Structure of trichodiene synthase from Fusarium sporotrichioides provides mechanistic inferences on the terpene cyclization cascade.

The x-ray crystal structure of recombinant trichodiene synthase from Fusarium sporotrichioides has been determined to 2.5-A resolution, both unliganded and complexed with inorganic pyrophosphate. This reaction product coordinates to three Mg(2+) ions near the mouth of the active site cleft. A comparison of the liganded and unliganded structures reveals a ligand-induced conformational change that closes the mouth of the active site cleft. Binding of the substrate farnesyl diphosphate similarly may trigger this conformational change, which would facilitate catalysis by protecting reactive carbocationic intermediates in the cyclization cascade. Trichodiene synthase also shares significant structural similarity with other sesquiterpene synthases despite a lack of significant sequence identity. This similarity indicates divergence from a common ancestor early in the evolution of terpene biosynthesis.

Crystal structure determination of aristolochene synthase from the blue cheese mold, Penicillium roqueforti.

The 2.5-A resolution crystal structure of recombinant aristolochene synthase from the blue cheese mold, Penicillium roqueforti, is the first of a fungal terpenoid cyclase. The structure of the enzyme reveals active site features that participate in the cyclization of the universal sesquiterpene cyclase substrate, farnesyl diphosphate, to form the bicyclic hydrocarbon aristolochene. Metal-triggered carbocation formation initiates the cyclization cascade, which proceeds through multiple complex intermediates to yield one exclusive structural and stereochemical isomer of aristolochene. Structural homology of this fungal cyclase with plant and bacterial terpenoid cyclases, despite minimal amino acid sequence identity, suggests divergence from a common, primordial ancestor in the evolution of terpene biosynthesis.

Chemical rescue by guanidine derivatives of an arginine-substituted site-directed mutant of Escherichia coli ornithine transcarbamylase.

Escherichia coli ornithine transcarbamylase (OTCase) catalyzes the production of L-citrulline and phosphate from carbamyl phosphate and L-ornithine in L-arginine biosynthesis. We show that exogenous guanidines can restore activity to (chemically rescue) a catalytically-impaired site-directed mutant OTCase, R57G, in which glycine replaces an an active site arginine. The best rescue agent is guanidine hydrochloride, which enhances the rate of the mutant 2000-fold. The turnover number for the guanidine-rescued R57G mutant is 10% that of wild-type. The addition of guanidine to the R57G mutant has little effect on KMCP values, and the rescue effect is therefore attributed principally to an increase in kcat. Other compounds were screened as potential rescue agents, but rate enhancement is highly selective for guanidines. Not all guanidines show large increases in kcat. For a comparative series that includes guanidine and alkylguanidines, substituent size is inversely related to kcat. Brønsted analysis of guanidines with varying pKa values indicates that a partial positive charge is implicated in rescue, consistent with the proposed role of arginine 57 in catalysis. In UV difference and 31P-NMR spectra, carbamyl phosphate-induced effects associated with wild-type OTCase are observed in the R57G mutant only in the presence of guanidine. The kinetic mechanism of the mutant is random in the presence or absence of guanidine, in contrast to the sequential ordered mechanism of the wild-type enzyme. Thus, chemical rescue of R57G by guanidine hydrochloride restores many but not all wild-type properties to the mutant enzyme.