Mastitis increases mammary mRNA abundance of beta-defensin 5, toll-like-receptor 2 (TLR2), and TLR4 but not TLR9 in cattle.

Coordination of the primary defense mechanisms against pathogens relies on the appropriate expression of pathogen recognition receptors (PRRs) triggering the early release of effector molecules of the innate immune system. To analyze the impact of this system on the counteraction of infections of the mammary gland (mastitis), we characterized the bovine gene encoding the key PRR Toll-like receptor 9 (TLR9) and mapped its precise position on chromosome BTA22. The sequence information was used to establish real-time PCR quantification assays to measure the mRNA abundances of TLR9, TLR2, and TLR4 together with those of beta-defensin 5 (BNBD5), an early bactericidal effector molecule of the innate system, in healthy and infected mammary glands. Mastitis strongly increased (4- to 13-fold) the mRNA abundances of all of these genes except TLR9. Slight subclinical infections already caused a substantial increase in the copy numbers, though they did so the least for TLR9. Induction was not systemic, since mRNA abundance was low in uninfected control quarters of the udder but high in the severely infected quarters of the same animal. The number of TLR2 copies correlated well with those of TLR4, indicating coordinated regulation of these two PRRs during infection of the udder. Their coordinated regulation explains our unexpected observation that pure Staphylococcus aureus infections caused a strong increase also in TLR4 mRNA abundance. In situ hybridizations revealed that BNBD5 is expressed predominantly in the mammary epithelial cells (MEC) of the infected gland. Our data therefore suggest a significant contribution of the innate immune system to counteract mastitis and attribute a prominent effector function to the MEC.

Mapping of ESTs derived from pre-implantation stage cattle embryos to allocate 16 new additions to the ordered comparative map of cattle and human.

Twenty expressed sequence tags (ESTs) derived from cDNA libraries of different developmental stages of embryos were mapped using a whole genome bovine hamster radiation hybrid panel. These include 14 markers representing genes, most of which have not so far been mapped in cattle, with another three being novel in both cattle and human. The markers were placed on specific chromosomes with high LOD scores and except two all localizations fit the current human and cattle comparative map. The assignment of these genes further enriches the cattle genome map and also contributes to the international effort of generating comparative maps.

Clarifications on breakpoints in HSAX and BTAX by comparative mapping of F9, HPRT, and XIST in cattle.

The coagulation factor IX gene (F9), the hypoxanthine phosphoribosyl transferase 1 gene (HPRT1), and the X-inactive specific transcript gene (XIST) were physically assigned in cattle to analyze chromosomal breakpoints on BTAX recently identified by radiation hybrid (RH) mapping experiments. Whereas the FISH assignment of XIST indicates a similar location on the q-arm of the human and cattle X chromosomes, the locus of HPRT1 supported the assumption of a chromosome rearrangement between the distal half of the q-arm of HSAX and the p-arm of BTAX identified by RH mapping. F9 previously located on the q-arm of BTAX was assigned to the p-arm of BTAX using RH mapping and FISH. The suggested new position of F9 close to HPRT1 supports the homology between HSAXq and BTAXp. The F9 locus corresponds with the gene order found in the homologous human chromosome segment. XIST was assigned on BTAXq23, HPRT1 and F9 were mapped to BTAXp22, and the verification of the location of F9 in a 5000 rad cattle-hamster whole genome radiation hybrid panel linked the gene to markers URB10 and HPRT1.

The bovine fibroblast growth factor receptor 3 (FGFR3) gene is not the locus responsible for bovine chondrodysplastic dwarfism in Japanese brown cattle.

Fibroblast growth factor receptor 3 (FGFR3) is one of the four distinct membrane-spanning tyrosine kinase receptors for fibroblast growth factors. The FGFR3 is a negative regulator of endochondral ossification and mutations in the FGFR3 gene have been found in patients of human hereditary diseases with chondrodysplastic phenotypes. Recently, we mapped the locus responsible for hereditary chondrodysplastic dwarfism in Japanese brown cattle to the distal region of bovine chromosome 6 close to the FGFR3 gene, suggesting that FGFR3 was a positional candidate gene for this disorder. In the present study, we isolated complementary DNA (cDNA) clones containing the entire coding region of the bovine FGFR3 gene. Comparison of the nucleotide sequence between affected and normal animals revealed no disease-specific differences in the deduced amino acid sequences. We further refined the localization of FGFR3 by radiation hybrid mapping, which is distinct from that of the disease locus. Therefore we conclude that bovine chondrodysplastic dwarfism in Japanese brown cattle is not caused by mutation in the FGFR3 gene.

Mapping of 12 bovine ribosomal protein genes using a bovine radiation hybrid panel.

