多相连接和配体结合对生物分子凝聚体调控的影响。

IF 2.9 Q2 BIOPHYSICS
Biophysics reviews Pub Date : 2021-06-01 Epub Date: 2021-06-15 DOI:10.1063/5.0050059
Kiersten M Ruff, Furqan Dar, Rohit V Pappu
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引用次数: 0

摘要

细胞物质可以在空间和时间上组织成无膜生物分子凝聚体。目前的观点认为,这些凝聚体是在一种或多种被称为支架的凝聚体特异性多价大分子的驱动下,通过相变形成和溶解的。细胞可能通过控制调控分子(我们称之为配体)的浓度来调节凝聚体的形成和溶解。Wyman 和 Gill 引入了多相联系框架来解释配体如何对相变进行热力学控制。本综述将重点介绍多相联结的概念以及这种机制与控制凝结物形成和溶解的相关性。我们描述了如何通过实验量化配体介导的支架相行为控制。此外,我们还在近期研究的基础上强调了配体的特点,即配体是相分离的抑制因素还是驱动因素。最后,我们强调了需要取得进展的领域,以进一步了解配体介导的对复杂细胞环境中凝聚物的控制。这些进展包括了解配体网络对凝聚态行为的影响,以及配体如何调节由支架大分子之间同型和异型相互作用的不同组合所控制的相变。从应用多相连接概念中获得的见解应有助于设计新型药物配体来调节凝聚态。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Polyphasic linkage and the impact of ligand binding on the regulation of biomolecular condensates.

Polyphasic linkage and the impact of ligand binding on the regulation of biomolecular condensates.

Polyphasic linkage and the impact of ligand binding on the regulation of biomolecular condensates.

Polyphasic linkage and the impact of ligand binding on the regulation of biomolecular condensates.

Cellular matter can be spatially and temporally organized into membraneless biomolecular condensates. The current thinking is that these condensates form and dissolve via phase transitions driven by one or more condensate-specific multivalent macromolecules known as scaffolds. Cells likely regulate condensate formation and dissolution by exerting control over the concentrations of regulatory molecules, which we refer to as ligands. Wyman and Gill introduced the framework of polyphasic linkage to explain how ligands can exert thermodynamic control over phase transitions. This review focuses on describing the concepts of polyphasic linkage and the relevance of such a mechanism for controlling condensate formation and dissolution. We describe how ligand-mediated control over scaffold phase behavior can be quantified experimentally. Further, we build on recent studies to highlight features of ligands that make them suppressors vs drivers of phase separation. Finally, we highlight areas where advances are needed to further understand ligand-mediated control of condensates in complex cellular environments. These advances include understanding the effects of networks of ligands on condensate behavior and how ligands modulate phase transitions controlled by different combinations of homotypic and heterotypic interactions among scaffold macromolecules. Insights gained from the application of polyphasic linkage concepts should be useful for designing novel pharmaceutical ligands to regulate condensates.

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CiteScore
3.60
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