Isolation and mapping of polymorphic microsatellites in cattle

Summary
A partial plasmid library with bovine genomic inserts of about 500 basepairs was screened with a (dC-dA)_n-(dG-dT)_n oligonucleotide probe for the repeated nucleotide motif (CA)_n. Eleven positive clones (0.3% of all colonies screened) were discovered and were subsequently isolated and sequenced. Eight microsatellite loci were analysed, one with eight alleles, one with seven alleles, three with six alleles, one with three alleles and two with two alleles. Six of these microsatellites were mapped by PCR-analysis of a panel of somatic hybrid lines.     

Synteny mapping in the horse using horse-mouse heterohybridomas

In a study of 35 horse-mouse heterohybridoma cell lines, synteny in the horse was found between LDHB, PEPB and IGFl and between NP, MPI and IDH2. A synteny between ADA and PEPC was also indicated. The loci for horse immunoglobulin light chain (IgL) genes and for LDHA were independent.     

The complex history of distal human chromosome 1q

Human chromosome 1 has been claimed to be a conserved ancestral chromosome of eutherian mammals. However, two small regions from distal 1q (with orthology to mouse chromosome 11) appear to have a different history. These two regions are proposed to have been added to the ancestor of human chromosome 1 as a single block that was subsequently disrupted by a paracentric inversion. The translocation and inversion appear to have occurred at some time after the primate lineage diverged from a common ancestor with rodents. Reconstruction of the history of distal human chromosome 1q is complicated by the "reuse" of breakpoints in different mammalian lineages and by coincidental shared synteny between humans and cats.     

Physical mapping confirms that sheep chromosome 10 has extensive conserved synteny with cattle chromosome 12 and human chromosome 13

The following loci, on human chromosome 13, have been newly assigned to sheep chromosome 10 using chromosomally characterized sheep-hamster cell hybrids: gap junction protein, beta 2, 26 kDa (connexin 26) (GJB2); gap junction protein, alpha 3, 46 kDa (connexin 46) (GJA3), and esterase D/formylglutathione hydrolase (ESD). This assignment of ESD is consistent with comparative mapping evidence, but not with an earlier report of it on sheep chromosome 3p26-p24. Cell hybrid analysis confirmed the location of another human chromosome 13 locus, retinoblastoma 1 (including osteosar-coma) (RBI), and the anonymous ovine genomic sequence RP11 on sheep chromosome 10. Isotopic in situ hybridization was used to regionally localize RP11 on to sheep 10q15-q22. The location of microsatellites AGLA226, OarDB3, OarHH41, OarVH58, and TGLA441, previously assigned to sheep chromosome 10 by linkage analysis, was confirmed by polymerase chain reaction using the cell hybrid panel. These mapping data provide further evidence that sheep chromosome 10 is the equivalent of cattle chromosome 12, and that these chromosomes show extensive conserved synteny with human chromosome 13.     

Genetic mapping of bovine T-cell receptor complex loci

Thymic-derived lymphocytes (T cells) recognize and respond to antigens through the mediation of the T-cell receptor complex. Here we report polymorphism at each of the five loci that encode the different components of the T-cell receptor complex in cattle. These genes were mapped on the bovine genome by genetic linkage analysis in the International Bovine Reference Panel (IBRP). These mapping data provide additional type I markers for linking the bovine genetic map with the human and mouse maps and also permit investigation of the effect of T-cell receptor polymorphism on immune responsiveness and disease susceptibility.     

Radiation hybrid comparative mapping between human chromosome 17 and porcine chromosome 12 demonstrates conservation of gene order

A comparative study of human chromosome 17 (HSA17) and pig chromosome 12 (SSC12) was conducted using both somatic cell hybrid panel (SCHP) and radiation hybrid (RH) panel analysis. Sequences from an expressed sequence tag (EST) project in pig reproduction were examined and six genes and ESTs originally believed to map to HSA17 were selected for this study. The genes/ESTs were TATA box binding protein-associated factor (TAF2N/RBP56), alpha-2-plasmin inhibitor (SERPINF2/PLI), H3 histone family 3B (H3F3B), aminopeptidase puromycin sensitive (NPEPPS), an expressed sequence tag (ESTMI015) and P311 protein (P311). The SCHP analysis mapped five genes/ESTs (TAF2N, H3F3B, SERPINF2, NPEPPS and ESTMI015) to SSC12q11-q15 and SSC12p11-p15 with 100% concordance, and assigned P311 to SSC2 (1/2q24)-q29 with 100% concordance. Radiation hybrid analysis of all six genes confirmed the SCHP mapping results, with average retention frequency of 25%. Recent human sequence data demonstrated that P311 is actually located on HSA5q. As HSA5q and SSC2q show conserved syntenic regions predicted from bi-directional painting, our P311 mapping data is consistent with these results. An expanded comparative SSC12 RH map integrating the five new type I markers and 23 previously mapped loci was established using a LOD score threshold of 4.8. The gene order of the five genes/ESTs on the SSC12 framework RH map (H3F3B-ESTMI015-NPEPPS-TAF2N-SERPINF2) is identical to the HSA17 GB4 map but with inversion of the map as conventionally drawn.     

