Your search keyword '"Verkhovskaya ML"' showing total 25 results

1. Real-time kinetics of electrogenic Na(+) transport by rhodopsin from the marine flavobacterium Dokdonia sp. PRO95.

Author

Bogachev AV, Bertsova YV, Verkhovskaya ML, Mamedov MD, and Skulachev VP

Subjects

Bacterial Proteins chemistry, Bacterial Proteins genetics, Cations, Monovalent, Cloning, Molecular, Escherichia coli genetics, Escherichia coli metabolism, Flavobacteriaceae genetics, Gene Expression, Ion Transport, Kinetics, Light, Protein Binding, Protein Structure, Secondary, Protein Transport, Proteolipids chemistry, Proteolipids metabolism, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Rhodopsin chemistry, Rhodopsin genetics, Time Factors, Bacterial Proteins metabolism, Flavobacteriaceae metabolism, Membrane Potentials physiology, Rhodopsin metabolism, Sodium metabolism

Abstract

Discovery of the light-driven sodium-motive pump Na(+)-rhodopsin (NaR) has initiated studies of the molecular mechanism of this novel membrane-linked energy transducer. In this paper, we investigated the photocycle of NaR from the marine flavobacterium Dokdonia sp. PRO95 and identified electrogenic and Na(+)-dependent steps of this cycle. We found that the NaR photocycle is composed of at least four steps: NaR519 + hv → K585 → (L450↔M495) → O585 → NaR519. The third step is the only step that depends on the Na(+) concentration inside right-side-out NaR-containing proteoliposomes, indicating that this step is coupled with Na(+) binding to NaR. For steps 2, 3, and 4, the values of the rate constants are 4×10(4) s(-1), 4.7 × 10(3) M(-1) s(-1), and 150 s(-1), respectively. These steps contributed 15, 15, and 70% of the total membrane electric potential (Δψ ~ 200 mV) generated by a single turnover of NaR incorporated into liposomes and attached to phospholipid-impregnated collodion film. On the basis of these observations, a mechanism of light-driven Na(+) pumping by NaR is suggested.

Published

2016

2. Identification of the coupling step in Na(+)-translocating NADH:quinone oxidoreductase from real-time kinetics of electron transfer.

Author

Belevich NP, Bertsova YV, Verkhovskaya ML, Baykov AA, and Bogachev AV

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, Cations, Monovalent, Cloning, Molecular, Electron Transport, Gene Expression, Ion Transport, Kinetics, Microfluidic Analytical Techniques, Models, Molecular, NAD chemistry, NAD metabolism, NAD(P)H Dehydrogenase (Quinone) genetics, NAD(P)H Dehydrogenase (Quinone) metabolism, Oxidation-Reduction, Protein Subunits genetics, Protein Subunits metabolism, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Sodium metabolism, Ubiquinone chemistry, Ubiquinone metabolism, Vibrio chemistry, Vibrio genetics, Vibrio cholerae chemistry, Vibrio cholerae genetics, Bacterial Proteins chemistry, NAD(P)H Dehydrogenase (Quinone) chemistry, Protein Subunits chemistry, Sodium chemistry, Vibrio enzymology, Vibrio cholerae enzymology

Abstract

Bacterial Na(+)-translocating NADH:quinone oxidoreductase (Na(+)-NQR) uses a unique set of prosthetic redox groups-two covalently bound FMN residues, a [2Fe-2S] cluster, FAD, riboflavin and a Cys4[Fe] center-to catalyze electron transfer from NADH to ubiquinone in a reaction coupled with Na(+) translocation across the membrane. Here we used an ultra-fast microfluidic stopped-flow instrument to determine rate constants and the difference spectra for the six consecutive reaction steps of Vibrio harveyi Na(+)-NQR reduction by NADH. The instrument, with a dead time of 0.25 ms and optical path length of 1 cm allowed collection of visible spectra in 50-μs intervals. By comparing the spectra of reaction steps with the spectra of known redox transitions of individual enzyme cofactors, we were able to identify the chemical nature of most intermediates and the sequence of electron transfer events. A previously unknown spectral transition was detected and assigned to the Cys4[Fe] center reduction. Electron transfer from the [2Fe-2S] cluster to the Cys4[Fe] center and all subsequent steps were markedly accelerated when Na(+) concentration was increased from 20 μM to 25 mM, suggesting coupling of the former step with tight Na(+) binding to or occlusion by the enzyme. An alternating access mechanism was proposed to explain electron transfer between subunits NqrF and NqrC. According to the proposed mechanism, the Cys4[Fe] center is alternatively exposed to either side of the membrane, allowing the [2Fe-2S] cluster of NqrF and the FMN residue of NqrC to alternatively approach the Cys4[Fe] center from different sides of the membrane., (Copyright © 2015 Elsevier B.V. All rights reserved.)

Published

2016

3. Redox-induced activation of the proton pump in the respiratory complex I.

Author

Sharma V, Belevich G, Gamiz-Hernandez AP, Róg T, Vattulainen I, Verkhovskaya ML, Wikström M, Hummer G, and Kaila VR

Subjects

Electron Transport, Escherichia coli metabolism, Lipid Bilayers chemistry, Molecular Dynamics Simulation, Mutagenesis, Site-Directed, Photosynthetic Reaction Center Complex Proteins physiology, Protein Binding, Protein Structure, Tertiary, Proton Pumps physiology, Static Electricity, Temperature, Thermus thermophilus enzymology, X-Rays, Electron Transport Complex I physiology, Oxidation-Reduction

Abstract

Complex I functions as a redox-linked proton pump in the respiratory chains of mitochondria and bacteria, driven by the reduction of quinone (Q) by NADH. Remarkably, the distance between the Q reduction site and the most distant proton channels extends nearly 200 Å. To elucidate the molecular origin of this long-range coupling, we apply a combination of large-scale molecular simulations and a site-directed mutagenesis experiment of a key residue. In hybrid quantum mechanics/molecular mechanics simulations, we observe that reduction of Q is coupled to its local protonation by the His-38/Asp-139 ion pair and Tyr-87 of subunit Nqo4. Atomistic classical molecular dynamics simulations further suggest that formation of quinol (QH2) triggers rapid dissociation of the anionic Asp-139 toward the membrane domain that couples to conformational changes in a network of conserved charged residues. Site-directed mutagenesis data confirm the importance of Asp-139; upon mutation to asparagine the Q reductase activity is inhibited by 75%. The current results, together with earlier biochemical data, suggest that the proton pumping in complex I is activated by a unique combination of electrostatic and conformational transitions.

