Electronic and Steric Effects on Oxygen Reactivities of NiFeSe Complexes Related to O2-Damaged [NiFeSe]-Hydrogenases’ Active Site

IF 3.1 4区化学 Q2 CHEMISTRY, INORGANIC & NUCLEAR Inorganics Pub Date : 2024-06-10 DOI:10.3390/inorganics12060163

Yuchen Qiao, Enting Xu, Yameng Hao, Xuemei Yang, Ming Ni

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Abstract

Hydrogen has the potential to serve as a new energy resource, reducing greenhouse gas emissions that contribute to climate change. Natural hydrogenases exhibit impressive catalytic abilities for hydrogen production, but they often lack oxygen tolerance. Oxygen-tolerant hydrogenases can work under oxygen by reacting with oxygen to form inactive states, which can be reactivated to catalytic states by oxygen atom removal. Herein, we synthesized three NiFeSe complexes: (NiSe(CH3)FeCp, NiSe(CH3)FeCp* and NiSe(PhNMe2)FeCp) with features of active sites of [NiFeSe]-H2ases, which are the oxygen-tolerant hydrogenases, and we investigated the influence of electronic and steric factors on the oxygen reaction of these “biomimetic” complexes. In our research, we found that they react with oxygen, forming 1-oxygen species, which is related to the O2-damaged [NiFeSe] active site. Through a comparative analysis of oxygen reactions, we have discovered that electronic factors and steric hindrance on Se play a significant role in determining the oxygen reactivity of NiFe complexes related to hydrogenases’ active sites.

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与氧气破坏的[NiFeSe]-氢化酶活性位点有关的 NiFeSe 复合物对氧活性的电子和立体效应

氢有可能成为一种新能源，减少导致气候变化的温室气体排放。天然氢酶在催化制氢方面表现出惊人的能力，但它们通常缺乏耐氧性。耐氧氢化酶可在氧气环境下工作，与氧反应形成非活性状态，通过去除氧原子可重新激活为催化状态。在此，我们合成了三种具有耐氧氢化酶[NiFeSe]-H2ase活性位点特征的NiFeSe配合物：（NiSe(CH3)FeCp、NiSe(CH3)FeCp*和NiSe(PhNMe2)FeCp），并研究了电子和立体因素对这些 "仿生物 "配合物氧反应的影响。在研究中，我们发现它们会与氧气发生反应，形成 1-氧物种，这与被氧气破坏的 [NiFeSe] 活性位点有关。通过对氧反应的比较分析，我们发现 Se 上的电子因素和立体阻碍在决定与氢化酶活性位点有关的 NiFe 复合物的氧反应性方面起着重要作用。

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来源期刊

Inorganics Chemistry-Inorganic Chemistry

CiteScore

2.80

自引率

10.30%

发文量

193

审稿时长

6 weeks

期刊介绍： Inorganics is an open access journal that covers all aspects of inorganic chemistry research. Topics include but are not limited to: synthesis and characterization of inorganic compounds, complexes and materials structure and bonding in inorganic molecular and solid state compounds spectroscopic, magnetic, physical and chemical properties of inorganic compounds chemical reactivity, physical properties and applications of inorganic compounds and materials mechanisms of inorganic reactions organometallic compounds inorganic cluster chemistry heterogenous and homogeneous catalytic reactions promoted by inorganic compounds thermodynamics and kinetics of significant new and known inorganic compounds supramolecular systems and coordination polymers bio-inorganic chemistry and applications of inorganic compounds in biological systems and medicine environmental and sustainable energy applications of inorganic compounds and materials MD