Your search keyword '"Pia Ädelroth"' showing total 126 results

1. Insights into the structure-function relationship of the NorQ/NorD chaperones from Paracoccus denitrificans reveal shared principles of interacting MoxR AAA+/VWA domain proteins

Author

Maximilian Kahle, Sofia Appelgren, Arne Elofsson, Marta Carroni, and Pia Ädelroth

Subjects

Iron, Nitric oxide reductase, cNOR, VWA, AAA+, ATPase, Biology (General), QH301-705.5

Abstract

Abstract Background NorQ, a member of the MoxR-class of AAA+ ATPases, and NorD, a protein containing a Von Willebrand Factor Type A (VWA) domain, are essential for non-heme iron (FeB) cofactor insertion into cytochrome c-dependent nitric oxide reductase (cNOR). cNOR catalyzes NO reduction, a key step of bacterial denitrification. This work aimed at elucidating the specific mechanism of NorQD-catalyzed FeB insertion, and the general mechanism of the MoxR/VWA interacting protein families. Results We show that NorQ-catalyzed ATP hydrolysis, an intact VWA domain in NorD, and specific surface carboxylates on cNOR are all features required for cNOR activation. Supported by BN-PAGE, low-resolution cryo-EM structures of NorQ and the NorQD complex show that NorQ forms a circular hexamer with a monomer of NorD binding both to the side and to the central pore of the NorQ ring. Guided by AlphaFold predictions, we assign the density that “plugs” the NorQ ring pore to the VWA domain of NorD with a protruding “finger” inserting through the pore and suggest this binding mode to be general for MoxR/VWA couples. Conclusions Based on our results, we present a tentative model for the mechanism of NorQD-catalyzed cNOR remodeling and suggest many of its features to be applicable to the whole MoxR/VWA family.

Published

2023

2. Cryo-EM structure and function of S. pombe complex IV with bound respiratory supercomplex factor

Author

Agnes Moe, Pia Ädelroth, Peter Brzezinski, and Linda Näsvik Öjemyr

Subjects

Chemistry, QD1-999

Abstract

Fission yeast Schizosaccharomyces pombe shares many characteristics with higher eukaryotes. Here, the authors investigate the structure and function of respiratory complex IV from S. pombe, reveal the subunit arrangements and the reaction sequence of O2 reduction.

Published

2023

3. NMR structural analysis of the yeast cytochrome c oxidase subunit Cox13 and its interaction with ATP

Author

Shu Zhou, Pontus Pettersson, Markus L. Björck, Hannah Dawitz, Peter Brzezinski, Lena Mäler, and Pia Ädelroth

Subjects

ATP, Membrane protein, NMR, Solution structure, Biology (General), QH301-705.5

Abstract

Abstract Background Mitochondrial respiration is organized in a series of enzyme complexes in turn forming dynamic supercomplexes. In Saccharomyces cerevisiae (baker’s yeast), Cox13 (CoxVIa in mammals) is a conserved peripheral subunit of Complex IV (cytochrome c oxidase, CytcO), localized at the interface of dimeric bovine CytcO, which has been implicated in the regulation of the complex. Results Here, we report the solution NMR structure of Cox13, which forms a dimer in detergent micelles. Each Cox13 monomer has three short helices (SH), corresponding to disordered regions in X-ray or cryo-EM structures of homologous proteins. Dimer formation is mainly induced by hydrophobic interactions between the transmembrane (TM) helix of each monomer. Furthermore, an analysis of chemical shift changes upon addition of ATP revealed that ATP binds at a conserved region of the C terminus with considerable conformational flexibility. Conclusions Together with functional analysis of purified CytcO, we suggest that this ATP interaction is inhibitory of catalytic activity. Our results shed light on the structural flexibility of an important subunit of yeast CytcO and provide structure-based insight into how ATP could regulate mitochondrial respiration.

