Sequencing, cloning, and heterologous expression of cyclomaltodextrin glucanotransferase of Bacillus firmus strain 37 in Bacillus subtilis WB800.

Bacillusfirmus strain 37 produces the cyclomaltodextrin glucanotransferase (CGTase) enzyme and CGTase produces cyclodextrins (CDs) through a starch cyclization reaction. The strategy for the cloning and expression of recombinant CGTase is a potentially viable alternative for the economically viable production of CGTase for use in industrial processes. The present study used Bacillus subtilis WB800 as a bacterial expression host for the production of recombinant CGTase cloned from the CGTase gene of B. firmus strain 37. The CGTase gene was cloned in TOPO-TA® plasmid, which was transformed in Escherichia coli DH5α. The subcloning was carried out with pWB980 plasmid and transformation in B. subtilis WB800. The 2xYT medium was the most suitable for the production of recombinant CGTase. The enzymatic activity of the crude extract of the recombinant CGTase of B. subtilis WB800 was 1.33 µmol ß-CD/min/mL, or 7.4 times greater than the enzymatic activity of the crude extract of CGTase obtained from the wild strain. Following purification, the recombinant CGTase exhibited an enzymatic activity of 157.78 µmol ß-CD/min/mL, while the activity of the CGTase from the wild strain was 9.54 µmol ß-CD/min/mL. When optimal CDs production conditions for the CGTase from B. firmus strain 37 were used, it was observed that the catalytic properties of the CGTase enzymes were equivalent. The strategy for the cloning and expression of CGTase in B. subtilis WB800 was efficient, with the production of greater quantities of CGTase than with the wild strain, offering essential data for the large-scale production of the recombinant enzyme.

Biosorption potential of synthetic dyes by heat-inactivated and live Lentinus edodes CCB-42 immobilized in loofa sponges.

Lentinus edodes CCB-42 was immobilized in loofa sponges and applied to the biosorption of the synthetic dyes congo red, bordeaux red and methyl violet. Live immobilized microorganisms achieved average decolorations of congo red, bordeaux red and methyl violet of 97.8, 99.7 and 90.6 %, respectively. The loofa sponge was the support and the coadjuvant promoting dye adsorption. The biosorption conditions were optimized for each dye, yielding 30 °C, pH 5.0 and a 12 h reaction time for congo red; 25 °C, pH 3.0 and 36 h for bordeaux red; and 25 °C, pH 8.0 and 24 h for methyl violet. Operational stability was evaluated over five consecutive cycles, with both bordeaux red and congo red exhibiting decolorations above 90 %, while the decoloration of methyl violet decreased after the third cycle. In the sixth month of storage, congo red, bordeaux red and methyl violet had decolorations of 93.1, 79.4 and 73.8 %, respectively. Biosorption process best fit the pseudo-second-order kinetic and Freundlich isotherm models. Maximum biosorption capacity of heat-treated L. edodes immobilized in loofa sponge was determined as 143.678, 500.00 and 381.679 mg/g for congo red, bordeaux red and methyl violet, respectively. Treatment with immobilized L. edodes reduced the phytotoxicity of the medium containing dyes. FT-Raman experiments suggested the occurrence of interactions between loofa sponge fibers, L. edodes and dye. L. edodes CCB-42 immobilized in loofa sponges represents a promising new mode of treatment of industrial effluents.