Kinetic characteristics of beta-cyclodextrin production by cyclodextrin glycosyltransferase from newly isolated Bacillus sp. C26

The kinetic characteristics of beta-cyclodextrin production by a cyclodextrin glycosyltransferase (CGTase) produced by Bacillus sp. C26, a new isolate from a soil sample was investigated. Considering highest yield and initial production rate of beta-cyclodextrin, among the starches examined, soluble starch, tapioca starch, sago starch, corn starch and rice starch, tapioca starch was the best substrate for this CGTase. The optimum temperature for tapioca starch gelatinization prior to its use as a substrate for beta-cyclodextrin production was 65ºC. The yield and initial production rate of beta-cyclodextrin increased with increasing starch concentration up to 6 percent and an enzyme concentration up to 48 U/g-starch. The kinetic parameters of Vmax and Km of beta-cyclodextrin production from tapioca starch by CGTase were 1.59 mg/mL/h and 22.3 mg/mL, respectively. Considering high initial production rate and high yield of beta-cyclodextrin, the optimum reaction temperature was at 50ºC. This study provided the necessary kinetic information that may be useful to define the most suitable condition for industrialized production of beta-cyclodextrin with the high yield and productivity.

Response surface methodology used for statistical optimization of jiean-peptide production by Bacillus subtilis cells adsorbed on wood chips

Response surface methodology (RSM) was used for statistical optimization of jiean-peptide (JAA) production by Bacillus subtilis ZK8 cells adsorbed on wood chips to form a novel fermentation system. The Plackett-Burman design was used in the first step to evaluate the effects of eight factors, including six fermentation medium components and two cell adsorption conditions. Among the variables screened, soybean meal hydrolysate (SMH) and MgSO4A7H2O in the fermentation medium had significant effects on JAA production. In the second step, the concentrations of SMH and MgSO4A7H2O were further optimized using central composite designs and response surface analysis. The optimized concentration of SMH and MgSO4À7H2O was 24 percent (v/v) and 0.38 percent (w/v), respectively, which increased the production of JAA in a shake flask system by 41 percent relative to optimization of a single variable component of the culture medium.