[{"citation":{"mla":"Stahnke, Stephanie, et al. “Loss of Hem1 Disrupts Macrophage Function and Impacts Migration, Phagocytosis, and Integrin-Mediated Adhesion.” <i>Current Biology</i>, vol. 31, no. 10, Elsevier, 2021, p. 2051–2064.e8, doi:<a href=\"https://doi.org/10.1016/j.cub.2021.02.043\">10.1016/j.cub.2021.02.043</a>.","ieee":"S. Stahnke <i>et al.</i>, “Loss of Hem1 disrupts macrophage function and impacts migration, phagocytosis, and integrin-mediated adhesion,” <i>Current Biology</i>, vol. 31, no. 10. Elsevier, p. 2051–2064.e8, 2021.","ista":"Stahnke S, Döring H, Kusch C, de Gorter DJJ, Dütting S, Guledani A, Pleines I, Schnoor M, Sixt MK, Geffers R, Rohde M, Müsken M, Kage F, Steffen A, Faix J, Nieswandt B, Rottner K, Stradal TEB. 2021. Loss of Hem1 disrupts macrophage function and impacts migration, phagocytosis, and integrin-mediated adhesion. Current Biology. 31(10), 2051–2064.e8.","chicago":"Stahnke, Stephanie, Hermann Döring, Charly Kusch, David J.J. de Gorter, Sebastian Dütting, Aleks Guledani, Irina Pleines, et al. “Loss of Hem1 Disrupts Macrophage Function and Impacts Migration, Phagocytosis, and Integrin-Mediated Adhesion.” <i>Current Biology</i>. Elsevier, 2021. <a href=\"https://doi.org/10.1016/j.cub.2021.02.043\">https://doi.org/10.1016/j.cub.2021.02.043</a>.","apa":"Stahnke, S., Döring, H., Kusch, C., de Gorter, D. J. J., Dütting, S., Guledani, A., … Stradal, T. E. B. (2021). Loss of Hem1 disrupts macrophage function and impacts migration, phagocytosis, and integrin-mediated adhesion. <i>Current Biology</i>. Elsevier. <a href=\"https://doi.org/10.1016/j.cub.2021.02.043\">https://doi.org/10.1016/j.cub.2021.02.043</a>","ama":"Stahnke S, Döring H, Kusch C, et al. Loss of Hem1 disrupts macrophage function and impacts migration, phagocytosis, and integrin-mediated adhesion. <i>Current Biology</i>. 2021;31(10):2051-2064.e8. doi:<a href=\"https://doi.org/10.1016/j.cub.2021.02.043\">10.1016/j.cub.2021.02.043</a>","short":"S. Stahnke, H. Döring, C. Kusch, D.J.J. de Gorter, S. Dütting, A. Guledani, I. Pleines, M. Schnoor, M.K. Sixt, R. Geffers, M. Rohde, M. Müsken, F. Kage, A. Steffen, J. Faix, B. Nieswandt, K. Rottner, T.E.B. Stradal, Current Biology 31 (2021) 2051–2064.e8."},"title":"Loss of Hem1 disrupts macrophage function and impacts migration, phagocytosis, and integrin-mediated adhesion","day":"24","author":[{"last_name":"Stahnke","first_name":"Stephanie","full_name":"Stahnke, Stephanie"},{"last_name":"Döring","first_name":"Hermann","full_name":"Döring, Hermann"},{"last_name":"Kusch","full_name":"Kusch, Charly","first_name":"Charly"},{"first_name":"David J.J.","full_name":"de Gorter, David J.J.","last_name":"de Gorter"},{"full_name":"Dütting, Sebastian","first_name":"Sebastian","last_name":"Dütting"},{"first_name":"Aleks","full_name":"Guledani, Aleks","last_name":"Guledani"},{"first_name":"Irina","full_name":"Pleines, Irina","last_name":"Pleines"},{"first_name":"Michael","full_name":"Schnoor, Michael","last_name":"Schnoor"},{"full_name":"Sixt, Michael K","first_name":"Michael K","last_name":"Sixt","orcid":"0000-0002-6620-9179","id":"41E9FBEA-F248-11E8-B48F-1D18A9856A87"},{"last_name":"Geffers","first_name":"Robert","full_name":"Geffers, Robert"},{"last_name":"Rohde","full_name":"Rohde, Manfred","first_name":"Manfred"},{"last_name":"Müsken","first_name":"Mathias","full_name":"Müsken, Mathias"},{"first_name":"Frieda","full_name":"Kage, Frieda","last_name":"Kage"},{"last_name":"Steffen","full_name":"Steffen, Anika","first_name":"Anika"},{"full_name":"Faix, Jan","first_name":"Jan","last_name":"Faix"},{"first_name":"Bernhard","full_name":"Nieswandt, Bernhard","last_name":"Nieswandt"},{"last_name":"Rottner","first_name":"Klemens","full_name":"Rottner, Klemens"},{"last_name":"Stradal","first_name":"Theresia E.B.","full_name":"Stradal, Theresia E.B."}],"type":"journal_article","acknowledgement":"We are grateful to Silvia Prettin, Ina Schleicher, and Petra Hagendorff for expert technical assistance; David Dettbarn for animal keeping and breeding; and Lothar Gröbe and Maria Höxter for cell sorting. We also thank Werner Tegge for peptides and Giorgio Scita for antibodies. This work was supported, in part, by the Deutsche Forschungsgemeinschaft (DFG), Priority Programm SPP1150 (to T.E.B.S., K.R., and M. Sixt), and by DFG grant GRK2223/1 (to K.R.). T.E.B.S. acknowledges support by the Helmholtz Society through HGF impulse fund W2/W3-066 and M. Schnoor by the Mexican Council for Science and Technology (CONACyT, 284292 ), Fund SEP-Cinvestav ( 108 ), and the Royal Society, UK (Newton Advanced Fellowship, NAF/R1/180017 ).","pmid":1,"language":[{"iso":"eng"}],"keyword":["General Agricultural and Biological Sciences","General Biochemistry","Genetics and Molecular Biology"],"doi":"10.1016/j.cub.2021.02.043","page":"2051-2064.e8","month":"05","date_created":"2022-03-08T07:51:04Z","publisher":"Elsevier","isi":1,"department":[{"_id":"MiSi"}],"quality_controlled":"1","publication":"Current Biology","status":"public","intvolume":"        31","article_type":"original","oa_version":"Preprint","year":"2021","date_updated":"2023-08-17T07:01:14Z","user_id":"4359f0d1-fa6c-11eb-b949-802e58b17ae8","external_id":{"pmid":["33711252"],"isi":["000654652200002"]},"scopus_import":"1","publication_identifier":{"issn":["0960-9822"]},"issue":"10","article_processing_charge":"No","date_published":"2021-05-24T00:00:00Z","_id":"10834","abstract":[{"text":"Hematopoietic-specific protein 1 (Hem1) is an essential subunit of the WAVE regulatory complex (WRC) in immune cells. WRC is crucial for Arp2/3 complex activation and the protrusion of branched actin filament networks. Moreover, Hem1 loss of function in immune cells causes autoimmune diseases in humans. Here, we show that genetic removal of Hem1 in macrophages diminishes frequency and efficacy of phagocytosis as well as phagocytic cup formation in addition to defects in lamellipodial protrusion and migration. Moreover, Hem1-null macrophages displayed strong defects in cell adhesion despite unaltered podosome formation and concomitant extracellular matrix degradation. Specifically, dynamics of both adhesion and de-adhesion as well as concomitant phosphorylation of paxillin and focal adhesion kinase (FAK) were significantly compromised. Accordingly, disruption of WRC function in non-hematopoietic cells coincided with both defects in adhesion turnover and altered FAK and paxillin phosphorylation. Consistently, platelets exhibited reduced adhesion and diminished integrin αIIbβ3 activation upon WRC removal. Interestingly, adhesion phenotypes, but not lamellipodia formation, were partially rescued by small molecule activation of FAK. A full rescue of the phenotype, including lamellipodia formation, required not only the presence of WRCs but also their binding to and activation by Rac. Collectively, our results uncover that WRC impacts on integrin-dependent processes in a FAK-dependent manner, controlling formation and dismantling of adhesions, relevant for properly grabbing onto extracellular surfaces and particles during cell edge expansion, like in migration or phagocytosis.","lang":"eng"}],"publication_status":"published","main_file_link":[{"open_access":"1","url":"https://doi.org/10.1101/2020.03.24.005835"}],"oa":1,"volume":31},{"date_published":"2021-11-08T00:00:00Z","_id":"11052","abstract":[{"lang":"eng","text":"In order to combat molecular damage, most cellular proteins undergo rapid turnover. We have previously identified large nuclear protein assemblies that can persist for years in post-mitotic tissues and are subject to age-related decline. Here, we report that mitochondria can be long lived in the mouse brain and reveal that specific mitochondrial proteins have half-lives longer than the average proteome. These mitochondrial long-lived proteins (mitoLLPs) are core components of the electron transport chain (ETC) and display increased longevity in respiratory supercomplexes. We find that COX7C, a mitoLLP that forms a stable contact site between complexes I and IV, is required for complex IV and supercomplex assembly. Remarkably, even upon depletion of COX7C transcripts, ETC function is maintained for days, effectively uncoupling mitochondrial function from ongoing transcription of its mitoLLPs. Our results suggest that modulating protein longevity within the ETC is critical for mitochondrial proteome maintenance and the robustness of mitochondrial function."}],"article_processing_charge":"No","issue":"21","volume":56,"publication_status":"published","article_type":"original","oa_version":"None","year":"2021","external_id":{"pmid":["34715012"]},"scopus_import":"1","date_updated":"2022-07-18T08:26:38Z","user_id":"72615eeb-f1f3-11ec-aa25-d4573ddc34fd","publication_identifier":{"issn":["1534-5807"]},"month":"11","extern":"1","date_created":"2022-04-07T07:43:14Z","page":"P2952-2965.e9","publication":"Developmental Cell","quality_controlled":"1","intvolume":"        56","status":"public","publisher":"Elsevier","day":"08","type":"journal_article","author":[{"last_name":"Krishna","first_name":"Shefali","full_name":"Krishna, Shefali"},{"full_name":"Arrojo e Drigo, Rafael","first_name":"Rafael","last_name":"Arrojo e Drigo"},{"last_name":"Capitanio","full_name":"Capitanio, Juliana S.","first_name":"Juliana S."},{"last_name":"Ramachandra","full_name":"Ramachandra, Ranjan","first_name":"Ranjan"},{"last_name":"Ellisman","first_name":"Mark","full_name":"Ellisman, Mark"},{"id":"86c0d31b-b4eb-11ec-ac5a-eae7b2e135ed","orcid":"0000-0002-2111-992X","first_name":"Martin W","full_name":"HETZER, Martin W","last_name":"HETZER"}],"citation":{"chicago":"Krishna, Shefali, Rafael Arrojo e Drigo, Juliana S. Capitanio, Ranjan Ramachandra, Mark Ellisman, and Martin Hetzer. “Identification of Long-Lived Proteins in the Mitochondria Reveals Increased Stability of the Electron Transport Chain.” <i>Developmental Cell</i>. Elsevier, 2021. <a href=\"https://doi.org/10.1016/j.devcel.2021.10.008\">https://doi.org/10.1016/j.devcel.2021.10.008</a>.","ieee":"S. Krishna, R. Arrojo e Drigo, J. S. Capitanio, R. Ramachandra, M. Ellisman, and M. Hetzer, “Identification of long-lived proteins in the mitochondria reveals increased stability of the electron transport chain,” <i>Developmental Cell</i>, vol. 56, no. 21. Elsevier, p. P2952–2965.e9, 2021.","ista":"Krishna S, Arrojo e Drigo R, Capitanio JS, Ramachandra R, Ellisman M, Hetzer M. 2021. Identification of long-lived proteins in the mitochondria reveals increased stability of the electron transport chain. Developmental Cell. 56(21), P2952–2965.e9.","mla":"Krishna, Shefali, et al. “Identification of Long-Lived Proteins in the Mitochondria Reveals Increased Stability of the Electron Transport Chain.” <i>Developmental Cell</i>, vol. 56, no. 21, Elsevier, 2021, p. P2952–2965.e9, doi:<a href=\"https://doi.org/10.1016/j.devcel.2021.10.008\">10.1016/j.devcel.2021.10.008</a>.","short":"S. Krishna, R. Arrojo e Drigo, J.S. Capitanio, R. Ramachandra, M. Ellisman, M. Hetzer, Developmental Cell 56 (2021) P2952–2965.e9.","ama":"Krishna S, Arrojo e Drigo R, Capitanio JS, Ramachandra R, Ellisman M, Hetzer M. Identification of long-lived proteins in the mitochondria reveals increased stability of the electron transport chain. <i>Developmental Cell</i>. 2021;56(21):P2952-2965.e9. doi:<a href=\"https://doi.org/10.1016/j.devcel.2021.10.008\">10.1016/j.devcel.2021.10.008</a>","apa":"Krishna, S., Arrojo e Drigo, R., Capitanio, J. S., Ramachandra, R., Ellisman, M., &#38; Hetzer, M. (2021). Identification of long-lived proteins in the mitochondria reveals increased stability of the electron transport chain. <i>Developmental Cell</i>. Elsevier. <a href=\"https://doi.org/10.1016/j.devcel.2021.10.008\">https://doi.org/10.1016/j.devcel.2021.10.008</a>"},"title":"Identification of long-lived proteins in the mitochondria reveals increased stability of the electron transport chain","keyword":["Developmental Biology","Cell Biology","General Biochemistry","Genetics and Molecular Biology","Molecular Biology"],"language":[{"iso":"eng"}],"doi":"10.1016/j.devcel.2021.10.008","pmid":1},{"month":"12","extern":"1","date_created":"2023-08-01T09:33:39Z","page":"191-201","publication":"Annals of the New York Academy of Sciences","quality_controlled":"1","intvolume":"      1505","status":"public","publisher":"Wiley","day":"01","author":[{"last_name":"Bian","first_name":"Tong","full_name":"Bian, Tong"},{"id":"8e84690e-1e48-11ed-a02b-a1e6fb8bb53b","last_name":"Klajn","first_name":"Rafal","full_name":"Klajn, Rafal"}],"type":"journal_article","citation":{"ama":"Bian T, Klajn R. Morphology control in crystalline nanoparticle–polymer aggregates. <i>Annals of the New York Academy of Sciences</i>. 2021;1505(1):191-201. doi:<a href=\"https://doi.org/10.1111/nyas.14674\">10.1111/nyas.14674</a>","apa":"Bian, T., &#38; Klajn, R. (2021). Morphology control in crystalline nanoparticle–polymer aggregates. <i>Annals of the New York Academy of Sciences</i>. Wiley. <a href=\"https://doi.org/10.1111/nyas.14674\">https://doi.org/10.1111/nyas.14674</a>","short":"T. Bian, R. Klajn, Annals of the New York Academy of Sciences 1505 (2021) 191–201.","mla":"Bian, Tong, and Rafal Klajn. “Morphology Control in Crystalline Nanoparticle–Polymer Aggregates.” <i>Annals of the New York Academy of Sciences</i>, vol. 1505, no. 1, Wiley, 2021, pp. 191–201, doi:<a href=\"https://doi.org/10.1111/nyas.14674\">10.1111/nyas.14674</a>.","chicago":"Bian, Tong, and Rafal Klajn. “Morphology Control in Crystalline Nanoparticle–Polymer Aggregates.” <i>Annals of the New York Academy of Sciences</i>. Wiley, 2021. <a href=\"https://doi.org/10.1111/nyas.14674\">https://doi.org/10.1111/nyas.14674</a>.","ieee":"T. Bian and R. Klajn, “Morphology control in crystalline nanoparticle–polymer aggregates,” <i>Annals of the New York Academy of Sciences</i>, vol. 1505, no. 1. Wiley, pp. 191–201, 2021.","ista":"Bian T, Klajn R. 2021. Morphology control in crystalline nanoparticle–polymer aggregates. Annals of the New York Academy of Sciences. 1505(1), 191–201."},"title":"Morphology control in crystalline nanoparticle–polymer aggregates","keyword":["History and Philosophy of Science","General Biochemistry","Genetics and Molecular Biology","General Neuroscience"],"language":[{"iso":"eng"}],"ddc":["540"],"doi":"10.1111/nyas.14674","pmid":1,"abstract":[{"lang":"eng","text":"Self-assembly of nanoparticles can be mediated by polymers, but has so far led almost exclusively to nanoparticle aggregates that are amorphous. Here, we employed Coulombic interactions to generate a range of composite materials from mixtures of charged nanoparticles and oppositely charged polymers. The assembly behavior of these nanoparticle/polymer composites depends on their order of addition: polymers added to nanoparticles give rise to stable aggregates, but nanoparticles added to polymers disassemble the initially formed aggregates. The amorphous aggregates were transformed into crystalline ones by transiently increasing the ionic strength of the solution. The morphology of the resulting crystals depended on the length of the polymer: short polymer chains mediated the self-assembly of nanoparticles into strongly faceted crystals, whereas long chains led to pseudospherical nanoparticle/polymer assemblies, within which the crystalline order of nanoparticles was retained."