Riedel, Dietmar

[["dc.bibliographiccitation.firstpage","e0240768"],["dc.bibliographiccitation.issue","5"],["dc.bibliographiccitation.journal","PLoS One"],["dc.bibliographiccitation.volume","16"],["dc.contributor.author","Lange, Felix"],["dc.contributor.author","Agüi-Gonzalez, Paola"],["dc.contributor.author","Riedel, Dietmar"],["dc.contributor.author","Phan, Nhu T. N."],["dc.contributor.author","Jakobs, Stefan"],["dc.contributor.author","Rizzoli, Silvio O."],["dc.date.accessioned","2021-08-12T07:45:38Z"],["dc.date.available","2021-08-12T07:45:38Z"],["dc.date.issued","2021"],["dc.description.abstract","Electron microscopy (EM) has been employed for decades to analyze cell structure. To also analyze the positions and functions of specific proteins, one typically relies on immuno-EM or on a correlation with fluorescence microscopy, in the form of correlated light and electron microscopy (CLEM). Nevertheless, neither of these procedures is able to also address the isotopic composition of cells. To solve this, a correlation with secondary ion mass spectrometry (SIMS) would be necessary. SIMS has been correlated in the past to EM or to fluorescence microscopy in biological samples, but not to CLEM. We achieved this here, using a protocol based on transmission EM, conventional epifluorescence microscopy and nanoSIMS. The protocol is easily applied, and enables the use of all three technologies at high performance parameters. We suggest that CLEM-SIMS will provide substantial information that is currently beyond the scope of conventional correlative approaches."],["dc.description.sponsorship","Open-Access-Publikationsfonds 2021"],["dc.identifier.doi","10.1371/journal.pone.0240768"],["dc.identifier.uri","https://resolver.sub.uni-goettingen.de/purl?gro-2/88511"],["dc.language.iso","en"],["dc.notes.intern","DOI Import GROB-448"],["dc.relation.eissn","1932-6203"],["dc.rights","CC BY 4.0"],["dc.title","Correlative fluorescence microscopy, transmission electron microscopy and secondary ion mass spectrometry (CLEM-SIMS) for cellular imaging"],["dc.type","journal_article"],["dc.type.internalPublication","yes"],["dc.type.subtype","original_ja"],["dc.type.version","published_version"],["dspace.entity.type","Publication"]]

[["dc.bibliographiccitation.firstpage","9853"],["dc.bibliographiccitation.issue","20"],["dc.bibliographiccitation.journal","Proceedings of the National Academy of Sciences"],["dc.bibliographiccitation.lastpage","9858"],["dc.bibliographiccitation.volume","116"],["dc.contributor.author","Stoldt, Stefan"],["dc.contributor.author","Stephan, Till"],["dc.contributor.author","Jans, Daniel C."],["dc.contributor.author","Brüser, Christian"],["dc.contributor.author","Lange, Felix"],["dc.contributor.author","Keller-Findeisen, Jan"],["dc.contributor.author","Riedel, Dietmar"],["dc.contributor.author","Hell, Stefan W."],["dc.contributor.author","Jakobs, Stefan"],["dc.date.accessioned","2020-12-10T18:12:52Z"],["dc.date.available","2020-12-10T18:12:52Z"],["dc.date.issued","2019"],["dc.description.abstract","Mitochondria are tubular double-membrane organelles essential for eukaryotic life. They form extended networks and exhibit an intricate inner membrane architecture. The MICOS (mitochondrial contact site and cristae organizing system) complex, crucial for proper architecture of the mitochondrial inner membrane, is localized primarily at crista junctions. Harnessing superresolution fluorescence microscopy, we demonstrate that Mic60, a subunit of the MICOS complex, as well as several of its interaction partners are arranged into intricate patterns in human and yeast mitochondria, suggesting an ordered distribution of the crista junctions. We show that Mic60 forms clusters that are preferentially localized in the inner membrane at two opposing sides of the mitochondrial tubules so that they form extended opposing distribution bands. These Mic60 distribution bands can be twisted, resulting in a helical arrangement. Focused ion beam milling-scanning electron microscopy showed that in yeast the twisting of the opposing distribution bands is echoed by the folding of the inner membrane. We show that establishment of the Mic60 distribution bands is largely independent of the cristae morphology. We suggest that Mic60 is part of an extended multiprotein interaction network that scaffolds