Kazumasa Muramoto

In all kingdoms of life, the regulation of membrane-bound enzyme function via oligomerization is a fundamental aspect of cell physiology. Often, the mechanistic role of oligomerization is unclear, due to a lack of structure-function comparisons between constituent forms of the enzyme. Here, we elucidate the structural underpinnings of enzyme regulation and oligomerization in the quinol-dependent nitric oxide reductase (qNOR) from Neisseria meningitidis, by high-resolution structural analyses of the less active monomeric form (2.25 Å) and the highly active dimeric form (1.89 Å). The comparison revealed that broad helical flexibility near the dimer interface of the monomer causes a conformational change in a critical amino acid near the active site, located apart from the dimer interface. We demonstrate that the crosstalk between the dimer interface and catalytic site in qNOR allows enhanced activation of the enzyme via dimerization. Given Neisseria meningitidis' dependence on qNOR to detoxify the host's immune response of nitric oxide, our results pave a way for new strategies to combat bacterial infections, via the inactivation of qNOR by monomerization. More broadly, this provides new insights into the role of membrane protein oligomerization and its influence on regulating activity.

Cytochrome c oxidase (CcO) catalyzes oxygen (O2) reduction at the heme a3-CuB site in the transmembrane region of the enzyme. It has been proposed that the hydrophobic channel that connects the transmembrane surface of subunit III through subunit I to the heme a3-CuB site is the O2 transfer pathway. Gas molecules other than O2, including carbon dioxide (CO2) generated in the tricarboxylic acid cycle, should also enter the hydrophobic channel, but it is not clear how these molecules are expelled from CcO. We analyzed the crystal structures of CO2-, nitrous oxide-, and Xe-bound bovine CcO in the oxidized and reduced states at resolutions of 1.75 to 1.85 Å. Binding of Xe in the channel of subunit I near the interface with subunit III supported the proposed O2 transfer pathway. CO2, nitrous oxide, and another Xe were all bound to a common site near the branching point of another hydrophobic channel that branched from the O2 transport channel. Additional Xe atoms were bound in the second channel leading up to the molecular surface on the intermembrane space side, suggesting that under physiological conditions, CO2 that has entered the O2 pathway could be passively expelled through this channel. This channel consists of subunit I and nuclear DNA-coded subunit VIIc, suggesting that the addition of subunit VIIc in the process of molecular evolution of mitochondrial CcO has made the CO2 exhaust pathway.

Cytochrome c oxidase (CcO) reduces O2 in the O2-reduction site by sequential four-electron donations through the low-potential metal sites (CuA and Fea). Redox-coupled X-ray crystal structural changes have been identified at five distinct sites including Asp51, Arg438, Glu198, the hydroxyfarnesyl ethyl group of heme a, and Ser382, respectively. These sites interact with the putative proton-pumping H-pathway. However, the metal sites responsible for each structural change have not been identified, since these changes were detected as structural differences between the fully reduced and fully oxidized CcOs. Thus, the roles of these structural changes in the CcO function are yet to be revealed. X-ray crystal structures of cyanide-bound CcOs under various oxidation states showed that the O2-reduction site controlled only the Ser382-including site, while the low potential metal sites induced the other changes. This finding indicates that these low-potential site-inducible structural changes are triggered by sequential electron-extraction from the low-potential sites by the O2-reduction site and that each structural change is insensitive to the oxidation and ligand-binding states of the O2-reduction site. Because the proton/electron coupling efficiency is constant (1:1), regardless of the reaction progress in the O2-reduction site, the structural changes induced by the low-potential sites are assignable to those critically involved in the proton-pumping, suggesting that the H-pathway, facilitating these low-potential site-inducible structural changes, pumps protons. Furthermore, a cyanide-bound CcO structure suggests that a hypoxia-inducible activator, Higd1a, activates the O2-reduction site without influencing the electron transfer mechanism through the low-potential sites, kinetically confirming that the low-potential sites facilitate proton-pump.

Abstract Antimicrobial resistance (AMR) is a global health problem. Despite the enormous efforts made in the last decade, threats from some species, including drug-resistant Neisseria gonorrhoeae, continue to rise and would become untreatable. The development of antibiotics with a different mechanism of action is seriously required. Here, we identified an allosteric inhibitory site buried inside eukaryotic mitochondrial heme-copper oxidases (HCOs), the essential respiratory enzymes for life. The steric conformation around the binding pocket of HCOs is highly conserved among bacteria and eukaryotes, yet the latter has an extra helix. This structural difference in the conserved allostery enabled us to rationally identify bacterial HCO-specific inhibitors: an antibiotic compound against ceftriaxone-resistant Neisseria gonorrhoeae. Molecular dynamics combined with resonance Raman spectroscopy and stopped-flow spectroscopy revealed an allosteric obstruction in the substrate accessing channel as a mechanism of inhibition. Our approach opens fresh avenues in modulating protein functions and broadens our options to overcome AMR.