}],"_id":"13356","date_published":"2021-12-01T00:00:00Z","article_processing_charge":"No","issue":"1","volume":1505,"publication_status":"published","oa":1,"main_file_link":[{"open_access":"1","url":"https://doi.org/10.1111/nyas.14674"}],"article_type":"original","oa_version":"Published Version","year":"2021","external_id":{"pmid":["34427923"]},"scopus_import":"1","date_updated":"2023-08-07T10:01:10Z","user_id":"2DF688A6-F248-11E8-B48F-1D18A9856A87","publication_identifier":{"issn":["0077-8923"],"eissn":["1749-6632"]}},{"oa":1,"main_file_link":[{"open_access":"1","url":"https://doi.org/10.1016/j.chempr.2020.11.025"}],"publication_status":"published","volume":7,"article_processing_charge":"No","issue":"1","date_published":"2021-01-14T00:00:00Z","_id":"13359","abstract":[{"text":"Dissipative self-assembly is ubiquitous in nature, where it gives rise to complex structures and functions such as self-healing, homeostasis, and camouflage. These phenomena are enabled by the continuous conversion of energy stored in chemical fuels, such as ATP. Over the past decade, an increasing number of synthetic chemically driven systems have been reported that mimic the features of their natural counterparts. At the same time, it has been shown that dissipative self-assembly can also be fueled by light; these optically fueled systems have been developed in parallel to the chemically fueled ones. In this perspective, we critically compare these two classes of systems. Despite the complementarity and fundamental differences between these two modes of dissipative self-assembly, our analysis reveals that multiple analogies exist between chemically and light-fueled systems. We hope that these considerations will facilitate further development of the field of dissipative self-assembly.","lang":"eng"}],"publication_identifier":{"issn":["2451-9294"]},"scopus_import":"1","date_updated":"2023-08-07T10:04:28Z","user_id":"2DF688A6-F248-11E8-B48F-1D18A9856A87","oa_version":"Published Version","year":"2021","article_type":"original","publisher":"Elsevier","intvolume":"         7","status":"public","publication":"Chem","quality_controlled":"1","page":"23-37","date_created":"2023-08-01T09:35:19Z","month":"01","extern":"1","doi":"10.1016/j.chempr.2020.11.025","keyword":["Materials Chemistry","Biochemistry (medical)","General Chemical Engineering","Environmental Chemistry","Biochemistry","General Chemistry"],"language":[{"iso":"eng"}],"title":"Dissipative self-assembly: Fueling with chemicals versus light","citation":{"chicago":"Weißenfels, Maren, Julius Gemen, and Rafal Klajn. “Dissipative Self-Assembly: Fueling with Chemicals versus Light.” <i>Chem</i>. Elsevier, 2021. <a href=\"https://doi.org/10.1016/j.chempr.2020.11.025\">https://doi.org/10.1016/j.chempr.2020.11.025</a>.","ista":"Weißenfels M, Gemen J, Klajn R. 2021. Dissipative self-assembly: Fueling with chemicals versus light. Chem. 7(1), 23–37.","ieee":"M. Weißenfels, J. Gemen, and R. Klajn, “Dissipative self-assembly: Fueling with chemicals versus light,” <i>Chem</i>, vol. 7, no. 1. Elsevier, pp. 23–37, 2021.","mla":"Weißenfels, Maren, et al. “Dissipative Self-Assembly: Fueling with Chemicals versus Light.” <i>Chem</i>, vol. 7, no. 1, Elsevier, 2021, pp. 23–37, doi:<a href=\"https://doi.org/10.1016/j.chempr.2020.11.025\">10.1016/j.chempr.2020.11.025</a>.","short":"M. Weißenfels, J. Gemen, R. Klajn, Chem 7 (2021) 23–37.","ama":"Weißenfels M, Gemen J, Klajn R. Dissipative self-assembly: Fueling with chemicals versus light. <i>Chem</i>. 2021;7(1):23-37. doi:<a href=\"https://doi.org/10.1016/j.chempr.2020.11.025\">10.1016/j.chempr.2020.11.025</a>","apa":"Weißenfels, M., Gemen, J., &#38; Klajn, R. (2021). Dissipative self-assembly: Fueling with chemicals versus light. <i>Chem</i>. Elsevier. <a href=\"https://doi.org/10.1016/j.chempr.2020.11.025\">https://doi.org/10.1016/j.chempr.2020.11.025</a>"},"type":"journal_article","author":[{"last_name":"Weißenfels","first_name":"Maren","full_name":"Weißenfels, Maren"},{"full_name":"Gemen, Julius","first_name":"Julius","last_name":"Gemen"},{"full_name":"Klajn, Rafal","first_name":"Rafal","last_name":"Klajn","id":"8e84690e-1e48-11ed-a02b-a1e6fb8bb53b"}],"day":"14"},{"title":"Two linked loci under mutation-selection balance and Muller’s ratchet","citation":{"chicago":"Khudiakova, Kseniia, Tatiana Yu. Neretina, and Alexey S. Kondrashov. “Two Linked Loci under Mutation-Selection Balance and Muller’s Ratchet.” <i>Journal of Theoretical Biology</i>. Elsevier , 2021. <a href=\"https://doi.org/10.1016/j.jtbi.2021.110729\">https://doi.org/10.1016/j.jtbi.2021.110729</a>.","ista":"Khudiakova K, Neretina TY, Kondrashov AS. 2021. Two linked loci under mutation-selection balance and Muller’s ratchet. Journal of Theoretical Biology. 524, 110729.","ieee":"K. Khudiakova, T. Y. Neretina, and A. S. Kondrashov, “Two linked loci under mutation-selection balance and Muller’s ratchet,” <i>Journal of Theoretical Biology</i>, vol. 524. Elsevier , 2021.","mla":"Khudiakova, Kseniia, et al. “Two Linked Loci under Mutation-Selection Balance and Muller’s Ratchet.” <i>Journal of Theoretical Biology</i>, vol. 524, 110729, Elsevier , 2021, doi:<a href=\"https://doi.org/10.1016/j.jtbi.2021.110729\">10.1016/j.jtbi.2021.110729</a>.","short":"K. Khudiakova, T.Y. Neretina, A.S. Kondrashov, Journal of Theoretical Biology 524 (2021).","ama":"Khudiakova K, Neretina TY, Kondrashov AS. Two linked loci under mutation-selection balance and Muller’s ratchet. <i>Journal of Theoretical Biology</i>. 2021;524. doi:<a href=\"https://doi.org/10.1016/j.jtbi.2021.110729\">10.1016/j.jtbi.2021.110729</a>","apa":"Khudiakova, K., Neretina, T. Y., &#38; Kondrashov, A. S. (2021). Two linked loci under mutation-selection balance and Muller’s ratchet. <i>Journal of Theoretical Biology</i>. Elsevier . <a href=\"https://doi.org/10.1016/j.jtbi.2021.110729\">https://doi.org/10.1016/j.jtbi.2021.110729</a>"},"type":"journal_article","author":[{"full_name":"Khudiakova, Kseniia","first_name":"Kseniia","last_name":"Khudiakova","id":"4E6DC800-AE37-11E9-AC72-31CAE5697425","orcid":"0000-0002-6246-1465"},{"last_name":"Neretina","full_name":"Neretina, Tatiana Yu.","first_name":"Tatiana Yu."},{"last_name":"Kondrashov","first_name":"Alexey S.","full_name":"Kondrashov, Alexey S."}],"day":"24","acknowledgement":"This work was supported by the Russian Science Foundation grant N 16-14-10173.","doi":"10.1016/j.jtbi.2021.110729","keyword":["General Biochemistry","Genetics and Molecular Biology","Modelling and Simulation","Statistics and Probability","General Immunology and Microbiology","Applied Mathematics","General Agricultural and Biological Sciences","General Medicine"],"language":[{"iso":"eng"}],"date_created":"2021-05-12T05:58:42Z","month":"04","isi":1,"publisher":"Elsevier ","intvolume":"       524","status":"public","publication":"Journal of Theoretical Biology","department":[{"_id":"GradSch"}],"quality_controlled":"1","oa_version":"Preprint","year":"2021","article_type":"original","publication_identifier":{"issn":["0022-5193"]},"external_id":{"isi":["000659161500002"]},"user_id":"4359f0d1-fa6c-11eb-b949-802e58b17ae8","date_updated":"2023-08-08T13:32:40Z","article_processing_charge":"No","_id":"9387","date_published":"2021-04-24T00:00:00Z","abstract":[{"text":"We report the complete analysis of a deterministic model of deleterious mutations and negative selection against them at two haploid loci without recombination. As long as mutation is a weaker force than selection, mutant alleles remain rare at the only stable equilibrium, and otherwise, a variety of dynamics are possible. If the mutation-free genotype is absent, generally the only stable equilibrium is the one that corresponds to fixation of the mutant allele at the locus where it is less deleterious. This result suggests that fixation of a deleterious allele that follows a click of the Muller’s ratchet is governed by natural selection, instead of random drift.","lang":"eng"}],"article_number":"110729","oa":1,"main_file_link":[{"url":"https://www.biorxiv.org/content/10.1101/477489v1","open_access":"1"}],"publication_status":"published","volume":524},{"acknowledged_ssus":[{"_id":"PreCl"}],"publication_identifier":{"eissn":["2041-1723"]},"external_id":{"isi":["000658769900010"]},"date_updated":"2024-09-10T12:04:26Z","user_id":"4359f0d1-fa6c-11eb-b949-802e58b17ae8","year":"2021","oa_version":"Published Version","has_accepted_license":"1","article_type":"original","oa":1,"publication_status":"published","tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)","image":"/images/cc_by.png","short":"CC BY (4.0)"},"volume":12,"file_date_updated":"2021-05-28T12:39:43Z","article_processing_charge":"No","issue":"1","_id":"9429","abstract":[{"lang":"eng","text":"De novo loss of function mutations in the ubiquitin ligase-encoding gene Cullin3 lead to autism spectrum disorder (ASD). In mouse, constitutive haploinsufficiency leads to motor coordination deficits as well as ASD-relevant social and cognitive impairments. However, induction of Cul3 haploinsufficiency later in life does not lead to ASD-relevant behaviors, pointing to an important role of Cul3 during a critical developmental window. Here we show that Cul3 is essential to regulate neuronal migration and, therefore, constitutive Cul3 heterozygous mutant mice display cortical lamination abnormalities. At the molecular level, we found that Cul3 controls neuronal migration by tightly regulating the amount of Plastin3 (Pls3), a previously unrecognized player of neural migration. Furthermore, we found that Pls3 cell-autonomously regulates cell migration by regulating actin cytoskeleton organization, and its levels are inversely proportional to neural migration speed. Finally, we provide evidence that cellular phenotypes associated with autism-linked gene haploinsufficiency can be rescued by transcriptional activation of the intact allele in vitro, offering a proof of concept for a potential therapeutic approach for ASDs."}],"date_published":"2021-05-24T00:00:00Z","file":[{"file_id":"9430","relation":"main_file","content_type":"application/pdf","date_created":"2021-05-28T12:39:43Z","success":1,"creator":"kschuh","file_size":9358599,"file_name":"2021_NatureCommunications_Morandell.pdf","checksum":"337e0f7959c35ec959984cacdcb472ba","access_level":"open_access","date_updated":"2021-05-28T12:39:43Z"}],"article_number":"3058","related_material":{"record":[{"status":"public","id":"7800","relation":"earlier_version"},{"status":"public","id":"12401","relation":"dissertation_contains"}],"link":[{"url":"https://ist.ac.at/en/news/defective-gene-slows-down-brain-cells/","relation":"press_release"}]},"project":[{"name":"ISTplus - Postdoctoral Fellowships","grant_number":"754411","_id":"260C2330-B435-11E9-9278-68D0E5697425","call_identifier":"H2020"},{"name":"Probing the Reversibility of Autism Spectrum Disorders by Employing in vivo and in vitro Models","grant_number":"715508","call_identifier":"H2020","_id":"25444568-B435-11E9-9278-68D0E5697425"},{"call_identifier":"FWF","_id":"2548AE96-B435-11E9-9278-68D0E5697425","grant_number":"W1232-B24","name":"Molecular Drug Targets"},{"name":"Neural stem cells in autism and epilepsy","grant_number":"F07807","_id":"05A0D778-7A3F-11EA-A408-12923DDC885E"},{"grant_number":"I03600","name":"Optical control of synaptic function via adhesion molecules","_id":"265CB4D0-B435-11E9-9278-68D0E5697425","call_identifier":"FWF"}],"acknowledgement":"We thank A. Coll Manzano, F. Freeman, M. Ladron de Guevara, and A. Ç. Yahya for technical assistance, S. Deixler, A. Lepold, and A. Schlerka for the management of our animal colony, as well as M. Schunn and the Preclinical Facility team for technical assistance. We thank K. Heesom and her team at the University of Bristol Proteomics Facility for the proteomics sample preparation, data generation, and analysis support. We thank Y. B. Simon for kindly providing the plasmid for lentiviral labeling. Further, we thank M. Sixt for his advice regarding cell migration and the fruitful discussions. This work was supported by the ISTPlus postdoctoral fellowship (Grant Agreement No. 754411) to B.B., by the European Union’s Horizon 2020 research and innovation program (ERC) grant 715508 (REVERSEAUTISM), and by the Austrian Science Fund (FWF) to G.N. (DK W1232-B24 and SFB F7807-B) and to J.G.D (I3600-B27).","doi":"10.1038/s41467-021-23123-x","ddc":["572"],"keyword":["General Biochemistry","Genetics and Molecular Biology"],"language":[{"iso":"eng"}],"title":"Cul3 regulates cytoskeleton protein homeostasis and cell migration during a critical window of brain development","citation":{"short":"J. Morandell, L.A. Schwarz, B. Basilico, S. Tasciyan, G.A. Dimchev, A. Nicolas, C.M. Sommer, C. Kreuzinger, C. Dotter, L. Knaus, Z. Dobler, E. Cacci, F.K. Schur, J.G. Danzl, G. Novarino, Nature Communications 12 (2021).","apa":"Morandell, J., Schwarz, L. A., Basilico, B., Tasciyan, S., Dimchev, G. A., Nicolas, A., … Novarino, G. (2021). Cul3 regulates cytoskeleton protein homeostasis and cell migration during a critical window of brain development. <i>Nature Communications</i>. Springer Nature. <a href=\"https://doi.org/10.1038/s41467-021-23123-x\">https://doi.org/10.1038/s41467-021-23123-x</a>","ama":"Morandell J, Schwarz LA, Basilico B, et al. Cul3 regulates cytoskeleton protein homeostasis and cell migration during a critical window of brain development. <i>Nature Communications</i>. 2021;12(1). doi:<a href=\"https://doi.org/10.1038/s41467-021-23123-x\">10.1038/s41467-021-23123-x</a>","ieee":"J. Morandell <i>et al.</i>, “Cul3 regulates cytoskeleton protein homeostasis and cell migration during a critical window of brain development,” <i>Nature Communications</i>, vol. 12, no. 1. Springer Nature, 2021.","ista":"Morandell J, Schwarz LA, Basilico B, Tasciyan S, Dimchev GA, Nicolas A, Sommer CM, Kreuzinger C, Dotter C, Knaus L, Dobler Z, Cacci E, Schur FK, Danzl JG, Novarino G. 2021. Cul3 regulates cytoskeleton protein homeostasis and cell migration during a critical window of brain development. Nature Communications. 12(1), 3058.","chicago":"Morandell, Jasmin, Lena A Schwarz, Bernadette Basilico, Saren Tasciyan, Georgi A Dimchev, Armel Nicolas, Christoph M Sommer, et al. “Cul3 Regulates Cytoskeleton Protein Homeostasis and Cell Migration during a Critical Window of Brain Development.” <i>Nature Communications</i>. Springer Nature, 2021. <a href=\"https://doi.org/10.1038/s41467-021-23123-x\">https://doi.org/10.1038/s41467-021-23123-x</a>.","mla":"Morandell, Jasmin, et al. “Cul3 Regulates Cytoskeleton Protein Homeostasis and Cell Migration during a Critical Window of Brain Development.” <i>Nature Communications</i>, vol. 12, no. 1, 3058, Springer Nature, 2021, doi:<a href=\"https://doi.org/10.1038/s41467-021-23123-x\">10.1038/s41467-021-23123-x</a>."