Published

2015

4. Aerobic respiratory chain of Escherichia coli is not allowed to work in fully uncoupled mode.

Author

Borisov VB, Murali R, Verkhovskaya ML, Bloch DA, Han H, Gennis RB, and Verkhovsky MI

Subjects

Adenosine Triphosphate biosynthesis, Aerobiosis, Cytochrome b Group, Cytochromes metabolism, Electron Transport Chain Complex Proteins metabolism, Escherichia coli Proteins metabolism, Membrane Potentials, Models, Biological, NAD metabolism, Oxidoreductases metabolism, Proton-Motive Force, Electron Transport, Escherichia coli metabolism

Abstract

Escherichia coli is known to couple aerobic respiratory catabolism to ATP synthesis by virtue of the primary generators of the proton motive force-NADH dehydrogenase I, cytochrome bo(3), and cytochrome bd-I. An E. coli mutant deficient in NADH dehydrogenase I, bo(3) and bd-I can, nevertheless, grow aerobically on nonfermentable substrates, although its sole terminal oxidase cytochrome bd-II has been reported to be nonelectrogenic. In the current work, the ability of cytochrome bd-II to generate a proton motive force is reexamined. Absorption and fluorescence spectroscopy and oxygen pulse methods show that in the steady-state, cytochrome bd-II does generate a proton motive force with a H(+)/e(-) ratio of 0.94 ± 0.18. This proton motive force is sufficient to drive ATP synthesis and transport of nutrients. Microsecond time-resolved, single-turnover electrometry shows that the molecular mechanism of generating the proton motive force is identical to that in cytochrome bd-I. The ability to induce cytochrome bd-II biosynthesis allows E. coli to remain energetically competent under a variety of environmental conditions.

Published

2011

5. Chapter 4 Electron transfer in respiratory complexes resolved by an ultra-fast freeze-quench approach.

Author

Belevich NP, Verkhovskaya ML, and Verkhovsky MI

Subjects

Biocatalysis, Electron Spin Resonance Spectroscopy, Kinetics, Electron Transport, Freezing

Abstract

The investigation of the molecular mechanism of the respiratory chain complexes requires determination of the time-dependent evolution of the catalytic cycle intermediates. The ultra-fast freeze-quench approach makes possible trapping such intermediates with consequent analysis of their chemical structure by means of different physical spectroscopic methods (e.g., EPR, optic, and Mössbauer spectroscopies). This chapter presents the description of a setup that allows stopping the enzymatic reaction in the time range from 100 microsec to tens of msec. The construction and production technology of the mixer head, ultra-fast freezing device, and accessories required for collecting a sample are described. Ways of solving a number of problems emerging on freezing of the reaction mixture and preparing the samples for EPR spectroscopy are proposed. The kinetics of electron transfer reaction in the first enzyme of the respiratory chain, Complex I (NADH: ubiquinone oxidoreductase), is presented as an illustration of the freeze-quench approach. Time-resolved EPR spectra indicating the redox state of FeS clusters of the wild-type and mutant (R274A in subunit NuoCD) Complex I from Escherichia coli are shown.

Published

2009

6. Real-time electron transfer in respiratory complex I.

Author

Verkhovskaya ML, Belevich N, Euro L, Wikström M, and Verkhovsky MI

Subjects

Electron Spin Resonance Spectroscopy, Electron Transport, Kinetics, NAD, Oxidation-Reduction, Thermus thermophilus, Electron Transport Complex I chemistry, Escherichia coli chemistry

Abstract

Electron transfer in complex I from Escherichia coli was investigated by an ultrafast freeze-quench approach. The reaction of complex I with NADH was stopped in the time domain from 90 mus to 8 ms and analyzed by electron paramagnetic resonance (EPR) spectroscopy at low temperatures. The data show that after binding of the first molecule of NADH, two electrons move via the FMN cofactor to the iron-sulfur (Fe/S) centers N1a and N2 with an apparent time constant of approximately 90 mus, implying that these two centers should have the highest redox potential in the enzyme. The rate of reduction of center N2 (the last center in the electron transfer sequence) is close to that predicted by electron transfer theory, which argues for the absence of coupled proton transfer or conformational changes during electron transfer from FMN to N2. After fast reduction of N1a and N2, we observe a slow, approximately 1-ms component of reduction of other Fe/S clusters. Because all elementary electron transfer rates between clusters are several orders of magnitude higher than this observed rate, we conclude that the millisecond component is limited by a single process corresponding to dissociation of the oxidized NAD(+) molecule from its binding site, where it prevents entry of the next NADH molecule. Despite the presence of approximately one ubiquinone per enzyme molecule, no transient semiquinone formation was observed, which has mechanistic implications, suggesting a high thermodynamic barrier for ubiquinone reduction to the semiquinone radical. Possible consequences of these findings for the proton translocation mechanism are discussed.

Published

2008

7. Activation of isolated NADH:ubiquinone reductase I (complex I) from Escherichia coli by detergent and phospholipids. Recovery of ubiquinone reductase activity and changes in EPR signals of iron-sulfur clusters.

