Tandem Metalloenzymes Gate Plant Cell Entry by Pathogenic Fungi

Overview

Journal Sci Adv

Specialties Biology
Science

Date 2022 Dec 21

PMID 36542709

Authors

Bastien Bissaro

Sayo Kodama

Takumi Nishiuchi

Anna Maria Diaz-Rovira

Hayat Hage

David Ribeaucourt

Mireille Haon

Sacha Grisel

A Jalila Simaan

Fred Beisson

Stephanie M Forget

Harry Brumer

Marie-Noelle Rosso

Victor Guallar

Richard OConnell

Mickael Lafond

Yasuyuki Kubo

Jean-Guy Berrin

Affiliations

Soon will be listed here.

Abstract

Global food security is endangered by fungal phytopathogens causing devastating crop production losses. Many of these pathogens use specialized appressoria cells to puncture plant cuticles. Here, we unveil a pair of alcohol oxidase-peroxidase enzymes to be essential for pathogenicity. Using , we show that the enzyme pair is cosecreted by the fungus early during plant penetration and that single and double mutants have impaired penetration ability. Molecular modeling, biochemical, and biophysical approaches revealed a fine-tuned interplay between these metalloenzymes, which oxidize plant cuticular long-chain alcohols into aldehydes. We show that the enzyme pair is involved in transcriptional regulation of genes necessary for host penetration. The identification of these infection-specific metalloenzymes opens new avenues on the role of wax-derived compounds and the design of oxidase-specific inhibitors for crop protection.

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