},"ec_funded":1,"type":"journal_article","author":[{"last_name":"Morandell","first_name":"Jasmin","full_name":"Morandell, Jasmin","id":"4739D480-F248-11E8-B48F-1D18A9856A87"},{"first_name":"Lena A","full_name":"Schwarz, Lena A","last_name":"Schwarz","id":"29A8453C-F248-11E8-B48F-1D18A9856A87"},{"last_name":"Basilico","first_name":"Bernadette","full_name":"Basilico, Bernadette","orcid":"0000-0003-1843-3173","id":"36035796-5ACA-11E9-A75E-7AF2E5697425"},{"orcid":"0000-0003-1671-393X","id":"4323B49C-F248-11E8-B48F-1D18A9856A87","last_name":"Tasciyan","first_name":"Saren","full_name":"Tasciyan, Saren"},{"last_name":"Dimchev","first_name":"Georgi A","full_name":"Dimchev, Georgi A","orcid":"0000-0001-8370-6161","id":"38C393BE-F248-11E8-B48F-1D18A9856A87"},{"id":"2A103192-F248-11E8-B48F-1D18A9856A87","first_name":"Armel","full_name":"Nicolas, Armel","last_name":"Nicolas"},{"full_name":"Sommer, Christoph M","first_name":"Christoph M","last_name":"Sommer","id":"4DF26D8C-F248-11E8-B48F-1D18A9856A87","orcid":"0000-0003-1216-9105"},{"id":"382077BA-F248-11E8-B48F-1D18A9856A87","full_name":"Kreuzinger, Caroline","first_name":"Caroline","last_name":"Kreuzinger"},{"orcid":"0000-0002-9033-9096","id":"4C66542E-F248-11E8-B48F-1D18A9856A87","full_name":"Dotter, Christoph","first_name":"Christoph","last_name":"Dotter"},{"first_name":"Lisa","full_name":"Knaus, Lisa","last_name":"Knaus","id":"3B2ABCF4-F248-11E8-B48F-1D18A9856A87"},{"last_name":"Dobler","full_name":"Dobler, Zoe","first_name":"Zoe","id":"D23090A2-9057-11EA-883A-A8396FC7A38F"},{"full_name":"Cacci, Emanuele","first_name":"Emanuele","last_name":"Cacci"},{"last_name":"Schur","full_name":"Schur, Florian KM","first_name":"Florian KM","id":"48AD8942-F248-11E8-B48F-1D18A9856A87","orcid":"0000-0003-4790-8078"},{"orcid":"0000-0001-8559-3973","id":"42EFD3B6-F248-11E8-B48F-1D18A9856A87","first_name":"Johann G","full_name":"Danzl, Johann G","last_name":"Danzl"},{"first_name":"Gaia","full_name":"Novarino, Gaia","last_name":"Novarino","orcid":"0000-0002-7673-7178","id":"3E57A680-F248-11E8-B48F-1D18A9856A87"}],"day":"24","isi":1,"publisher":"Springer Nature","status":"public","intvolume":"        12","publication":"Nature Communications","quality_controlled":"1","department":[{"_id":"GaNo"},{"_id":"JoDa"},{"_id":"FlSc"},{"_id":"MiSi"},{"_id":"LifeSc"},{"_id":"Bio"}],"date_created":"2021-05-28T11:49:46Z","month":"05"},{"article_type":"original","has_accepted_license":"1","year":"2021","oa_version":"Published Version","date_updated":"2023-08-08T13:53:53Z","user_id":"4359f0d1-fa6c-11eb-b949-802e58b17ae8","scopus_import":"1","external_id":{"isi":["000659145000011"]},"acknowledged_ssus":[{"_id":"ScienComp"},{"_id":"LifeSc"},{"_id":"EM-Fac"}],"publication_identifier":{"eissn":["2041-1723"]},"article_number":"3226","file":[{"content_type":"application/pdf","file_id":"9538","relation":"main_file","date_created":"2021-06-09T15:21:14Z","success":1,"file_name":"2021_NatureCommunications_Obr.pdf","creator":"kschuh","file_size":6166295,"checksum":"53ccc53d09a9111143839dbe7784e663","date_updated":"2021-06-09T15:21:14Z","access_level":"open_access"}],"date_published":"2021-05-28T00:00:00Z","_id":"9431","abstract":[{"lang":"eng","text":"Inositol hexakisphosphate (IP6) is an assembly cofactor for HIV-1. We report here that IP6 is also used for assembly of Rous sarcoma virus (RSV), a retrovirus from a different genus. IP6 is ~100-fold more potent at promoting RSV mature capsid protein (CA) assembly than observed for HIV-1 and removal of IP6 in cells reduces infectivity by 100-fold. Here, visualized by cryo-electron tomography and subtomogram averaging, mature capsid-like particles show an IP6-like density in the CA hexamer, coordinated by rings of six lysines and six arginines. Phosphate and IP6 have opposing effects on CA in vitro assembly, inducing formation of T = 1 icosahedrons and tubes, respectively, implying that phosphate promotes pentamer and IP6 hexamer formation. Subtomogram averaging and classification optimized for analysis of pleomorphic retrovirus particles reveal that the heterogeneity of mature RSV CA polyhedrons results from an unexpected, intrinsic CA hexamer flexibility. In contrast, the CA pentamer forms rigid units organizing the local architecture. These different features of hexamers and pentamers determine the structural mechanism to form CA polyhedrons of variable shape in mature RSV particles."}],"issue":"1","article_processing_charge":"No","file_date_updated":"2021-06-09T15:21:14Z","volume":12,"tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)","image":"/images/cc_by.png","short":"CC BY (4.0)"},"publication_status":"published","oa":1,"day":"28","type":"journal_article","author":[{"last_name":"Obr","first_name":"Martin","full_name":"Obr, Martin","id":"4741CA5A-F248-11E8-B48F-1D18A9856A87"},{"last_name":"Ricana","first_name":"Clifton L.","full_name":"Ricana, Clifton L."},{"last_name":"Nikulin","full_name":"Nikulin, Nadia","first_name":"Nadia"},{"last_name":"Feathers","full_name":"Feathers, Jon-Philip R.","first_name":"Jon-Philip R."},{"last_name":"Klanschnig","first_name":"Marco","full_name":"Klanschnig, Marco"},{"last_name":"Thader","first_name":"Andreas","full_name":"Thader, Andreas","id":"3A18A7B8-F248-11E8-B48F-1D18A9856A87"},{"last_name":"Johnson","first_name":"Marc C.","full_name":"Johnson, Marc C."},{"full_name":"Vogt, Volker M.","first_name":"Volker M.","last_name":"Vogt"},{"id":"48AD8942-F248-11E8-B48F-1D18A9856A87","orcid":"0000-0003-4790-8078","full_name":"Schur, Florian KM","first_name":"Florian KM","last_name":"Schur"},{"full_name":"Dick, Robert A.","first_name":"Robert A.","last_name":"Dick"}],"citation":{"short":"M. Obr, C.L. Ricana, N. Nikulin, J.-P.R. Feathers, M. Klanschnig, A. Thader, M.C. Johnson, V.M. Vogt, F.K. Schur, R.A. Dick, Nature Communications 12 (2021).","ama":"Obr M, Ricana CL, Nikulin N, et al. Structure of the mature Rous sarcoma virus lattice reveals a role for IP6 in the formation of the capsid hexamer. <i>Nature Communications</i>. 2021;12(1). doi:<a href=\"https://doi.org/10.1038/s41467-021-23506-0\">10.1038/s41467-021-23506-0</a>","apa":"Obr, M., Ricana, C. L., Nikulin, N., Feathers, J.-P. R., Klanschnig, M., Thader, A., … Dick, R. A. (2021). Structure of the mature Rous sarcoma virus lattice reveals a role for IP6 in the formation of the capsid hexamer. <i>Nature Communications</i>. Nature Research. <a href=\"https://doi.org/10.1038/s41467-021-23506-0\">https://doi.org/10.1038/s41467-021-23506-0</a>","chicago":"Obr, Martin, Clifton L. Ricana, Nadia Nikulin, Jon-Philip R. Feathers, Marco Klanschnig, Andreas Thader, Marc C. Johnson, Volker M. Vogt, Florian KM Schur, and Robert A. Dick. “Structure of the Mature Rous Sarcoma Virus Lattice Reveals a Role for IP6 in the Formation of the Capsid Hexamer.” <i>Nature Communications</i>. Nature Research, 2021. <a href=\"https://doi.org/10.1038/s41467-021-23506-0\">https://doi.org/10.1038/s41467-021-23506-0</a>.","ieee":"M. Obr <i>et al.</i>, “Structure of the mature Rous sarcoma virus lattice reveals a role for IP6 in the formation of the capsid hexamer,” <i>Nature Communications</i>, vol. 12, no. 1. Nature Research, 2021.","ista":"Obr M, Ricana CL, Nikulin N, Feathers J-PR, Klanschnig M, Thader A, Johnson MC, Vogt VM, Schur FK, Dick RA. 2021. Structure of the mature Rous sarcoma virus lattice reveals a role for IP6 in the formation of the capsid hexamer. Nature Communications. 12(1), 3226.","mla":"Obr, Martin, et al. “Structure of the Mature Rous Sarcoma Virus Lattice Reveals a Role for IP6 in the Formation of the Capsid Hexamer.” <i>Nature Communications</i>, vol. 12, no. 1, 3226, Nature Research, 2021, doi:<a href=\"https://doi.org/10.1038/s41467-021-23506-0\">10.1038/s41467-021-23506-0</a>."},"title":"Structure of the mature Rous sarcoma virus lattice reveals a role for IP6 in the formation of the capsid hexamer","language":[{"iso":"eng"}],"keyword":["General Biochemistry","Genetics and Molecular Biology","General Physics and Astronomy","General Chemistry"],"ddc":["570"],"doi":"10.1038/s41467-021-23506-0","acknowledgement":"This work was funded by the National Institute of Allergy and Infectious Diseases under awards R01AI147890 to R.A.D., R01AI150454 to V.M.V, R35GM136258 in support of J-P.R.F, and the Austrian Science Fund (FWF) grant P31445 to F.K.M.S. Access to high-resolution cryo-ET data acquisition at EMBL Heidelberg was supported by iNEXT (grant no. 653706), funded by the Horizon 2020 program of the European Union (PID 4246). We thank Wim Hagen and Felix Weis at EMBL Heidelberg for support in cryo-ET data acquisition. This work made use of the Cornell Center for Materials Research Shared Facilities, which are supported through the NSF MRSEC program (DMR-179875). This research was also supported by the Scientific Service Units (SSUs) of IST Austria through resources provided by Scientific Computing (SciComp), the Life Science Facility (LSF), and the Electron Microscopy Facility (EMF).","related_material":{"link":[{"description":"News on IST Homepage","url":"https://ist.ac.at/en/news/how-retroviruses-become-infectious/","relation":"press_release"}]},"project":[{"name":"Structural conservation and diversity in retroviral capsid","grant_number":"P31445","_id":"26736D6A-B435-11E9-9278-68D0E5697425","call_identifier":"FWF"}],"month":"05","date_created":"2021-05-28T14:25:50Z","quality_controlled":"1","department":[{"_id":"FlSc"}],"publication":"Nature Communications","intvolume":"        12","status":"public","publisher":"Nature Research","isi":1},{"ddc":["570"],"doi":"10.1038/s41467-021-23854-x","language":[{"iso":"eng"}],"keyword":["General Biochemistry","Genetics and Molecular Biology","General Physics and Astronomy","General Chemistry"],"acknowledgement":"We are deeply grateful to the late Gregor Högenauer who built the foundation for this study with his visionary work on the inhibitor diazaborine and its bacterial target. We thank Rolf Breinbauer for insightful discussions on boron chemistry. We thank Anton Meinhart and Tim Clausen for the valuable discussion of the manuscript. We are indebted to Thomas Köcher for the MS measurement of the diazaborine-ATPγS adduct. We thank the team of the VBCF for support during early phases of this work and the IST Austria Electron Microscopy Facility for providing equipment. The lab of D.H. is supported by Boehringer Ingelheim. The work was funded by FWF projects P32536 and P32977 (to H.B.).","pmid":1,"type":"journal_article","author":[{"first_name":"Michael","full_name":"Prattes, Michael","last_name":"Prattes"},{"last_name":"Grishkovskaya","first_name":"Irina","full_name":"Grishkovskaya, Irina"},{"id":"3661B498-F248-11E8-B48F-1D18A9856A87","last_name":"Hodirnau","full_name":"Hodirnau, Victor-Valentin","first_name":"Victor-Valentin"},{"last_name":"Rössler","first_name":"Ingrid","full_name":"Rössler, Ingrid"},{"first_name":"Isabella","full_name":"Klein, Isabella","last_name":"Klein"},{"full_name":"Hetzmannseder, Christina","first_name":"Christina","last_name":"Hetzmannseder"},{"first_name":"Gertrude","full_name":"Zisser, Gertrude","last_name":"Zisser"},{"last_name":"Gruber","first_name":"Christian C.","full_name":"Gruber, Christian C."},{"first_name":"Karl","full_name":"Gruber, Karl","last_name":"Gruber"},{"last_name":"Haselbach","first_name":"David","full_name":"Haselbach, David"},{"last_name":"Bergler","first_name":"Helmut","full_name":"Bergler, Helmut"}],"day":"09","title":"Structural basis for inhibition of the AAA-ATPase Drg1 by diazaborine","citation":{"chicago":"Prattes, Michael, Irina Grishkovskaya, Victor-Valentin Hodirnau, Ingrid Rössler, Isabella Klein, Christina Hetzmannseder, Gertrude Zisser, et al. “Structural Basis for Inhibition of the AAA-ATPase Drg1 by Diazaborine.” <i>Nature Communications</i>. Springer Nature, 2021. <a href=\"https://doi.org/10.1038/s41467-021-23854-x\">https://doi.org/10.1038/s41467-021-23854-x</a>.","ieee":"M. Prattes <i>et al.</i>, “Structural basis for inhibition of the AAA-ATPase Drg1 by diazaborine,” <i>Nature Communications</i>, vol. 12, no. 1. Springer Nature, 2021.","ista":"Prattes M, Grishkovskaya I, Hodirnau V-V, Rössler I, Klein I, Hetzmannseder C, Zisser G, Gruber CC, Gruber K, Haselbach D, Bergler H. 2021. Structural basis for inhibition of the AAA-ATPase Drg1 by diazaborine. Nature Communications. 12(1), 3483.","mla":"Prattes, Michael, et al. “Structural Basis for Inhibition of the AAA-ATPase Drg1 by Diazaborine.” <i>Nature Communications</i>, vol. 12, no. 1, 3483, Springer Nature, 2021, doi:<a href=\"https://doi.org/10.1038/s41467-021-23854-x\">10.1038/s41467-021-23854-x</a>.","short":"M. Prattes, I. Grishkovskaya, V.-V. Hodirnau, I. Rössler, I. Klein, C. Hetzmannseder, G. Zisser, C.C. Gruber, K. Gruber, D. Haselbach, H. Bergler, Nature Communications 12 (2021).","ama":"Prattes M, Grishkovskaya I, Hodirnau V-V, et al. Structural basis for inhibition of the AAA-ATPase Drg1 by diazaborine. <i>Nature Communications</i>. 2021;12(1). doi:<a href=\"https://doi.org/10.1038/s41467-021-23854-x\">10.1038/s41467-021-23854-x</a>","apa":"Prattes, M., Grishkovskaya, I., Hodirnau, V.-V., Rössler, I., Klein, I., Hetzmannseder, C., … Bergler, H. (2021). Structural basis for inhibition of the AAA-ATPase Drg1 by diazaborine. <i>Nature Communications</i>. Springer Nature. <a href=\"https://doi.org/10.1038/s41467-021-23854-x\">https://doi.org/10.1038/s41467-021-23854-x</a>"},"status":"public","intvolume":"        12","department":[{"_id":"EM-Fac"}],"quality_controlled":"1","publication":"Nature Communications","isi":1,"publisher":"Springer Nature","date_created":"2021-06-10T14:57:45Z","month":"06","publication_identifier":{"eissn":["2041-1723"]},"acknowledged_ssus":[{"_id":"EM-Fac"}],"date_updated":"2023-08-08T14:05:26Z","user_id":"4359f0d1-fa6c-11eb-b949-802e58b17ae8","external_id":{"pmid":["34108481"],"isi":["000664874700014"]},"has_accepted_license":"1","oa_version":"Published Version","year":"2021","article_type":"original","volume":12,"tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)","image":"/images/cc_by.png","short":"CC BY (4.0)"},"file_date_updated":"2021-06-15T18:55:59Z","oa":1,"publication_status":"published","date_published":"2021-06-09T00:00:00Z","_id":"9540","abstract":[{"lang":"eng","text":"The hexameric AAA-ATPase Drg1 is a key factor in eukaryotic ribosome biogenesis and initiates cytoplasmic maturation of the large ribosomal subunit by releasing the shuttling maturation factor Rlp24. Drg1 monomers contain two AAA-domains (D1 and D2) that act in a concerted manner. Rlp24 release is inhibited by the drug diazaborine which blocks ATP hydrolysis in D2. The mode of inhibition was unknown. Here we show the first cryo-EM structure of Drg1 revealing the inhibitory mechanism. Diazaborine forms a covalent bond to the 2′-OH of the nucleotide in D2, explaining its specificity for this site. As a consequence, the D2 domain is locked in a rigid, inactive state, stalling the whole Drg1 hexamer. Resistance mechanisms identified include abolished drug binding and altered positioning of the nucleotide. Our results suggest nucleotide-modifying compounds as potential novel inhibitors for AAA-ATPases."