Transcriptional Response of a Target Plant to Benzoxazinoid and Diterpene Allelochemicals Highlights Commonalities in Detoxification

Overview

Journal BMC Plant Biol

Publisher Biomed Central

Specialty Biology

Date 2022 Aug 16

PMID 35974304

Authors

Eva Knoch

Judit Kovacs

Sebastian Deiber

Keisuke Tomita

Reshi Shanmuganathan

Nuria Serra Serra

Kazunori Okada

Claude Becker

Niklas Schandry

Affiliations

Soon will be listed here.

Abstract

Background: Plants growing in proximity to other plants are exposed to a variety of metabolites that these neighbors release into the environment. Some species produce allelochemicals to inhibit growth of neighboring plants, which in turn have evolved ways to detoxify these compounds.

Results: In order to understand how the allelochemical-receiving target plants respond to chemically diverse compounds, we performed whole-genome transcriptome analysis of Arabidopsis thaliana exposed to either the benzoxazinoid derivative 2-amino- 3H-phenoxazin-3-one (APO) or momilactone B. These two allelochemicals belong to two very different compound classes, benzoxazinoids and diterpenes, respectively, produced by different Poaceae crop species.

Conclusions: Despite their distinct chemical nature, we observed similar molecular responses of A. thaliana to these allelochemicals. In particular, many of the same or closely related genes belonging to the three-phase detoxification pathway were upregulated in both treatments. Further, we observed an overlap between genes upregulated by allelochemicals and those involved in herbicide detoxification. Our findings highlight the overlap in the transcriptional response of a target plant to natural and synthetic phytotoxic compounds and illustrate how herbicide resistance could arise via pathways involved in plant-plant interaction.

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