Characterization of Ruminiclostridium josui arabinoxylan arabinofuranohydrolase, RjAxh43B, and RjAxh43B-containing xylanolytic complex.

A novel gene (axh43B) from Ruminiclostridium josui encoding a cellulosomal enzyme consisting of a catalytic module of subfamily GH43_10, a family-6 carbohydrate-binding module, and a dockerin module, was expressed using Escherichia coli. RjAxh43B released only arabinose from arabinoxylan and 23,33-di-α-l-arabinofuranosyl xylotriose, but not 32-α-l-arabinofuranosyl xylobiose or 23-α-l-arabinofuranosyl xylotriose, strongly suggesting that RjAxh43B is an arabinoxylan α-l-1,3-arabinofuranohydrolase capable of cleaving α-1,3-linked arabinose residues of doubly arabinosylated xylan. When Axh43B was mixed with the recombinant scaffolding protein RjCipA of R. josui at a molar ratio of 6:1, the activity of the RjAxh43B-RjCipA complex (6:1) toward insoluble wheat arabinoxylan was similar to that of RjAxh43B alone, suggesting that RjAxh43B does not show a proximity effect, which is defined as an activity enhancement effect caused by the presence of plural catalytic subunits adjoining each other. When RjAxh43A was mixed with xylanase RjXyn10C, they acted synergistically toward insoluble wheat arabinoxylan and rice straw powder in the absence of RjCipA. Furthermore, the RjAxh43B-RjXyn10C-RjCipA (3:3:3) complex had higher activity toward insoluble wheat arabinoxylan than a mixture of RjAxh43B and RjXyn10C without RjCipA, suggesting that incorporation of a xylanase and an α-l-arabinofuranosidase into a cellulosome is beneficial for more efficiently degrading arabinoxylan.

Recombinant cellulolytic or xylanolytic complex comprising the full-length scaffolding protein RjCipA and cellulase RjCel5B or xylanase RjXyn10C of Ruminiclostridium josui.

Three cellulosomal subunits of Ruminiclostridium josui, the full-length scaffolding protein CipA (RjCipA), a cellulase Cel5B (RjCel5B) and a xylanase Xyn10C (RjXyn10C), were successfully produced by Escherichia coli recombinant clones. RjCel5B and RjXyn10C were characterized as an endoglucanase and an endoxylanase, respectively. RjCipA, RjCel5B and Xyn10C adsorbed to microcrystalline cellulose (Funacel) and rice straw powder. Interaction between RjCel5B and RjCipA, and RjXyn10C and RjCipA were confirmed by qualitative assays. When a fixed amount of RjCel5B was mixed with different amounts of RjCipA, i.e., at the molar ratio of 6:1 or 6:6, the 6:6 complex showed 6.6-fold higher activity toward Funacel and 11.5-fold higher activity toward rice straw powder than RjCel5B, whereas the 6:1 complex showed only 2.8- and 3.9-folds higher activities toward Funacel and rice straw powder, respectively, than RjCel5B. These results suggest that the family-3 carbohydrate binding module (CBM3) of RjCipA in the RjCel5B-RjCipA complex plays an important role for hydrolysis of cellulose and the substrate-targeting effect of the CBM is more significant than the proximity effect caused by the presence of plural catalytic subunits adjoining each other. In contrast, the 6:1 complex of RjXyn10C and RjCipA showed 45% and 28% of the activities of RjXyn10C toward insoluble wheat arabinoxylan and rice straw powder, respectively. These results suggest that both a negative proximity effect and substrate-isolating effect, but not substrate-targeting effect, are caused by the CBM3 with inappropriate polysaccharide specificity. Substrate-targeting, proximity and substrate-isolating effects are discussed.