Pascal Lanciano

Biogenesis of a Respiratory Complex Is Orchestrated by a Single Accessory Protein

The biogenesis of respiratory complexes is a multistep process that requires finely tuned coordination of subunit assembly, metal cofactor insertion, and membrane-anchoring events. The dissimilatory nitrate reductase of the bacterial anaerobic respiratory chain is a membrane-bound heterotrimeric complex nitrate reductase A (NarGHI) carrying no less than eight redox centers. Here, we identified different stable folding assembly intermediates of the nitrate reductase complex and analyzed their redox cofactor contents using electron paramagnetic resonance spectroscopy. Upon the absence of the accessory protein NarJ, a global defect in metal incorporation was revealed. In addition to the molybdenum cofactor, we show that NarJ is required for specific insertion of the proximal iron-sulfur cluster (FS0) within the soluble nitrate reductase (NarGH) catalytic dimer. Further, we establish that NarJ ensures complete maturation of the b-type cytochrome subunit NarI by a proper timing for membrane anchoring of the NarGH complex. Our findings demonstrate that NarJ has a multifunctional role by orchestrating both the maturation and the assembly steps.

Cardiolipin-based respiratory complex activation in bacteria

Anionic lipids play a variety of key roles in membrane function, including functional and structural effects on respiratory complexes. However, little is known about the molecular basis of these lipid–protein interactions. In this study, NarGHI, an anaerobic respiratory complex of Escherichia coli, has been used to investigate the relations in between membrane-bound proteins with phospholipids. Activity of the NarGHI complex is enhanced by anionic phospholipids both in vivo and in vitro. The anionic cardiolipin tightly associates with the NarGHI complex and is the most effective phospholipid to restore functionality of a nearly inactive detergent-solubilized enzyme complex. A specific cardiolipin-binding site is identified on the basis of the available X-ray diffraction data and of site-directed mutagenesis experiment. One acyl chain of cardiolipin is in close proximity to the heme bD center and is responsible for structural adjustments of bD and of the adjacent quinol substrate binding site. Finally, cardiolipin binding tunes the interaction with the quinol substrate. Together, our results provide a molecular basis for the activation of a bacterial respiratory complex by cardiolipin.

Inter-monomer Electron Transfer Between the Low Potential b Hemes of Cytochrome bc1

Cytochrome (cyt) bc(1) is a structural dimer with its monomers consisting of the Fe-S protein, cyt b, and cyt c(1) subunits. Its three-dimensional architecture depicts it as a symmetrical homodimer, but the mobility of the head domain of the Fe-S protein indicates that the functional enzyme exists in asymmetrical heterodimeric conformations. Here, we report a new genetic system for studying intra- and intermonomer interactions within the cyt bc(1) using the facultative phototrophic bacterium Rhodobacter capsulatus. The system involves two different sets of independently expressed cyt bc(1) structural genes carried by two plasmids that are coharbored by a cell without its endogenous enzyme. Our results indicate that coexpressed cyt bc(1) subunits were matured, assorted, and assembled in vivo into homo- and heterodimeric enzymes that can bear different mutations in each monomer. Using the system, the occurrence of intermonomer electron transfer between the low-potential b hemes of cyt bc(1) was probed by choosing mutations that perturb electron transfer at the hydroquinone oxidation (Q(o)) and quinone reduction (Q(i)) sites of the enzyme. The data demonstrate that active heterodimeric variants, formed of monomers carrying mutations that abolish only one of the two (Q(o) or Q(i)) active sites of each monomer, are produced, and they support photosynthetic growth of R. capsulatus. Detailed analyses of the physicochemical properties of membranes of these mutants, as well as purified homo- and heterodimeric cyt bc(1) preparations, demonstrated that efficient and productive electron transfer occurs between the low-potential b(L) hemes of the monomers in a heterodimeric enzyme. Overall findings are discussed with respect to intra- and intermonomer interactions that take place during the catalytic turnover of cyt bc(1).

