between four equine acrocentric chromosomes (ECA22, 23, 25 and 28) and the donkey chromosomes. Overall, the findings mark the beginning of an ordered study of comparative organization of genomes/karyotypes of the equids, that can shed light on karyotype evolution and ancestral chromosomal condition in the Perissodactyls.

Published

2001

220. HSA4 and GGA4: remarkable conservation despite 300-Myr divergence.

Author

Chowdhary BP and Raudsepp T

Subjects

Animals, Chromosome Painting, Humans, Time Factors, Chickens genetics, Chromosomes, Chromosomes, Human, Conserved Sequence

Abstract

The chicken (GGA) and human (HSA) genomes diverged around 300-350 Myr ago. Due to this large phylogenetic distance, significant synteny conservation has not been anticipated between the genomes of the two species. However, Zoo-FISH with HSA4 chromosome-specific paint on chicken metaphase chromosomes shows that the human chromosome corresponds largely to the GGA4cen-->q26 region. Comparative gene mapping data in the two species, though limited, provide strong support for these observations. The findings, together with the very recently published data on HSA9-GGAZ and HSA12-GGA1, show that some large chromosomal segments share conserved synteny in the two species. These syntenies are considerably disrupted in the mouse. This makes us believe that despite very early divergence, parts of the human and chicken genomes are more conserved than those of human and mouse, which radiated only 100-120 Myr ago. Moreover, the HSA4-GGA4q correspondence points to a "candidate" chromosome from the karyotype of a mammal-bird ancestor. The findings are thus a small but important step toward understanding the evolution of the two genomes., (Copyright 2000 Academic Press.)

Published

2000

221. Cytogenetics of donkey chromosomes: nomenclature proposal based on GTG-banded chromosomes and depiction of NORs and telomeric sites.

Author

Raudsepp T, Christensen K, and Chowdhar BP

Subjects

Animals, Histology, Comparative standards, Horses genetics, Humans, In Situ Hybridization, Fluorescence, Karyotyping, Nucleolus Organizer Region genetics, Nucleolus Organizer Region ultrastructure, Physical Chromosome Mapping standards, Telomere genetics, Telomere ultrastructure, Chromosome Banding standards, Chromosomes genetics, Cytogenetic Analysis standards, Equidae genetics, Terminology as Topic

Abstract

With the expansion of comparative genome analysis across different mammals, there is an increasing need to have well-defined banded karyotypes for the species chosen for investigation. In this context, the steadily growing gene mapping data in the donkey urgently require a framework whereby alignment/comparison of genetic information can be readily made with equids and other mammalian species. Hence a GTG-banded karyotype of the donkey (Equus asinus; EAS) is presented, along with schematic drawings and nomenclature of the banded chromosomes. In addition, the most characteristic features of individual chromosomes are described and their relative size estimated. Using the FISH approach, the location of nucleolous organizer regions (NORs) and telomeric repeat sequences (TTAGGG) were detected. Where possible, information on asine chromosomes is supplemented with known/likely equine and human homologues. The study thus primarily aims to provide an appropriate cytogenetic basis for the donkey chromosomes, so that research focused on gene mapping and comparative genomics in this species can be reported under a common format.

Published

2000

222. Comparison of horse chromosome 3 with donkey and human chromosomes by cross-species painting and heterologous FISH mapping.

Author

Raudsepp T, Kijas J, Godard S, Guérin G, Andersson L, and Chowdhary BP

Subjects

Animals, Base Sequence, DNA Primers, DNA Probes, DNA, Complementary, Humans, Species Specificity, Chromosomes, Chromosomes, Human, Equidae genetics, Horses genetics, In Situ Hybridization, Fluorescence methods