Published

2021

4. De Novo Emergence of Peptides That Confer Antibiotic Resistance

Author

Michael Knopp, Jonina S. Gudmundsdottir, Tobias Nilsson, Finja König, Omar Warsi, Fredrika Rajer, Pia Ädelroth, and Dan I. Andersson

Subjects

Escherichia coli, antibiotic resistance, aminoglycosides, de novo, gene evolution, membrane potential, Microbiology, QR1-502

Abstract

ABSTRACT The origin of novel genes and beneficial functions is of fundamental interest in evolutionary biology. New genes can originate from different mechanisms, including horizontal gene transfer, duplication-divergence, and de novo from noncoding DNA sequences. Comparative genomics has generated strong evidence for de novo emergence of genes in various organisms, but experimental demonstration of this process has been limited to localized randomization in preexisting structural scaffolds. This bypasses the basic requirement of de novo gene emergence, i.e., lack of an ancestral gene. We constructed highly diverse plasmid libraries encoding randomly generated open reading frames and expressed them in Escherichia coli to identify short peptides that could confer a beneficial and selectable phenotype in vivo (in a living cell). Selections on antibiotic-containing agar plates resulted in the identification of three peptides that increased aminoglycoside resistance up to 48-fold. Combining genetic and functional analyses, we show that the peptides are highly hydrophobic, and by inserting into the membrane, they reduce membrane potential, decrease aminoglycoside uptake, and thereby confer high-level resistance. This study demonstrates that randomized DNA sequences can encode peptides that confer selective benefits and illustrates how expression of random sequences could spark the origination of new genes. In addition, our results also show that this question can be addressed experimentally by expression of highly diverse sequence libraries and subsequent selection for specific functions, such as resistance to toxic compounds, the ability to rescue auxotrophic/temperature-sensitive mutants, and growth on normally nonused carbon sources, allowing the exploration of many different phenotypes. IMPORTANCE De novo gene origination from nonfunctional DNA sequences was long assumed to be implausible. However, recent studies have shown that large fractions of genomic noncoding DNA are transcribed and translated, potentially generating new genes. Experimental validation of this process so far has been limited to comparative genomics, in vitro selections, or partial randomizations. Here, we describe selection of novel peptides in vivo using fully random synthetic expression libraries. The peptides confer aminoglycoside resistance by inserting into the bacterial membrane and thereby partly reducing membrane potential and decreasing drug uptake. Our results show that beneficial peptides can be selected from random sequence pools in vivo and support the idea that expression of noncoding sequences could spark the origination of new genes.

Published

2019

5. Investigating the Proton Donor in the NO Reductase from Paracoccus denitrificans.

Author

Josy ter Beek, Nils Krause, and Pia Ädelroth

Subjects

Medicine, Science

Abstract

Variant nomenclature: the variants were made in the NorB subunit if not indicated by the superscript c, which are variants in the NorC subunit (e.g. E122A = exchange of Glu-122 in NorB for an Ala, E71cD; exchange of Glu-71 in NorC for an Asp). Bacterial NO reductases (NORs) are integral membrane proteins from the heme-copper oxidase superfamily. Most heme-copper oxidases are proton-pumping enzymes that reduce O2 as the last step in the respiratory chain. With electrons from cytochrome c, NO reductase (cNOR) from Paracoccus (P.) denitrificans reduces NO to N2O via the following reaction: 2NO+2e-+2H+→N2O+H2O. Although this reaction is as exergonic as O2-reduction, cNOR does not contribute to the electrochemical gradient over the membrane. This means that cNOR does not pump protons and that the protons needed for the reaction are taken from the periplasmic side of the membrane (since the electrons are donated from this side). We previously showed that the P. denitrificans cNOR uses a single defined proton pathway with residues Glu-58 and Lys-54 from the NorC subunit at the entrance. Here we further strengthened the evidence in support of this pathway. Our further aim was to define the continuation of the pathway and the immediate proton donor for the active site. To this end, we investigated the region around the calcium-binding site and both propionates of heme b3 by site directed mutagenesis. Changing single amino acids in these areas often had severe effects on cNOR function, with many variants having a perturbed active site, making detailed analysis of proton transfer properties difficult. Our data does however indicate that the calcium ligation sphere and the region around the heme b3 propionates are important for proton transfer and presumably contain the proton donor. The possible evolutionary link between the area for the immediate donor in cNOR and the proton loading site (PLS) for pumped protons in oxygen-reducing heme-copper oxidases is discussed.

