Characterizing a thermostable amylopullulanase from Caldisericum exile with wide pH adaptation and broad substrate specificity

The crystal structure of GH57 family amylopullulanase reveals its dual binding pockets sharing the same catalytic dyad

Glycoside Hydrolase Family 57 (GH57) amylopullulanase is a thermophilic endoamylase capable of hydrolyzing both α-1,4 and α-1,6-glycosidic bonds, demonstrating significant potential for one-step starch saccharification in industrial applications. However, the mechanisms underlying the dual catalytic activities of GH57 family amylopullulanase remain poorly understood. In this study, we report the first crystal structures of a GH57 amylopullulanase from Aquifex aeolicus (AaApu) in complex with oligosaccharides containing both α-1,4 and α-1,6 glycosidic bonds. Our structural analysis reveals that GH57 amylopullulanase features dual binding pockets arranged in a "Y"-shaped configuration, which accommodates branched-chain starches. The dual binding pockets share a common catalytic dyad composed of Glu256 and Asp352. Notably, unlike the typical retaining mechanism observed in many glycoside hydrolases, the distance between the catalytic residues in GH57 amylopullulanase is significantly larger (approximately 7 Å). This study provides critical insights into the structural basis of GH57 amylopullulanase activity and offers a foundation for the rational engineering of these enzymes for industrial applications.

Dividing the α-amylase family GH57 of starch hydrolases and related enzymes into subfamilies using evolutionary, clustering and functional criteria

In the CAZy classification, four glycoside hydrolase families - GH13, GH57, GH119 and GH126 - have been designated as α-amylase families. The present study applied to a dataset of over 5000 family GH57 sequences, delivers a functionally balanced subdivision of the family GH57 into ten subfamilies. Eight of these subfamilies bear a specific enzyme activity: GH57_1, 4-α-glucanotransferases; GH57_2, amylopullulanases; GH57_3, α-amylases; GH57_4, α-galactosidases; GH57_5, α-glucan-branching enzymes; GH57_6, non-specified amylases; GH57_7, amylopullulanases-cyclomaltodextrinases; and GH57_8, maltogenic amylases. Two subfamilies, GH57_9 and GH57_10, not including any characterized members so far despite their conserved catalytic machinery, will deserve the community attention. Each subfamily is highlighted by its sequence fingerprints, through the logo of the five GH57 conserved sequence regions. The structural features are also compared with regard to domains complementing the catalytic module composed by the (β/α)7-barrel and the succeeding α-helical bundle. Characterized members in each subfamily display a strong agreement in their functional profile, indicating that the here proposed GH57 subfamily annotation results in functionally meaningful subsets. Moreover, several small groups of sequences still lacking sufficient sequence diversity and biochemical characterization did not integrate any of the created GH57 subfamilies so far; nevertheless, they could complete the overall GH57 subfamily picture in future.

Mechanistic insights into cyclodextrins as substrates and inhibitors of GH57 family amylopullulanase from Aquifex aeolicus

Maltooligosaccharides (MOs) have gained significant attention in the food and pharmaceutical industries owing to their valuable functional properties, including controlled sweetness, digestibility, and enhanced bioavailability. However, conventional MOs is production involves complex processing steps and significant production costs. A potential high-efficiency synthesis of specific MOs can be achieved through the ring-opening reaction of cyclodextrins (CDs) catalyzed by amylolytic enzymes. In this study, we analyze the catalytic conversion of α-, β-, and γ-CDs by a GH57 family amylopullulanase from Aquifex aeolicus (AaApu) using thin-layer chromatography (TLC). Our findings demonstrate that AaApu has a substrate specificity for γ-CD, while all three CDs exert competitive inhibition on pullulan hydrolysis. To elucidate the molecular mechanism of CDs as inhibitor and substrate of amylopullulanase, we determined high-resolution crystal structures of AaApu (wild-type and D352N) in complex with α-, β-, and γ-CD through co-crystallization. These findings establish a structure-function framework for understanding the bifunctional nature of CDs as both substrates and inhibitors in GH57 amylopullulanases.

Industrial Biotechnology Based on Enzymes From Extreme Environments

Biocatalysis is crucial for a green, sustainable, biobased economy, and this has driven major advances in biotechnology and biocatalysis over the past 2 decades. There are numerous benefits to biocatalysis, including increased selectivity and specificity, reduced operating costs and lower toxicity, all of which result in lower environmental impact of industrial processes. Most enzymes available commercially are active and stable under a narrow range of conditions, and quickly lose activity at extremes of ion concentration, temperature, pH, pressure, and solvent concentrations. Extremophilic microorganisms thrive under extreme conditions and produce robust enzymes with higher activity and stability under unconventional circumstances. The number of extremophilic enzymes, or extremozymes, currently available are insufficient to meet growing industrial demand. This is in part due to difficulty in cultivation of extremophiles in a laboratory setting. This review will present an overview of extremozymes and their biotechnological applications. Culture-independent and genomic-based methods for study of extremozymes will be presented.