Conductive proteins‐based extracellular electron transfer of electroactive microorganisms

IF 0.6 4区生物学 Q4 MATHEMATICAL & COMPUTATIONAL BIOLOGY Quantitative Biology Pub Date : 2023-11-27 DOI:10.1002/qub2.24

Junqi Zhang, Zixuan You, Dingyuan Liu, Rui Tang, Chao Zhao, Yingxiu Cao, Feng Li, Hao-Qing Song

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Abstract

Electroactive microorganisms (EAMs) could utilize extracellular electron transfer (EET) pathways to exchange electrons and energy with their external surroundings. Conductive cytochrome proteins and nanowires play crucial roles in controlling electron transfer rate from cytosol to extracellular electrode. Many previous studies elucidated how the c‐type cytochrome proteins and conductive nanowires are synthesized, assembled, and engineered to manipulate the EET rate, and quantified the kinetic processes of electron generation and EET. Here, we firstly overview the electron transfer pathways of EAMs and quantify the kinetic parameters that dictating intracellular electron production and EET. Secondly, we systematically review the structure, conductivity mechanisms, and engineering strategies to manipulate conductive cytochromes and nanowire in EAMs. Lastly, we outlook potential directions for future research in cytochromes and conductive nanowires for enhanced electron transfer. This article reviews the quantitative kinetics of intracellular electron production and EET, and the contribution of engineered c‐type cytochromes and conductive nanowire in enhancing the EET rate, which lay the foundation for enhancing electron transfer capacity of EAMs.

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基于导电蛋白质的电活性微生物胞外电子转移

电活性微生物（EAMs）可利用细胞外电子传递（EET）途径与其外部环境交换电子和能量。导电细胞色素蛋白和纳米线在控制从细胞液到细胞外电极的电子传递速率方面发挥着关键作用。以往的许多研究阐明了c型细胞色素蛋白和导电纳米线是如何合成、组装和工程化以操纵电子传递速率的，并量化了电子产生和电子传递的动力学过程。在这里，我们首先概述了EAMs的电子传递途径，并量化了决定细胞内电子产生和EET的动力学参数。其次，我们系统地回顾了EAMs的结构、传导机制以及操纵导电细胞色素和纳米线的工程策略。最后，我们展望了用于增强电子传递的细胞色素和导电纳米线未来研究的潜在方向。本文综述了细胞内电子产生和电子传递的定量动力学，以及工程化c型细胞色素和导电纳米线在提高电子传递速率方面的贡献，为提高EAMs的电子传递能力奠定了基础。

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来源期刊

Quantitative Biology MATHEMATICAL & COMPUTATIONAL BIOLOGY-

CiteScore

5.00

自引率

3.20%

发文量

264

期刊介绍： Quantitative Biology is an interdisciplinary journal that focuses on original research that uses quantitative approaches and technologies to analyze and integrate biological systems, construct and model engineered life systems, and gain a deeper understanding of the life sciences. It aims to provide a platform for not only the analysis but also the integration and construction of biological systems. It is a quarterly journal seeking to provide an inter- and multi-disciplinary forum for a broad blend of peer-reviewed academic papers in order to promote rapid communication and exchange between scientists in the East and the West. The content of Quantitative Biology will mainly focus on the two broad and related areas: ·bioinformatics and computational biology, which focuses on dealing with information technologies and computational methodologies that can efficiently and accurately manipulate –omics data and transform molecular information into biological knowledge. ·systems and synthetic biology, which focuses on complex interactions in biological systems and the emergent functional properties, and on the design and construction of new biological functions and systems. Its goal is to reflect the significant advances made in quantitatively investigating and modeling both natural and engineered life systems at the molecular and higher levels. The journal particularly encourages original papers that link novel theory with cutting-edge experiments, especially in the newly emerging and multi-disciplinary areas of research. The journal also welcomes high-quality reviews and perspective articles.