An 1,4-α-glucosyltransferase defines a new maltodextrin catabolism scheme in Lactobacillus acidophilus

ABSTRACTThe maltooligosaccharide (MOS) utilization locus in Lactobacillus acidophilus NCFM, a model for human small-intestine lactobacilli, encodes a family 13 subfamily 31 glycoside hydrolase (GH13_31), annotated as an 1,6-α-glucosidase. Here, we reveal that this enzyme (LaGH13_31B) is an 1,4-α-glucosyltransferase that disproportionates MOS with preference for maltotriose. LaGH13_31B acts in concert with a maltogenic α-amylase that efficiently releases maltose from MOS larger than maltotriose. Collectively, these two enzymes promote efficient conversion of preferentially odd-numbered MOS to maltose that is phosphorolysed by a maltose phosphorylase, encoded by the same locus. Structural analyses revealed the presence of a flexible elongated loop, which is unique for LaGH13_31B and its close homologues. The identified loop insertion harbours a conserved aromatic residue that modulates the activity and substrate affinity of the enzyme, thereby offering a functional signature of this previously undescribed clade, which segregates from described activities such as 1,6-α-glucosidases and sucrose isomerases within GH13_31. Sequence analyses revealed that the LaGH13_31B gene is conserved in the MOS utilization loci of lactobacilli, including acidophilus cluster members that dominate the human small intestine.IMPORTANCEThe degradation of starch in the small intestine generates short linear and branched α-glucans. The latter are poorly digestible by humans, rendering them available to the gut microbiota e.g. lactobacilli adapted to the human small intestine and considered as beneficial to health. This study unveils a previously unknown scheme of maltooligosaccharide (MOS) catabolism, via the concerted action of activity together with a classical hydrolase and a phosphorylase. The intriguing involvement of a glucosyltransferase is likely to allow fine-tuning the regulation of MOS catabolism for optimal harnessing of this key metabolic resource in the human small intestine. The study extends the suite of specificities that have been identified in GH13_31 and highlights amino acid signatures underpinning the evolution of 1,4-α-glucosyl transferases that have been recruited in the MOS catabolism pathway in lactobacilli.