}],"file":[{"success":1,"date_created":"2021-06-15T18:55:59Z","relation":"main_file","file_id":"9556","content_type":"application/pdf","access_level":"open_access","date_updated":"2021-06-15T18:55:59Z","checksum":"40fc24c1310930990b52a8ad1142ee97","creator":"cziletti","file_size":3397292,"file_name":"2021_NatureComm_Prattes.pdf"}],"article_number":"3483","issue":"1","article_processing_charge":"No"},{"ddc":["610"],"doi":"10.1038/s41467-021-26360-2","language":[{"iso":"eng"}],"keyword":["general physics and astronomy","general biochemistry","genetics and molecular biology","general chemistry"],"acknowledgement":"D.S. thanks Claudine Kraft, Renée Schroeder, Verena Jantsch, Franz Klein and Peter Schlögelhofer for support. We thank Anita Testa Salmazo for help with purifying Pol II; Matthias Geyer and Robert Düster for sharing DYRK1A kinase; Felix Hartmann and Clemens Plaschka for help with mass photometry; Goran Kokic for design of the arrest assay sequences; Petra van der Lelij for help with generating mESC KO; Maximilian Freilinger for help with the purification of mEGFP-CTD; Stefan Ameres, Nina Fasching and Brian Reichholf for advice on SLAM-seq and for sharing reagents; Laura Gallego Valle for advice regarding LLPS assays; Krzysztof Chylinski for advice regarding CRISPR/Cas9 methodology; VBCF Protein Technologies facility for purifying PHF3 and providing gRNAs and Cas9; VBCF NGS facility for sequencing; Monoclonal antibody facility at the Helmholtz center for Pol II antibodies; Friedrich Propst and Elzbieta Kowalska for advice and for sharing materials; Egon Ogris for sharing materials; Martin Eilers for recommending a ChIP-grade TFIIS antibody; Susanne Opravil, Otto Hudecz, Markus Hartl and Natascha Hartl for mass spectrometry analysis; staff of the X-ray beamlines at the ESRF in Grenoble for their excellent support; Christa Bücker, Anton Meinhart, Clemens Plaschka and members of the Slade lab for critical comments on the manuscript; Life Science Editors for editing assistance. M.B. and D.S. acknowledge support by the FWF-funded DK ‘Chromosome Dynamics’. T.K. is a recipient of the DOC fellowship from the Austrian Academy of Sciences. U.S. is supported by the L’Oreal for Women in Science Austria Fellowship and the Austrian Science Fund (FWF T 795-B30). M.L is supported by the Vienna Science and Technology Fund (WWTF, VRG14-006). R.S. is supported by the Czech Science Foundation (15-17670 S and 21-24460 S), Ministry of Education, Youths and Sports of the Czech Republic (CEITEC 2020 project (LQ1601)), and the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (Grant agreement no. 649030); this publication reflects only the author’s view and the Research Executive Agency is not responsible for any use that may be made of the information it contains. M.S. is supported by the Czech Science Foundation (GJ20-21581Y). K.D.C. research is supported by the Austrian Science Fund (FWF) Projects I525 and I1593, P22276, P19060, and W1221, Federal Ministry of Economy, Family and Youth through the initiative ‘Laura Bassi Centres of Expertise’, funding from the Centre of Optimized Structural Studies No. 253275, the Wellcome Trust Collaborative Award (201543/Z/16), COST action BM1405 Non-globular proteins - from sequence to structure, function and application in molecular physiopathology (NGP-NET), the Vienna Science and Technology Fund (WWTF LS17-008), and by the University of Vienna. This project was funded by the MFPL start-up grant, the Vienna Science and Technology Fund (WWTF LS14-001), and the Austrian Science Fund (P31546-B28 and W1258 “DK: Integrative Structural Biology”) to D.S.","related_material":{"link":[{"description":"Preprint ","url":"https://www.biorxiv.org/content/10.1101/2020.02.11.943159","relation":"earlier_version"}]},"author":[{"first_name":"Lisa-Marie","full_name":"Appel, Lisa-Marie","last_name":"Appel"},{"first_name":"Vedran","full_name":"Franke, Vedran","last_name":"Franke"},{"last_name":"Bruno","first_name":"Melania","full_name":"Bruno, Melania"},{"full_name":"Grishkovskaya, Irina","first_name":"Irina","last_name":"Grishkovskaya"},{"last_name":"Kasiliauskaite","full_name":"Kasiliauskaite, Aiste","first_name":"Aiste"},{"full_name":"Kaufmann, Tanja","first_name":"Tanja","last_name":"Kaufmann"},{"first_name":"Ursula E.","full_name":"Schoeberl, Ursula E.","last_name":"Schoeberl"},{"last_name":"Puchinger","first_name":"Martin G.","full_name":"Puchinger, Martin G."},{"first_name":"Sebastian","full_name":"Kostrhon, Sebastian","last_name":"Kostrhon"},{"first_name":"Carmen","full_name":"Ebenwaldner, Carmen","last_name":"Ebenwaldner"},{"first_name":"Marek","full_name":"Sebesta, Marek","last_name":"Sebesta"},{"first_name":"Etienne","full_name":"Beltzung, Etienne","last_name":"Beltzung"},{"first_name":"Karl","full_name":"Mechtler, Karl","last_name":"Mechtler"},{"last_name":"Lin","full_name":"Lin, Gen","first_name":"Gen"},{"last_name":"Vlasova","first_name":"Anna","full_name":"Vlasova, Anna"},{"full_name":"Leeb, Martin","first_name":"Martin","last_name":"Leeb"},{"last_name":"Pavri","full_name":"Pavri, Rushad","first_name":"Rushad"},{"first_name":"Alexander","full_name":"Stark, Alexander","last_name":"Stark"},{"full_name":"Akalin, Altuna","first_name":"Altuna","last_name":"Akalin"},{"first_name":"Richard","full_name":"Stefl, Richard","last_name":"Stefl"},{"last_name":"Bernecky","full_name":"Bernecky, Carrie A","first_name":"Carrie A","orcid":"0000-0003-0893-7036","id":"2CB9DFE2-F248-11E8-B48F-1D18A9856A87"},{"full_name":"Djinovic-Carugo, Kristina","first_name":"Kristina","last_name":"Djinovic-Carugo"},{"full_name":"Slade, Dea","first_name":"Dea","last_name":"Slade"}],"type":"journal_article","day":"19","title":"PHF3 regulates neuronal gene expression through the Pol II CTD reader domain SPOC","citation":{"mla":"Appel, Lisa-Marie, et al. “PHF3 Regulates Neuronal Gene Expression through the Pol II CTD Reader Domain SPOC.” <i>Nature Communications</i>, vol. 12, no. 1, 6078, Springer Nature, 2021, doi:<a href=\"https://doi.org/10.1038/s41467-021-26360-2\">10.1038/s41467-021-26360-2</a>.","ista":"Appel L-M, Franke V, Bruno M, Grishkovskaya I, Kasiliauskaite A, Kaufmann T, Schoeberl UE, Puchinger MG, Kostrhon S, Ebenwaldner C, Sebesta M, Beltzung E, Mechtler K, Lin G, Vlasova A, Leeb M, Pavri R, Stark A, Akalin A, Stefl R, Bernecky C, Djinovic-Carugo K, Slade D. 2021. PHF3 regulates neuronal gene expression through the Pol II CTD reader domain SPOC. Nature Communications. 12(1), 6078.","ieee":"L.-M. Appel <i>et al.</i>, “PHF3 regulates neuronal gene expression through the Pol II CTD reader domain SPOC,” <i>Nature Communications</i>, vol. 12, no. 1. Springer Nature, 2021.","chicago":"Appel, Lisa-Marie, Vedran Franke, Melania Bruno, Irina Grishkovskaya, Aiste Kasiliauskaite, Tanja Kaufmann, Ursula E. Schoeberl, et al. “PHF3 Regulates Neuronal Gene Expression through the Pol II CTD Reader Domain SPOC.” <i>Nature Communications</i>. Springer Nature, 2021. <a href=\"https://doi.org/10.1038/s41467-021-26360-2\">https://doi.org/10.1038/s41467-021-26360-2</a>.","apa":"Appel, L.-M., Franke, V., Bruno, M., Grishkovskaya, I., Kasiliauskaite, A., Kaufmann, T., … Slade, D. (2021). PHF3 regulates neuronal gene expression through the Pol II CTD reader domain SPOC. <i>Nature Communications</i>. Springer Nature. <a href=\"https://doi.org/10.1038/s41467-021-26360-2\">https://doi.org/10.1038/s41467-021-26360-2</a>","ama":"Appel L-M, Franke V, Bruno M, et al. PHF3 regulates neuronal gene expression through the Pol II CTD reader domain SPOC. <i>Nature Communications</i>. 2021;12(1). doi:<a href=\"https://doi.org/10.1038/s41467-021-26360-2\">10.1038/s41467-021-26360-2</a>","short":"L.-M. Appel, V. Franke, M. Bruno, I. Grishkovskaya, A. Kasiliauskaite, T. Kaufmann, U.E. Schoeberl, M.G. Puchinger, S. Kostrhon, C. Ebenwaldner, M. Sebesta, E. Beltzung, K. Mechtler, G. Lin, A. Vlasova, M. Leeb, R. Pavri, A. Stark, A. Akalin, R. Stefl, C. Bernecky, K. Djinovic-Carugo, D. Slade, Nature Communications 12 (2021)."},"status":"public","intvolume":"        12","quality_controlled":"1","department":[{"_id":"CaBe"}],"publication":"Nature Communications","isi":1,"publisher":"Springer Nature","date_created":"2021-10-20T14:40:32Z","month":"10","publication_identifier":{"eissn":["2041-1723"]},"date_updated":"2023-08-14T08:02:31Z","user_id":"4359f0d1-fa6c-11eb-b949-802e58b17ae8","external_id":{"isi":["000709050300001"]},"has_accepted_license":"1","year":"2021","oa_version":"Published Version","article_type":"original","volume":12,"tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)","image":"/images/cc_by.png","short":"CC BY (4.0)"},"file_date_updated":"2021-10-21T13:51:49Z","oa":1,"publication_status":"published","abstract":[{"text":"The C-terminal domain (CTD) of the largest subunit of RNA polymerase II (Pol II) is a regulatory hub for transcription and RNA processing. Here, we identify PHD-finger protein 3 (PHF3) as a regulator of transcription and mRNA stability that docks onto Pol II CTD through its SPOC domain. We characterize SPOC as a CTD reader domain that preferentially binds two phosphorylated Serine-2 marks in adjacent CTD repeats. PHF3 drives liquid-liquid phase separation of phosphorylated Pol II, colocalizes with Pol II clusters and tracks with Pol II across the length of genes. PHF3 knock-out or SPOC deletion in human cells results in increased Pol II stalling, reduced elongation rate and an increase in mRNA stability, with marked derepression of neuronal genes. Key neuronal genes are aberrantly expressed in Phf3 knock-out mouse embryonic stem cells, resulting in impaired neuronal differentiation. Our data suggest that PHF3 acts as a prominent effector of neuronal gene regulation by bridging transcription with mRNA decay.","lang":"eng"}],"_id":"10163","date_published":"2021-10-19T00:00:00Z","file":[{"date_created":"2021-10-21T13:51:49Z","success":1,"content_type":"application/pdf","file_id":"10169","relation":"main_file","checksum":"d99fcd51aebde19c21314e3de0148007","date_updated":"2021-10-21T13:51:49Z","access_level":"open_access","file_name":"2021_NatComm_Appel.pdf","file_size":5111706,"creator":"cchlebak"}],"article_number":"6078","issue":"1","article_processing_charge":"No"},{"acknowledgement":"We thank Stuart Lipton and Nobuki Nakanishi for providing the Grin3a knockout mice, Beverly Davidson for the AAV-caRheb, Jose Esteban for help with behavioral and biochemical experiments, and Noelia Campillo, Rebeca Martínez-Turrillas, and Ana Navarro for expert technical help. Work was funded by the UTE project CIMA; fellowships from the Fundación Tatiana Pérez de Guzmán el Bueno, FEBS, and IBRO (to M.J.C.D.), Generalitat Valenciana (to O.E.-Z.), Juan de la Cierva (to L.G.R.), FPI-MINECO (to E.R.V., to S.N.) and Intertalentum postdoctoral program (to V.B.); ANR (GluBrain3A) and ERC Advanced Grants (#693021) (to P.P.); Ramón y Cajal program RYC2014-15784, RETOS-MINECO SAF2016-76565-R, ERANET-Neuron JTC 2019 ISCIII AC19/00077 FEDER funds (to R.A.); RETOS-MINECO SAF2017-87928-R (to A.B.); an NIH grant (NS76637) and UTHSC College of Medicine funds (to S.J.T.); and NARSAD Independent Investigator Award and grants from the MINECO (CSD2008-00005, SAF2013-48983R, SAF2016-80895-R), Generalitat Valenciana (PROMETEO 2019/020)(to I.P.O.) and Severo-Ochoa Excellence Awards (SEV-2013-0317, SEV-2017-0723).","language":[{"iso":"eng"}],"keyword":["general immunology and microbiology","general biochemistry","genetics and molecular biology","general medicine","general neuroscience"],"ddc":["570"],"doi":"10.7554/elife.71575","citation":{"chicago":"Conde-Dusman, María J, Partha N Dey, Óscar Elía-Zudaire, Luis E Garcia Rabaneda, Carmen García-Lira, Teddy Grand, Victor Briz, et al. “Control of Protein Synthesis and Memory by GluN3A-NMDA Receptors through Inhibition of GIT1/MTORC1 Assembly.” <i>ELife</i>. eLife Sciences Publications, 2021. <a href=\"https://doi.org/10.7554/elife.71575\">https://doi.org/10.7554/elife.71575</a>.","ieee":"M. J. Conde-Dusman <i>et al.</i>, “Control of protein synthesis and memory by GluN3A-NMDA receptors through inhibition of GIT1/mTORC1 assembly,” <i>eLife</i>, vol. 10. eLife Sciences Publications, 2021.","ista":"Conde-Dusman MJ, Dey PN, Elía-Zudaire Ó, Garcia Rabaneda LE, García-Lira C, Grand T, Briz V, Velasco ER, Andero Galí R, Niñerola S, Barco A, Paoletti P, Wesseling JF, Gardoni F, Tavalin SJ, Perez-Otaño I. 2021. Control of protein synthesis and memory by GluN3A-NMDA receptors through inhibition of GIT1/mTORC1 assembly. eLife. 10, e71575.","mla":"Conde-Dusman, María J., et al. “Control of Protein Synthesis and Memory by GluN3A-NMDA Receptors through Inhibition of GIT1/MTORC1 Assembly.” <i>ELife</i>, vol. 10, e71575, eLife Sciences Publications, 2021, doi:<a href=\"https://doi.org/10.7554/elife.71575\">10.7554/elife.71575</a>.","short":"M.J. Conde-Dusman, P.N. Dey, Ó. Elía-Zudaire, L.E. Garcia Rabaneda, C. García-Lira, T. Grand, V. Briz, E.R. Velasco, R. Andero Galí, S. Niñerola, A. Barco, P. Paoletti, J.F. Wesseling, F. Gardoni, S.J. Tavalin, I. Perez-Otaño, ELife 10 (2021).","ama":"Conde-Dusman MJ, Dey PN, Elía-Zudaire Ó, et al. Control of protein synthesis and memory by GluN3A-NMDA receptors through inhibition of GIT1/mTORC1 assembly. <i>eLife</i>. 