Natural variation of plant metabolism: genetic mechanisms, interpretive caveats, evolutionary and mechanistic insights.

Soltis, Nicole E.; Kliebenstein, Daniel J.

doi:10.1104/pp.15.01108

Cited by 40 publications

(56 citation statements)

References 133 publications

(238 reference statements)

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“…Recently, the naturally occurring metabolic diversity within species and the underlying genetic determinants have attracted increasing research interests (Luo, ). Studies with natural or artificial populations in several species discovered that plant metabolism is moderately inheritable and shows polygenic inheritance (Chen et al ., ; Alseekh et al ., ; Soltis and Kliebenstein, ). Metabolites displayed high heritability and constant diversity within experimental populations, making the metabolome of plants an ideal target trait for population genetics studies.…”

Section: Deciphering the Genetic Bases Of Metabolic Diversity With Mgwasmentioning

confidence: 99%

Metabolic GWAS‐based dissection of genetic bases underlying the diversity of plant metabolism

2018

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Plants have served as sources providing humans with metabolites for food and nutrition, biomaterials for living, and treatment for pain and disease. Plants produce a huge array of metabolites, with an immense diversity at both the population and individual levels. Dissection of the genetic bases for metabolic diversity has attracted increasing research attention. The concept of genome-wide association study (GWAS) was extended to studies on the diversity of plant metabolome that benefitted from the development of mass-spectrometry-based analytical systems and genome sequencing technologies. Metabolic genome-wide association study (mGWAS) is one of the most powerful tools for global identification of genetic determinants for diversity of plant metabolism. Recently, mGWAS has been performed for various species with continuous improvements, providing deeper insights into the genetic bases of metabolic diversity. In this review, we discuss fully the achievements to date and remaining challenges that are associated with both mGWAS and mGWAS-based multi-dimensional analysis. We begin with a summary of GWAS and its development based on statistical methods and populations. As variation in targeted traits is essential for GWAS, we review metabolic diversity and its rise at both the population and individual levels. Subsequently, the application of mGWAS for plants and its corresponding achievements are fully discussed. We address the current knowledge on mGWAS-based multi-dimensional analysis and emerging insights into the diversity of metabolism.

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Section: Deciphering the Genetic Bases Of Metabolic Diversity With Mgwasmentioning

confidence: 99%

Metabolic GWAS‐based dissection of genetic bases underlying the diversity of plant metabolism

2018

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“…Plants are renowned for their metabolic flexibility to generate many thousands of specialized metabolites that are non-uniformly distributed among discrete phylogenetic clades (Schilmiller et al, 2012a;Soltis and Kliebenstein, 2015). Because of their sessile lifestyles, it has been suggested that plants have developed this metabolic diversity to enable a biochemical response to environmental stimuli, often exploiting the language of low molecular weight chemicals.…”

Section: Discussionmentioning

confidence: 99%

Integrating metabolomics and transcriptomics data to discover a biocatalyst that can generate the amine precursors for alkamide biosynthesis

et al. 2016

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Summary The Echinacea genus is exemplary of over 30 plant families that produce a set of bioactive amides, called alkamides. The Echinacea alkamides may be assembled from two distinct moieties, a branched-chain amine that is acylated with a novel polyunsaturated fatty acid. In this study we identified the potential enzymological source of the amine moiety as a pyridoxal phosphate dependent decarboxylating enzyme that uses branched chain amino acids as substrate. This identification was based on a correlative analysis of the transcriptomes and metabolomes of 36 different E. purpurea tissues and organs, which expressed distinct alkamide profiles. Although no correlation was found between the accumulation patterns of the alkamides and their putative metabolic precursors (i.e., fatty acids and branched chain amino acids), isotope-labeling analyses supported the transformation of valine and isoleucine to isobutylamine and 2-methylbutylamine as reactions of alkamide biosynthesis. Sequence homology identified the pyridoxal phosphate dependent decarboxylase-like proteins in the translated proteome of E. purpurea. These sequences were prioritized for direct characterization by correlating their transcript levels with alkamide accumulation patterns in different organs and tissues, and this multi-pronged approach led to the identification and characterization of a branched-chain amino acid decarboxylase, which would appear to be responsible for generating the amine moieties of naturally occurring alkamides.

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“…Metabolomic analysis can aid in the development of standardization methods for understanding natural variation and/or various environmental conditions regarding plant growth (Kusano et al 2007b;Meyer et al 2007;Sato and Yanagisawa 2014;Soltis and Kliebenstein 2015;Sotelo-Silveira et al 2015;Sulpice et al 2009;Tamura et al 2018). According to recent studies of plant metabolic processes, metabolic profiling has shown a close link between biomass accumulation and metabolites, as both negative and positive correlations (Meyer et al 2007;Sulpice et al 2009).…”

Section: Introductionmentioning

confidence: 99%

“…Most studies have focused on analyzing natural variation under limited growth conditions or on an accession under various growth conditions (Meyer et al 2007;Sato and Yanagisawa 2014;Seaton et al 2018;Sotelo-Silveira et al 2015;Weckwerth et al 2004). Therefore, expanding research to understand fully functional systems is required (Soltis and Kliebenstein 2015). Here, our comprehensive study investigated the correlation of growth response and metabolite profiling among two Arabidopsis accessions and their F 1 hybrid under short-day conditions (SD) (12 h light, 12 h dark) and long-day conditions (LD) (16 h light, 8 h dark), with or without exogenous Suc.…”

Section: Introductionmentioning

confidence: 99%

Association analysis of phenotypic and metabolomic changes in Arabidopsis accessions and their F<sub>1</sub> hybrids affected by different photoperiod and sucrose supply

Sugi

Furukawa

et al. 2019

Plant Biotechnology

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Photoperiod and sucrose (Suc) assimilation play important roles in the regulation of plant growth and development. However, it remains unclear how natural variation of plants could contribute to metabolic changes under various growth conditions. Here, we investigated the developmental and metabolomic responses of two natural accessions of Arabidopsis thaliana, Columbia (Col) and C24, and their reciprocal F 1 hybrids grown under four carbon source regimens, i.e., two different photoperiods and the presence or absence of exogenous Suc supply. The effect of exogenous Suc clearly appeared in the growth of Col and the F 1 hybrid but not in C24, whereas long-day conditions had significant positive effects on the growth of all lines. Comparative metabolite profiling of Col, C24, and the F 1 hybrid revealed that changes in metabolite levels, particularly sugars, were highly dependent on genotype-specific responses rather than growth conditions. The presence of Suc led to over-accumulation of seven metabolites, including four sugars, a polyamine, and two amino acids in C24, whereas no such accumulation was observed in the profiles of Col and the F 1 hybrid. Thus, the comparative metabolite profiling revealed that the two parental lines of the hybrid show a distinct difference in sugar metabolism.

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Natural variation of plant metabolism: genetic mechanisms, interpretive caveats, evolutionary and mechanistic insights.

Cited by 40 publications

References 133 publications

Metabolic GWAS‐based dissection of genetic bases underlying the diversity of plant metabolism

Metabolic GWAS‐based dissection of genetic bases underlying the diversity of plant metabolism

Integrating metabolomics and transcriptomics data to discover a biocatalyst that can generate the amine precursors for alkamide biosynthesis

Association analysis of phenotypic and metabolomic changes in Arabidopsis accessions and their F<sub>1</sub> hybrids affected by different photoperiod and sucrose supply

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