Annotation of novel transcripts putatively relevant for bovine fat metabolism.

Two bovine transcripts encoded by the interleukin-1 receptor-associated kinase 1 (IRAK1) gene and the locus LOC618944 predicted as similar to human chromosome 6 open reading frame 52 (C6orf52) gene had indicated divergent expression in bovine skeletal muscle containing different amount of intramuscular fat in a pilot screening experiment. However, for both loci any role in the regulation of energy or fat metabolism is not yet described. In this study, we validated and refined gene structure, screened for mRNA splice variants and analyzed the tissue-specific gene expression patterns of both loci as a prerequisite to elucidate their potential physiological function. Based on comparative sequence analysis, a new full-length gene model for the bovine IRAK1 gene was developed and confirmed experimentally. Expression of IRAK1 mRNA was found in a variety of tissues, and a splice variant was identified in skeletal muscle caused by an in-frame deleted segment of 210 bp affecting regions of intrinsic disorder in the respective protein. For the locus LOC618944, our data contributed to a revised gene model and its assignment to BTA23 (bovine chromosome 23) on the current bovine genome assembly supported by comparative similarity analysis between the bovine and human genomes and experimental data. Furthermore, we identified several splice variants in mammary gland, fat and skeletal muscle tissue and detected a highly similar processed pseudogene on BTA26. All transcript variants of LOC618944 detected in the analyzed tissues represent noncoding RNAs. For both loci, our results suggest yet undetected physiological functions in tissues relevant for fat or energy metabolism in cattle.

Analysis of structure and gene expression of bovine CCDC3 gene indicates a function in fat metabolism.

Our study reports the molecular analysis of the bovine gene encoding the coiled-coil domain-containing protein 3 (CCDC3). Based on comparative sequence analysis and in silico sequence merging of predicted gene models, a new full-length gene model for the bovine CCDC3 gene was predicted and confirmed experimentally. The CCDC3 gene was assigned to bovine chromosome 13. It consists of three exons comprising 2599bp encoding for a respective protein of 274 amino acids. The strong CCDC3 sequence homology on amino acid level between species suggests a conserved universal function of this protein. In mice, the CCDC3 gene had been found to be highly expressed in adipocytes and regulated by hormonal-nutritional alternations and in obesity. The tissue expression pattern of bovine CCDC3 mRNA indicates a ubiquitous physiological function of the gene. Significant differences in CCDC3 mRNA expression in skeletal muscle between individuals characterized by divergent intramuscular fat deposition support the potential function of the gene in fat or energy metabolism, which possibly could also be inferred for other mammalian species. This first report of structural analysis and molecular characterization of the CCDC3 gene in cattle will contribute to a better understanding of the yet unknown physiological role of the respective protein in mammals.

Dissection of genetic factors modulating fetal growth in cattle indicates a substantial role of the non-SMC condensin I complex, subunit G (NCAPG) gene.

The increasing evidence of fetal developmental effects on postnatal life, the still unknown fetal growth mechanisms impairing offspring generated by somatic nuclear transfer techniques, and the impact on stillbirth and dystocia in conventional reproduction have generated increasing attention toward mammalian fetal growth. We identified a highly significant quantitative trait locus (QTL) affecting fetal growth on bovine chromosome 6 in a specific resource population, which was set up by consistent use of embryo transfer and foster mothers and, thus, enabled dissection of fetal-specific genetic components of fetal growth. Merging our data with results from other cattle populations differing in historical and geographical origin and with comparative data from human whole-genome association mapping suggests that a nonsynonymous polymorphism in the non-SMC condensin I complex, subunit G (NCAPG) gene, NCAPG c.1326T>G, is the potential cause of the identified QTL resulting in divergent bovine fetal growth. NCAPG gene expression data in fetal placentomes with different NCAPG c.1326T>G genotypes, which are in line with recent results about differential NCAPG expression in placentomes from studies on assisted reproduction techniques, indicate that the NCAPG locus may give valuable information on the specific mechanisms regulating fetal growth in mammals.

Novel transcripts discovered by mining genomic DNA from defined regions of bovine chromosome 6.

BACKGROUND: Linkage analyses strongly suggest a number of QTL for production, health and conformation traits in the middle part of bovine chromosome 6 (BTA6). The identification of the molecular background underlying the genetic variation at the QTL and subsequent functional studies require a well-annotated gene sequence map of the critical QTL intervals. To complete the sequence map of the defined subchromosomal regions on BTA6 poorly covered with comparative gene information, we focused on targeted isolation of transcribed sequences from bovine bacterial artificial chromosome (BAC) clones mapped to the QTL intervals. RESULTS: Using the method of exon trapping, 92 unique exon trapping sequences (ETS) were discovered in a chromosomal region of poor gene coverage. Sequence identity to the current NCBI sequence assembly for BTA6 was detected for 91% of unique ETS. Comparative sequence similarity search revealed that 11% of the isolated ETS displayed high similarity to genomic sequences located on the syntenic chromosomes of the human and mouse reference genome assemblies. Nearly a third of the ETS identified similar equivalent sequences in genomic sequence scaffolds from the alternative Celera-based sequence assembly of the human genome. Screening gene, EST, and protein databases detected 17% of ETS with identity to known transcribed sequences. Expression analysis of a subset of the ETS showed that most ETS (84%) displayed a distinctive expression pattern in a multi-tissue panel of a lactating cow verifying their existence in the bovine transcriptome. CONCLUSION: The results of our study demonstrate that the exon trapping method based on region-specific BAC clones is very useful for targeted screening for novel transcripts located within a defined chromosomal region being deficiently endowed with annotated gene information. The majority of identified ETS represents unknown noncoding sequences in intergenic regions on BTA6 displaying a distinctive tissue-specific expression profile. However, their definite regulatory function has to be analyzed in further studies. The novel transcripts will add new sequence information to annotate a complete bovine genome sequence assembly, contribute to establish a detailed transcription map for targeted BTA6 regions and will also be helpful to dissect of the molecular and regulatory background of the QTL detected on BTA6.