Membranes arrest the coarsening of mitochondrial condensates.

bioRxiv : the preprint server for biology Pub Date : 2025-06-08 DOI:10.1101/2025.06.06.658068

Sanjaya V B D Aththawala Gedara, Surya Teja Penna, Marina Feric

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Abstract

Mitochondria contain double membranes that enclose their contents. Within their interior, the mitochondrial genome and its RNA products are condensed into ~100 nm sized (ribo)nucleoprotein complexes. How these endogenous condensates maintain their roughly uniform size and spatial distributions within membranous mitochondria remains unclear. Here, we engineered an optogenetic tool (mt-optoIDR) that allowed for controlled formation of synthetic condensates upon light activation in live mitochondria. Using live cell super-resolution microscopy, we visualized the nucleation of small, yet elongated condensates (mt-opto-condensates), which recapitulated the morphologies of endogenous mitochondrial condensates. We decoupled the contribution of the double membranes from the environment within the matrix by overexpressing the dominant negative mutant of a membrane fusion protein (Drp1K38A). The resulting bulbous mitochondria had significantly more dynamic condensates that coarsened into a single, prominent droplet. These observations inform how mitochondrial membranes can limit the growth and dynamics of the condensates they enclose, without the need of additional regulatory mechanisms.

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膜阻止线粒体凝聚物的粗化。

线粒体含有双层膜，将其内容物包裹起来。在线粒体内部，线粒体基因组及其RNA产物被浓缩成约100 nm大小的核蛋白复合物。这些内源性凝析物如何在膜性线粒体内保持大致均匀的大小和空间分布尚不清楚。在这里，我们设计了一种光遗传学工具（mt-optoIDR），允许在活线粒体的光激活下控制合成凝聚物的形成。利用活细胞超分辨率显微镜，我们看到了小而细长的凝聚物（mt-opto-冷凝物）的成核，它概括了内源性线粒体凝聚物的形态。我们通过过表达膜融合蛋白（Drp1K38A）的显性负突变体，将双膜的贡献从基质内的环境中分离出来。由此产生的球茎状线粒体具有明显更多的动态凝聚物，这些凝聚物粗化成单个突出的液滴。这些观察结果告诉我们，线粒体膜是如何在不需要额外的调节机制的情况下，限制它们所包围的凝聚物的生长和动力学的。

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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bioRxiv : the preprint server for biology

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