Direct Quantification of Ligand-Induced Lipid and Protein Microdomains with Distinctive Signaling Properties**

IF 3.1 Q2 CHEMISTRY, MULTIDISCIPLINARY
Dr. Daniel Wirth, Dr. Michael D. Paul, Prof. Elena B. Pasquale, Prof. Kalina Hristova
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Abstract

Lipid rafts are ordered lipid domains that are enriched in saturated lipids, such as the ganglioside GM1. While lipid rafts are believed to exist in cells and to serve as signaling platforms through their enrichment in signaling components, they have not been directly observed in the plasma membrane without treatments that artificially cluster GM1 into large lattices. Here, we report that microscopic GM1-enriched domains can form in the plasma membrane of live mammalian cells expressing the EphA2 receptor tyrosine kinase in response to its ligand ephrinA1-Fc. The GM1-enriched microdomains form concomitantly with EphA2-enriched microdomains. To gain insight into how plasma membrane heterogeneity controls signaling, we quantify the degree of EphA2 segregation and study initial EphA2 signaling steps in both EphA2-enriched and EphA2-depleted domains. By measuring dissociation constants, we demonstrate that the propensity of EphA2 to oligomerize is similar in EphA2-enriched and -depleted domains. However, surprisingly, EphA2 interacts preferentially with its downstream effector SRC in EphA2-depleted domains. The ability to induce microscopic GM1-enriched domains in live cells using a ligand for a transmembrane receptor will give us unprecedented opportunities to study the biophysical chemistry of lipid rafts.

Abstract Image

配体诱导的具有独特信号特性的脂质和蛋白质微域的直接定量研究**
脂筏是有序的脂质结构域,富含饱和脂质,如神经节苷脂GM1。虽然脂筏被认为存在于细胞中,并通过富集信号成分作为信号传导平台,但如果没有人工将GM1聚集成大晶格的处理,它们在质膜中并未被直接观察到。在这里,我们报道了微观的gm1富集结构域可以在活的哺乳动物细胞的质膜上形成,表达EphA2受体酪氨酸激酶响应其配体ephrinA1-Fc。富含gm1的微域与富含epha2的微域同时形成。为了深入了解质膜异质性如何控制信号传导,我们量化了EphA2分离的程度,并研究了EphA2富集和EphA2缺失结构域中EphA2的初始信号传导步骤。通过测量解离常数,我们证明EphA2的寡聚倾向在EphA2富集和缺失的结构域是相似的。然而,令人惊讶的是,EphA2优先与EphA2缺失区域的下游效应物SRC相互作用。使用跨膜受体配体在活细胞中诱导微观gm1富集结构域的能力将为我们研究脂筏的生物物理化学提供前所未有的机会。
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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CiteScore
7.00
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