A glucodextranase (iGDase) from Arthrobacter globiformis I42 hydrolyzes ␣-1,6-glucosidic linkages of dextran from the non-reducing end to produce -D-glucose via an inverting reaction mechanism and classified into the glycoside hydrolase family 15 (GH15). Here we cloned the iGDase gene and determined the crystal structures of iGDase of the unliganded form and the complex with acarbose at 2.42-Å resolution. The structure of iGDase is composed of four domains N, A, B, and C. Domain A forms an (␣/␣) 6 -barrel structure and domain N consists of 17 antiparallel -strands, and both domains are conserved in bacterial glucoamylases (GAs) and appear to be mainly concerned with catalytic activity. The structure of iGDase complexed with acarbose revealed that the positions and orientations of the residues at subsites ؊1 and ؉1 are nearly identical between iGDase and GA; however, the residues corresponding to subsite 3, which form the entrance of the substrate binding pocket, and the position of the open space and constriction of iGDase are different from those of GAs. On the other hand, domains B and C are not found in the bacterial GAs. The primary structure of domain C is homologous with a surface layer homology domain of pullulanases, and the three-dimensional structure of domain C resembles the carbohydrate-binding domain of some glycohydrolases.
A region downstream of the gene for pullulan-hydrolyzing alpha-amylase, TVA II, of Thermoactinomyces vulgaris R-47 was sequenced, and an open reading frame encoding an enzyme homologous to glucoamylase was found. The nucleotide sequence of this enzyme, designated TGA, consists of 1,953 base pairs corresponding to a protein of 651 amino acid residues. The TGA gene was subcloned and expressed in Escherichia coli. Enzymatic analyses showed that, like other glucoamylases, TGA produced beta-D-glucose from its substrate. However, TGA hydrolyzed maltooligosaccharides such as maltotetraose and maltose more efficiently than starch, while fungal glucoamylases preferred starch to maltooligosaccharides. The primary structure of TGA resembled a putative glucoamylase from the hyperthermophilic archaeon Methanococcus jannaschii (MGA), while homologies between TGA and the fungal glucoamylases were low. The enzymatic properties of recombinant MGA produced in E. coli cells were similar to those of TGA. These findings indicate that TGA and MGA are novel glucoamy-lase-type enzymes with oligosaccaharide-metabolizing activity.
A maltooligosaccharide-metabolizing enzyme from Thermoactinomyces vulgaris R-47 (TGA) homologous to glucoamylases does not degrade starch efficiently unlike most glucoamylases such as fungal glucoamylases (Uotsu-Tomita et al., Appl. Microbiol. Biotechnol., 56, 465-473 (2001)). In this study, we purified and characterized TGA, and determined the subsite affinities of the enzyme. The optimal pH and temperature of the enzyme are 6.8 and 60 degrees C, respectively. Activity assays with 0.4% substrate showed that TGA was most active against maltotriose, but did not prefer soluble starch. Kinetic analysis using maltooligosaccharides ranging from maltose to maltoheptaose revealed that TGA has high catalytic efficiency for maltotriose and maltose. Based on the kinetics, subsite affinities were determined. The A1+A2 value of this enzyme was highly positive whereas A4-A6 values were negative and little affinity was detected at subsites 3 and 7. Thus, the subsite structure of TGA is different from that of any other GA. The results indicate that TGA is a metabolizing enzyme specific for small maltooligosaccharides.
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