Ronald M. Brunner

Comparative analysis of Y chromosome structure in Bos taurus and B. indicus by FISH using region-specific, microdissected, and locus-specific DNA probes

Results of fluorescence in situ hybridization (FISH) of Bos taurus and B. indicus Y chromosomes using the bovine locus-specific Y probes BC1.2 and lambda ES6.0 and region-specific probes of B. indicus and B. taurus Y chromosomes, which were generated by microdissection and DOP-PCR, indicate that the Y chromosomes of B. indicus (BIN Y) and B. taurus (BTA Y) differ by a pericentric inversion. Parts of the short and long arms of the Y chromosome in B. taurus and the distal half of the Y chromosome in B. indicus were microdissected, amplified by DOP-PCR, biotinylated, and rehybridized in situ to the corresponding metaphase chromosomes to test the chromosome fragment specificity of the DNA probes. The region-specific painting probes were used for hybridization to metaphase chromosomes of the other species. The DNA painting probes BTA Yp12 and BTA Yq12.1-ter derived from BTA Y hybridized to the distal and proximal halves of BIN Y, respectively. Complex hybridization signals on BTA Yq12.1-->qter were generated with the DNA probe BIN Yqcen-centr (centromere-central) after FISH. The results demonstrate that BTA Yp is homologous to the distal half of BIN Y and that BTA Yq corresponds to the proximal part of BIN Yq. Hybridization of the Y chromosome-specific DNA probes lambda ES6.0 to BTA Yp12-->p11 and near to the telomere of BIN Y and BC1.2 to BTA Yq12-->q13 and to the telomere of BIN Y indicate an opposite orientation of the homologous chromosome fragments BTA Yp and of the distal half of BIN Yq.

A first generation whole genome RH map of the river buffalo with comparison to domestic cattle

BackgroundThe recently constructed river buffalo whole-genome radiation hybrid panel (BBURH5000) has already been used to generate preliminary radiation hybrid (RH) maps for several chromosomes, and buffalo-bovine comparative chromosome maps have been constructed. Here, we present the first-generation whole genome RH map (WG-RH) of the river buffalo generated from cattle-derived markers. The RH maps aligned to bovine genome sequence assembly Btau_4.0, providing valuable comparative mapping information for both species.ResultsA total of 3990 markers were typed on the BBURH5000 panel, of which 3072 were cattle derived SNPs. The remaining 918 were classified as cattle sequence tagged site (STS), including coding genes, ESTs, and microsatellites. Average retention frequency per chromosome was 27.3% calculated with 3093 scorable markers distributed in 43 linkage groups covering all autosomes (24) and the X chromosomes at a LOD ≥ 8. The estimated total length of the WG-RH map is 36,933 cR5000. Fewer than 15% of the markers (472) could not be placed within any linkage group at a LOD score ≥ 8. Linkage group order for each chromosome was determined by incorporation of markers previously assigned by FISH and by alignment with the bovine genome sequence assembly (Btau_4.0).ConclusionWe obtained radiation hybrid chromosome maps for the entire river buffalo genome based on cattle-derived markers. The alignments of our RH maps to the current bovine genome sequence assembly (Btau_4.0) indicate regions of possible rearrangements between the chromosomes of both species. The river buffalo represents an important agricultural species whose genetic improvement has lagged behind other species due to limited prior genomic characterization. We present the first-generation RH map which provides a more extensive resource for positional candidate cloning of genes associated with complex traits and also for large-scale physical mapping of the river buffalo genome.

A comparative radiation hybrid map of bovine chromosome 18 and homologous chromosomes in human and mice

A comprehensive radiation hybrid (RH) map and a high resolution comparative map of Bos taurus (BTA) chromosome 18 were constructed, composed of 103 markers and 76 markers, respectively, by using a cattle-hamster somatic hybrid cell panel and a 5,000 rad whole-genome radiation hybrid (WGRH) panel. These maps include 65 new assignments (56 genes, 3 expressed-sequence tags, 6 microsatellites) and integrate 38 markers from the first generation WGRH5,000 map of BTA18. Fifty-nine assignments of coding sequences were supported by somatic hybrid cell mapping to markers on BTA18. The total length of the comprehensive map was 1666 cR5,000. Break-point positions within the chromosome were refined and a new telomeric RH linkage group was established. Conserved synteny between cattle, human, and mouse was found for 76 genes of BTA18 and human chromosomes (HSA) 16 and 19 and for 34 cattle genes and mouse chromosomes (MMU) 7 and 8. The new RH map is potentially useful for the identification of candidate genes for economically important traits, contributes to the expansion of the existing BTA18 gene map, and provides new information about the chromosome evolution in cattle, humans, and mice.

