Jans, Daniel C.

[["dc.bibliographiccitation.firstpage","247"],["dc.bibliographiccitation.issue","2"],["dc.bibliographiccitation.journal","Molecular Biology of the Cell"],["dc.bibliographiccitation.lastpage","257"],["dc.bibliographiccitation.volume","23"],["dc.contributor.author","Alkhaja, Alwaleed K."],["dc.contributor.author","Jans, Daniel C."],["dc.contributor.author","Nikolov, Miroslav"],["dc.contributor.author","Vukotic, Milena"],["dc.contributor.author","Lytovchenko, Oleksandr"],["dc.contributor.author","Ludewig, Fabian"],["dc.contributor.author","Schliebs, Wolfgang"],["dc.contributor.author","Riedel, Dietmar"],["dc.contributor.author","Urlaub, Henning"],["dc.contributor.author","Jakobs, Stefan"],["dc.contributor.author","Deckers, Markus"],["dc.date.accessioned","2017-09-07T11:49:01Z"],["dc.date.available","2017-09-07T11:49:01Z"],["dc.date.issued","2012"],["dc.description.abstract","The inner membrane of mitochondria is especially protein rich and displays a unique morphology characterized by large invaginations, the mitochondrial cristae, and the inner boundary membrane, which is in proximity to the outer membrane. Mitochondrial inner membrane proteins appear to be not evenly distributed in the inner membrane, but instead organize into functionally distinct subcompartments. It is unknown how the organization of the inner membrane is achieved. We identified MINOS1/MIO10 (C1orf151/YCL057C-A), a conserved mitochondrial inner membrane protein. mio10-mutant yeast cells are affected in growth on nonfermentable carbon sources and exhibit altered mitochondrial morphology. At the ultrastructural level, mutant mitochondria display loss of inner membrane organization. Proteomic analyses reveal MINOS1/Mio10 as a novel constituent of Mitofilin/Fcj1 complexes in human and yeast mitochondria. Thus our analyses reveal new insight into the composition of the mitochondrial inner membrane organizing machinery."],["dc.identifier.doi","10.1091/mbc.E11-09-0774"],["dc.identifier.gro","3142588"],["dc.identifier.isi","000299108000002"],["dc.identifier.pmid","22114354"],["dc.identifier.purl","https://resolver.sub.uni-goettingen.de/purl?gs-1/7823"],["dc.identifier.uri","https://resolver.sub.uni-goettingen.de/purl?gro-2/8955"],["dc.language.iso","en"],["dc.notes.intern","WoS Import 2017-03-10"],["dc.notes.intern","Merged from goescholar"],["dc.notes.status","final"],["dc.notes.submitter","PUB_WoS_Import"],["dc.relation.issn","1059-1524"],["dc.rights","Goescholar"],["dc.rights.uri","https://goescholar.uni-goettingen.de/licenses"],["dc.title","MINOS1 is a conserved component of mitofilin complexes and required for mitochondrial function and cristae organization"],["dc.type","journal_article"],["dc.type.internalPublication","yes"],["dc.type.peerReviewed","yes"],["dc.type.subtype","original"],["dc.type.version","published_version"],["dspace.entity.type","Publication"]]

[["dc.bibliographiccitation.firstpage","572"],["dc.bibliographiccitation.issue","7"],["dc.bibliographiccitation.journal","Biology"],["dc.bibliographiccitation.volume","10"],["dc.contributor.author","Bollmann, Franziska"],["dc.contributor.author","Dohrke, Jan-Niklas"],["dc.contributor.author","Wurm, Christian A."],["dc.contributor.author","Jans, Daniel C."],["dc.contributor.author","Jakobs, Stefan"],["dc.date.accessioned","2021-09-01T06:43:08Z"],["dc.date.available","2021-09-01T06:43:08Z"],["dc.date.issued","2021"],["dc.description.abstract","Mitochondria are highly dynamic organelles that interchange their contents mediated by fission and fusion. However, it has previously been shown that the mitochondria of cultured human epithelial cells exhibit a gradient in the relative abundance of several proteins, with the perinuclear mitochondria generally exhibiting a higher protein abundance than the peripheral mitochondria. The molecular mechanisms that are required for the establishment and the maintenance of such inner-cellular mitochondrial protein abundance gradients are unknown. We verified the existence of inner-cellular gradients