The cryo-EM structure of the bd oxidase from M. tuberculosis reveals a unique structural framework and enables rational drug design to combat TB.

New drugs are urgently needed to combat the global TB epidemic. Targeting simultaneously multiple respiratory enzyme complexes of Mycobacterium tuberculosis is regarded as one of the most effective treatment options to shorten drug administration regimes, and reduce the opportunity for the emergence of drug resistance. During infection and proliferation, the cytochrome bd oxidase plays a crucial role for mycobacterial pathophysiology by maintaining aerobic respiration at limited oxygen concentrations. Here, we present the cryo-EM structure of the cytochrome bd oxidase from M. tuberculosis at 2.5 Å. In conjunction with atomistic molecular dynamics (MD) simulation studies we discovered a previously unknown MK-9-binding site, as well as a unique disulfide bond within the Q-loop domain that defines an inactive conformation of the canonical quinol oxidation site in Actinobacteria. Our detailed insights into the long-sought atomic framework of the cytochrome bd oxidase from M. tuberculosis will form the basis for the design of highly specific drugs to act on this enzyme.

Bacterial Oxidases of the Cytochrome bd Family: Redox Enzymes of Unique Structure, Function, and Utility As Drug Targets.

Significance: Cytochrome bd is a ubiquinol:oxygen oxidoreductase of many prokaryotic respiratory chains with a unique structure and functional characteristics. Its primary role is to couple the reduction of molecular oxygen, even at submicromolar concentrations, to water with the generation of a proton motive force used for adenosine triphosphate production. Cytochrome bd is found in many bacterial pathogens and, surprisingly, in bacteria formally denoted as anaerobes. It endows bacteria with resistance to various stressors and is a potential drug target. Recent Advances: We summarize recent advances in the biochemistry, structure, and physiological functions of cytochrome bd in the light of exciting new three-dimensional structures of the oxidase. The newly discovered roles of cytochrome bd in contributing to bacterial protection against hydrogen peroxide, nitric oxide, peroxynitrite, and hydrogen sulfide are assessed. Critical Issues: Fundamental questions remain regarding the precise delineation of electron flow within this multihaem oxidase and how the extraordinarily high affinity for oxygen is accomplished, while endowing bacteria with resistance to other small ligands. Future Directions: It is clear that cytochrome bd is unique in its ability to confer resistance to toxic small molecules, a property that is significant for understanding the propensity of pathogens to possess this oxidase. Since cytochrome bd is a uniquely bacterial enzyme, future research should focus on harnessing fundamental knowledge of its structure and function to the development of novel and effective antibacterial agents.

Structure of a bd oxidase indicates similar mechanisms for membrane-integrated oxygen reductases.

The cytochrome bd oxidases are terminal oxidases that are present in bacteria and archaea. They reduce molecular oxygen (dioxygen) to water, avoiding the production of reactive oxygen species. In addition to their contribution to the proton motive force, they mediate viability under oxygen-related stress conditions and confer tolerance to nitric oxide, thus contributing to the virulence of pathogenic bacteria. Here we present the atomic structure of the bd oxidase from Geobacillus thermodenitrificans, revealing a pseudosymmetrical subunit fold. The arrangement and order of the heme cofactors support the conclusions from spectroscopic measurements that the cleavage of the dioxygen bond may be mechanistically similar to that in the heme-copper-containing oxidases, even though the structures are completely different.

Characterization of photosystem II in salt-stressed cyanobacterial Spirulina platensis cells.

PSII activity was inhibited after Spirulina platensis cells were incubated with different salt concentrations (0-0.8 M NaCl) for 12 h. Flash-induced fluorescence kinetics showed that in the absence of DCMU, the half time of the fast and slow components decreased while that of the middle component increased considerably with increasing salt concentration. In the presence of DCMU, fluorescence relaxation was dominated by a 0.6s component in control cells. After salt stress, this was partially replaced by a faster new component with half time of 20-50 ms. Thermoluminescence measurements revealed that S(2)Q(A)(-) and S(2)Q(B)(-) recombinations were shifted to higher temperatures in parallel and the intensities of the thermoluminescence emissions were significantly reduced in salt-stressed cells. The period-four oscillation of the thermoluminescence B band was highly damped. There were no significant changes in contents of CP47, CP43, cytochrome c550, and D1 proteins. However, content of the PsbO protein in thylakoid fraction decreased but increased significantly in soluble fraction. The results suggest that salt stress leads to a modification of the Q(B) niche at the acceptor side and an increase in the stability of the S(2) state at the donor side, which is associated with a dissociation of the PsbO protein.

Cytochrome bd from Azotobacter vinelandii: evidence for high-affinity oxygen binding.

Cytochrome bd from Azotobacter vinelandii is a respiratory quinol oxidase that is highly efficient in reducing intracellular oxygen concentration, thus enabling nitrogen fixation under ambient aerobic conditions. Equilibrium measurements of O2 binding to ferrous heme d in the one-electron-reduced form of the A. vinelandii enzyme give Kd(O2) = 0.5 microM, close to the value for the Escherichia coli cytochrome bd (ca. 0.3 microM); thus, both enzymes have similar, high affinity for oxygen. The reaction of the A. vinelandii cytochrome bd in the one-electron-reduced and fully reduced states with O2 is extremely fast approaching the diffusion-controlled limit in water. In the fully reduced state, the rate of O2 binding depends linearly on the oxygen concentration consistently with a simple, single-step process. In contrast, in the one-electron-reduced state the rate of oxygen binding is hyperbolic, implying a more complex binding pattern. Two possible explanations for the saturation kinetics are considered: (A) There is a spectroscopically silent prebinding of oxygen to an unidentified low-affinity saturatable site followed by the oxygen transfer to heme d. (B) Oxygen binding to heme d requires an "activated" state of the enzyme in which an oxygen channel connecting heme d to the bulk is open. This channel is permanently open in the fully reduced enzyme (hence no saturation behavior) but flickers between the open and closed states in the one-electron-reduced enzyme.