Genomic organization of the bovine aromatase encoding gene and a homologous pseudogene as revealed by DNA fiber FISH

In cattle, the CYP19 locus comprises the aromatase cytochrome P450-encoding gene (CYP19) and a homologous pseudogene (CYP19P1). It has been assigned to chromosome region 10q26. Cloning of genomic DNA revealed that the CYP19 gene covers more than 56 kb. Its precise extent is still unknown because the DNA spanning the untranslated first exon 1.1 and the coding region (exons 2 to 10) have not been isolated. Furthermore, the chromosome arrangement of closely linked CYP19 and CYP19P1 was also not clear. To establish a high resolution physical map of the entire CYP19 locus, fluorescence in situ hybridization to extended bovine genomic DNA fibers (fiber FISH) was performed. The results demonstrate (1) that the clone containing exon 1.1 is located about 19 kb upstream from the CYP19 coding region. (2) Within the chromosome region 10q26 CYP19 and CYP19P1 are arranged “tail-to-head”, being separated by a distance of about 24 kb between the labeled clones. (3) The physical size of the bovine CYP19 locus amounts to a minimum of 130 kb.

Bovine NALP5, NALP8, and NALP9 Genes: Assignment to a QTL Region and the Expression in Adult Tissues, Oocytes, and Preimplantation Embryos

Abstract A 3204-bp full-length cDNA of bovine NALP9 was cloned and its genomic organization was analyzed. The 2988-bp open reading frame covers 9 exons and encodes a deduced protein of 996 amino acids containing Pyrin, Nacht and leucine-rich repeat domains like the human NALP gene family members. Mapping with the WGRH5000 panel and fluorescence in situ hybridization assigned NALP9 in close vicinity to BM2078 (LOD score 25.71; distance 0.0 cR5000) on bovine chromosome 18, BTA18q25-q26, within a previously identified QTL region for reproductive traits flanked by the bovine marker BM2078 and TGLA227. BAC contig analysis revealed that NALP9, NALP8, and NALP5 map in this QTL region. Temporospatial expression of these members of the NALP gene family was monitored. Among the adult tissues examined, transcripts of NALP8 and NALP9 were detected exclusively in testis and ovary, whereas transcripts of the NALP5 gene are limited to the ovary. The transcripts of NALP9, NALP8, and NALP5 were detected in oocytes before and after in vitro maturation and with a gradual decline from 2-cell to 8-cell stage, suggesting no reactivation at the time of bovine maternal to embryonic transition. Assignment to a QTL region for reproductive traits and preferential expression of NALP9, NALP8, and NALP5 in oocyte, germinal lineage, and gonad cells may suggest their functional relevance to reproduction and possible contribution to phenotypic variation.

Application of disease-associated differentially expressed genes - Mining for functional candidate genes for mastitis resistance in cattle

In this study the mRNA differential display method was applied to identify mastitis-associated expressed DNA sequences based on different expression patterns in mammary gland samples of non-infected and infected udder quarters of a cow. In total, 704 different cDNA bands were displayed in both udder samples. Five hundred-and-thirty two bands, (75.6%) were differentially displayed. Ninety prominent cDNA bands were isolated, re-amplified, cloned and sequenced resulting in 87 different sequences. Amongst the 19 expressed sequence tags showing a similarity with previously described genes, the majority of these sequences exhibited homology to protein kinase encoding genes (26.3%), to genes involved in the regulation of gene expression (26.3%), to growth and differentiation factor encoding genes (21.0%) and to immune response or inflammation marker encoding genes (21.0%). These sequences were shown to have mastitis-associated expression in the udder samples of animals with and without clinical mastitis by quantitative RT-PCR. They were mapped physically using a bovine-hamster somatic cell hybrid panel and a 5000 rad bovine whole genome radiation hybrid panel. According to their localization in QTL regions based on an established integrated marker/gene-map and their disease-associated expression, four genes (AHCY, PRKDC, HNRPU, OSTF1) were suggested as potentially involved in mastitis defense.

