Yan Su, Xu Yan, Yu Xiao-Wei
Key Laboratory of Industrial Biotechnology, Ministry of Education, School of Biotechnology, Jiangnan University, Wuxi, 214122, People's Republic of China.
Biotechnol Biofuels. 2021 Apr 8;14(1):90. doi: 10.1186/s13068-021-01943-9.
Filamentous fungus Trichoderma reesei has been widely used as a workhorse for cellulase and xylanase productions. Xylanase has been reported as the crucial accessory enzyme in the degradation of lignocellulose for higher accessibility of cellulase. In addition, the efficient hydrolysis of xylan needs the co-work of multiple xylanolytic enzymes, which rise an increasing demand for the high yield of xylanase for efficient biomass degradation.
In this study, a xylanase hyper-producing system in T. reesei was established by tailoring two transcription factors, XYR1 and ACE1, and homologous overexpression of the major endo-xylanase XYNII. The expressed xylanase cocktail contained 5256 U/mL xylanase activity and 9.25 U/mL β-xylosidase (pNPXase) activity. Meanwhile, the transcription level of the xylanolytic genes in the strain with XYR1 overexpressed was upregulated, which was well correlated with the amount of XYR1-binding sites. In addition, the higher expression of associated xylanolytic enzymes would result in more efficient xylan hydrolysis. Besides, 2310-3085 U/mL of xylanase activities were achieved using soluble carbon source, which was more efficient and economical than the traditional strategy of xylan induction. Unexpectedly, deletion of ace1 in C30OExyr1 did not give any improvement, which might be the result of the disturbed function of the complex formed between ACE1 and XYR1. The enzymatic hydrolysis of alkali pretreated corn stover using the crude xylanase cocktails as accessory enzymes resulted in a 36.64% increase in saccharification efficiency with the ratio of xylanase activity vs FPase activity at 500, compared to that using cellulase alone.
An efficient and economical xylanase hyper-producing platform was developed in T. reesei RUT-C30. The novel platform with outstanding ability for crude xylanase cocktail production would greatly fit in biomass degradation and give a new perspective of further engineering in T. reesei for industrial purposes.
丝状真菌里氏木霉已被广泛用作生产纤维素酶和木聚糖酶的主力菌株。木聚糖酶被报道为木质纤维素降解过程中的关键辅助酶,可提高纤维素酶的可及性。此外,木聚糖的高效水解需要多种木聚糖分解酶协同作用,这就对高产木聚糖酶以实现生物质的高效降解提出了越来越高的要求。
在本研究中,通过定制两个转录因子XYR1和ACE1以及主要内切木聚糖酶XYNII的同源过表达,在里氏木霉中建立了一个木聚糖酶高产系统。表达的木聚糖酶混合物含有5256 U/mL的木聚糖酶活性和9.25 U/mL的β-木糖苷酶(pNPXase)活性。同时,XYR1过表达菌株中木聚糖分解基因的转录水平上调,并与XYR1结合位点的数量密切相关。此外,相关木聚糖分解酶的更高表达会导致木聚糖水解更高效。此外,使用可溶性碳源可实现2310 - 3085 U/mL的木聚糖酶活性,这比传统的木聚糖诱导策略更高效、更经济。出乎意料的是,在C30OExyr1中缺失ace1并没有带来任何改善,这可能是ACE1和XYR1之间形成的复合物功能受到干扰的结果。以粗木聚糖酶混合物作为辅助酶对碱预处理玉米秸秆进行酶水解,与单独使用纤维素酶相比,糖化效率提高了36.64%,木聚糖酶活性与滤纸酶活性之比为500。
在里氏木霉RUT - C30中开发了一个高效且经济的木聚糖酶高产平台。这个具有出色粗木聚糖酶混合物生产能力的新平台将非常适合生物质降解,并为里氏木霉用于工业目的的进一步工程改造提供新的视角。
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