Author

Sinegina L, Wikström M, Verkhovsky MI, and Verkhovskaya ML

Subjects

Detergents, Dose-Response Relationship, Drug, Electron Spin Resonance Spectroscopy, Electron Transport Complex I isolation & purification, Electron Transport Complex II chemistry, Electron Transport Complex II metabolism, Enzyme Activation, Escherichia coli Proteins isolation & purification, NAD chemistry, NAD metabolism, Ruthenium Compounds metabolism, Electron Transport Complex I chemistry, Electron Transport Complex I metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Glucosides chemistry, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism, Phospholipids chemistry

Abstract

NADH:ubiquinone oxidoreductase (NDH-1 or complex I) from Escherichia coli was purified using a combination of anion exchange chromatography and centrifugation in sucrose density gradient. The dependence of enzyme activity on detergent and phospholipids was studied. Artificial hexaammineruthenium reductase activity was not affected by dodecyl maltoside (DDM) and asolectin. Ubiquinone reductase activity had a bell-shape dependence on DDM concentration; 7-10-fold activation could be achieved. Treatment with asolectin subsequently yields additional 2-fold activation with a corresponding increase in the apparent V(max) and without significant changes in apparent K(m). Comparative EPR studies of complex I reduced with NADH, "as prepared" and "activated by asolectin" showed an increase in the signals derived mainly from two [4Fe-4S] clusters in the activated enzyme. One of these signals could be simulated with an axial spectrum with g values of g(xyz)= 1.895, 1.904, 2.05, which corresponds to the parameters reported for the N2 cluster. This data indicates conformational rearrangements of catalytic importance in complex I upon binding of phospholipids.

Published

2005

8. Deletion of one of two Escherichia coli genes encoding putative Na+/H+ exchangers (ycgO) perturbs cytoplasmic alkali cation balance at low osmolarity.

Author

Verkhovskaya ML, Barquera B, and Wikström M

Subjects

Amino Acid Sequence, Biological Transport, Cation Transport Proteins, Escherichia coli genetics, Escherichia coli growth & development, Escherichia coli Proteins genetics, Genes, Bacterial, Hydrogen-Ion Concentration, Membrane Potentials, Molecular Sequence Data, Mutation, Osmolar Concentration, Oxygen metabolism, Phenotype, Plasmids genetics, Potassium metabolism, Sequence Homology, Amino Acid, Sodium-Hydrogen Exchangers genetics, Escherichia coli metabolism, Escherichia coli Proteins physiology, Sodium metabolism, Sodium-Hydrogen Exchangers physiology

Abstract

Two genes in the Escherichia coli genome, b4065 (yjcE) and b1191 (ycgO), are similar to genes encoding eukaryotic Na+/H+ exchangers. Mutants were constructed in which yjcE (GRN11), ycgO (GRF55) or both (GRD22) were inactivated. There was no change in respiration-driven Na+ efflux in any of the mutants when grown in media containing 50-500 mM Na+. The only striking finding was that growth of GRF55 was impaired at low osmolarity. In complex low-salt medium, GRF55 grew at a wild-type rate for three to four generations but then stopped; the growth was partially recovered after a pause, the length of which was dependent on salt concentration. Measurement of cytoplasmic alkali cations showed that an abrupt loss of about one-half of the intracellular K+ preceded the pause. When grown in low-salt medium with only 20 mM added Na+, GRF55 also lost the ability to maintain a sodium concentration gradient. However, this phenomenon appears to be a secondary effect of the ycgO deletion. The double mutant GRD22 has the same properties as GRF55; no additional effect was found. The data indicate that neither ycgO nor yjeE participates in respiration-driven Na+ extrusion. Instead, ycgO is required for growth at low osmolarity. Hence it is concluded that ycgO participates in cell volume regulation, and accordingly it is suggested that ycgO be renamed cvrA.

Published

2001

9. Heme-copper oxidases with modified D- and K-pathways are yet efficient proton pumps.

Author

Gomes CM, Backgren C, Teixeira M, Puustinen A, Verkhovskaya ML, Wikström M, and Verkhovsky MI

Subjects

Amino Acid Substitution, Archaea, Cytochrome b Group genetics, Cytochrome b Group metabolism, Electron Transport, Electron Transport Complex IV genetics, Electron Transport Complex IV metabolism, Ion Channels chemistry, Ion Channels metabolism, Models, Molecular, Molecular Sequence Data, Mutagenesis, Site-Directed, Oxidoreductases genetics, Oxygen Consumption drug effects, Paracoccus denitrificans, Protons, Reducing Agents pharmacology, Sequence Homology, Amino Acid, Signal Transduction drug effects, Thermus thermophilus, Oxidoreductases metabolism, Proton Pumps metabolism

Abstract

The cytochrome aa(3)-type quinol oxidase from the archaeon Acidianus ambivalens and the ba(3)-type cytochrome c oxidase from Thermus thermophilus are divergent members of the heme-copper oxidase superfamily of enzymes. In particular they lack most of the key residues involved in the proposed proton transfer pathways. The pumping capability of the A. ambivalens enzyme was investigated and found to occur with the same efficiency as the canonical enzymes. This is the first demonstration of pumping of 1 H(+)/electron in a heme-copper oxidase that lacks most residues of the K- and D-channels. Also, the structure of the ba(3) oxidase from T. thermophilus was simulated by mutating Phe274 to threonine and Glu278 to isoleucine in the D-pathway of the Paracoccus denitrificans cytochrome c oxidase. This modification resulted in full efficiency of proton translocation albeit with a substantially lowered turnover. Together, these findings show that multiple structural solutions for efficient proton conduction arose during evolution of the respiratory oxidases, and that very few residues remain invariant among these enzymes to function in a common proton-pumping mechanism.

Published

2001

10. The caa(3) terminal oxidase of Rhodothermus marinus lacking the key glutamate of the D-channel is a proton pump.

Author

Pereira MM, Verkhovskaya ML, Teixeira M, and Verkhovsky MI

Subjects

Amino Acid Sequence, Copper chemistry, Cytochrome c Group isolation & purification, Electron Transport Complex IV isolation & purification, Glutamic Acid, Heme analogs & derivatives, Heme chemistry, Macromolecular Substances, Models, Molecular, Molecular Sequence Data, Protein Conformation, Proton Pumps isolation & purification, Sequence Alignment, Sequence Homology, Amino Acid, Cytochrome c Group chemistry, Electron Transport Complex IV chemistry, Gram-Negative Aerobic Bacteria enzymology, Liposomes chemistry, Liposomes metabolism, Proteolipids chemistry, Proteolipids metabolism, Proton Pumps chemistry, Proton Pumps metabolism, Tyrosine