Isolation and characterization of hepatic and intestinal expressed sequence tags potentially involved in trait differentiation between cows of different metabolic type

Abstract. mRNA differential display was applied to identify hepatic and intestinal expressed sequence tags (ESTs) in lactating cows of different metabolic types (milk type, meat/milk type, meat type) that are potentially associated with energy turnover and involved in the regulation of these processes. Altogether, 277 ESTs (liver: 161, intestine: 116) were identified. For 150 transcripts (liver: 99, intestine: 51), the sequences showed similarity to previously described genes and ESTs. Many of these homologous sequences are reported to be involved in hepatic metabolism. Ninety-four ESTs (liver: 43, intestine: 51) did not match with any database entries. Semi-quantitative RT-PCR revealed quantitative differences in transcript represented by randomly chosen ESTs in liver samples of animals of the Holstein and Charolais breeds. One hundred twenty-two ESTs were mapped physically by using a bovine-hamster somatic cell hybrid panel (SCP) and a 5000-rad bovine whole genome radiation hybrid panel (WGRH). These ESTs were assigned to the bovine syntenic groups and positioned in the recently established RH-based ordered comparative map of the cattle and human genomes. The mapped, differentially expressed sequence tags are a useful prerequisite for cloning of genetic variation underlying economic traits.

Cloning of the bovine prion-like Shadoo (SPRN) gene by comparative analysis of the predicted genomic locus

SPRN is a new prion-like gene coding for Sho, a protein with significant similarity to PrP. SPRN was initially described in zebrafish; however, the strong evolutionary conservation led to the hypothesis that SPRN might be the ancestral prion-like gene. We mapped SPRN in Bos taurus by comparative analysis of the locus and of the predicted flanking genes. BACs, spanning the whole SPRN genomic locus, were assigned to BTA26q23 by radiation hybrid mapping and fluorescent in situ hybridization (FISH). Sequencing of five genes flanking SPRN, namely, ECHS1, PAOX, MTG1, SPRN, and CYP2E1, high-resolution FISH on mechanically stretched chromosomes, and combed BAC DNA allowed us to establish their order and reciprocal orientation. The results confirmed that BTA26q23 corresponds to HSA10q24.3–26.3, which is the site where the human SPRN is located. The gene order in Bos taurus is the same as in man, cen-ECHS1-PAOX-MTG1-SPRN-CYP2E1-tel, but PAOX has a different orientation in the two species. SPRN has the typical two-exon PRNP arrangement, with the CDS fully contained within exon 2; furthermore, it codes for a 143-amino-acid protein with 74.8% identity and 84.7% similarity with the human PRNP. RT-PCR and Northern blot analysis showed that SPRN is expressed at high levels in brain and less in testis and lung.

Generation of chromosome fragment specific bovine DNA sequences by microdissection and DOP-PCR.

A rapid procedure for the defined isolation and characterization of single bovine chromosome fragment specific probes is described. This has been developed as a technical prerequisite for the directed generation of bovine DNA sequences. The specific regions lql3–24, 5q21–24, 6q31–32, 7q21–22, 12q24-ter, and 20ql2-ter of bovine GTG-banded metaphase chromosomes were microdissected and amplified by PCR with a degenerate oligonucleotide primer and subsequently cloned into pBluescript II SK. The DNA probes generated were characterized by gel electrophoresis, dot blot analysis and rehybridization in situ to GTG-banded metaphase spreads. The position and size of the hybridization sites on the chromosomes correspond exactly to the dissected chromosome areas and indicate the complexity and specificity of the microdissected and amplified chromosome material.

Tissue-specific mRNA expression patterns reveal a coordinated metabolic response associated with genetic selection for milk production in cows

The molecular mechanisms regulating the physiological adaptation of tissues important for nutrient partitioning and metabolism in lactating cows are still not completely understood. The aim of our study was to identify tissue-specific regulatory mechanisms necessary to accommodate metabolic changes associated with different genetic potential for milk performance. For this purpose, we analyzed mRNA expression of genes involved in energy metabolism of segregating F(2) beef type cows with a combined genetic dairy and beef background (Charolais × German Holstein cross, CH×GH) in contrast to purebred German Holstein (GH) dairy cows. Three groups of cows differing in milk performance were examined using quantitative real-time PCR in liver, mammary gland, and skeletal muscle. Our results describe substantial tissue-specific differences in mRNA transcription profiles between cow groups in relation to their genetic potential for milk performance and highlight genes exhibiting specific, partially yet-unknown functions in dairy and beef type cows, e.g., upregulation of PCK2 transcripts in the mammary gland and FBP2 transcripts in skeletal muscle of dairy cows. Noticeably, PCCA and PPARGC1A mRNA abundance varied significantly across experimental groups in all three tissues, pointing to potential key gene functions in the metabolic adaptation relative to divergent milk production performance. Correlations of mRNA expression levels to milk performance traits indicate that gene transcriptional processes may play a regulatory role in liver, mammary gland, and skeletal muscle to enable cows with different genetic potential for milk performance to cope with metabolic lactation-associated challenges.