Enhanced metabolic detoxification is associated with fluroxypyr resistance in Bassia scoparia

Olivia E Todd; Eric L Patterson; Eric P Westra; Scott J Nissen; André Lucas Simões Araujo; William B Kramer; Franck E Dayan; Todd A Gaines

doi:10.1002/pld3.560

Enhanced metabolic detoxification is associated with fluroxypyr resistance in Bassia scoparia

Plant Direct. 2024 Jan 24;8(1):e560. doi: 10.1002/pld3.560. eCollection 2024 Jan.

Authors

Olivia E Todd^{1

2}, Eric L Patterson³, Eric P Westra^{2

4}, Scott J Nissen², André Lucas Simões Araujo², William B Kramer², Franck E Dayan², Todd A Gaines²

Affiliations

¹ United States Department of Agriculture - Agriculture Research Service (USDA-ARS) Fort Collins Colorado USA.
² Department of Agricultural Biology Colorado State University Fort Collins Colorado USA.
³ Department of Plant, Soil, and Microbial Sciences Michigan State University East Lansing Michigan USA.
⁴ Department of Plants, Soils & Climate Utah State University Logan Utah USA.

Abstract

Auxin-mimic herbicides chemically mimic the phytohormone indole-3-acetic-acid (IAA). Within the auxin-mimic herbicide class, the herbicide fluroxypyr has been extensively used to control kochia (Bassia scoparia). A 2014 field survey for herbicide resistance in kochia populations across Colorado identified a putative fluroxypyr-resistant (Flur-R) population that was assessed for response to fluroxypyr and dicamba (auxin-mimics), atrazine (photosystem II inhibitor), glyphosate (EPSPS inhibitor), and chlorsulfuron (acetolactate synthase inhibitor). This population was resistant to fluroxypyr and chlorsulfuron but sensitive to glyphosate, atrazine, and dicamba. Subsequent dose-response studies determined that Flur-R was 40 times more resistant to fluroxypyr than a susceptible population (J01-S) collected from the same field survey (LD₅₀ 720 and 20 g ae ha^-1, respectively). Auxin-responsive gene expression increased following fluroxypyr treatment in Flur-R, J01-S, and in a dicamba-resistant, fluroxypyr-susceptible line 9,425 in an RNA-sequencing experiment. In Flur-R, several transcripts with molecular functions for conjugation and transport were constitutively higher expressed, such as glutathione S-transferases (GSTs), UDP-glucosyl transferase (GT), and ATP binding cassette transporters (ABC transporters). After analyzing metabolic profiles over time, both Flur-R and J01-S rapidly converted [¹⁴C]-fluroxypyr ester, the herbicide formulation applied to plants, to [¹⁴C]-fluroxypyr acid, the biologically active form of the herbicide, and three unknown metabolites. The formation and flux of these metabolites were faster in Flur-R than J01-S, reducing the concentration of phytotoxic fluroxypyr acid. One unique metabolite was present in Flur-R that was not present in the J01-S metabolic profile. Gene sequence variant analysis specifically for auxin receptor and signaling proteins revealed the absence of non-synonymous mutations affecting auxin signaling and binding in candidate auxin target site genes, further supporting our hypothesis that non-target site metabolic degradation is contributing to fluroxypyr resistance in Flur-R.

Keywords: NTSR; herbicide resistance; synthetic auxin.