Analysis of metabolic network disruption in engineered microbial hosts due to enzyme promiscuity

IF 3.7 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Metabolic Engineering Communications Pub Date : 2021-06-01 DOI:10.1016/j.mec.2021.e00170
Vladimir Porokhin , Sara A. Amin , Trevor B. Nicks , Venkatesh Endalur Gopinarayanan , Nikhil U. Nair , Soha Hassoun
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引用次数: 5

Abstract

Increasing understanding of metabolic and regulatory networks underlying microbial physiology has enabled creation of progressively more complex synthetic biological systems for biochemical, biomedical, agricultural, and environmental applications. However, despite best efforts, confounding phenotypes still emerge from unforeseen interplay between biological parts, and the design of robust and modular biological systems remains elusive. Such interactions are difficult to predict when designing synthetic systems and may manifest during experimental testing as inefficiencies that need to be overcome. Transforming organisms such as Escherichia coli into microbial factories is achieved via several engineering strategies, used individually or in combination, with the goal of maximizing the production of chosen target compounds. One technique relies on suppressing or overexpressing selected genes; another involves introducing heterologous enzymes into a microbial host. These modifications steer mass flux towards the set of desired metabolites but may create unexpected interactions. In this work, we develop a computational method, termed Metabolic Disruption Workflow (MDFlow), for discovering interactions and network disruptions arising from enzyme promiscuity – the ability of enzymes to act on a wide range of molecules that are structurally similar to their native substrates. We apply MDFlow to two experimentally verified cases where strains with essential genes knocked out are rescued by interactions resulting from overexpression of one or more other genes. We demonstrate how enzyme promiscuity may aid cells in adapting to disruptions of essential metabolic functions. We then apply MDFlow to predict and evaluate a number of putative promiscuous reactions that can interfere with two heterologous pathways designed for 3-hydroxypropionic acid (3-HP) production. Using MDFlow, we can identify putative enzyme promiscuity and the subsequent formation of unintended and undesirable byproducts that are not only disruptive to the host metabolism but also to the intended end-objective of high biosynthetic productivity and yield. As we demonstrate, MDFlow provides an innovative workflow to systematically identify incompatibilities between the native metabolism of the host and its engineered modifications due to enzyme promiscuity.

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酶乱交导致工程微生物宿主代谢网络中断的分析
对微生物生理学基础上的代谢和调控网络的日益了解,使越来越复杂的合成生物系统能够用于生化、生物医学、农业和环境应用。然而,尽管尽了最大的努力,混淆表型仍然出现在不可预见的生物部分之间的相互作用,稳健和模块化的生物系统的设计仍然难以捉摸。这种相互作用在设计合成系统时很难预测,并可能在实验测试中表现为需要克服的低效率。将大肠杆菌等生物转化为微生物工厂是通过几种工程策略来实现的,这些策略可以单独使用,也可以组合使用,目的是使选定的目标化合物的产量最大化。一种技术依赖于抑制或过度表达选定的基因;另一种方法是将异源酶引入微生物宿主。这些修饰将质量通量导向所需的代谢物集,但可能产生意想不到的相互作用。在这项工作中,我们开发了一种称为代谢破坏工作流(MDFlow)的计算方法,用于发现酶滥交引起的相互作用和网络破坏-酶作用于结构上与其天然底物相似的广泛分子的能力。我们将MDFlow应用于两个经过实验验证的案例,其中必需基因被敲除的菌株通过一个或多个其他基因过表达引起的相互作用而获救。我们展示了酶乱交如何帮助细胞适应基本代谢功能的破坏。然后,我们应用MDFlow来预测和评估一些可能干扰3-羟基丙酸(3-HP)生产的两种异源途径的假定混杂反应。使用MDFlow,我们可以识别假定的酶乱交和随后形成的意外和不希望的副产物,这些副产物不仅破坏宿主代谢,而且破坏高生物合成生产力和产量的预期最终目标。正如我们所展示的,MDFlow提供了一种创新的工作流程,可以系统地识别宿主的天然代谢与其由于酶混杂而引起的工程修饰之间的不兼容性。
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来源期刊
Metabolic Engineering Communications
Metabolic Engineering Communications Medicine-Endocrinology, Diabetes and Metabolism
CiteScore
13.30
自引率
1.90%
发文量
22
审稿时长
18 weeks
期刊介绍: Metabolic Engineering Communications, a companion title to Metabolic Engineering (MBE), is devoted to publishing original research in the areas of metabolic engineering, synthetic biology, computational biology and systems biology for problems related to metabolism and the engineering of metabolism for the production of fuels, chemicals, and pharmaceuticals. The journal will carry articles on the design, construction, and analysis of biological systems ranging from pathway components to biological complexes and genomes (including genomic, analytical and bioinformatics methods) in suitable host cells to allow them to produce novel compounds of industrial and medical interest. Demonstrations of regulatory designs and synthetic circuits that alter the performance of biochemical pathways and cellular processes will also be presented. Metabolic Engineering Communications complements MBE by publishing articles that are either shorter than those published in the full journal, or which describe key elements of larger metabolic engineering efforts.
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