Development of a comprehensive comparative radiation hybrid map of bovine chromosome 7 (BTA7) versus human chromosomes 1 (HSA1), 5 (HSA5) and 19 (HSA19)

In this study, we present a comprehensive 3,000-rad radiation hybrid (RH) map of bovine chromosome 7 (BTA7) with 108 markers including 54 genes or ESTs. For 52 of them, a human ortholog sequence was found either on HSA1 (one gene), HSA5 (31 genes) or HSA19 (19 genes and one non-annotated sequence) confirming previously described syntenies. Moreover, in order to refine boundaries of blocks of conserved synteny, nine new genes were mapped to the bovine genome on the basis of their localization on the human genome: six on BTA7 and originating from HSA1 (TRIM17), HSA5 (MAN2A1, LMNB1, SIAT8D and FLJ1159) and HSA19 (VAV1), and the three others (AP3B1, APC and CCNG1) on BTA10. The available draft of the human genome sequence allowed us to present a detailed picture of the distribution of conserved synteny segments between man and cattle. Finally, the INRA bovine BAC library was screened for most of the BTA7 markers considered in this study to provide anchors for the bovine physical map.     

A comprehensive radiation hybrid map of bovine Chromosome 26 (BTA26): comparative chromosomal organization between HSA10q and BTA26 and BTA28

In this study, we present a comprehensive 3000-rad radiation hybrid (RH) map of bovine Chromosome (Chr) 26 (BTA26) with 80 markers including 50 genes or ESTs: 44 have an ortholog mapping to human Chr 10 (HSA10) and 29 to mouse Chr (MMU) 7, 10, and 19. Moreover, 12 other HSA10 genes were integrated in a newly developed RH map of BTA28 (seven represent new assignments). The available draft of the mouse genome allowed us to present a detailed picture of the distribution of conserved synteny segments among the three species (human, cattle, and mouse) and to propose a simple model of the comparative chromosomal organization between the long arm of HSA10 and BTA26 and 28. Finally, the INRA bovine BAC library was screened for most of the BTA26 markers considered in this study to provide anchors for the bovine physical map.     

Comparative FISH mapping of mucin 1, transmembrane (MUC1) among cattle, river buffalo, sheep and goat chromosomes: comparison between bovine chromosome 3 and human chromosome 1

Four bovine BAC clones (0494F01, 0069D07, 0060B06, and 0306A12) containing MUC1, as confirmed by mapping MUC1 on a RH3000 radiation hybrid panel, were hybridised on R-banded chromosomes of cattle (BTA), river buffalo (BBU), sheep (OAR) and goat (CHI). MUC1 was FISH-mapped on BTA3q13, BBU6q13, OAR1p13 and CHI3q13 and both chromosomes and chromosome bands were homoeologous confirming the high degree of chromosome homoeologies among bovids and adding more information on the pericentromeric regions of these species' chromosomes. Indeed, MUC1 was more precisely assigned to BTA3 and assigned for the first time to BBU6, OAR1p and CHI3. Moreover, detailed and improved cytogenetic maps of BTA3, CHI3, OAR1p and BBU6 are shown and compared with HSA1.     

Synteny mapping of five human chromosome 7 genes on bovine chromosomes 4 and 21.

Five genes on human chromosome 7 (HSA 7) were assigned to bovine chromosome 21 (BTA 21) and 4 (BTA 4) using a bovine-rodent somatic hybrid cell panel. These five genes were alpha-I subunit of adenylate cyclase-inhibiting G-protein (GNAI1), alpha/beta preprotachykinin (TAC1), reelin (RELN), c-AMP dependant protein kinase type II beta regulatory chain (PRKAR2B) and apolipoprotein A1 regulatory protein 1 (TFCOUP2). Four genes mapped to BTA 4 (GNAI1, TAC1, RELN, PRKAR2B) while one gene mapped to BTA 21 (TFCOUP2). This study confirms the synteny conservation between HSA 7 and BTA 4, finely maps the breakpoints of conserved synteny on HSA 7 and defines a new synteny conservation between HSA 7 and BTA 21.     

