人类凋亡扰乱酶 Xkr4 的结构和功能

Alessio Accardi, Sayan Chakraborty, Zhang Feng, Sangyun Lee, Omar E Alvarenga, Aniruddha Panda, Renato Bruni, George Khelashvili, Kallol Gupta
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引用次数: 0

摘要

垂死细胞表面的磷脂酰丝氨酸外化是巨噬细胞识别和清除这些细胞的关键信号,由 X-Kell 相关蛋白(Xkr)家族成员介导。Xkr 介导的扰乱功能缺陷会损害清除能力,从而导致炎症。有人提出,Xkr4 细胞凋亡扰乱酶的激活需要 Caspase 酶裂解,然后是二聚化和配体结合。在这里,我们综合使用了多种生化方法,证明纯化的单体全长人 Xkr4(hXkr4)能扰乱脂质。冷冻电子显微镜成像显示,hXkr4 采用了一种新的构象,其中三个保守的酸性残基形成了一个嵌入膜中的电负性表面。分子动力学模拟显示,这种构象会导致膜变薄,从而促进扰乱。在扰乱被取消或减少的条件下,膜变薄会被消除或减少。我们的研究深入揭示了 hXkr4 扰乱的分子机制,并表明膜变薄的能力可能是活性扰乱酶的一般特性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Structure and function of the human apoptotic scramblase Xkr4
Phosphatidylserine externalization on the surface of dying cells is a key signal for their recognition and clearance by macrophages and is mediated by members of the X-Kell related (Xkr) protein family. Defective Xkr-mediated scrambling impairs clearance, leading to inflammation. It was proposed that activation of the Xkr4 apoptotic scramblase requires caspase cleavage, followed by dimerization and ligand binding. Here, using a combination of biochemical approaches we show that purified monomeric, full-length human Xkr4 (hXkr4) scrambles lipids. CryoEM imaging shows that hXkr4 adopts a novel conformation, where three conserved acidic residues create an electronegative surface embedded in the membrane. Molecular dynamics simulations show this conformation induces membrane thinning, which could promote scrambling. Thinning is ablated or reduced in conditions where scrambling is abolished or reduced. Our work provides insights into the molecular mechanisms of hXkr4 scrambling and suggests the ability to thin membranes might be a general property of active scramblases.
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