The Maltodextrin Transport System and Metabolism in Lactobacillus Acidophilus NCFM and Production of Novel Alpha-glucosides Through Reverse Phosphorolysis by Maltose Phosphorylase

Overview

Journal FEBS J

Specialty Biochemistry

Date 2009 Nov 19

PMID 19919544

Citations 18

Authors

Hiroyuki Nakai

Martin J Baumann

Bent O Petersen

Yvonne Westphal

Henk Schols

Adiphol Dilokpimol

Maher A Hachem

Sampo J Lahtinen

Jens O Duus

Birte Svensson

Affiliations

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Abstract

A gene cluster involved in maltodextrin transport and metabolism was identified in the genome of Lactobacillus acidophilus NCFM, which encoded a maltodextrin-binding protein, three maltodextrin ATP-binding cassette transporters and five glycosidases, all under the control of a transcriptional regulator of the LacI-GalR family. Enzymatic properties are described for recombinant maltose phosphorylase (MalP) of glycoside hydrolase family 65 (GH65), which is encoded by malP (GenBank: AAV43670.1) of this gene cluster and produced in Escherichia coli. MalP catalyses phosphorolysis of maltose with inversion of the anomeric configuration releasing beta-glucose 1-phosphate (beta-Glc 1-P) and glucose. The broad specificity of the aglycone binding site was demonstrated by products formed in reverse phosphorolysis using various carbohydrate acceptor substrates and beta-Glc 1-P as the donor. MalP showed strong preference for monosaccharide acceptors with equatorial 3-OH and 4-OH, such as glucose and mannose, and also reacted with 2-deoxy glucosamine and 2-deoxy N-acetyl glucosamine. By contrast, none of the tested di- and trisaccharides served as acceptors. Disaccharide yields obtained from 50 mmbeta-Glc 1-P and 50 mm glucose, glucosamine, N-acetyl glucosamine, mannose, xylose or l-fucose were 99, 80, 53, 93, 81 and 13%, respectively. Product structures were determined by NMR and ESI-MS to be alpha-Glcp-(1-->4)-Glcp (maltose), alpha-Glcp-(1-->4)-GlcNp (maltosamine), alpha-Glcp-(1-->4)-GlcNAcp (N-acetyl maltosamine), alpha-Glcp-(1-->4)-Manp, alpha-Glcp-(1-->4)-Xylp and alpha-Glcp-(1-->4)- L-Fucp, the three latter being novel compounds. Modelling using L. brevis GH65 as the template and superimposition of acarbose from a complex with Thermoanaerobacterium thermosaccharolyticum GH15 glucoamylase suggested that loop 3 of MalP involved in substrate recognition blocked the binding of candidate acceptors larger than monosaccharides.

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