Sequence-controlled divergent supramolecular assembly of polyproline helices into metallo-peptide nanoparticles†

IF 4.6 3区材料科学 Q2 CHEMISTRY, MULTIDISCIPLINARY Nanoscale Advances Pub Date : 2024-12-05 DOI:10.1039/D4NA00762J

Dominic F. Brightwell, Kushal Samanta, Julie A. Watts, Michael W. Fay and Aniello Palma

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Abstract

The field of peptide based supramolecular biomaterials is fast evolving. These types of constructs have been shown to find applications in the fields of bioimaging, drug delivery and scaffolds for chemical reactions. However, the community typically focuses on the use of two specific classes of structured peptides: α-helices and β-sheets, clearly neglecting a unique peptide secondary structure: the polyproline helix. Herein, we report the first design, synthesis and characterization of polyproline based metallo-peptide nanoparticles. We demonstrate that rationally engineered polyproline helices can assemble in a divergent manner, into two types of nanoparticles. We also demonstrate that the primary sequence of the functionalised polyproline peptide is crucial to ensure a controlled assembly. This work clearly demonstrates that polyproline helices can be a powerful tool to achieve supramolecular assemblies of complex and responsive bioinspired nanomaterials.

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序列控制的聚脯氨酸螺旋成金属肽纳米粒子的发散超分子组装。

基于肽的超分子生物材料领域正在快速发展。这些类型的结构已被证明在生物成像、药物输送和化学反应支架等领域得到应用。然而，该社区通常侧重于使用两种特定类型的结构肽：α-螺旋和β-片，显然忽略了独特的肽二级结构：聚脯氨酸螺旋。本文首次设计、合成并表征了基于聚脯氨酸的金属肽纳米颗粒。我们证明了合理设计的聚脯氨酸螺旋可以以不同的方式组装成两种类型的纳米颗粒。我们还证明了功能化的聚脯氨酸肽的一级序列对于确保受控组装至关重要。这项工作清楚地表明，聚脯氨酸螺旋可以成为实现复杂和响应性生物启发纳米材料的超分子组装的有力工具。

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