Developing a genetic engineering method for Acetobacterium wieringae to expand one-carbon valorization pathways.

João P C Moreira, John T Heap, Joana I Alves, Lucília Domingues
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引用次数: 0

Abstract

Background: Developing new bioprocesses to produce chemicals and fuels with reduced production costs will greatly facilitate the replacement of fossil-based raw materials. In most fermentation bioprocesses, the feedstock usually represents the highest cost, which becomes the target for cost reduction. Additionally, the biorefinery concept advocates revenue growth from the production of several compounds using the same feedstock. Taken together, the production of bio commodities from low-cost gas streams containing CO, CO2, and H2, obtained from the gasification of any carbon-containing waste streams or off-gases from heavy industry (steel mills, processing plants, or refineries), embodies an opportunity for affordable and renewable chemical production. To achieve this, by studying non-model autotrophic acetogens, current limitations concerning low growth rates, toxicity by gas streams, and low productivity may be overcome. The Acetobacterium wieringae strain JM is a novel autotrophic acetogen that is capable of producing acetate and ethanol. It exhibits faster growth rates on various gaseous compounds, including carbon monoxide, compared to other Acetobacterium species, making it potentially useful for industrial applications. The species A. wieringae has not been genetically modified, therefore developing a genetic engineering method is important for expanding its product portfolio from gas fermentation and overall improving the characteristics of this acetogen for industrial demands.

Results: This work reports the development and optimization of an electrotransformation protocol for A. wieringae strain JM, which can also be used in A. wieringae DSM 1911, and A. woodii DSM 1030. We also show the functionality of the thiamphenicol resistance marker, catP, and the functionality of the origins of replication pBP1, pCB102, pCD6, and pIM13 in all tested Acetobacterium strains, with transformation efficiencies of up to 2.0 × 103 CFU/μgDNA. Key factors affecting electrotransformation efficiency include OD600 of cell harvesting, pH of resuspension buffer, the field strength of the electric pulse, and plasmid amount. Using this method, the acetone production operon from Clostridium acetobutylicum was efficiently introduced in all tested Acetobacterium spp., leading to non-native biochemical acetone production via plasmid-based expression.

Conclusions: A. wieringae can be electrotransformed at high efficiency using different plasmids with different replication origins. The electrotransformation procedure and tools reported here unlock the genetic and metabolic manipulation of the biotechnologically relevant A. wieringae strains. For the first time, non-native acetone production is shown in A. wieringae.

开发一种扩展单碳增殖途径的维氏醋酸杆菌基因工程方法。
背景:开发新的生物工艺以降低生产成本生产化学品和燃料将极大地促进化石原料的替代。在大多数发酵生物工艺中,原料通常是成本最高的,因此成为降低成本的目标。此外,生物精炼厂的概念主张通过使用相同的原料生产几种化合物来增加收入。总之,从含有CO、CO2和H2的低成本气体流中生产生物商品,这些气体流来自重工业(钢铁厂、加工厂或炼油厂)的任何含碳废物流或废气的气化,体现了经济实惠和可再生化学生产的机会。为了实现这一目标,通过研究非模式自养型醋酸菌,可以克服目前有关低生长速度、气流毒性和低生产力的限制。wieringae醋酸杆菌JM是一种新型的自养型醋酸菌,能够生产乙酸和乙醇。与其他醋酸杆菌相比,它在包括一氧化碳在内的各种气体化合物上表现出更快的生长速度,这使得它在工业应用中具有潜在的用途。该物种尚未进行过基因改造,因此开发一种基因工程方法对于扩大其气体发酵产品组合和全面改善该气体的特性以满足工业需求具有重要意义。结果:本工作建立并优化了一种电转化菌株JM的方案,该方案也可用于A. wieringae DSM 1911和A. woodii DSM 1030。我们还发现了硫霉素耐药标记catP的功能性,以及在所有测试的醋酸杆菌菌株中复制起始点pBP1、pCB102、pCD6和pIM13的功能性,转化效率高达2.0 × 103 CFU/μgDNA。影响电转化效率的关键因素包括细胞收获的OD600、再悬浮缓冲液的pH、电脉冲场强和质粒数量。利用该方法,将乙酰丁酸梭菌产丙酮操纵子有效地引入到所有被试醋酸杆菌中,通过质粒表达实现非天然生化产丙酮。结论:利用不同复制起点的质粒,可以高效电转化野乳杆菌。本文报道的电转化程序和工具解锁了与生物技术相关的A. wieringae菌株的遗传和代谢操作。首次在A. wieringae中发现了非天然丙酮生产。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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