Entomopathogenic Fungus -based Bioinsecticide Suppresses Severity of Powdery Mildews of Vegetables by Inducing the Plant Defense Responses

Overview

Journal Front Plant Sci

Date 2023 Sep 11

PMID 37692425

Authors

Yuichiro Iida

Yumiko Higashi

Oumi Nishi

Mariko Kouda

Kazuya Maeda

Kandai Yoshida

Shunsuke Asano

Taku Kawakami

Kaori Nakajima

Katsutoshi Kuroda

Chiharu Tanaka

Ayano Sasaki

Katsumi Kamiya

Naho Yamagishi

Masashi Fujinaga

Fumihiro Terami

Satoshi Yamanaka

Masaharu Kubota

Affiliations

Soon will be listed here.

Abstract

The entomopathogenic fungus is used commercially as a microbial insecticides against a wide range of agricultural insect pests. Some strains of protect the plants from pathogens, but the underlying mechanisms are largely unknown. Here, we found that prophylactic sprays of commercial bioinsecticide Botanigard on cucumber, tomato, and strawberry plants suppressed the severity of economically damaging powdery mildews. On leaf surfaces, hyphal elongation and spore germination of cucumber powdery mildew, , were inhibited, but strain GHA, the active ingredient isolated from Botanigard, only inhibited hyphal elongation but had no effect on spore germination of . In addition, strain GHA suppressed powdery mildew symptoms locally, not systemically. Treatment with Botanigard and strain GHA induced a hypersensitive response (HR)-like cell death in epidermal cells of the cucumber leaves in a concentration-dependent manner and inhibited penetration by . Transcriptome analysis and mass spectrometry revealed that GHA induced expression of salicylic acid (SA)-related genes, and treatment with Botanigard and GHA increased the SA level in the cucumber leaves. In -transgenic tomato plants, which do not accumulate SA, the biocontrol effect of tomato powdery mildew by GHA was significantly reduced. These results suggested that GHA induces SA accumulation, leading to the induction of HR-like cell death against powdery mildew and subsequent suppression of fungal penetration. Thus, Botanigard has the potential to control both insect pests and plant diseases.

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