Abstract

The thermohalophilic bacterium Rhodothermus marinus expresses a caa(3)-type dioxygen reductase as one of its terminal oxidases. The subunit I amino acid sequence shows the presence of all the essential residues of the D- and K-proton channels, defined in most heme-copper oxidases, with the exception of the key glutamate residue located in the middle of the membrane dielectric (E278 in Paracoccus denitrificans). On the basis of homology modeling studies, a tyrosine residue (Y256, R. marinus numbering) has been proposed to act as a functional substitute [Pereira, M. M., Santana, M., Soares, C. M., Mendes, J., Carita, J. N., Fernandes, A. S., Saraste, M., Carrondo, M. A., and Teixeira, M. (1999) Biochim. Biophys. Acta 1413, 1-13]. Here, R. marinus caa(3) oxidase was reconstituted in liposomes and shown to operate as a proton pump, translocating protons from the cytoplasmic side of the bacterial inner membrane to the periplasmatic space with a stoichiometry of 1H(+)/e(-), as in the case in heme-copper oxidases that contain the glutamate residue. Possible mechanisms of proton transfer in the D-channel with the participation of the tyrosine residue are discussed. The observation that the tyrosine residue is conserved in several other members of the heme-copper oxidase superfamily suggests a common alternative mode of action for the D-channel.

Published

2000

11. Sequencing and preliminary characterization of the Na+-translocating NADH:ubiquinone oxidoreductase from Vibrio harveyi.

Author

Zhou W, Bertsova YV, Feng B, Tsatsos P, Verkhovskaya ML, Gennis RB, Bogachev AV, and Barquera B

Subjects

Amino Acid Sequence, Catalysis, Electron Transport Complex I, Energy Metabolism, Flavin-Adenine Dinucleotide isolation & purification, Ligands, Molecular Sequence Data, NADH, NADPH Oxidoreductases genetics, NADH, NADPH Oxidoreductases isolation & purification, NADH, NADPH Oxidoreductases metabolism, Operon, Sequence Analysis, Protein, Sequence Homology, Amino Acid, Sodium metabolism, NADH, NADPH Oxidoreductases chemistry, Vibrio enzymology

Abstract

The Na(+)-translocating NADH: ubiquinone oxidoreductase (Na(+)-NQR) generates an electrochemical Na(+) potential driven by aerobic respiration. Previous studies on the enzyme from Vibrio alginolyticus have shown that the Na(+)-NQR has six subunits, and it is known to contain FAD and an FeS center as redox cofactors. In the current work, the enzyme from the marine bacterium Vibrio harveyi has been purified and characterized. In addition to FAD, a second flavin, tentatively identified as FMN, was discovered to be covalently attached to the NqrC subunit. The purified V. harveyi Na(+)-NQR was reconstituted into proteoliposomes. The generation of a transmembrane electric potential by the enzyme upon NADH:Q(1) oxidoreduction was strictly dependent on Na(+), resistant to the protonophore CCCP, and sensitive to the sodium ionophore ETH-157, showing that the enzyme operates as a primary electrogenic sodium pump. Interior alkalinization of the inside-out proteoliposomes due to the operation of the Na(+)-NQR was accelerated by CCCP, inhibited by valinomycin, and completely arrested by ETH-157. Hence, the protons required for ubiquinol formation must be taken up from the outside of the liposomes, which corresponds to the bacterial cytoplasm. The Na(+)-NQR operon from this bacterium was sequenced, and the sequence shows strong homology to the previously reported Na(+)-NQR operons from V. alginolyticus and Haemophilus influenzae. Homology studies show that a number of other bacteria, including a number of pathogenic species, also have an Na(+)-NQR operon.

Published

1999

12. Proton translocation by cytochrome c oxidase.

Author

Verkhovsky MI, Jasaitis A, Verkhovskaya ML, Morgan JE, and Wikström M

Subjects

Animals, Biological Transport, Catalysis, Cattle, Electron Transport, Electron Transport Complex IV chemistry, Hydrogen-Ion Concentration, Liposomes, Membrane Potentials, Mitochondria, Heart enzymology, Oxidation-Reduction, Oxygen metabolism, Proton Pumps chemistry, Electron Transport Complex IV metabolism, Proton Pumps metabolism

Abstract

Cell respiration in mitochondria and some bacteria is catalysed by cytochrome c oxidase, which reduces O2 to water, coupled with translocation of four protons across the mitochondrial or bacterial membrane. The enzyme's catalytic cycle consists of a reductive phase, in which the oxidized enzyme receives electrons from cytochrome c, and an oxidative phase, in which the reduced enzyme is oxidized by O2. Previous studies indicated that proton translocation is coupled energetically only to the oxidative phase, but this has been challenged. Here, with the purified enzyme inlaid in liposomes, we report time-resolved measurements of membrane potential, which show that half of the electrical charges due to proton-pumping actually cross the membrane during reduction after a preceding oxidative phase. pH measurements confirm that proton translocation also occurs during reduction, but only when immediately preceded by an oxidative phase. We conclude that all the energy for proton translocation is conserved in the enzyme during its oxidation by O2. One half of it is utilized for proton-pumping during oxidation, but the other half is unlatched for this purpose only during re-reduction of the enzyme.

Published

1999

13. Coordination of CuB in reduced and CO-liganded states of cytochrome bo3 from Escherichia coli. Is chloride ion a cofactor?

Author

Ralle M, Verkhovskaya ML, Morgan JE, Verkhovsky MI, Wikström M, and Blackburn NJ

Subjects

Animals, Bromides chemistry, Cattle, Chlorides metabolism, Cytochrome b Group, Cytochromes metabolism, Escherichia coli Proteins, Fourier Analysis, Histidine chemistry, Imidazoles chemistry, Ligands, Oxidation-Reduction, Photolysis, Spectrometry, X-Ray Emission, Carbon Monoxide chemistry, Chlorides chemistry, Copper chemistry, Cytochromes chemistry, Escherichia coli enzymology