The binding of cyanide to cytochrome d in intact cells, spheroplasts, membrane fragments and solubilized enzyme from Salmonella typhimurium.

This investigation focused on the kinetics of cyanide binding to oxidized and reduced cytochrome d in Salmonella typhimurium intact cells, spheroplasts, membrane fragments and solubilized enzyme, and on the effect of pH on this binding. Cyanide bound to the oxidized form of cytochrome d under all experimental conditions, inducing a trough at 649 nm in the oxidized-cyanide-minus-oxidized difference absorption spectra. V(max) of cyanide binding to oxidized cytochrome d at pH 7.0 was 14.0+/-2.0 pmol/min/mg protein (prot.) in intact cells, 37.0+/-3.5 pmol/min/mg prot. in spheroplasts, 125.0+/-6.0 pmol/min/mg prot. in membrane fragments, and 538.0+/-8.5 pmol/min/mg prot. in solubilized cytochrome d. The pseudo-first order rate constants were 0.004 s(-1) for intact cells, 0.005 s(-1) for spheroplasts, 0.007 s(-1) for membrane fragments and 0.025 s(-1) for the solubilized enzyme. The V(max) value was highest at pH 7.0 for intact cells and solubilized cytochrome d and at pH 8.0 for both spheroplasts and membrane fragments. The K(s) of binding at pH 7.0 was around 4 mM in intact cells, spheroplasts and membrane fragments, but was 10.5 mM in solubilized cytochrome d. This difference between the K(s) values suggested a change in conformation, upon solubilization, leading to a decrease in the affinity of cyanide for the solubilized enzyme. The K(s) value was nearly the same at all pH investigated (pH 5-10). Cyanide was found to also bind to the reduced form of cytochrome d in membrane fragments (K(s)=18+/-3 mM, V(max)=377+/-28 pmol/min/mg prot. at pH 7) and the solubilized enzyme (K(s)=18+/-1.2 mM, V(max)=649+/-45 pmol/min/mg prot. at pH 7) with a lower affinity of cyanide for the reduced cytochrome d than for the oxidized enzyme. Pseudo-first order rate constants were 0.025 s(-1) and 0.042 s(-1) respectively for membrane fragments and solubilized enzyme. The value of V(max) for cyanide binding to the reduced cytochrome d, whether membrane-bound or solubilized, increased slightly with pH (for pH 6-10) while the K(s) value dropped significantly with increasing pH. The pH dependence observed here might be interpretable as a possible role for conformational transition associated with energy transduction. Finally, this investigation pointed to the influence of the microenvironment of a protein within the cell on its reactivity.

EPR study of NO complex of bd-type ubiquinol oxidase from Escherichia coli.

The heme axial ligands of bd-type ubiquinol oxidase of Escherichia coli were studied by EPR and optical spectroscopies using nitric oxide (NO) as a monitoring probe. We found that NO bound to ferrous heme d of the air-oxidized and fully reduced enzymes with very high affinity and to ferrous heme b595 of the fully reduced enzyme with low affinity. EPR spectrum of the 14NO complex of the reduced enzyme exhibited an axially symmetric signal with g-values at g = 2.041 and g = 1.993 and a clear triplet of triplet (or a triplet of doublet for the 15NO complex) superhyperfine structure originating from a nitrogenous proximal ligand trans to NO was observed. This EPR species was assigned to the ferrous heme d-NO complex. This suggests that the proximal axial ligand of heme d is a histidine residue in an anomalous condition or other nitrogenous amino acid residue. Furthermore, the EPR line shape of the ferrous heme d-NO was slightly influenced by the oxidation state of the heme b595. This indicates that heme d exists in close proximity to heme b595 forming a binuclear center. Another axially symmetric EPR signal with g-values at g(parallel) = 2.108 and g(perpendicular) = 2.020 appeared after prolonged incubation of the reduced enzyme with NO and was attributed to the ferrous heme b595-NO complex.

Cytochrome d axial ligand of the bd-type terminal quinol oxidase from Escherichia coli.

Using various spectroscopic techniques, we studied the structure of the dioxygen reduction site of the bd-type terminal quinol oxidase in the aerobic respiratory chain of Escherichia coli. Resonance Raman and FT-IR spectroscopies identified the v(Fe(2+)-CO) and v(C-O) stretching frequencies at 471 and 1980.7 cm-1, respectively, at the cytochrome d center of the dithionite-reduced CO-bound enzyme. The CO ligation in the cytochrome bd complex is considerably different from those of the heme-copper terminal oxidases. Anaerobic addition of NO to the air-oxidized enzyme caused an exchange of cytochrome d-bound dioxygen with NO leading to an appearance of cytochrome d-NO EPR signal. But there is no superhyperfine structure originating from the cytochrome d proximal 14N ligand in the central resonance of the NO EPR signal. These results suggest that cytochrome d axial ligand of the cytochrome bd complex is likely a histidine residue in an anomalous condition or other than a histidine residue and, therefore, the molecular structure around the dioxygen-binding site is different from that of the heme-copper terminal oxidases.