Litcius/Paper detail

Transcriptionally linked simultaneous overexpression of P450 genes for broad-spectrum herbicide resistance

Hiroe Suda, T. Kubo, Yusuke Yoshimoto, Keisuke Tanaka, Satoru Tanaka, Akira Uchino, Satoshi Azuma, Makoto Hattori, Takuya Yamaguchi, Masahiro Miyashita, Tohru Tominaga, Satoshi Iwakami

2023PLANT PHYSIOLOGY33 citationsDOIOpen Access PDF

Abstract

Broad-spectrum herbicide resistance (BSHR), often linked to weeds with metabolism-based herbicide resistance, poses a threat to food production. Past studies have revealed that overexpression of catalytically promiscuous enzymes explains BSHR in some weeds; however, the mechanism of BSHR expression remains poorly understood. Here, we investigated the molecular basis of high-level resistance to diclofop-methyl in BSHR late watergrass (Echinochloa phyllopogon) found in the United States, which cannot be solely explained by the overexpression of promiscuous cytochrome P450 monooxygenases CYP81A12/21. The BSHR late watergrass line rapidly produced 2 distinct hydroxylated diclofop acids, only 1 of which was the major metabolite produced by CYP81A12/21. RNA-seq and subsequent reverse transcription quantitative PCR (RT-qPCR)-based segregation screening identified the transcriptionally linked overexpression of a gene, CYP709C69, with CYP81A12/21 in the BSHR line. The gene conferred diclofop-methyl resistance in plants and produced another hydroxylated diclofop acid in yeast (Saccharomyces cerevisiae). Unlike CYP81A12/21, CYP709C69 showed no other herbicide-metabolizing function except for a presumed clomazone-activating function. The overexpression of the 3 herbicide-metabolizing genes was also identified in another BSHR late watergrass in Japan, suggesting a convergence of BSHR evolution at the molecular level. Synteny analysis of the P450 genes implied that they are located at mutually independent loci, which supports the idea that a single trans-element regulates the 3 genes. We propose that transcriptionally linked simultaneous overexpression of herbicide-metabolizing genes enhances and broadens the metabolic resistance in weeds. The convergence of the complex mechanism in BSHR late watergrass from 2 countries suggests that BSHR evolved through co-opting a conserved gene regulatory system in late watergrass.

Topics & Concepts

BiologyGeneCytochrome P450GeneticsMonooxygenaseGene expressionFunction (biology)Transcription (linguistics)SyntenyBiochemistryEnzymeGenomePhilosophyLinguisticsWeed Control and Herbicide ApplicationsPesticide and Herbicide Environmental StudiesInsect Resistance and Genetics