mitochondria."],["dc.identifier.doi","10.1073/pnas.1820364116"],["dc.identifier.pmid","31028145"],["dc.identifier.uri","https://resolver.sub.uni-goettingen.de/purl?gro-2/74522"],["dc.identifier.url","https://sfb1190.med.uni-goettingen.de/production/literature/publications/66"],["dc.language.iso","en"],["dc.notes.intern","DOI Import GROB-354"],["dc.relation","SFB 1190: Transportmaschinen und Kontaktstellen zellulärer Kompartimente"],["dc.relation","SFB 1190 | P01: Untersuchung der Unterschiede in der Zusammensetzung, Funktion und Position von individuellen MICOS Komplexen in einzelnen Säugerzellen"],["dc.relation.workinggroup","RG Jakobs (Structure and Dynamics of Mitochondria)"],["dc.rights","CC BY-NC-ND 4.0"],["dc.title","Mic60 exhibits a coordinated clustered distribution along and across yeast and mammalian mitochondria"],["dc.type","journal_article"],["dc.type.internalPublication","yes"],["dc.type.subtype","original_ja"],["dc.type.version","published_version"],["dspace.entity.type","Publication"]]

[["dc.bibliographiccitation.issue","14"],["dc.bibliographiccitation.journal","The EMBO Journal"],["dc.bibliographiccitation.volume","39"],["dc.contributor.author","Stephan, Till"],["dc.contributor.author","Brüser, Christian"],["dc.contributor.author","Deckers, Markus"],["dc.contributor.author","Steyer, Anna M."],["dc.contributor.author","Balzarotti, Francisco"],["dc.contributor.author","Barbot, Mariam"],["dc.contributor.author","Behr, Tiana S."],["dc.contributor.author","Heim, Gudrun"],["dc.contributor.author","Hübner, Wolfgang"],["dc.contributor.author","Ilgen, Peter"],["dc.contributor.author","Lange, Felix"],["dc.contributor.author","Pacheu‐Grau, David"],["dc.contributor.author","Pape, Jasmin K."],["dc.contributor.author","Stoldt, Stefan"],["dc.contributor.author","Huser, Thomas"],["dc.contributor.author","Hell, Stefan W."],["dc.contributor.author","Möbius, Wiebke"],["dc.contributor.author","Rehling, Peter"],["dc.contributor.author","Riedel, Dietmar"],["dc.contributor.author","Jakobs, Stefan"],["dc.date.accessioned","2021-04-14T08:25:12Z"],["dc.date.available","2021-04-14T08:25:12Z"],["dc.date.issued","2020"],["dc.description.abstract","Mitochondrial function is critically dependent on the folding of the mitochondrial inner membrane into cristae; indeed, numerous human diseases are associated with aberrant crista morphologies. With the MICOS complex, OPA1 and the F1Fo-ATP synthase, key players of cristae biogenesis have been identified, yet their interplay is poorly understood. Harnessing super-resolution light and 3D electron microscopy, we dissect the roles of these proteins in the formation of cristae in human mitochondria. We individually disrupted the genes of all seven MICOS subunits in human cells and re-expressed Mic10 or Mic60 in the respective knockout cell line. We demonstrate that assembly of the MICOS complex triggers remodeling of pre-existing unstructured cristae and de novo formation of crista junctions (CJs) on existing cristae. We show that the Mic60-subcomplex is sufficient for CJ formation, whereas the Mic10-subcomplex controls lamellar cristae biogenesis. OPA1 stabilizes tubular CJs and, along with the F1Fo-ATP synthase, fine-tunes the positioning of the MICOS complex and CJs. We propose a new model of cristae formation, involving the coordinated remodeling of an unstructured crista precursor into multiple lamellar cristae."],["dc.identifier.doi","10.15252/embj.2019104105"],["dc.identifier.pmid","32567732"],["dc.identifier.uri","https://resolver.sub.uni-goettingen.de/purl?gro-2/81550"],["dc.identifier.url","https://mbexc.uni-goettingen.de/literature/publications/51"],["dc.identifier.url","https://sfb1190.med.uni-goettingen.de/production/literature/publications/115"],["dc.identifier.url","https://for2848.gwdguser.de/literature/publications/25"],["dc.language.iso","en"],["dc.notes.intern","DOI Import GROB-399"],["dc.relation","EXC 2067: Multiscale Bioimaging"],["dc.relation","SFB 1190: Transportmaschinen und Kontaktstellen zellulärer Kompartimente"],["dc.relation","SFB 1190 | P01: Untersuchung der Unterschiede in der Zusammensetzung, Funktion und Position von individuellen MICOS Komplexen in einzelnen Säugerzellen"],["dc.relation","SFB 1190 | P13: Protein Transport über den mitochondrialen Carrier Transportweg"],["dc.relation","FOR 2848: Architektur und Heterogenität der inneren mitochondrialen Membran auf der Nanoskala"],["dc.relation","FOR 2848 | P04: Analyse der räumlichen Organisation der OXPHOS Assemblierung in Säugerzellen"],["dc.relation.eissn","1460-2075"],["dc.relation.issn","0261-4189"],["dc.relation.workinggroup","RG Hell"],["dc.relation.workinggroup","RG Jakobs (Structure and Dynamics of Mitochondria)"],["dc.relation.workinggroup","RG Möbius"],["dc.relation.workinggroup","RG Rehling (Mitochondrial Protein Biogenesis)"],["dc.relation.workinggroup","RG Riedel"],["dc.rights","CC BY 4.0"],["dc.title","MICOS assembly controls mitochondrial inner membrane remodeling and crista junction redistribution to mediate cristae formation"],["dc.type","journal_article"],["dc.type.internalPublication","yes"],["dc.type.subtype","original_ja"],["dc.type.version","published_version"],["dspace.entity.type","Publication"]]

