Detergent-compatible bacterial cellulases.

Cellulases, lipases, proteases, and amylases are employed in the detergent preparation to speed up the detergency process. Microbial cellulases are now commercially manufactured and are being used by various industries like detergent industry. Currently, the supplementation of detergent-compatible enzymes is a new trend followed by most of the detergent industries. The cellulases are supplemented to the detergents to improve the fabric smoothness and soil removal without damaging them. They act by passing through the textile interfibril spaces and thus the fabric quality is preserved. The process is environment friendly, and the use of cellulases and other detergent-compatible enzymes diminishes the utilization of toxic detergent constituents that are hazardous to humans. Alkaline cellulases active at ambient and low temperature are now preferred to maintain the fabric quality and use of low energy. The review reports on the production, purification, and properties studies of detergent-compatible proteases, amylases, and lipases are available. However, there is no report on detergent-compatible bacterial cellulases. In the present review, an overview on the production, purification, and characterization of detergent bacterial cellulases is presented. The stability and compatibility of the alkaline bacterial cellulases in the presence of the detergents and the detergent constituents are also discussed.

Metagenomic cellulases highly tolerant towards the presence of ionic liquids--linking thermostability and halotolerance.

Cellulose is an important renewable resource for the production of bioethanol and other valuable compounds. Several ionic liquids (ILs) have been described to dissolve water-insoluble cellulose and/or wood. Therefore, ILs would provide a suitable reaction medium for the enzymatic hydrolysis of cellulose if cellulases were active and stable in the presence of high IL concentrations. For the discovery of novel bacterial enzymes with elevated stability in ILs, metagenomic libraries from three different hydrolytic communities (i.e. an enrichment culture inoculated with an extract of the shipworm Teredo navalis, a biogas plant sample and elephant faeces) were constructed and screened. Altogether, 14 cellulolytic clones were identified and subsequently assayed in the presence of six different ILs. The most promising enzymes, CelA2, CelA3 (both derived from the biogas plant) and CelA84 (derived from elephant faeces), showed high activities (up to 6.4 U/mg) in the presence of 30% (v/v) ILs. As these enzymes were moderately thermophilic and halotolerant, they retained 40% to 80% relative activity after 34 days in 4 M NaCl, and they were benchmarked with two thermostable enzymes, CelA from Thermotoga maritima and Cel5K from a metagenome library derived from Avachinsky crater in Kamchatka. These enzymes also exhibited high activity (up to 11.1 U/mg) in aqueous IL solutions (30% (v/v)). Some of the enzymes furthermore exhibited remarkable stability in 60% (v/v) IL. After 4 days, CelA3 and Cel5K retained up to 79% and 100% of their activity, respectively. Altogether, the obtained data suggest that IL tolerance appears to correlate with thermophilicity and halotolerance.

pH-dependent stability of EGX, a multi-functional cellulase from mollusca, Ampullaria crossean.

The cellulase activity and stability of EGX, a multi-functional cellulase previously purified from the mollusca Ampullaria crossean, was systematically studied under different pH. The pH induced con-formation and stability change of EGX have been investigated by using the intrinsic fluorescence, ANS fluorescence and CD spectrum. It has been found that the conformation and activity of this cellulase were strongly dependent on the pH. EGX was stable for both the enzyme activity and the conformation from pH 5.6 to pH 7.4. As shown by intrinsic and ANS fluorescence, no red shift of emission maximum occurred and a negligible intensity change was observed at pH 5.6-7.4. The activity of EGX remained about 80% in pH 5.6-7.4 and obviously decreased out of side the pH range. Urea-induced changes in EGX at pH 5.4 and pH 8.0 were measured by intrinsic fluorescence and CD spectrum. At pH 5.4, a significantly red shift of emission maximum occurred when the concentration of urea was 5 M compared to the concentration was 3 M at pH 8.0. The alpha-helix at pH 5.4 was 40.51% in the absence of urea and 31.04% in the presence of 4 M urea. At pH 8.0 the alpha-helix was 7.23% in the presence of 4 M urea. The data indicated that EGX was much susceptible to urea-induced unfolding at pH 8.0 and much stable at pH 5.4. The greater pH dependent stability of EGX may allow the enzyme to adequately catalyze the hydrolysis of cellulosic materials under natural or industrial extreme conditions.