Genetic mapping of five human chromosome 4 orthologues to bovine chromosomes 6 and 17

Five loci that map to human chromosome 4 (HSA4) were selected to expand the bovine comparative linkage map. Loci included b-casein ( CSN2 ), basic fibroblast growth factor ( FGF2 ), immunoglobulin J chain ( IGJ ), interleukin 2 ( IL2 ) and microsomal triglyceride transfer protein ( MTTP ). Polymorphisms for each locus were identified by either polymerase chain reaction-restriction fragment length polymorphism (PCR–RFLP) or single-strand conformational polymorphism (SSCP) analysis. The bovine genes for CSN2 , IGJ and MTTP were mapped by linkage analysis to chromosome 6; FGF2 and IL2 mapped to chromosome 17. These data refine a position of chromosomal evolution to a small region between FGF2 and the previously mapped complement I factor ( IF ).     

Comparative mapping of bovine chromosome 13 by fluorescence in situ hybridization

We present chromosomal fluorescence in situ hybridization (FISH) results that both extend the HSA20/BTA13 comparative map as well as cytogenetically anchor two microsatellite markers. A bovine bacterial artificial chromosome (BAC) library was screened for conserved genes (type I loci) previously assigned to HSA10 or HSA20 and BTA13, and for microsatellites selected from two published BTA13 linkage maps. Clones from six out of nine comparative loci and both microsatellites were found represented in the BAC library. These BAC clones were used as probes in single colour FISH to determine the chromosome band position of each locus. As predicted by the human/bovine comparative map, all type I loci mapped to BTA13. Because single colour FISH analysis revealed that the loci were clustered within the distal half of BTA13, dual colour FISH was used to confirm the locus order. Established order was centromere- PRNP-(SODIL/AVP/OXT)-(BL42/GNAS1)-HCK-CSSM30 . The findings confirm the presence of a conserved HSA20 homologous synteny group on BTA13 distal of a HSA10 homologous segment.     

Synteny mapping in the bovine: genes from human chromosome 4.

Genes homologous to those located on human chromosome 4 (HSA4) were mapped in the bovine to determine regions of syntenic conservation among humans, mice, and cattle. Previous studies have shown that two homologs of genes on HSA4, PGM2 and PEPS, are located in bovine syntenic group U15 (chromosome 6). The homologous mouse genes, Pgm-1 and Pep-7, are on MMU5. Using a panel of bovine x hamster hybrid somatic cells, we have assigned homologs of 11 additional HSA4 loci to their respective bovine syntenic groups. D4S43, D4S10, QDPR, IGJ, ADH2, KIT, and IF were assigned to syntenic group U15. This syntenic arrangement is not conserved in the mouse, where D4s43, D4s10, Qdpr, and Igj are on MMU5 while Adh-2 is on MMU3. IL-2, FGB, FGG, and F11, which also reside on MMU3, were assigned to bovine syntenic group U23. These data suggest that breaks and/or fusions of ancestral chromosomes carrying these genes occurred at different places during the evolution of humans, cattle, and mice.     

Synteny mapping in the bovine: genes from human chromosome 5.

In an effort to generate a more complete bovine syntenic map of Type I comparative anchor loci, seven homologs to genes found on HSA5 were mapped using a panel of bovine x rodent hybrid somatic cells. Five HSA5 genes, CSF2, RPS14, PDGFRB, FGFA, and CSF1R, were assigned to bovine syntenic group U22 (chromosome 7), while two others, C9 and HGMCR, mapped to U10 and U5, respectively. Previous studies had assigned the HSA5 marker SPARC to bovine syntenic group U22. The mapping of genes spanning the length of HSA5 in cattle and also in mouse permits syntenic comparisons between prototypic genomes of three mammalian orders, providing insight into the evolutionary history of this region of the ancestral mammalian genome.     

A 12,000 rad whole genome radiation hybrid panel for high resolution mapping in cattle: characterization of the centromeric end of chromosome 1

We have constructed a 12,000 rad bovine whole-genome radiation hybrid panel (BovR12) to complement the 5000 rad panel (BovR5) currently available to the bovine genomics research community. Initial characterization with markers from chromosome 1 reveals a higher frequency of breakage between adjacent markers and subsequently a larger number of 'linkage' groups on this chromosome. For this set of markers, the retention frequency is also higher than in BovR5.     

