All-in-One CO2 Capture and Transformation: Lessons from Formylmethanofuran Dehydrogenases.

IF 16.4 1区 化学 Q1 CHEMISTRY, MULTIDISCIPLINARY
Accounts of Chemical Research Pub Date : 2024-12-17 Epub Date: 2024-11-25 DOI:10.1021/acs.accounts.4c00623
Olivier N Lemaire, Tristan Wagner
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引用次数: 0

Abstract

ConspectusCarbon-one-unit (C1) feedstocks are generally used in the chemical synthesis of organic molecules, such as solvents, drugs, polymers, and fuels. Contrary to the dangerous and polluting carbon monoxide mostly coming from fossil fuels, formate and formamide are attractive alternative feedstocks for chemical synthesis. As these are currently mainly obtained from the oil industry, novel synthetic routes have been developed based on the transformation of the greenhouse gas CO2. Such developments are motivated by the urgent need for carbon chemical recycling, leading to a sustainable future. The inert nature of CO2 represents a challenge for chemists to activate and specifically convert the molecule through an affordable and efficient process. The chemical transformation could be inspired by biological CO2 activation, in which highly specialized enzymes perform atmospheric CO2 fixation through relatively abundant metal catalysts. In this Account, we describe and discuss the potential of one of the most efficient biological CO2-converting systems: the formylmethanofuran dehydrogenase (abbreviated as FMD).FMDs are multienzymatic complexes found in archaea that capture CO2 as a formyl group branched on the amine moiety of the methanofuran (MFR) cofactor. This overall reaction leading to formyl-MFR production does not require ATP hydrolysis as compared to the CO2-fixing microbes relying on the reductive Wood-Ljungdahl pathway, highlighting a different operative mode that saves cellular energy. FMD reaction represents the entry point in hydrogenotrophic methanogenesis (H2 and CO2 dependent or formate dependent) and operates in reverse in other methanogenic pathways and microbial metabolisms. Therefore, FMD is a key enzyme in the planetary carbon cycle. After decades of investigations, recent studies have provided a description of the FMD structure, reaction mechanism, and potential for the electroreduction of CO2, to which our laboratory has been actively contributing.FMD is an "all-in-one" enzyme catalyzing a redox-active transformation coupled to a redox-neutral transformation at two very different metal cofactors where new C-H and C-N bonds are made. First, the principle of the overall reaction consisting of an exergonic CO2 reduction coupled with an endergonic formate condensation on MFR is resumed. Then, this Account exposes the molecular details of the active sites and provides an overview of each catalytic mechanism. It also describes the natural versatility of electron-delivery modules fueling CO2 reduction and extends it to the possibilities of using artificial systems such as electrodes.A perspective concludes on how the mechanistic of FMD could be applied to produce CO2-based chemical intermediates to synthesize organic molecules. Indeed, through its biochemical properties, the enzyme opens opportunities for CO2 electroreduction to generate molecules such as formate and formamide derivatives, which are all intermediates for synthesizing organic compounds. Transferring the chemical knowledge acquired from these biological systems would provide coherent models that can lead to further development in the field of synthetic biology and bio-inspired synthetic chemistry to perform large-scale CO2 conversion into building blocks for chemical synthesis.

一体化二氧化碳捕获和转化:甲酰甲呋喃脱氢酶的启示。
Conspectus 碳单质(C1)原料通常用于有机分子(如溶剂、药物、聚合物和燃料)的化学合成。一氧化碳主要来自化石燃料,具有危险性和污染性,与之相反,甲酸酯和甲酰胺是化学合成中极具吸引力的替代原料。由于甲酸盐和甲酰胺目前主要从石油工业中获取,因此人们开发出了基于温室气体二氧化碳转化的新型合成路线。这种发展的动力来自于对碳化学循环的迫切需求,从而实现可持续发展的未来。二氧化碳的惰性对化学家来说是一个挑战,他们需要通过一种经济、高效的工艺来激活和专门转化这种分子。化学转化可以从生物二氧化碳活化中得到启发,在生物二氧化碳活化中,高度特化的酶通过相对丰富的金属催化剂来固定大气中的二氧化碳。在本开户绑定手机领体验金中,我们描述并讨论了最有效的生物二氧化碳转化系统之一:甲酰甲呋喃脱氢酶(简称 FMD)的潜力。FMD 是在古细菌中发现的多酶复合物,它以甲酰基团支链在甲呋喃(MFR)辅助因子的氨基上的形式捕获二氧化碳。与依靠伍德-荣格达尔还原途径固定二氧化碳的微生物相比,这种产生甲酰-甲呋喃的整体反应不需要 ATP 水解,突出了一种节省细胞能量的不同运作模式。FMD 反应是养氢型甲烷生成(依赖 H2 和 CO2 或甲酸盐)的切入点,并在其他甲烷生成途径和微生物代谢中反向运行。因此,FMD 是地球碳循环中的一个关键酶。经过数十年的研究,最近的研究对 FMD 的结构、反应机理和二氧化碳电还原的潜力进行了描述,我们的实验室对此做出了积极的贡献。FMD 是一种 "一体化 "酶,在两种截然不同的金属辅助因子上催化氧化还原活性转化和氧化还原中性转化,在这两种转化中生成新的 C-H 和 C-N 键。首先,我们恢复了整个反应的原理,即在甲酸甲酯还原酶(MFR)上的放能二氧化碳还原与内能甲酸缩合反应。然后,本报告揭示了活性位点的分子细节,并概述了每种催化机理。报告还描述了电子传输模块助燃二氧化碳还原的天然多功能性,并将其扩展到使用电极等人工系统的可能性。最后,报告从一个角度探讨了如何将 FMD 的机理应用于生产二氧化碳化学中间体,以合成有机分子。事实上,通过其生物化学特性,该酶为二氧化碳电还原生成甲酸盐和甲酰胺衍生物等分子提供了机会,而这些分子都是合成有机化合物的中间体。将从这些生物系统中获得的化学知识转化为连贯的模型,可促进合成生物学和生物启发合成化学领域的进一步发展,将二氧化碳大规模转化为化学合成的构件。
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
Accounts of Chemical Research
Accounts of Chemical Research 化学-化学综合
CiteScore
31.40
自引率
1.10%
发文量
312
审稿时长
2 months
期刊介绍: Accounts of Chemical Research presents short, concise and critical articles offering easy-to-read overviews of basic research and applications in all areas of chemistry and biochemistry. These short reviews focus on research from the author’s own laboratory and are designed to teach the reader about a research project. In addition, Accounts of Chemical Research publishes commentaries that give an informed opinion on a current research problem. Special Issues online are devoted to a single topic of unusual activity and significance. Accounts of Chemical Research replaces the traditional article abstract with an article "Conspectus." These entries synopsize the research affording the reader a closer look at the content and significance of an article. Through this provision of a more detailed description of the article contents, the Conspectus enhances the article's discoverability by search engines and the exposure for the research.
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