4 A Role for Metabolomics in Plant Ecology
Annual Plant Reviews book series, Volume 43: Biology of Plant Metabolomics
Nicole M. van Dam,
Eddy van der Meijden,
Nicole M. van Dam
Radboud University Nijmegen, Institute for Water and Wetland Research (IWWR), PO Box 9010, Nijmegen, GL, 6500 The Netherlands
Search for more papers by this authorEddy van der Meijden
Institute of Biology Leiden, PO Box 9505, Leiden, RA, 2300 The Netherlands
Search for more papers by this authorNicole M. van Dam,
Eddy van der Meijden,
Nicole M. van Dam
Radboud University Nijmegen, Institute for Water and Wetland Research (IWWR), PO Box 9010, Nijmegen, GL, 6500 The Netherlands
Search for more papers by this authorEddy van der Meijden
Institute of Biology Leiden, PO Box 9505, Leiden, RA, 2300 The Netherlands
Search for more papers by this authorThis article was originally published in 2011 in Biology of Plant Metabolomics, Volume 43 (ISBN 9781405199544) of the Annual Plant Reviews book series, this volume edited by Robert D. Hall. The article was republished in Annual Plant Reviews online in April 2018.
Abstract
Plant metabolomic analyses have been mostly applied to analyse metabolomes of crops and model species. However, metabolomic analyses may also be extremely valuable for plant ecologists. Because of the untargeted nature of most metabolomic platforms, the analyses will provide a comprehensive overview of both the primary and secondary plant metabolome. This is especially valuable for chemical ecologists studying plant–herbivore interactions, as both primary and secondary metabolites together determine the performance and preference of herbivores feeding on a plant. A few examples from the recent scientific literature exemplify how metabolomics may yield novel knowledge on the effects of hybridization on plant chemistry, insect resistance and genotype × environment interactions that could not have been so easily obtained with targeted studies alone. Theories and hypotheses regarding optimal defence strategies in plants and invasive plant biology may also benefit from metabolomic analysis. Testable hypotheses built on our current knowledge of plant responses to herbivores and competition may be substantiated and expanded based on metabolomic analyses. Despite some of the limitations that metabolomics analyses may have, the implementation of broad-spectrum chemical analysis in plant ecology will definitively open up new horizons for plant ecologists and enhance our understanding of the importance of plant chemistry in plant–environment interactions for fundamental and applied research.
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