Contemporaneous Production of Amylase and Protease through CCD Response Surface Methodology by Newly Isolated Bacillus megaterium Strain B69.

Q2 Biochemistry, Genetics and Molecular Biology Enzyme Research Pub Date : 2014-01-01 Epub Date: 2014-11-12 DOI:10.1155/2014/601046
Rajshree Saxena, Rajni Singh
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Abstract

The enormous increase in world population has resulted in generation of million tons of agricultural wastes. Biotechnological process for production of green chemicals, namely, enzymes, provides the best utilization of these otherwise unutilized wastes. The present study elaborates concomitant production of protease and amylase in solid state fermentation (SSF) by a newly isolated Bacillus megaterium B69, using agroindustrial wastes. Two-level statistical model employing Plackett-Burman and response surface methodology was designed for optimization of various physicochemical conditions affecting the production of two enzymes concomitantly. The studies revealed that the new strain concomitantly produced 1242 U/g of protease and 1666.6 U/g of amylase by best utilizing mustard oilseed cake as the substrate at 20% substrate concentration and 45% moisture content after 84 h of incubation. An increase of 2.95- and 2.04-fold from basal media was observed in protease and amylase production, respectively. ANOVA of both the design models showed high accuracy of the polynomial model with significant similarities between the predicted and the observed results. The model stood accurate at the bench level validation, suggesting that the design model could be used for multienzyme production at mass scale.

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新分离的巨型芽孢杆菌菌株 B69 通过 CCD 响应面方法同时生产淀粉酶和蛋白酶
世界人口的大幅增长导致产生了数百万吨的农业废料。生产绿色化学品(即酶)的生物技术工艺为这些原本未被利用的废物提供了最佳利用方式。本研究阐述了新分离的巨型芽孢杆菌 B69 利用农业工业废料在固态发酵(SSF)中同时生产蛋白酶和淀粉酶的情况。采用普拉克特-伯曼和响应面方法设计了两级统计模型,用于优化影响两种酶同时生产的各种理化条件。研究表明,新菌株以芥子油籽饼为底物,在底物浓度为 20%、含水量为 45%的条件下,经过 84 小时的培养,可同时产生 1242 U/g 蛋白酶和 1666.6 U/g 淀粉酶。与基础培养基相比,蛋白酶和淀粉酶的产量分别增加了 2.95 倍和 2.04 倍。两个设计模型的方差分析显示,多项式模型具有很高的准确性,预测结果与观察结果之间具有显著的相似性。该模型在台架水平验证中准确无误,表明该设计模型可用于大规模多酶生产。
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Enzyme Research
Enzyme Research Biochemistry, Genetics and Molecular Biology-Biochemistry
CiteScore
4.60
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