内在有序蛋白质聚合物的可编程性和生物医学用途。

IF 15.2 1区 医学 Q1 PHARMACOLOGY & PHARMACY
Maria Camila Giraldo-Castaño, Kai A. Littlejohn, Alexa Regina Chua Avecilla, Natalia Barrera-Villamizar, Felipe Garcia Quiroz
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引用次数: 0

摘要

本征无序蛋白(IDPs)表现出分子水平的构象动态,可在各种奇妙的生物现象中发挥功能。IDPs 的低序列复杂性促使人们设计和开发了本征无序蛋白聚合物 (IDPPs),这是一类具有刺激响应特性的工程化重复 IDPs。IDPPs 完美的重复结构允许对可调蛋白质功能进行重复级编码。设计的 IDPPs 可以以内源性 IDPs 为模型,也可以重新设计为具有生物物理和生物学双重功能的蛋白质聚合物。可以对它们的特性进行合理定制,从而获得神秘的 IDP 生物学特性,并创造出可编程的智能生物材料。为了启发基于 IDP 的多功能材料的生物工程,我们在此综述了最近在编程和利用 IDPPs 和含 IDPP 蛋白质的生物功能方面取得的多学科进展。总之,IDPP 功能的序列级控制超越了细胞外 IDPs 的传统序列空间,正在推动自组装生物材料、高级药物输送系统、组织支架和生物分子凝聚体(基因编码细胞器样结构)的生物工程。展望未来,我们强调开放的挑战和新兴的机遇,认为 IDPPs 的细胞内行为代表着生物医学发现和创新的丰富空间。IDPPs 及其生物医学应用的不断发展为加速高价值生物技术和生物材料的工程化奠定了基础。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Programmability and biomedical utility of intrinsically-disordered protein polymers

Programmability and biomedical utility of intrinsically-disordered protein polymers

Intrinsically disordered proteins (IDPs) exhibit molecular-level conformational dynamics that are functionally harnessed across a wide range of fascinating biological phenomena. The low sequence complexity of IDPs has led to the design and development of intrinsically-disordered protein polymers (IDPPs), a class of engineered repeat IDPs with stimuli-responsive properties. The perfect repetitive architecture of IDPPs allows for repeat-level encoding of tunable protein functionality. Designer IDPPs can be modeled on endogenous IDPs or engineered de novo as protein polymers with dual biophysical and biological functionality. Their properties can be rationally tailored to access enigmatic IDP biology and to create programmable smart biomaterials. With the goal of inspiring the bioengineering of multifunctional IDP-based materials, here we synthesize recent multidisciplinary progress in programming and exploiting the bio-functionality of IDPPs and IDPP-containing proteins. Collectively, expanding beyond the traditional sequence space of extracellular IDPs, emergent sequence-level control of IDPP functionality is fueling the bioengineering of self-assembling biomaterials, advanced drug delivery systems, tissue scaffolds, and biomolecular condensates —genetically encoded organelle-like structures. Looking forward, we emphasize open challenges and emerging opportunities, arguing that the intracellular behaviors of IDPPs represent a rich space for biomedical discovery and innovation. Combined with the intense focus on IDP biology, the growing landscape of IDPPs and their biomedical applications set the stage for the accelerated engineering of high-value biotechnologies and biomaterials.

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来源期刊
CiteScore
28.10
自引率
5.00%
发文量
294
审稿时长
15.1 weeks
期刊介绍: The aim of the Journal is to provide a forum for the critical analysis of advanced drug and gene delivery systems and their applications in human and veterinary medicine. The Journal has a broad scope, covering the key issues for effective drug and gene delivery, from administration to site-specific delivery. In general, the Journal publishes review articles in a Theme Issue format. Each Theme Issue provides a comprehensive and critical examination of current and emerging research on the design and development of advanced drug and gene delivery systems and their application to experimental and clinical therapeutics. The goal is to illustrate the pivotal role of a multidisciplinary approach to modern drug delivery, encompassing the application of sound biological and physicochemical principles to the engineering of drug delivery systems to meet the therapeutic need at hand. Importantly the Editorial Team of ADDR asks that the authors effectively window the extensive volume of literature, pick the important contributions and explain their importance, produce a forward looking identification of the challenges facing the field and produce a Conclusions section with expert recommendations to address the issues.
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