Abstract

The melanocortin 1 receptor (MC1R), mast/stem cell growth factor receptor (KIT), and platelet-derived growth factor receptor alpha (PDGFRA) are loci that all belong to equine linkage group 2 (LG2). Of these, KIT was fluorescent in situ hybridization (FISH) mapped to ECA3q21 with equine cDNA and heterologous porcine BAC probes, while MC1R was localized to ECA3p12 and PDGFRA to ECA3q21 with heterologous porcine BAC probes. A three-step comparison between ECA3 and donkey chromosomes was carried out. First, microdissected ECA3 painting probe was used on donkey chromosomes, which showed disruption of the equine synteny. Next, human (HSA) Chromosomes (Chrs) 16q and 4 specific paints, known to be homologous to ECA3p and 3q, respectively, were applied to detect homologous chromosomal segment(s) in donkey. Finally, four genes (MC1R, ALB, PDGFRA, KIT) and two equine microsatellite markers (SGCV18 and SGCV33) located on ECA3 were FISH mapped to donkey chromosomes. The findings refined the cross species painting homology results and added six new markers to the nascent donkey gene map. The hypothesis that Tobiano coat color in horses may be associated with a chromosomal inversion involving genes within LG2 was tested by G-banding-based cytogenetic analysis and ordering of four loci-KIT, PDGFRA, albumin (ALB), and MC1R-in Tobiano and non-tobiano (homozygous as well as heterozygous) horses. However, no difference either in banding patterns or location/relative order of the genes was observed in the three classes. The study highlights successful FISH mapping of BAC probes across evolutionarily diverged species, viz., pig and horse/donkey, and represents the first use of large-sized individual clones across distantly related farm animals.

Published

1999

223. Structure and chromosomal assignment of the sterol 12alpha-hydroxylase gene (CYP8B1) in human and mouse: eukaryotic cytochrome P-450 gene devoid of introns.

Author

Gåfvels M, Olin M, Chowdhary BP, Raudsepp T, Andersson U, Persson B, Jansson M, Björkhem I, and Eggertsen G

Subjects

Amino Acid Sequence, Animals, Base Sequence, COS Cells, Chromosome Banding, Chromosome Mapping, Chromosomes genetics, Chromosomes, Human, Pair 3 genetics, DNA, Complementary chemistry, DNA, Complementary genetics, DNA, Complementary isolation & purification, Eukaryotic Cells metabolism, Gene Expression Regulation, Genes genetics, Humans, Hybrid Cells, In Situ Hybridization, Fluorescence, Introns, Liver metabolism, Male, Mice, Mice, Inbred BALB C, Mice, Inbred Strains, Molecular Sequence Data, Promoter Regions, Genetic, RNA genetics, RNA metabolism, Rabbits, Regulatory Sequences, Nucleic Acid, Sequence Alignment, Sequence Analysis, DNA, Sequence Homology, Amino Acid, Steroid 12-alpha-Hydroxylase, Transfection, Cytochrome P-450 Enzyme System genetics, Steroid Hydroxylases genetics

Abstract

Sterol 12alpha-hydroxylase (CYP8B1) is a hepatic cytochrome P-450 that controls the ratio of cholic acid over chenodeoxycholic acid in bile and thus controls the solubility of cholesterol. Both the human and the mouse CYP8B1 complementary DNA and gene were cloned and structurally characterized. Surprisingly, the genomic DNA from both species was found to lack introns. The major transcript of the human gene was estimated to be 3950 bp, and the putative promoter region was estimated to be at least 1360 bp. The murine structural gene was found to span approximately 3 kb. By using FISH and radiation hybrid mapping techniques, the human CYP8B1 gene was located to chromosome 3p21.3-p22, whereas FISH mapped the murine counterpart to chromosome 9qF4, a region that is homologous to the third human chromosome. The results from the chromosome mapping and Southern blotting indicated that the gene is present in a single copy. Transcription of the mouse and human CYP8B1 genes was initiated from a position situated 51 and 35 bases, respectively, downstream of a consensus TATA box. A homology of 21% for the promoter regions of mouse and human may indicate differences in transcriptional regulation. Although a potent induction of CYP8B1 mRNA was observed upon starvation of mice, the mechanism behind this effect was not revealed by analysis of the promoter for potential cis-acting elements. In the human promoter, several possible cis-acting regions were identified but none of them could be directly related to bile acid metabolism. After transfection of COS cells with the human coding region, mRNA and enzymatic activity for the 12alpha-hydroxylase were identified. This is the first mammalian cytochrome P-450 gene reported to lack introns. The importance of this structural feature for evolution and gene regulation is discussed., (Copyright 1999 Academic Press.)

