Browsing by Author "Stephan Hann"

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    Reaction of pyranose dehydrogenase from Agaricus meleagris with its carbohydrate substrates
    (2015-11-01) Michael M.H. Graf; Jeerus Sucharitakul; Urban Bren; Dinh Binh Chu; Gunda Koellensperger; Stephan Hann; Paul G. Furtmüller; Christian Obinger; Clemens K. Peterbauer; Chris Oostenbrink; Pimchai Chaiyen; Dietmar Haltrich; Universitat fur Bodenkultur Wien; Chulalongkorn University; Univerza v Mariboru; Hanoi University of Science and Technology; Universitat Wien; Mahidol University
    © 2015 The Authors. FEBS Journal published by John Wiley & Sons Ltd on behalf of Federation of European Biochemical Societies. Monomeric Agaricus meleagris pyranose dehydrogenase (AmPDH) belongs to the glucose-methanol-choline family of oxidoreductases. An FAD cofactor is covalently tethered to His103 of the enzyme. AmPDH can double oxidize various mono- and oligosaccharides at different positions (C1 to C4). To study the structure/function relationship of selected active-site residues of AmPDH pertaining to substrate (carbohydrate) turnover in more detail, several active-site variants were generated, heterologously expressed in Pichia pastoris, and characterized by biochemical, biophysical and computational means. The crystal structure of AmPDH shows two active-site histidines, both of which could take on the role as the catalytic base in the reductive half-reaction. Steady-state kinetics revealed that His512 is the only catalytic base because H512A showed a reduction in (kcat/KM)glucose by a factor of 105, whereas this catalytic efficiency was reduced by two or three orders of magnitude for His556 variants (H556A, H556N). This was further corroborated by transient-state kinetics, where a comparable decrease in the reductive rate constant was observed for H556A, whereas the rate constant for the oxidative half-reaction (using benzoquinone as substrate) was increased for H556A compared to recombinant wild-type AmPDH. Steady-state kinetics furthermore indicated that Gln392, Tyr510, Val511 and His556 are important for the catalytic efficiency of PDH. Molecular dynamics (MD) simulations and free energy calculations were used to predict d-glucose oxidation sites, which were validated by GC-MS measurements. These simulations also suggest that van der Waals interactions are the main driving force for substrate recognition and binding.