in the abundance of clusters of the mitochondrial outer membrane protein Tom20 in the mitochondria of kidney epithelial cells from an African green monkey (Vero cells) using STED nanoscopy and confocal microscopy. We found that the Tom20 gradients are established immediately after cell division and require the presence of microtubules. Furthermore, the gradients are abrogated in hyperfused mitochondrial networks. Our results suggest that inner-cellular protein abundance gradients from the perinuclear to the peripheral mitochondria are established by the trafficking of individual mitochondria to their respective cellular destination."],["dc.description.abstract","Mitochondria are highly dynamic organelles that interchange their contents mediated by fission and fusion. However, it has previously been shown that the mitochondria of cultured human epithelial cells exhibit a gradient in the relative abundance of several proteins, with the perinuclear mitochondria generally exhibiting a higher protein abundance than the peripheral mitochondria. The molecular mechanisms that are required for the establishment and the maintenance of such inner-cellular mitochondrial protein abundance gradients are unknown. We verified the existence of inner-cellular gradients in the abundance of clusters of the mitochondrial outer membrane protein Tom20 in the mitochondria of kidney epithelial cells from an African green monkey (Vero cells) using STED nanoscopy and confocal microscopy. We found that the Tom20 gradients are established immediately after cell division and require the presence of microtubules. Furthermore, the gradients are abrogated in hyperfused mitochondrial networks. Our results suggest that inner-cellular protein abundance gradients from the perinuclear to the peripheral mitochondria are established by the trafficking of individual mitochondria to their respective cellular destination."],["dc.description.sponsorship","Deutsche Forschungsgemeinschaft"],["dc.description.sponsorship","European Research Council"],["dc.identifier.doi","10.3390/biology10070572"],["dc.identifier.pii","biology10070572"],["dc.identifier.pmid","34201436"],["dc.identifier.uri","https://resolver.sub.uni-goettingen.de/purl?gro-2/89225"],["dc.identifier.url","https://sfb1190.med.uni-goettingen.de/production/literature/publications/146"],["dc.language.iso","en"],["dc.notes.intern","DOI-Import GROB-455"],["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","2079-7737"],["dc.relation.workinggroup","RG Jakobs (Structure and Dynamics of Mitochondria)"],["dc.rights","https://creativecommons.org/licenses/by/4.0/"],["dc.title","Mitochondrial Protein Abundance Gradients Require the Distribution of Separated Mitochondria"],["dc.type","journal_article"],["dc.type.internalPublication","yes"],["dc.type.subtype","original_ja"],["dspace.entity.type","Publication"]]

[["dc.bibliographiccitation.firstpage","1072"],["dc.bibliographiccitation.issue","9"],["dc.bibliographiccitation.journal","Nature Methods"],["dc.bibliographiccitation.lastpage","1075"],["dc.bibliographiccitation.volume","19"],["dc.contributor.author","Ostersehlt, Lynn M."],["dc.contributor.author","Jans, Daniel C."],["dc.contributor.author","Wittek, Anna"],["dc.contributor.author","Keller-Findeisen, Jan"],["dc.contributor.author","Inamdar, Kaushik"],["dc.contributor.author","Sahl, Steffen J."],["dc.contributor.author","Hell, Stefan W."],["dc.contributor.author","Jakobs, Stefan"],["dc.date.accessioned","2022-10-04T10:21:07Z"],["dc.date.available","2022-10-04T10:21:07Z"],["dc.date.issued","2022"],["dc.description.abstract","Abstract\n MINimal fluorescence photon FLUXes (MINFLUX) nanoscopy, providing photon-efficient fluorophore localizations, has brought about three-dimensional resolution at nanometer scales. However, by using an intrinsic on–off switching process for single fluorophore separation, initial MINFLUX implementations have been limited to two color channels. Here we show that MINFLUX can be effectively combined with sequentially multiplexed