Modeling for understanding and engineering metabolism.

Q3 Biochemistry, Genetics and Molecular Biology

QRB Discovery Pub Date : 2025-02-18 eCollection Date: 2025-01-01 DOI:10.1017/qrd.2025.1

Jens Nielsen, Dina Petranovic

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Abstract

Metabolism is at the core of all functions of living cells as it provides Gibbs free energy and building blocks for synthesis of macromolecules, which are necessary for structures, growth, and proliferation. Metabolism is a complex network composed of thousands of reactions catalyzed by enzymes involving many co-factors and metabolites. Traditionally it has been difficult to study metabolism as a whole network and most traditional efforts were therefore focused on specific metabolic pathways, enzymes, and metabolites. By using engineering principles of mathematical modeling to analyze and study metabolism, as well as engineer it, that is, design and build, new metabolic features, it is possible to gain many new fundamental insights as well as applications in biotechnology. Here, we present the history and basic principles of engineering metabolism, as well as the newest developments in the field. We are using examples of applications in: (1) production of protein pharmaceuticals and chemicals; (2) basic studies of metabolism; and (3) impacting health care. We will end by discussing how engineering metabolism can benefit from advances in artificial intelligence (AI)-based models.

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为理解和工程代谢建模。

代谢是活细胞所有功能的核心，因为它提供吉布斯自由能和合成大分子的基石，而大分子是结构、生长和增殖所必需的。代谢是由酶催化的数千种反应组成的复杂网络，涉及许多辅助因子和代谢物。传统上很难将代谢作为一个整体网络来研究，因此大多数传统的努力都集中在特定的代谢途径、酶和代谢物上。通过使用数学建模的工程原理来分析和研究代谢，并对其进行工程化，即设计和构建新的代谢特征，有可能获得许多新的基本见解以及在生物技术中的应用。在这里，我们介绍了工程代谢的历史和基本原理，以及该领域的最新发展。我们使用的应用示例包括：(1)蛋白质药物和化学品的生产；(2)代谢基础研究；(3)影响医疗保健。最后，我们将讨论工程代谢如何从基于人工智能（AI）的模型的进步中受益。

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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