Publication:
Na+ controls hypoxic signalling by the mitochondrial respiratory chain.

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dc.contributor.authorHernansanz-Agustín, Pablo
dc.contributor.authorChoya-Foces, Carmen
dc.contributor.authorCarregal-Romero, Susana
dc.contributor.authorRamos, Elena
dc.contributor.authorOliva, Tamara
dc.contributor.authorVilla-Piña, Tamara
dc.contributor.authorMoreno, Laura
dc.contributor.authorIzquierdo-Álvarez, Alicia
dc.contributor.authorCabrera-García, J Daniel
dc.contributor.authorCortés, Ana
dc.contributor.authorLechuga-Vieco, Ana Victoria
dc.contributor.authorJadiya, Pooja
dc.contributor.authorNavarro, Elisa
dc.contributor.authorParada, Esther
dc.contributor.authorPalomino-Antolín, Alejandra
dc.contributor.authorTello, Daniel
dc.contributor.authorAcin-Perez, Rebeca
dc.contributor.authorRodríguez-Aguilera, Juan Carlos
dc.contributor.authorNavas, Plácido
dc.contributor.authorCogolludo, Ángel
dc.contributor.authorLópez-Montero, Iván
dc.contributor.authorMartínez-Del-Pozo, Álvaro
dc.contributor.authorEgea, Javier
dc.contributor.authorLópez, Manuela G
dc.contributor.authorElrod, John W
dc.contributor.authorRuíz-Cabello, Jesús
dc.contributor.authorBogdanova, Anna
dc.contributor.authorEnriquez, Jose Antonio
dc.contributor.authorMartínez-Ruiz, Antonio
dc.date.accessioned2022-07-07T11:28:55Z
dc.date.available2022-07-07T11:28:55Z
dc.date.issued2020-10
dc.description.abstractAll metazoans depend on the consumption of O2 by the mitochondrial oxidative phosphorylation system (OXPHOS) to produce energy. In addition, the OXPHOS uses O2 to produce reactive oxygen species that can drive cell adaptations1-4, a phenomenon that occurs in hypoxia4-8 and whose precise mechanism remains unknown. Ca2+ is the best known ion that acts as a second messenger9, yet the role ascribed to Na+ is to serve as a mere mediator of membrane potential10. Here we show that Na+ acts as a second messenger that regulates OXPHOS function and the production of reactive oxygen species by modulating the fluidity of the inner mitochondrial membrane. A conformational shift in mitochondrial complex I during acute hypoxia11 drives acidification of the matrix and the release of free Ca2+ from calcium phosphate (CaP) precipitates. The concomitant activation of the mitochondrial Na+/Ca2+ exchanger promotes the import of Na+ into the matrix. Na+ interacts with phospholipids, reducing inner mitochondrial membrane fluidity and the mobility of free ubiquinone between complex II and complex III, but not inside supercomplexes. As a consequence, superoxide is produced at complex III. The inhibition of Na+ import through the Na+/Ca2+ exchanger is sufficient to block this pathway, preventing adaptation to hypoxia. These results reveal that Na+ controls OXPHOS function and redox signalling through an unexpected interaction with phospholipids, with profound consequences for cellular metabolism.es_ES
dc.description.peerreviewedNoes_ES
dc.description.sponsorshipWe thank M. Kowalewski (Institute of Veterinary Anatomy, UZH) for allowing us the use of the microscope for live-cell imaging; A. Alfuzzi, J. Prieto, A. Mellado (IIS-IP) and B. Barreira (CIBERES) for collaboration in experiments; E. Fuertes-Yebra (IIS-IP) for technical assistance; M. E. Soriano and F. Caicci (University of Padova) for performing electron microscopy; R. Rizzuto and D. De Stefani (University of Padova) for MCU KO and control cell lines; M. T. Alonso (IBGM, University of Valladolid and CSIC) for the pcDNA3-erGAP3 plasmid; J. Langer from CIC biomaGUNE for fruitful discussion and support with the IR spectroscopy measurements; I. Sekler (Ben-Gurion University), C. Rueda and J. Satrustegui (CMBSO, UAM-CSIC) for providing plasmids and other material and for helpful discussions; M. Cano and A. G. Garcia (IIS-IP and UAM), M. Murphy (MRC and University of Cambridge), I. Wittig (Goethe Universitat), J. Miguel Mancheno (IQFR, CSIC), A. Pascual and J. Lopez-Barneo (IBIS, US-CSIC) for helpful discussions; and L. del Peso (UAM) and F. Sanchez-Madrid (IIS-IP and UAM) for their support. This research has been financed by Spanish Government grants (ISCIII and AEI agencies, partially funded by the European Union FEDER/ERDF) CSD2007-00020 (RosasNet, Consolider-Ingenio 2010 programme to A.M.