Evolution of herbicide resistance mechanisms in grass weeds

•TS resistance to PSII inhibitors was associated with significant fitness cost.•NTS resistance was found regardless of herbicide application history.•CYT-P450-based detoxification conferred ACCase resistance in Brachipodium.•BrIFAR offers a new and improved weed management for agricultural practice....

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Veröffentlicht in:	Plant science (Limerick) 2014-12, Vol.229, p.43-52
Hauptverfasser:	Matzrafi, Maor, Gadri, Yaron, Frenkel, Eyal, Rubin, Baruch, Peleg, Zvi
Format:	Artikel
Sprache:	eng
Schlagworte:	ACCase inhibitors Acetyl-CoA Carboxylase - antagonists & inhibitors Acetyl-CoA Carboxylase - metabolism ALS/AHAS inhibitors Amino Acid Sequence Arabidopsis - metabolism Brachypodium Brachypodium - drug effects Brachypodium - genetics Ecosystem EPSPS inhibitor Evolution, Molecular Halogenated Diphenyl Ethers - toxicity Herbicide detoxification Herbicide Resistance - genetics Heterocyclic Compounds, 2-Ring - toxicity Israel Molecular Sequence Data Photosystem II Protein Complex - metabolism Plant Proteins - chemistry Plant Weeds - drug effects Plant Weeds - genetics PSII inhibitors
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creator	Matzrafi, Maor Gadri, Yaron Frenkel, Eyal Rubin, Baruch Peleg, Zvi
description	•TS resistance to PSII inhibitors was associated with significant fitness cost.•NTS resistance was found regardless of herbicide application history.•CYT-P450-based detoxification conferred ACCase resistance in Brachipodium.•BrIFAR offers a new and improved weed management for agricultural practice. Herbicide resistant weeds are becoming increasingly common, threatening global food security. Here, we present BrIFAR: a new model system for the functional study of mechanisms of herbicide resistance in grass weeds. We have developed a large collection of Brachypodium accessions, the BrI collection, representing a wide range of habitats. Wide screening of the responses of the accessions to four major herbicide groups (PSII, ACCase, ALS/AHAS and EPSPS inhibitors) identified 28 herbicide-resistance candidate accessions. Target-site resistance to PSII inhibitors was found in accessions collected from habitats with a known history of herbicide applications. An amino acid substitution in the psbA gene (serine264 to glycine) conferred resistance and also significantly affected the flowering and shoot dry weight of the resistant accession, as compared to the sensitive accession. Non-target site resistance to ACCase inhibitors was found in accessions collected from habitats with a history of herbicide application and from a nature reserve. In-vitro enzyme activity tests and responses following pre-treatment with malathion (a cytochrome-P450 inhibitor) indicated sensitivity at the enzyme level, and give strong support to diclofop-methyl and pinoxaden enhanced detoxification as NTS resistance mechanism. BrIFAR can promote better understanding of the evolution of mechanisms of herbicide resistance and aid the implementation of integrative management approaches for sustainable agriculture.
doi_str_mv	10.1016/j.plantsci.2014.08.013
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Herbicide resistant weeds are becoming increasingly common, threatening global food security. Here, we present BrIFAR: a new model system for the functional study of mechanisms of herbicide resistance in grass weeds. We have developed a large collection of Brachypodium accessions, the BrI collection, representing a wide range of habitats. Wide screening of the responses of the accessions to four major herbicide groups (PSII, ACCase, ALS/AHAS and EPSPS inhibitors) identified 28 herbicide-resistance candidate accessions. Target-site resistance to PSII inhibitors was found in accessions collected from habitats with a known history of herbicide applications. An amino acid substitution in the psbA gene (serine264 to glycine) conferred resistance and also significantly affected the flowering and shoot dry weight of the resistant accession, as compared to the sensitive accession. Non-target site resistance to ACCase inhibitors was found in accessions collected from habitats with a history of herbicide application and from a nature reserve. In-vitro enzyme activity tests and responses following pre-treatment with malathion (a cytochrome-P450 inhibitor) indicated sensitivity at the enzyme level, and give strong support to diclofop-methyl and pinoxaden enhanced detoxification as NTS resistance mechanism. 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Non-target site resistance to ACCase inhibitors was found in accessions collected from habitats with a history of herbicide application and from a nature reserve. In-vitro enzyme activity tests and responses following pre-treatment with malathion (a cytochrome-P450 inhibitor) indicated sensitivity at the enzyme level, and give strong support to diclofop-methyl and pinoxaden enhanced detoxification as NTS resistance mechanism. 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subjects	ACCase inhibitors Acetyl-CoA Carboxylase - antagonists & inhibitors Acetyl-CoA Carboxylase - metabolism ALS/AHAS inhibitors Amino Acid Sequence Arabidopsis - metabolism Brachypodium Brachypodium - drug effects Brachypodium - genetics Ecosystem EPSPS inhibitor Evolution, Molecular Halogenated Diphenyl Ethers - toxicity Herbicide detoxification Herbicide Resistance - genetics Heterocyclic Compounds, 2-Ring - toxicity Israel Molecular Sequence Data Photosystem II Protein Complex - metabolism Plant Proteins - chemistry Plant Weeds - drug effects Plant Weeds - genetics PSII inhibitors
title	Evolution of herbicide resistance mechanisms in grass weeds
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