A fungal wheat pathogen evolved host specialization by extensive chromosomal rearrangements

Fungal pathogens can rapidly evolve virulence towards resistant crops in agricultural ecosystems. Gains in virulence are often mediated by the mutation or deletion of a gene encoding a protein recognized by the plant immune system. However, the loci and the mechanisms of genome evolution enabling ra...

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Bibliographic Details
Published in:The ISME Journal 2017-05, Vol.11 (5), p.1189-1204
Main Authors: Hartmann, Fanny E, Sánchez-Vallet, Andrea, McDonald, Bruce A, Croll, Daniel
Format: Article
Language:English
Subjects:
45/43
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631/181/457
631/208/212/748
631/326/193/2539
Agricultural ecosystems
Ascomycota - genetics
Ascomycota - isolation & purification
Ascomycota - pathogenicity
Biomedical and Life Sciences
Chromosomes, Fungal
DNA Transposable Elements
Ecology
Evolution, Molecular
Evolutionary Biology
Gene Deletion
Genome, Fungal
Genome-Wide Association Study
Genomics
Genotypes
Immune system
Life Sciences
Microbial Ecology
Microbial Genetics and Genomics
Microbiology
Original
original-article
Pathogens
Polymorphism, Genetic
Reproduction
Speciation
Triticum - microbiology
Triticum aestivum
Virulence - genetics
Wheat
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Summary:Fungal pathogens can rapidly evolve virulence towards resistant crops in agricultural ecosystems. Gains in virulence are often mediated by the mutation or deletion of a gene encoding a protein recognized by the plant immune system. However, the loci and the mechanisms of genome evolution enabling rapid virulence evolution are poorly understood. We performed genome-wide association mapping on a global collection of 106 strains of Zymoseptoria tritici , the most damaging pathogen of wheat in Europe, to identify polymorphisms linked to virulence on two wheat varieties. We found 25 distinct genomic loci associated with reproductive success of the pathogen. However, no locus was shared between the host genotypes, suggesting host specialization. The main locus associated with virulence encoded a highly expressed, small secreted protein. Population genomic analyses showed that the gain in virulence was explained by a segregating gene deletion polymorphism. The deletion was likely adaptive by preventing detection of the encoded protein. Comparative genomics of closely related species showed that the locus emerged de novo since speciation. A large cluster of transposable elements in direct proximity to the locus generated extensive rearrangements leading to multiple independent gene losses. Our study demonstrates that rapid turnover in the chromosomal structure of a pathogen can drive host specialization.
ISSN:1751-7362
1751-7370
DOI:10.1038/ismej.2016.196