Optimization of Cellulolytic Enzyme Components Through Engineering and On-site Fermentation Using the Soluble Inducer for Cellulosic Ethanol Production from Corn Stover

Overview

Journal Biotechnol Biofuels

Publisher Biomed Central

Specialty Biotechnology

Date 2018 Feb 28

PMID 29483942

Citations 7

Authors

Yong-Hao Li

Xiao-Yue Zhang

Fei Zhang

Liang-Cai Peng

Da-Bing Zhang

Akihiko Kondo

Feng-Wu Bai

Xin-Qing Zhao

Affiliations

Soon will be listed here.

Abstract

Background: Cellulolytic enzymes produced by are widely studied for biomass bioconversion, and enzymatic components vary depending on different inducers. In our previous studies, a mixture of glucose and disaccharide (MGD) was developed and used to induce cellulase production. However, the enzymatic profile induced by MGD is still not defined, and further optimization of the enzyme cocktail is also required for efficient ethanol production from lignocellulosic biomass.

Results: In this study, cellulolytic enzymes produced by Rut C30 using MGD and alkali-pretreated corn stover (APCS) as inducer were compared. Cellular secretome in response to each inducer was analyzed, which revealed a similar enzyme profile. However, significant difference in the content of cellulases and xylanase was detected. Although MGD induction enhanced β-glucosidase production, its activity was still not sufficient for biomass hydrolysis. To overcome such a disadvantage, encoding β-glucosidase in was heterologously expressed in Rut C30 under the control of the promoter. The recombinant PB-3 strain showed an improved β-glucosidase activity of 310 CBU/mL in the fed-batch fermentation, 71-folds higher than that produced by the parent strain. Meanwhile, cellulase activity of 50 FPU/mL was detected. Subsequently, the crude enzyme was applied for hydrolyzing corn stover with a solid loading of 20% through separate hydrolysis and fermentation (SHF) and simultaneous saccharification and fermentation, respectively, for ethanol production. Better performance was observed in the SHF process, through which a total of 119.9 g/L glucose was released within 12 h for concomitant ethanol production of 54.2 g/L.

Conclusions: The similar profile of cellulolytic enzymes was detected under the induction of MGD and APCS, but higher amount of cellulases was present in the crude enzyme induced by MGD. However, β-glucosidase activity induced by MGD was not sufficient for hydrolyzing lignocellulosic biomass. High titers of cellulases and β-glucosidase were achieved simultaneously by heterologous expression of in and fed-batch fermentation through feeding MGD. We demonstrated that on-site cellulase production by PB-3 has a potential for efficient biomass saccharification and ethanol production from lignocellulosic biomass.

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