A systems biology approach using metabolomic data reveals genes and pathways interacting to modulate divergent growth in cattle

A systems biology approach using metabolomic data reveals genes and pathways interacting to modulate divergent growth in cattle

Systems biology enables the identification of gene networks that modulate complex traits. Comprehensive metabolomic analyses provide innovative phenotypes that are intermediate between the initiator of genetic variability, the genome, and raw phenotypes that are influenced by a large number of envir...

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Bibliographic Details
Published in:BMC genomics Vol. 14; no. 1; p. 798
Main Authors: Widmann, Philipp, Reverter, Antonio, Fortes, Marina R S, Weikard, Rosemarie, Suhre, Karsten, Hammon, Harald, Albrecht, Elke, Kuehn, Christa
Format: Journal Article
Language:English
Published: England BioMed Central Ltd 18-11-2013
BioMed Central
Subjects:
Adenosine Triphosphatases - genetics
Animal development
Animals
Arginine
Beef cattle
Biology
Biomedical research
Body weight
Body Weight - genetics
Cattle
Data analysis
DNA-Binding Proteins - genetics
Epistasis, Genetic
Gene Expression Profiling
Genes
Genetic aspects
Genetic research
Genetic Variation
Genomes
Genomics
Gonadotropin-Releasing Hormone - genetics
Growth
Male
Metabolic Networks and Pathways - genetics
Metabolites
Metabolomics
Multiprotein Complexes - genetics
Myostatin - biosynthesis
Myostatin - genetics
Phenotype
Physiological aspects
Pituitary hormones
Polymorphism, Single Nucleotide - genetics
Population
Sexual Maturation - genetics
Studies
Systems Biology
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Summary:Systems biology enables the identification of gene networks that modulate complex traits. Comprehensive metabolomic analyses provide innovative phenotypes that are intermediate between the initiator of genetic variability, the genome, and raw phenotypes that are influenced by a large number of environmental effects. The present study combines two concepts, systems biology and metabolic analyses, in an approach without prior functional hypothesis in order to dissect genes and molecular pathways that modulate differential growth at the onset of puberty in male cattle. Furthermore, this integrative strategy was applied to specifically explore distinctive gene interactions of non-SMC condensin I complex, subunit G (NCAPG) and myostatin (GDF8), known modulators of pre- and postnatal growth that are only partially understood for their molecular pathways affecting differential body weight. Our study successfully established gene networks and interacting partners affecting growth at the onset of puberty in cattle. We demonstrated the biological relevance of the created networks by comparison to randomly created networks. Our data showed that GnRH (Gonadotropin-releasing hormone) signaling is associated with divergent growth at the onset of puberty and revealed two highly connected hubs, BTC and DGKH, within the network. Both genes are known to directly interact with the GnRH signaling pathway. Furthermore, a gene interaction network for NCAPG containing 14 densely connected genes revealed novel information concerning the functional role of NCAPG in divergent growth. Merging both concepts, systems biology and metabolomic analyses, successfully yielded new insights into gene networks and interacting partners affecting growth at the onset of puberty in cattle. Genetic modulation in GnRH signaling was identified as key modifier of differential cattle growth at the onset of puberty. In addition, the benefit of our innovative concept without prior functional hypothesis was demonstrated by data suggesting that NCAPG might contribute to vascular smooth muscle contraction by indirect effects on the NO pathway via modulation of arginine metabolism. Our study shows for the first time in cattle that integration of genetic, physiological and metabolomics data in a systems biology approach will enable (or contribute to) an improved understanding of metabolic and gene networks and genotype-phenotype relationships.
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ISSN:1471-2164
1471-2164
DOI:10.1186/1471-2164-14-798