2021;10. doi:<a href=\"https://doi.org/10.7554/elife.71575\">10.7554/elife.71575</a>","apa":"Conde-Dusman, M. J., Dey, P. N., Elía-Zudaire, Ó., Garcia Rabaneda, L. E., García-Lira, C., Grand, T., … Perez-Otaño, I. (2021). Control of protein synthesis and memory by GluN3A-NMDA receptors through inhibition of GIT1/mTORC1 assembly. <i>ELife</i>. eLife Sciences Publications. <a href=\"https://doi.org/10.7554/elife.71575\">https://doi.org/10.7554/elife.71575</a>"},"title":"Control of protein synthesis and memory by GluN3A-NMDA receptors through inhibition of GIT1/mTORC1 assembly","day":"17","type":"journal_article","author":[{"last_name":"Conde-Dusman","first_name":"María J","full_name":"Conde-Dusman, María J"},{"last_name":"Dey","full_name":"Dey, Partha N","first_name":"Partha N"},{"first_name":"Óscar","full_name":"Elía-Zudaire, Óscar","last_name":"Elía-Zudaire"},{"full_name":"Garcia Rabaneda, Luis E","first_name":"Luis E","last_name":"Garcia Rabaneda","id":"33D1B084-F248-11E8-B48F-1D18A9856A87"},{"first_name":"Carmen","full_name":"García-Lira, Carmen","last_name":"García-Lira"},{"last_name":"Grand","full_name":"Grand, Teddy","first_name":"Teddy"},{"first_name":"Victor","full_name":"Briz, Victor","last_name":"Briz"},{"first_name":"Eric R","full_name":"Velasco, Eric R","last_name":"Velasco"},{"last_name":"Andero Galí","first_name":"Raül","full_name":"Andero Galí, Raül"},{"last_name":"Niñerola","full_name":"Niñerola, Sergio","first_name":"Sergio"},{"last_name":"Barco","full_name":"Barco, Angel","first_name":"Angel"},{"first_name":"Pierre","full_name":"Paoletti, Pierre","last_name":"Paoletti"},{"full_name":"Wesseling, John F","first_name":"John F","last_name":"Wesseling"},{"last_name":"Gardoni","full_name":"Gardoni, Fabrizio","first_name":"Fabrizio"},{"last_name":"Tavalin","first_name":"Steven J","full_name":"Tavalin, Steven J"},{"last_name":"Perez-Otaño","first_name":"Isabel","full_name":"Perez-Otaño, Isabel"}],"publisher":"eLife Sciences Publications","isi":1,"quality_controlled":"1","department":[{"_id":"GaNo"}],"publication":"eLife","status":"public","intvolume":"        10","month":"11","date_created":"2021-11-18T06:59:45Z","date_updated":"2023-08-14T11:50:50Z","user_id":"4359f0d1-fa6c-11eb-b949-802e58b17ae8","external_id":{"isi":["000720945900001"]},"publication_identifier":{"issn":["2050-084X"]},"article_type":"original","has_accepted_license":"1","oa_version":"Published Version","year":"2021","publication_status":"published","oa":1,"file_date_updated":"2021-11-18T07:02:02Z","volume":10,"tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)","image":"/images/cc_by.png","short":"CC BY (4.0)"},"article_processing_charge":"No","article_number":"e71575","file":[{"success":1,"date_created":"2021-11-18T07:02:02Z","relation":"main_file","file_id":"10302","content_type":"application/pdf","access_level":"open_access","date_updated":"2021-11-18T07:02:02Z","checksum":"59318e9e41507cec83c2f4070e6ad540","file_size":2477302,"creator":"lgarciar","file_name":"elife-71575-v1.pdf"}],"date_published":"2021-11-17T00:00:00Z","_id":"10301","abstract":[{"text":"De novo protein synthesis is required for synapse modifications underlying stable memory encoding. Yet neurons are highly compartmentalized cells and how protein synthesis can be regulated at the synapse level is unknown. Here, we characterize neuronal signaling complexes formed by the postsynaptic scaffold GIT1, the mechanistic target of rapamycin (mTOR) kinase, and Raptor that couple synaptic stimuli to mTOR-dependent protein synthesis; and identify NMDA receptors containing GluN3A subunits as key negative regulators of GIT1 binding to mTOR. Disruption of GIT1/mTOR complexes by enhancing GluN3A expression or silencing GIT1 inhibits synaptic mTOR activation and restricts the mTOR-dependent translation of specific activity-regulated mRNAs. Conversely, GluN3A removal enables complex formation, potentiates mTOR-dependent protein synthesis, and facilitates the consolidation of associative and spatial memories in mice. The memory enhancement becomes evident with light or spaced training, can be achieved by selectively deleting GluN3A from excitatory neurons during adulthood, and does not compromise other aspects of cognition such as memory flexibility or extinction. Our findings provide mechanistic insight into synaptic translational control and reveal a potentially selective target for cognitive enhancement.","lang":"eng"}]},{"title":"Cryo-EM structure of a functional monomeric Photosystem I from Thermosynechococcus elongatus reveals red chlorophyll cluster","citation":{"apa":"Çoruh, M. O., Frank, A., Tanaka, H., Kawamoto, A., El-Mohsnawy, E., Kato, T., … Kurisu, G. (2021). Cryo-EM structure of a functional monomeric Photosystem I from Thermosynechococcus elongatus reveals red chlorophyll cluster. <i>Communications Biology</i>. Springer . <a href=\"https://doi.org/10.1038/s42003-021-01808-9\">https://doi.org/10.1038/s42003-021-01808-9</a>","ama":"Çoruh MO, Frank A, Tanaka H, et al. Cryo-EM structure of a functional monomeric Photosystem I from Thermosynechococcus elongatus reveals red chlorophyll cluster. <i>Communications Biology</i>. 2021;4(1). doi:<a href=\"https://doi.org/10.1038/s42003-021-01808-9\">10.1038/s42003-021-01808-9</a>","short":"M.O. Çoruh, A. Frank, H. Tanaka, A. Kawamoto, E. El-Mohsnawy, T. Kato, K. Namba, C. Gerle, M.M. Nowaczyk, G. Kurisu, Communications Biology 4 (2021).","mla":"Çoruh, Mehmet Orkun, et al. “Cryo-EM Structure of a Functional Monomeric Photosystem I from Thermosynechococcus Elongatus Reveals Red Chlorophyll Cluster.” <i>Communications Biology</i>, vol. 4, no. 1, 304, Springer , 2021, doi:<a href=\"https://doi.org/10.1038/s42003-021-01808-9\">10.1038/s42003-021-01808-9</a>.","ista":"Çoruh MO, Frank A, Tanaka H, Kawamoto A, El-Mohsnawy E, Kato T, Namba K, Gerle C, Nowaczyk MM, Kurisu G. 2021. Cryo-EM structure of a functional monomeric Photosystem I from Thermosynechococcus elongatus reveals red chlorophyll cluster. Communications Biology. 4(1), 304.","ieee":"M. O. Çoruh <i>et al.</i>, “Cryo-EM structure of a functional monomeric Photosystem I from Thermosynechococcus elongatus reveals red chlorophyll cluster,” <i>Communications Biology</i>, vol. 4, no. 1. Springer , 2021.","chicago":"Çoruh, Mehmet Orkun, Anna Frank, Hideaki Tanaka, Akihiro Kawamoto, Eithar El-Mohsnawy, Takayuki Kato, Keiichi Namba, Christoph Gerle, Marc M. Nowaczyk, and Genji Kurisu. “Cryo-EM Structure of a Functional Monomeric Photosystem I from Thermosynechococcus Elongatus Reveals Red Chlorophyll Cluster.” <i>Communications Biology</i>. Springer , 2021. <a href=\"https://doi.org/10.1038/s42003-021-01808-9\">https://doi.org/10.1038/s42003-021-01808-9</a>."},"author":[{"orcid":"0000-0002-3219-2022","id":"d25163e5-8d53-11eb-a251-e6dd8ea1b8ef","last_name":"Çoruh","first_name":"Mehmet Orkun","full_name":"Çoruh, Mehmet Orkun"},{"full_name":"Frank, Anna","first_name":"Anna","last_name":"Frank"},{"first_name":"Hideaki","full_name":"Tanaka, Hideaki","last_name":"Tanaka"},{"full_name":"Kawamoto, Akihiro","first_name":"Akihiro","last_name":"Kawamoto"},{"last_name":"El-Mohsnawy","first_name":"Eithar","full_name":"El-Mohsnawy, Eithar"},{"last_name":"Kato","full_name":"Kato, Takayuki","first_name":"Takayuki"},{"last_name":"Namba","first_name":"Keiichi","full_name":"Namba, Keiichi"},{"last_name":"Gerle","first_name":"Christoph","full_name":"Gerle, Christoph"},{"last_name":"Nowaczyk","full_name":"Nowaczyk, Marc M.","first_name":"Marc M."},{"full_name":"Kurisu, Genji","first_name":"Genji","last_name":"Kurisu"}],"type":"journal_article","day":"08","pmid":1,"acknowledgement":"We are grateful for additional support and valuable scientific input for this project by Yuko Misumi, Jiannan Li, Hisako Kubota-Kawai, Takeshi Kawabata, Mian Wu, Eiki Yamashita, Atsushi Nakagawa, Volker Hartmann, Melanie Völkel and Matthias Rögner. Parts of this research were funded by the German Research Council (DFG) within the framework of GRK 2341 (Microbial Substrate Conversion) to M.M.N., the Platform Project for Supporting Drug Discovery and Life Science Research [Basis for Supporting Innovative Drug Discovery and Life Science Research (BINDS)] from AMED under grant number JP20am0101117 (K.N.), JP16K07266 to Atsunori Oshima and C.G., a Grants-in-Aid for Scientific Research under grant number JP 25000013 (K.N.), 17H03647 (C.G.) and 16H06560 (G.K.) from MEXT-KAKENHI, the International Joint Research Promotion Program from Osaka University to M.M.N., C.G. and G.K., and the Cyclic Innovation for Clinical Empowerment (CiCLE) Grant Number JP17pc0101020 from AMED to K.N. and G.K.","doi":"10.1038/s42003-021-01808-9","ddc":["570"],"keyword":["general agricultural and biological Sciences","general biochemistry","genetics and molecular biology","medicine (miscellaneous)"],"language":[{"iso":"eng"}],"date_created":"2021-11-19T11:37:29Z","month":"03","isi":1,"publisher":"Springer ","intvolume":"         4","status":"public","publication":"Communications Biology","quality_controlled":"1","department":[{"_id":"LeSa"}],"year":"2021","oa_version":"Published Version","has_accepted_license":"1","article_type":"original","publication_identifier":{"issn":["2399-3642"]},"scopus_import":"1","external_id":{"isi":["000627440700001"],"pmid":["33686186"]},"date_updated":"2023-08-14T11:51:19Z","user_id":"4359f0d1-fa6c-11eb-b949-802e58b17ae8","article_processing_charge":"No","issue":"1","abstract":[{"text":"A high-resolution structure of trimeric cyanobacterial Photosystem I (PSI) from Thermosynechococcus elongatus was reported as the first atomic model of PSI almost 20 years ago. However, the monomeric PSI structure has not yet been reported despite long-standing interest in its structure and extensive spectroscopic characterization of the loss of red chlorophylls upon monomerization. Here, we describe the structure of monomeric PSI from Thermosynechococcus elongatus BP-1. Comparison with the trimer structure gave detailed insights into monomerization-induced changes in both the central trimerization domain and the peripheral regions of the complex. Monomerization-induced loss of red chlorophylls is assigned to a cluster of chlorophylls adjacent to PsaX. Based on our findings, we propose a role of PsaX in the stabilization of red chlorophylls and that lipids of the surrounding membrane present a major source of thermal energy for uphill excitation energy transfer from red chlorophylls to P700.","lang":"eng"}],"_id":"10310","date_published":"2021-03-08T00:00:00Z","file":[{"access_level":"open_access","date_updated":"2021-11-19T15:09:18Z","checksum":"8ffd39f2bba7152a2441802ff313bf0b","creator":"cchlebak","file_size":6030261,"file_name":"2021_CommBio_Çoruh.pdf","success":1,"date_created":"2021-11-19T15:09:18Z","file_id":"10318","relation":"main_file","content_type":"application/pdf"}],"article_number":"304","oa":1,"publication_status":"published","tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)","image":"/images/cc_by.png","short":"CC BY (4.0)"},"volume":4,"file_date_updated":"2021-11-19T15:09:18Z"},{"publication_identifier":{"eissn":["1545-2948"],"issn":["0066-4197"]},"external_id":{"isi":["000747220900010"],"pmid":["34460295"]},"scopus_import":"1","date_updated":"2023-08-14T13:05:13Z","user_id":"4359f0d1-fa6c-11eb-b949-802e58b17ae8","oa_version":"None","year":"2021","article_type":"original","publication_status":"published","volume":55,"article_processing_charge":"No","_id":"10406","date_published":"2021-08-30T00:00:00Z","abstract":[{"lang":"eng","text":"Multicellular organisms develop complex shapes from much simpler, single-celled zygotes through a process commonly called morphogenesis. Morphogenesis involves an interplay between several factors, ranging from the gene regulatory networks determining cell fate and differentiation to the mechanical processes underlying cell and tissue shape changes. Thus, the study of morphogenesis has historically been based on multidisciplinary approaches at the interface of biology with physics and mathematics. Recent technological advances have further improved our ability to study morphogenesis by bridging the gap between the genetic and biophysical factors through the development of new tools for visualizing, analyzing, and perturbing these factors and their biochemical intermediaries. Here, we review how a combination of genetic, microscopic, biophysical, and biochemical approaches has aided our attempts to understand morphogenesis and discuss potential approaches that may be beneficial to such an inquiry in the future."}],"pmid":1,"project":[{"_id":"260C2330-B435-11E9-9278-68D0E5697425","call_identifier":"H2020","grant_number":"754411","name":"ISTplus - Postdoctoral Fellowships"}],"acknowledgement":"The authors would like to thank Feyza Nur Arslan, Suyash Naik, Diana Pinheiro, Alexandra Schauer, and Shayan Shamipour for their comments on the draft. N.M. is supported by an ISTplus postdoctoral fellowship (H2020 Marie-Sklodowska-Curie COFUND Action).","doi":"10.1146/annurev-genet-071819-103748","keyword":["morphogenesis","forward genetics","high-resolution microscopy","biophysics","biochemistry","patterning"],"language":[{"iso":"eng"}],"title":"Dissecting organismal morphogenesis by bridging genetics and biophysics","citation":{"short":"N. Mishra, C.-P.J. Heisenberg, Annual Review of Genetics 55 (2021) 209–233.","apa":"Mishra, N., &#38; Heisenberg, C.-P. J. (2021). Dissecting organismal morphogenesis by bridging genetics and biophysics. <i>Annual Review of Genetics</i>. Annual Reviews. <a href=\"https://doi.org/10.1146/annurev-genet-071819-103748\">https://doi.org/10.1146/annurev-genet-071819-103748</a>","ama":"Mishra N, Heisenberg C-PJ. Dissecting organismal morphogenesis by bridging genetics and biophysics. <i>Annual Review of Genetics</i>. 2021;55:209-233. doi:<a href=\"https://doi.org/10.1146/annurev-genet-071819-103748\">10.1146/annurev-genet-071819-103748</a>","ista":"Mishra N, Heisenberg C-PJ. 2021. Dissecting organismal morphogenesis by bridging genetics and biophysics. Annual Review of Genetics. 55, 209–233.","ieee":"N. Mishra and C.-P. J. Heisenberg, “Dissecting organismal morphogenesis by bridging genetics and biophysics,” <i>Annual Review of Genetics</i>, vol. 55. Annual Reviews, pp. 209–233, 2021.","chicago":"Mishra, Nikhil, and Carl-Philipp J Heisenberg. “Dissecting Organismal Morphogenesis by Bridging Genetics and Biophysics.” <i>Annual Review of Genetics</i>. Annual Reviews, 2021. <a href=\"https://doi.org/10.1146/annurev-genet-071819-103748\">https://doi.org/10.1146/annurev-genet-071819-103748</a>.","mla":"Mishra, Nikhil, and Carl-Philipp J. Heisenberg. “Dissecting Organismal Morphogenesis by Bridging Genetics and Biophysics.” <i>Annual Review of Genetics</i>, vol. 55, Annual Reviews, 2021, pp. 209–33, doi:<a href=\"https://doi.org/10.1146/annurev-genet-071819-103748\">10.1146/annurev-genet-071819-103748</a>."},"ec_funded":1,"author":[{"orcid":"0000-0002-6425-5788","id":"C4D70E82-1081-11EA-B3ED-9A4C3DDC885E","last_name":"Mishra","full_name":"Mishra, Nikhil","first_name":"Nikhil"},{"orcid":"0000-0002-0912-4566","id":"39427864-F248-11E8-B48F-1D18A9856A87","last_name":"Heisenberg","full_name":"Heisenberg, Carl-Philipp J","first_name":"Carl-Philipp J"}],"type":"journal_article","day":"30","isi":1,"publisher":"Annual Reviews","status":"public","intvolume":"        55","publication":"Annual Review of Genetics","department":[{"_id":"CaHe"}],"quality_controlled":"1","page":"209-233","date_created":"2021-12-05T23:01:41Z","month":"08"},{"extern":"1","month":"05","date_created":"2023-02-20T08:11:29Z","quality_controlled":"1","publication":"Nature Communications","intvolume":"        12","status":"public","publisher":"Springer Nature","day":"17","type":"journal_article","author":[{"first_name":"Evan","full_name":"Miles, Evan","last_name":"Miles"},{"full_name":"McCarthy, Michael","first_name":"Michael","last_name":"McCarthy"},{"last_name":"Dehecq","first_name":"Amaury","full_name":"Dehecq, Amaury"},{"full_name":"Kneib, Marin","first_name":"Marin","last_name":"Kneib"},{"last_name":"Fugger","first_name":"Stefan","full_name":"Fugger, Stefan"},{"last_name":"Pellicciotti","first_name":"Francesca","full_name":"Pellicciotti, Francesca","id":"b28f055a-81ea-11ed-b70c-a9fe7f7b0e70"}],"citation":{"mla":"Miles, Evan, et al. “Health and Sustainability of Glaciers in High Mountain Asia.” <i>Nature Communications</i>, vol. 12, 2868, Springer Nature, 2021, doi:<a href=\"https://doi.org/10.1038/s41467-021-23073-4\">10.1038/s41467-021-23073-4</a>.","ista":"Miles E, McCarthy M, Dehecq A, Kneib M, Fugger S, Pellicciotti F. 2021. Health and sustainability of glaciers in High Mountain Asia. Nature Communications. 