Abstract
Membrane bound respiratory complex I is the key enzyme in the respiratory chains of bacteria and mitochondria, and couples the reduction of quinone to the pumping of protons across the membrane. Recently solved crystal or electron microscopy structures of bacterial and mitochondrial complexes have provided significant insights into the electron and proton transfer pathways. However, due to large spatial separation between the electron and proton transfer routes, the molecular mechanism of coupling remains unclear. Here, based on atomistic molecular dynamics simulations performed on the entire structure of complex I from Thermus thermophilus, we studied the hydration of the quinone-binding site and the membrane-bound subunits. The data from simulations show rapid diffusion of water molecules in the protein interior, and formation of hydrated regions in the three antiporter-type subunits. An unexpected water-protein based connectivity between the middle of the Q-tunnel and the fourth proton channel is also observed. The protonation-state dependent dynamics of key acidic residues in the Nqo8 subunit suggest that the latter may be linked to redox-coupled proton pumping in complex I. We propose that in complex I the proton and electron transfer paths are not entirely separate, instead the nature of coupling may in part be ‘direct’.
Highlights
Complex I (NADH-quinone oxidoreductase), the largest enzyme in the respiratory chains of eukaryotes and several bacteria, serves as a redox-linked reversible proton pump[1]
Atomistic classical molecular dynamics (MD) simulations performed on the entire crystal structure of complex I show that the root mean square deviation (RMSD) of protein stabilizes at a value of 4–5 Å in the first 50–100 ns of simulation time (Supplementary Fig. S1)
The data suggests that the system is fully equilibrated, and timescales of simulation are sufficient to analyze fast dynamics associated with the protein and the water molecules
Summary
Complex I (NADH-quinone oxidoreductase), the largest enzyme in the respiratory chains of eukaryotes and several bacteria, serves as a redox-linked reversible proton pump[1]. The three smaller membrane-bound subunits (Nqo[7], Nqo10–11), together with Nqo[8], provide the connectivity between the membrane arm and the hydrophilic domain of the enzyme (Fig. 1). Among these subunits Nqo[8] has been proposed to be involved in proton translocation based on X-ray structure analysis[18]. See refs 4–8 for various aspects associated with complex I mechanism
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