实时跟踪药物与流感A M2的结合,揭示了一个高能量屏障

IF 3.5 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY
Kumar Tekwani Movellan, Melanie Wegstroth, Kerstin Overkamp, Andrei Leonov, Stefan Becker, Loren B. Andreas
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引用次数: 1

摘要

金刚乙胺药物与来自甲型流感病毒的M2蛋白中的两个不同位点结合,一个是外周位点,一个是主要有效位点的孔位点。在某些洗涤剂胶束中不发生孔结合仍然是一个谜,特别是在选择与病毒膜匹配的脂质混合物中观察到不完全结合。在这里,我们证明了两种影响是负责的,即蛋白质在孔隙结合时的变化,阻止了洗涤剂的增溶作用,以及脂质样品中的缓慢结合动力学。利用55-100 kHz的魔角旋转核磁共振,我们表征了三种不同脂质环境下药物结合的动力学:DPhPC, DPhPC与胆固醇和病毒模拟膜脂双分子层。缓慢的药理学结合动力学允许表征在动力学捕获的孔载子状态下与蛋白质周围的非特异性结合相关的光谱变化。共振分配是由一组质子探测的三维光谱确定的。实时跟踪M2孔隙中与功能结合相关的化学位移变化,以估计活化能。结合动力学受pH值和脂质环境,特别是胆固醇的影响。我们发现,残基组氨酸37上的咪唑-咪唑氢键是蛋白质跨越几种脂质组成的稳定特征。孔结合破坏了咪唑-咪唑氢键,限制了DHPC洗涤剂的增溶。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Real-time tracking of drug binding to influenza A M2 reveals a high energy barrier

Real-time tracking of drug binding to influenza A M2 reveals a high energy barrier

The drug Rimantadine binds to two different sites in the M2 protein from influenza A, a peripheral site and a pore site that is the primary site of efficacy. It remained enigmatic that pore binding did not occur in certain detergent micelles, and in particular incomplete binding was observed in a mixture of lipids selected to match the viral membrane. Here we show that two effects are responsible, namely changes in the protein upon pore binding that prevented detergent solubilization, and slow binding kinetics in the lipid samples. Using 55–100 kHz magic-angle spinning NMR, we characterize kinetics of drug binding in three different lipid environments: DPhPC, DPhPC with cholesterol and viral mimetic membrane lipid bilayers. Slow pharmacological binding kinetics allowed the characterization of spectral changes associated with non-specific binding to the protein periphery in the kinetically trapped pore-apo state. Resonance assignments were determined from a set of proton-detected 3D spectra. Chemical shift changes associated with functional binding in the pore of M2 were tracked in real time in order to estimate the activation energy. The binding kinetics are affected by pH and the lipid environment and in particular cholesterol. We found that the imidazole-imidazole hydrogen bond at residue histidine 37 is a stable feature of the protein across several lipid compositions. Pore binding breaks the imidazole-imidazole hydrogen bond and limits solubilization in DHPC detergent.

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来源期刊
Journal of Structural Biology: X
Journal of Structural Biology: X Biochemistry, Genetics and Molecular Biology-Structural Biology
CiteScore
6.50
自引率
0.00%
发文量
20
审稿时长
62 days
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