Redox-Driven Metabolic Shift in Clostridium acetobutylicum for Enhanced Butanol Production

IF 7.3 1区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

ACS Sustainable Chemistry & Engineering Pub Date : 2025-10-14 DOI:10.1021/acssuschemeng.5c06355

Akashdeep S. Oberoi, David Wendell, Maobing Tu

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Abstract

Butanol is a valuable industrial chemical and a potential transportation biofuel with superior fuel properties compared to ethanol. However, its production through traditional acetone–butanol–ethanol fermentation using Clostridium species is limited by the low titer, productivity, and yield. In this study, we employed a redox-based strategy to enhance butanol production by adding external electron shuttles. Various electron shuttles (anthraquinone-2-sulfonate, anthraquinone-1,5-disulfonic acid, riboflavin, methyl viologen, neutral red, and benzyl viologen) were screened for their ability to modulate intracellular redox states. Optimal concentrations and addition times were determined. We found that adding benzyl viologen (5 mg/L) at 0 h resulted in the highest butanol titer of 15.2 ± 0.9 g/L and a yield of 0.29 g/g, representing a 1.4- and 1.5-fold increase in titer and yield, respectively, compared to the control. The results suggest that the inherent redox potential of the electron shuttles plays a key role in redirecting metabolic fluxes toward reduced end-products (butanol and ethanol) by altering electron transfer pathways. To explore the underlying mechanisms, GC–MS-based metabolomics was used to study global metabolic shifts following the addition of benzyl viologen. Specifically, the upregulation of amino acids such as tryptophan and aspartic acid may enhance NADH biosynthesis. Electron shuttles likely divert electron flow from ferredoxin to NADH regeneration, thereby increasing butanol production. Overall, this study offers mechanistic insights and a potential approach for using redox-active electron shuttles to improve butanol production through metabolic redirection.

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氧化还原驱动的乙酰丁酸梭菌代谢转变促进丁醇生产

丁醇是一种有价值的工业化学品，与乙醇相比具有优越的燃料性能，是一种潜在的运输生物燃料。然而，传统的利用梭状芽孢杆菌进行丙酮-丁醇-乙醇发酵的生产受到低效价、低生产率和低产量的限制。在这项研究中，我们采用了一种基于氧化还原的策略，通过增加外部电子穿梭来提高丁醇的产量。筛选了各种电子穿梭体（蒽醌-2-磺酸、蒽醌-1,5-二磺酸、核黄素、甲基紫素、中性红和苄基紫素）调节细胞内氧化还原状态的能力。确定了最佳浓度和添加时间。我们发现，在0 h时添加5 mg/L的紫苄酯，丁醇滴度最高，为15.2±0.9 g/L，产量为0.29 g/g，滴度和产量分别比对照提高了1.4倍和1.5倍。结果表明，电子穿梭固有的氧化还原电位通过改变电子转移途径，在将代谢通量重定向到还原终产物（丁醇和乙醇）方面起着关键作用。为了探索潜在的机制，采用GC-MS-based代谢组学研究了添加紫苯酯后的全球代谢变化。具体来说，氨基酸如色氨酸和天冬氨酸的上调可能会促进NADH的生物合成。电子穿梭可能将电子流从铁氧还蛋白转移到NADH再生，从而增加丁醇的产量。总的来说，这项研究提供了利用氧化还原活性电子穿梭通过代谢重定向改善丁醇生产的机制见解和潜在方法。

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来源期刊

ACS Sustainable Chemistry & Engineering CHEMISTRY, MULTIDISCIPLINARY-ENGINEERING, CHEMICAL

CiteScore

13.80

自引率

4.80%

发文量

1470

审稿时长

1.7 months

期刊介绍： ACS Sustainable Chemistry & Engineering is a prestigious weekly peer-reviewed scientific journal published by the American Chemical Society. Dedicated to advancing the principles of green chemistry and green engineering, it covers a wide array of research topics including green chemistry, green engineering, biomass, alternative energy, and life cycle assessment. The journal welcomes submissions in various formats, including Letters, Articles, Features, and Perspectives (Reviews), that address the challenges of sustainability in the chemical enterprise and contribute to the advancement of sustainable practices. Join us in shaping the future of sustainable chemistry and engineering.