Supramolecular fibrillation in coacervates and other confined systems towards biomimetic function

IF 5.9 2区 化学 Q1 CHEMISTRY, MULTIDISCIPLINARY Communications Chemistry Pub Date : 2024-09-30 DOI:10.1038/s42004-024-01308-x
Adrian Sanchez-Fernandez, Ignacio Insua, Javier Montenegro
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Abstract

As in natural cytoskeletons, the cooperative assembly of fibrillar networks can be hosted inside compartments to engineer biomimetic functions, such as mechanical actuation, transport, and reaction templating. Coacervates impose an optimal liquid-liquid phase separation within the aqueous continuum, functioning as membrane-less compartments that can organise such self-assembling processes as well as the exchange of information with their environment. Furthermore, biological fibrillation can often be controlled or assisted by intracellular compartments. Thus, the reconstitution of analogues of natural filaments in simplified artificial compartments, such as coacervates, offer a suitable model to unravel, mimic, and potentially exploit cellular functions. This perspective summarises the latest developments towards assembling fibrillar networks under confinement inside coacervates and related compartments, including a selection of examples ranging from biological to fully synthetic monomers. Comparative analysis between coacervates, lipid vesicles, and droplet emulsions showcases the interplay between supramolecular fibres and the boundaries of the corresponding compartment. Combining inspiration from natural systems and the custom properties of tailored synthetic fibrillators, rational monomer and compartment design will contribute towards engineering increasingly complex and more realistic artificial protocells. The bottom-up reconstitution of natural filaments within simplified artificial cellular compartments, such as coacervates, offer a model to study, mimic, and potentially exploit cellular functions. Here, the authors summarize the latest developments towards assembling confined fibrillar networks inside coacervates and related compartments, including a selection of examples ranging from biological to fully synthetic building blocks.

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在共聚物和其他封闭系统中实现超分子纤化,从而实现生物仿生功能
与自然界的细胞骨架一样,纤维网络的合作组装可以在隔间内进行,以实现仿生物功能,如机械驱动、运输和反应模板化。凝聚体在水连续体中实现了最佳的液-液相分离,可作为无膜隔室发挥作用,组织此类自组装过程,并与周围环境交换信息。此外,生物纤维化通常可由细胞内区室控制或辅助。因此,在共液态等简化的人工区室中重组天然丝状物的类似物,为揭示、模拟和潜在利用细胞功能提供了一个合适的模型。本视角总结了在共渗物和相关隔室内封闭条件下组装纤维网的最新进展,包括从生物单体到全合成单体的一系列实例。凝聚态、脂质囊泡和液滴乳液之间的对比分析展示了超分子纤维与相应隔室边界之间的相互作用。结合从自然系统中汲取的灵感和量身定制的合成纤维的定制特性,合理的单体和隔室设计将有助于设计出越来越复杂、越来越逼真的人造原细胞。自下而上地在简化的人工细胞区室(如凝聚体)中重组天然纤维丝,为研究、模拟和开发潜在的细胞功能提供了一个模型。在此,作者总结了在凝聚体和相关隔室中组装封闭纤维网络的最新进展,包括从生物到全合成构建模块的一系列实例。
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来源期刊
Communications Chemistry
Communications Chemistry Chemistry-General Chemistry
CiteScore
7.70
自引率
1.70%
发文量
146
审稿时长
13 weeks
期刊介绍: Communications Chemistry is an open access journal from Nature Research publishing high-quality research, reviews and commentary in all areas of the chemical sciences. Research papers published by the journal represent significant advances bringing new chemical insight to a specialized area of research. We also aim to provide a community forum for issues of importance to all chemists, regardless of sub-discipline.
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