Distinct Infection Mechanisms of AG-1 IA and AG-4 HG-I+II in and Barley

Overview

Journal Life (Basel)

Specialty Biology

Date 2025 Feb 26

PMID 40003643

Authors

Niranjan Mahadevan

Rozi Fernanda

Yusuke Kouzai

Natsuka Kohno

Reiko Nagao

Khin Thida Nyein

Megumi Watanabe

Nanami Sakata

Hidenori Matsui

Kazuhiro Toyoda

Yuki Ichinose

Keiichi Mochida

Hiroshi Hisano

Yoshiteru Noutoshi

Affiliations

Soon will be listed here.

Abstract

is a basidiomycete phytopathogenic fungus that causes rapid necrosis in a wide range of crop species, leading to substantial agricultural losses worldwide. The species complex is divided into 13 anastomosis groups (AGs) based on hyphal fusion compatibility and further subdivided by culture morphology. While classifications were shown to be independent of host specificity, it remains unclear whether different isolates share similar virulence mechanisms. Here, we investigated the infectivity of Japanese isolates on and barley. Two isolates, AG-1 IA (from rice) and AG-4 HG-I+II (from cauliflower), infected leaves of both plants, but only AG-4 HG-I+II infected roots. accessions Bd3-1 and Gaz-4 and barley cultivar 'Morex' exhibited enhanced resistance to both isolates compared to Bd21 and barley cultivars 'Haruna Nijo' and 'Golden Promise'. During AG-1 IA infection, but not AG-4 HG-I+II infection, resistant Bd3-1 and Morex induced genes for salicylic acid (SA) and -hydroxypipecolic acid (NHP) biosynthesis. Pretreatment with SA or NHP conferred resistance to AG-1 IA, but not AG-4 HG-I+II, in susceptible Bd21 and barley Haruna Nijo. On the leaves of susceptible Bd21 and Haruna Nijo, AG-1 IA developed extensive mycelial networks with numerous infection cushions, which are specialized infection structures well-characterized in rice sheath blight. In contrast, AG-4 HG-I+II formed dispersed mycelial masses associated with underlying necrosis. We propose that the species complex encompasses at least two distinct infection strategies: AG-1 IA exhibits a hemibiotrophic lifestyle, while AG-4 HG-I+II follows a predominantly necrotrophic strategy.

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