Gene mutations conferring herbicide resistance are hypothesized to have negative pleiotropic effects on plant growth and fitness, which may in turn determine the evolutionary dynamics of herbicide resistance alleles. We used the widespread, annual, diploid grass weed Alopecurus aequalis as a model species to investigate the effect of two resistance mutations—the rare Pro-197-Tyr mutation and the most common mutation, Trp-574-Leu—on acetolactate synthase (ALS) functionality and plant growth. We characterized the enzyme kinetics of ALS from two purified A. aequalis populations, each homozygous for the resistance mutation 197-Tyr or 574-Leu, and assessed the pleiotropic effects of these mutations on plant growth. Both mutations reduced sensitivity of ALS to ALS-inhibiting herbicides without significant changes in extractable ALS activity. The 197-Tyr mutation slightly decreased the substrate affinity (corresponding to an increased Km for pyruvate) and maximum reaction velocity (Vmax) of ALS, whereas the 574-Leu mutation significantly increased these kinetics. Significant decrease or increase in plant growth associated, respectively, with the 197-Tyr and 574-Leu resistance mutations was highly correlated with their impact on ALS kinetics, suggesting more likely persistence of the 574-Leu mutation than the 197-Tyr mutation if herbicide application is discontinued.
Aegilops tauschii Coss.
is a malignant
weed in wheat fields in China, its herbicide resistance has been threatening
crop production. This study identified one mesosulfuron-methyl-resistant(R)
population, JJMHN2018-05 (R), without target resistance mutations.
To fully understand the resistance mechanism, non-target site resistance
was investigated by using transcriptome sequencing combined with a
reference genome. Results showed that the cytochrome P450 monooxygenase
(P450) inhibitor malathion significantly increased the mesosulfuron-methyl
sensitivity in R plants, and greater herbicide-induced glutathione
S-transferase (GST) activity was also confirmed. Liquid chromatography
with tandem mass spectrometry analysis further supported the enhanced
mesosulfuron-methyl metabolism in R plants. Gene expression data analysis
and qRT-PCR validation indicated that eight P450s, six GSTs, two glycosyltransferases
(GTs), four peroxidases, and one aldo-keto reductase (AKRs) stably
upregulated in R plants. This research demonstrates that the P450s
and GSTs involved in enhanced mesosulfuron-methyl metabolism contribute
to mesosulfuron-methyl resistance in A. tauschii and identifies potential contributors from metabolic enzyme families.
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