Abstract

Arabidopsis (Arabidopsis thaliana) siliques synthesize high levels of benzoic acid (BA), which is incorporated into several glucosinolate compounds. The origin of BA in the siliques has not yet been determined. Here, we show that siliques have higher levels of benzaldehyde (BD)-oxidizing activity relative to leaves. The BD-oxidizing activity was purified from siliques in several chromatographic steps, and a 145-kD protein was identified as the enzyme most likely to possess this activity. The protein was trypsinized, and the sequence of the resulting peptides was determined by mass spectrometry, identifying it as the product of gene At1g04580, also designated as AAO4 (for ARABIDOPSIS ALDEHYDE OXIDASE4). AAO4 had previously been shown to be highly and specifically expressed in developing seeds, and its protein was shown to belong to a family of aldehyde oxidases. Here, we show that the AAO4 protein is an aldehyde oxidase that can use several substrates but that, among the substrates tested, has the lowest K(m) value (23 microm) with BD. AAO4 is able to oxidize BD without NAD(+), but its activity increases by 50% when this cofactor is added. The pH optimum of AAO4 is 7.0. Plants homozygous for a null allele in AAO4 showed a reduction of 30% to 45% in the total levels of BA in seeds as well as 7% to 9% and 32% to 38% decreases in the levels of 3-benzoyloxypropylglucosinolate and 4-benzoyloxybutylglucosinolate, respectively. Expressing AAO4 in Escherichia coli resulted in a 3-fold increase of BD-oxidizing activity in crude bacterial extracts over endogenous levels. These findings indicate that in Arabidopsis seeds, oxidation of BD contributes in part to the synthesis of BA.

Highlights

  • Arabidopsis (Arabidopsis thaliana) siliques synthesize high levels of benzoic acid (BA), which is incorporated into several glucosinolate compounds

  • We further show that at least some of this activity resides in a 145-kD protein, designated ARABIDOPSIS ALDEHYDE OXIDASE4 (AAO4), that belongs to a previously characterized family of aldehyde oxidases, some of which may be involved in the biosyntheses of indole-3-acetic acid (Koiwai et al, 2000) and abscisic acid (Seo et al, 1998)

  • Protein extracts from Arabidopsis siliques of aao4-1 and aao4-2 showed a decrease BD-oxidizing activity by 30% to 45% as compared with protein extract of wild-type plants (Fig. 7)

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Summary

Introduction

Arabidopsis (Arabidopsis thaliana) siliques synthesize high levels of benzoic acid (BA), which is incorporated into several glucosinolate compounds. AAO4 had previously been shown to be highly and expressed in developing seeds, and its protein was shown to belong to a family of aldehyde oxidases. Expressing AAO4 in Escherichia coli resulted in a 3-fold increase of BD-oxidizing activity in crude bacterial extracts over endogenous levels. These findings indicate that in Arabidopsis seeds, oxidation of BD contributes in part to the synthesis of BA. Arabidopsis (Arabidopsis thaliana) plants synthesize a set of defense compounds of the glucosinolate class throughout the plant (Graser et al, 2001) Two such glucosinolates, 3-benzoyloxypropylglucosinolate (3BZO) and 4-benzoyloxybutylglucosinolate (4BZO), contain a benzoyl moiety. T-DNA insertions that eliminate functional transcripts of At1g04580 cause decreases in the levels of total BA and in the levels of benzoylated glucosinolates in seeds

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