Abstract

The ubiquinol oxidase cytochrome bo3 from Escherichia coli is one of the respiratory heme-copper oxidases which catalyze the reduction of O2 to water linked to translocation of protons across the bacterial or mitochondrial membrane. We have studied the structure of the CuB site in the binuclear heme-copper center of O2 reduction by EXAFS spectroscopy in the fully reduced state of this enzyme, as well as in the reduced CO-liganded states where CO is bound either to the heme iron or to CuB. We find that, in the reduced enzyme, CuB is coordinated by one weakly bound and two strongly bound histidine imidazoles at Cu-N distances of 2.10 and 1.92 A, respectively, and that an additional feature at 2.54 A is due to a highly ordered water molecule that might be weakly associated with the copper. Unexpectedly, the binding of CO to heme iron is found to result in a major conformational change at CuB, which now binds only two equidistant histidine imidazoles at 1.95 A and a chloride ion at 2. 25 A, with elimination of the water molecule and one of the histidines. Attempts to remove the chloride from the enzyme by extensive dialysis did not change this finding, nor did substitution of chloride with bromide. Photolysis of CO bound to the heme iron is known to cause the CO to bind to CuB in a very fast reaction and to remain bound to CuB at low temperatures. In this state, we indeed find the CO to be bound to CuB at a Cu-C distance of 1.85 A, with chloride still bound at 2.25 A and the two histidine imidazoles at a Cu-N distance of 2.01 A. These results suggest that reduction of the binuclear site weakens the bond between CuB and one of its three histidine imidazole ligands, and that binding of CO to the reduced binuclear site causes a major structural change in CuB in which one histidine ligand is lost and replaced by a chloride ion. Whether chloride is a cofactor in this enzyme is discussed.

Published

1999

14. Assignment and charge translocation stoichiometries of the major electrogenic phases in the reaction of cytochrome c oxidase with dioxygen.

Author

Jasaitis A, Verkhovsky MI, Morgan JE, Verkhovskaya ML, and Wikström M

Subjects

Animals, Cattle, Electron Transport, Lipid Bilayers chemistry, Mathematical Computing, Membrane Potentials, Models, Biological, Models, Chemical, Oxidation-Reduction, Phospholipids chemistry, Photolysis, Potentiometry, Time Factors, Electron Transport Complex IV chemistry, Oxygen chemistry

Abstract

The reaction of cytochrome c oxidase with dioxygen has been studied by means of time-resolved measurements of electrical membrane potential (DeltaPsi). Microsecond time resolution was achieved by starting with the CO-inhibited enzyme, which was photolyzed after addition of oxygen. The time course of the reaction could be fitted by using a five-step sequential reaction as a model. The first two phases of the reaction, which correspond in time to binding of oxygen followed by formation of the P (peroxy) intermediate, as observed spectroscopically, are not associated with net charge displacement across the membrane. After this lag, DeltaPsi develops in three phases, which correspond in time to the conversion of P to the F (ferryl) intermediate, in a single phase, and conversion of F to O (the fully oxidized enzyme), in two phases. The amplitude of DeltaPsi was approximately equal for the P --> F and F --> O portions of the reaction. When the oxygen reaction is started with incompletely reduced enzyme, it will halt at the P or F state. When the reaction was allowed to proceed to the F state, but no further, only the fast phase of DeltaPsi formation was observed, whereas no DeltaPsi was generated if the reaction was halted at P. This finding places the assignments of phases in the electrometric data on a firmer basis-they are no longer based solely on temporal correspondence with phases in the spectroscopic data. To define the number of charges transferred across the membrane during the reaction, some kind of calibration is needed. For this purpose, another type of reaction-electron transfer following CO photolysis in the absence of oxygen ("backflow")-was studied. Parallel spectroscopic and electrometric measurements showed that the fast electron transfer from the low-spin heme to CuA in the backflow process results in approximately 11 times smaller amplitude of DeltaPsi as compared with DeltaPsi generated in the reaction of the reduced enzyme with oxygen (the polarity is also reversed). If it is assumed that transfer of an electron from the low-spin heme to CuA amounts to movement of a unit charge across half of the membrane dielectric, charge translocation in the reaction of the reduced enzyme with oxygen amounts to approximately 5.5 unit charges-the value predicted if all four protons pumped during the catalytic cycle are translocated during the oxidative part of the reaction.

Published

1999

15. The Na+ and K+ transport deficiency of an E. coli mutant lacking the NhaA and NhaB proteins is apparent and caused by impaired osmoregulation.

Author

Verkhovskaya ML, Barquera B, Verkhovsky MI, and Wikström M

Subjects

Cell Division, Cytoplasm metabolism, Escherichia coli genetics, Ion Transport, Membrane Proteins genetics, Mutation, Sodium-Hydrogen Exchangers genetics, Water-Electrolyte Balance, Bacterial Proteins, Escherichia coli metabolism, Escherichia coli Proteins, Membrane Proteins metabolism, Potassium metabolism, Sodium metabolism, Sodium-Hydrogen Exchangers metabolism

Abstract

Cells of the E. coli mutant EP432, which lacks the two Na+/H+ antiporters, NhaA and NhaB, have been reported to have an impaired sodium transport activity (Harel-Bronstein et al. (1995) J. Biol. Chem. 270, 3816-3822). Here we report that active transport of Na+ in EP432 cells can be restored to wild-type levels, either by a high K+ concentration or by an increase in the medium osmolarity. We suggest that this mutant is primarily deficient in osmoregulation rather than in cation transport per se.

Published

1998

16. Glutamic acid 286 in subunit I of cytochrome bo3 is involved in proton translocation.

Author

Verkhovskaya ML, Garcìa-Horsman A, Puustinen A, Rigaud JL, Morgan JE, Verkhovsky MI, and Wikström M

Subjects

Cytochrome b Group, Cytochromes chemistry, Cytochromes genetics, Escherichia coli enzymology, Escherichia coli Proteins, Glutamic Acid genetics, Ion Transport, Mutagenesis, Site-Directed, Proteolipids metabolism, Protons, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Spectroscopy, Fourier Transform Infrared, Cytochromes metabolism, Glutamic Acid metabolism

Abstract

Glutamic acid 286 (E286; Escherichia coli cytochrome bo3 numbering) in subunit I of the respiratory heme-copper oxidases is highly conserved and has been suggested to be involved in proton translocation. We report a technique of enzyme reconstitution that yields essentially unidirectionally oriented cytochrome bo3 vesicles in which proton translocation can be measured. Such experiments are not feasible in the E286Q mutant due to strong inhibition of respiration, but this is not the case for the mutants E286D and E286C. The reconstituted E286D mutant enzyme readily translocates protons whereas E286C does not. Loss of proton translocation in the D135N mutant, but not in D135E or D407N, also is verified using proteoliposomes. Stopped-flow experiments show that the peroxy intermediate accumulates in the reaction of the E286Q and E286C mutant enzymes with O2. We conclude that an acidic function of the 286 locus is essential for the mechanism of proton translocation.