Loss of a Conserved Tyrosine Residue of Cytochrome b Induces Reactive Oxygen Species Production by Cytochrome bc1

Production of reactive oxygen species (ROS) induces oxidative damages, decreases cellular energy conversion efficiencies, and induces metabolic diseases in humans. During respiration, cytochrome bc1 efficiently oxidizes hydroquinone to quinone, but how it performs this reaction without any leak of electrons to O2 to yield ROS is not understood. Using the bacterial enzyme, here we show that a conserved Tyr residue of the cytochrome b subunit of cytochrome bc1 is critical for this process. Substitution of this residue with other amino acids decreases cytochrome bc1 activity and enhances ROS production. Moreover, the Tyr to Cys mutation cross-links together the cytochrome b and iron-sulfur subunits and renders the bacterial enzyme sensitive to O2 by oxidative disruption of its catalytic [2Fe-2S] cluster. Hence, this Tyr residue is essential in controlling unproductive encounters between O2 and catalytic intermediates at the quinol oxidation site of cytochrome bc1 to prevent ROS generation. Remarkably, the same Tyr to Cys mutation is encountered in humans with mitochondrial disorders and in Plasmodium species that are resistant to the anti-malarial drug atovaquone. These findings illustrate the harmful consequences of this mutation in human diseases.

Direct Evidence for Nitrogen Ligation to the High Stability Semiquinone Intermediate in Escherichia coli Nitrate Reductase A

The membrane-bound heterotrimeric nitrate reductase A (NarGHI) catalyzes the oxidation of quinols in the cytoplasmic membrane of Escherichia coli and reduces nitrate to nitrite in the cytoplasm. The enzyme strongly stabilizes a menasemiquinone intermediate at a quinol oxidation site (QD) located in the vicinity of the distal heme bD. Here molecular details of the interaction between the semiquinone radical and the protein environment have been provided using advanced multifrequency pulsed EPR methods. 14N and 15N ESEEM and HYSCORE measurements carried out at X-band (∼9.7 GHz) on the wild-type enzyme or the enzyme uniformly labeled with 15N nuclei reveal an interaction between the semiquinone and a single nitrogen nucleus. The isotropic hyperfine coupling constant Aiso(14N) ∼0.8 MHz shows that it occurs via an H-bond to one of the quinone carbonyl group. Using 14N ESEEM and HYSCORE spectroscopies at a lower frequency (S-band, ∼3.4 GHz), the 14N nuclear quadrupolar parameters of the interacting nitrogen nucleus (κ = 0.49, η = 0.50) were determined and correspond to those of a histidine Nδ, assigned to the heme bD ligand His-66 residue. Moreover S-band 15N ESEEM spectra enabled us to directly measure the anisotropic part of the nitrogen hyperfine interaction (T(15N) = 0.16 MHz). A distance of ∼2.2 Åbetween the carbonyl oxygen and the nitrogen could then be calculated. Mechanistic implications of these results are discussed in the context of the peculiar properties of the menasemiquinone intermediate stabilized at the QD site of NarGHI.

Recent advances in cytochrome bc(1): inter monomer electronic communication?

The ubihydroquinone: cytochrome c oxidoreductase, or cytochrome bc 1, is a central component of photosynthetic and respiratory energy transduction pathways in many organisms. It contributes to the generation of membrane potential and proton gradient used for cellular energy production (ATP). The three‐dimensional structures of cytochrome bc 1 indicate that its two monomers are intertwined to form a symmetrical homodimer. This unusual architecture raises the issue of whether the monomers operate independently, or function cooperatively during the catalytic cycle of the enzyme. In this review, recent progresses achieved in our understanding of the mechanism of function of dimeric cytochrome bc 1 are presented. New genetic approaches producing heterodimeric enzymes, and emerging insights related to the inter monomer electron transfer between the heme b cofactors of cytochrome bc 1 are described.

