X-ray structure of potato epoxide hydrolase sheds light on substrate specificity in plant enzymes.

Epoxide hydrolases catalyze the conversion of epoxides to diols. The known functions of such enzymes include detoxification of xenobiotics, drug metabolism, synthesis of signaling compounds, and intermediary metabolism. In plants, epoxide hydrolases are thought to participate in general defense systems. In the present study, we report the first structure of a plant epoxide hydrolase, one of the four homologous enzymes found in potato. The structure was solved by molecular replacement and refined to a resolution of 1.95 A. Analysis of the structure allows a better understanding of the observed substrate specificities and activity. Further, comparisons with mammalian and fungal epoxide hydrolase structures reported earlier show the basis of differing substrate specificities in the various epoxide hydrolase subfamilies. Most plant enzymes, like the potato epoxide hydrolase, are expected to be monomers with a preference for substrates with long lipid-like substituents of the epoxide ring. The significance of these results in the context of biological roles and industrial applications is discussed.

Implications for an ionized alkyl-enzyme intermediate during StEH1-catalyzed trans-stilbene oxide hydrolysis.

The catalytic mechanism of epoxide hydrolase (EC 3.3.2.3) involves acid-assisted ring opening of the oxirane during the alkylation half-reaction of hydrolysis. Two tyrosyl residues in the active site of epoxide hydrolases have been shown to contribute to the catalysis of enzyme alkylation, but their mechanism of action has not been fully described. We have investigated the involvement of the active site Tyr154 and Tyr235 during S,S-trans-stilbene oxide hydrolysis catalyzed by potato epoxide hydrolase StEH1. Tyr phenol ionizations of unliganded enzyme as well as under pre-steady-state conditions during catalysis were studied by direct absorption spectroscopy. A transient UV absorption, indicative of tyrosinate formation, was detected during the lifetime of the alkyl-enzyme intermediate. The apparent pKa of Tyr ionization was 7.3, a value more than 3 pH units below the estimated pKa of protein Tyr residues in the unliganded enzyme. In addition, the pH dependencies of microscopic kinetic rates of catalyzed S,S-trans-stilbene oxide hydrolysis were determined. The alkylation rate increased with pH and displayed a pKa value identical to that of Tyr ionization (7.3), whereas the reverse (epoxidation) reaction did not display any pH dependence. The rate of alkyl-enzyme hydrolysis was inversely dependent on tyrosinate formation, decreasing with its buildup in the active site. Since alkyl-enzyme hydrolysis is the rate-limiting step of the overall reaction, kcat displayed the same decrease with pH as the hydrolysis rate. The compiled results suggested that the role of the Tyr154/Tyr235 pair was not as ultimate proton donor to the alkoxide anion but to stabilize the negatively charged alkyl-enzyme through electrophilic catalysis via hydrogen bonding.

Catalysis of potato epoxide hydrolase, StEH1.

The kinetic mechanism of epoxide hydrolase (EC 3.3.2.3) from potato, StEH1 (Solanum tuberosum epoxide hydrolase 1), was studied by presteady-state and steady-state kinetics as well as by pH dependence of activity. The specific activities towards the different enantiomers of TSO (trans-stilbene oxide) as substrate were 43 and 3 micromol x min(-1) x mg(-1) with the R,R- or S,S-isomers respectively. The enzyme was, however, enantioselective in favour of the S,S enantiomer due to a lower K(m) value. The pH dependences of kcat with R,R or S,S-TSO were also distinct and supposedly reflecting the pH dependences of the individual kinetic rates during substrate conversion. The rate-limiting step for TSO and cis- and trans-epoxystearate was shown by rapid kinetic measurements to be the hydrolysis of the alkylenzyme intermediate. Functional characterization of point mutants verified residues Asp105, Tyr154, Tyr235 and His300 as crucial for catalytic activity. All mutants displayed drastically decreased enzymatic activities during steady state. Presteady-state measurements revealed the base-deficient H300N (His300-->Asn) mutant to possess greatly reduced efficiencies in catalysis of both chemical steps (alkylation and hydrolysis).

The Saccharomyces cerevisiae ORF YNR064c protein has characteristics of an 'orphaned' epoxide hydrolase.

The open reading frame YNR064c in Saccharomyces cerevisiae encodes a protein tentatively assigned as similar to a bacterial dehalogenase. In this study we conclude that the YNR064c protein displays characteristics of an epoxide hydrolase belonging to the alpha/beta-hydrolase fold family of enzymes. Endogenous expression of the protein in S. cerevisiae was confirmed and a His-tagged variant of the protein was heterologously expressed in both Escherichia coli and Pichia pastoris for isolation and characterization. The YNR064c protein displayed low but reproducible epoxide hydrolase activity with racemic phenanthrene 9,10-oxide and trans- or cis-stilbene oxide. Phylogenetic analysis of related gene products found in various microorganisms suggested that the YNR064c protein is a member of a new subclass of alpha/beta-hydrolase fold enzymes.