RNA scaffolds the Golgi ribbon by forming condensates with GM130

The mammalian Golgi is composed of stacks that are laterally connected into a continuous ribbon-like structure. The integrity and function of the ribbon is disrupted under stress conditions, but the molecular mechanisms remain unclear. Here we show that the ribbon is maintained by biomolecular conde...

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Veröffentlicht in:	Nature cell biology 2024-07, Vol.26 (7), p.1139-1153
Hauptverfasser:	Zhang, Yijun, Seemann, Joachim
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Schlagworte:	631/45/500 631/80/642/1525 Biology Biomedical and Life Sciences Biopolymers Cancer Research Cell Biology Condensates Developmental Biology Golgi cells Integrity Life Sciences Liquid phases Matrix protein Membrane proteins Membranes Molecular modelling Molecular structure Phase separation Protein structure Proteins Ribonucleic acid RNA RNA-binding protein Stacks Stem Cells Structure-function relationships
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container_title	Nature cell biology
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creator	Zhang, Yijun Seemann, Joachim
description	The mammalian Golgi is composed of stacks that are laterally connected into a continuous ribbon-like structure. The integrity and function of the ribbon is disrupted under stress conditions, but the molecular mechanisms remain unclear. Here we show that the ribbon is maintained by biomolecular condensates of RNA and the Golgi matrix protein GM130 (GOLGA2). We identify GM130 as a membrane-bound RNA-binding protein, which directly recruits RNA and associated RNA-binding proteins to the Golgi membrane. Acute degradation of RNA or GM130 in cells disrupts the ribbon. Under stress conditions, RNA dissociates from GM130 and the ribbon is disjointed, but after the cells recover from stress the ribbon is restored. When overexpressed in cells, GM130 forms RNA-dependent liquid-like condensates. GM130 contains an intrinsically disordered domain at its amino terminus, which binds RNA to induce liquid–liquid phase separation. These co-condensates are sufficient to link purified Golgi membranes, reconstructing lateral linking of stacks into a ribbon-like structure. Together, these studies show that RNA acts as a structural biopolymer that together with GM130 maintains the integrity of the Golgi ribbon. Zhang and Seemann show that GM130 forms a complex with RNA-binding proteins. RNA binding of GM130 induces liquid–liquid phase separation and these co-condensates function to link the Golgi ribbon.
doi_str_mv	10.1038/s41556-024-01447-2
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The integrity and function of the ribbon is disrupted under stress conditions, but the molecular mechanisms remain unclear. Here we show that the ribbon is maintained by biomolecular condensates of RNA and the Golgi matrix protein GM130 (GOLGA2). We identify GM130 as a membrane-bound RNA-binding protein, which directly recruits RNA and associated RNA-binding proteins to the Golgi membrane. Acute degradation of RNA or GM130 in cells disrupts the ribbon. Under stress conditions, RNA dissociates from GM130 and the ribbon is disjointed, but after the cells recover from stress the ribbon is restored. When overexpressed in cells, GM130 forms RNA-dependent liquid-like condensates. GM130 contains an intrinsically disordered domain at its amino terminus, which binds RNA to induce liquid–liquid phase separation. These co-condensates are sufficient to link purified Golgi membranes, reconstructing lateral linking of stacks into a ribbon-like structure. 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subjects	631/45/500 631/80/642/1525 Biology Biomedical and Life Sciences Biopolymers Cancer Research Cell Biology Condensates Developmental Biology Golgi cells Integrity Life Sciences Liquid phases Matrix protein Membrane proteins Membranes Molecular modelling Molecular structure Phase separation Protein structure Proteins Ribonucleic acid RNA RNA-binding protein Stacks Stem Cells Structure-function relationships
title	RNA scaffolds the Golgi ribbon by forming condensates with GM130
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