Determination of the proton environment of high stability Menasemiquinone intermediate in Escherichia coli nitrate reductase A by pulsed EPR.

Background: Escherichia coli nitrate reductase A highly stabilizes a semiquinone catalytic intermediate. Results: Three proton hyperfine couplings to this radical with atypical characteristics are characterized. Conclusion: Semiquinone binding is strongly asymmetric and occurs via a single short in-plane H-bond. Significance: Learning how the protein environment tunes the semiquinone properties is crucial for understanding the quinol utilization mechanism by energy-transducing enzymes. Escherichia coli nitrate reductase A (NarGHI) is a membrane-bound enzyme that couples quinol oxidation at a periplasmically oriented Q-site (QD) to proton release into the periplasm during anaerobic respiration. To elucidate the molecular mechanism underlying such a coupling, endogenous menasemiquinone-8 intermediates stabilized at the QD site (MSQD) of NarGHI have been studied by high-resolution pulsed EPR methods in combination with 1H2O/2H2O exchange experiments. One of the two non-exchangeable proton hyperfine couplings resolved in hyperfine sublevel correlation (HYSCORE) spectra of the radical displays characteristics typical from quinone methyl protons. However, its unusually small isotropic value reflects a singularly low spin density on the quinone carbon α carrying the methyl group, which is ascribed to a strong asymmetry of the MSQD binding mode and consistent with single-sided hydrogen bonding to the quinone oxygen O1. Furthermore, a single exchangeable proton hyperfine coupling is resolved, both by comparing the HYSCORE spectra of the radical in 1H2O and 2H2O samples and by selective detection of the exchanged deuterons using Q-band 2H Mims electron nuclear double resonance (ENDOR) spectroscopy. Spectral analysis reveals its peculiar characteristics, i.e. a large anisotropic hyperfine coupling together with an almost zero isotropic contribution. It is assigned to a proton involved in a short ∼1.6 Å in-plane hydrogen bond between the quinone O1 oxygen and the Nδ of the His-66 residue, an axial ligand of the distal heme bD. Structural and mechanistic implications of these results for the electron-coupled proton translocation mechanism at the QD site are discussed, in light of the unusually high thermodynamic stability of MSQD.

The cytochrome b Zn binding amino acid residue histidine 291 is essential for ubihydroquinone oxidation at the Qo site of bacterial cytochrome bc1

The ubiquinol:cytochrome (cyt) c oxidoreductase (or cyt bc1) is an important membrane protein complex in photosynthetic and respiratory energy transduction. In bacteria such as Rhodobacter capsulatus it is constituted of three subunits: the iron-sulfur protein, cyt b and cyt c1, which form two catalytic domains, the Qo (hydroquinone (QH2) oxidation) and Qi (quinone (Q) reduction) sites. At the Qo site, the pathways of bifurcated electron transfers emanating from QH2 oxidation are known, but the associated proton release routes are not well defined. In energy transducing complexes, Zn2+ binding amino acid residues often correlate with proton uptake or release pathways. Earlier, using combined EXAFS and structural studies, we identified Zn coordinating residues of mitochondrial and bacterial cyt bc1. In this work, using the genetically tractable bacterial cyt bc1, we substituted each of the proposed Zn binding residues with non-protonatable side chains. Among these mutants, only the His291Leu substitution destroyed almost completely the Qo site catalysis without perturbing significantly the redox properties of the cofactors or the assembly of the complex. In this mutant, which is unable to support photosynthetic growth, the bifurcated electron transfer reactions that result from QH2 oxidation at the Qo site, as well as the associated proton(s) release, were dramatically impaired. Based on these findings, on the putative role of His291 in liganding Zn, and on its solvent exposed and highly conserved position, we propose that His291 of cyt b is critical for proton release associated to QH2 oxidation at the Qo site of cyt bc1.