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Cellulase enzyme has shown their potential application in different industry. cellulase immobilization is one of the different methods for enzymatic stabilization. An advantage of immobilization is enzymatic reusability, which have an economical advantage for enzyme using in industry. Properties of Chitosan as a support for enzyme immobilization are always considerable. Due to its unique biological properties such as biocompability, biodegradability and non-toxicity, chitosan is an attractive support for immobilization. In this investigation Aa-cel9A endoglucanase gene was cloned in pET28 (+) expression vector. Sequencing result had been proved gene cloning in vector. Then the constructed vector was transformed to Eshershia.Coli (BL21) cells and enzyme production was induced. The result obtained from SDS-PAGE analysis and enzymatic assay showed the recombinant protein has been expressed and protein purification was done with Ni-NTA column. Chitosan macrobeads were prepared by precipitation procedure. After immobilization of enzyme with glutaraldehyde as linker, enzyme immobilization has been proved with FTIR and Bradford analysis. The obtained result showed optimum condition for covalent immobization on support are 0.7% of glutaraldehyde concentration and sodium phosphate buffer with pH 7. Bradford analysis and enzymatic activity assay have proved 85% of enzyme molecules immobilized on support.

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Objective: Organophosphorus hydrolase (OPH) is a homodimeric enzyme that can hydrolyze phosphoester bonds and reduce the toxicity of organophosphorus compounds. This makes OPH a suitable element for the biodegradation of these compounds. Methods: We successfully cloned the OPH gene from Pseudomonas diminuta, after optimization for Pichia pastoris, into a yeast expression vector (pPICZαB). After transformation and induction of recombinant yeasts, the expressed enzyme was investigated for its biochemical and kinetical parameters. Results: The enzyme was purified 7.49-fold to a specific activity of 0.421×10³ U/mg protein from the supernatant with a yield of 33%. The purified enzyme was able to degrade organophosphates. It had an optimal activity and stability up to 50°C, and a pH range of 7.0-10.0. The enzyme had a Km of 45.96 µM and a Vmax of 11.23 µM/min (421 µM/min/mg) for paraoxon as a substrate. This enzyme was sensitive to divalent cations and inactivated by denaturing compounds such as SDS. The molecular mass of the purified enzyme as estimated by SDS–PAGE analysis was approximately 40 kDa. Conclusion: In this study, the purified enzyme effectively hydrolyzed paraoxon, an organophosphorus compound. The activity and stability of this enzyme at high temperatures and pH, and low Km in comparision with bacterial isolates could make it an attractive biocatalyst for applied bioremediation and biosensing