通过选择性 Fe 标记连接氮酶铁钼辅因子的几何和电子结构。
Connecting the geometric and electronic structures of the nitrogenase iron-molybdenum cofactor through site-selective Fe labelling.
机构信息
Department of Chemistry, Massachusetts Institute of Technology, Cambridge, MA, USA.
Department of Chemistry, Northwestern University, Evanston, IL, USA.
出版信息
Nat Chem. 2023 May;15(5):658-665. doi: 10.1038/s41557-023-01154-9. Epub 2023 Mar 13.
Abstract
Understanding the chemical bonding in the catalytic cofactor of the Mo nitrogenase (FeMo-co) is foundational for building a mechanistic picture of biological nitrogen fixation. A persistent obstacle towards this goal has been that the Fe-based spectroscopic data-although rich with information-combines responses from all seven Fe sites, and it has therefore not been possible to map individual spectroscopic responses to specific sites in the three-dimensional structure. Here we have addressed this challenge by incorporating Fe into a single site of FeMo-co. Spectroscopic analysis of the resting state informed on the local electronic structure of the terminal Fe1 site, including its oxidation state and spin orientation, and, in turn, on the spin-coupling scheme for the entire cluster. The oxidized resting state and the first intermediate in nitrogen fixation were also characterized, and comparisons with the resting state provided molecular-level insights into the redox chemistry of FeMo-co.
摘要
了解钼氮酶(FeMo-co)催化辅因子的化学键合对于构建生物固氮的机理图景至关重要。实现这一目标的一个持久障碍是,基于铁的光谱数据虽然信息量丰富,但结合了所有七个铁位点的响应,因此不可能将单个光谱响应映射到三维结构中的特定位点。在这里,我们通过将铁掺入 FeMo-co 的单个位点来解决这一挑战。对静止状态的光谱分析提供了关于末端 Fe1 位点的局部电子结构的信息,包括其氧化态和自旋取向,并进而提供了整个团簇的自旋偶联方案。还对氧化的静止状态和固氮的第一个中间状态进行了表征,并与静止状态进行了比较,为 FeMo-co 的氧化还原化学提供了分子水平的见解。
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