Abstract
In this work we report a detailed analysis of the topology and phylogenetics of family 2 glycoside hydrolases (GH2). We distinguish five topologies or domain architectures based on the presence and distribution of protein domains defined in Pfam and Interpro databases. All of them share a central TIM barrel (catalytic module) with two β-sandwich domains (non-catalytic) at the N-terminal end, but differ in the occurrence and nature of additional non-catalytic modules at the C-terminal region. Phylogenetic analysis was based on the sequence of the Pfam Glyco_hydro_2_C catalytic module present in most GH2 proteins. Our results led us to propose a model in which evolutionary diversity of GH2 enzymes is driven by the addition of different non-catalytic domains at the C-terminal region. This model accounts for the divergence of β-galactosidases from β-glucuronidases, the diversification of β-galactosidases with different transglycosylation specificities, and the emergence of bicistronic β-galactosidases. This study also allows the identification of groups of functionally uncharacterized protein sequences with potential biotechnological interest.
Highlights
ΒnGalactosidases are classified by the Enzyme Commission as EC3.2.1.23/108
Additional N-terminal domains related to carbohydrate recognition (Ricin B lectin domain) [24] or a cell surface adhesion signal (YSIRK signal) [25,26,27] were found, suggesting that these sequences correspond to surface anchored β-galactosidases
Proteins have been classified in 5 domain architectures (DAs) types (Fig 1) according to C-terminal variable topologies
Summary
ΒnGalactosidases are classified by the Enzyme Commission as EC3.2.1.23/108 They hydrolyze terminal, non-reducing D-galactosyl residues connected through e-glycoside linkages to polymers, oligosaccharides or secondary metabolites [1, 2]. These are important enzymes in the food and dairy industries because of their use in the manufacture of lactose free milk products. An emerging application is the use of β-galactosidases to synthesize prebiotic galactooligosaccharides (GOS) by means of their transglycosylating activity. This is allowed by the retaining mechanism of these enzymes, which proceeds through two steps. In the second step either a molecule of water or lactose may act as the acceptor of this galactosyl moiety resulting in final hydrolysis or in the synthesis of a PLOS ONE | DOI:10.1371/journal.pone.0168035 December 8, 2016
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