The gene encoding a glycoside hydrolase family 43 enzyme termed deAX was isolated and subcloned from a culture seeded with a compost starter mixed bacterium population, expressed with a C-terminal His(6)-tag, and purified to apparent homogeneity. deAX was monomeric in solution and had a broad pH maximum between pH 5.5 and pH 7. A twofold greater k (cat)/K (m) for the p-nitrophenyl derivative of alpha-L: -arabinofuranose versus that for the isomeric substrate beta-D-xylopyranose was due to an appreciably lower K (m) for the arabinofuranosyl substrate. Substrate inhibition was observed for both 4-methylumbelliferryl arabinofuranoside and the xylopyranoside cogener. While no loss of activity was observed over 4 h at 40 degrees C, the observed t (1/2) value rapidly decreased from 630 min at 49 degrees C to 47 min at 53 degrees C. The enzyme exhibited end-product inhibition, with a K (i) for xylose of 145 mM, 18.5 mM for arabinose, and 750 mM for glucose. Regarding natural substrate specificity, deAX had arabinofuranosidase activity on sugar beet arabinan, 1,5-alpha-L-arabinobiose, and 1,5-alpha-L-arabinotriose, and wheat and rye arabinoxylan, while xylosidase activity was detected for the substrates xylobiose, xylotriose, xylotetraose, and arabinoxylan from beech and birch. Thus, deAX can be classified as a dual-function xylosidase/arabinofuranosidase with respect to both artificial and natural substrate specificity.
The gene encoding a glycoside hydrolase family 43 beta-xylosidase (GbtXyl43A) from the thermophilic bacterium Geobacillus thermoleovorans strain IT-08 was synthesized and cloned with a C-terminal His-tag into a pET29b expression vector. The recombinant gene product termed GbtXyl43A was expressed in Escherichia coli and purified to apparent homogeneity. Michaelis-Menten kinetic parameters were obtained for the artificial substrates p-nitrophenyl-beta-D: -xylopyranose (4NPX) and p-nitrophenyl-alpha-L: -arabinofuranose (4NPA), and it was found that the ratio k (cat)/K (m) 4NPA/k (cat)/K (m) 4NPX was approximately 7, indicting greater catalytic efficiency for 4NP hydrolysis from the arabinofuranose aglycon moiety. Substrate inhibition was observed for the substrates 4-methylumbelliferyl xylopyranoside (muX) and the arabinofuranoside cogener (muA), and the ratio k (cat)/K (m) muA/k (cat)/K (m) muX was approximately 5. The enzyme was competitively inhibited by monosaccharides, with an arabinose K (i) of 6.8 +/- 0.62 mM and xylose K (i) of 76 +/- 8.5 mM. The pH maxima was 5.0, and the enzyme was not thermally stable above 54 degrees C, with a t (1/2) of 35 min at 57.5 degrees C. GbtXyl43A showed a broad substrate specificity for hydrolysis of xylooligosaccharides up to the highest degree of polymerization tested (xylopentaose), and also released xylose from birch and beechwood arabinoxylan.
Beta-D-Xylosidase catalyzes hydrolysis of xylooligosaccharides to D-xylose residues. The enzyme, SXA from Selenomonas ruminantium, is the most active catalyst known for the reaction; however, its activity is inhibited by D-xylose and D-glucose (K (i) values of approximately 10(-2) M). Higher K (i)'s could enhance enzyme performance in lignocellulose saccharification processes for bioethanol production. We report here the development of a two-tier high-throughput screen where the 1 degrees screen selects for activity (active/inactive screen) and the 2 degrees screen selects for a higher K (i(D-xylose)) and its subsequent use in screening approximately 5,900 members of an SXA enzyme library prepared using error-prone PCR. In one variant, termed SXA-C3, K (i(D-xylose)) is threefold and K (i(D-glucose)) is twofold that of wild-type SXA. C3 contains four amino acid mutations, and one of these, W145G, is responsible for most of the lost affinity for the monosaccharides. Experiments that probe the active site with ligands that bind only to subsite -1 or subsite +1 indicate that the changed affinity stems from changed affinity for D-xylose in subsite +1 and not in subsite -1 of the two-subsite active site. Trp145 is 6 A from the active site, and its side chain contacts three active-site residues, two in subsite +1 and one in subsite -1.
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