L-tyrosine is the precursor of PQQ biosynthesis in Hyphomicrobium X

AbstractA method was developed to study amino acids as possible precursors of PQQ biosynthesis. Cultures of Hyphomicrobium X, growing on [13C]methanol, were supplemented with unlabelled amino acids. Uptake and participation in metabolism were determined via gas chromatography/mass spectrometry of derivatized amino acids, obtained from hydrolysed cellular protein, by measuring their 12C content. Several amino acids appeared to be incorporated into the protein to a significant extent, without degradation or conversion. Among these were the aromatic amino acids, L-tyrosine and L-phenylalanine. Using the same replacement approach, their incorporation into PQQ was determined by 1H- and 13C-NMR spectroscopy of purified PQQ obtained from the culture medium. It appeared that the complete carbon skeleton of tyrosine was present, forming the o-quinone and pyrrole-2-carboxylic acid moieties in PQQ, while phenylalanine was not incorporated at all. Starting with L-tyrosine, possible biosynthetic routes to PQQ are discussed

Tetrazolium-dye-linked alcohol dehydrogenase of the methylotrophic actinomycete Amycolatopsis methanolica is a three-component complex

Tetrazolium-dye-linked alcohol dehydrogenase (TD-ADH) of Arnycolatopsis methanolica could be resolved into three protein components, which have been purified. Each of the components has the ability to reconstitute TD-ADH activity when combined with the other two. Component 1 is identical to the previously characterized methanol:N,N’-dimethyl-4-nitrosoaniline oxidoreductase (MNO), a decameric protein with 50-kDa subunits, each carrying a tightly bound NADPH. Component 2 is a high molecular mass (>640 kDa) protein with subunits of 44 kDa and 72 kDa, and which possesses a low tetrazolium-dye-linked NADH dehydrogenase activity. The protein contains a yellow chromophore of unknown identity. Component 3 is a low molecular mass (15 kDa) protein containing a 5’-deazaflavin and at least one other low-molecular-mass compound with properties similar, but not identical, to those of nicotinamide coenzymes. The results suggest that alcohol oxidation by the TD-ADH complex is carried out by component 1 (MNO), after which transfer of the reducing equivalents (mediated by component 3) occurs to component 2, which (in vitro) is linked to the tetrazolium dye. Fractionation of A. methanolica extracts showed that most of the 5’-deazaflavin was present in component 3. Other gram-positive bacteria having a TD-ADH complex also produced 5’-deazaflavin. It is concluded that oxidation of primary aliphatic alcohols by A. methanolica, and probably also by other gram-positive bacteria containing MNO or TD-ADH, proceeds via TD-ADH. The likeliness of 5’-deazaflavin participation in this process is discussed.

Structure and mechanism of soluble quinoprotein glucose dehydrogenase

Soluble glucose dehydrogenase (s-GDH; EC 1.1.99.17) is a classical quinoprotein which requires the cofactor pyrroloquinoline quinone (PQQ) to oxidize glucose to gluconolactone. The reaction mechanism of PQQ-dependent enzymes has remained controversial due to the absence of comprehensive structural data. We have determined the X-ray structure of s-GDH with the cofactor at 2.2 Angstrom resolution, and of a complex with reduced PQQ and glucose at 1.9 Angstrom resolution. These structures reveal the active site of s-GDH, and show for the first time how a functionally bound substrate interacts with the cofactor in a PQQ-dependent enzyme. Twenty years after the discovery of PQQ, our results finally provide conclusive evidence for a reaction mechanism comprising general base-catalyzed hydride transfer, rather than the generally accepted covalent addition-elimination mechanism. Thus, PQQ-dependent enzymes use a mechanism similar to that of nicotinamide- and flavin-dependent oxidoreductases.</p