合成细胞模型中膜相分离与细菌分裂蛋白动态之间的相互依存关系

Nishu Kanwa, Shunshi Kohyama, Leonard Fröhlich, Amogh Desai, Petra Schwille
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引用次数: 0

摘要

细菌的细胞膜是横向极化的,为膜蛋白创造了特定的环境,例如,参与细胞分裂的蛋白质聚集在细胞中部或细胞两极。这种膜-脂相互作用的一个有趣结果是,在细胞分裂开始时,脂质结构域与膜结合蛋白一起重组,这表明膜区在细胞周期中具有功能意义。在这里,我们以关键的细菌分裂蛋白 MinCDE 和 FtsZ 为原型空间模式系统,提出了一个简单的基于囊泡的体外模型,以探索蛋白模式形成与膜异质性的相互依存关系。与许多其他外周膜蛋白一样,MinDE在Ld结构域表现出优先结合和大尺度模式形成,这导致相分离膜区(GUVs)中振荡模式选择的改变。此外,在相分离的 GUVs 中加入细菌分裂蛋白会导致类似裂片的膜变形,随后在裂片颈部区域对齐的 Lo 结构域会重组,这与紧接着径向收缩过程之前细菌膜中的结构域重组非常吻合。总之,所介绍的体外模型系统展示了一个基本框架,以便在考虑复杂的细胞脂质环境时更好地理解细胞分裂机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Mutual dependence between membrane phase separation and bacterial division protein dynamics in synthetic cell models
Cell membranes in bacteria are laterally polarized to produce specific environments for membrane proteins, e.g., proteins involved in cell division which accumulate at mid-cell or the cell poles. An interesting result of such membrane-lipid interplay is the reorganization of lipid domains together with membrane-bound proteins at the onset of cell division, suggesting a functional significance of membrane compartments in the cell cycle. Here, by adopting the key bacterial division proteins MinCDE and FtsZ as an archetypal spatial patterning system, we present a simple vesicle-based in vitro model to explore the mutual dependence of protein pattern formation and membrane heterogeneity. Like many other peripheral membrane proteins, MinDE exhibit preferential binding and macro-scale pattern formation at Ld domains, which leads to altered oscillation mode selection in phase-separated membrane compartments (GUVs). Moreover, incorporating bacterial division proteins within phase-separated GUVs leads to blebbing-like membrane deformations followed by the reorganization of Lo domains aligning at the neck region of the bleb, which agrees well with the domain rearrangement in bacterial membranes immediately preceding the radial constriction process. Overall, the presented in vitro model system showcases a basic framework to better comprehend the cellular division mechanism in consideration of complex cellular lipid environments.
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