Conformational Analyses of the Reaction Coordinate of Glycosidases

Davies, G.J.; Planas, Antoni; Rovira, Carme

doi:10.1021/ar2001765

Cited by 223 publications

(269 citation statements)

References 55 publications

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“…A similar situation is obtained in the case of trans H + CB (2), where the excess proton was initially placed near OH4 0 , but in this case, there is less indication that water formed may be departing in the course of the trajectory, though the bond O4 0 -C4 0 is considerably weaker throughout the simulation, see Fig. 10c, red.…”

Section: Trans H + Cb(2)supporting

confidence: 72%

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When a proton attacks cellobiose in the gas phase: ab initio molecular dynamics simulations

Pincu

Brauer

Gerber

2013

Phys. Chem. Chem. Phys.

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Section: Trans H + Cb(2)supporting

confidence: 72%

“…[1][2][3] In many of these processes reactions of a proton with the sugar are assumed to take place. Nevertheless, while the importance of a proton interacting with a sugar is recognized, there is incomplete knowledge of the pathways of this interaction and its dynamics on a microscopic scale.…”

Section: Introductionmentioning

confidence: 99%

When a proton attacks cellobiose in the gas phase: ab initio molecular dynamics simulations

Pincu

Brauer

Gerber

2013

Phys. Chem. Chem. Phys.

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“…When modeled in the energetically favoured 4 C 1 chair conformation, the phosphate of βG1P sterically clashed with the side chain of Met 292. This was not too surprising, however, considering that retaining glucosidases are known to assist bond cleavage by distorting the substrate to position the leaving group in a pseudoaxial position, which brings the conformation of the substrate closer to that of the reaction transition state 39 . Thus, the repulsive interactions between Met292 and the phosphate of βG1P, in conjunction with the favourable binding interactions between the substrate glucosyl and phosphate moieties likely force the phosphate of bound β-Glc-1-phosphate product into a pseudoaxial position.…”

Section: As Seen Inmentioning

confidence: 99%

Structural and mechanistic analysis of a β-glycoside phosphorylase identified by screening a metagenomic library

Macdonald

Patel

Larmour

et al. 2018

Journal of Biological Chemistry

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Glycoside phosphorylases have considerable potential as catalysts for the assembly of useful glycans for products ranging from functional foods and prebiotics to novel materials. However, the substrate diversity of currently identified phosphorylases is relatively small, limiting their practical applications. To address this limitation, we developed a high-throughput screening approach using the activated substrate 2,4-dinitrophenyl β-D-glucoside (DNPGlc) and inorganic phosphate for identifying glycoside phosphorylase activity and used it to screen a large insert metagenomic library. The initial screen, based on release of 2,4-dinitrophenol from DNPGlc in the presence of phosphate, identified the gene bglP, encoding a retaining β-glycoside phosphorylase from the CAZy GH3 family. Kinetic and mechanistic analysis of the gene product, BglP, confirmed a double displacement ping-pong mechanism involving a covalent glycosyl-enzyme intermediate. X-ray crystallographic analysis provided insights into the phosphate-binding mode and identified a key glutamine residue in the active site important for substrate recognition. Substituting this glutamine for a serine swapped the substrate specificity from glucoside to Nacetylglucosaminide. In summary, we present a high-throughput screening approach for identifying β-glycoside phosphorylases, which was robust, simple to implement, and useful in identifying active clones within a metagenomics library. GH3 β-glycoside phosphorylase from a metagenomic library 2 Implementation of this screen enabled discovery of a new glycoside phosphorylase class and has paved the way to devising simple ways in which enzyme specificity can be encoded and swapped, which has implications for biotechnological applications.Carbohydrate active enzymes (CAZymes) are the biocatalysts responsible for the assembly, degradation and modification of glycans in biological systems 1 . They are also widely employed enzymes in industry, being used in brewing and food processing, animal feed preparation, industrial pulp and paper applications and increasingly in biofuel and bioproduct development [2][3][4][5] . While the use of CAZymes is cost-effective in glycan degradation, glycan assembly generally requires the use of expensive starting materials, such as nucleotide phosphosugars 6 . The high-cost of these materials makes de novo industrial-scale glycan synthesis difficult and usually non-viable.One class of CAZyme that offers a potential solution to the high costs typically associated with enzymatic glycan synthesis is that of the glycoside phosphorylases (GPs), which are increasingly being recognized and used for the biocatalysis and biotransformation of glycans 7-9 . These enzymes ordinarily carry out phosphorolysis by transferring a glycosyl moiety from the nonreducing end of a di-or polysaccharide substrate onto inorganic phosphate, thereby generating a sugar-1-phosphate 10 ( Figure 1A). GPs distinguish themselves from most CAZymes in that the hydrolytic free energy associated with the glycosidic e...

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“…Such a mechanism demands two crucial catalytic residues, a nucleophile and an acid/base ( Fig. 1), both of which are typically enzyme-derived carboxylates (such mechanisms are reviewed in Vocadlo & Davies, 2008;Davies et al, 2012), as discussed further below. The primary biotechnological importance of -d-glucosidases is their key role in cellulose degradation (Fig.…”

Section: Introductionmentioning

confidence: 99%

Three-dimensional structures of two heavily N-glycosylatedAspergillussp. family GH3 β-D-glucosidases

Agirre

Ariza

Offen

et al. 2016

Acta Crystallogr D Struct Biol

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The industrial conversion of cellulosic plant biomass into useful products such as biofuels is a major societal goal. These technologies harness diverse plant degrading enzymes, classical exo-and endo-acting cellulases and, increasingly, cellulose-active lytic polysaccharide monooxygenases, to deconstruct the recalcitrant -d-linked polysaccharide. A major drawback with this process is that the exo-acting cellobiohydrolases suffer from severe inhibition from their cellobiose product. -d-Glucosidases are therefore important for liberating glucose from cellobiose and thereby relieving limiting product inhibition. Here, the three-dimensional structures of two industrially important family GH3 -d-glucosidases from Aspergillus fumigatus and A. oryzae, solved by molecular replacement and refined at 1.95 Å resolution, are reported. Both enzymes, which share 78% sequence identity, display a three-domain structure with the catalytic domain at the interface, as originally shown for barley -d-glucan exohydrolase, the first three-dimensional structure solved from glycoside hydrolase family GH3. Both enzymes show extensive N-glycosylation, with only a few external sites being truncated to a single GlcNAc molecule. Those glycans N-linked to the core of the structure are identified purely as highmannose trees, and establish multiple hydrogen bonds between their sugar components and adjacent protein side chains. The extensive glycans pose special problems for crystallographic refinement, and new techniques and protocols were developed especially for this work. These protocols ensured that all of the d-pyranosides in the glycosylation trees were modelled in the preferred minimum-energy 4 C 1 chair conformation and should be of general application to refinements of other crystal structures containing O-or N-glycosylation. The Aspergillus GH3 structures, in light of other recent three-dimensional structures, provide insight into fungal -d-glucosidases and provide a platform on which to inform and inspire new generations of variant enzymes for industrial application.

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Conformational Analyses of the Reaction Coordinate of Glycosidases

Cited by 223 publications

References 55 publications

When a proton attacks cellobiose in the gas phase: ab initio molecular dynamics simulations

When a proton attacks cellobiose in the gas phase: ab initio molecular dynamics simulations

Structural and mechanistic analysis of a β-glycoside phosphorylase identified by screening a metagenomic library

Three-dimensional structures of two heavily N-glycosylatedAspergillussp. family GH3 β-D-glucosidases

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