Rational conversion of substrate and product specificity in a Salvia monoterpene synthase: structural insights into the evolution of terpene synthase function.

Terpene synthases are responsible for the biosynthesis of the complex chemical defense arsenal of plants and microorganisms. How do these enzymes, which all appear to share a common terpene synthase fold, specify the many different products made almost entirely from one of only three substrates? Elucidation of the structure of 1,8-cineole synthase from Salvia fruticosa (Sf-CinS1) combined with analysis of functional and phylogenetic relationships of enzymes within Salvia species identified active-site residues responsible for product specificity. Thus, Sf-CinS1 was successfully converted to a sabinene synthase with a minimum number of rationally predicted substitutions, while identification of the Asn side chain essential for water activation introduced 1,8-cineole and alpha-terpineol activity to Salvia pomifera sabinene synthase. A major contribution to product specificity in Sf-CinS1 appears to come from a local deformation within one of the helices forming the active site. This deformation is observed in all other mono- or sesquiterpene structures available, pointing to a conserved mechanism. Moreover, a single amino acid substitution enlarged the active-site cavity enough to accommodate the larger farnesyl pyrophosphate substrate and led to the efficient synthesis of sesquiterpenes, while alternate single substitutions of this critical amino acid yielded five additional terpene synthases.

Study of the mechanisms of cigarette smoke gas phase cytotoxicity.

BACKGROUND: The cytotoxicity of cigarette smoke (CS) in humans is well-documented, but the mechanism behind CS toxicity and carcinogenicity remains unknown. We are interested in the toxicological effects of CS gas phase and the biological mechanisms of its action. MATERIALS AND METHODS: Gas phase CS cytotoxicity was measured by Wst-1 and LDH assays, in cultured cells. The mechanism of cell death was investigated by flow cytometric analysis using Annexin V and PI staining. Gas phase CS-induced oxidative damage was evaluated by estimating cellular glutathione (GSH) levels. Protein modifications (nitration of tyrosines) induced by gas phase CS and activation of key signalling proteins (Mitogen-activated protein kinase, MAPK) were detected by immunoblotting. RESULTS: The cytotoxicity of gas phase CS was found to be dose-dependent. The mechanism of cell death was found to be both apoptotic and necrotic depending on the concentrations used. Exposure to gas phase CS resulted in depletion of cellular GSH levels, increased nitrotyrosine immunoreactivity and phosphorylation of p44/42 MAPK proteins. CONCLUSION: These results suggest that the CS gas phase alone contributes significantly to the deleterious effects of CS in cellular systems.