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Making the leap from structure to mechanism: are the open states of mammalian complex I identified by cryoEM resting states or catalytic intermediates?

Injae Chung, Daniel N. Grba, John J. Wright, Judy Hirst

2022Current Opinion in Structural Biology50 citationsDOIOpen Access PDF

Abstract

Respiratory complex I (NADH:ubiquinone oxidoreductase) is a multi-subunit, energy-transducing mitochondrial enzyme that is essential for oxidative phosphorylation and regulating NAD+/NADH pools. Despite recent advances in structural knowledge and a long history of biochemical analyses, the mechanism of redox-coupled proton translocation by complex I remains unknown. Due to its ability to separate molecules in a mixed population into distinct classes, single-particle electron cryomicroscopy has enabled identification and characterisation of different complex I conformations. However, deciding on their catalytic and/or regulatory properties to underpin mechanistic hypotheses, especially without detailed biochemical characterisation of the structural samples, has proven challenging. In this review we explore different mechanistic interpretations of the closed and open states identified in cryoEM analyses of mammalian complex I.

Topics & Concepts

OxidoreductaseCryo-electron microscopyProtein subunitNAD+ kinaseMechanism (biology)BiologyOxidative phosphorylationElectron Transport Complex IBiochemistryComputational biologyStructural biologyCatalytic cyclePopulationRespiratory chainMitochondrionBiophysicsChemistryEnzymeGenePhysicsDemographyQuantum mechanicsSociologyPhotosynthetic Processes and MechanismsAdvanced Electron Microscopy Techniques and ApplicationsATP Synthase and ATPases Research
Making the leap from structure to mechanism: are the open states of mammalian complex I identified by cryoEM resting states or catalytic intermediates? | Litcius