Published

1999

224. Construction of chromosome-specific paints for meta- and submetacentric autosomes and the sex chromosomes in the horse and their use to detect homologous chromosomal segments in the donkey.

Author

Raudsepp T and Chowdhary BP

Subjects

Animals, Female, Humans, Male, Chromosome Painting methods, Equidae genetics, Horses genetics, Sex Chromosomes

Abstract

A pilot study comparing horse and donkey karyotypes on a molecular basis was initiated using the chromosomal microdissection approach. All equine meta- and submetacentric chromosomes, viz. ECA1 to ECA13 and the X and Y chromosomes, were microdissected. The DNA was PCR amplified, non-radioactively labelled and used as probes on equine metaphase chromosomes to confirm their origin. Once tested, the paints were used as probes on donkey metaphase chromosomes to detect homologous chromosomal segments between the two species. The results not only detected conservation of whole chromosome and/or arm synteny between the two karyotypes, but also highlighted varying degrees of rearrangements. The findings also enable deduction of homology between parts of donkey and human karyotypes. In light of the molecular evidence, this study examines the accuracy of the available comparative cytogenetic data between horse and donkey.

Published

1999

225. Repetitive exon 45/46-related sequences of human Ca2+ channel alpha1C subunit gene.

Author

Soldatov NM, Raudsepp T, and Chowdhary BP

Subjects

Base Sequence, Chromosome Mapping, Chromosomes, Human, Pair 12, DNA, Complementary, Humans, In Situ Hybridization, Fluorescence, Molecular Sequence Data, Sequence Homology, Nucleic Acid, Calcium Channels genetics, Exons, Repetitive Sequences, Nucleic Acid

Abstract

We found in the Ca2+ channel alpha1C subunit gene a new repetitive element of three paired exon 45/46-related sequences. We also identified a new exon 45/46-related sequence in the human genome and mapped it by fluorescence in situ hybridization to the 12p11.2 and 12p13.2-p13.1 bands. These positions are not recognized by DNA probes generated from the 5'- and 3'-terminal regions of the alpha1C gene. A possible existence of a new genomic homologue of the alpha1C subunit gene is discussed.

Published

1998

226. Evolution of the avian sex chromosomes from an ancestral pair of autosomes.

Author

Fridolfsson AK, Cheng H, Copeland NG, Jenkins NA, Liu HC, Raudsepp T, Woodage T, Chowdhary B, Halverson J, and Ellegren H

Subjects

Animals, Chickens, Genetic Linkage, In Situ Hybridization, Fluorescence, Molecular Sequence Data, Biological Evolution, Chromosome Mapping, Sex Chromosomes genetics

Abstract

Among the mechanisms whereby sex is determined in animals, chromosomal sex determination is found in a wide variety of distant taxa. The widespread but not ubiquitous occurrence, not even within lineages, of chromosomal sex determination suggests that sex chromosomes have evolved independently several times during animal radiation, but firm evidence for this is lacking. The most favored model for this process is gradual differentiation of ancestral pairs of autosomes. As known for mammals, sex chromosomes may have a very ancient origin, and it has even been speculated that the sex chromosomes of mammals and birds would share a common chromosomal ancestry. In this study we showed that the two genes, ATP5A1 and CHD1, so far assigned to the female-specific W chromosome of birds both exist in a very closely related copy on the Z chromosome but are not pseudoautosomal. This indicates a common ancestry of the two sex chromosomes, consistent with the evolution from a pair of autosomes. Comparative mapping demonstrates, however, that ATP5A1 and CHD1 are not sex-linked among eutherian mammals; this is also not the case for the majority of other genes so far assigned to the avian Z chromosome. Our results suggest that the evolution of sex chromosomes has occurred independently in mammals and birds.