DNA-based labeling (DNA-PAINT), expanding MINFLUX nanoscopy to multiple molecular targets. Our method is exemplified with three-color recordings of mitochondria in human cells."],["dc.identifier.doi","10.1038/s41592-022-01577-1"],["dc.identifier.pii","1577"],["dc.identifier.uri","https://resolver.sub.uni-goettingen.de/purl?gro-2/114334"],["dc.language.iso","en"],["dc.notes.intern","DOI-Import GROB-600"],["dc.relation.eissn","1548-7105"],["dc.relation.issn","1548-7091"],["dc.rights.uri","https://creativecommons.org/licenses/by/4.0"],["dc.title","DNA-PAINT MINFLUX nanoscopy"],["dc.type","journal_article"],["dc.type.internalPublication","yes"],["dspace.entity.type","Publication"]]

[["dc.bibliographiccitation.firstpage","389"],["dc.bibliographiccitation.journal","FEBS Journal"],["dc.bibliographiccitation.lastpage","390"],["dc.bibliographiccitation.volume","282"],["dc.contributor.author","Barbot, M."],["dc.contributor.author","Jans, D. C."],["dc.contributor.author","Schulz, C."],["dc.contributor.author","Denkert, N."],["dc.contributor.author","Kroppen, B."],["dc.contributor.author","Hoppert, M."],["dc.contributor.author","Jakobs, Sebastian"],["dc.contributor.author","Meinecke, Michael"],["dc.date.accessioned","2018-11-07T09:54:51Z"],["dc.date.available","2018-11-07T09:54:51Z"],["dc.date.issued","2015"],["dc.identifier.isi","000362570607078"],["dc.identifier.uri","https://resolver.sub.uni-goettingen.de/purl?gro-2/36626"],["dc.notes.status","zu prüfen"],["dc.notes.submitter","Najko"],["dc.publisher","Wiley-blackwell"],["dc.publisher.place","Hoboken"],["dc.relation.eventlocation","Berlin, GERMANY"],["dc.relation.issn","1742-4658"],["dc.relation.issn","1742-464X"],["dc.relation.orgunit","Institut für Zellbiochemie"],["dc.title","Mic10 oligomerizes to bend mitochondrial inner membranes at cristae junctions"],["dc.type","conference_abstract"],["dc.type.internalPublication","yes"],["dc.type.peerReviewed","yes"],["dspace.entity.type","Publication"]]

[["dc.bibliographiccitation.firstpage","598"],["dc.bibliographiccitation.issue","2"],["dc.bibliographiccitation.journal","The Journal of Cell Biology"],["dc.bibliographiccitation.lastpage","614"],["dc.bibliographiccitation.volume","218"],["dc.contributor.author","Richter, Frank"],["dc.contributor.author","Dennerlein, Sven"],["dc.contributor.author","Nikolov, Miroslav"],["dc.contributor.author","Jans, Daniel C."],["dc.contributor.author","Naumenko, Nataliia"],["dc.contributor.author","Aich, Abhishek"],["dc.contributor.author","MacVicar, Thomas"],["dc.contributor.author","Linden, Andreas"],["dc.contributor.author","Jakobs, Stefan"],["dc.contributor.author","Urlaub, Henning"],["dc.contributor.author","Langer, Thomas"],["dc.contributor.author","Rehling, Peter"],["dc.date.accessioned","2019-07-09T11:50:27Z"],["dc.date.available","2019-07-09T11:50:27Z"],["dc.date.issued","2019"],["dc.description.abstract","The mitochondrial presequence translocation machinery (TIM23 complex) is conserved between the yeast Saccharomyces cerevisiae and humans; however, functional characterization has been mainly performed in yeast. Here, we define the constituents of the human TIM23 complex using mass spectrometry and identified ROMO1 as a new translocase constituent with an exceptionally short half-life. Analyses of a ROMO1 knockout cell line revealed aberrant inner membrane structure and altered processing of the GTPase OPA1. We show that in the absence of ROMO1, mitochondria lose the inner membrane YME1L protease, which participates in OPA1 processing and ROMO1 turnover. While ROMO1 is dispensable for general protein import along the presequence pathway, we show that it participates in the dynamics of TIM21 during respiratory chain biogenesis and is specifically required for import of YME1L. This selective import defect can be linked to charge distribution in the unusually long targeting sequence of YME1L. Our analyses establish an unexpected link between mitochondrial protein import and inner membrane protein quality