两性聚电解质物种在细胞器样凝聚物中的亚区室化是由电荷模式不匹配和强烈的排除体积相互作用促进的。

Subcompartmentalization of polyampholyte species in organelle-like condensates is promoted by charge-pattern mismatch and strong excluded-volume interaction.

作者信息

Pal Tanmoy, Wessén Jonas, Das Suman, Chan Hue Sun

机构信息

Department of Biochemistry, University of Toronto, Toronto, Ontario M5S 1A8, Canada.

出版信息

Phys Rev E. 2021 Apr;103(4-1):042406. doi: 10.1103/PhysRevE.103.042406.

DOI:10.1103/PhysRevE.103.042406

PMID:34005864

Abstract

Polyampholyte field theory and explicit-chain molecular dynamics models of sequence-specific phase separation of a system with two intrinsically disordered protein (IDP) species indicate consistently that a substantial polymer excluded volume and a significant mismatch of the IDP sequence charge patterns can act in concert, but not in isolation, to demix the two IDP species upon condensation. This finding reveals an energetic-geometric interplay in a stochastic, "fuzzy" molecular recognition mechanism that may facilitate subcompartmentalization of membraneless organelles.

摘要

两性电解质场论以及具有两种内在无序蛋白质（IDP）物种的系统的序列特异性相分离的显式链分子动力学模型一致表明，大量的聚合物排除体积和IDP序列电荷模式的显著不匹配可以协同作用，但不能单独作用，以使两种IDP物种在凝聚时发生 demix。这一发现揭示了一种随机的、“模糊”分子识别机制中的能量 - 几何相互作用，这种相互作用可能有助于无膜细胞器的亚区室化。

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两性聚电解质物种在细胞器样凝聚物中的亚区室化是由电荷模式不匹配和强烈的排除体积相互作用促进的。

Subcompartmentalization of polyampholyte species in organelle-like condensates is promoted by charge-pattern mismatch and strong excluded-volume interaction.

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