Synergetic Enhancing the Soluble Expression of Thermotoga maritima α-Glucan Phosphorylase by Chemical Chaperones and Induction Condition Optimization

doi:10.13560/j.cnki.biotech.bull.1985.2020-1473

Abstract

Abstract:

In order to efficiently prepare α-glucan phosphorylase from Thermotoga maritima,a recombinant strain of producing α-glucan phosphorylase was constructed and the condition of fermentation was optimized. The preliminary study uncovered that the activity of the enzyme was only 5.2 U/mL when the recombinant strain was cultured under induction at 37℃ in shake flasks for 24 h. SDS-PAGE electrophoresis also revealed that the recombinant enzyme mostly existed as insoluble inclusion bodies,while the soluble protein in the supernatant was very low. In order to reduce the formation of inclusion body and to increase the soluble expression of recombinant α-glucan phosphorylase,both of the induction conditions and chaperones were optimized. Firstly,the induction conditions,including inducer types,inducer dosage,temperature,and induction time were optimized in shake flasks. Under optimized induction condition,the maximal enzyme activity reached 27.0 U/ml,which was 5.2 times of that before optimized. In addition,it also showed that the best chemical chaperone was inositol and the optimal dosage and additive time of inositol was 20 mmol/L and 0 h,the maximal enzyme activity was 62.0 U/mL,which was 11.9 times of that before optimized. However,the molecular chaperone plasmid（pG-KJE8,pGro7,pKJE7,pG-Tf2 and pTf16）did not enhance the soluble expression of recombinant α-glucan phosphorylase.

Key words: α-glucan phosphorylase, recombinant expression, optimization of induction conditions, molecular chaperones, chemical chaperones

DUAN Xu-guo, ZHANG Yu-hua, HUANG Ting-ting, DING Qian, LUAN Shu-yue, ZHU Qiu-yu. Synergetic Enhancing the Soluble Expression of Thermotoga maritima α-Glucan Phosphorylase by Chemical Chaperones and Induction Condition Optimization[J]. Biotechnology Bulletin, 2021, 37(8): 233-242.

Figures/Tables 7

Fig. 1 SDS-PAGE analysis of α-glucan phosphorylase pro-duced by the recombinant strains and the control strain M: protein standard; 1: soluble fraction of recombinant strain; 2: insoluble fraction of recombinant strain; 3: soluble fraction of the control strain; 4: insoluble fraction of the control strain

Fig. 2 Effect of lactose concentration on the recombinant strain growth and enzyme production (A) and the SDS-PAGE analysis of cell disruption supernatant of the recombinant strain (B)

Fig. 3 Effect of IPTG concentration on the recombinant strain growth and enzyme production (A) and the SDS-PAGE analysis of cell disruption supernatant of the recombinant strain (B)

Fig. 4 Effect of induction temperature on the recombinant strain growth and enzyme production (A) and the SDS-PAGE analysis of cell disruption supernatant of the recombinant strain (B)

Fig. 5 Effect of adding inducer at different times on the recombinant strain growth and enzyme production (A) and the SDS-PAGE analysis of cell disruption supernatant of the recombinant strain (B)

Fig. 6 Effect of different chemical chaperone (A) and inositol concentration (B) on the recombinant strain growth and enzyme production

Fig. 7 Growth curve and enzyme production curve of recombinant strain on the optimal condition

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