control."],["dc.identifier.doi","10.1083/jcb.201806093"],["dc.identifier.pmid","30598479"],["dc.identifier.purl","https://resolver.sub.uni-goettingen.de/purl?gs-1/15943"],["dc.identifier.uri","https://resolver.sub.uni-goettingen.de/purl?gro-2/59776"],["dc.language.iso","en"],["dc.notes.intern","Merged from goescholar"],["dc.relation","info:eu-repo/grantAgreement/EC/FP7/339580/EU//MITRAC"],["dc.relation.issn","1540-8140"],["dc.rights","CC BY 4.0"],["dc.rights.uri","https://creativecommons.org/licenses/by/4.0"],["dc.subject.ddc","610"],["dc.title","ROMO1 is a constituent of the human presequence translocase required for YME1L protease import"],["dc.type","journal_article"],["dc.type.internalPublication","yes"],["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.firstpage","4222"],["dc.bibliographiccitation.issue","24"],["dc.bibliographiccitation.journal","Molecular and Cellular Biology"],["dc.bibliographiccitation.lastpage","4237"],["dc.bibliographiccitation.volume","35"],["dc.contributor.author","Sakowska, Paulina"],["dc.contributor.author","Jans, Daniel C."],["dc.contributor.author","Mohanraj, Karthik"],["dc.contributor.author","Riedel, Dietmar"],["dc.contributor.author","Jakobs, Stefan"],["dc.contributor.author","Chacinska, Agnieszka"],["dc.date.accessioned","2017-09-07T11:54:51Z"],["dc.date.available","2017-09-07T11:54:51Z"],["dc.date.issued","2015"],["dc.description.abstract","The function of mitochondria depends on the proper organization of mitochondrial membranes. The morphology of the inner membrane is regulated by the recently identified mitochondrial contact site and crista organizing system (MICOS) complex. MICOS mutants exhibit alterations in crista formation, leading to mitochondrial dysfunction. However, the mechanisms that underlie MICOS regulation remain poorly understood. MIC19, a peripheral protein of the inner membrane and component of the MICOS complex, was previously reported to be required for the proper function of MICOS in maintaining the architecture of the inner membrane. Here, we show that human and Saccharomyces cerevisiae MIC19 proteins undergo oxidation in mitochondria and require the mitochondrial intermembrane space assembly (MIA) pathway, which couples the oxidation and import of mitochondrial intermembrane space proteins for mitochondrial localization. Detailed analyses identified yeast Mic19 in two different redox forms. The form that contains an intramolecular disulfide bond is bound to Mic60 of the MICOS complex. Mic19 oxidation is not essential for its integration into the MICOS complex but plays a role in MICOS assembly and the maintenance of the proper inner membrane morphology. These findings suggest that Mic19 is a redox-dependent regulator of MICOS function."],["dc.identifier.doi","10.1128/MCB.00578-15"],["dc.identifier.gro","3141780"],["dc.identifier.isi","000365715500011"],["dc.identifier.pmid","26416881"],["dc.identifier.purl","https://resolver.sub.uni-goettingen.de/purl?gs-1/12742"],["dc.identifier.uri","https://resolver.sub.uni-goettingen.de/purl?gro-2/990"],["dc.language.iso","en"],["dc.notes.intern","WoS Import 2017-03-10"],["dc.notes.intern","Merged from goescholar"],["dc.notes.status","final"],["dc.notes.submitter","PUB_WoS_Import"],["dc.relation.eissn","1098-5549"],["dc.relation.issn","0270-7306"],["dc.rights","CC BY-NC-SA 3.0"],["dc.rights.uri","https://creativecommons.org/licenses/by-nc-sa/3.0"],["dc.title","The Oxidation Status of Mic19 Regulates MICOS Assembly"],["dc.type","journal_article"],["dc.type.internalPublication","yes"],["dc.type.peerReviewed","yes"],["dc.type.subtype","original"],["dc.type.version","published_version"],["dspace.entity.type","Publication"]]