12, 2868.","ieee":"E. Miles, M. McCarthy, A. Dehecq, M. Kneib, S. Fugger, and F. Pellicciotti, “Health and sustainability of glaciers in High Mountain Asia,” <i>Nature Communications</i>, vol. 12. Springer Nature, 2021.","chicago":"Miles, Evan, Michael McCarthy, Amaury Dehecq, Marin Kneib, Stefan Fugger, and Francesca Pellicciotti. “Health and Sustainability of Glaciers in High Mountain Asia.” <i>Nature Communications</i>. Springer Nature, 2021. <a href=\"https://doi.org/10.1038/s41467-021-23073-4\">https://doi.org/10.1038/s41467-021-23073-4</a>.","apa":"Miles, E., McCarthy, M., Dehecq, A., Kneib, M., Fugger, S., &#38; Pellicciotti, F. (2021). Health and sustainability of glaciers in High Mountain Asia. <i>Nature Communications</i>. Springer Nature. <a href=\"https://doi.org/10.1038/s41467-021-23073-4\">https://doi.org/10.1038/s41467-021-23073-4</a>","ama":"Miles E, McCarthy M, Dehecq A, Kneib M, Fugger S, Pellicciotti F. Health and sustainability of glaciers in High Mountain Asia. <i>Nature Communications</i>. 2021;12. doi:<a href=\"https://doi.org/10.1038/s41467-021-23073-4\">10.1038/s41467-021-23073-4</a>","short":"E. Miles, M. McCarthy, A. Dehecq, M. Kneib, S. Fugger, F. Pellicciotti, Nature Communications 12 (2021)."},"title":"Health and sustainability of glaciers in High Mountain Asia","language":[{"iso":"eng"}],"keyword":["General Physics and Astronomy","General Biochemistry","Genetics and Molecular Biology","General Chemistry","Multidisciplinary"],"doi":"10.1038/s41467-021-23073-4","article_number":"2868","date_published":"2021-05-17T00:00:00Z","_id":"12585","abstract":[{"text":"Glaciers in High Mountain Asia generate meltwater that supports the water needs of 250 million people, but current knowledge of annual accumulation and ablation is limited to sparse field measurements biased in location and glacier size. Here, we present altitudinally-resolved specific mass balances (surface, internal, and basal combined) for 5527 glaciers in High Mountain Asia for 2000–2016, derived by correcting observed glacier thinning patterns for mass redistribution due to ice flow. We find that 41% of glaciers accumulated mass over less than 20% of their area, and only 60% ± 10% of regional annual ablation was compensated by accumulation. Even without 21st century warming, 21% ± 1% of ice volume will be lost by 2100 due to current climatic-geometric imbalance, representing a reduction in glacier ablation into rivers of 28% ± 1%. The ablation of glaciers in the Himalayas and Tien Shan was mostly unsustainable and ice volume in these regions will reduce by at least 30% by 2100. The most important and vulnerable glacier-fed river basins (Amu Darya, Indus, Syr Darya, Tarim Interior) were supplied with >50% sustainable glacier ablation but will see long-term reductions in ice mass and glacier meltwater supply regardless of the Karakoram Anomaly.","lang":"eng"}],"article_processing_charge":"No","volume":12,"publication_status":"published","oa":1,"main_file_link":[{"open_access":"1","url":"https://doi.org/10.1038/s41467-021-23073-4"}],"article_type":"original","year":"2021","oa_version":"Published Version","date_updated":"2023-02-28T13:21:51Z","user_id":"2DF688A6-F248-11E8-B48F-1D18A9856A87","scopus_import":"1","publication_identifier":{"issn":["2041-1723"]}},{"day":"18","author":[{"first_name":"David H","full_name":"Vandael, David H","last_name":"Vandael","orcid":"0000-0001-7577-1676","id":"3AE48E0A-F248-11E8-B48F-1D18A9856A87"},{"orcid":"0000-0003-0408-6094","id":"3337E116-F248-11E8-B48F-1D18A9856A87","first_name":"Yuji","full_name":"Okamoto, Yuji","last_name":"Okamoto"},{"last_name":"Jonas","first_name":"Peter M","full_name":"Jonas, Peter M","id":"353C1B58-F248-11E8-B48F-1D18A9856A87","orcid":"0000-0001-5001-4804"}],"type":"journal_article","ec_funded":1,"citation":{"ista":"Vandael DH, Okamoto Y, Jonas PM. 2021. Transsynaptic modulation of presynaptic short-term plasticity in hippocampal mossy fiber synapses. Nature Communications. 12(1), 2912.","ieee":"D. H. Vandael, Y. Okamoto, and P. M. Jonas, “Transsynaptic modulation of presynaptic short-term plasticity in hippocampal mossy fiber synapses,” <i>Nature Communications</i>, vol. 12, no. 1. Springer, 2021.","chicago":"Vandael, David H, Yuji Okamoto, and Peter M Jonas. “Transsynaptic Modulation of Presynaptic Short-Term Plasticity in Hippocampal Mossy Fiber Synapses.” <i>Nature Communications</i>. Springer, 2021. <a href=\"https://doi.org/10.1038/s41467-021-23153-5\">https://doi.org/10.1038/s41467-021-23153-5</a>.","mla":"Vandael, David H., et al. “Transsynaptic Modulation of Presynaptic Short-Term Plasticity in Hippocampal Mossy Fiber Synapses.” <i>Nature Communications</i>, vol. 12, no. 1, 2912, Springer, 2021, doi:<a href=\"https://doi.org/10.1038/s41467-021-23153-5\">10.1038/s41467-021-23153-5</a>.","short":"D.H. Vandael, Y. Okamoto, P.M. Jonas, Nature Communications 12 (2021).","apa":"Vandael, D. H., Okamoto, Y., &#38; Jonas, P. M. (2021). Transsynaptic modulation of presynaptic short-term plasticity in hippocampal mossy fiber synapses. <i>Nature Communications</i>. Springer. <a href=\"https://doi.org/10.1038/s41467-021-23153-5\">https://doi.org/10.1038/s41467-021-23153-5</a>","ama":"Vandael DH, Okamoto Y, Jonas PM. Transsynaptic modulation of presynaptic short-term plasticity in hippocampal mossy fiber synapses. <i>Nature Communications</i>. 2021;12(1). doi:<a href=\"https://doi.org/10.1038/s41467-021-23153-5\">10.1038/s41467-021-23153-5</a>"},"title":"Transsynaptic modulation of presynaptic short-term plasticity in hippocampal mossy fiber synapses","language":[{"iso":"eng"}],"keyword":["general physics and astronomy","general biochemistry","genetics and molecular biology","general chemistry"],"ddc":["570"],"doi":"10.1038/s41467-021-23153-5","acknowledgement":"We thank Drs. Carolina Borges-Merjane and Jose Guzman for critically reading the manuscript, and Pablo Castillo for discussions. We are grateful to Alois Schlögl for help with analysis, Florian Marr for excellent technical assistance and cell reconstruction, Christina Altmutter for technical help, Eleftheria Kralli-Beller for manuscript editing, and the Scientific Service Units of IST Austria for support. This project received funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation program (grant agreement No 692692) and the Fond zur Förderung der Wissenschaftlichen Forschung (Z 312-B27, Wittgenstein award), both to P.J.","related_material":{"link":[{"relation":"press_release","url":"https://ist.ac.at/en/news/synaptic-transmission-not-a-one-way-street/","description":"News on IST Homepage"}]},"project":[{"grant_number":"692692","name":"Biophysics and circuit function of a giant cortical glumatergic synapse","call_identifier":"H2020","_id":"25B7EB9E-B435-11E9-9278-68D0E5697425"},{"grant_number":"Z00312","name":"The Wittgenstein Prize","_id":"25C5A090-B435-11E9-9278-68D0E5697425","call_identifier":"FWF"}],"month":"05","date_created":"2021-08-06T07:22:55Z","quality_controlled":"1","department":[{"_id":"PeJo"}],"publication":"Nature Communications","status":"public","intvolume":"        12","publisher":"Springer","isi":1,"article_type":"original","year":"2021","has_accepted_license":"1","oa_version":"Published Version","user_id":"4359f0d1-fa6c-11eb-b949-802e58b17ae8","date_updated":"2023-08-10T14:16:16Z","external_id":{"isi":["000655481800014"]},"scopus_import":"1","acknowledged_ssus":[{"_id":"SSU"}],"publication_identifier":{"issn":["2041-1723"]},"article_number":"2912","file":[{"file_id":"10563","relation":"main_file","content_type":"application/pdf","success":1,"date_created":"2021-12-17T11:34:50Z","creator":"kschuh","file_size":3108845,"file_name":"2021_NatureCommunications_Vandael.pdf","access_level":"open_access","date_updated":"2021-12-17T11:34:50Z","checksum":"6036a8cdae95e1707c2a04d54e325ff4"}],"date_published":"2021-05-18T00:00:00Z","_id":"9778","abstract":[{"lang":"eng","text":"The hippocampal mossy fiber synapse is a key synapse of the trisynaptic circuit. Post-tetanic potentiation (PTP) is the most powerful form of plasticity at this synaptic connection. It is widely believed that mossy fiber PTP is an entirely presynaptic phenomenon, implying that PTP induction is input-specific, and requires neither activity of multiple inputs nor stimulation of postsynaptic neurons. To directly test cooperativity and associativity, we made paired recordings between single mossy fiber terminals and postsynaptic CA3 pyramidal neurons in rat brain slices. By stimulating non-overlapping mossy fiber inputs converging onto single CA3 neurons, we confirm that PTP is input-specific and non-cooperative. Unexpectedly, mossy fiber PTP exhibits anti-associative induction properties. EPSCs show only minimal PTP after combined pre- and postsynaptic high-frequency stimulation with intact postsynaptic Ca2+ signaling, but marked PTP in the absence of postsynaptic spiking and after suppression of postsynaptic Ca2+ signaling (10 mM EGTA). PTP is largely recovered by inhibitors of voltage-gated R- and L-type Ca2+ channels, group II mGluRs, and vacuolar-type H+-ATPase, suggesting the involvement of retrograde vesicular glutamate signaling. Transsynaptic regulation of PTP extends the repertoire of synaptic computations, implementing a brake on mossy fiber detonation and a “smart teacher” function of hippocampal mossy fiber synapses."}],"issue":"1","article_processing_charge":"No","file_date_updated":"2021-12-17T11:34:50Z","volume":12,"tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)","image":"/images/cc_by.png","short":"CC BY (4.0)"},"publication_status":"published","oa":1},{"extern":"1","month":"09","date_created":"2022-04-07T07:43:48Z","quality_controlled":"1","publication":"eLife","status":"public","intvolume":"         9","publisher":"eLife Sciences Publications","day":"08","type":"journal_article","author":[{"full_name":"Bersini, Simone","first_name":"Simone","last_name":"Bersini"},{"last_name":"Schulte","first_name":"Roberta","full_name":"Schulte, Roberta"},{"last_name":"Huang","full_name":"Huang, Ling","first_name":"Ling"},{"last_name":"Tsai","first_name":"Hannah","full_name":"Tsai, Hannah"},{"id":"86c0d31b-b4eb-11ec-ac5a-eae7b2e135ed","orcid":"0000-0002-2111-992X","full_name":"HETZER, Martin W","first_name":"Martin W","last_name":"HETZER"}],"citation":{"mla":"Bersini, Simone, et al. “Direct Reprogramming of Human Smooth Muscle and Vascular Endothelial Cells Reveals Defects Associated with Aging and Hutchinson-Gilford Progeria Syndrome.” <i>ELife</i>, vol. 9, e54383, eLife Sciences Publications, 2020, doi:<a href=\"https://doi.org/10.7554/elife.54383\">10.7554/elife.54383</a>.","chicago":"Bersini, Simone, Roberta Schulte, Ling Huang, Hannah Tsai, and Martin Hetzer. “Direct Reprogramming of Human Smooth Muscle and Vascular Endothelial Cells Reveals Defects Associated with Aging and Hutchinson-Gilford Progeria Syndrome.” <i>ELife</i>. eLife Sciences Publications, 2020. <a href=\"https://doi.org/10.7554/elife.54383\">https://doi.org/10.7554/elife.54383</a>.","ista":"Bersini S, Schulte R, Huang L, Tsai H, Hetzer M. 2020. Direct reprogramming of human smooth muscle and vascular endothelial cells reveals defects associated with aging and Hutchinson-Gilford progeria syndrome. eLife. 9, e54383.","ieee":"S. Bersini, R. Schulte, L. Huang, H. Tsai, and M. Hetzer, “Direct reprogramming of human smooth muscle and vascular endothelial cells reveals defects associated with aging and Hutchinson-Gilford progeria syndrome,” <i>eLife</i>, vol. 9. eLife Sciences Publications, 2020.","ama":"Bersini S, Schulte R, Huang L, Tsai H, Hetzer M. Direct reprogramming of human smooth muscle and vascular endothelial cells reveals defects associated with aging and Hutchinson-Gilford progeria syndrome. <i>eLife</i>. 2020;9. doi:<a href=\"https://doi.org/10.7554/elife.54383\">10.7554/elife.54383</a>","apa":"Bersini, S., Schulte, R., Huang, L., Tsai, H., &#38; Hetzer, M. (2020). Direct reprogramming of human smooth muscle and vascular endothelial cells reveals defects associated with aging and Hutchinson-Gilford progeria syndrome. <i>ELife</i>. eLife Sciences Publications. <a href=\"https://doi.org/10.7554/elife.54383\">https://doi.org/10.7554/elife.54383</a>","short":"S. Bersini, R. Schulte, L. Huang, H. Tsai, M. Hetzer, ELife 9 (2020)."},"title":"Direct reprogramming of human smooth muscle and vascular endothelial cells reveals defects associated with aging and Hutchinson-Gilford progeria syndrome","language":[{"iso":"eng"}],"keyword":["General Immunology and Microbiology","General Biochemistry","Genetics and Molecular Biology","General Medicine","General Neuroscience"],"ddc":["570"],"doi":"10.7554/elife.54383","pmid":1,"article_number":"e54383","file":[{"file_name":"2020_eLife_Bersini.pdf","file_size":4399825,"creator":"dernst","checksum":"f8b3821349a194050be02570d8fe7d4b","date_updated":"2022-04-08T06:53:10Z","access_level":"open_access","content_type":"application/pdf","file_id":"11132","relation":"main_file","date_created":"2022-04-08T06:53:10Z","success":1}],"abstract":[{"text":"Vascular dysfunctions are a common feature of multiple age-related diseases. However, modeling healthy and pathological aging of the human vasculature represents an unresolved experimental challenge. Here, we generated induced vascular endothelial cells (iVECs) and smooth muscle cells (iSMCs) by direct reprogramming of healthy human fibroblasts from donors of different ages and Hutchinson-Gilford Progeria Syndrome (HGPS) patients. iVECs induced from old donors revealed upregulation of GSTM1 and PALD1, genes linked to oxidative stress, inflammation and endothelial junction stability, as vascular aging markers. A functional assay performed on PALD1 KD VECs demonstrated a recovery in vascular permeability. We found that iSMCs from HGPS donors overexpressed bone morphogenetic protein (BMP)−4, which plays a key role in both vascular calcification and endothelial barrier damage observed in HGPS. Strikingly, BMP4 concentrations are higher in serum from HGPS vs. age-matched mice. Furthermore, targeting BMP4 with blocking antibody recovered the functionality of the vascular barrier in vitro, hence representing a potential future therapeutic strategy to limit cardiovascular dysfunction in HGPS. These results show that iVECs and iSMCs retain disease-related signatures, allowing modeling of vascular aging and HGPS in vitro.","lang":"eng"}],"_id":"11055","date_published":"2020-09-08T00:00:00Z","article_processing_charge":"No","file_date_updated":"2022-04-08T06:53:10Z","volume":9,"tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)","image":"/images/cc_by.png","short":"CC BY (4.0)"},"publication_status":"published","oa":1,"article_type":"original","year":"2020","oa_version":"Published Version","has_accepted_license":"1","user_id":"72615eeb-f1f3-11ec-aa25-d4573ddc34fd","date_updated":"2022-07-18T08:30:37Z","scopus_import":"1","external_id":{"pmid":["32896271"]},"publication_identifier":{"issn":["2050-084X"]}},{"publication_identifier":{"issn":["2366-7478","2366-7478"]},"user_id":"72615eeb-f1f3-11ec-aa25-d4573ddc34fd","date_updated":"2022-07-18T08:30:48Z","external_id":{"pmid":["32402127"]},"scopus_import":"1","oa_version":"Published Version","year":"2020","has_accepted_license":"1","article_type":"original","oa":1,"publication_status":"published","volume":4,"tmp":{"name":"Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International (CC BY-NC-ND 4.0)","image":"/images/cc_by_nc_nd.png","legal_code_url":"https://creativecommons.org/licenses/by-nc-nd/4.0/legalcode","short":"CC BY-NC-ND (4.0)"},"file_date_updated":"2022-04-08T07:06:05Z","issue":"5","article_processing_charge":"No","_id":"11056","abstract":[{"lang":"eng","text":"Aging of the circulatory system correlates with the pathogenesis of a large spectrum of diseases. However, it is largely unknown which factors drive the age-dependent or pathological decline of the vasculature and how vascular defects relate to tissue aging. The goal of the study is to design a multianalytical approach to identify how the cellular microenvironment (i.e., fibroblasts) and serum from healthy donors of different ages or Alzheimer disease (AD) patients can modulate the functionality of organ-specific vascular endothelial cells (VECs). Long-living human microvascular networks embedding VECs and fibroblasts from skin biopsies are generated. RNA-seq, secretome analyses, and microfluidic assays demonstrate that fibroblasts from young donors restore the functionality of aged endothelial cells, an effect also achieved by serum from young donors. New biomarkers of vascular aging are validated in human biopsies and it is shown that young serum induces angiopoietin-like-4, which can restore compromised vascular barriers. This strategy is then employed to characterize transcriptional/functional changes induced on the blood–brain barrier by AD serum, demonstrating the importance of PTP4A3 in the regulation of permeability. Features of vascular degeneration during aging and AD are recapitulated, and a tool to identify novel biomarkers that can be exploited to develop future therapeutics modulating vascular function is established."