Published

1998

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

Author

Chaudhary R, Raudsepp T, Guan XY, Zhang H, and Chowdhary BP

Subjects

Animals, Humans, Chromosomes, Human, Pair 16, Chromosomes, Human, Pair 19, Chromosomes, Human, Pair 2, Chromosomes, Human, Pair 5, Chromosomes, Human, Pair 6, Horses genetics, In Situ Hybridization, Fluorescence methods, Swine genetics

Abstract

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.

Published

1998

228. International system for cytogenetic nomenclature of the domestic horse. Report of the Third International Committee for the Standardization of the domestic horse karyotype, Davis, CA, USA, 1996.

Author

Bowling AT, Breen M, Chowdhary BP, Hirota K, Lear T, Millon LV, Ponce de Leon FA, Raudsepp T, and Stranzinger G

Subjects

Animals, Chromosomes classification, Chromosomes genetics, Cytogenetics, Karyotyping, Horses genetics, Terminology as Topic

Published

1997

229. FISH mapping of the IGF2 gene in horse and donkey-detection of homoeology with HSA11.

Author

Raudsepp T, Otte K, Rozell B, and Chowdhary BP

Subjects

Animals, Blotting, Southern, Chromosomes genetics, Karyotyping, Metaphase, Chromosome Mapping, Equidae genetics, Horses genetics, In Situ Hybridization, Fluorescence, Insulin-Like Growth Factor II genetics

Abstract

Three genomic subclones derived from a phage clone containing the equine IGF2 gene were used to FISH map the gene on horse (ECA) and donkey (EAS) metaphase chromosomes. The gene mapped on ECA 12q13 band and is the first locus mapped to this horse chromosome. In donkey the gene mapped very terminal on the long arm of one small submetacentric chromosome that shows almost identical DAPI-banding pattern with ECA12. This is the first locus mapped in donkey genome. Cross species chromosome painting of equine metaphase chromosomes with human Chromosome (Chr) 11-specific probe showed homoeology of this human chromosome with ECA12 and ECA7. The novel ECA12 comparative painting results are thus in accordance with the localization of the equine IGF2 gene. Comparison of the hitherto known physical locations of IGF2 in different species, viz. human, cattle, sheep, horse, and donkey, shows that this gene tends to maintain a terminal location on the chromosome arm.

Published

1997

230. Zoo-FISH delineates conserved chromosomal segments in horse and man.

Author

Raudsepp T, Frönicke L, Scherthan H, Gustavsson I, and Chowdhary BP

Subjects

Animals, Chromosomes ultrastructure, Chromosomes, Human ultrastructure, Humans, Male, Phylogeny, Species Specificity, Chromosome Mapping veterinary, Evolution, Molecular, Hominidae genetics, Horses genetics, In Situ Hybridization, Fluorescence

Abstract

Human chromosome specific libraries (CSLs) were individually applied to equine metaphase chromosomes using the fluorescence in situ hybridization (FISH) technique. All CSLs, except Y, showed painting signals on one or several horse chromosomes. In total 43 conserved chromosomal segments were painted. Homoeology could not, however, be detected for some segments of the equine genome. This is most likely related to the very weak signals displayed by some libraries, rather than to the absence of similarity with the human genome. In spite of divergence from the human genome, dated 70-80 million years ago, a fairly high degree of synteny conservation was observed. In seven cases, whole chromosome synteny was detected between the two species. The comparative painting results agreed completely with the limited gene mapping data available in horses, and also enabled us provisionally to assign one linkage group (U2) and one syntenic group (NP, MPI, IDH2) to specific equine chromosomes. Chromosomal assignments of three other syntenic groups are also proposed. The findings of this study will be of significant use in the expansion of the hitherto poorly developed equine gene map.

Published

1996