细菌鞭毛生物模板pH和序列响应的形态变化调控二氧化硅纳米管的合成。

Journal of Materials Chemistry Pub Date : 2012-01-01 Epub Date: 2012-05-21 DOI:10.1039/C2JM31034A
Dong Li, Xuewei Qu, Salete M C Newton, Philip E Klebba, Chuanbin Mao
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引用次数: 27

摘要

细菌鞭毛是自然产生的自组装蛋白质纳米纤维,从细菌表面突出,以帮助细菌游泳。它们是刚性的,并表现出不同的形态,这取决于离子强度、pH值、温度和亚基序列。在温和条件下,以鞭毛为生物模板,在水溶液中合成了形貌可控的二氧化硅纳米管(SNTs)。通过肽显示调节pH值或鞭毛表面化学,可以简单地调整鞭毛模板snt的形态和表面特征。获得了snt的多种不同形态(不同波长的卷曲、直、卷)和表面特征(光滑、粗糙、颗粒状和梨项链状)。当pH值从酸性到碱性变化时,snt通常从束状卷曲到特征正弦波、螺旋和直线形态变化。在遗传控制下,带负电荷肽的鞭毛硅结层较薄,表面粗糙。然而,带正电荷肽插入的鞭毛诱导了表面光滑的更厚的二氧化硅壳的沉积。将含羟基氨基酸残基(如丝氨酸)结合到鞭毛上显示的肽中,可以大大增强二氧化硅的生物模板化沉积。这项工作表明,细菌鞭毛是一种有前途的生物模板,用于开发一种环境友好和经济有效的形态控制纳米管合成方法。此外,二氧化硅壳的厚度与鞭毛上显示的肽的依赖关系有助于我们进一步了解二氧化硅在生物模板上的仿生成核机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Morphology-controlled synthesis of silica nanotubes through pH- and sequence-responsive morphological change of bacterial flagellar biotemplates.

Bacterial flagella are naturally-occurring self-assembling protein nanofibers protruding from the bacterial surface to assist the swimming of bacteria. They are rigid and exhibit diverse morphologies depending on the ionic strength, the pH values, temperature, and subunit sequences. Here, the silica nanotubes (SNTs) with controllable morphologies were synthesized using flagella as biological templates in aqueous solution under mild conditions. The morphologies and surface features of flagella-templated SNTs can be simply tuned by adjusting the pH value or surface chemistry of flagella by peptide display. A variety of different morphologies (coiled, straight, and curly with different wavelengths) and surface features (smooth, rough, granular and pear-necklace-like) of SNTs were obtained. When pH varies from acidic to alkaline conditions, in general, SNTs varied from bundled coiled, to characteristic sinusoidal waves, helical, and straight morphology. Under genetic control, flagella displaying negatively-charged peptides exhibited thinner layer of silica condensation but rough surface. However, flagella with positively-charged peptide inserts induced the deposition of thicker silica shell with smooth surface. Incorporation of hydroxyl bearing amino acid residues such as Ser into the peptide displayed on flagella highly enhanced the biotemplated deposition of silica. This work suggests that bacterial flagella are promising biotemplates for developing an environmentally-benign and cost-efficient approach to morphology-controlled synthesis of nanotubes. Moreover, the dependency of the thickness of the silica shell on the peptides displayed on flagella helps us to further understand the mechanism of biomimetic nucleation of silica on biological templates.

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来源期刊
Journal of Materials Chemistry
Journal of Materials Chemistry 工程技术-材料科学:综合
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