}],"date_published":"2020-05-01T00:00:00Z","file":[{"relation":"main_file","file_id":"11134","content_type":"application/pdf","success":1,"date_created":"2022-04-08T07:06:05Z","creator":"dernst","file_size":2490829,"file_name":"2020_AdvancedBiosystems_Bersini.pdf","access_level":"open_access","date_updated":"2022-04-08T07:06:05Z","checksum":"5584d9a1609812dc75c02ce1e35d2ec0"}],"article_number":"2000044","pmid":1,"ddc":["570"],"doi":"10.1002/adbi.202000044","language":[{"iso":"eng"}],"keyword":["General Biochemistry","Genetics and Molecular Biology","Biomedical Engineering","Biomaterials"],"title":"Transcriptional and functional changes of the human microvasculature during physiological aging and Alzheimer disease","citation":{"short":"S. Bersini, R. Arrojo e Drigo, L. Huang, M.N. Shokhirev, M. Hetzer, Advanced Biosystems 4 (2020).","ama":"Bersini S, Arrojo e Drigo R, Huang L, Shokhirev MN, Hetzer M. Transcriptional and functional changes of the human microvasculature during physiological aging and Alzheimer disease. <i>Advanced Biosystems</i>. 2020;4(5). doi:<a href=\"https://doi.org/10.1002/adbi.202000044\">10.1002/adbi.202000044</a>","apa":"Bersini, S., Arrojo e Drigo, R., Huang, L., Shokhirev, M. N., &#38; Hetzer, M. (2020). Transcriptional and functional changes of the human microvasculature during physiological aging and Alzheimer disease. <i>Advanced Biosystems</i>. Wiley. <a href=\"https://doi.org/10.1002/adbi.202000044\">https://doi.org/10.1002/adbi.202000044</a>","chicago":"Bersini, Simone, Rafael Arrojo e Drigo, Ling Huang, Maxim N. Shokhirev, and Martin Hetzer. “Transcriptional and Functional Changes of the Human Microvasculature during Physiological Aging and Alzheimer Disease.” <i>Advanced Biosystems</i>. Wiley, 2020. <a href=\"https://doi.org/10.1002/adbi.202000044\">https://doi.org/10.1002/adbi.202000044</a>.","ieee":"S. Bersini, R. Arrojo e Drigo, L. Huang, M. N. Shokhirev, and M. Hetzer, “Transcriptional and functional changes of the human microvasculature during physiological aging and Alzheimer disease,” <i>Advanced Biosystems</i>, vol. 4, no. 5. Wiley, 2020.","ista":"Bersini S, Arrojo e Drigo R, Huang L, Shokhirev MN, Hetzer M. 2020. Transcriptional and functional changes of the human microvasculature during physiological aging and Alzheimer disease. Advanced Biosystems. 4(5), 2000044.","mla":"Bersini, Simone, et al. “Transcriptional and Functional Changes of the Human Microvasculature during Physiological Aging and Alzheimer Disease.” <i>Advanced Biosystems</i>, vol. 4, no. 5, 2000044, Wiley, 2020, doi:<a href=\"https://doi.org/10.1002/adbi.202000044\">10.1002/adbi.202000044</a>."},"type":"journal_article","author":[{"last_name":"Bersini","full_name":"Bersini, Simone","first_name":"Simone"},{"last_name":"Arrojo e Drigo","full_name":"Arrojo e Drigo, Rafael","first_name":"Rafael"},{"last_name":"Huang","full_name":"Huang, Ling","first_name":"Ling"},{"last_name":"Shokhirev","full_name":"Shokhirev, Maxim N.","first_name":"Maxim N."},{"full_name":"HETZER, Martin W","first_name":"Martin W","last_name":"HETZER","id":"86c0d31b-b4eb-11ec-ac5a-eae7b2e135ed","orcid":"0000-0002-2111-992X"}],"day":"01","publisher":"Wiley","intvolume":"         4","status":"public","quality_controlled":"1","publication":"Advanced Biosystems","date_created":"2022-04-07T07:43:57Z","extern":"1","month":"05"},{"article_type":"original","oa_version":"Published Version","year":"2020","has_accepted_license":"1","external_id":{"pmid":["31959624"]},"scopus_import":"1","user_id":"72615eeb-f1f3-11ec-aa25-d4573ddc34fd","date_updated":"2022-07-18T08:31:20Z","publication_identifier":{"issn":["2575-1077"]},"article_processing_charge":"No","issue":"1","article_number":"e201900623","file":[{"checksum":"3bf33e7e93bef7823287807206b69b38","access_level":"open_access","date_updated":"2022-04-08T07:33:01Z","file_size":2653960,"creator":"dernst","file_name":"2020_LifeScienceAlliance_Bersini.pdf","date_created":"2022-04-08T07:33:01Z","success":1,"relation":"main_file","file_id":"11137","content_type":"application/pdf"}],"_id":"11058","abstract":[{"text":"Nucleoporin 93 (Nup93) expression inversely correlates with the survival of triple-negative breast cancer patients. However, our knowledge of Nup93 function in breast cancer besides its role as structural component of the nuclear pore complex is not understood. Combination of functional assays and genetic analyses suggested that chromatin interaction of Nup93 partially modulates the expression of genes associated with actin cytoskeleton remodeling and epithelial to mesenchymal transition, resulting in impaired invasion of triple-negative, claudin-low breast cancer cells. Nup93 depletion induced stress fiber formation associated with reduced cell migration/proliferation and impaired expression of mesenchymal-like genes. Silencing LIMCH1, a gene responsible for actin cytoskeleton remodeling and up-regulated upon Nup93 depletion, partially restored the invasive phenotype of cancer cells. Loss of Nup93 led to significant defects in tumor establishment/propagation in vivo, whereas patient samples revealed that high Nup93 and low LIMCH1 expression correlate with late tumor stage. Our approach identified Nup93 as contributor of triple-negative, claudin-low breast cancer cell invasion and paves the way to study the role of nuclear envelope proteins during breast cancer tumorigenesis.","lang":"eng"}],"date_published":"2020-01-01T00:00:00Z","publication_status":"published","oa":1,"file_date_updated":"2022-04-08T07:33:01Z","tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)","image":"/images/cc_by.png","short":"CC BY (4.0)"},"volume":3,"citation":{"mla":"Bersini, Simone, et al. “Nup93 Regulates Breast Tumor Growth by Modulating Cell Proliferation and Actin Cytoskeleton Remodeling.” <i>Life Science Alliance</i>, vol. 3, no. 1, e201900623, Life Science Alliance, 2020, doi:<a href=\"https://doi.org/10.26508/lsa.201900623\">10.26508/lsa.201900623</a>.","chicago":"Bersini, Simone, Nikki K Lytle, Roberta Schulte, Ling Huang, Geoffrey M Wahl, and Martin Hetzer. “Nup93 Regulates Breast Tumor Growth by Modulating Cell Proliferation and Actin Cytoskeleton Remodeling.” <i>Life Science Alliance</i>. Life Science Alliance, 2020. <a href=\"https://doi.org/10.26508/lsa.201900623\">https://doi.org/10.26508/lsa.201900623</a>.","ieee":"S. Bersini, N. K. Lytle, R. Schulte, L. Huang, G. M. Wahl, and M. Hetzer, “Nup93 regulates breast tumor growth by modulating cell proliferation and actin cytoskeleton remodeling,” <i>Life Science Alliance</i>, vol. 3, no. 1. Life Science Alliance, 2020.","ista":"Bersini S, Lytle NK, Schulte R, Huang L, Wahl GM, Hetzer M. 2020. Nup93 regulates breast tumor growth by modulating cell proliferation and actin cytoskeleton remodeling. Life Science Alliance. 3(1), e201900623.","ama":"Bersini S, Lytle NK, Schulte R, Huang L, Wahl GM, Hetzer M. Nup93 regulates breast tumor growth by modulating cell proliferation and actin cytoskeleton remodeling. <i>Life Science Alliance</i>. 2020;3(1). doi:<a href=\"https://doi.org/10.26508/lsa.201900623\">10.26508/lsa.201900623</a>","apa":"Bersini, S., Lytle, N. K., Schulte, R., Huang, L., Wahl, G. M., &#38; Hetzer, M. (2020). Nup93 regulates breast tumor growth by modulating cell proliferation and actin cytoskeleton remodeling. <i>Life Science Alliance</i>. Life Science Alliance. <a href=\"https://doi.org/10.26508/lsa.201900623\">https://doi.org/10.26508/lsa.201900623</a>","short":"S. Bersini, N.K. Lytle, R. Schulte, L. Huang, G.M. Wahl, M. Hetzer, Life Science Alliance 3 (2020)."},"title":"Nup93 regulates breast tumor growth by modulating cell proliferation and actin cytoskeleton remodeling","day":"01","author":[{"last_name":"Bersini","first_name":"Simone","full_name":"Bersini, Simone"},{"full_name":"Lytle, Nikki K","first_name":"Nikki K","last_name":"Lytle"},{"last_name":"Schulte","full_name":"Schulte, Roberta","first_name":"Roberta"},{"last_name":"Huang","first_name":"Ling","full_name":"Huang, Ling"},{"first_name":"Geoffrey M","full_name":"Wahl, Geoffrey M","last_name":"Wahl"},{"first_name":"Martin W","full_name":"HETZER, Martin W","last_name":"HETZER","id":"86c0d31b-b4eb-11ec-ac5a-eae7b2e135ed","orcid":"0000-0002-2111-992X"}],"type":"journal_article","pmid":1,"keyword":["Health","Toxicology and Mutagenesis","Plant Science","Biochemistry","Genetics and Molecular Biology (miscellaneous)","Ecology"],"language":[{"iso":"eng"}],"doi":"10.26508/lsa.201900623","ddc":["570"],"month":"01","extern":"1","date_created":"2022-04-07T07:44:18Z","publisher":"Life Science Alliance","publication":"Life Science Alliance","quality_controlled":"1","intvolume":"         3","status":"public"},{"month":"01","extern":"1","date_created":"2020-09-17T10:26:53Z","publisher":"Springer Nature","publication":"BMC Biology","quality_controlled":"1","intvolume":"        18","status":"public","citation":{"mla":"Rampelt, Heike, et al. “The Mitochondrial Carrier Pathway Transports Non-Canonical Substrates with an Odd Number of Transmembrane Segments.” <i>BMC Biology</i>, vol. 18, 2, Springer Nature, 2020, doi:<a href=\"https://doi.org/10.1186/s12915-019-0733-6\">10.1186/s12915-019-0733-6</a>.","chicago":"Rampelt, Heike, Iva Sucec, Beate Bersch, Patrick Horten, Inge Perschil, Jean-Claude Martinou, Martin van der Laan, Nils Wiedemann, Paul Schanda, and Nikolaus Pfanner. “The Mitochondrial Carrier Pathway Transports Non-Canonical Substrates with an Odd Number of Transmembrane Segments.” <i>BMC Biology</i>. Springer Nature, 2020. <a href=\"https://doi.org/10.1186/s12915-019-0733-6\">https://doi.org/10.1186/s12915-019-0733-6</a>.","ieee":"H. Rampelt <i>et al.</i>, “The mitochondrial carrier pathway transports non-canonical substrates with an odd number of transmembrane segments,” <i>BMC Biology</i>, vol. 18. Springer Nature, 2020.","ista":"Rampelt H, Sucec I, Bersch B, Horten P, Perschil I, Martinou J-C, van der Laan M, Wiedemann N, Schanda P, Pfanner N. 2020. The mitochondrial carrier pathway transports non-canonical substrates with an odd number of transmembrane segments. BMC Biology. 18, 2.","ama":"Rampelt H, Sucec I, Bersch B, et al. The mitochondrial carrier pathway transports non-canonical substrates with an odd number of transmembrane segments. <i>BMC Biology</i>. 2020;18. doi:<a href=\"https://doi.org/10.1186/s12915-019-0733-6\">10.1186/s12915-019-0733-6</a>","apa":"Rampelt, H., Sucec, I., Bersch, B., Horten, P., Perschil, I., Martinou, J.-C., … Pfanner, N. (2020). The mitochondrial carrier pathway transports non-canonical substrates with an odd number of transmembrane segments. <i>BMC Biology</i>. Springer Nature. <a href=\"https://doi.org/10.1186/s12915-019-0733-6\">https://doi.org/10.1186/s12915-019-0733-6</a>","short":"H. Rampelt, I. Sucec, B. Bersch, P. Horten, I. Perschil, J.-C. Martinou, M. van der Laan, N. Wiedemann, P. Schanda, N. Pfanner, BMC Biology 18 (2020)."},"title":"The mitochondrial carrier pathway transports non-canonical substrates with an odd number of transmembrane segments","day":"06","type":"journal_article","author":[{"last_name":"Rampelt","first_name":"Heike","full_name":"Rampelt, Heike"},{"last_name":"Sucec","first_name":"Iva","full_name":"Sucec, Iva"},{"full_name":"Bersch, Beate","first_name":"Beate","last_name":"Bersch"},{"last_name":"Horten","first_name":"Patrick","full_name":"Horten, Patrick"},{"last_name":"Perschil","first_name":"Inge","full_name":"Perschil, Inge"},{"first_name":"Jean-Claude","full_name":"Martinou, Jean-Claude","last_name":"Martinou"},{"first_name":"Martin","full_name":"van der Laan, Martin","last_name":"van der Laan"},{"last_name":"Wiedemann","first_name":"Nils","full_name":"Wiedemann, Nils"},{"last_name":"Schanda","full_name":"Schanda, Paul","first_name":"Paul","orcid":"0000-0002-9350-7606","id":"7B541462-FAF6-11E9-A490-E8DFE5697425"},{"full_name":"Pfanner, Nikolaus","first_name":"Nikolaus","last_name":"Pfanner"}],"pmid":1,"keyword":["Biotechnology","Plant Science","General Biochemistry","Genetics and Molecular Biology","Developmental Biology","Cell Biology","Physiology","Ecology","Evolution","Behavior and Systematics","Structural Biology","General Agricultural and Biological Sciences"],"language":[{"iso":"eng"}],"doi":"10.1186/s12915-019-0733-6","article_processing_charge":"No","article_number":"2","_id":"8402","abstract":[{"lang":"eng","text":"Background: The mitochondrial pyruvate carrier (MPC) plays a central role in energy metabolism by transporting pyruvate across the inner mitochondrial membrane. Its heterodimeric composition and homology to SWEET and semiSWEET transporters set the MPC apart from the canonical mitochondrial carrier family (named MCF or SLC25). The import of the canonical carriers is mediated by the carrier translocase of the inner membrane (TIM22) pathway and is dependent on their structure, which features an even number of transmembrane segments and both termini in the intermembrane space. The import pathway of MPC proteins has not been elucidated. The odd number of transmembrane segments and positioning of the N-terminus in the matrix argues against an import via the TIM22 carrier pathway but favors an import via the flexible presequence pathway.