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Sylvain Foissac, Sarah Djebali, Kylie Munyard, Nathalie Vialaneix, Andrea Rau, Herve Acloque, Sandrine Lagarrigue, Elisabetta Giuffra, 32 Functional annotation of livestock genomes: chromatin structure and regulation of gene expression, Journal of Animal Science, Volume 97, Issue Supplement_2, July 2019, Pages 15–16, https://doi.org/10.1093/jas/skz122.028
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Abstract
Improving the functional annotation of animal genomes is a key challenge in bridging the gap between genotype and phenotype, thus enabling predictive biology. Regarding livestock production, major outcomes are expected from a better understanding of the genetic architecture underlying quantitative traits. As part of the Functional Annotation of ANimal Genomes action (FAANG: www.faang.org), the FR-AgENCODE project generated omics data to improve the reference annotation of the cattle, pig, goat and chicken genome. High-throughput molecular assays have been performed on tissues/cells relevant to immune and metabolic traits. From two males and two females per species (pig, cattle, goat, chicken), strand-oriented RNA-seq gene expression and ATAC-seq chromatin accessibility assays were performed on liver and two PBMC-sorted T-cell types (CD4+ and CD8+). Chromosome Conformation Capture (in situ Hi-C) was also carried out on liver samples. About 4,000 samples have been collected at the INRA biorepository and registered at the EBI BioSamples registry. More than 80% of the planned experiments could be completed, generating ~11.5 billions of sequencing reads over the 3 assays. While most (50–80%) RNA-seq reads mapped to annotated exons, thousands of novel transcripts were found, with ~60K mRNAs and ~22K lncRNAs in cattle. Differentially expressed genes between cell types were enriched for immunity- or metabolism-related terms, and differentially accessible chromatin regions were identified as potential regulatory sites. Interestingly, correlations between gene expression and promoter accessibility across samples were skewed towards both positive and negative values, suggesting distinct regulatory mechanisms of gene expression. These patterns have been further investigated using human data from the Epigenome Roadmap Mapping Consortium. Altogether, this study illustrates the interest of a coordinated effort to tackle the genome-to-phenome challenge and provides a useful resource to the community. Availability: www.fragencode.org.
