Population Genomics Demystifies the Defoliation Phenotype in the Plant Pathogen Verticillium Dahliae

Overview

Journal New Phytol

Specialty Biology

Date 2019 Jan 5

PMID 30609067

Citations 24

Authors

Dan-Dan Zhang

Jie Wang

Dan Wang

Zhi-Qiang Kong

Lei Zhou

Geng-Yun Zhang

Yue-Jing Gui

Jun-Jiao Li

Jin-Qun Huang

Bao-Li Wang

Chun Liu

Chun-Mei Yin

Rui-Xing Li

Ting-Gang Li

Jin-Long Wang

Dylan P G Short

Steven J Klosterman

Richard M Bostock

Krishna V Subbarao

Jie-Yin Chen

Xiao-Feng Dai

Affiliations

Soon will be listed here.

Abstract

Verticillium dahliae is a broad host-range pathogen that causes vascular wilts in plants. Interactions between three hosts and specific V. dahliae genotypes result in severe defoliation. The underlying mechanisms of defoliation are unresolved. Genome resequencing, gene deletion and complementation, gene expression analysis, sequence divergence, defoliating phenotype identification, virulence analysis, and quantification of V. dahliae secondary metabolites were performed. Population genomics previously revealed that G-LSR2 was horizontally transferred from the fungus Fusarium oxysporum f. sp. vasinfectum to V. dahliae and is exclusively found in the genomes of defoliating (D) strains. Deletion of seven genes within G-LSR2, designated as VdDf genes, produced the nondefoliation phenotype on cotton, olive, and okra but complementation of two genes restored the defoliation phenotype. Genes VdDf5 and VdDf6 associated with defoliation shared homology with polyketide synthases involved in secondary metabolism, whereas VdDf7 shared homology with proteins involved in the biosynthesis of N-lauroylethanolamine (N-acylethanolamine (NAE) 12:0), a compound that induces defoliation. NAE overbiosynthesis by D strains also appears to disrupt NAE metabolism in cotton by inducing overexpression of fatty acid amide hydrolase. The VdDfs modulate the synthesis and overproduction of secondary metabolites, such as NAE 12:0, that cause defoliation either by altering abscisic acid sensitivity, hormone disruption, or sensitivity to the pathogen.

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