The ARL2 GTPase regulates mitochondrial fusion from the intermembrane space.

Cellular logistics Pub Date : 2017-06-23 eCollection Date: 2017-01-01 DOI:10.1080/21592799.2017.1340104
Laura E Newman, Cara R Schiavon, Rachel E Turn, Richard A Kahn
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Abstract

Mitochondria are essential, dynamic organelles that regularly undergo both fusion and fission in response to cellular conditions, though mechanisms of the regulation of their dynamics are incompletely understood. We provide evidence that increased activity of the small GTPase ARL2 is strongly correlated with an increase in fusion, while loss of ARL2 activity results in a decreased rate of mitochondrial fusion. Strikingly, expression of activated ARL2 can partially restore the loss of fusion resulting from deletion of either mitofusin 1 (MFN1) or mitofusin 2 (MFN2), but not deletion of both. We only observe the full effects of ARL2 on mitochondrial fusion when it is present in the intermembrane space (IMS), as constructs driven to the matrix or prevented from entering mitochondria are essentially inactive in promoting fusion. Thus, ARL2 is the first regulatory (small) GTPase shown to act inside mitochondria or in the fusion pathway. Finally, using high-resolution, structured illumination microscopy (SIM), we find that ARL2 and mitofusin immunoreactivities present as punctate staining along mitochondria that share a spatial convergence in fluorescence signals. Thus, we propose that ARL2 plays a regulatory role in mitochondrial fusion, acting from the IMS and requiring at least one of the mitofusins in their canonical role in fusion of the outer membranes.

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ARL2 GTPase 可调节线粒体与膜间隙的融合。
线粒体是重要的动态细胞器,会根据细胞条件定期发生融合和分裂,但其动态调控机制尚不完全清楚。我们提供的证据表明,小 GTP 酶 ARL2 活性的增加与融合的增加密切相关,而 ARL2 活性的丧失会导致线粒体融合率的降低。令人震惊的是,表达活化的 ARL2 可以部分恢复因缺失丝裂蛋白 1(MFN1)或丝裂蛋白 2(MFN2)而导致的融合损失,但不能同时缺失这两种蛋白。只有当 ARL2 存在于膜间空间(IMS)时,我们才能观察到它对线粒体融合的全部作用,因为被驱赶到基质中或被阻止进入线粒体的构建体在促进融合方面基本上没有作用。因此,ARL2 是第一个在线粒体内部或融合途径中发挥作用的调节性(小)GTPase。最后,通过使用高分辨率结构照明显微镜(SIM),我们发现 ARL2 和丝裂霉素的免疫活性表现为沿线粒体的点状染色,它们的荧光信号在空间上趋于一致。因此,我们认为 ARL2 在线粒体融合过程中发挥着调控作用,它从 IMS 起作用,并需要至少一种丝裂蛋白在外膜融合过程中发挥典型作用。
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