\r\nResults: Here, we systematically analyzed the import pathways of Mpc2 and Mpc3 and report that, contrary to an expected import via the flexible presequence pathway, yeast MPC proteins with an odd number of transmembrane segments and matrix-exposed N-terminus are imported by the carrier pathway, using the receptor Tom70, small TIM chaperones, and the TIM22 complex. The TIM9·10 complex chaperones MPC proteins through the mitochondrial intermembrane space using conserved hydrophobic motifs that are also required for the interaction with canonical carrier proteins.\r\nConclusions: The carrier pathway can import paired and non-paired transmembrane helices and translocate N-termini to either side of the mitochondrial inner membrane, revealing an unexpected versatility of the mitochondrial import pathway for non-cleavable inner membrane proteins."}],"date_published":"2020-01-06T00:00:00Z","publication_status":"published","oa":1,"main_file_link":[{"open_access":"1","url":"https://doi.org/10.1186/s12915-019-0733-6"}],"volume":18,"article_type":"original","year":"2020","oa_version":"Published Version","external_id":{"pmid":["31907035"]},"date_updated":"2021-01-12T08:19:02Z","user_id":"2DF688A6-F248-11E8-B48F-1D18A9856A87","publication_identifier":{"issn":["1741-7007"]}},{"external_id":{"isi":["000577280200001"]},"date_updated":"2024-08-07T07:11:51Z","user_id":"4359f0d1-fa6c-11eb-b949-802e58b17ae8","publication_identifier":{"issn":["2041-1723"]},"acknowledged_ssus":[{"_id":"NanoFab"}],"article_type":"original","year":"2020","has_accepted_license":"1","oa_version":"Published Version","publication_status":"published","oa":1,"file_date_updated":"2020-09-18T13:02:37Z","tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)","image":"/images/cc_by.png","short":"CC BY (4.0)"},"volume":11,"article_processing_charge":"No","file":[{"date_created":"2020-09-18T13:02:37Z","success":1,"content_type":"application/pdf","relation":"main_file","file_id":"8530","checksum":"88f92544889eb18bb38e25629a422a86","date_updated":"2020-09-18T13:02:37Z","access_level":"open_access","file_name":"2020_NatureComm_Arnold.pdf","creator":"dernst","file_size":1002818}],"article_number":"4460","_id":"8529","date_published":"2020-09-08T00:00:00Z","abstract":[{"text":"Practical quantum networks require low-loss and noise-resilient optical interconnects as well as non-Gaussian resources for entanglement distillation and distributed quantum computation. The latter could be provided by superconducting circuits but existing solutions to interface the microwave and optical domains lack either scalability or efficiency, and in most cases the conversion noise is not known. In this work we utilize the unique opportunities of silicon photonics, cavity optomechanics and superconducting circuits to demonstrate a fully integrated, coherent transducer interfacing the microwave X and the telecom S bands with a total (internal) bidirectional transduction efficiency of 1.2% (135%) at millikelvin temperatures. The coupling relies solely on the radiation pressure interaction mediated by the femtometer-scale motion of two silicon nanobeams reaching a <jats:italic>V</jats:italic><jats:sub><jats:italic>π</jats:italic></jats:sub> as low as 16 μV for sub-nanowatt pump powers. Without the associated optomechanical gain, we achieve a total (internal) pure conversion efficiency of up to 0.019% (1.6%), relevant for future noise-free operation on this qubit-compatible platform.","lang":"eng"}],"project":[{"name":"Hybrid Optomechanical Technologies","grant_number":"732894","_id":"257EB838-B435-11E9-9278-68D0E5697425","call_identifier":"H2020"},{"name":"A Fiber Optic Transceiver for Superconducting Qubits","grant_number":"758053","_id":"26336814-B435-11E9-9278-68D0E5697425","call_identifier":"H2020"},{"name":"ISTplus - Postdoctoral Fellowships","grant_number":"754411","call_identifier":"H2020","_id":"260C2330-B435-11E9-9278-68D0E5697425"},{"_id":"237CBA6C-32DE-11EA-91FC-C7463DDC885E","call_identifier":"H2020","name":"Quantum readout techniques and technologies","grant_number":"862644"},{"name":"Coherent on-chip conversion of superconducting qubit signals from microwaves to optical frequencies","_id":"2671EB66-B435-11E9-9278-68D0E5697425"}],"related_material":{"record":[{"status":"public","id":"13056","relation":"research_data"}],"link":[{"url":"https://doi.org/10.1038/s41467-020-18912-9","relation":"erratum"},{"relation":"press_release","description":"News on IST Homepage","url":"https://ist.ac.at/en/news/how-to-transport-microwave-quantum-information-via-optical-fiber/"}]},"acknowledgement":"We thank Yuan Chen for performing supplementary FEM simulations and Andrew Higginbotham, Ralf Riedinger, Sungkun Hong, and Lorenzo Magrini for valuable discussions. This work was supported by IST Austria, the IST nanofabrication facility (NFF), the European Union’s Horizon 2020 research and innovation program under grant agreement no. 732894 (FET Proactive HOT) and the European Research Council under grant agreement no. 758053 (ERC StG QUNNECT). G.A. is the recipient of a DOC fellowship of the Austrian Academy of Sciences at IST Austria. W.H. is the recipient of an ISTplus postdoctoral fellowship with funding from the European Union’s Horizon 2020 research and innovation program under the Marie Sklodowska-Curie grant agreement no. 754411. J.M.F. acknowledges support from the Austrian Science Fund (FWF) through BeyondC (F71), a NOMIS foundation research grant, and the EU’s Horizon 2020 research and innovation program under grant agreement no. 862644 (FET Open QUARTET).","keyword":["General Biochemistry","Genetics and Molecular Biology","General Physics and Astronomy","General Chemistry"],"language":[{"iso":"eng"}],"ddc":["530"],"doi":"10.1038/s41467-020-18269-z","citation":{"ama":"Arnold GM, Wulf M, Barzanjeh S, et al. Converting microwave and telecom photons with a silicon photonic nanomechanical interface. <i>Nature Communications</i>. 2020;11. doi:<a href=\"https://doi.org/10.1038/s41467-020-18269-z\">10.1038/s41467-020-18269-z</a>","apa":"Arnold, G. M., Wulf, M., Barzanjeh, S., Redchenko, E., Rueda Sanchez, A. R., Hease, W. J., … Fink, J. M. (2020). Converting microwave and telecom photons with a silicon photonic nanomechanical interface. <i>Nature Communications</i>. Springer Nature. <a href=\"https://doi.org/10.1038/s41467-020-18269-z\">https://doi.org/10.1038/s41467-020-18269-z</a>","short":"G.M. Arnold, M. Wulf, S. Barzanjeh, E. Redchenko, A.R. Rueda Sanchez, W.J. Hease, F. Hassani, J.M. Fink, Nature Communications 11 (2020).","mla":"Arnold, Georg M., et al. “Converting Microwave and Telecom Photons with a Silicon Photonic Nanomechanical Interface.” <i>Nature Communications</i>, vol. 11, 4460, Springer Nature, 2020, doi:<a href=\"https://doi.org/10.1038/s41467-020-18269-z\">10.1038/s41467-020-18269-z</a>.","chicago":"Arnold, Georg M, Matthias Wulf, Shabir Barzanjeh, Elena Redchenko, Alfredo R Rueda Sanchez, William J Hease, Farid Hassani, and Johannes M Fink. “Converting Microwave and Telecom Photons with a Silicon Photonic Nanomechanical Interface.” <i>Nature Communications</i>. Springer Nature, 2020. <a href=\"https://doi.org/10.1038/s41467-020-18269-z\">https://doi.org/10.1038/s41467-020-18269-z</a>.","ieee":"G. M. Arnold <i>et al.</i>, “Converting microwave and telecom photons with a silicon photonic nanomechanical interface,” <i>Nature Communications</i>, vol. 11. Springer Nature, 2020.","ista":"Arnold GM, Wulf M, Barzanjeh S, Redchenko E, Rueda Sanchez AR, Hease WJ, Hassani F, Fink JM. 2020. Converting microwave and telecom photons with a silicon photonic nanomechanical interface. Nature Communications. 11, 4460."},"ec_funded":1,"title":"Converting microwave and telecom photons with a silicon photonic nanomechanical interface","day":"08","type":"journal_article","author":[{"first_name":"Georg M","full_name":"Arnold, Georg M","last_name":"Arnold","id":"3770C838-F248-11E8-B48F-1D18A9856A87","orcid":"0000-0003-1397-7876"},{"id":"45598606-F248-11E8-B48F-1D18A9856A87","orcid":"0000-0001-6613-1378","full_name":"Wulf, Matthias","first_name":"Matthias","last_name":"Wulf"},{"id":"2D25E1F6-F248-11E8-B48F-1D18A9856A87","orcid":"0000-0003-0415-1423","full_name":"Barzanjeh, Shabir","first_name":"Shabir","last_name":"Barzanjeh"},{"last_name":"Redchenko","full_name":"Redchenko, Elena","first_name":"Elena","id":"2C21D6E8-F248-11E8-B48F-1D18A9856A87"},{"full_name":"Rueda Sanchez, Alfredo R","first_name":"Alfredo R","last_name":"Rueda Sanchez","id":"3B82B0F8-F248-11E8-B48F-1D18A9856A87","orcid":"0000-0001-6249-5860"},{"last_name":"Hease","full_name":"Hease, William J","first_name":"William J","orcid":"0000-0001-9868-2166","id":"29705398-F248-11E8-B48F-1D18A9856A87"},{"id":"2AED110C-F248-11E8-B48F-1D18A9856A87","orcid":"0000-0001-6937-5773","last_name":"Hassani","full_name":"Hassani, Farid","first_name":"Farid"},{"first_name":"Johannes M","full_name":"Fink, Johannes M","last_name":"Fink","id":"4B591CBA-F248-11E8-B48F-1D18A9856A87","orcid":"0000-0001-8112-028X"}],"publisher":"Springer Nature","isi":1,"publication":"Nature Communications","department":[{"_id":"JoFi"}],"quality_controlled":"1","status":"public","intvolume":"        11","month":"09","date_created":"2020-09-18T10:56:20Z"},{"publication_status":"published","oa":1,"file_date_updated":"2020-09-28T13:16:15Z","tmp":{"legal_code_url":"https://creativecommons.org/licenses/by/4.0/legalcode","name":"Creative Commons Attribution 4.0 International Public License (CC-BY 4.0)","image":"/images/cc_by.png","short":"CC BY (4.0)"},"volume":11,"article_processing_charge":"No","file":[{"checksum":"eada7bc8dd16a49390137cff882ef328","access_level":"open_access","date_updated":"2020-09-28T13:16:15Z","creator":"dernst","file_size":1822469,"file_name":"2020_NatureComm_Prehal.pdf","date_created":"2020-09-28T13:16:15Z","success":1,"relation":"main_file","file_id":"8585","content_type":"application/pdf"}],"article_number":"4838","date_published":"2020-09-24T00:00:00Z","_id":"8568","abstract":[{"text":"Aqueous iodine based electrochemical energy storage is considered a potential candidate to improve sustainability and performance of current battery and supercapacitor technology. It harnesses the redox activity of iodide, iodine, and polyiodide species in the confined geometry of nanoporous carbon electrodes. However, current descriptions of the electrochemical reaction mechanism to interconvert these species are elusive. Here we show that electrochemical oxidation of iodide in nanoporous carbons forms persistent solid iodine deposits. Confinement slows down dissolution into triiodide and pentaiodide, responsible for otherwise significant self-discharge via shuttling. The main tools for these insights are in situ Raman spectroscopy and in situ small and wide-angle X-ray scattering (in situ SAXS/WAXS). In situ Raman confirms the reversible formation of triiodide and pentaiodide. In situ SAXS/WAXS indicates remarkable amounts of solid iodine deposited in the carbon nanopores. Combined with stochastic modeling, in situ SAXS allows quantifying the solid iodine volume fraction and visualizing the iodine structure on 3D lattice models at the sub-nanometer scale. Based on the derived mechanism, we demonstrate strategies for improved iodine pore filling capacity and prevention of self-discharge, applicable to hybrid supercapacitors and batteries.","lang":"eng"}],"external_id":{"isi":["000573756600004"]},"date_updated":"2023-08-22T09:37:24Z","user_id":"4359f0d1-fa6c-11eb-b949-802e58b17ae8","publication_identifier":{"issn":["2041-1723"]},"article_type":"original","has_accepted_license":"1","year":"2020","oa_version":"Published Version","publisher":"Springer Nature","isi":1,"publication":"Nature Communications","department":[{"_id":"StFr"}],"quality_controlled":"1","status":"public","intvolume":"        11","month":"09","date_created":"2020-09-25T07:23:13Z","related_material":{"link":[{"relation":"erratum","url":"https://doi.org/10.1038/s41467-020-19720-x"}]},"keyword":["General Biochemistry","Genetics and Molecular Biology","General Physics and Astronomy","General Chemistry"],"language":[{"iso":"eng"}],"ddc":["530"],"doi":"10.1038/s41467-020-18610-6","citation":{"ama":"Prehal C, Fitzek H, Kothleitner G, et al. Persistent and reversible solid iodine electrodeposition in nanoporous carbons. <i>Nature Communications</i>. 2020;11. doi:<a href=\"https://doi.org/10.1038/s41467-020-18610-6\">10.1038/s41467-020-18610-6</a>","apa":"Prehal, C., Fitzek, H., Kothleitner, G., Presser, V., Gollas, B., Freunberger, S. A., &#38; Abbas, Q. (2020). Persistent and reversible solid iodine electrodeposition in nanoporous carbons. <i>Nature Communications</i>. Springer Nature. <a href=\"https://doi.org/10.1038/s41467-020-18610-6\">https://doi.org/10.1038/s41467-020-18610-6</a>","short":"C. Prehal, H. Fitzek, G. Kothleitner, V. Presser, B. Gollas, S.A. Freunberger, Q. Abbas, Nature Communications 11 (2020).","mla":"Prehal, Christian, et al. “Persistent and Reversible Solid Iodine Electrodeposition in Nanoporous Carbons.” <i>Nature Communications</i>, vol. 11, 4838, Springer Nature, 2020, doi:<a href=\"https://doi.org/10.1038/s41467-020-18610-6\">10.1038/s41467-020-18610-6</a>.","chicago":"Prehal, Christian, Harald Fitzek, Gerald Kothleitner, Volker Presser, Bernhard Gollas, Stefan Alexander Freunberger, and Qamar Abbas. “Persistent and Reversible Solid Iodine Electrodeposition in Nanoporous Carbons.” <i>Nature Communications</i>. Springer Nature, 2020. <a href=\"https://doi.org/10.1038/s41467-020-18610-6\">https://doi.org/10.1038/s41467-020-18610-6</a>.","ista":"Prehal C, Fitzek H, Kothleitner G, Presser V, Gollas B, Freunberger SA, Abbas Q. 2020. Persistent and reversible solid iodine electrodeposition in nanoporous carbons. Nature Communications. 11, 4838.","ieee":"C. Prehal <i>et al.</i>, “Persistent and reversible solid iodine electrodeposition in nanoporous carbons,” <i>Nature Communications</i>, vol. 11. Springer Nature, 2020."},"title":"Persistent and reversible solid iodine electrodeposition in nanoporous carbons","day":"24","author":[{"first_name":"Christian","full_name":"Prehal, Christian","last_name":"Prehal"},{"last_name":"Fitzek","first_name":"Harald","full_name":"Fitzek, Harald"},{"last_name":"Kothleitner","first_name":"Gerald","full_name":"Kothleitner, Gerald"},{"full_name":"Presser, Volker","first_name":"Volker","last_name":"Presser"},{"first_name":"Bernhard","full_name":"Gollas, Bernhard","last_name":"Gollas"},{"orcid":"0000-0003-2902-5319","id":"A8CA28E6-CE23-11E9-AD2D-EC27E6697425","last_name":"Freunberger","first_name":"Stefan Alexander","full_name":"Freunberger, Stefan Alexander"},{"first_name":"Qamar","full_name":"Abbas, Qamar","last_name":"Abbas"}],"type":"journal_article"}]