AUTHOR=Suárez-Vega Aroa , Frutos Pilar , Gutiérrez-Gil Beatriz , Esteban-Blanco Cristina , Toral Pablo G. , Arranz Juan-José , Hervás Gonzalo
TITLE=Feed efficiency in dairy sheep: An insight from the milk transcriptome
JOURNAL=Frontiers in Veterinary Science
VOLUME=10
YEAR=2023
URL=https://www.frontiersin.org/journals/veterinary-science/articles/10.3389/fvets.2023.1122953
DOI=10.3389/fvets.2023.1122953
ISSN=2297-1769
ABSTRACT=IntroductionAs higher feed efficiency in dairy ruminants means a higher capability to transform feed nutrients into milk and milk components, differences in feed efficiency are expected to be partly linked to changes in the physiology of the mammary glands. Therefore, this study aimed to determine the biological functions and key regulatory genes associated with feed efficiency in dairy sheep using the milk somatic cell transcriptome.
Material and methodsRNA-Seq data from high (H-FE, n = 8) and low (L-FE, n = 8) feed efficiency ewes were compared through differential expression analysis (DEA) and sparse Partial Least Square-Discriminant analysis (sPLS-DA).
ResultsIn the DEA, 79 genes were identified as differentially expressed between both conditions, while the sPLS-DA identified 261 predictive genes [variable importance in projection (VIP) > 2] that discriminated H-FE and L-FE sheep.
DiscussionThe DEA between sheep with divergent feed efficiency allowed the identification of genes associated with the immune system and stress in L-FE animals. In addition, the sPLS-DA approach revealed the importance of genes involved in cell division (e.g., KIF4A and PRC1) and cellular lipid metabolic process (e.g., LPL, SCD, GPAM, and ACOX3) for the H-FE sheep in the lactating mammary gland transcriptome. A set of discriminant genes, commonly identified by the two statistical approaches, was also detected, including some involved in cell proliferation (e.g., SESN2, KIF20A, or TOP2A) or encoding heat-shock proteins (HSPB1). These results provide novel insights into the biological basis of feed efficiency in dairy sheep, highlighting the informative potential of the mammary gland transcriptome as a target tissue and revealing the usefulness of combining univariate and multivariate analysis approaches to elucidate the molecular mechanisms controlling complex traits.