Transcriptome changes in chlorsulfuron-treated plants are caused by acetolactate synthase inhibition and not induction of a herbicide detoxification system in Marchantia polymorpha

Abstract

AbstractA sensing mechanism in mammals perceives xenobiotics and induces the transcription of genes encoding proteins that detoxify these molecules. However, it is unclear if plants sense xenobiotics, and activate an analogous signalling system leading to their detoxification. Using the liverwort Marchantia polymorpha, we tested the hypothesis that there is a sensing system in plants that perceives herbicides resulting in the increased transcription of genes encoding proteins that detoxify these herbicides. Consistent with the hypothesis, we show that chlorsulfuron-treatment induces changes in the M. polymorpha transcriptome. However, these transcriptome changes do not occur in chlorsulfuron (CS)-treated target site resistant mutants, where the gene encoding the target carries a mutation that confers resistance to chlorsulfuron. Instead, we show that inactivation of the chlorsulfuron target, acetolactate synthase (ALS) (also known as acetohydroxyacid synthase (AHAS)), is required for the transcriptome response. These data are consistent with the changes in the transcriptome of chlorsulfuron-treated plants being caused by disrupted amino acid synthesis and metabolism resulting from acetolactate synthase inhibition. These conclusions suggest that chlorsulfuron is not sensed in M. polymorpha leading to induce a detoxification system.Author SummaryHerbicide use is increasing throughout the world, however we know little about how plants respond to herbicide treatment and regulate their metabolism. Some plants have evolved resistance to herbicides such as chlorsulfuron by increasing the detoxification of the herbicide compared to sensitive plants. It has been suggested that plants can directly sense the herbicide chemical which activates a detoxification response, in a similar way to the detoxification of foreign chemicals in mammalian cells. The liverwort Marchantia polymorpha is an excellent system to study plant herbicide responses due to its short generation time, ease of propagation and low genetic redundancy. We show that chlorsulfuron treatment alters the expression of many genes in M. polymorpha, however plants with a resistance-conferring mutation in the molecular target of chlorsulfuron do not show any changes in gene expression in response to chlorsulfuron treatment. This result indicates that transcriptome changes caused by chlorsulfuron depend on the inhibition of the target by chlorsulfuron. This suggests that plants do not sense chlorsulfuron and activate a detoxification system. This finding has implications for herbicide use and discovery.