Your search keyword '"Pia Ädelroth"' showing total 7 results

1. Solution NMR structure of yeast Rcf1, a protein involved in respiratory supercomplex formation

Author

Pia Ädelroth, Jingjing Huang, Shu Zhou, Martin Högbom, Régis Pomès, Pontus Pettersson, Dan Sjöstrand, Johannes Sjöholm, Lena Mäler, and Peter Brzezinski

Subjects

Models, Molecular, 0301 basic medicine, Magnetic Resonance Spectroscopy, Saccharomyces cerevisiae Proteins, Protein Conformation, Stereochemistry, Dimer, Saccharomyces cerevisiae, Model lipid bilayer, Micelle, Electron Transport Complex IV, 03 medical and health sciences, Molecular dynamics, chemistry.chemical_compound, Escherichia coli, Computer Simulation, Binding Sites, Multidisciplinary, biology, Chemistry, Cytochrome c, Cytochromes c, Biological Sciences, Lipids, Transmembrane protein, 030104 developmental biology, Models, Chemical, Membrane protein, Helix, biology.protein

Abstract

The Saccharomyces cerevisiae respiratory supercomplex factor 1 (Rcf1) protein is located in the mitochondrial inner membrane where it is involved in formation of supercomplexes composed of respiratory complexes III and IV. We report the solution structure of Rcf1, which forms a dimer in dodecylphosphocholine (DPC) micelles, where each monomer consists of a bundle of five transmembrane (TM) helices and a short flexible soluble helix (SH). Three TM helices are unusually charged and provide the dimerization interface consisting of 10 putative salt bridges, defining a "charge zipper" motif. The dimer structure is supported by molecular dynamics (MD) simulations in DPC, although the simulations show a more dynamic dimer interface than the NMR data. Furthermore, CD and NMR data indicate that Rcf1 undergoes a structural change when reconstituted in liposomes, which is supported by MD data, suggesting that the dimer structure is unstable in a planar membrane environment. Collectively, these data indicate a dynamic monomer-dimer equilibrium. Furthermore, the Rcf1 dimer interacts with cytochrome c, suggesting a role as an electron-transfer bridge between complexes III and IV. The Rcf1 structure will help in understanding its functional roles at a molecular level.

Published

2018

2. The timing of proton migration in membrane-reconstituted cytochrome c oxidase

Author

Lina Salomonsson, Peter Brzezinski, Pia Ädelroth, and Kristina Faxén

Subjects

Models, Molecular, Time Factors, Multidisciplinary, Proton, biology, Chemistry, Aerobic bacteria, Detergents, Rhodobacter sphaeroides, Biological Sciences, Photochemistry, Lipids, Proton pump, Electron Transport Complex IV, Solutions, Electron transfer, Nuclear magnetic resonance, Membrane, Deuterium, biology.protein, Cytochrome c oxidase, Protons, Proton-coupled electron transfer, Protein Structure, Quaternary

Abstract

In mitochondria and aerobic bacteria energy conservation involves electron transfer through a number of membrane-bound protein complexes to O 2 . The reduction of O 2 , accompanied by the uptake of substrate protons to form H 2 O, is catalyzed by cytochrome c oxidase (C c O). This reaction is coupled to proton translocation (pumping) across the membrane such that each electron transfer to the catalytic site is linked to the uptake of two protons from one side and the release of one proton to the other side of the membrane. To address the mechanism of vectorial proton translocation, in this study we have investigated the solvent deuterium isotope effect of proton-transfer rates in C c O oriented in small unilamellar vesicles. Although in H 2 O the uptake and release reactions occur with the same rates, in D 2 O the substrate and pumped protons are taken up first (τ D ≅ 200 μs, “peroxy” to “ferryl” transition) followed by a significantly slower proton release to the other side of the membrane (τ D ≅ 1 ms). Thus, the results define the order and timing of the proton transfers during a pumping cycle. Furthermore, the results indicate that during C c O turnover internal electron transfer to the catalytic site is controlled by the release of the pumped proton, which suggests a mechanism by which C c O orchestrates a tight coupling between electron transfer and proton translocation.

Published

2005

3. Conformational coupling between the active site and residues within the K C -channel of the Vibrio cholerae cbb 3 -type (C-family) oxygen reductase

Author

Paween Mahinthichaichan, Davinia Arjona, Hyun Ju Lee, Denis L. Rousseau, Young O. Ahn, Robert B. Gennis, Daniel Kaluka, Emad Tajkhorshid, Pia Ädelroth, Syun Ru Yeh, and Hanlin Ouyang

Subjects

Cytoplasm, Protein Conformation, Molecular Conformation, chemistry.chemical_element, Molecular Dynamics Simulation, Reductase, Ligands, Spectrum Analysis, Raman, medicine.disease_cause, Oxygen, Electron Transport Complex IV, Protein structure, Bacterial Proteins, Catalytic Domain, medicine, Histidine, Vibrio cholerae, Multidisciplinary, biology, Water, Active site, PNAS Plus, chemistry, Biochemistry, Mutation, Mutagenesis, Site-Directed, biology.protein, Spectrophotometry, Ultraviolet, Protons, Copper

