In silico and in vivo stability analysis of a heterologous biosynthetic pathway for 1,4-butanediol production in metabolically engineered E. coli

生物信息学 异源的 代谢工程 通量平衡分析 计算生物学 木糖 基因敲除 发酵 生物化学 大肠杆菌 合成生物学 生物 化学 生物合成 焊剂(冶金) 生物炼制 基因 生物技术 生物燃料 有机化学
作者
Ildikó Miklóssy,Zsolt Bodor,Réka Sinkler,Kálmán Csongor Orbán,Szabolcs Lányi,Beáta Albert
出处
期刊:Journal of Biomolecular Structure & Dynamics [Taylor & Francis]
卷期号:35 (9): 1874-1889 被引量:8
标识
DOI:10.1080/07391102.2016.1198721
摘要

Recently, several approaches have been published in order to develop a functional biosynthesis route for the non-natural compound 1,4-butanediol (BDO) in E. coli using glucose as a sole carbon source or starting from xylose. Among these studies, there was reported as high as 18 g/L product concentration achieved by industrial strains, however BDO production varies greatly in case of the reviewed studies. Our motivation was to build a simple heterologous pathway for this compound in E. coli and to design an appropriate cellular chassis based on a systemic biology approach, using constraint-based flux balance analysis and bi-level optimization for gene knock-out prediction. Thus, the present study reports, at the "proof-of concept" level, our findings related to model-driven development of a metabolically engineered E. coli strain lacking key genes for ethanol, lactate and formate production (ΔpflB, ΔldhA and ΔadhE), with a three-step biosynthetic pathway. We found this strain to produce a limited quantity of 1,4-BDO (.89 mg/L BDO under microaerobic conditions and .82 mg/L under anaerobic conditions). Using glycerol as carbon source, an approach, which to our knowledge has not been tackled before, our results suggest that further metabolic optimization is needed (gene-introductions or knock-outs, promoter fine-tuning) to address the redox potential imbalance problem and to achieve development of an industrially sustainable strain. Our experimental data on culture conditions, growth dynamics and fermentation parameters can consist a base for ongoing research on gene expression profiles and genetic stability of such metabolically engineered E. coli strains.
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