Supplementary material to "Anomalous Amide Proton Chemical Shifts as Signatures of Hydrogen Bonding to Aromatic Sidechains"

Q3 Physics and Astronomy

Magnetic resonance (Gottingen, Germany) Pub Date : 2021-07-01 DOI:10.5194/MR-2021-53

Kumaran Baskaran, Colin W. Wilburn, Jonathan R. Wedell, Leonardus M. I. Koharudin, E. Ulrich, A. Schuyler, H. Eghbalnia, A. Gronenborn, J. Hoch

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引用次数: 4

Abstract

Abstract. Hydrogen bonding between an amide group and the p-π cloud of an aromatic ring was first identified in a protein in the 1980s. Subsequent surveys of high-resolution X-ray crystal structures found multiple instances, but their preponderance was determined to be infrequent. Hydrogen atoms participating in a hydrogen bond to the p-π cloud of an aromatic ring are expected to experience an upfield chemical shift arising from a shielding ring current shift. We survey the Biological Magnetic Resonance Data Bank for amide hydrogens exhibiting unusual shifts as well as corroborating nuclear Overhauser effects between the amide protons and ring protons. We find evidence that Trp residues are more likely to be involved in p-π hydrogen bonds than other aromatic amino acids, whereas His residues are more likely to be involved in hydrogen bonds with a ring nitrogen acting as the hydrogen acceptor. The p-π hydrogen bonds may be more abundant than previously believed. The inclusion in NMR structure refinement protocols of shift effects in amide protons from aromatic side chains, or explicit hydrogen bond restraints between amides and aromatic rings, could improve the local accuracy of side-chain orientations in solution NMR protein structures, but their impact on global accuracy is likely be limited.

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“作为芳香侧链氢键特征的异常酰胺质子化学位移”的补充材料

摘要20世纪80年代，在一种蛋白质中首次发现了酰胺基团和芳香环的p-π云之间的氢键。随后对高分辨率x射线晶体结构的调查发现了多个实例，但它们的优势被确定为不常见。参与到芳香环的p-π云的氢键中的氢原子预计会经历由屏蔽环电流位移引起的前场化学位移。我们调查了酰胺氢的生物磁共振数据库，显示出不寻常的变化，以及确证酰胺质子和环质子之间的核Overhauser效应。我们发现有证据表明，Trp残基比其他芳香氨基酸更容易参与p-π氢键，而His残基更容易参与以环氮作为氢受体的氢键。p-π氢键可能比以前认为的更丰富。在核磁共振结构改进方案中包含了芳香族侧链上酰胺质子的移位效应，或者酰胺和芳香族环之间明确的氢键约束，可以提高溶液核磁共振蛋白质结构中侧链取向的局部精度，但它们对全局精度的影响可能有限。

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