Super-resolution modularity analysis shows polyhedral caveolin-1 oligomers combine to form scaffolds and caveolae

Caveolin-1 (Cav1), the coat protein for caveolae, also forms non-caveolar Cav1 scaffolds. Single molecule Cav1 super-resolution microscopy analysis previously identified caveolae and three distinct scaffold domains: smaller S1A and S2B scaffolds and larger hemispherical S2 scaffolds. Application her...

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Veröffentlicht in:	Scientific reports 2019-07, Vol.9 (1), p.9888-10, Article 9888
Hauptverfasser:	Khater, Ismail M., Liu, Qian, Chou, Keng C., Hamarneh, Ghassan, Nabi, Ivan Robert
Format:	Artikel
Sprache:	eng
Schlagworte:	101/1 631/114/1564 631/1647/328/2238 631/80/313/2026 Caveolae Caveolae - metabolism Caveolin Caveolin 1 - metabolism Caveolin-1 Cell Line, Tumor Cell Membrane - metabolism Coat protein HeLa Cells Humanities and Social Sciences Humans Localization Microscopy Microscopy - methods multidisciplinary Prostate cancer Proteins Science Science (multidisciplinary) Single Molecule Imaging - methods
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description	Caveolin-1 (Cav1), the coat protein for caveolae, also forms non-caveolar Cav1 scaffolds. Single molecule Cav1 super-resolution microscopy analysis previously identified caveolae and three distinct scaffold domains: smaller S1A and S2B scaffolds and larger hemispherical S2 scaffolds. Application here of network modularity analysis of SMLM data for endogenous Cav1 labeling in HeLa cells shows that small scaffolds combine to form larger scaffolds and caveolae. We find modules within Cav1 blobs by maximizing the intra-connectivity between Cav1 molecules within a module and minimizing the inter-connectivity between Cav1 molecules across modules, which is achieved via spectral decomposition of the localizations adjacency matrix. Features of modules are then matched with intact blobs to find the similarity between the module-blob pairs of group centers. Our results show that smaller S1A and S1B scaffolds are made up of small polygons, that S1B scaffolds correspond to S1A scaffold dimers and that caveolae and hemispherical S2 scaffolds are complex, modular structures formed from S1B and S1A scaffolds, respectively. Polyhedral interactions of Cav1 oligomers, therefore, leads progressively to the formation of larger and more complex scaffold domains and the biogenesis of caveolae.
doi_str_mv	10.1038/s41598-019-46174-z
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Single molecule Cav1 super-resolution microscopy analysis previously identified caveolae and three distinct scaffold domains: smaller S1A and S2B scaffolds and larger hemispherical S2 scaffolds. Application here of network modularity analysis of SMLM data for endogenous Cav1 labeling in HeLa cells shows that small scaffolds combine to form larger scaffolds and caveolae. We find modules within Cav1 blobs by maximizing the intra-connectivity between Cav1 molecules within a module and minimizing the inter-connectivity between Cav1 molecules across modules, which is achieved via spectral decomposition of the localizations adjacency matrix. Features of modules are then matched with intact blobs to find the similarity between the module-blob pairs of group centers. 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Single molecule Cav1 super-resolution microscopy analysis previously identified caveolae and three distinct scaffold domains: smaller S1A and S2B scaffolds and larger hemispherical S2 scaffolds. Application here of network modularity analysis of SMLM data for endogenous Cav1 labeling in HeLa cells shows that small scaffolds combine to form larger scaffolds and caveolae. We find modules within Cav1 blobs by maximizing the intra-connectivity between Cav1 molecules within a module and minimizing the inter-connectivity between Cav1 molecules across modules, which is achieved via spectral decomposition of the localizations adjacency matrix. Features of modules are then matched with intact blobs to find the similarity between the module-blob pairs of group centers. Our results show that smaller S1A and S1B scaffolds are made up of small polygons, that S1B scaffolds correspond to S1A scaffold dimers and that caveolae and hemispherical S2 scaffolds are complex, modular structures formed from S1B and S1A scaffolds, respectively. Polyhedral interactions of Cav1 oligomers, therefore, leads progressively to the formation of larger and more complex scaffold domains and the biogenesis of caveolae.</abstract><cop>London</cop><pub>Nature Publishing Group UK</pub><pmid>31285524</pmid><doi>10.1038/s41598-019-46174-z</doi><tpages>10</tpages><orcidid>https://orcid.org/0000-0002-0670-0513</orcidid><orcidid>https://orcid.org/0000-0002-8782-5253</orcidid><oa>free_for_read</oa></addata></record>
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subjects	101/1 631/114/1564 631/1647/328/2238 631/80/313/2026 Caveolae Caveolae - metabolism Caveolin Caveolin 1 - metabolism Caveolin-1 Cell Line, Tumor Cell Membrane - metabolism Coat protein HeLa Cells Humanities and Social Sciences Humans Localization Microscopy Microscopy - methods multidisciplinary Prostate cancer Proteins Science Science (multidisciplinary) Single Molecule Imaging - methods
title	Super-resolution modularity analysis shows polyhedral caveolin-1 oligomers combine to form scaffolds and caveolae
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