7p7e Citations

A universal coupling mechanism of respiratory complex I.

Kravchuk V, Petrova O, Kampjut D, Wojciechowska-Bason A, Breese Z, Sazanov L
Nature (2022)
Related entries: 7p61, 7p62, 7p63, 7p64, 7p69, 7p7c, 7p7j, 7p7k, 7p7l, 7p7m, 7z7r, 7z7s, 7z7t, 7z7v, 7z80, 7z83, 7z84, 7zc5, 7zci, 7zd6, 7zdh, 7zdj, 7zdm, 7zdp, 7zeb

Cited: 17 times
EuropePMC logo PMID: 36104567

Abstract

Complex I is the first enzyme in the respiratory chain, which is responsible for energy production in mitochondria and bacteria1. Complex I couples the transfer of two electrons from NADH to quinone and the translocation of four protons across the membrane2, but the coupling mechanism remains contentious. Here we present cryo-electron microscopy structures of Escherichia coli complex I (EcCI) in different redox states, including catalytic turnover. EcCI exists mostly in the open state, in which the quinone cavity is exposed to the cytosol, allowing access for water molecules, which enable quinone movements. Unlike the mammalian paralogues3, EcCI can convert to the closed state only during turnover, showing that closed and open states are genuine turnover intermediates. The open-to-closed transition results in the tightly engulfed quinone cavity being connected to the central axis of the membrane arm, a source of substrate protons. Consistently, the proportion of the closed state increases with increasing pH. We propose a detailed but straightforward and robust mechanism comprising a 'domino effect' series of proton transfers and electrostatic interactions: the forward wave ('dominoes stacking') primes the pump, and the reverse wave ('dominoes falling') results in the ejection of all pumped protons from the distal subunit NuoL. This mechanism explains why protons exit exclusively from the NuoL subunit and is supported by our mutagenesis data. We contend that this is a universal coupling mechanism of complex I and related enzymes.

Reviews citing this publication (4)

  1. The functional significance of mitochondrial respiratory chain supercomplexes. Kohler A, Barrientos A, Fontanesi F, Ott M. EMBO Rep 24 e57092 (2023)
  2. An evolving view of complex II-noncanonical complexes, megacomplexes, respiration, signaling, and beyond. Iverson TM, Singh PK, Cecchini G. J Biol Chem 299 104761 (2023)
  3. From the 'black box' to 'domino effect' mechanism: what have we learned from the structures of respiratory complex I. Sazanov LA. Biochem J 480 319-333 (2023)
  4. Mitochondrial complex I ROS production and redox signaling in hypoxia. Okoye CN, Koren SA, Wojtovich AP. Redox Biol 67 102926 (2023)

Articles citing this publication (13)

  1. Plant-specific features of respiratory supercomplex I + III2 from Vigna radiata. Maldonado M, Fan Z, Abe KM, Letts JA. Nat Plants 9 157-168 (2023)
  2. Resting mitochondrial complex I from Drosophila melanogaster adopts a helix-locked state. Padavannil A, Murari A, Rhooms SK, Owusu-Ansah E, Letts JA. Elife 12 e84415 (2023)
  3. Ameliorating Mitochondrial Dysfunction of Neurons by Biomimetic Targeting Nanoparticles Mediated Mitochondrial Biogenesis to Boost the Therapy of Parkinson's Disease. Zheng Q, Liu H, Zhang H, Han Y, Yuan J, Wang T, Gao Y, Li Z. Adv Sci (Weinh) 10 e2300758 (2023)
  4. Cryo-EM structures of mitochondrial respiratory complex I from Drosophila melanogaster. Agip AA, Chung I, Sanchez-Martinez A, Whitworth AJ, Hirst J. Elife 12 e84424 (2023)
  5. Membrane-domain mutations in respiratory complex I impede catalysis but do not uncouple proton pumping from ubiquinone reduction. Jarman OD, Hirst J. PNAS Nexus 1 pgac276 (2022)
  6. Quinone Catalysis Modulates Proton Transfer Reactions in the Membrane Domain of Respiratory Complex I. Kim H, Saura P, Pöverlein MC, Gamiz-Hernandez AP, Kaila VRI. J Am Chem Soc 145 17075-17086 (2023)
  7. Structure of mycobacterial respiratory complex I. Liang Y, Plourde A, Bueler SA, Liu J, Brzezinski P, Vahidi S, Rubinstein JL. Proc Natl Acad Sci U S A 120 e2214949120 (2023)
  8. Exploring ND-011992, a quinazoline-type inhibitor targeting quinone reductases and quinol oxidases. Kägi J, Sloan W, Schimpf J, Nasiri HR, Lashley D, Friedrich T. Sci Rep 13 12226 (2023)
  9. H2O2 selectively damages the binuclear iron-sulfur cluster N1b of respiratory complex I. Strotmann L, Harter C, Gerasimova T, Ritter K, Jessen HJ, Wohlwend D, Friedrich T. Sci Rep 13 7652 (2023)
  10. Horizontal proton transfer across the antiporter-like subunits in mitochondrial respiratory complex I. Zdorevskyi O, Djurabekova A, Lasham J, Sharma V. Chem Sci 14 6309-6318 (2023)
  11. Investigation of hydrated channels and proton pathways in a high-resolution cryo-EM structure of mammalian complex I. Grba DN, Chung I, Bridges HR, Agip AA, Hirst J. Sci Adv 9 eadi1359 (2023)
  12. Mechanism of rotenone binding to respiratory complex I depends on ligand flexibility. Pereira CS, Teixeira MH, Russell DA, Hirst J, Arantes GM. Sci Rep 13 6738 (2023)
  13. Structural insights into respiratory complex I deficiency and assembly from the mitochondrial disease-related ndufs4-/- mouse. Yin Z, Agip AA, Bridges HR, Hirst J. EMBO J 43 225-249 (2024)


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