Abstract
Brassinosteroids (BRs) are steroid hormones of plants that coordinate fundamental growth and development processes. Their homeostasis is controlled by diverse means, including glucosylation of the bioactive BR brassinolide (BL), which is catalyzed by the UDP-glycosyltransferases (UGTs) UGT73C5 and UGT73C6 and occurs mainly at the C-23 position. Additional evidence had suggested that the resultant BL-23-O-glucoside (BL-23-O-Glc) can be malonylated, but the physiological significance of and enzyme required for this reaction had remained unknown. Here, we show that in Arabidopsis thaliana malonylation of BL-23-O-Glc is catalyzed by the acyltransferase phenolic glucoside malonyl-transferase 1 (PMAT1), which is also known to malonylate phenolic glucosides and lipid amides. Loss of PMAT1 abolished BL-23-O-malonylglucoside formation and enriched BL-23-O-Glc, showing that the enzyme acts on the glucoside. An overexpression of PMAT1 in plants where UGT73C6 was also overexpressed, and thus, BL-23-O-Glc formation was promoted, enhanced the symptoms of BR-deficiency of UGT73C6oe plants, providing evidence that PMAT1 contributes to BL inactivation. Based on these results, a model is proposed in which PMAT1 acts in the conversion of both endogenous and xenobiotic glucosides to adjust metabolic homeostasis in spatial and temporal modes.
Highlights
Homeostasis of steroids must be controlled to allow for proper development, and catabolic inactivation by glycosylation plays a vital role in this process
Steroid hormone glycosides can serve as storage forms, because the bioactive hormones can be reactivated by the action of βglucuronidases (1, 2)
The precise adjustment of BR homeostasis is of equal importance
Summary
Overexpression of PMAT1 in a background in which the UDP-glucosyltransferase UGT73C6 was overexpressed, and BR-glucoside levels were elevated, increased BL-MalGlc amounts, and enhanced symptoms of BR-deficiency in UGT73C6oe plants, providing evidence that malonylation of BL-Glc decreased BL bioavailability. The generated lines were used to test, if altering PMAT1 or At5MAT mRNA abundance may impact the BL23-O-Glc malonylation capacities of plants.
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