Published

1997

17. The respiration-driven active sodium transport system in E. coli does not function with lithium.

Author

Verkhovskaya ML, Verkhovsky MI, and Wikström M

Subjects

Biological Transport, Active, Potassium metabolism, Escherichia coli metabolism, Lithium metabolism, Sodium metabolism

Abstract

Comparison of respiration-driven active transport of alkali cations from E. coli cells loaded with Na+ or Li+ showed that Li+ could not be expelled from the cells like Na+. K+ accumulation, which was fast in Na+-loaded cells, was strongly inhibited in Li+-loaded cells, despite high membrane potential and respiratory rate. When Li+-loaded cells were placed into medium containing Na+ instead of Li+, Li+/Na+ exchange took place initially, while K+ accumulation was delayed. Only after almost all inside Li+ was replaced by Na+ did active Na+ and K+ transport commence. These data confirm that it is a distinct active sodium transport system (AST) with Na+,K+/H+ antiporter activity, and not the Na+/H+ antiporters, that is responsible for active Na+ transport in E. coli [Verkhovskaya, M.L., Verkhovsky, M.I. and Wikstrom, M. (1996) Biochim. Biophys. Acta 1273, 207-216]. In contrast to the Na+/H+ antiporters, the AST system is inhibited by Li+.

Published

1996

18. K+-dependent Na+ transport driven by respiration in Escherichia coli cells and membrane vesicles.

Author

Verkhovskaya ML, Verkhovsky MI, and Wikström M

Subjects

Biological Transport drug effects, Carbonyl Cyanide m-Chlorophenyl Hydrazone pharmacology, Carrier Proteins metabolism, Escherichia coli genetics, Escherichia coli growth & development, Fluorescent Dyes, Hydrogen-Ion Concentration, Kinetics, Potassium metabolism, Sodium-Hydrogen Exchangers metabolism, Spectrometry, Fluorescence, Valinomycin pharmacology, Cell Membrane metabolism, Escherichia coli metabolism, Oxygen Consumption, Sodium metabolism

Abstract

Respiration-driven Na+ transport from Escherichia coli cells and right-side-out membrane vesicles is strictly dependent on K+. Cells from an E. colic mutant deficient in three major K+ transport systems were incapable of accumulating K+ or expelling Na+ unless valinomycin was added. Membrane vesicles from an E. coli mutant from which the genes encoding the two known electrogenic Na+/nH+ antiporters nhaA and nhaB were deleted transported Na+ as well as did vesicles from wild-type cells. Quantitative analysis of Delta psi and Delta pH showed a high driving force for electrogenic Na+/nH+ antiport whether K+ was present or not, although Na+ transport occurred only in its presence. These results suggest that an Na+/nH+ antiporter is not responsible for the Na+ transport. Respiration-driven efflux of Na+ from vesicles was found to be accompanied by primary uphill efflux of K+. Also, no respiration-dependent efflux of K+ was observed in the absence of Na+. Such coupling between Na+ and K+ fluxes may be explained by the operation of an Na+, K+/H+ antiporter previously described in E. coli membrane vesicles (Verkhovskay, M.L., Verkhovsky, M.I. and Wikström, M. (1995) FEBS Lett. 363, 46-48). Active Na+ transport is abolished when delta mu H+ is eliminated by a protonophore, but at low concentrations the protonophore actually accelerated Na+ transport. Such an effect may be expected if the Na+, K+/H+ antiporter normally operates in tight conjunction with respiratory chain complexes, thus exhibiting some phenomenological properties of a primary redox-linked sodium pump.

Published

1996

19. Structure of CuB in the binuclear heme-copper center of the cytochrome aa3-type quinol oxidase from Bacillus subtilis: an ENDOR and EXAFS study.

Author

Fann YC, Ahmed I, Blackburn NJ, Boswell JS, Verkhovskaya ML, Hoffman BM, and Wikström M

Subjects

Histidine chemistry, Hydrogen-Ion Concentration, Protein Conformation, Spectrum Analysis methods, Bacillus subtilis enzymology, Copper chemistry, Electron Transport Complex IV chemistry, Heme chemistry, Oxidoreductases chemistry

Abstract

We have studied the structure of the CuB site in the binuclear heme-copper center of the fully oxidized form of the quinol-oxidizing cytochrome aa3-600 from Bacillus subtilis by EXAFS and ENDOR spectroscopy. This enzyme is member of the large superfamily of heme-copper respiratory oxidases, which catalyze the reduction of dioxygen to water and link it to translocation of protons across the bacterial or mitochondrial membrane. The EXAFS of the CuB site strongly suggests tetragonal coordination by two or three histidines with one or two O/N donor ligands. There are some indications that a Cl- ion might fractionally occupy substitution-labile sites, although the majority of enzyme molecules did not contain any heavy (second row) scatters, indicative of a Cl- (or S) bridge between the heme iron and CuB [cf. Powers, L., et al. (1994) Biochim. Biophys. Acta 1183, 504-512]. Proton ENDOR spectroscopy of the CuB site in 1H2O and 2H2O media showed evidence of an oxygenous copper ligand with an exchangeable proton. 14N ENDOR revealed three inequivalent nitrogenous ligands with hyperfine coupling constants consistent with histidines. Together, these results strongly suggest that the fully oxidized enzyme has a low-symmetry, tetragonal CuB site with three histidine nitrogens and one oxygen as ligands, the latter with an exchangeable proton(s). The identity and assignment of these ligands are discussed.

