在我的预培养物中添加氧化铝微粒可提高纤维素酶的产量并影响真菌形态。

Addition of aluminum oxide microparticles to My preculture enhances cellulase production and influences fungal morphology.

作者信息

Dong Miaoyin, Wang Shuyang, Xu Fuqiang, Li Qiaoqiao, Li Wenjian

机构信息

Institute of Modern Physics Chinese Academy of Sciences Lanzhou Gansu P. R. China.

College of Life Science University of Chinese Academy of Sciences Beijing P. R. China.

出版信息

Eng Life Sci. 2018 Feb 22;18(6):353-358. doi: 10.1002/elsc.201700188. eCollection 2018 Jun.

DOI:10.1002/elsc.201700188

PMID:32624915

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6999258/

Abstract

Morphological engineering techniques have recently become popular, since they are used to increase the production of a variety of metabolites and enzymes when fungi are grown in submerged cultures. This study aimed to facilitate cellulase production by adding aluminum oxide to My precultures. The results showed that the highest cellulase activity was achieved when aluminum oxide at 10 g/L was used, and the activities of cellulase for filter paper and endoglucanase activity assays increased from 519.11 to 607.35 U/mL by 17.1%, and from 810.08 U/mL to 917.59 U/mL by 13.3%, compared with the control, respectively. Addition of aluminum oxide decreased the size of My pellets and increased the final pH. The changes in pellet diameter after the addition of different concentrations of aluminum oxide were fitted using a modified exponential decay model, which could precisely predict the pellet size by controlling aluminum oxide concentration. The optimum concentration of microparticles, and therefore pellet size, could significantly improve cellulase production, which is an encouraging step towards commercial cellulase production.

摘要

形态工程技术最近变得很流行，因为当真菌在深层培养中生长时，它们被用于提高各种代谢产物和酶的产量。本研究旨在通过向预培养物中添加氧化铝来促进纤维素酶的产生。结果表明，当使用10 g/L的氧化铝时，纤维素酶活性最高，与对照相比，滤纸纤维素酶活性测定和内切葡聚糖酶活性测定的纤维素酶活性分别从519.11 U/mL增加到607.35 U/mL，增幅为17.1%，从810.08 U/mL增加到917.59 U/mL，增幅为13.3%。添加氧化铝减小了米曲霉菌球的大小并提高了最终pH值。使用修正的指数衰减模型拟合添加不同浓度氧化铝后菌球直径的变化，该模型可以通过控制氧化铝浓度精确预测菌球大小。微粒的最佳浓度以及因此的菌球大小可以显著提高纤维素酶的产量，这是朝着商业生产纤维素酶迈出的令人鼓舞的一步。

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