Benzoyl-CoA:anthranilate N-benzoyltransferase catalyzes the first committed reaction of phytoalexin biosynthesis in carnation (Dianthus caryophyllus L.), and the product N-benzoylanthranilate is the precursor of several sets of dianthramides. The transferase activity is constitutively expressed in suspension-cultured carnation cells and can be rapidly induced by the addition of yeast extract. The enzyme was purified to homogeneity from yeast-induced carnation cells and shown to consist of a single polypeptide chain of 53 kDa. Roughly 20% of the sequence was identified by micro-sequencing of tryptic peptides, and some of these sequences differed in a few amino acid residues only suggesting the presence of isoenzymes. A specific 0.8 kb cDNA probe was generated by RT-PCR, employing degenerated oligonucleotide primers complementary to two of the tryptic peptides and using poly(A)+ RNA from elicited carnation cells. Five distinct benzoyltransferase clones were isolated from a cDNA library, and three cDNAs, pchcbt1-3, were sequenced and shown to encode full-size N-benzoyltransferases. The translated peptide sequences revealed more than 95% identity among these three clones. The additional two clones harbored insert sequences mostly homologous with pchcbt 1 but differing in the 3'-flanking regions due to variable usage of poly(A) addition sites. The identity of the clones was confirmed by matching the translated polypeptides with the tryptic enzyme sequences as well as by the activity of the benzoyltransferase expressed in Escherichia coli. Therefore, carnation encodes a small family of anthranilate N-benzoyltransferase genes. In vitro, the benzoyltransferases exhibited narrow substrate specificity for anthranilate but accepted a variety of aromatic acyl-CoAs. Catalytic rates with cinnamoyl- or 4-coumaroyl-CoA exceeded those observed with benzoyl-CoA, although the corresponding dianthramides did not accumulate in vivo. Thus the cDNAs described represent also the first hydroxycinnamoyl-transferases cloned from plants, which classifies the enzymes as hydroxycinnamoyl/benzoyltransferases.
Cell suspension cultures of carnation (Ditr~?~hus ccrr~~~p/~~//~.s L.) accumulate, upon challenge with crude fungal elicitor, various dianthramide phytoalexins, all of which derive from N-benzoylanthranilate. In vitro, microsomes from the elicited carnation cells hydroxylated N-benzoylanthranilate in the 4-and/or 2'-positions to yield the hydroxyanthranilate and/or salicyloyl derivatives. 2'-Hydroxylation was shown to precede 4-hydroxylation in the formation of N-salicyloyl-4-hydroxyanthranilate, and both these activities depended strictly on NADPH and molecular oxygen. 4-Hydroxylation was shown to be catalyzed by cytochrome P-450-dependent monooxygenase(s), whereas the 2'-hydroxylating activity appeared to be due to a novel class of enzymes. also responding synergistically to NADH in combination with NADPH and showing apparent inhibition by cytochromc (' but not by carbon monoxide. The difference in type of 4-and 2'-hydroxylases was corroborated by the exclusive inhibition of either activity in imidazolc vs. MOPS buffers as well as their differential heat sensitivities. In the course of these studies, low concentrations of N-salicyloylanthranilatc turned out to inhibit the cytochrome P-4SO-dependent 4-hydroxylation more strongly than any of the commercial inhibitor chemicals tested, while neither the substrate, N-benzoylanthrdnilate, nor the final product, Ksalicyloyl-4_hydroxyanthranilate, exhibited such signkant inhibition. In addition, 2'-hydroxylation activity was affected much less by N-benzoyianthranilate, N-salicyloylanthranilate or by inhibitor chemicals. The results demonstrate the requirement of two different classes of hydroxylase activities that appear to introduce the antimycotic quality to the dianthramides for phytoalexin defense.Dicmlhrrs ccrr~vph~~lhrs cell culture; carnation phytoalexin; ortho-and parahydroxylations
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