Abstract
Management of rice false smut disease caused by Villosiclava virens is dependent on demethylation inhibitor (DMI) fungicides. Investigation of molecular mechanisms of resistance is therefore of upmost importance. In this study the gene encoding the target protein for DMI fungicides (VvCYP51) was cloned and investigated. The VvCYP51 gene in the resistant mutant revealed both a change from tyrosine to histidine at position 137 (Y137H) and elevated gene expression compared to the parental isolate. In order to determine which of these mechanisms was responsible for the reduced sensitivity to DMI fungicide tebuconazole, transformants expressing the mutated or the wild type VvCYP51 gene were generated. Transformants carrying the mutated gene were more resistant to tebuconazole compared to control transformants lacking the mutation, but the expression of the VvCYP51 gene was not significantly correlated with EC50 values. The wild type VvCYP51 protein exhibited stronger affinity for tebuconazole compared to the VvCYP51/Y137H in both molecular docking analysis and experimental binding assays. The UV-generated mutant as well as transformants expressing the VvCYP51/Y137H did not exhibit significant fitness penalties based on mycelial growth and spore germination, suggesting that isolates resistant to DMI fungicides based on the Y137H mutation may develop and be competitive in the field.
Highlights
The goal of this study was to investigate potential resistance mechanisms in V. virens
Based on the local BLAST analysis of cytochrome P450 sterol 14α -demethylase (CYP51) genes from two V. virens-close species M. anisopliae (CYP51A, CYP51B) and Fusarium ussurianum (CYP51C) in the V. virens database, the V. virens CYP51 (VvCYP51) gene was confirmed to be present as a single copy in the V. virens genome
Homologous CYP51 genes including CYP51A, CYP51B, and CYP51C have been found in some fungi and each may exhibit a different degree of fungicide resistance
Summary
The goal of this study was to investigate potential resistance mechanisms in V. virens. Because DMI-resistant isolates were not available, we produced a DMI-resistant mutant using UV-mutagenesis and cloned and sequenced the 14α -demethylase gene (designated as VvCYP51) from V. virens. Specific objectives were to (i) determine the variation of VvCYP51 gene sequences and expression patterns between the UV-generated mutant and the parental isolate; (ii) investigate the role of the mutated gene through genetic transformation; (iii) and elucidate the affinity of DMI fungicide tebuconazole with VvCYP51 protein through molecular docking analysis and binding assays
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