Shift of fibril-forming ability of the designed alpha-helical coiled-coil peptides into the physiological pH region.

Protein engineering Pub Date : 2003-12-01 DOI:10.1093/protein/gzg138

T N Melnik, V Villard, V Vasiliev, G Corradin, A V Kajava, S A Potekhin

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引用次数: 27

Abstract

Recently, we designed a short alpha-helical fibril-forming peptide (alphaFFP) that can form alpha-helical nanofibrils at acid pH. The non-physiological conditions of the fibril formation hamper biomedical application of alphaFFP. It was hypothesized that electrostatic repulsion between glutamic acid residues present at positions (g) of the alphaFFP coiled-coil sequence prevent the fibrillogenesis at neutral pH, while their protonation below pH 5.5 triggers axial growth of the fibril. To test this hypothesis, we synthesized alphaFFPs where all glutamic acid residues were substituted by glutamines or serines. The electron microscopy study confirmed that the modified alphaFFPs form nanofibrils in a wider range of pH (2.5-11). Circular dichroism spectroscopy, sedimentation, diffusion and differential scanning calorimetry showed that the fibrils are alpha-helical and have elongated and highly stable cooperative tertiary structures. This work leads to a better understanding of interactions that control the fibrillogenesis of the alphaFFPs and opens opportunities for their biomedical application.

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设计的α -螺旋卷曲肽的原纤维形成能力转移到生理pH区域。

最近，我们设计了一种可以在酸性ph下形成α -螺旋状纳米原纤维的短肽(alphaFFP)，其纤维形成的非生理条件阻碍了alphaFFP的生物医学应用。据推测，在中性pH下，位于alphaFFP盘绕序列(g)位置的谷氨酸残基之间的静电斥力阻止了纤维的形成，而在pH低于5.5时，它们的质子化引发了纤维的轴向生长。为了验证这一假设，我们合成了所有谷氨酸残基都被谷氨酰胺或丝氨酸取代的alphaFFPs。电镜研究证实，修饰的alphaFFPs在更宽的pH范围内形成纳米原纤维(2.5-11)。圆二色光谱、沉积、扩散和差示扫描量热分析表明，原纤维呈α -螺旋状，具有细长且高度稳定的三级协同结构。这项工作有助于更好地理解控制alphaFFPs纤维形成的相互作用，并为其生物医学应用开辟了机会。

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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Protein engineering

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