在酵母中表达细菌纤维二糖酶使草汁的同步糖化和发酵生产生物乙醇成为可能。

Expression of bacterial levanase in yeast enables simultaneous saccharification and fermentation of grass juice to bioethanol.

机构信息

Institute of Life Science and School of Medicine, Swansea University, Swansea SA2 8PP, Wales, UK.

出版信息

Bioresour Technol. 2011 Jan;102(2):1503-8. doi: 10.1016/j.biortech.2010.07.099. Epub 2010 Jul 29.

DOI:10.1016/j.biortech.2010.07.099

PMID:20801645

Abstract

This study demonstrates use of recombinant yeast to simultaneously saccharify and ferment grass juice (GJ) to bioethanol. A modified Bacillus subtilis levanase gene (sacC) in which the native bacterial signal sequence was replaced with a yeast α-factor domain, was synthesised with yeast codon preferences and transformed into Saccharomyces cerevisiae (strain AH22) using the expression vector pMA91. AH22:psacC transformants secreted sacCp as an active, hyper-glycosylated (>180 kDa) protein allowing them to utilise inulin (β[2-1] linked fructose) and levan (β[2-6] linkages) as growth substrates. The control (AH22:pMA91) strain, transformed with empty plasmid DNA was not able to utilise inulin or levan. When cultured on untreated GJ levels of growth and bioethanol production were significantly higher in experiments with AH22:psacC than with AH22:pMA91. Bioethanol yields from AH22:psacC grown on GJ (32.7[±4] mg mL(-1)) compared closely to those recently achieved (Martel et al., 2010) using enzymatically pre-hydrolysed GJ (36.8[±4] mg mL(-1)).

摘要

本研究展示了利用重组酵母同时糖化和发酵草汁（GJ）生产生物乙醇的方法。我们合成了一种经过修饰的枯草芽孢杆菌纤维二糖酶基因（sacC），其中将天然细菌信号序列替换为酵母α因子结构域，并根据酵母密码子偏好性进行了优化，然后使用表达载体 pMA91 将其转化入酿酒酵母（AH22 菌株）中。AH22:psacC 转化体分泌的 sacCp 是一种具有活性的、高度糖基化的（>180 kDa）蛋白，使其能够利用菊粉（β[2-1] 连接果糖）和果聚糖（β[2-6] 键）作为生长基质。用空质粒 DNA 转化的对照（AH22:pMA91）菌株则无法利用菊粉或果聚糖。在未处理的 GJ 上培养时，与 AH22:pMA91 相比，AH22:psacC 的生长和生物乙醇产量显著更高。从 AH22:psacC 在 GJ 上生长获得的生物乙醇产量（32.7[±4] mg mL(-1))与最近使用酶法预先水解的 GJ（36.8[±4] mg mL(-1))所达到的产量（Martel 等人，2010）非常接近。

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在酵母中表达细菌纤维二糖酶使草汁的同步糖化和发酵生产生物乙醇成为可能。

Expression of bacterial levanase in yeast enables simultaneous saccharification and fermentation of grass juice to bioethanol.

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