Physical assignment of six type I anchor loci to bovine chromosome 19 by fluorescence in situ hybridization

A bovine bacterial artificial chromosome (BAC) library was screened for the presence of eight type I anchor loci previously used within hybrid somatic cells and an interspecies hybrid backcross to construct a genome map of bovine chromosome 19 (BTA19). Six out of eight loci were identified in the BAC library ( NF1, CRYB1, CHRNB1, TP53, GH1 and P4HB ). The BACs were then used in single-colour fluorescence in situ hybridization (FISH) to assign these genes to BTA19 band locations. Gene order was determined by single-colour FISH, and was confirmed by dual-colour FISH to mitotic and meiotic chromosomes. The order, centromere- NF1-CRYB1-CHRNB1-TP53-GH1-P4HB , was in agreement with the order determined by linkage analyses. In addition, the order of CHRNB1 and TP53 , previously unresolved by linkage analyses, was established. These data provide high-resolution cytogenetic anchorage of the BTA19 genome map from chromosome bands 14–22.     

Assessment of selection mapping near the myostatin gene (GDF-8) in cattle

Domestic species provide a unique opportunity to examine the effects of selection on the genome. The myostatin gene ( GDF-8 ) has been under strong selection in a number of cattle breeds because of its influence on muscle conformation and association with the 'double-muscling' phenotype. This study examined genetic diversity near this gene in a set of breeds including some nearly fixed for the allele associated with double-muscling (MH), some where the allele is segregating at intermediate frequency and some where the allele is absent. A set of microsatellites and SNPs were used to examine patterns of diversity at the centromeric end of bovine chromosome 2, the region where GDF-8 is located, using various statistical methods. The putative position of a selected gene was moved across the genomic region to determine, by regression, a best position of reduced heterozygosity. Additional analyses examined extended homozygous regions and linkage disequilibrium patterns. While the SNP data was not found to be very informative for selection mapping in this dataset, analyses of the microsatellite data provided evidence of selection on GDF-8 in several breeds. These results suggested that, of the breeds examined, the allele was most recently introduced into the South Devon. Limitations to the selection-mapping approach were highlighted from the analysis of the SNP data and the situation where the MH allele was at intermediate frequency.     

肉牛的数量性状基因座定位研究进展

遗传图谱的发展为寻找和定位影响重要数量性状变异的基因提供了便利。迄今为止,育种学家已经在肉牛的1、2、5、6、14、15、17、18、19、21、23、27、和29号常染色体上发现了QTL的踪迹。候选基因的研分显示肌肉生长抑制素基因等可能就是生长和屠宰重性状的QTL,基困组统计定位则揭示最有可能的QTL区域在2、5、6、15、19、27、29号染色体上。进一步的定位仍需遗传学家、分子生物学家及育种学家的共同努力。     

Physical mapping of CSF2RA, ANT3 and STS on the pseudoautosomal region of bovine chromosome X

The pseudoautosomal region (PAR) of bovine chromosome X (BTA X) has a particularly low representation of genes and markers, making comparative gene mapping in this region difficult. We describe the localization of three genes, colony-stimulating factor 2 receptor alpha (CSF2RA), ADP/ATP translocase 3 (ANT3) and steroid sulphatase (STS) on PAR of BTA X using a 5000 rad whole-genome radiation hybrid panel. The relationship of these genes to a number of previously mapped simple sequence repeat (microsatellite) markers is determined by physical and radiation hybrid mapping methods. The resulting radiation hybrid map resolves a discrepancy between the two major bovine linkage maps in the PAR of BTA X.     

Comparative mapping of bovine chromosome 27 with human chromosome 8 near a dairy form QTL in cattle

In the absence of a complete and annotated bovine genome sequence, detailed human-bovine comparative maps are one of the most effective tools for identification of positional candidate genes contributing to quantitative trait loci (QTL) in cattle. In the present study, eight genes from human chromosome 8 were selected for mapping in cattle to improve breakpoint resolution and confirm gene order on the comparative map near the 40 cM region of the BTA27 linkage map where a QTL affecting dairy form had previously been identified. The resulting map identified ADRB3 as a positional candidate gene for the QTL contributing to the dairy form trait based on its estimated position between 40 and 45 cM on the linkage map. It is also a functional candidate gene due to its role in fat metabolism, and polymorphisms in the ADRB3 gene associated with obesity and metabolic disease in humans, as well as, carcass fat in sheep. Further studies are underway to investigate the existence of polymorphisms in the bovine ADRB3 gene and their association with traits related to fat deposition in cattle.     

