Arabidopsis Plants Sense Non-self Peptides to Promote Resistance Against

Overview

Journal Front Plant Sci

Date 2020 Jun 16

PMID 32536929

Citations 5

Authors

Julia Pastor-Fernandez

Jordi Gamir

Victoria Pastor

Paloma Sanchez-Bel

Neus Sanmartin

Miguel Cerezo

Victor Flors

Affiliations

Soon will be listed here.

Abstract

Peptides are important regulators that participate in the modulation of almost every physiological event in plants, including defense. Recently, many of these peptides have been described as defense elicitors, termed phytocytokines, that are released upon pest or pathogen attack, triggering an amplification of plant defenses. However, little is known about peptides sensing and inducing resistance activities in heterologous plants. In the present study, exogenous peptides from solanaceous species, Systemins and HypSys, are sensed and induce resistance to the necrotrophic fungus in the taxonomically distant species Surprisingly, other peptides from closer taxonomic clades have very little or no effect on plant protection. bioassays showed that the studied peptides do not have direct antifungal activities, suggesting that they protect the plant through the promotion of the plant immune system. Interestingly, tomato Systemin was able to induce resistance at very low concentrations (0.1 and 1 nM) and displays a maximum threshold being ineffective above at higher concentrations. Here, we show evidence of the possible involvement of the JA-signaling pathway in the Systemin-Induced Resistance (Sys-IR) in Arabidopsis. Additionally, Systemin treated plants display enhanced and gene expression following infection as well as increased production of ROS after PAMP treatment suggesting that Systemin sensitizes Arabidopsis perception to pathogens and PAMPs.

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