Abstract
Mitochondrial complex I (NADH:ubiquinone oxidoreductase), a crucial enzyme in energy metabolism, captures the redox potential energy from NADH oxidation/ubiquinone reduction to create the proton motive force used to drive ATP synthesis in oxidative phosphorylation. High-resolution single-particle electron cryo-EM analyses have provided detailed structural knowledge of the catalytic machinery of complex I, but not of the molecular principles of its energy transduction mechanism. Although ubiquinone is considered to bind in a long channel at the interface of the membrane-embedded and hydrophilic domains, with channel residues likely involved in coupling substrate reduction to proton translocation, no structures with the channel fully occupied have yet been described. Here, we report the structure (determined by cryo-EM) of mouse complex I with a tight-binding natural product acetogenin inhibitor, which resembles the native substrate, bound along the full length of the expected ubiquinone-binding channel. Our structure reveals the mode of acetogenin binding and the molecular basis for structure–activity relationships within the acetogenin family. It also shows that acetogenins are such potent inhibitors because they are highly hydrophobic molecules that contain two specific hydrophilic moieties spaced to lock into two hydrophilic regions of the otherwise hydrophobic channel. The central hydrophilic section of the channel does not favor binding of the isoprenoid chain when the native substrate is fully bound but stabilizes the ubiquinone/ubiquinol headgroup as it transits to/from the active site. Therefore, the amphipathic nature of the channel supports both tight binding of the amphipathic inhibitor and rapid exchange of the ubiquinone/ubiquinol substrate and product.
Highlights
NADH:ubiquinone oxidoreductase, located in the energy-transducing inner membrane of mitochondria, oxidises NADH and reduces ubiquinone, and couples the redox process to proton translocation across the membrane to generate the proton-motive force that powers ATP synthesis and transport processes (Figure 1)
Substrates (NADH and decylubiquinone, DQ) were added alongside to stimulate complex I turnover, along with an alcohol dehydrogenase and an alternative oxidase for substrate regeneration, to ensure exposure of the high-affinity binding site that may only be present in specific intermediates
Ubiquinone binding to complex I has been explored using synthesised ubiquinone derivatives of varying lengths, with bulky groups (1-methoxy-2,6-di(3-methoxy-3methyl-1-butynyl)benzene) added to the end of their tails—known as ‘oversized ubiquinones’ (OSUQs)
Summary
NADH:ubiquinone oxidoreductase (complex I), located in the energy-transducing inner membrane of mitochondria, oxidises NADH and reduces ubiquinone, and couples the redox process to proton translocation across the membrane to generate the proton-motive force that powers ATP synthesis and transport processes (Figure 1). A group of natural-product complex I inhibitors known as annonaceous acetogenins, derived from Annonaceae plants and shown to have anti-tumour effects [31], are much more hydrophobic than the inhibitors characterised in the aforementioned structural studies due to their substantial aliphatic carbon extensions and linker regions (Figures 1 and 2) Their long, unbranched architecture, terminal γ-lactone group, and high hydrophobicity render them analogues to the native ubiquinone substrates of complex I Journal Pre-proof Å) and thereby competitive inhibitors against it [34] On this basis, the chemical synthesis of orthologs of the natural-product acetogenins, such as bullatacin, has been developed and has provided affinity-labelling data to probe the acetogenin-binding site in complex I, highlighting interactions sites with the core subunits ND1 and NDUFS2 located at the interface of the transmembrane and hydrophilic arms, respectively. Our data provide the first experimental evidence for a molecule occupying the full length of the complex I binding channel and allow the molecular interpretation of structure–activity relationships within the acetogenin family
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