Title of article
Agaricus meleagris pyranose dehydrogenase: Influence of covalent FAD linkage on catalysis and stability
Author/Authors
Krondorfer، نويسنده , , Iris and Brugger، نويسنده , , Dagmar and Paukner، نويسنده , , Regina and Scheiblbrandner، نويسنده , , Stefan and Pirker، نويسنده , , Katharina F. and Hofbauer، نويسنده , , Stefan and Furtmüller، نويسنده , , Paul G. and Obinger، نويسنده , , Christian and Haltrich، نويسنده , , Dietmar and Peterbauer، نويسنده , , Clemens K. and Leech، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2014
Pages
9
From page
111
To page
119
Abstract
Pyranose dehydrogenase (PDH) is a monomeric flavoprotein belonging to the glucose–methanol–choline (GMC) family of oxidoreductases. It catalyzes the oxidation of free, non-phosphorylated sugars to the corresponding keto sugars. The enzyme harbors an FAD cofactor that is covalently attached to histidine 103 via an 8α-N(3) histidyl linkage. Our previous work showed that variant H103Y was still able to bind FAD (non-covalently) and perform catalysis but steady-state kinetic parameters for several substrates were negatively affected. In order to investigate the impact of the covalent FAD attachment in Agaricus meleagris PDH in more detail, pre-steady-state kinetics, reduction potential and stability of the variant H103Y in comparison to the wild-type enzyme were probed. Stopped-flow analysis revealed that the mutation slowed down the reductive half-reaction by around three orders of magnitude whereas the oxidative half-reaction was affected only to a minor degree. This was reflected by a decrease in the standard reduction potential of variant H103Y compared to the wild-type protein. The existence of an anionic semiquinone radical in the resting state of both the wild-type and variant H103Y was demonstrated using electron paramagnetic resonance (EPR) spectroscopy and suggested a higher mobility of the cofactor in the variant H103Y. Unfolding studies showed significant negative effects of the disruption of the covalent bond on thermal and conformational stability. The results are discussed with respect to the role of covalently bound FAD in catalysis and stability.
Keywords
Covalent flavinylation , thermal stability , Conformational stability , Semiquinone radical , FAD , Pyranose dehydrogenase
Journal title
Archives of Biochemistry and Biophysics
Serial Year
2014
Journal title
Archives of Biochemistry and Biophysics
Record number
1634367
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