Next-generation metabolic models informed by biomolecular simulations.

IF 7.1 2区工程技术 Q1 BIOCHEMICAL RESEARCH METHODS

Current opinion in biotechnology Pub Date : 2025-01-18 DOI:10.1016/j.copbio.2025.103259

Mohammed S Noor, Sakib Ferdous, Rahil Salehi, Hannah Gates, Supantha Dey, Vaishnavey S Raghunath, Mohammad R Zargar, Ratul Chowdhury

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Abstract

Metabolic modeling is essential for understanding the mechanistic bases of cellular metabolism in various organisms, from microbes to humans, and the design of fitter microbial strains. Metabolic networks focus on the overall fluxes through biochemical reactions that implicitly rely on several biochemical processes, such as active or diffusive uptake (or export) of nutrients (or metabolites), enzymatic turnover of metabolites, and metal-cofactor enzyme interactions. Despite independent progress in biomolecular simulations, they have yet to be integrated to inform metabolic models. We explore the evolution of computational metabolic modeling approaches, starting with flux balance analysis, dynamic, kinetic delineations of metabolic shifts in single organisms within cells and across tissues, and mutually informing, community-level modeling frameworks and provide a narrative to tie in biomolecular simulations and machine learning predictions to usher the new phase of structure-guided synthetic biology applications. These additions and prospective novel ones are likely to open hitherto untapped paradigms for optimizing/understanding metabolic pathways toward improving bioproduction of protein and small molecule products with downstream applications in health, environment, energy, and sustainability.

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基于生物分子模拟的下一代代谢模型。

代谢建模对于理解从微生物到人类的各种生物的细胞代谢机制基础以及设计更适合的微生物菌株至关重要。代谢网络关注的是通过生化反应的总体通量，这些生化反应隐含地依赖于几种生化过程，如营养物质（或代谢物）的活性或弥漫性摄取（或输出）、代谢物的酶代谢以及金属-辅因子酶的相互作用。尽管在生物分子模拟方面取得了独立的进展，但它们尚未被整合到代谢模型中。我们探索了计算代谢建模方法的演变，从通量平衡分析、细胞内和组织内单个生物体代谢变化的动态、动力学描述、相互通知的社区级建模框架开始，并提供了一种叙事方式，将生物分子模拟和机器学习预测联系起来，引领结构导向合成生物学应用的新阶段。这些新添加的和前瞻性的新内容可能会为优化/理解代谢途径开辟迄今尚未开发的范例，从而改善蛋白质和小分子产品的生物生产，并在健康、环境、能源和可持续性方面进行下游应用。

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

Current opinion in biotechnology 工程技术-生化研究方法

CiteScore

16.20

自引率

2.60%

发文量

226

审稿时长

4-8 weeks

期刊介绍： Current Opinion in Biotechnology (COBIOT) is renowned for publishing authoritative, comprehensive, and systematic reviews. By offering clear and readable syntheses of current advances in biotechnology, COBIOT assists specialists in staying updated on the latest developments in the field. Expert authors annotate the most noteworthy papers from the vast array of information available today, providing readers with valuable insights and saving them time. As part of the Current Opinion and Research (CO+RE) suite of journals, COBIOT is accompanied by the open-access primary research journal, Current Research in Biotechnology (CRBIOT). Leveraging the editorial excellence, high impact, and global reach of the Current Opinion legacy, CO+RE journals ensure they are widely read resources integral to scientists' workflows. COBIOT is organized into themed sections, each reviewed once a year. These themes cover various areas of biotechnology, including analytical biotechnology, plant biotechnology, food biotechnology, energy biotechnology, environmental biotechnology, systems biology, nanobiotechnology, tissue, cell, and pathway engineering, chemical biotechnology, and pharmaceutical biotechnology.