Terpenoids from Weedy Ricefield Flatsedge ( L.) Are Developmentally Regulated and Stress-Induced, and Have Antifungal Properties

Overview

Journal Molecules

Publisher MDPI

Specialty Biology

Date 2018 Dec 6

PMID 30513639

Citations 3

Authors

Yifan Jiang

Bonnie H Ownley

Feng Chen

Affiliations

Soon will be listed here.

Abstract

Ricefield flatsedge ( L.), a troublesome weed in rice production, actively adapts to ecological niches. In this study, terpenoids were identified as the dominant compounds from organic extracts of leaves. To understand the role of terpenoid production in plant development and resistance to abiotic and biotic stresses, the dynamics of terpenoid production at different developmental stages, and the regulation of these compounds by stresses were determined. Terpenoid production exhibited temporal and spatial specificity. During vegetative growth, the total concentration of sesquiterpenoids increased and reached a maximum at 70 d after germination, and then decreased until the emergence of inflorescence. Monoterpenoids were only detected from leaves 90 d after germination. During reproductive growth, the total concentration of sesquiterpenoids increased dramatically and mainly accumulated in inflorescences, indicating that the sesquiterpenoids were primarily produced in newly formed and actively growing tissues. The total amount of monoterpenoids, mostly accumulated in flowers, increased until 130 d after germination. Furthermore, accumulation of sesquiterpenoids in leaves was promoted significantly by methyl jasmonate (MeJA) and drought treatment. Infestation by beet armyworm (, BAW) promoted the emission of total sesquiterpenoids significantly and induced the production of more monoterpenoids and sesquiterpenoids specifically. Furthermore, volatiles from leaves had an anti-fungal effect on . The implications of our findings on the biosynthetic pathways leading to the production of sesquiterpenoids in as well as their potential as fungicides are discussed.

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