• KSBB Journal
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• v.10 no.4
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• pp.374-385
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• 1995

Nutritional requirements and cultural conditions for the production of extracellular gelatin-degrading proteolytic enzyme by Bacillus subtilis B0021 were investigated. Optimum carbon source for proteolytic enzyme production was salicin, but it was substituted by glucose for economical reason. The fermentation medium giving a maximum proteolytic enzyme activity was consisted of 1.5%(w/v) glucose, 2.5%(w/v) yeast extract, and 0.001%(w/v) manganese sulfate and 0.002%(w/v) ferrous sulfate. Proteolytic enzyme activity of B. subtilis B0021 was completely inhibited by 0.5%(w/v) tannic acid. Initial pH was optimal at 7.0 and the enzyme activity in the flask culture usually reached a maximal level after 36 hours of fermentation at $30^{\circ}C$. In the $5\ell$ fermentor fermentation at $30^{\circ}C$, enzyme activity was maximum at 36 hour of cultivation but after this enzyme activity was decreased rapidly. Initial viscosity of 45%(w/v) gelatin(2,800mPas) was decreased rapidly to 96%(mPas) after hydrolysis for 4hr at $40^{\circ}C$ by crude enzyme of B. subtilis B0021.

• Journal of Life Science
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• v.24 no.10
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• pp.1110-1117
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• 2014

Tidal flats are continuously contaminated by human activities. This study assessed the bioremediation efficiency of tidal flat soil using microcosm reactors and microorganisms originating from the tidal area. We screened 135 bacterial strains that produce extracellular enzymes from the tidal area located in the North port of Incheon bay. Two bacterial strains (Pseudoalteromonas sp. and IC35 Halothiobacillus neapolitanus IC_S22) were selected and used in the microcosm reactors, which were specially designed to functionally mimic the ecological conditions of the tidal flats. Pseudoalteromonas sp. IC35 was selected based on its relatively high activity of the enzymes amylase, cellulose, lipase, and protease. Halothiobacillus neapolitanus IC_S22 was selected for oxidation of sulfur. The M1 and M2 microcosm reactors were operated by continuous feeding of seawater under the same conditions, but M2 was first inoculated with Pseudoalteromonas sp. IC35 before the seawater feeding. The initial COD in both the M1 and M2 microcosm reactors was 320 mg/l. The final COD was 21 mg/l (M1) and 7 mg/l (M2). The M3 and M4 microcosm reactors were operated by continuous feeding of seawater under the same conditions, but M4 was first inoculated with H. neapolitanus IC_S22. The initial sulfate concentration in both the M3 and M4 microcosm reactors was 660 mg/l, and the maximum sulfate concentration was 1,360 mg/l (M3) and 1,600 mg/l (M4).