化学
溶剂化
氢键
膜
磁导率
电介质
分子动力学
极地的
化学物理
溶剂
膜透性
计算化学
分子
有机化学
生物化学
材料科学
物理
光电子学
天文
作者
Taha Rezai,Jonathan Bock,Mai V. Zhou,Chakrapani Kalyanaraman,R. Scott Lokey,Matthew P. Jacobson
摘要
We report an atomistic physical model for the passive membrane permeability of cyclic peptides. The computational modeling was performed in advance of the experiments and did not involve the use of "training data". The model explicitly treats the conformational flexibility of the peptides by extensive conformational sampling in low (membrane) and high (water) dielectric environments. The passive membrane permeabilities of 11 cyclic peptides were obtained experimentally using a parallel artificial membrane permeability assay (PAMPA) and showed a linear correlation with the computational results with R(2) = 0.96. In general, the results support the hypothesis, already well established in the literature, that the ability to form internal hydrogen bonds is critical for passive membrane permeability and can be the distinguishing factor among closely related compounds, such as those studied here. However, we have found that the number of internal hydrogen bonds that can form in the membrane and the solvent-exposed polar surface area correlate more poorly with PAMPA permeability than our model, which quantitatively estimates the solvation free energy losses upon moving from high-dielectric water to the low-dielectric interior of a membrane.
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