A machine learning-based approach for improving plasmid DNA production in Escherichia coli fed-batch fermentations

IF 3.2 3区 生物学 Q2 BIOCHEMICAL RESEARCH METHODS Biotechnology Journal Pub Date : 2024-06-19 DOI:10.1002/biot.202400140
Zhixian Xu, Xiaofeng Zhu, Ali Mohsin, Jianfei Guo, Yingping Zhuang, Ju Chu, Meijin Guo, Guan Wang
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Abstract

Artificial Intelligence (AI) technology is spearheading a new industrial revolution, which provides ample opportunities for the transformational development of traditional fermentation processes. During plasmid fermentation, traditional subjective process control leads to highly unstable plasmid yields. In this study, a multi-parameter correlation analysis was first performed to discover a dynamic metabolic balance among the oxygen uptake rate, temperature, and plasmid yield, whilst revealing the heating rate and timing as the most important optimization factor for balanced cell growth and plasmid production. Then, based on the acquired on-line parameters as well as outputs of kinetic models constructed for describing process dynamics of biomass concentration, plasmid yield, and substrate concentration, a machine learning (ML) model with Random Forest (RF) as the best machine learning algorithm was established to predict the optimal heating strategy. Finally, the highest plasmid yield and specific productivity of 1167.74 mg L−1 and 8.87 mg L−1/OD600 were achieved with the optimal heating strategy predicted by the RF model in the 50 L bioreactor, respectively, which was 71% and 21% higher than those obtained in the control cultures where a traditional one-step temperature upshift strategy was applied. In addition, this study transformed empirical fermentation process optimization into a more efficient and rational self-optimization method. The methodology employed in this study is equally applicable to predict the regulation of process dynamics for other products, thereby facilitating the potential for furthering the intelligent automation of fermentation processes.

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一种基于机器学习的方法,用于提高大肠杆菌间歇发酵过程中质粒 DNA 的产量。
人工智能(AI)技术正在引领一场新的工业革命,为传统发酵工艺的转型发展提供了大量机遇。在质粒发酵过程中,传统的主观过程控制导致质粒产量极不稳定。在本研究中,首先进行了多参数相关分析,发现了氧气吸收率、温度和质粒产量之间的动态代谢平衡,同时揭示了加热速率和时间是实现细胞生长和质粒产量平衡的最重要优化因素。然后,根据获得的在线参数以及为描述生物质浓度、质粒产量和底物浓度的过程动态而构建的动力学模型的输出结果,建立了一个以随机森林(RF)为最佳机器学习算法的机器学习(ML)模型,以预测最佳加热策略。最后,在 50 L 生物反应器中,采用 RF 模型预测的最佳加热策略获得了最高的质粒产量和比生产率,分别为 1167.74 mg L-1 和 8.87 mg L-1/OD600,比采用传统的一步升温策略的对照培养物分别高出 71% 和 21%。此外,本研究还将经验发酵过程优化转化为一种更高效、更合理的自我优化方法。本研究采用的方法同样适用于预测其他产品的过程动态调节,从而为进一步实现发酵过程的智能自动化提供了可能。
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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来源期刊
Biotechnology Journal
Biotechnology Journal Biochemistry, Genetics and Molecular Biology-Molecular Medicine
CiteScore
8.90
自引率
2.10%
发文量
123
审稿时长
1.5 months
期刊介绍: Biotechnology Journal (2019 Journal Citation Reports: 3.543) is fully comprehensive in its scope and publishes strictly peer-reviewed papers covering novel aspects and methods in all areas of biotechnology. Some issues are devoted to a special topic, providing the latest information on the most crucial areas of research and technological advances. In addition to these special issues, the journal welcomes unsolicited submissions for primary research articles, such as Research Articles, Rapid Communications and Biotech Methods. BTJ also welcomes proposals of Review Articles - please send in a brief outline of the article and the senior author''s CV to the editorial office. BTJ promotes a special emphasis on: Systems Biotechnology Synthetic Biology and Metabolic Engineering Nanobiotechnology and Biomaterials Tissue engineering, Regenerative Medicine and Stem cells Gene Editing, Gene therapy and Immunotherapy Omics technologies Industrial Biotechnology, Biopharmaceuticals and Biocatalysis Bioprocess engineering and Downstream processing Plant Biotechnology Biosafety, Biotech Ethics, Science Communication Methods and Advances.
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