-R. and J.A.E.); CP07/00143, PS09/00101, PI12/00875, PI15/00107 and RTI2018-094203-B-I00 (to A.M.-R.); CP12/03304 and PI15/01100 (to L.M.); CP14/00008, CPII19/00005 and PI16/00735 (to J.E.); SAF2016-77222-R (to A. Cogolludo); PI17/01286 (to P.N.); SAF2015-65633-R, RTI2018-099357-B-I00 and CB16/10/00282 (to J.A.E.); RTI2018-095793-B-I00 (to M.G.L.); and SAF2017-84494-2-R (to J.R.-C.), by the European Union (ITN GA317433 to J.A.E. and MC-CIG GA304217 to R.A.-P.), by grants from the Comunidad de Madrid B2017/BMD-3727 (to A. Cogolludo) and B2017/BMD-3827 (to M.G.L.), by a grant from the Fundacion Domingo Martinez (to M.G.L. and A.M.-R.), by the Human Frontier Science Program grant HFSP-RGP0016/2018 (to J.A.E.), by grants from the Fundacion BBVA (to R.A.-P. and J.R.-C.), by the UCM-Banco Santander grant PR75/18-21561 (to A.M.-d.-P.), by the Programa Red Guipuzcoana de Ciencia, Tecnologia e Informacion 2018-CIEN-000058-01 (to J.R.-C.) and from the Basque Government under the ELKARTEK Program (grant no. KK-2019/bmG19 to J.R.-C.), by the Swiss National Science Foundation (SNF) grant 310030_124970/1 (to A.B.), by a travel grant from the IIS-IP (to P.H.-A.) and by the COST actions TD0901 (HypoxiaNet) and BM1203 (EU-ROS). The CNIC is supported by the Pro-CNIC Foundation and is a Severo Ochoa Center of Excellence (Spanish Government award SEV-2015-0505). CIC biomaGUNE is supported by the Maria de Maeztu Units of Excellence Program from the Spanish Government (MDM-2017-0720). P.H.-A. was a recipient of a predoctoral FPU fellowship from the Spanish Government. E.N. is a recipient of a predoctoral FPI fellowship from the Universidad Autonoma de Madrid (UAM). A.M.-R., L.M. and J.E. are supported by the I3SNS or 'Miguel Servet' programmes (ISCIII, Spanish Government; partially funded by the FEDER/ERDF).es_ES
dc.format.number7828es_ES
dc.format.page287-291es_ES
dc.format.volume586es_ES
dc.identifier.citationNature. 2020; 586(7828):287-291.es_ES
dc.identifier.doi10.1038/s41586-020-2551-yes_ES
dc.identifier.e-issn1476-4687es_ES
dc.identifier.journalNaturees_ES
dc.identifier.pubmedID32728214 es_ES
dc.identifier.urihttp://hdl.handle.net/20.500.12105/14685
dc.language.isoenges_ES
dc.repisalud.institucionCNICes_ES
dc.repisalud.orgCNICCNIC::Grupos de investigación::Genética Funcional del Sistema de Fosforilación Oxidativaes_ES
dc.rights.accessRightsopen accesses_ES
dc.rights.licenseAttribution-NonCommercial-NoDerivatives 4.0 Internacional*
dc.rights.urihttp://creativecommons.org/licenses/by-nc-nd/4.0/*
dc.subject.meshElectron Transportes_ES
dc.subject.meshSecond Messenger Systemses_ES
dc.subject.meshAnimalses_ES
dc.subject.meshBreast Neoplasmses_ES
dc.subject.meshCalcium Phosphateses_ES
dc.subject.meshCell Line, Tumores_ES
dc.subject.meshChemical Precipitationes_ES
dc.subject.meshHumanses_ES
dc.subject.meshHypoxiaes_ES
dc.subject.meshMalees_ES
dc.subject.meshMembrane Fluidityes_ES
dc.subject.meshMice, Inbred C57BLes_ES
dc.subject.meshMitochondriaes_ES
dc.subject.meshMitochondrial Membraneses_ES
dc.subject.meshMitochondrial Proteinses_ES
dc.subject.meshOxidative Phosphorylationes_ES
dc.subject.meshRatses_ES
dc.subject.meshRats, Wistares_ES
dc.subject.meshReactive Oxygen Specieses_ES
dc.subject.meshSodiumes_ES
dc.subject.meshSodium-Calcium Exchangeres_ES
dc.titleNa+ controls hypoxic signalling by the mitochondrial respiratory chain.es_ES
dc.typejournal articlees_ES
dc.type.hasVersionVoRes_ES
dspace.entity.typePublication
relation.isAuthorOfPublicationead3da70-42e5-4ade-b027-ba61fddae2c5
relation.isAuthorOfPublication3a0c79b2-8c86-491c-91f1-116d726c24b3
relation.isAuthorOfPublication.latestForDiscoveryead3da70-42e5-4ade-b027-ba61fddae2c5

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