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米罗GTP酶对线粒体动力学的双向钙离子依赖性调控

Bidirectional Ca2+-dependent control of mitochondrial dynamics by the Miro GTPase.

作者信息

Saotome Masao, Safiulina Dzhamilja, Szabadkai György, Das Sudipto, Fransson Asa, Aspenstrom Pontus, Rizzuto Rosario, Hajnóczky György

机构信息

Department of Pathology, Anatomy and Cell Biology, Thomas Jefferson University, Philadelphia, PA 19107, USA.

出版信息

Proc Natl Acad Sci U S A. 2008 Dec 30;105(52):20728-33. doi: 10.1073/pnas.0808953105. Epub 2008 Dec 19.

DOI:10.1073/pnas.0808953105
PMID:19098100
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2634948/
Abstract

Calcium oscillations suppress mitochondrial movements along the microtubules to support on-demand distribution of mitochondria. To activate this mechanism, Ca(2+) targets a yet unidentified cytoplasmic factor that does not seem to be a microtubular motor or a kinase/phosphatase. Here, we have studied the dependence of mitochondrial dynamics on the Miro GTPases that reside in the mitochondria and contain two EF-hand Ca(2+)-binding domains, in H9c2 cells and primary neurons. At resting cytoplasmic [Ca(2+)] (Ca(2+)), movements of the mitochondria were enhanced by Miro overexpression irrespective of the presence of the EF-hands. The Ca(2+)-induced arrest of mitochondrial motility was also promoted by Miro overexpression and was suppressed when either the Miro were depleted or their EF-hand was mutated. Miro also enhanced the fusion state of the mitochondria at resting Ca(2+) but promoted mitochondrial fragmentation at high Ca(2+). These effects of Miro on mitochondrial morphology seem to involve Drp1 suppression and activation, respectively. In primary neurons, Miro also caused an increase in dendritic mitochondrial mass and enhanced mitochondrial calcium signaling. Thus, Miro proteins serve as a Ca(2+)-sensitive switch and bifunctional regulator for both the motility and fusion-fission dynamics of the mitochondria.

摘要

钙振荡抑制线粒体沿微管的移动,以支持线粒体按需分布。为激活这一机制,Ca(2+)作用于一个尚未明确的胞质因子,该因子似乎既不是微管马达,也不是激酶/磷酸酶。在此,我们在H9c2细胞和原代神经元中研究了线粒体动力学对线粒体中存在的、含有两个EF手型Ca(2+)结合结构域的Miro GTP酶的依赖性。在静息胞质[Ca(2+)]([Ca(2+)]c)时,无论EF手型结构域是否存在,Miro过表达都会增强线粒体的移动。Miro过表达也会促进Ca(2+)诱导的线粒体运动停滞,而当Miro被耗尽或其EF手型结构域发生突变时,这种停滞会受到抑制。Miro还会在静息[Ca(2+)]c时增强线粒体的融合状态,但在高[Ca(2+)]c时促进线粒体分裂。Miro对线粒体形态的这些影响似乎分别涉及Drp1的抑制和激活。在原代神经元中,Miro还会导致树突线粒体质量增加,并增强线粒体钙信号传导。因此,Miro蛋白作为一种对[Ca(2+)]c敏感的开关和双功能调节剂,调节线粒体的运动以及融合-分裂动力学。

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