Thirteen type I loci from HSA4q, HSA6p, HSA7q and HSA12q were comparatively FISH-mapped in four river buffalo and sheep chromosomes

Thirteen goat BAC clones containing coding sequences from HSA7, HSA12q, HSA4 and HSA6p were fluorescence in situ mapped to river buffalo (Bubalus bubalis, BBU) and sheep (Ovis aries, OAR) R-banded chromosomes. The following type I loci were mapped: BCP to BBU8q32 and OAR4q32, CLCN1 to BBU8q34 and OAR4q34, IGFBP3 to BBU8q24 and OAR4q27, KRT to BBU4q21 and OAR 3q21, IFNG to BBU4q23 and OAR3q23, IGF1 to BBU4q31 and OAR3q31, GNRHR to BBU7q32 and OAR6q32, MTP to BBU7q21 and OAR6q15, PDE6B to BBU7q36 and OAR6q36, BF to BBU2p22 and OAR20q22, EDN1 to BBU2p24 and OAR20q24, GSTA1 to BBU2p22 and OAR20q22, OLADRB (MHC) to BBU2p22 and OAR20q22. All mapped loci appeared to be located on homologous chromosomes and chromosome bands in both bovids. Comparison between gene orders in bovid (BBU and OAR) and human (HSA) chromosomes revealed complex rearrangements, especially between BBU7/OAR6 and HSA4, as well as between BBU2p/OAR20 and HSA6p.     

Brachygnathia,cardiomegaly and renal hypoplasia syndrome (BCRHS) in Merino sheep maps to a 1.1‐megabase region on ovine chromosome OAR2

A genome scan was conducted to map the autosomal recessive lethal disorder brachygnathia, cardiomegaly and renal hypoplasia syndrome (BCRHS) in Poll Merino sheep. The scan involved 10 affected and 27 unaffected animals from a single Poll Merino/Merino sheep flock, which were genotyped with the Illumina Ovine SNP50 BeadChip. Association and homozygosity mapping analyses located the disorder in a region comprising 20 consecutive SNPs spanning 1.1 Mb towards the distal end of chromosome OAR2. All affected animals and none of the unaffected animals were homozygous for the associated haplotype in this region. These results provide the basis for identifying the causative mutation(s) and should enable the development of a DNA test to identify carriers in the Poll Merino sheep population. Understanding the molecular control of BCRHS may provide insight into the fundamental genetic control and regulation of the affected organ systems.     

Extended cytogenetic maps of sheep chromosome 1 and their cattle and river buffalo homoeologues: comparison with the OAR1 RH map and human chromosomes 2, 3, 21 and 1q

Cytogenetic maps are useful tools for several applications, such as the physical anchoring of linkage and RH maps or genome sequence contigs to specific chromosome regions or the analysis of chromosome rearrangements. Recently, a detailed RH map was reported in OAR1. In the present study, we selected 38 markers equally distributed in this RH map for identification of ovine genomic DNA clones within the ovine BAC library CHORI-243 using the virtual sheep genome browser and performed FISH mapping for both comparison of OAR1 and homoeologous chromosomes BBU1q-BBU6 and BTA1-BTA3 and considerably extending the cytogenetic maps of the involved species-specific chromosomes. Comparison of the resulting maps with human-identified homology with HSA2q, HSA3, HSA21 and HSA1q reveals complex chromosome rearrangements differentiating human and bovid chromosomes. In addition, we identified 2 new small human segments from HSA2q and HSA3q conserved in the telomeric regions of OAR1p and homoeologous chromosome regions of BTA3 and BBU6, and OAR1q, respectively. Evaluation of the present OAR1 cytogenetic map and the OAR1 RH map supports previous RH assignments with 2 main exceptions. The 2 loci BMS4011 and CL638002 occupy inverted positions in these 2 maps.     

Comparative mapping of Homo sapiens chromosome 4 (HSA4) and Sus scrofa chromosome 8 (SSC8) using orthologous genes representing different cytogenetic bands as landmarks.

The recently published draft sequence of the human genome will provide a basic reference for the comparative mapping of genomes among mammals. In this study, we selected 214 genes with complete coding sequences on Homo sapiens chromosome 4 (HSA4) to search for orthologs and expressed sequence tag (EST) sequences in eight other mammalian species (cattle, pig, sheep, goat, horse, dog, cat, and rabbit). In particular, 46 of these genes were used as landmarks for comparative mapping of HSA4 and Sus scrofa chromosome 8 (SSC8); most of HSA4 is homologous to SSC8, which is of particular interest because of its association with genes affecting the reproductive performance of pigs. As a reference framework, the 46 genes were selected to represent different cytogenetic bands on HSA4. Polymerase chain reaction (PCR) products amplified from pig DNA were directly sequenced and their orthologous status was confirmed by a BLAST search. These 46 genes, plus 11 microsatellite markers for SSC8, were typed against DNA from a pig-mouse radiation hybrid (RH) panel with 110 lines. RHMAP analysis assigned these 57 markers to 3 linkage groups in the porcine genome, 52 to SSC8, 4 to SSC15, and 1 to SSC17. By comparing the order and orientation of orthologous landmark genes on the porcine RH maps with those on the human sequence map, HSA4 was recognized as being split into nine conserved segments with respect to the porcine genome, seven with SSC8, one with SSC15, and one with SSC17. With 41 orthologous gene loci mapped, this report provides the largest functional gene map of SSC8, with 30 of these loci representing new single-gene assignments to SSC8.     

