Genome reduction improves octanoic acid production in scale down bioreactors

IF 5.7 2区 生物学 Microbial Biotechnology Pub Date : 2024-11-06 DOI:10.1111/1751-7915.70034
William T. Cordell, Gennaro Avolio, Ralf Takors, Brian F. Pfleger
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Abstract

Microorganisms in large-scale bioreactors are exposed to heterogeneous environmental conditions due to physical mixing constraints. Nutritional gradients can lead to transient expression of energetically wasteful stress responses and as a result, can reduce the titres, rates and yields of a bioprocess at larger scales. To what extent these process parameters are impacted is often unknown and therefore bioprocess scale-up comes with major risk. Designing platform strains to account for these intermittent stresses before introducing synthesis pathways is one strategy for de-risking bioprocess development. For example, Escherichia coli strain RM214 is a derivative of wild-type MG1655 that has had several genes and whole operons removed from its genome based on their metabolic cost. In this study, we engineered E. coli strain RM214 (referred to as WG02) to produce octanoic acid from glycerol in batch-flask and fed-batch bioreactor cultivations and compared it to an octanoic acid-producing E. coli MG1655 (WG01). In batch flask cultivations, the two strains performed similarly. However, in carbon limited fed-batch bioreactor cultivations, WG02 provided a greater than 22% boost to biomass compared to WG01 while maintaining similar titres of octanoic acid. Reducing the biomass accumulation of WG02 with nitrogen limited fed-batch cultivation resulted in a 16% improvement in octanoic acid titre over WG01. Finally, in a scale-down system consisting of a stirred tank reactor (representing a well-mixed zone) and plug flow reactor (representing an intermittent carbon starvation zone), WG02 again improved octanoic acid titre by almost 18% while maintaining similar biomass concentrations as WG01.

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减少基因组可提高缩比生物反应器中辛酸的产量。
由于物理混合的限制,大规模生物反应器中的微生物会暴露在不同的环境条件下。营养梯度会导致能量消耗大的应激反应的瞬时表达,从而降低大规模生物工艺的滴度、速率和产量。这些工艺参数受影响的程度往往是未知的,因此生物工艺的放大具有很大的风险。在引入合成途径之前设计平台菌株以应对这些间歇性压力,是降低生物工艺开发风险的一种策略。例如,大肠杆菌菌株 RM214 是野生型 MG1655 的衍生物,根据其代谢成本从基因组中删除了多个基因和整个操作子。在本研究中,我们改造了大肠杆菌菌株 RM214(简称 WG02),使其能够在批次烧瓶和喂料批次生物反应器培养中从甘油中生产辛酸,并将其与生产辛酸的大肠杆菌 MG1655(WG01)进行了比较。在间歇式烧瓶培养过程中,这两种菌株的表现相似。然而,在限碳喂料批量生物反应器培养中,WG02 的生物量比 WG01 提高了 22% 以上,同时辛酸滴度保持相似。通过限氮喂料批次培养减少 WG02 的生物量积累,辛酸滴度比 WG01 提高了 16%。最后,在一个由搅拌罐反应器(代表充分混合区)和塞流反应器(代表间歇性碳饥饿区)组成的缩小系统中,WG02 再次将辛酸滴度提高了近 18%,同时保持了与 WG01 相似的生物量浓度。
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来源期刊
Microbial Biotechnology
Microbial Biotechnology Immunology and Microbiology-Applied Microbiology and Biotechnology
CiteScore
11.20
自引率
3.50%
发文量
162
审稿时长
1 months
期刊介绍: Microbial Biotechnology publishes papers of original research reporting significant advances in any aspect of microbial applications, including, but not limited to biotechnologies related to: Green chemistry; Primary metabolites; Food, beverages and supplements; Secondary metabolites and natural products; Pharmaceuticals; Diagnostics; Agriculture; Bioenergy; Biomining, including oil recovery and processing; Bioremediation; Biopolymers, biomaterials; Bionanotechnology; Biosurfactants and bioemulsifiers; Compatible solutes and bioprotectants; Biosensors, monitoring systems, quantitative microbial risk assessment; Technology development; Protein engineering; Functional genomics; Metabolic engineering; Metabolic design; Systems analysis, modelling; Process engineering; Biologically-based analytical methods; Microbially-based strategies in public health; Microbially-based strategies to influence global processes
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