Field-Based Metabolomics of . Stems Provides New Insights for Genotype Discrimination and Polyphenol Metabolism Structuring

Overview

Journal Front Plant Sci

Date 2018 Jul 7

PMID 29977248

Citations 20

Authors

Kevin Billet

Benjamin Houille

Thomas Duge de Bernonville

Sebastien Besseau

Audrey Oudin

Vincent Courdavault

Guillaume Delanoue

Laurence Guerin

Marc Clastre

Nathalie Giglioli-Guivarch

Arnaud Lanoue

Affiliations

Soon will be listed here.

Abstract

Grape accumulates numerous polyphenols with abundant health benefit and organoleptic properties that act as key components of the plant defense system against diseases. Considerable advances have been made in the chemical characterization of wine metabolites particularly volatile and polyphenolic compounds. However, the metabotyping (metabolite-phenotype characterization) of grape varieties, from polyphenolic-rich vineyard by-product is unprecedented. As this composition might result from the complex interaction between genotype, environment and viticultural practices, a field experiment was setting up with uniform pedo-climatic factors and viticultural practices of growing vines to favor the genetic determinism of polyphenol expression. As a result, UPLC-MS-based targeted metabolomic analyses of grape stems from 8 L. cultivars allowed the determination of 42 polyphenols related to phenolic acids, flavonoids, procyanidins, and stilbenoids as resveratrol oligomers (degree of oligomerization 1-4). Using a partial least-square discriminant analysis approach, grape stem chemical profiles were discriminated according to their genotypic origin showing that polyphenol profile express a varietal signature. Furthermore, hierarchical clustering highlights various degree of polyphenol similarity between grape varieties that were in agreement with the genetic distance using clustering analyses of 22 microsatellite DNA markers. Metabolite correlation network suggested that several polyphenol subclasses were differently controlled. The present polyphenol metabotyping approach coupled to multivariate statistical analyses might assist grape selection programs to improve metabolites with both health-benefit potential and plant defense traits.

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