Yannick Batard

Regulation of the Cinnamate 4-Hydroxylase (CYP73A1) in Jerusalem Artichoke Tubers in Response to Wounding and Chemical Treatments

trans-Cinnamate 4-hydroxylase (C4H) is a plant-specific cytochrome (P450) that is encoded by the gene CYP73A and catalyzes the second step of the multibranched phenylpropanoid pathway. Increases in C4H activity in response to physical and chemical stresses have been well documented, but the mechanism of these increases has never been studied in detail. This paper reports on the regulatory mechanism controlling C4H activity in Jerusalem artichoke (Helianthus tuberosus) tubers in response to wounding and chemical treatments. We compared induction of C4H and other P450-catalyzed activities. C4H was moderately induced by chemicals relative to other P450s. Increases in enzyme activity, C4H protein, and transcripts were quantified and compared in tuber tissue 48 h after wounding and chemical treatments. Our data suggest that induction of the enzyme activity results primarily from gene activation. Time-course experiments were performed after wounding and aminopyrine treatment. Compared with wounded tissues, aminopyrine triggered an additional and delayed peak of transcript accumulation. The timing of the induced changes in activity, protein, and transcripts confirms that C4H induction results primarily from an increase in CYP73A1 mRNA, in both wounded and aminopyrine-treated tissues. However, posttranscriptional mechanisms might also contribute to the regulation of C4H activity.

Monospecific Polyclonal Antibodies Directed against Purified Cinnamate 4-Hydroxylase from Helianthus tuberosus (Immunopurification, Immunoquantitation, and Interspecies Cross-Reactivity)

We recently reported the purification of cinnamic acid 4-hydroxylase (CA4H), a cytochrome P-450 catalyzing the second reaction of the general phenylpropanoid pathway, from Jerusalem artichoke (Helianthus tuberosus L.) (B. Gabriac, D. Werck-Reichhart, H. Teutsch, F. Durst [1991] Arch Biochem Biophys 288: 302–309). Rabbit polyclonal antibodies were raised against the native and denaturated nitrocellulose-bound enzyme. Only the immunoglobulins G (IgGs) elicited upon immunization with native enzyme produced strong inhibition of catalytic activity and good cross-reactivity on western blots. In microsomes from H. tuberosus tissues induced by wounding and various chemicals, a positive correlation between catalytic activity and amounts of immuno-reactive protein on western blots was observed. When coupled to cyanogen bromide-activated Sepharose, purified IgGs selectively retained CA4H activity from solubilized plant microsomes. Acid elution from the immunoaffinity matrix provided a rapid procedure for high-yield purification of the CA4H protein. The same IgGs immunoprecipitated a single protein from the in vitro translation products of mRNA isolated from wounded tissues. The apparent molecular weight (57,000) of this polypeptide was identical to that of CA4H purified from tuber microsomes. Immunochemical relatedness between CA4H from different plant species was demonstrated by strong inhibition of catalytic activity and immunopurification of several orthologous enzymes, using IgGs directed against CA4H from H. tuberosus. However, only limited interspecies cross-reactivity was observed on western blots. A careful immunochemical analysis indicates that CA4H immunoreactivity significantly differs from plant to plant. Results are discussed in terms of antibody specificity, enzyme glycosylation, and CA4H regulation.

Xenobiotics: Substrates and inhibitors of the plant cytochrome P450

The ability of a plant cytochrome P450 to bind and metabolise plant endogenous molecules and xenobiotics was investigated. The work was performed on the yeast-expressed CYP73A1, a cinnamate 4-hydroxylase isolated fromHelianthus tuberosus. CYP73 controls the general phenylpropanoid pathway and is likely to be one of the most abundant sources of P450 in the biosphere. The enzyme shows a high selectivity toward plant secondary metabolites. Nevertheless, it oxygenates several small and planar xenobiotics with low efficiency, including an herbicide (chlorotoluron). One xenobiotic molecule, 2naphthoic acid, is hydroxylated with an efficiency comparable to that of the physiological substrate. This reaction was used to devise a fluorimetric test for the rapid measurement of enzyme activity. A series of herbicidal molecules (hydroxybenzonitriles) are shown to bind the active site without being metabolised. These molecules behave as strong competitive inhibitors of CYP73 with a Ki in the same micromolar range as the Km for the physiological substrate. It is proposed that their inhibition of the phenylpropanoid pathway reinforces their other phytotoxic effects at the level of the chloroplasts. All our results indicate a strong reciprocal interaction between plant P450s and xenobiotics.