[["dc.bibliographiccitation.firstpage","402"],["dc.bibliographiccitation.issue","4"],["dc.bibliographiccitation.journal","EMBO Journal"],["dc.bibliographiccitation.lastpage","413"],["dc.bibliographiccitation.volume","35"],["dc.contributor.author","Große, Lena"],["dc.contributor.author","Wurm, Christian Andreas"],["dc.contributor.author","Brüser, Christian"],["dc.contributor.author","Neumann, Daniel"],["dc.contributor.author","Jans, Daniel C."],["dc.contributor.author","Jakobs, Stefan"],["dc.date.accessioned","2017-09-07T11:54:38Z"],["dc.date.available","2017-09-07T11:54:38Z"],["dc.date.issued","2016"],["dc.description.abstract","The Bcl-2 family proteins Bax and Bak are essential for the execution of many apoptotic programs. During apoptosis, Bax translocates to the mitochondria and mediates the permeabilization of the outer membrane, thereby facilitating the release of pro-apoptotic proteins. Yet the mechanistic details of the Bax-induced membrane permeabilization have so far remained elusive. Here, we demonstrate that activated Bax molecules, besides forming large and compact clusters, also assemble, potentially with other proteins including Bak, into ring-like structures in the mitochondrial outer membrane. STED nanoscopy indicates that the area enclosed by a Bax ring is devoid of mitochondrial outer membrane proteins such as Tom20, Tom22, and Sam50. This strongly supports the view that the Bax rings surround an opening required for mitochondrial outer membrane permeabilization (MOMP). Even though these Bax assemblies may be necessary for MOMP, we demonstrate that at least in Drp1 knockdown cells, these assemblies are not sufficient for full cytochrome c release. Together, our super-resolution data provide direct evidence in support of large Bax-delineated pores in the mitochondrial outer membrane as being crucial for Bax-mediated MOMP in cells."],["dc.identifier.doi","10.15252/embj.201592789"],["dc.identifier.gro","3141728"],["dc.identifier.isi","000370346400005"],["dc.identifier.pmid","26783364"],["dc.identifier.purl","https://resolver.sub.uni-goettingen.de/purl?gs-1/14032"],["dc.identifier.uri","https://resolver.sub.uni-goettingen.de/purl?gro-2/413"],["dc.language.iso","en"],["dc.notes.intern","WoS Import 2017-03-10"],["dc.notes.intern","Merged from goescholar"],["dc.notes.status","final"],["dc.notes.submitter","PUB_WoS_Import"],["dc.relation.eissn","1460-2075"],["dc.relation.issn","0261-4189"],["dc.rights","CC BY 4.0"],["dc.rights.uri","https://creativecommons.org/licenses/by/4.0"],["dc.title","Bax assembles into large ring-like structures remodeling the mitochondrial outer membrane in apoptosis"],["dc.type","journal_article"],["dc.type.internalPublication","yes"],["dc.type.peerReviewed","yes"],["dc.type.subtype","original"],["dc.type.version","published_version"],["dspace.entity.type","Publication"]]

[["dc.bibliographiccitation.firstpage","756"],["dc.bibliographiccitation.issue","5"],["dc.bibliographiccitation.journal","Cell Metabolism"],["dc.bibliographiccitation.lastpage","763"],["dc.bibliographiccitation.volume","21"],["dc.contributor.author","Barbot, Mariam"],["dc.contributor.author","Jans, Daniel C."],["dc.contributor.author","Schulz, Christian"],["dc.contributor.author","Denkert, Niels"],["dc.contributor.author","Kroppen, Benjamin"],["dc.contributor.author","Hoppert, Michael"],["dc.contributor.author","Jakobs, Stefan"],["dc.contributor.author","Meinecke, Michael"],["dc.date.accessioned","2017-09-07T11:44:24Z"],["dc.date.available","2017-09-07T11:44:24Z"],["dc.date.issued","2015"],["dc.description.abstract","The mitochondrial inner membrane is highly folded and displays a complex molecular architecture. Cristae junctions are highly curved tubular openings that separate cristae membrane invaginations from the surrounding boundary membrane. Despite their central role in many vital cellular processes like apoptosis, the details of cristae junction formation remain elusive. Here we identify Mic10, a core subunit of the recently discovered MICOS complex, as an inner mitochondrial membrane protein with the ability to change membrane morphology in vitro and in vivo. We show that Mic10 spans the inner membrane in a hairpin topology and that its ability to sculpt membranes depends on oligomerization through a glycine-rich motif. Oligomerization mutants fail to induce curvature in model membranes, and when expressed in yeast, mitochondria display