In-Depth Computational Analysis of Natural and Artificial Carbon Fixation Pathways.

Q2 Agricultural and Biological Sciences
生物设计研究(英文) Pub Date : 2021-08-31 eCollection Date: 2021-01-01 DOI:10.34133/2021/9898316
Hannes Löwe, Andreas Kremling
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Abstract

In the recent years, engineering new-to-nature CO2- and C1-fixing metabolic pathways made a leap forward. New, artificial pathways promise higher yields and activity than natural ones like the Calvin-Benson-Bassham (CBB) cycle. The question remains how to best predict their in vivo performance and what actually makes one pathway "better" than another. In this context, we explore aerobic carbon fixation pathways by a computational approach and compare them based on their specific activity and yield on methanol, formate, and CO2/H2 considering the kinetics and thermodynamics of the reactions. Besides pathways found in nature or implemented in the laboratory, this included two completely new cycles with favorable features: the reductive citramalyl-CoA cycle and the 2-hydroxyglutarate-reverse tricarboxylic acid cycle. A comprehensive kinetic data set was collected for all enzymes of all pathways, and missing kinetic data were sampled with the Parameter Balancing algorithm. Kinetic and thermodynamic data were fed to the Enzyme Cost Minimization algorithm to check for respective inconsistencies and calculate pathway-specific activities. The specific activities of the reductive glycine pathway, the CETCH cycle, and the new reductive citramalyl-CoA cycle were predicted to match the best natural cycles with superior product-substrate yield. However, the CBB cycle performed better in terms of activity compared to the alternative pathways than previously thought. We make an argument that stoichiometric yield is likely not the most important design criterion of the CBB cycle. Still, alternative carbon fixation pathways were paretooptimal for specific activity and product-substrate yield in simulations with C1 substrates and CO2/H2 and therefore hold great potential for future applications in Industrial Biotechnology and Synthetic Biology.

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天然和人工碳固定途径的深度计算分析。
近年来,对新的天然CO2和C1固定代谢途径进行工程设计取得了飞跃性进展。与Calvin Benson Bassham(CBB)循环等天然途径相比,新的人工途径有望获得更高的产量和活性。问题仍然是如何最好地预测它们的体内表现,以及是什么让一种途径比另一种途径“更好”。在这种情况下,我们通过计算方法探索好氧固碳途径,并根据它们对甲醇、甲酸盐和CO2/H2的比活性和产率,考虑到反应的动力学和热力学,对它们进行比较。除了在自然界中发现或在实验室中实施的途径外,这包括两个具有有利特征的全新循环:还原性柠檬酰辅酶A循环和2-羟基戊二酸反式三羧酸循环。收集所有途径的所有酶的综合动力学数据集,并使用参数平衡算法对缺失的动力学数据进行采样。将动力学和热力学数据输入酶成本最小化算法,以检查各自的不一致性并计算途径特异性活性。预测了还原性甘氨酸途径、CETCH循环和新的还原性柠檬酰辅酶A循环的比活性,以匹配具有优异产物底物产率的最佳天然循环。然而,与先前认为的替代途径相比,CBB循环在活性方面表现更好。我们认为化学计量产率可能不是CBB循环最重要的设计标准。尽管如此,在C1底物和CO2/H2的模拟中,替代碳固定途径在比活性和产物底物产量方面是非最佳的,因此在工业生物技术和合成生物学的未来应用中具有巨大潜力。
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
CiteScore
3.90
自引率
0.00%
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0
审稿时长
12 weeks
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