Altered DNA methylation associated with an abnormal liver phenotype in a cattle model with a high incidence of perinatal pathologies

Cloning enables the generation of both clinically normal and pathological individuals from the same donor cells, and may therefore be a DNA sequence-independent driver of phenotypic variability. We took advantage of cattle clones with identical genotypes but different developmental abilities to inve...

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Published in:Scientific reports 2016-12, Vol.6 (1), p.38869-38869, Article 38869
Main Authors: Kiefer, Hélène, Jouneau, Luc, Campion, Évelyne, Rousseau-Ralliard, Delphine, Larcher, Thibaut, Martin-Magniette, Marie-Laure, Balzergue, Sandrine, Ledevin, Mireille, Prézelin, Audrey, Chavatte-Palmer, Pascale, Heyman, Yvan, Richard, Christophe, Le Bourhis, Daniel, Renard, Jean-Paul, Jammes, Hélène
Format: Article
Language:English
Subjects:
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Animals
Cattle
Cattle Diseases - genetics
Cattle Diseases - mortality
Cattle Diseases - pathology
Cloning
Cloning, Organism
Dairy cattle
Deoxyribonucleic acid
Development Biology
Diabetes mellitus
Disease Models, Animal
DNA
DNA Methylation
Energy Metabolism
Epigenesis, Genetic
Epigenetics
Fatty acid composition
Fatty Acids - metabolism
Female
Gene Expression Regulation, Developmental
Genetic variability
Genomes
Genotypes
Glycogen
Humanities and Social Sciences
Life Sciences
Liver
Liver - metabolism
Liver - pathology
Male
Mortality
multidisciplinary
Nucleotide sequence
Phenotype
Reproductive Biology
Science
Stress, Physiological
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Description
Summary:Cloning enables the generation of both clinically normal and pathological individuals from the same donor cells, and may therefore be a DNA sequence-independent driver of phenotypic variability. We took advantage of cattle clones with identical genotypes but different developmental abilities to investigate the role of epigenetic factors in perinatal mortality, a complex trait with increasing prevalence in dairy cattle. We studied livers from pathological clones dying during the perinatal period, clinically normal adult clones with the same genotypes as perinatal clones and conventional age-matched controls. The livers from deceased perinatal clones displayed histological lesions, modifications to quantitative histomorphometric and metabolic parameters such as glycogen storage and fatty acid composition, and an absence of birth-induced maturation. In a genome-wide epigenetic analysis, we identified DNA methylation patterns underlying these phenotypic alterations and targeting genes relevant to liver metabolism, including the type 2 diabetes gene TCF7L2 . The adult clones were devoid of major phenotypic and epigenetic abnormalities in the liver, ruling out the effects of genotype on the phenotype observed. These results thus provide the first demonstration of a genome-wide association between DNA methylation and perinatal mortality in cattle, and highlight epigenetics as a driving force for phenotypic variability in farmed animals.
ISSN:2045-2322
2045-2322
DOI:10.1038/srep38869