Abstract

The respiratory chains of nearly all aerobic organisms are terminated by proton-pumping heme-copper oxygen reductases (HCOs). Previous studies have established that C-family HCOs contain a single channel for uptake from the bacterial cytoplasm of all chemical and pumped protons, and that the entrance of the K(C)-channel is a conserved glutamate in subunit III. However, the majority of the K(C)-channel is within subunit I, and the pathway from this conserved glutamate to subunit I is not evident. In the present study, molecular dynamics simulations were used to characterize a chain of water molecules leading from the cytoplasmic solution, passing the conserved glutamate in subunit III and extending into subunit I. Formation of the water chain, which controls the delivery of protons to the K(C)-channel, was found to depend on the conformation of Y241(Vc), located in subunit I at the interface with subunit III. Mutations of Y241(Vc) (to A/F/H/S) in the Vibrio cholerae cbb3 eliminate catalytic activity, but also cause perturbations that propagate over a 28-Å distance to the active site heme b3. The data suggest a linkage between residues lining the K(C)-channel and the active site of the enzyme, possibly mediated by transmembrane helix α7, which contains both Y241(Vc) and the active site cross-linked Y255(Vc), as well as two CuB histidine ligands. Other mutations of residues within or near helix α7 also perturb the active site, indicating that this helix is involved in modulation of the active site of the enzyme.

Published

2014

4. On the role of the K-proton transfer pathway in cytochrome c oxidase

Author

Pia Ädelroth, Magnus Brändén, Andreas Namslauer, Robert B. Gennis, Peter Brzezinski, and Håkan Sigurdson

Subjects

Models, Molecular, Proton, Protein Conformation, Static Electricity, chemistry.chemical_element, Electrons, Heme, Rhodobacter sphaeroides, Photochemistry, Oxygen, Electron Transport, Electron Transport Complex IV, Electron transfer, Cytochrome c oxidase, Exergonic reaction, Binding Sites, Photolysis, Multidisciplinary, biology, Lysine, Spectrum Analysis, Biological Transport, Hydrogen Bonding, Biological Sciences, biology.organism_classification, Electron transport chain, Amino Acid Substitution, chemistry, Mutation, biology.protein, Protons

Abstract

Cytochrome c oxidase is a membrane-bound enzyme that catalyzes the four-electron reduction of oxygen to water. This highly exergonic reaction drives proton pumping across the membrane. One of the key questions associated with the function of cytochrome c oxidase is how the transfer of electrons and protons is coupled and how proton transfer is controlled by the enzyme. In this study we focus on the function of one of the proton transfer pathways of the R. sphaeroides enzyme, the so-called K-proton transfer pathway (containing a highly conserved Lys(I-362) residue), leading from the protein surface to the catalytic site. We have investigated the kinetics of the reaction of the reduced enzyme with oxygen in mutants of the enzyme in which a residue [Ser(I-299)] near the entry point of the pathway was modified with the use of site-directed mutagenesis. The results show that during the initial steps of oxygen reduction, electron transfer to the catalytic site (to form the “peroxy” state, P r ) requires charge compensation through the proton pathway, but no proton uptake from the bulk solution. The charge compensation is proposed to involve a movement of the K(I-362) side chain toward the binuclear center. Thus, in contrast to what has been assumed previously, the results indicate that the K-pathway is used during oxygen reduction and that K(I-362) is charged at pH ≈ 7.5. The movement of the Lys is proposed to regulate proton transfer by “shutting off” the protonic connectivity through the K-pathway after initiation of the O 2 reduction chemistry. This “shutoff” prevents a short-circuit of the proton-pumping machinery of the enzyme during the subsequent reaction steps.

Published

2001

5. Identification of the proton pathway in bacterial reaction centers: Both protons associated with reduction of Q B to Q B H 2 share a common entry point

Author

George Feher, Mark L. Paddock, Melvin Y. Okamura, Pia Ädelroth, and Laura B. Sagle

Subjects

Models, Molecular, Photosynthetic reaction centre, Light, Proton, Protein Conformation, Ubiquinone, Stereochemistry, Photosynthetic Reaction Center Complex Proteins, Coenzymes, Glutamic Acid, Protonation, Rhodobacter sphaeroides, Photochemistry, Electron Transport, Electron transfer, Amino Acid Sequence, Multidisciplinary, Aqueous solution, biology, Chemistry, Biological Sciences, biology.organism_classification, Electron transport chain, Quinone, Kinetics, Zinc, Models, Chemical, Oxidation-Reduction

