Integrated strategy of CRISPR-Cas9 gene editing and small RNA RhyB regulation in Enterobacter aerogenes: A novel protocol for improving biohydrogen production

Ping Lu , Yan Wu , Ruoxuan Bai , Ke Jiang , Fangxu Xu , Hongxin Zhao
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引用次数: 1

Abstract

Dark fermentation is considered as one of the most practical biological hydrogen production methods. However, current productivity and yield are still not economically viable for industrial applications. This biological process must be improved through multiple strategies, of which screening for more effective microbial strains is an important aspect. Here, based on the hydrogen production pathway of E. aerogenes, we describe three strategies to improve hydrogen production by effectively regulating the anaerobic metabolism of E. aerogenes through genetic modification. This protocol describes in detail how to obtain NADH dehydrogenase-damaged mutants and overexpress Nad synthase genes using the CRISPR-Cas9 gene editing system. In addition, the overexpression of small RNA RyhB was achieved and verified by Northern Blot. This protocol is of great significance for the study of genetic engineering operation in E. aerogenes and other bacteria, and also provides theoretical guidance and technical support for the study of E. aerogenes biological hydrogen production.

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产气肠杆菌CRISPR-Cas9基因编辑和小RNA RhyB调控的整合策略:提高生物制氢的新方案
暗发酵被认为是最实用的生物制氢方法之一。然而,目前的生产力和产量在经济上仍然不适合工业应用。这一生物过程必须通过多种策略来改进,其中筛选更有效的微生物菌株是一个重要方面。本文以产氢荚膜荚膜荚膜荚膜荚膜荚膜荚膜荚膜荚膜荚膜荚膜荚膜荚膜荚膜荚膜荚膜荚膜荚膜荚膜荚膜荚膜荚膜荚膜。本方案详细描述了如何利用CRISPR-Cas9基因编辑系统获得NADH脱氢酶损伤突变体和过表达NADH合成酶基因。此外,还实现了小RNA RyhB的过表达,并通过Northern Blot进行了验证。该方案对产气荚膜荚膜菌等细菌的基因工程操作研究具有重要意义,也为产气荚膜荚膜菌生物制氢研究提供理论指导和技术支持。
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