Trends in the Binding of Cell Penetrating Peptides to siRNA: A Molecular Docking Study.

P V G M Rathnayake, B G C M Gunathunge, P N Wimalasiri, D N Karunaratne, R J K U Ranatunga
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引用次数: 19

Abstract

The use of gene therapeutics, including short interfering RNA (siRNA), is limited by the lack of efficient delivery systems. An appealing approach to deliver gene therapeutics involves noncovalent complexation with cell penetrating peptides (CPPs) which are able to penetrate the cell membranes of mammals. Although a number of CPPs have been discovered, our understanding of their complexation and translocation of siRNA is as yet insufficient. Here, we report on computational studies comparing the binding affinities of CPPs with siRNA, considering a variety of CPPs. Specifically, seventeen CPPs from three different categories, cationic, amphipathic, and hydrophobic CPPs, were studied. Molecular mechanics were used to minimize structures, while molecular docking calculations were used to predict the orientation and favorability of sequentially binding multiple peptides to siRNA. Binding scores from docking calculations were highest for amphipathic peptides over cationic and hydrophobic peptides. Results indicate that initial complexation of peptides will likely occur along the major groove of the siRNA, driven by electrostatic interactions. Subsequent binding of CPPs is likely to occur in the minor groove and later on bind randomly, to siRNA or previously bound CPPs, through hydrophobic interactions. However, hydrophobic CPPs do not show this binding pattern. Ultimately binding yields a positively charged nanoparticle capable of noninvasive cellular import of therapeutic molecules.

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细胞穿透肽与siRNA结合的趋势:分子对接研究。
基因疗法的使用,包括短干扰RNA (siRNA),由于缺乏有效的递送系统而受到限制。提供基因治疗的一种吸引人的方法涉及与细胞穿透肽(CPPs)的非共价络合,CPPs能够穿透哺乳动物的细胞膜。虽然已经发现了许多cps,但我们对它们的络合和siRNA的易位的了解还不够。在这里,我们报告了比较CPPs与siRNA结合亲和力的计算研究,考虑到各种CPPs。具体来说,研究了阳离子型、两性型和疏水性三种不同类别的17种CPPs。分子力学用于最小化结构,而分子对接计算用于预测顺序结合多个肽与siRNA的取向和有利性。通过对接计算得出,两亲肽的结合分数最高,高于阳离子和疏水肽。结果表明,在静电相互作用的驱动下,肽的初始络合可能沿着siRNA的主要凹槽发生。CPPs的后续结合可能发生在小凹槽中,随后通过疏水相互作用随机结合siRNA或先前结合的CPPs。然而,疏水性CPPs不表现出这种结合模式。最终结合产生带正电的纳米颗粒,能够无创地向细胞输入治疗分子。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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