Emergence of Cell Behavior Through Feedback Control of Polymersome Membrane Transport

IF 3.1 Q2 CHEMISTRY, MULTIDISCIPLINARY
Omar Rifaie-Graham
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引用次数: 0

Abstract

Artificial cell and organelle construction has recently gained substantial attention to generate simplified models for understanding of biological phenomena, or micro- and nanomachines for biomedical and biotechnological applications. A wide array of building blocks has been employed to build these systems as membraneless structures with the ability to compartmentalize chemical reactions by enhanced partitioning, or as membrane-defined entities that provide a physical barrier that inhibits the interference of external factors. While these systems present unique properties that enable high fidelity to biological processes, they present limited ability to recreate the high selectivity and specificity of small molecule trafficking observed in biological membranes. Owing to their high chemical versatility, polymers can be leveraged to generate 3D structures that resemble biological membranes while providing transmembrane chemical motifs that enable responsiveness to a wide array of stimuli. This Concept Article discusses the ability to control membrane transport facilitating the emergence of out-of-equilibrium feedback mechanisms that ultimately modulate enzymatic rates. This can be employed to engineer future artificial cells and organelles that display homeostasis as a mechanism of self-adaptation to continuously evolving environments.

Abstract Image

通过聚合体膜运输的反馈控制实现细胞行为的产生
人工细胞和细胞器的构建近来备受关注,其目的是生成简化模型,用于理解生物现象,或用于生物医学和生物技术应用的微型和纳米机器。人们利用各种构件将这些系统构建成无膜结构,通过增强分区能力将化学反应分隔开来,或构建成膜定义的实体,提供物理屏障,抑制外部因素的干扰。虽然这些系统具有独特的特性,能够高度逼真地反映生物过程,但它们再现生物膜中观察到的小分子贩运的高选择性和特异性的能力有限。由于聚合物具有高度的化学通用性,因此可以利用它们生成与生物膜相似的三维结构,同时提供跨膜化学基团,从而对各种刺激做出响应。这篇概念文章讨论了控制膜传输的能力,这种能力可促进失衡反馈机制的出现,最终调节酶的速率。这可以用来设计未来的人造细胞和细胞器,使其显示出平衡状态,作为一种自我适应不断进化的环境的机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
7.00
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