Crystallisation of wild-type and variant forms of a recombinant plant enzyme β-D-glucan glucohydrolase from barley (Hordeum vulgare L.) and preliminary X-ray analysis

The evolutionary advantage of an aromatic clamp in plant family 3 glycoside exo-hydrolases

In the barley β-D-glucan glucohydrolase, a glycoside hydrolase family 3 (GH3) enzyme, the Trp286/Trp434 clamp ensures β-D-glucosides binding, which is fundamental for substrate hydrolysis during plant growth and development. We employ mutagenesis, high-resolution X-ray crystallography, and multi-scale molecular modelling methods to examine the binding and conformational behaviour of isomeric β-D-glucosides during substrate-product assisted processive catalysis that operates in GH3 hydrolases. Enzyme kinetics reveals that the W434H mutant retains broad specificity, while W434A behaves as a strict (1,3)-β-D-glucosidase. Investigations of reactant movements on the nanoscale reveal that processivity is sensitive to mutation-specific alterations of the tryptophan clamp. While wild-type and W434H utilise a lateral cavity for glucose displacement and sliding of (1,3)-linked hydrolytic products through the catalytic site without dissociation, consistent with their high hydrolytic rates, W434A does not adopt processive catalysis. Phylogenomic analyses of GH3 hydrolases disclose the evolutionary advantage of the tryptophan clamp that confers broad specificity, high catalytic efficiency, and processivity.

Expression of rice β-exoglucanase II (OsExoII) in Escherichia coli, purification, and characterization

Enzymes involved in β-glucan breakdown in plants include endoglucanases, exoglucanases and β-glucosidases. Glycoside hydrolase family 3 (GH3) exoglucanases from barley and maize and a few plant GH3 β-glucosidases have been characterized, but none from rice. A few of these enzymes have been expressed in recombinant yeast and plant systems, but bacterial expression of plant GH3 enzymes has not been successful. We expressed the rice GH3 exoglucanase OsExo2 in Escherichia coli as a thioredoxin fusion protein, while other active plant GH3 enzymes could not be produced in this system. The protein was purified over 2000-fold in three chromatographic steps. The enzyme hydrolyzed β-1,3- and β-1,4-linked oligosaccharides and polysaccharides, consistent with a role in cell wall remodeling. Of the oligosaccharides tested, it had highest catalytic efficiency toward laminaritriose, (apparent k_cat/K_m = 37.7 mM^-1s^-1). Among polysaccharides, OsExoII hydrolyzed barley mixed β-glucan and laminarin with similar efficiencies (apparent k_cat/K_m = 3.7 and 3.4 mL mg^-1 s^-1, respectively), but achieved its highest apparent k_cat with lichenan (2.9 s^-1). OsExoII was found to be stimulated by ethylene glycol, which increased the apparent k_cat and decreased the K_m and was transglycosylated. These results imply that E. coli expression may be successful for certain plant GH3 enzymes and OsExoII may be a useful enzyme for application to glycoside production.

Discovery of processive catalysis by an exo-hydrolase with a pocket-shaped active site

Substrates associate and products dissociate from enzyme catalytic sites rapidly, which hampers investigations of their trajectories. The high-resolution structure of the native Hordeum exo-hydrolase HvExoI isolated from seedlings reveals that non-covalently trapped glucose forms a stable enzyme-product complex. Here, we report that the alkyl β-d-glucoside and methyl 6-thio-β-gentiobioside substrate analogues perfused in crystalline HvExoI bind across the catalytic site after they displace glucose, while methyl 2-thio-β-sophoroside attaches nearby. Structural analyses and multi-scale molecular modelling of nanoscale reactant movements in HvExoI reveal that upon productive binding of incoming substrates, the glucose product modifies its binding patterns and evokes the formation of a transient lateral cavity, which serves as a conduit for glucose departure to allow for the next catalytic round. This path enables substrate-product assisted processive catalysis through multiple hydrolytic events without HvExoI losing contact with oligo- or polymeric substrates. We anticipate that such enzyme plasticity could be prevalent among exo-hydrolases.

Enzyme substrates and products often diffuse too rapidly to assess the catalytic implications of these movements. Here, the authors characterise the structural basis of product and substrate diffusion for an exo-hydrolase and discover a substrate-product assisted processive catalytic mechanism.

Crystallisation of wild-type and variant forms of a recombinant plant enzyme β-D-glucan glucohydrolase from barley (Hordeum vulgare L.) and preliminary X-ray analysis

Wild-type and variant crystals of a recombinant enzyme beta-d-glucan glucohydrolase from barley (Hordeum vulgare L.) were obtained by macroseeding and cross-seeding with microcrystals obtained from native plant protein. Crystals grew to dimensions of up to 500 x 250 x 375 mum at 277 K in the hanging-drops by vapour-diffusion. Further, the conditions are described that yielded the wild-type crystals with dimensions of 80 x 40 x 60 mum by self-nucleation vapour-diffusion in sitting-drops at 281 K. The wild-type and recombinant crystals prepared by seeding techniques achived full size within 5-14 days, while the wild-type crystals grown by self-nucleation appeared after 30 days and reached their maximum size after another two months. Both the wild-type and recombinant variant crystals, the latter altered in the key catalytic and substrate-binding residues Glu220, Trp434 and Arg158/Glu161 belonged to the P4(3)2(1)2 tetragonal space group, i.e., the space group of the native microcrystals was retained in the newly grown recombinant crystals. The crystals diffracted beyond 1.57-1.95 A and the cell dimensions were between a = b = 99.2-100.8 A and c = 183.2-183.6 A. With one molecule in the asymmetric unit, the calculated Matthews coefficients were between 3.4-3.5 A(3).Da(-1) and the solvent contents varied between 63.4% and 64.5%. The macroseeding and cross-seeding techniques are advantageous, where a limited amount of variant proteins precludes screening of crystallisation conditions, or where variant proteins could not be crystallized.