Koder Ronald L, Walsh Joseph D, Pometun Maxim S, Dutton P Leslie, Wittebort Richard J, Miller Anne-Frances
Department of Chemistry, University of Kentucky, Lexington, Kentucky 40506-0055, USA.
J Am Chem Soc. 2006 Nov 29;128(47):15200-8. doi: 10.1021/ja0648817.
Flavins are central to the reactivity of a wide variety of enzymes and electron transport proteins. There is great interest in understanding the basis for the different reactivities displayed by flavins in different protein contexts. We propose solid-state nuclear magnetic resonance (SS-NMR) as a tool for directly observing reactive positions of the flavin ring and thereby obtaining information on their frontier orbitals. We now report the SS-NMR signals of the redox-active nitrogens N1 and N5, as well as that of N3. The chemical shift tensor of N5 is over 720 ppm wide, in accordance with the predictions of theory and our calculations. The signal of N3 can be distinguished on the basis of coupling to 1H absent for N1 and N5, as well as the shift tensor span of only 170 ppm, consistent with N3's lower aromaticity and lack of a nonbonding lone pair. The isotropic shifts and spans of N5 and N1 reflect two opposite extremes of the chemical shift range for "pyridine-type" N's, consistent with their electrophilic and nucleophilic chemical reactivities, respectively. Upon flavin reduction, N5's chemical shift tensor contracts dramatically to a span of less than 110 ppm, and the isotropic chemical shift changes by approximately 300 ppm. Both are consistent with loss of N5's nonbonding lone pair and decreased aromaticity, and illustrate the responsiveness of the 15N chemical shift principal values to electronic structure. Thus. 15N chemical shift principal values promise to be valuable tools for understanding electronic differences that underlie variations in flavin reactivity, as well as the reactivities of other heterocyclic cofactors.
黄素对于多种酶和电子传递蛋白的反应活性至关重要。人们对理解黄素在不同蛋白质环境中表现出的不同反应活性的基础有着浓厚兴趣。我们提出将固态核磁共振(SS-NMR)作为一种直接观察黄素环反应位点的工具,从而获取有关其前沿轨道的信息。我们现在报告氧化还原活性氮N1和N5以及N3的SS-NMR信号。N5的化学位移张量宽度超过720 ppm,这与理论预测和我们的计算结果一致。N3的信号可以根据与N1和N5不存在的1H耦合以及仅170 ppm的位移张量跨度来区分,这与N3较低的芳香性和缺乏非键孤对电子一致。N5和N1的各向同性位移和跨度分别反映了“吡啶型”氮化学位移范围的两个相反极端,分别与其亲电和亲核化学反应活性一致。在黄素还原时,N5的化学位移张量急剧收缩至小于110 ppm的跨度,各向同性化学位移变化约300 ppm。两者都与N5非键孤对电子的丧失和芳香性降低一致,并说明了15N化学位移主值对电子结构的响应性。因此,15N化学位移主值有望成为理解黄素反应活性变化以及其他杂环辅因子反应活性背后电子差异的有价值工具。