Published

1995

20. A novel antiporter activity catalyzing sodium and potassium transport from right-side-out vesicles of E. coli.

Author

Verkhovskaya ML, Verkhovsky MI, and Wikström M

Subjects

Choline pharmacology, Diffusion, Hydrogen-Ion Concentration, Liposomes metabolism, Membrane Potentials, Morpholines pharmacology, Potassium pharmacology, Sodium metabolism, Sodium pharmacology, Sodium-Hydrogen Exchangers metabolism, Valinomycin pharmacology, Antiporters metabolism, Cell Membrane metabolism, Escherichia coli metabolism

Abstract

Downhill sodium efflux from right-side-out E. coli membrane vesicles was found to be stimulated by negative electric potential, as has been reported earlier [Bassilana et al., Biochemistry 23 (1984) 1015-1022], and in agreement with the concept of electrogenic Na+/nH+ antiporters with n > 1. However, sodium efflux was much more accelerated by positive electric potential, indicating the operation of another sodium transport system. delta pH (alkaline inside), created by a pH shift from 8.5 to 6.8 in the medium was found to drive sodium efflux against its concentration gradient, but only when the vesicles had been loaded with both Na+ and K+. Efflux of K+ against the concentration gradient was also observed under these conditions. When the vesicles were loaded separately with sodium tricine or potassium tricine, no K+ efflux and insignificant Na+ efflux were observed. We propose that there are at least two different mechanisms responsible for Na+ efflux in E. coli vesicles. One is the Na+/nH+ antiporter previously described, and the other is a novel Na+,K+/mH+ antiporter.

Published

1995

21. The H(+)-motive and Na(+)-motive respiratory chains in Bacillus FTU subcellular vesicles.

Author

Kostyrko VA, Semeykina AL, Skulachev VP, Smirnova IA, Vaghina ML, and Verkhovskaya ML

Subjects

Cyanides pharmacology, Cytochromes metabolism, Hydrogen-Ion Concentration, Kinetics, Models, Biological, Monensin pharmacology, Organelles drug effects, Organelles ultrastructure, Protons, Sodium-Hydrogen Exchangers, Valinomycin pharmacology, Bacillus metabolism, Carrier Proteins metabolism, Organelles metabolism, Oxygen Consumption drug effects, Sodium metabolism

Abstract

Respiration-dependent pumping of Na+ and H+ into the inside-out subcellular vesicles of alkalotolerant and halotolerant Bacillus FTU grown at alkaline pH was studied. The vesicles were shown to be competent in Na+ and H+ transport coupled to ascorbate oxidation via N,N,N',N'-tetramethyl-p-phenylenediamine or diaminodurene. The uphill Na+ uptake is strongly stimulated by either protonophores or valinomycin, whereas H+ uptake is stimulated by valinomycin and completely inhibited by protonophores. The salt of a penetrating weak base and of the penetrating weak acid, diethylammonium acetate, potentiates the stimulating effect of protonophores on Na+ uptake and abolishes H+ uptake. Na+ transport, supported by ascorbate oxidation, is resistant to 2-heptyl-4-hydroxyquinoline N-oxide, but sensitive to Ag+ and Na+ ionophore, N,N'-dibenzyl-N,N'-diphenyl-1,2-phenylenediacetamide. Micromolar concentrations of cyanide specifically inhibit the H+ uptake but does not affect Na+ uptake. These cyanide concentrations are shown to cause 70% inhibition of respiration, complete reduction of alpha-type cytochromes and partial reduction of c/b-type cytochromes. To inhibit the remaining respiratory activity and Na/ uptake, approximately 100-fold higher cyanide concentrations are necessary. High cyanide concentrations cause some additional increase in absorbance in the region of cytochromes c and/or b. In the presence of a high cyanide concentration, Na+ uptake can be supported by NADH oxidation by fumarate. This Na+ transport is stimulated by protonophores and diethylammonium acetate, being sensitive to very low concentrations of 2-heptyl-4-hydroxyquinoline N-oxide and Ag+. The NADH-fumarate reductase reaction is also found to be competent in H+ uptake, which is inhibited by protonophores and by much higher 2-heptyl-4-hydroxyquinoline N-oxide concentrations, and is resistant to Ag+. It is inferred that Bacillus FTU possesses two respiratory chains: the H(+)-motive and the Na(+)-motive, which strongly differ in their inhibitor sensitivities. Each chain comprises at least two energy-coupling sites which are localized in their initial and terminal segments. It has been indicated that common redox carrier(s) are present in the two chains.

Published

1991

22. A study on Na+ -coupled oxidative phosphorylation: ATP formation supported by artificially imposed delta pNa and delta pK in Vibrio alginolyticus cells.

Author

Dibrov PA, Lazarova RL, Skulachev VP, and Verkhovskaya ML

Subjects

Biological Transport, Active drug effects, Cell Membrane metabolism, Ion Channels, Potassium metabolism, Protons, Sodium-Potassium-Exchanging ATPase metabolism, Vibrio drug effects, Adenosine Triphosphate biosynthesis, Oxidative Phosphorylation, Sodium metabolism, Vibrio metabolism

Abstract

Addition of Na+ to the K+-loaded Vibrio alginolyticus cells, creating a 250-fold Na+ gradient, is shown to induce a transient increase in the intracellular ATP concentration, which is abolished by the Na+/H+ antiporter, monensin. The delta pNa-supported ATP synthesis requires an additional driving force supplied by endogenous respiration or, alternatively, by a K+ gradient (high [K+] inside). In the former case, ATP formation is resistant to the protonophorous uncoupler. Dicyclohexylcarbodiimide and diethylstilbestrol, but not vanadate, completely inhibit Na+ pulse-induced ATP formation. The data agree with the assumption that Na+ -ATP-synthase is involved in oxidative phosphorylation in V alginolyticus. Interrelation of H+ and Na+ cycles in bacteria is discussed.