Twelve bovine ribosomal protein genes, for which sequence data had been acquired from complementary deoxyribonucleic acid (cDNA) clones isolated from a cattle skin cDNA library, were mapped. As ribosomal protein genes are a group of highly conserved house keeping genes, specific primers were designed to span the intron-exon splice sites and to amplify intronic sequences, in order to obtain bovine-specific polymerase chain reaction (PCR) products. Two of 12 ribosomal protein genes were genotyped in this way and the remaining 10 were mapped using additional primers designed from within the intron. Eleven previously unmapped ribosomal protein genes were localized and one previously reported ribosomal protein gene localization was confirmed. The 12 ribosomal protein genes mapped in this study are spread over 10 chromosomes, including the X chromosome. The locations show conservation of comparative map position in cattle and human.

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

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.

Comparative mapping of five coding DNA sequences on cattle chromosomes 7 and 25.

Comparative mapping of four genes and one unknown coding DNA sequence in breakpoint positions of bovine chromosomes (BTA) 7 and 25 are presented. Performing a genome data base search five bovine expressed sequence tags from the MARC library matched with human genes coding for the general transcription factor IIIC polypeptide 1 (GTF3C1), the hypothetical protein KIAA0556, the interleukin 4 receptor (IL4R), the regulatory factor X-associated ankyrin-containing protein (RFXANK), and with an unknown human coding sequence partially homologous to the genomic cosmid clone R30923. Loci for these sequences were COMPASS predicted on BTA7 or BTA18 and to BTA18 or BTA25. Mapping was performed in a cattle-hamster somatic hybrid cell panel and a cattle-hamster 5000 rad whole genome radiation hybrid panel. GTF3C1, KIAA0556 and IL4R were assigned to the centromere region of BTA25 and RFXANK and R30923 close to the centromere of BTA7. The assignments contribute to the identification of evolutionary chromosome break points between human chromosomes 16 and 19 and BTA7, BTA18, and BTA25.

RH maps of bovine chromosomes 15 and 29: conservation of human chromosomes 11 and 5.

Comparative mapping data on evolutionary conserved coding sequences and synteny maps between human and cattle are insufficient to define the extent and distribution of conserved segments between these two species, because the order of loci is often rearranged. A 5000-rad cattle whole-genome radiation hybrid (WG-RH) panel was constructed to provide high-resolution comparative maps and also to integrate linkage maps of microsatellites with evolutionary conserved genes and transcripts in a single ordered map. We used the WG-RH panel to construct radiation hybrid maps of bovine Chromosomes (Chrs) 15 and 29 (BTA15 and BTA29), integrating microsatellites from published linkage maps with selected genes. The comprehensive map of BTA15 consists of 24 markers, 13 of which were placed in the framework map. Eleven molecular markers compose the comprehensive map of BTA29, seven of which were placed in the framework map. We identified the homologous regions between bovine Chr 15 (BTA15) and human Chrs 5 and 11 (HSA5 and HSA11), as well as between BTA29 and HSA11. The present study demonstrates that WG-RH mapping is an efficient method for integrating multiple genetic maps into one map and for incorporating monomorphic Type I loci into ordered maps for comparison between species.

Bovine genome mapping: evolutionary inference and the power of comparative genomics.

All bovine chromosomes are now represented by a syntenic group, a linkage map and at least one in situ hybridization. Almost 1,000 loci are mapped, about 300 of which are coding sequences useful for comparative mapping and evolutionary inference. Economically important loci are beginning to appear on bovine linkage maps and enhanced comparative maps are likely to be necessary to identify many of these genes by a comparative positional candidate gene approach.

Identification of opaque-2 genotypes in segregating populations of Quality Protein Maize by analysis of restriction fragment length polymorphisms.

Quality Protein Maize (QPM) is a name given to genetically modified opaque-2 maize with hard endosperm. The opaque-2 mutation conditions a reduction in the amount of zein seed storage protein; zeins are deficient in the essential amino acids lysine and tryptophan, and mutant seed have a higher nutritional value. To utilize the potential of opaque-2 maize, elite inbreds can be converted to o2/o2 forms and subsequently to hard endosperm opaque-2. Since opaque-2 is recessive and endosperm specific, conventional backcross procedures to convert elite inbreds to opaque-2 forms are inefficient. To alleviate this problem, a marker-assisted selection procedure was developed for the Texas A&M University Quality Protein Maize breeding program. Hybridization of an O2 cDNA probe to blots of DNA from plants carrying O2 and o2 alleles showed that restriction fragment length polymorphisms (RFLPs) exist between the W64A o2 allele and O2 alleles of Mo17 and TX5855 inbred lines. To identify the opaque2 genotypes in segregating populations, an RFLP marker assay combining the O2 cDNA probe and HindIII-digestion of genomic DNA was developed. The effectiveness of the O2 RFLP marker assay was tested under field conditions using F2 and backcross populations of several hard endosperm opaque-2 lines. A comparison of the genotypes identified by RFLP analysis with the seed phenotypes of the next generation indicated that this procedure is accurate and can be used for identifying O2/O2, O2/o2, and o2/o2 genotypes of individual juvenile plants in breeding populations.