冠状动脉粥样硬化性心脏病8号染色体基因扫描

冠状动脉粥样硬化性心脏病(Coronary heart disease,CHD)的全基因组扫描研究在世界各大研究中心展开,关于CHD易感基因位点的报道多集中于1号、3号、9号、11号、16号染色体,对8号染色体的研究报道甚少。在汉族人群中未见关于CHD的8号染色体的基因扫描研究。文章旨在查找汉族人群中CHD易感基因位点,选取8号染色体上间隔10 cM遗传距离的13个微卫星遗传位点,采用DNA混合池的方法对CHD患者组156例和正常对照组1 000例DNA样本进行基因扫描,经卡方检验分析患者组和对照组每个位点的等位基因频率差异。发现在患者组与对照组中D8S264位点(8p23.3-p23.2)及D8S285位点(8q12.1)的等位基因频率差异有统计学意义(P<0.05)。汉族人群中CHD患者8号染色体上8p23.3-p23.2、8q12.1区域可能存在CHD易感基因,需要进行候选基因突变筛查。     

A radiation hybrid map of bovine chromosome 24 and comparative mapping with human chromosome 18

We present herein a bovine chromosome 24 (BTA24) radiation hybrid (RH) map using 40 markers scored on a panel of 90 RHs. Of these markers, 29 loci were ordered with odds of at least 1000:1 in a framework map. An average retention frequency of 17.4% was observed, with relatively higher frequencies near the centromere. The length of the comprehensive map was 640 centiray5000 (cR5000) with an average marker interval of approximately 17.3 cR5000. The observed locus order is generally consistent with currently published bovine linkage and physical maps. Nineteen markers were either Type I loci or closely associated with expressed sequences and thus could be used to compare the BTA24 RH map with human mapping information. All genes located on BTA24 were located on human chromosome 18, and previously reported regions of conserved synteny were extended. The comparative data revealed the presence of at least six conserved regions between these chromosomes.     

Isolation and molecular characterization of bovine Rhesus-like transcripts and chromosome mapping of the relevant locus

The bovine erythrocyte membrane carries Rhesus (Rh)-like proteins. To obtain a bovine nucleotide probe, a cDNA library of foetal liver was constructed and screened with the human RhCE probe. Three clones (245 bp, 1012 bp and 1400 bp) were isolated and sequenced. They share a high degree of similarity (up to 73%) with Rh-like cDNAs of primates characterized so far and all of them were shown to contain a polymorphic microsatellite in their 3' untranslated region. Their sequences support the occurrence of different splicing isoforms transcribed from the same RH-like gene. One of the clones (1400 bp), which has a 134-nucleotide deletion causing a frameshift, is structurally similar to the human Rh4 cDNA isoform. Synteny mapping and genetic linkage analysis located the bovine RH-like locus on chromosome BTA2, on which none of the 10 previously mapped blood group systems are found. In situ hybridization mapped the RH-like locus to BTA2q45. No linkage was detected between the microsatellite and the only unmapped blood group system (locus F). These results strongly suggest that the putative bovine Rh-like polypeptides do not correspond to any previously described bovine blood group. Comparative studies of human and bovine maps clearly show that the human RH locus, which is located on HSA1p34-p36, and its bovine counterpart belong to a linkage group highly conserved between both species.     

Mapping of bovine PRGS and PAIS genes in hybrid somatic cells: Syntenic conservation with human chromosome 21

Somatic cell genetics coupled with enzyme electrophoresis has facilitated the mapping of PRGS and PAIS genes in cattle. Individual cow-hamster hybrid cell lines established by fusion of mutant CHO cells, ade-C and ade-G, with cattle leukocytes required complementing bovine genes for PRGS and PAIS, respectively, when propogated on selective media. Homogenates of 12 PRGS⁺ hybrid clones and 12 PAIS⁺ hybrid clones retained the bovine electromorph of SOD1 while extensively segregating 14 biochemical markers of other cattle syntenic groups. Secondary cattle-hamster hybrid subclones which segregated bovine PRGS and PAIS in late passages on nonselective media concordantly segregated bovine SOD1. These data support a syntenic relationship among PRGS, PAIS, and SOD1 on cattle syntenic group U10. An interferon receptor locus, IFREC, is also syntenic with SOD1. This synteny represents an extensive conservation of bovine U10 and the Down syndrome region of human chromosome 21.This work was supported in part by USDA Grants 83-CRSR-2-2234 and 85-CRCR-1-1699 and the Texas Agricultural Experiment Station Project RI 6718 (J. E. Womack) and by NIH Grants HD 17449 and HD13423 (D. Patterson).