Difference between revisions of "Glycoside Hydrolase Family 31"

• Author: Ran Zhang
• Responsible Curator: Steve Withers

Substrate specificities

CAZy Family GH31 is one of the two major families, along with GH13, that contain α-glucosidases. These enzymes play important roles in primary metabolism (e.g. human sucrase/isomaltase, a target for diabetic drugs such as miglitol), in catabolism (e.g. human lysosomal α-glucosidase) and in glycoprotein processing (e.g. ER glucosidase II). In addition to α-glucosidases, GH31 also contains α-xylosidases, isomaltosyltransferases, maltase/glucoamylases and the mechanistically interesting, non-hydrolytic α-glucan lyases. These enzymes can be found in a wide range of organisms including archaea, bacteria, plants and animals. Interestingly the two mammalian digestive enzymes are both duplicated genes, each with dual specificities.

Kinetics and Mechanism

Family GH 31 enzymes are retaining α-glycosidases, as was first demonstrated by a combination of polarimetric and reducing sugar measurement. [1] GH31 enzymes (except for the α-glucan lyases) are believed to follow the classical double displacement mechanism. [2] This has been strongly supported by labelinging of the catalytic nucleophile of several GH31 enzymes using conduritol B epoxide [3], with early examples including rabbit intestinal sucrase/isomaltase [4] and human lysosomal α-glucosidase [5]. Later studies on an α-glucosidase from Aspergillus niger [6] and an α-xylosidase from Escherichia coli [7] used the more reliable 5-fluoroglycosyl fluoride trapping reagents, which form catalytically competent intermediates.

The α-glucan lyases from GH31 cleave α-glucan polymers via an elimination mechanism to generate 1,5-anhydro-fructose. Detailed mechanistic studies have been carried out on Gracilariopsis α-1,4-glucan lyase revealing a mechanism that involves a nucleophilic displacement as the first step, followed by syn-elimination as the second step [8, 9]. Evidence for the first step includes trapping of the catalytically competent glycosyl-enzyme intermediate by 5-fluoro-β-L-idopyranosyl fluoride and the observation of secondary kinetic isotope effects (KIEs) on both H-1 and H-2 of two α-glucoside substrates. Direct proof of the second elimination step was provided by the observation of a small primary KIE on C-2 by using a substrate for which the elimination step is rate-limiting, 5-fluoro-α-D-glucopyranosyl fluoride.

Catalytic Residues

Measurements of pH profiles suggested that two essential residues were involved in catalysis [2, 7, 9]. Earlier active site-labeling studies employing conduritol B epoxide identified an invariant Asp residue as the catalytic nucleophile, corresponding to Asp224 of Aspergillus niger α-glucosidase within the sequence IDM [3, 5]. This was confirmed by using the more reliable 5-fluoro-α-D-glucopyransyl fluoride reagent followed by subsequent peptide mapping by LC/MS-MS [6]. The general acid/base residue was first tentatively assigned as Asp647 in the Schizosaccharomyces pombe α-glucosidase based on sequence comparison and kinetic analysis of the mutants [10]. This was subsequently confirmed by the crystallographic studies on α-xylosidase (YicI) from Escherichia coli [7] and successfully engineering YicI into the first α-thioglycoligase by mutating the corresponding general acid/base residue D482 [11]. The equivalent residue, Asp553, in Gracilariopsis α-1,4-glucan lyase has also been identified as the catalytic nucleophile through the use of 5-fluoro-β-L-idopyranosyl fluoride [8]. However, the identity of the base which deprotonates H-2 in the second elimination step is not clear, though one of the most probable candidates was proposed to be the carboxyl group of the catalytic nucleophile as it departs [9].

Three-dimensional structures

Family Firsts

First sterochemistry determination

Cite some reference here, with a short explanation [1].

First catalytic nucleophile identification

First general acid/base residue identification

First 3-D structure

References

1. Ernst HA, Lo Leggio L, Willemoës M, Leonard G, Blum P, and Larsen S. (2006). Structure of the Sulfolobus solfataricus alpha-glucosidase: implications for domain conservation and substrate recognition in GH31. J Mol Biol. 2006;358(4):1106-24. DOI:10.1016/j.jmb.2006.02.056 | PubMed ID:16580018 [1]