TY - JOUR
T1 - Ecological plant epigenetics
T2 - Evidence from model and non-model species, and the way forward
AU - Richards, Christina L.
AU - Alonso, Conchita
AU - Becker, Claude
AU - Bossdorf, Oliver
AU - Bucher, Etienne
AU - Colomé-Tatché, Maria
AU - Durka, Walter
AU - Engelhardt, Jan
AU - Gaspar, Bence
AU - Gogol-Doering, Andreas
AU - Grosse, Ivo
AU - van Gurp, Thomas P.
AU - Heer, Katrin
AU - Kronholm, Ilkka
AU - Lampei, Christian
AU - Latzel, Vit
AU - Mirouze, Marie
AU - Opgenoorth, Lars
AU - Paun, Ovidiu
AU - Prohaska, Sonja J.
AU - Rensing, Stefan A.
AU - Stadler, Peter F.
AU - Trucchi, Emiliano
AU - Ullrich, Kristian
AU - Verhoeven, Koen J. F.
PY - 2017/12
Y1 - 2017/12
N2 - Growing evidence shows that epigenetic mechanisms contribute to complex traits, with implications across many fields of biology. In plant ecology, recent studies have attempted to merge ecological experiments with epigenetic analyses to elucidate the contribution of epigenetics to plant phenotypes, stress responses, adaptation to habitat, and range distributions. While there has been some progress in revealing the role of epigenetics in ecological processes, studies with non-model species have so far been limited to describing broad patterns based on anonymous markers of DNA methylation. In contrast, studies with model species have benefited from powerful genomic resources, which contribute to a more mechanistic understanding but have limited ecological realism. Understanding the significance of epigenetics for plant ecology requires increased transfer of knowledge and methods from model species research to genomes of evolutionarily divergent species, and examination of responses to complex natural environments at a more mechanistic level. This requires transforming genomics tools specifically for studying non-model species, which is challenging given the large and often polyploid genomes of plants. Collaboration among molecular geneticists, ecologists and bioinformaticians promises to enhance our understanding of the mutual links between genome function and ecological processes.
AB - Growing evidence shows that epigenetic mechanisms contribute to complex traits, with implications across many fields of biology. In plant ecology, recent studies have attempted to merge ecological experiments with epigenetic analyses to elucidate the contribution of epigenetics to plant phenotypes, stress responses, adaptation to habitat, and range distributions. While there has been some progress in revealing the role of epigenetics in ecological processes, studies with non-model species have so far been limited to describing broad patterns based on anonymous markers of DNA methylation. In contrast, studies with model species have benefited from powerful genomic resources, which contribute to a more mechanistic understanding but have limited ecological realism. Understanding the significance of epigenetics for plant ecology requires increased transfer of knowledge and methods from model species research to genomes of evolutionarily divergent species, and examination of responses to complex natural environments at a more mechanistic level. This requires transforming genomics tools specifically for studying non-model species, which is challenging given the large and often polyploid genomes of plants. Collaboration among molecular geneticists, ecologists and bioinformaticians promises to enhance our understanding of the mutual links between genome function and ecological processes.
KW - Bioinformatics
KW - ecological epigenetics
KW - genomics
KW - phenotypic plasticity
KW - response to environment
KW - DNA METHYLATION VARIATION
KW - HERB HELLEBORUS-FOETIDUS
KW - ARABIDOPSIS-THALIANA
KW - NATURAL-POPULATIONS
KW - SEQUENCING DATA
KW - PERENNIAL HERB
KW - PHENOTYPIC PLASTICITY
KW - PHYSCOMITRELLA-PATENS
KW - EPIGENOMIC DIVERSITY
KW - INDIVIDUAL VARIATION
U2 - 10.1111/ele.12858
DO - 10.1111/ele.12858
M3 - Review article
C2 - 29027325
SN - 1461-023X
VL - 20
SP - 1576
EP - 1590
JO - Ecology Letters
JF - Ecology Letters
IS - 12
ER -