A backbone-reversed all-beta polypeptide (retro-CspA) folds and assembles into amyloid nanofibres.

Protein engineering Pub Date : 2003-12-01 DOI:10.1093/protein/gzg142

Anshuman Shukla, Manoj Raje, Purnananda Guptasarma

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引用次数: 10

Abstract

The backbone-reversed or 'retro', form of a model all-beta-sheet protein, Escherichia coli CspA, was produced from a synthetic gene in E.coli in fusion with an N-terminal affinity tag. Following purification under denaturing conditions and dialysis-based removal of urea, the protein was found to fold into a soluble, poorly structured multimer. Upon concentration, this state readily transformed into amyloid nanofibres. Congo Red-binding amorphous forms were also observed. Since a beta-sheet-forming sequence is expected to retain high beta-sheet-forming propensity even after backbone reversal and given the fact that folding of retro-CspA occurs only to a poorly structured form, we conclude that the increase effected in protein concentration may be responsible for the formation of intermolecular beta-sheets, facilitating the bleeding away of the protein's conformational equilibrium into aggregates that generate well-formed fibres. Since every molecule in these fibres contains a peptide tag for binding Ni(2+), the fibres may provide a template for deposition of nickel to generate novel materials.

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一种反向全β多肽(逆转录- cspa)折叠并组装成淀粉样纳米纤维。

大肠杆菌(Escherichia coli) CspA是一种模型全β -sheet蛋白的反向或“复古”形式，它是由大肠杆菌中的一个合成基因与一个n端亲和标签融合而成的。经过变性条件下的纯化和基于尿素的透析去除，蛋白质被发现折叠成可溶的，结构不良的多聚体。浓缩后，这种状态很容易转化为淀粉样纳米纤维。还观察到刚果红结合的无定形。由于β -薄片形成序列即使在主链反转后仍有望保持较高的β -薄片形成倾向，并且考虑到逆转录cspa的折叠只发生在结构不良的形式，我们得出结论，蛋白质浓度的增加可能是分子间β -薄片形成的原因，促进了蛋白质构象平衡的流失，形成了形成良好纤维的聚集体。由于这些纤维中的每个分子都含有一个结合Ni(2+)的肽标签，因此这些纤维可能为镍的沉积提供模板，从而产生新的材料。

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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