High-resolution comparative mapping between human chromosomes 4 and 8 and bovine chromosome 27 provides genes and segments serving as positional candidates for udder health in cattle

To get more information about the order of genes located in Bos taurus (BTA) chromosome 27 segments, supposed to harbor loci influencing clinical mastitis and somatic cell count, and to identify genes that serve as positional candidates for the mentioned traits, we constructed a high-resolution, comparative, and comprehensive gene map for BTA27. The map includes 57 loci in a 5000-rad cattle-hamster whole genome radiation hybrid panel supported by 50 syntenic assignments in a cattle-murine somatic hybrid cell panel. Thirty-eight new loci (36 genes, 2 microsatellites) together with repeated mappings of 5 genes and 7 microsatellites and integration of existing data from 7 microsatellites were used to generate a comprehensive RH5000 map. The RH map, constructed at lod score criterion 8 using the software RHMAP v.3.0, consisted of three linkage groups 23, 22, and 590 cR5000 in length. Gene assignments on BTA27 and the localization of 8 more genes on BTA8 and BTA14 previously predicted on BTA8/BTA27 and BTA14/BTA27 narrowed down significantly the chromosome break points between the three cattle chromosomes and segments on Homo sapiens chromosomes HSA4 and HSA8. Defined evolutionary break points increase the accuracy of comparative in silico mapping of further human genes in conserved chromosome segments of BTA27.     

Isolation, mapping and identification of SNPs for four genes (ACP6, CGN, ANXA9, SLC27A3) from a bovine QTL region on BTA3

On the basis of fine mapping of a quantitative trait loci region of BTA3 for milk fat content, an examination of the comparative map between cattle and human indicates that the annexin 9 protein gene (ANXA9) and the fatty acid transport protein type 3 gene (SLC27A3) are two strong candidate genes. The objective of the present study is to isolate, map and characterize these genes and identify polymorphisms that could be further utilized in linkage or association studies. Furthermore, two new genes which are in the same region, cingulin protein gene (CGN) and lysophosphatidic acid phosphatase protein gene (ACP6) were studied. DNA fragments (869, 1778, 1933 and 2618 bp) corresponding to partial sequences of ACP6,CGN,ANXA9 and SLC27A3 genes were isolated. Direct sequencing of PCR products amplified from different cattle breeds revealed 1, 4, 4 and 2 SNPs for ACP6, CGN,ANXA9 and SLC27A3, respectively. For ANXA9 one SNP was located in exon 5 (A-->G 951) resulting in an amino acid change from histidine to arginine. Finally, ACP6,CGN,ANXA9 and SLC27A3 genes were located on chromosome 3 between ILSTS096 and BMS819 markers, in a region in which quantitative trait loci (QTL) for several milk traits have been described.     

Mapping of equine potassium chloride co-transporter (SLC12A4) and amino acid transporter (SLC7A10) and preliminary studies on associations between SNPs from SLC12A4, SLC7A10 and SLC7A9 and osmotic fragility of erythrocytes

Consensus DNA sequences from human, mouse and/or rat were used to design oligonucleotide primers for equine homologues of exons 16, 17 and 20-23 of potassium chloride co-transporter (SLC12A4) and exons 10, 11 and 3, 4, respectively, for two amino acid transporters (SLC7A10 and SLC7A9). DNA sequences of the PCR products showed high sequence identity to these regions. Equine BAC clones were obtained for SLC12A4 and SLC7A10 and mapped to equine chromosomes ECA3p13 and ECA10p15, respectively, by fluorescence in situ hybridization (FISH). Several single nucleotide polymorphisms (SNP) were found. Substitutions of A/G were found within exon 17 of SLC12A4, within intron 11 of SLC7A10 and within intron 3 of SLC7A9. The SNP associated with SLC7A10 and SLC7A9 were sufficiently polymorphic to investigate associations with erythrocyte fragility among a group of 20 thoroughbred horses. A non-parametric rank-sum test showed a weak association between erythrocyte fragility and the SNP associated with SLC7A10 (P < 0.05).     

Standard G-, Q-, and R-banded ideograms of the domestic sheep (Ovis aries): homology with cattle (Bos taurus). Report of the committee for the standardization of the sheep karyotype

Revised G-, Q- and R-banded karyotypes and ideograms for sheep chromosomes at the 420-band level of resolution are presented. The positions of landmark bands on the sheep chromosomes are defined by their distance relative to the centromere to facilitate comparison with equivalent cattle chromosomes. Chromosome-specific (reference) molecular markers that have been mapped to sheep chromosomes and their equivalent cattle chromosomes are proposed. Reference markers will facilitate genome comparisons between sheep and cattle and minimise confusion due to chromosome nomenclature. Numbering of the Robertsonian translocation chromosomes remains as previously reported.