Crystal structure of the polyextremophilic α-amylase AmyB from Halothermothrix orenii:: Details of a productive enzyme-substrate complex and an N domain with a role in binding raw starch

The gene for a membrane-bound, halophilic, and thermostable alpha-amylase, AmyB, from Halothermothrix orenii was cloned and sequenced. The crystal structure shows that, in addition to the typical domain organization of family 13 glycoside hydrolases, AmyB carries an additional N-terminal domain (N domain) that forms a large groove-the N-C groove some 30 angstrom away from the active site. The structure of AmyB with the inhibitor acarbose at 1.35 angstrom resolution shows that a nonasaccharide has been synthesized through successive transglycosylation reactions of acarbose. Unexpectedly, in a complex of wild-type AmyB with alpha-cyclodextrin and maltoheptaose at 2.2 angstrom resolution, a maltotetraose molecule is bound in subsites -1 to +3, spanning the cleavage point at -1 / + 1, with the -1 glucosyl residue present as a S-2(o) skew boat. This wild-type AmyB complex was obtained in the presence of a large excess of substrate, a condition under which it is possible to capture Michaelis complexes, which may explain the observed binding across -1/+ 1 and ring distortion. We observe three methionine side chains that serve as '' binding platforms '' for glucosyl rings in AmyB, a seemingly rare occurrence in carbohydrate-binding proteins. The structures and results from the biochemical characterization of AmyB and AmyB lacking the N domain show that the N domain increases binding of the enzyme to raw starch. Furthermore, theoretical modeling suggests that the N-C groove can accommodate, spatially and chemically, large substrates such as A-starch. (c) 2008 Elsevier Ltd. All rights reserved.