Edited by Harry B. Gray, California Institute of Technology, Pasadena, CA, and approved April 1, 2014 (received for review October 16, 2013)
Using large-scale classical and quantum simulations, we elucidate key aspects of the molecular function of complex I, a protein central to biological energy conversion. Complex I serves as the primary electron entry point into the mitochondrial and bacterial respiratory chains and operates as a redox-coupled proton pump. Our simulations suggest that transient water chains establish highly efficient pathways for proton transfer. Our findings form a basis for understanding long-range energy conversion in complex I, and mechanistic similarities to other redox-driven proton-pumps, such as cytochrome c oxidase and bacteriorhodopsin.
Complex I serves as the primary electron entry point into the mitochondrial and bacterial respiratory chains. It catalyzes the reduction of quinones by electron transfer from NADH, and couples this exergonic reaction to the translocation of protons against an electrochemical proton gradient. The membrane domain of the enzyme extends ∼180 Å from the site of quinone reduction to the most distant proton pathway. To elucidate possible mechanisms of the long-range proton-coupled electron transfer process, we perform large-scale atomistic molecular dynamics simulations of the membrane domain of complex I from Escherichia coli. We observe spontaneous hydration of a putative proton entry channel at the NuoN/K interface, which is sensitive to the protonation state of buried glutamic acid residues. In hybrid quantum mechanics/classical mechanics simulations, we find that the observed water wires support rapid proton transfer from the protein surface to the center of the membrane domain. To explore the functional relevance of the pseudosymmetric inverted-repeat structures of the antiporter-like subunits NuoL/M/N, we constructed a symmetry-related structure of a possible alternate-access state. In molecular dynamics simulations, we find the resulting structural changes to be metastable and reversible at the protein backbone level. However, the increased hydration induced by the conformational change persists, with water molecules establishing enhanced lateral connectivity and pathways for proton transfer between conserved ionizable residues along the center of the membrane domain. Overall, the observed water-gated transitions establish conduits for the unidirectional proton translocation processes, and provide a possible coupling mechanism for the energy transduction in complex I.
Author contributions: V.R.I.K., M.W., and G.H. designed research; V.R.I.K. performed research; V.R.I.K., M.W., and G.H. analyzed data; and V.R.I.K., M.W., and G.H. wrote the paper.
The authors declare no conflict of interest.
This article is a PNAS Direct Submission.
This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10.1073/pnas.1319156111/-/DCSupplemental.
