Colloid assembly and transformation (CAT): The relationship of PILP to biomineralization

IF 3.5 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY Journal of Structural Biology: X Pub Date : 2022-01-01 DOI:10.1016/j.yjsbx.2021.100059
Laurie Gower, Jeremy Elias
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引用次数: 5

Abstract

The field of biomineralization has undergone a revolution in the past 25 years, which paralleled the discovery by Gower of a polymer-induced liquid-precursor (PILP) mineralization process. She proposed this in vitro model system might be useful for studying the role biopolymers play in biomineralization; however, the ramifications of this pivotal discovery were slow to be recognized. This was presumably because it utilized simple polypeptide additives, and at that time it was not recognized that the charged proteins intimately associated with biominerals are often intrinsically disordered proteins (IDPs). Over the years, many enigmatic biomineral features have been emulated with this model system, too many to be mere coincidence. Yet the PILP system continues to be underacknowledged, probably because of its namesake, which indicates a “liquid precursor”, while we now know the phase appears to have viscoelastic character. Another factor is the confusing semantics that arose from the discovery of multiple “non-classical crystallization” pathways. This review suggests a more relevant terminology for the polymer-modulated reactions is “colloid assembly and transformation (CAT)”, which we believe more accurately captures the key stages involved in both biomineralization and the PILP process. The PILP model system has helped to decipher the key role that biopolymers, namely the IDPs, play in modulating biomineralization processes, which was not readily accomplished in living biological systems. Some remaining challenges in understanding the organic–inorganic interactions involved in biomineralization are discussed, which further highlight how the PILP model system may prove invaluable for studying the simple, yet complex, CAT crystallization pathway.

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胶体组装和转化(CAT): PILP与生物矿化的关系
生物矿化领域在过去的25年里经历了一场革命,与此同时,高尔发现了聚合物诱导的液体前驱体(PILP)矿化过程。她提出这种体外模型系统可能有助于研究生物聚合物在生物矿化中的作用;然而,这一关键发现的影响却迟迟未被认识到。这可能是因为它使用了简单的多肽添加剂,当时还没有认识到与生物矿物质密切相关的带电蛋白通常是内在无序蛋白(IDPs)。多年来,许多神秘的生物矿物特征已经用这个模型系统模拟,太多的仅仅是巧合。然而,可能是因为它的名字,它表示“液体前体”,而我们现在知道该相似乎具有粘弹性特征,所以PILP系统仍然未得到充分承认。另一个因素是由于发现多种“非经典结晶”途径而引起的语义混乱。这篇综述认为,聚合物调节反应更相关的术语是“胶体组装和转化(CAT)”,我们认为这更准确地捕捉了生物矿化和PILP过程中涉及的关键阶段。PILP模型系统帮助破译了生物聚合物(即IDPs)在调节生物矿化过程中的关键作用,这在活的生物系统中是不容易完成的。本文还讨论了理解生物矿化过程中有机-无机相互作用的一些挑战,这些挑战进一步强调了PILP模型系统对于研究简单而复杂的CAT结晶途径可能是非常宝贵的。
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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来源期刊
Journal of Structural Biology: X
Journal of Structural Biology: X Biochemistry, Genetics and Molecular Biology-Structural Biology
CiteScore
6.50
自引率
0.00%
发文量
20
审稿时长
62 days
期刊最新文献
Corrigendum to “Minimizing ice contamination during specimen preparation for cryo-soft X-ray tomography and cryo-electron tomography” [J. Struct. Biol.: X 10(2024) 100113] Editorial by Natalie Reznikov [for Buss et al., “Hierarchical organization of bone in three dimensions: A twist of twists” (2022)] Structural analysis of the stable form of fibroblast growth factor 2 – FGF2-STAB Localization of albumin with correlative super resolution light- and electron microscopy in the kidney Minimizing ice contamination during specimen preparation for cryo-soft X-ray tomography and cryo-electron tomography
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