an altered inner membrane architecture characterized by drastically decreased numbers of cristae junctions. Thus, we demonstrate that membrane sculpting by Mic10 is essential for cristae junction formation."],["dc.identifier.doi","10.1016/j.cmet.2015.04.006"],["dc.identifier.gro","3141906"],["dc.identifier.isi","000353978700017"],["dc.identifier.pmid","25955211"],["dc.identifier.uri","https://resolver.sub.uni-goettingen.de/purl?gro-2/2389"],["dc.language.iso","en"],["dc.notes.intern","WoS Import 2017-03-10"],["dc.notes.status","final"],["dc.notes.submitter","PUB_WoS_Import"],["dc.relation.eissn","1932-7420"],["dc.relation.issn","1550-4131"],["dc.relation.orgunit","Institut für Zellbiochemie"],["dc.title","Mic10 Oligomerizes to Bend Mitochondrial Inner Membranes at Cristae Junctions"],["dc.type","journal_article"],["dc.type.internalPublication","yes"],["dc.type.peerReviewed","yes"],["dc.type.subtype","original_ja"],["dspace.entity.type","Publication"]]

[["dc.bibliographiccitation.firstpage","4147"],["dc.bibliographiccitation.issue","23"],["dc.bibliographiccitation.journal","FEBS Letters"],["dc.bibliographiccitation.lastpage","4158"],["dc.bibliographiccitation.volume","590"],["dc.contributor.author","Callegari, Sylvie"],["dc.contributor.author","Richter, Frank"],["dc.contributor.author","Chojnacka, Katarzyna"],["dc.contributor.author","Jans, Daniel C."],["dc.contributor.author","Lorenzi, Isotta"],["dc.contributor.author","Pacheu-Grau, David"],["dc.contributor.author","Jakobs, Stefan"],["dc.contributor.author","Lenz, Christof"],["dc.contributor.author","Urlaub, Henning"],["dc.contributor.author","Dudek, Jan"],["dc.contributor.author","Chacinska, Agnieszka"],["dc.contributor.author","Rehling, Peter"],["dc.date.accessioned","2017-09-07T11:53:09Z"],["dc.date.available","2017-09-07T11:53:09Z"],["dc.date.issued","2016"],["dc.description.abstract","Hydrophobic inner mitochondrial membrane proteins with internal targeting signals, such as the metabolite carriers, use the carrier translocase (TIM22 complex) for transport into the inner membrane. Defects in this transport pathway have been associated with neurodegenerative disorders. While the TIM22 complex is well studied in baker's yeast, very little is known about the mammalian TIM22 complex. Using immunoprecipitation, we purified the human carrier translocase and identified a mitochondrial inner membrane protein TIM29 as a novel component, specific to metazoa. We show that TIM29 is a constituent of the 440 kDa TIM22 complex and interacts with oxidized TIM22. Our analyses demonstrate that TIM29 is required for the structural integrity of the TIM22 complex and for import of substrate proteins by the carrier translocase."],["dc.identifier.doi","10.1002/1873-3468.12450"],["dc.identifier.fs","625768"],["dc.identifier.gro","3145043"],["dc.identifier.pmid","27718247"],["dc.identifier.purl","https://resolver.sub.uni-goettingen.de/purl?gs-1/14166"],["dc.identifier.uri","https://resolver.sub.uni-goettingen.de/purl?gro-2/2736"],["dc.identifier.url","https://sfb1190.med.uni-goettingen.de/production/literature/publications/59"],["dc.language.iso","en"],["dc.notes.intern","Crossref Import"],["dc.notes.intern","Merged from goescholar"],["dc.notes.status","final"],["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","SFB 1190 | Z02: Massenspektrometrie-basierte Proteomanalyse"],["dc.relation.issn","0014-5793"],["dc.relation.workinggroup","RG Jakobs (Structure and Dynamics of Mitochondria)"],["dc.relation.workinggroup","RG Rehling (Mitochondrial Protein Biogenesis)"],["dc.relation.workinggroup","RG Urlaub (Bioanalytische Massenspektrometrie)"],["dc.rights","Goescholar"],["dc.rights.uri","https://goescholar.uni-goettingen.de/licenses"],["dc.title","TIM29 is a subunit of the human carrier translocase required for protein transport"],["dc.type","journal_article"],["dc.type.internalPublication","unknown"],["dc.type.peerReviewed","no"],["dc.type.subtype","original_ja"],["dc.type.version","published_version"],["dspace.entity.type","Publication"]]