对代谢网络进行通量平衡分析,以实现微生物细胞工厂的高效工程设计。

IF 6.5 3区 工程技术 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Pramita Sen
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引用次数: 0

摘要

长期以来,代谢工程原理一直被用于探索复杂微生物细胞工厂在各种环境限制条件下的代谢网络,以便有效地部署微生物,优化生物燃料、聚合物、氨基酸、重组蛋白等生物化学品的生产。通量平衡分析法(FBA)是用于分析微生物代谢网络的方法之一,它采用优化技术预测生物量的增长和特定环境条件下工业重要产品的代谢通量分布。硅学通量模拟有助于设计针对特定生产的微生物细胞工厂。然而,FBA 有一些固有的局限性。本综述强调了如何将额外的动力学、热力学、表达和调控约束以及 omics 数据整合到经典的 FBA 平台中,从而提高 FBA 的预测准确性。为支持这一观点,还对模拟数据与实验观察结果进行了程序化比较。该综述进一步说明了经典 FBA 在生物技术应用中的成功实施,并指出了经典 FBA 无法做出正确预测的领域。对本文介绍的不同 FBA 策略预测能力的分析有望帮助研究人员找到工程化高效微生物代谢途径的新途径,并确定过程中的关键代谢瓶颈。基于适当的代谢网络设计,发酵工程师将能够有效地设计生物反应器,并通过适当的途径改造优化大规模生化生产。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Flux balance analysis of metabolic networks for efficient engineering of microbial cell factories.

Metabolic engineering principles have long been applied to explore the metabolic networks of complex microbial cell factories under a variety of environmental constraints for effective deployment of the microorganisms in the optimal production of biochemicals like biofuels, polymers, amino acids, recombinant proteins. One of the methodologies used for analyzing microbial metabolic networks is the Flux Balance Analysis (FBA), which employs applications of optimization techniques for forecasting biomass growth and metabolic flux distribution of industrially important products under specified environmental conditions. The in silico flux simulations are instrumental for designing the production-specific microbial cell factories. However, FBA has some inherent limitations. The present review emphasizes how the incorporation of additional kinetic, thermodynamic, expression and regulatory constraints and integration of omics data into the classical FBA platform improve the prediction accuracy of FBA. A programmed comparison of the simulated data with the experimental observations is presented for supporting the claim. The review further accounts for the successful implementation of classical FBA in biotechnological applications and identifies areas in which classical FBA fails to make correct predictions. The analysis of the predictive capabilities of the different FBA strategies presented here is expected to help researchers in finding new avenues in engineering highly efficient microbial metabolic pathways and identify the key metabolic bottlenecks during the process. Based on the appropriate metabolic network design, fermentation engineers will be able to effectively design the bioreactors and optimize large-scale biochemical production through suitable pathway modifications.

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来源期刊
Biotechnology & Genetic Engineering Reviews
Biotechnology & Genetic Engineering Reviews BIOTECHNOLOGY & APPLIED MICROBIOLOGY-GENETICS & HEREDITY
CiteScore
6.50
自引率
3.10%
发文量
33
期刊介绍: Biotechnology & Genetic Engineering Reviews publishes major invited review articles covering important developments in industrial, agricultural and medical applications of biotechnology.
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