Unraveling terminal C-domain-mediated condensation in fungal biosynthesis of imidazoindolone metabolites.

The fungal peptidyl alkaloids of the tryptoquialanine and fumiquinazoline families are nonribosomally assembled by annulation of the indole side chain of fumiquinazoline F (FQF) with an alaninyl or aminoisobutyryl unit by monomodular NRPS enzymes containing adenylation, thiolation, and condensation (A-T-C) domains. The Af12060 and Af12050 enzyme pair from Aspergillus fumigatus thereby converts FQF to FQA, while the homologous TqaH and TqaB enzyme pair from Penicillium aethiopicum makes the 2'-epi diastereomer of FQA, differing only in the stereochemistry of one of the C-N bonds formed in the annulation with l-Ala. To evaluate the basis for this stereochemical control, we have mixed and matched the flavoprotein oxygenases Af12060 and TqaH with the A-T-C modular enzymes Af12050 and TqaB to show that the NRPS enzymes control the stereochemical outcome. The terminal 50 kDa condensation domains of Af12050 and TqaB are solely responsible for the stereochemical control as shown both by making chimeric (e.g., A-T-C* and A*-T*-C) forms of these monomodular NRPS enzymes and by expression, purification, and assay of the excised C-domains. The Af12050 and TqaB condensation domains are thus a paired set of diastereospecific annulation catalysts that act on the fumiquinazoline F scaffold.

Designing new Baeyer-Villiger monooxygenases using restricted CASTing.

This paper outlines the design and execution of the first mini-evolution of cyclopentanone monooxygenase (CPMO). The methodology described is a relatively inexpensive and rapid way to obtain mutant enzymes with the desired characteristics. Several successful mutants with enhanced enantioselectivities were identified. For example, mutant-catalyzed oxidation of 4-methoxycyclohexanone gave the corresponding lactone with 92% entantiometric excess (ee) compared to the 46% ee achieved with wild-type cyclohexanone monoxygenase (WT-CHMO). The original design of the mini-evolution and the following evaluation of mutants can provide valuable insights into the active site's construction and dynamics and can suggest other catalytically profitable mutations within the putative active site.

Metabolic engineering of monoterpene biosynthesis: two-step production of (+)-trans-isopiperitenol by tobacco.

Monoterpenoid biosynthesis in tobacco was modified by introducing two subsequent enzymatic activities targeted to different cell compartments. A limonene-3-hydroxylase (lim3h) cDNA was isolated from Mentha spicata L. 'Crispa'. This cDNA was used to re-transform a transgenic Nicotiana tabacum'Petit Havana' SR1 (tobacco) line expressing three Citrus limon L. Burm. f. (lemon) monoterpene synthases producing (+)-limonene, gamma-terpinene and (-)-beta-pinene as their main products. The targeting sequences of these synthases indicate that they are probably localized in the plastids, whereas the sequence information of the P450 hydroxylase indicates targeting to the endoplasmatic reticulum. Despite the different location of the enzymes, the introduced P450 hydroxylase proved to be functional in the transgenic plants as it hydroxylated (+)-limonene, resulting in the emission of (+)-trans-isopiperitenol. Some further modifications of the (+)-trans-isopiperitenol were also detected, resulting in the additional emission of 1,3,8-p-menthatriene, 1,5,8-p-menthatriene, p-cymene and isopiperitenone.

Preparation and kinetic properties of 5-ethylphenazine-lactate-dehydrogenase-NAD+ conjugate, a semisynthetic lactate oxidase showing a hide-and-seek effect.

5-Ethylphenazine-lactate-dehydrogenase-NAD+ conjugate (EP(+)-LDH-NAD+) was prepared by linking poly(ethylene glycol)-bound 5-ethylphenazine and poly(ethylene glycol)-bound NAD+ to lactate dehydrogenase. The average number of the ethylphenazine moieties bound per molecule of enzyme subunit was 0.46, and that of the NAD+ moieties was 0.32. This conjugate is a semisynthetic enzyme having lactate oxidase activity using oxygen or 3-(4,5-dimethyl-2-thiazolyl)-2,5-diphenyl-2H-tetrazolium bromide (MTT) as an electron acceptor; to make such conjugates seems to be a general method for artificially converting a dehydrogenase into an oxidase. When the concentration of oxygen or MTT is varied, the oxidase activity fits the Michaelis-Menten equation with the following kinetic constants: for the reaction system with oxygen, the turnover number per subunit is 2.3 min-1 and Km for oxygen is 1.91 mM; and for the system with MTT, the turnover number is 0.25 min-1 and Km for MTT is 0.076 mM. At the initial steady state of the oxidase reaction, only 2.1% of the NAD+ moieties of the conjugate are in the free state (i.e. not bound in the coenzyme-binding site of the lactate dehydrogenase moiety) and the rest are hidden in the coenzyme site; almost all the NAD+ moieties are in the reduced state. The apparent intramolecular rate constant for the reaction between a free NADH moiety and an oxidized ethylphenazine moiety is 2.3 s-1 and 2.1 s-1 for the systems with oxygen and with MTT, respectively. The apparent effective concentration of the free NADH moiety for the ethylphenazine moiety is 5.5 microM and is much smaller than that (0.34 mM) of the ethylphenazine moiety for the free NADH moiety; this difference is due to the effect of hiding the NADH moiety in the binding site, as the hidden NADH moiety cannot react with the ethylphenazine moiety.

Molecular engineering of the L-tryptophan-depleting enzyme indolyl-3-alkane alpha-hydroxylase.

Polymaleic acid and polyacrylic acid polymers have been covalently linked to indolyl-3-alkane alpha-hydroxylase with a shift of the pH optimum from 3.5 to between 5.0 and 5.5. In addition, the specific activity of the modified enzyme was increased approximately threefold at pH 7.0. The Km values of the polymer-bound enzyme preparations are essentially the same as that of the native enzyme. The plasma half-life was shortened from 6-7 hours with the native enzyme to 2-4 hours with the modified enzymes. The degree of L-tryptophan depletion in the circulation of mice, however, was the same during a 24-hour period after injection of native or modified enzymes.