[["dc.bibliographiccitation.firstpage","20607"],["dc.bibliographiccitation.issue","34"],["dc.bibliographiccitation.journal","Proceedings of the National Academy of Sciences"],["dc.bibliographiccitation.lastpage","20614"],["dc.bibliographiccitation.volume","117"],["dc.contributor.author","Pape, Jasmin K."],["dc.contributor.author","Stephan, Till"],["dc.contributor.author","Balzarotti, Francisco"],["dc.contributor.author","Büchner, Rebecca"],["dc.contributor.author","Lange, Felix"],["dc.contributor.author","Riedel, Dietmar"],["dc.contributor.author","Jakobs, Stefan"],["dc.contributor.author","Hell, Stefan W."],["dc.date.accessioned","2021-04-14T08:24:20Z"],["dc.date.available","2021-04-14T08:24:20Z"],["dc.date.issued","2020"],["dc.description.abstract","The mitochondrial contact site and cristae organizing system (MICOS) is a multisubunit protein complex that is essential for the proper architecture of the mitochondrial inner membrane. MICOS plays a key role in establishing and maintaining crista junctions, tubular or slit-like structures that connect the cristae membrane with the inner boundary membrane, thereby ensuring a contiguous inner membrane. MICOS is enriched at crista junctions, but the detailed distribution of its subunits around crista junctions is unclear because such small length scales are inaccessible with established fluorescence microscopy. By targeting individually activated fluorophores with an excitation beam featuring a central zero-intensity point, the nanoscopy method called MINFLUX delivers single-digit nanometer-scale three-dimensional (3D) resolution and localization precision. We employed MINFLUX nanoscopy to investigate the submitochondrial localization of the core MICOS subunit Mic60 in relation to two other MICOS proteins, Mic10 and Mic19. We demonstrate that dual-color 3D MINFLUX nanoscopy is applicable to the imaging of organellar substructures, yielding a 3D localization precision of ∼5 nm in human mitochondria. This isotropic precision facilitated the development of an analysis framework that assigns localization clouds to individual molecules, thus eliminating a source of bias when drawing quantitative conclusions from single-molecule localization microscopy data. MINFLUX recordings of Mic60 indicate ringlike arrangements of multiple molecules with a diameter of 40 to 50 nm, suggesting that Mic60 surrounds individual crista junctions. Statistical analysis of dual-color MINFLUX images demonstrates that Mic19 is generally in close proximity to Mic60, whereas the spatial coordination of Mic10 with Mic60 is less regular, suggesting structural heterogeneity of MICOS."],["dc.identifier.doi","10.1073/pnas.2009364117"],["dc.identifier.pmid","32788360"],["dc.identifier.uri","https://resolver.sub.uni-goettingen.de/purl?gro-2/81251"],["dc.identifier.url","https://mbexc.uni-goettingen.de/literature/publications/61"],["dc.identifier.url","https://sfb1190.med.uni-goettingen.de/production/literature/publications/124"],["dc.language.iso","en"],["dc.notes.intern","DOI Import GROB-399"],["dc.relation","EXC 2067: Multiscale Bioimaging"],["dc.relation","SFB 1190: Transportmaschinen und Kontaktstellen zellulärer Kompartimente"],["dc.relation","SFB 1190 | P01: Untersuchung der Unterschiede in der Zusammensetzung, Funktion und Position von individuellen MICOS Komplexen in einzelnen Säugerzellen"],["dc.relation.eissn","1091-6490"],["dc.relation.issn","0027-8424"],["dc.relation.workinggroup","RG Hell"],["dc.relation.workinggroup","RG Jakobs (Structure and Dynamics of Mitochondria)"],["dc.rights","CC BY-NC-ND 4.0"],["dc.title","Multicolor 3D MINFLUX nanoscopy of mitochondrial MICOS proteins"],["dc.type","journal_article"],["dc.type.internalPublication","yes"],["dc.type.subtype","original_ja"],["dc.type.version","published_version"],["dspace.entity.type","Publication"]]