Published

1989

23. The Na+-motive terminal oxidase activity in an alkalo- and halo-tolerant Bacillus.

Author

Semeykina AL, Skulachev VP, Verkhovskaya ML, Bulygina ES, and Chumakov KM

Subjects

Ascorbic Acid metabolism, Bacillus genetics, Bacillus metabolism, Base Sequence, Biological Evolution, Carbonyl Cyanide p-Trifluoromethoxyphenylhydrazone pharmacology, Hot Temperature, Kinetics, Oxidation-Reduction, Oxidative Phosphorylation drug effects, RNA, Ribosomal, 5S genetics, Sodium metabolism, Species Specificity, Uncoupling Agents pharmacology, Bacillus enzymology, Oxidoreductases metabolism

Abstract

An alkalo- and halo-tolerant aerobic microorganism has been isolated which, according to microbiological analysis data and the ribosomal 5S RNA sequence, is a Bacillus similar, but not identical, to B. licheniformis and B. subtilis. The microorganism, called Bacillus FTU, proved to be resistant to the protonophorous uncoupler carbonylcyanide m-chlorophenylhydrazone (CCCP). The fast growth of Bacillus FTU in the presence of CCCP was shown to require a high Na+ concentration in the medium. A procedure was developed to exhaust endogenous respiratory substrates in Bacillus FTU cells so that fast oxygen consumption by the cells was observed only when an exogenous respiratory substrate was added. The exhausted cells were found to oxidize ascorbate in the presence of N,N,N',N'-tetramethyl-p-phenylenediamine (TMPD) in a cyanide-sensitive fashion. The ascorbate oxidation was coupled to the uphill Na+ extrusion which was stimulated by CCCP and a penetrating weak base, diethylamine, as well as by valinomycin with or without diethylamine. Operation of the Bacillus FTU terminal oxidase resulted in the generation of a delta psi which, in the Na+ medium, was slightly decreased by CCCP and strongly decreased by CCCP + diethylamine. In the K+ medium, CCCP discharged delta psi even without diethylamine. Ascorbate oxidation was competent in ATP synthesis which was resistant to CCCP in the Na+ medium and sensitive to CCCP in the K+ medium as if Na+- and H+-coupled oxidative phosphorylations were operative in the Na+ and K+ media, respectively. Inside-out subcellular vesicles of Bacillus FTU were found to be competent in the Na+ uptake supported by oxidation of ascorbate + TMPD or diaminodurene. CCCP or valinomycin + K+ increased the Na+ uptake very strongly. The process was completely inhibited by cyanide or monensin, the former, but not the latter, being inhibitory for respiration. The data obtained indicate that in Bacillus FTU there is not only H+-motive but also Na+-motive terminal oxidase activity.

Published

1989

24. The sodium cycle. II. Na+-coupled oxidative phosphorylation in Vibrio alginolyticus cells.

Author

Dibrov PA, Lazarova RL, Skulachev VP, and Verkhovskaya ML

Subjects

Adenosine Triphosphatases metabolism, Adenosine Triphosphate biosynthesis, Carbonyl Cyanide m-Chlorophenyl Hydrazone pharmacology, Dicyclohexylcarbodiimide pharmacology, Hydrogen-Ion Concentration, Hydroxyquinolines pharmacology, Kinetics, Lactates metabolism, Lactic Acid, Lithium metabolism, Monensin pharmacology, Oxygen Consumption drug effects, Potassium metabolism, Valinomycin pharmacology, Cation Transport Proteins, Oxidative Phosphorylation, Sodium physiology, Vibrio physiology

Abstract

The role of Na+ in Vibrio alginolyticus oxidative phosphorylation has been studied. It has been found that the addition of a respiratory substrate, lactate, to bacterial cells exhausted in endogenous pools of substrates and ATP has a strong stimulating effect on oxygen consumption and ATP synthesis. Phosphorylation is found to be sensitive to anaerobiosis as well as to HQNO, an agent inhibiting the Na+-motive respiratory chain of V. alginolyticus. Na+ loaded cells incubated in a K+ or Li+ medium fail to synthesize ATP in response to lactate addition. The addition of Na+ at a concentration comparable to that inside the cell is shown to abolish the inhibiting effect of the high intracellular Na+ level. Neither lactate oxidation nor delta psi generation coupled with this oxidation is increased by external Na+ in the Na+-loaded cells. It is concluded that oxidative ATP synthesis in V. alginolyticus cells is inhibited by the artificially imposed reverse delta pNa, i.e., [Na+]in greater than [Na+]out. Oxidative phosphorylation is resistant to a protonophorous uncoupler (0.1 mM CCCP) in the K+-loaded cells incubated in a high Na+ medium, i.e., when delta pNa of the proper direction [( Na+]in less than [Na+]out) is present. The addition of monensin in the presence of CCCP completely arrests the ATP synthesis. Monensin without CCCP is ineffective. Oxidative phosphorylation in the same cells incubated in a high K+ medium (delta pNa is low) is decreased by CCCP even without monensin. Artificial formation of delta pNa by adding 0.25 M NaCl to the K+-loaded cells (Na+ pulse) results in a temporary increase in the ATP level which spontaneously decreases again within a few minutes. Na+ pulse-induced ATP synthesis is completely abolished by monensin and is resistant to CCCP, valinomycin and HQNO. 0.05 M NaCl increases the ATP level only slightly. Thus, V. alginolyticus cells at alkaline pH represent the first example of an oxidative phosphorylation system which uses Na+ instead of H+ as the coupling ion.

Published

1986

25. The ATP-driven primary Na+ pump in subcellular vesicles of Vibrio alginolyticus.

Author

Dibrov PA, Skulachev VP, Sokolov MV, and Verkhovskaya ML

Subjects

Adenosine Triphosphate metabolism, Carbonyl Cyanide m-Chlorophenyl Hydrazone pharmacology, Dicyclohexylcarbodiimide pharmacology, Kinetics, Models, Biological, Potassium pharmacology, Subcellular Fractions enzymology, Valinomycin pharmacology, Adenosine Triphosphatases metabolism, Cation Transport Proteins, Sodium metabolism, Vibrio enzymology

Abstract

Subcellular vesicles of Vibrio alginolyticus hydrolyze ATP and accumulate Na+ in an ATP-dependent fashion. The Na+ uptake is (i) strongly stimulated by delta psi-discharging agents, i.e., the protonophorous uncoupler CCCP or valinomycin + K+ and (ii) arrested by DCCD at a concentration strongly inhibiting ATP hydrolysis. Lower concentrations of DCCD stimulate the Na+ accumulation supported by ATP hydrolysis as well as by NADH oxidation. It is concluded that there is an electrogenic DCCD-sensitive Na+-ATPase in the cytoplasmic membrane of V. alginolyticus.

Published

1988