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WEISZMANN, J. WALTHER, D. CLAUW, P. BACK, G. GUNIS, J. REICHARDT, I. KOEMEDA, S. JEZ, J. NORDBORG, M. PIERDIES, I. SCHWARZEROVÁ, J. NÄGELE, T. WECKWERTH, W.
Original Title
Metabolome plasticity in 241 Arabidopsis thaliana accessions reveals evolutionary cold adaptation processes
Type
journal article in Web of Science
Language
English
Original Abstract
Acclimation and adaptation of metabolism to a changing environment are key processes for plant survival and reproductive success. In the present study, 241 natural accessions of Arabidopsis (Arabidopsis thaliana) were grown under two different temperature regimes, 16 °C and 6 °C, and growth parameters were recorded, together with metabolite profiles, to investigate the natural genome × environment effects on metabolome variation. The plasticity of metabolism, which was captured by metabolic distance measures, varied considerably between accessions. Both relative growth rates and metabolic distances were predictable by the underlying natural genetic variation of accessions. Applying machine learning methods, climatic variables of the original growth habitats were tested for their predictive power of natural metabolic variation among accessions. We found specifically habitat temperature during the first quarter of the year to be the best predictor of the plasticity of primary metabolism, indicating habitat temperature as the causal driver of evolutionary cold adaptation processes. Analyses of epigenome- and genome-wide associations revealed accession-specific differential DNA-methylation levels as potentially linked to the metabolome and identified FUMARASE2 as strongly associated with cold adaptation in Arabidopsis accessions. These findings were supported by calculations of the biochemical Jacobian matrix based on variance and covariance of metabolomics data, which revealed that growth under low temperatures most substantially affects the accession-specific plasticity of fumarate and sugar metabolism. Our findings indicate that the plasticity of metabolic regulation is predictable from the genome and epigenome and driven evolutionarily by Arabidopsis growth habitats.
Keywords
Arabidopsis thaliana, Metabolomics, Evolution, Adaption, GWAS
Authors
WEISZMANN, J.; WALTHER, D.; CLAUW, P.; BACK, G.; GUNIS, J.; REICHARDT, I.; KOEMEDA, S.; JEZ, J.; NORDBORG, M.; PIERDIES, I.; SCHWARZEROVÁ, J.; NÄGELE, T.; WECKWERTH, W.
Released
23. 5. 2023
Publisher
Oxford University Press
ISBN
0032-0889
Periodical
PLANT PHYSIOLOGY
Year of study
192
Number
2
State
United States of America
Pages from
980
Pages to
1000
Pages count
21
URL
https://academic.oup.com/plphys/article/193/2/980/7176103
Full text in the Digital Library
http://hdl.handle.net/11012/244948
BibTex
@article{BUT183866, author="Jakob {Weiszmann} and Dirk {Walther} and Pieter {Clauw} and Georg {Back} and Joanna {Gunis} and Ilka {Reichardt} and Stefanie {Koemeda} and Jakub {Jez} and Magnus {Nordborg} and Jana {Schwarzerová} and Iro {Pierdies} and Thomas {Nägele} and Wolfram {Weckwerth}", title="Metabolome plasticity in 241 Arabidopsis thaliana accessions reveals evolutionary cold adaptation processes", journal="PLANT PHYSIOLOGY", year="2023", volume="192", number="2", pages="980--1000", doi="10.1093/plphys/kiad298", issn="0032-0889", url="https://academic.oup.com/plphys/article/193/2/980/7176103" }