Acridone alkaloids formed by acridone synthase in Ruta graveolens L. are composed of N ‐methylanthraniloyl CoA and malonyl CoAs. A 1095 bp cDNA from elicited Ruta cells was expressed in Escherichia coli , and shown to encode S‐ adenosyl‐l ‐methionine‐dependent anthranilate N ‐methyltransferase. SDS–PAGE of the purified enzyme revealed a mass of 40 ± 2 kDa, corresponding to 40 059 Da for the translated polypeptide, whereas the catalytic activity was assigned to a homodimer. Alignments revealed closest relationships to catechol or caffeate O ‐methyltransferases at 56% and 55% identity (73% similarity), respectively, with little similarity (∼20%) to N ‐methyltransferases for purines, putrescine, glycine, or nicotinic acid substrates. Notably, a single Asn residue replacing Glu that is conserved in caffeate O ‐methyltransferases determines the catalytic efficiency. The recombinant enzyme showed narrow specificity for anthranilate, and did not methylate catechol, salicylate, caffeate, or 3‐ and 4‐aminobenzoate. Moreover, anthraniloyl CoA was not accepted. As Ruta graveolens acridone synthase also does not accept anthraniloyl CoA as a starter substrate, the anthranilate N ‐methylation prior to CoA activation is a key step in acridone alkaloid formation, channelling anthranilate from primary into secondary branch pathways, and holds promise for biotechnological applications. RT‐PCR amplifications and Western blotting revealed expression of the N ‐methyltransferase in all organs of Ruta plants, particularly in the flower and root, mainly associated with vascular tissues. This expression correlated with the pattern reported previously for expression of acridone synthase and acridone alkaloid accumulation.

The seeds of most members of the Brassicaceae accumulate high amounts of sinapine (sinapoylcholine) that is rapidly hydrolyzed during early stages of seed germination. One of three isoforms of sinapine esterase activity (BnSCE3) has been isolated from Brassica napus seedlings and subjected to trypsin digestion and spectrometric sequencing. The peptide sequences were used to isolate BnSCE3 cDNA, which was shown to contain an open reading frame of 1170 bp encoding a protein of 389 amino acids, including a leader peptide of 25 amino acids. Sequence comparison identified the protein as the recently cloned BnLIP2, i.e. a GDSL lipase‐like protein, which displays high sequence identity to a large number of corresponding plant proteins, including four related Arabidopsis lipases. The enzymes belong to the SGNH protein family, which use a catalytic triad of Ser‐Asp‐His, with serine as the nucleophile of the GDSL motif. The corresponding B. napus and Arabidopsis genes were heterologously expressed in Nicotiana benthamiana leaves and proved to confer sinapine esterase activity. In addition to sinapine esterase activity, the native B. napus protein (BnSCE3/BnLIP2) showed broad substrate specificity towards various other choline esters, including phosphatidylcholine. This exceptionally broad substrate specificity, which is common to a large number of other GDSL lipases in plants, hampers their functional analysis. However, the data presented here indicate a role for the GDSL lipase‐like BnSCE3/BnLIP2 as a sinapine esterase in members of the Brassicaceae, catalyzing hydrolysis of sinapine during seed germination, leading, via 1‐O ‐sinapoyl‐β‐glucose, to sinapoyl‐l ‐malate in the seedlings.

Members of the Brassicaceae family accumulate specific sinapate esters, i.e. sinapoylcholine (sinapine), which is considered as a major antinutritive compound in seeds of important crop plants like Brassica napus , and sinapoylmalate, which is implicated in UV‐B tolerance in leaves. We have studied the molecular regulation of the sinapate ester metabolism in B. napus , and we describe expression of genes, some properties of the encoded proteins and profiles of the metabolites and enzyme activities. The cloned cDNAs encoding the key enzymes of sinapine biosynthesis, UDP‐glucose (UDP‐Glc):B. napus sinapate glucosyltransferase (BnSGT1) and sinapoylglucose:B. napus choline sinapoyltransferase (BnSCT), were functionally expressed. BnSGT1 belongs to a subgroup of plant GTs catalysing the formation of 1‐O‐hydroxycinnamoyl‐β‐d ‐glucoses. BnSCT is another member of serine carboxypeptidase‐like (SCPL) family of acyltransferases. The B. napus genome contains at least two SGT and SCT genes, each derived from its progenitors B. oleracea and B. rapa . BnSGT1 and BnSCT activities are subjected to pronounced transcriptional regulation. BnSGT1 transcript level increases throughout early stages of seed development until the early cotyledonary stage, and stays constant in later stages. The highest level of BnSGT1 transcripts is reached in 2‐day‐old seedlings followed by a dramatic decrease. In contrast, expression of BnSCT is restricted to developing seeds. Regulation of gene expression at the transcript level seems to be responsible for changes of BnSGT1 and BnSCT activities during seed and seedling development of B. napus . Together with sinapine esterase (SCE) and sinapoylglucose:malate sinapoyltransferase (SMT), activities of BnSGT1 and BnSCT show a close correlation with the accumulation kinetics of the corresponding metabolites.