Comparison of the Impact of Two Key Fungal Signalling Pathways on Zymoseptoria Tritici Infection Reveals Divergent Contribution to Invasive Growth Through Distinct Regulation of Infection-associated Genes

Overview

Journal Mol Plant Pathol

Specialty Molecular Biology

Date 2023 Jun 12

PMID 37306534

Authors

Harry T Child

Michael J Deeks

Jason J Rudd

Steven Bates

Affiliations

Soon will be listed here.

Abstract

The lifecycle of Zymoseptoria tritici requires a carefully regulated asymptomatic phase within the wheat leaf following penetration of the mesophyll via stomata. Here we compare the roles in this process of two key fungal signalling pathways, mutants of which were identified through forward genetics due to their avirulence on wheat. Whole-genome resequencing of avirulent Z. tritici T-DNA transformants identified disruptive mutations in ZtBCK1 from the kinase cascade of the cell wall integrity (CWI) pathway, and the adenylate cyclase gene ZtCYR1. Targeted deletion of these genes abolished the pathogenicity of the fungus and led to similar in vitro phenotypes to those associated with disruption of putative downstream kinases, both supporting previous studies and confirming the importance of these pathways in virulence. RNA sequencing was used to investigate the effect of ZtBCK1 and ZtCYR1 deletion on gene expression in both the pathogen and host during infection. ZtBCK1 was found to be required for the adaptation to the host environment, controlling expression of infection-associated secreted proteins, including known virulence factors. Meanwhile, ZtCYR1 is implicated in controlling the switch to necrotrophy, regulating expression of effectors associated with this transition. This represents the first study to compare the influence of CWI and cAMP signalling on in planta transcription of a fungal plant pathogen, providing insights into their differential regulation of candidate effectors during invasive growth.

Citing Articles

The Zymoseptoria tritici effector Zt-11 contributes to aggressiveness in wheat.

Karki S, Pilo P, Lawless C, Mastrodimos N, Tiley A, Burke J PLoS One. 2024; 19(11):e0313859.

PMID: 39561154 PMC: 11575801. DOI: 10.1371/journal.pone.0313859.

Comparison of the impact of two key fungal signalling pathways on Zymoseptoria tritici infection reveals divergent contribution to invasive growth through distinct regulation of infection-associated genes.

Child H, Deeks M, Rudd J, Bates S Mol Plant Pathol. 2023; 24(10):1220-1237.

PMID: 37306534 PMC: 10502814. DOI: 10.1111/mpp.13365.

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