A roadmap for ribosome assembly in human mitochondria

Elena Lavdovskaia, Elisa Hanitsch, Andreas Linden, Martin Pašen, Venkatapathi Challa, Yehor Horokhovskyi, Hanna P. Roetschke, Franziska Nadler, Luisa Welp, Emely Steube, Marleen Heinrichs, Mandy Mong-Quyen Mai, Henning Urlaub, Juliane Liepe, Ricarda Richter-Dennerlein
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Abstract

Mitochondria contain dedicated ribosomes (mitoribosomes), which synthesize the mitochondrial-encoded core components of the oxidative phosphorylation complexes. The RNA and protein components of mitoribosomes are encoded on two different genomes (mitochondrial and nuclear) and are assembled into functional complexes with the help of dedicated factors inside the organelle. Defects in mitoribosome biogenesis are associated with severe human diseases, yet the molecular pathway of mitoribosome assembly remains poorly understood. Here, we applied a multidisciplinary approach combining biochemical isolation and analysis of native mitoribosomal assembly complexes with quantitative mass spectrometry and mathematical modeling to reconstitute the entire assembly pathway of the human mitoribosome. We show that, in contrast to its bacterial and cytosolic counterparts, human mitoribosome biogenesis involves the formation of ribosomal protein-only modules, which then assemble on the appropriate ribosomal RNA moiety in a coordinated fashion. The presence of excess protein-only modules primed for assembly rationalizes how mitochondria cope with the challenge of forming a protein-rich ribonucleoprotein complex of dual genetic origin. This study provides a comprehensive roadmap of mitoribosome biogenesis, from very early to late maturation steps, and highlights the evolutionary divergence from its bacterial ancestor.

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人类线粒体核糖体组装路线图
线粒体含有专用核糖体(mitoribosomes),可合成线粒体编码的氧化磷酸化复合物的核心成分。核糖体的 RNA 和蛋白质成分由两个不同的基因组(线粒体和核)编码,并在细胞器内专用因子的帮助下组装成功能性复合物。线粒体生物发生缺陷与严重的人类疾病有关,但人们对线粒体组装的分子途径仍然知之甚少。在这里,我们采用一种多学科方法,结合生化分离和分析原生mitoribosome组装复合物、定量质谱分析和数学建模,重建了人类mitoribosome的整个组装途径。我们的研究表明,与细菌和细胞质中的核糖体不同,人类核糖体的生物发生涉及核糖体纯蛋白模块的形成,然后这些模块以协调的方式组装到适当的核糖体 RNA 分子上。过量的纯蛋白质模块为组装做好了准备,这说明线粒体如何应对挑战,形成富含蛋白质的双基因核糖核蛋白复合物。这项研究为线粒体的生物发生提供了一个从早期到晚期成熟步骤的全面路线图,并强调了线粒体与其细菌祖先的进化分化。
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