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RESEARCH PRODUCT
Cytosine methylation patterns suggest a role of methylation in plastic and adaptive responses to temperature in European grayling (Thymallus thymallus) populations
Craig R. PrimmerSpiros PapakostasL. Asbjørn VøllestadPaul V. DebesPaul V. DebesTiina SävilammiTiina SävilammiErica H. LederErica H. Ledersubject
0301 basic medicineCancer ResearchDATABASEsalmonidPopulationCytosine methylationSNPepigenetic variationCytosine03 medical and health sciences0302 clinical medicineINTRAGENIC DNA METHYLATIONthermal adaptationPHENOTYPIC PLASTICITYAnimalsADAPTATIONeducationMolecular BiologyGENE-EXPRESSIONLocal adaptationeducation.field_of_studyPhenotypic plasticitypromoterCLIMATE-CHANGEbiologyTemperatureGenetic VariationDNA Methylationbiology.organism_classificationThymallusEVOLUTIONEuropean graylingINSIGHTS030104 developmental biologyCpG siteEvolutionary biologydevelopmental plasticity030220 oncology & carcinogenesisEctotherm1181 Ecology evolutionary biologyDNA methylationTHERMAL PLASTICITYtranscriptionSalmonidaeResearch Paperdescription
Temperature is a key environmental parameter affecting both the phenotypes and distributions of organisms, particularly ectotherms. Rapid organismal responses to thermal environmental changes have been described for several ectotherms; however, the underlying molecular mechanisms often remain unclear. Here, we studied whole genome cytosine methylation patterns of European grayling (Thymallus thymallus) embryos from five populations with contemporary adaptations of early life history traits at either 'colder' or 'warmer' spawning grounds. We reared fish embryos in a common garden experiment using two temperatures that resembled the 'colder' and 'warmer' conditions of the natal natural environments. Genome-wide methylation patterns were similar in populations originating from colder thermal origin subpopulations, whereas single nucleotide polymorphisms uncovered from the same data identified strong population structure among isolated populations, but limited structure among interconnected populations. This was surprising because the previously studied gene expression response among populations was mostly plastic, and mainly influenced by the developmental temperature. These findings support the hypothesis of the magnified role of epigenetic mechanisms in modulating plasticity. The abundance of consistently changing methylation loci between two warmer-to-colder thermal origin population pairs suggests that local adaptation has shaped the observed methylation patterns. The dynamic nature of the methylomes was further highlighted by genome-wide and site-specific plastic responses. Our findings support both the presence of a plastic response in a subset of CpG loci, and the evolutionary role of methylation divergence between populations adapting to contrasting thermal environments. Peer reviewed
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2020-07-30 | Epigenetics |