Abstract

The reaction center from Rhodobacter sphaeroides uses light energy for the reduction and protonation of a quinone molecule, Q B . This process involves the transfer of two protons from the aqueous solution to the protein-bound Q B molecule. The second proton, H + (2), is supplied to Q B by Glu-L212, an internal residue protonated in response to formation of Q A − and Q B − . In this work, the pathway for H + (2) to Glu-L212 was studied by measuring the effects of divalent metal ion binding on the protonation of Glu-L212, which was assayed by two types of processes. One was proton uptake from solution after the one-electron reduction of Q A (DQ A →D + Q A − ) and Q B (DQ B →D + Q B − ), studied by using pH-sensitive dyes. The other was the electron transfer k AB (1) (Q A − Q B →Q A Q B − ). At pH 8.5, binding of Zn 2+ , Cd 2+ , or Ni 2+ reduced the rates of proton uptake upon Q A − and Q B − formation as well as k AB (1) by ≈an order of magnitude, resulting in similar final values, indicating that there is a common rate-limiting step. Because D + Q A − is formed 10 5 -fold faster than the induced proton uptake, the observed rate decrease must be caused by an inhibition of the proton transfer. The Glu-L212→Gln mutant reaction centers displayed greatly reduced amplitudes of proton uptake and exhibited no changes in rates of proton uptake or electron transfer upon Zn 2+ binding. Therefore, metal binding specifically decreased the rate of proton transfer to Glu-L212, because the observed rates were decreased only when proton uptake by Glu-L212 was required. The entry point for the second proton H + (2) was thus identified to be the same as for the first proton H + (1), close to the metal binding region Asp-H124, His-H126, and His-H128.

Published

2000

6. Proton uptake controls electron transfer in cytochrome c oxidase

Author

Yuejun Zhen, Shelagh Ferguson-Miller, Peter Brzezinski, Pia Ädelroth, and Martin Karpefors

Subjects

Multidisciplinary, Proton, Electron Transport Complex IV, Biological Sciences, Photochemistry, Electron transport chain, Redox, Electron Transport, chemistry.chemical_compound, Electron transfer, Heme A, Amino Acid Substitution, chemistry, Point Mutation, Protons, Rhodobacter, Proton-coupled electron transfer, Heme

Abstract

In cytochrome c oxidase, a requirement for proton pumping is a tight coupling between electron and proton transfer, which could be accomplished if internal electron-transfer rates were controlled by uptake of protons. During reaction of the fully reduced enzyme with oxygen, concomitant with the “peroxy” to “oxoferryl” transition, internal transfer of the fourth electron from Cu A to heme a has the same rate as proton uptake from the bulk solution (8,000 s −1 ). The question was therefore raised whether the proton uptake controls electron transfer or vice versa. To resolve this question, we have studied a site-specific mutant of the Rhodobacter sphaeroides enzyme in which methionine 263 (SU II), a Cu A ligand, was replaced by leucine, which resulted in an increased redox potential of Cu A . During reaction of the reduced mutant enzyme with O 2 , a proton was taken up at the same rate as in the wild-type enzyme (8,000 s −1 ), whereas electron transfer from Cu A to heme a was impaired. Together with results from studies of the EQ(I-286) mutant enzyme, in which both proton uptake and electron transfer from Cu A to heme a were blocked, the results from this study show that the Cu A → heme a electron transfer is controlled by the proton uptake and not vice versa. This mechanism prevents further electron transfer to heme a 3 –Cu B before a proton is taken up, which assures a tight coupling of electron transfer to proton pumping.

Published

1998

7. Kinetic coupling between electron and proton transfer in cytochrome c oxidase: simultaneous measurements of conductance and absorbance changes

Author

Peter Brzezinski, Håkan Sigurdson, Stefan Hallen, and Pia Ädelroth

Subjects

Photolysis, Multidisciplinary, biology, Chemistry, Myocardium, Static Electricity, Photodissociation, Conductance, Electron Transport Complex IV, Protonation, Photochemistry, Electron transport chain, Electron Transport, Absorbance, Kinetics, Electron transfer, biology.protein, Animals, Cytochrome c oxidase, Cattle, Protons, Research Article

Abstract

Bovine heart cytochrome c oxidase is an electron-current driven proton pump. To investigate the mechanism by which this pump operates it is important to study individual electron- and proton-transfer reactions in the enzyme, and key reactions in which they are kinetically and thermodynamically coupled. In this work, we have simultaneously measured absorbance changes associated with electron-transfer reactions and conductance changes associated with protonation reactions following pulsed illumination of the photolabile complex of partly reduced bovine cytochrome c oxidase and carbon monoxide. Following CO dissociation, several kinetic phases in the absorbance changes were observed with time constants ranging from approximately 3 microseconds to several milliseconds, reflecting internal electron-transfer reactions within the enzyme. The data show that the rate of one of these electron-transfer reactions, from cytochrome a3 to a on a millisecond time scale, is controlled by a proton-transfer reaction. These results are discussed in terms of a model in which cytochrome a3 interacts electrostatically with a protonatable group, L, in the vicinity of the binuclear center, in equilibrium with the bulk through a proton-conducting pathway, which determines the rate of proton transfer (and indirectly also of electron transfer). The interaction energy of cytochrome a3 with L was determined independently from the pH dependence of the extent of the millisecond-electron transfer and the number of protons released, as determined from the conductance measurements. The magnitude of the interaction energy, 70 meV (1 eV = 1.602 x 10(-19) J), is consistent with a distance of 5-10 A between cytochrome a3 and L. Based on the recently determined high-resolution x-ray structures of bovine and a bacterial cytochrome c oxidase, possible candidates for L and a physiological role for L are discussed.

Published

1996