Published

2016

6. Reduction of Nitric Oxide to Nitrous Oxide in Flavodiiron Proteins: Catalytic Mechanism and Plausible Intermediates

Author

Margareta Blomberg and Pia Ädelroth

Subjects

General Chemistry, Catalysis

Published

2023

7. Structure of the bc1-cbb3 respiratory supercomplex from Pseudomonas aeruginosa.

Author

Di Trani, Justin M., Gheorghita, Andreea A., Turner, Madison, Brzezinski, Peter, Pia Ädelroth, Vahidi, Siavash, Howell, P. Lynne, and Rubinstein, John L.

Subjects

PSEUDOMONAS aeruginosa, ELECTRON transport, CHARGE exchange, BIOLOGICAL transport, ENERGY conversion

Abstract

Energy conversion by electron transport chains occurs through the sequential transfer of electrons between protein complexes and intermediate electron carriers, creating the proton motive force that enables ATP synthesis and membrane transport. These protein complexes can also form higher order assemblies known as respiratory supercomplexes (SCs). The electron transport chain of the opportunistic pathogen Pseudomonas aeruginosa is closely linked with its ability to invade host tissue, tolerate harsh conditions, and resist antibiotics but is poorly characterized. Here, we determine the structure of a P. aeruginosa SC that forms between the quinol:cytochrome c oxidoreductase (cytochrome bc1) and one of the organism's terminal oxidases, cytochrome cbb3, which is found only in some bacteria. Remarkably, the SC structure also includes two intermediate electron carriers: a diheme cytochrome c4 and a single heme cytochrome c5. Together, these proteins allow electron transfer from ubiquinol in cytochrome bc1 to oxygen in cytochrome cbb3. We also present evidence that different isoforms of cytochrome cbb3 can participate in formation of this SC without changing the overall SC architecture. Incorporating these different subunit isoforms into the SC would allow the bacterium to adapt to different environmental conditions. Bioinformatic analysis focusing on structural motifs in the SC suggests that cytochrome bc1-cbb3 SCs also exist in other bacterial pathogens. [ABSTRACT FROM AUTHOR]

Published

2023

8. Cryo-EM structure and function of S. pombe complex IV with bound respiratory supercomplex factor

Author

Peter Brzezinski, Linda Nasvik Ojemyr, Agnes Moe, and Pia Ädelroth

Subjects

Materials Chemistry, Environmental Chemistry, General Chemistry, Biochemistry

Abstract

Fission yeast Schizosaccharomyces pombe serves as model organism for studying higher eukaryotes. We combined the use of cryo-EM and spectroscopy to investigate the structure and function of affinity purified respiratory complex IV (CIV) from S. pombe. The reaction sequence of the reduced enzyme with O2 proceeds over a time scale of µs-ms, similar to that of the mammalian CIV. The cryo-EM structure of CIV revealed eleven subunits as well as a bound hypoxia-induced gene 1 (Hig1) domain of respiratory supercomplex factor 2 (Rcf2). These results suggest that binding of Rcf2 does not require the presence of a CIII-CIV supercomplex, i.e. Rcf2 is a component of CIV. An AlphaFold-Multimer model suggests that the Hig1 domains of both Rcf1 and Rcf2 bind at the same site of CIV suggesting that their binding is mutually exclusive. Furthermore, the differential functional effect of Rcf1 or Rcf2 is presumably caused by interactions of CIV with their different non-Hig1 domain parts.

Published

2023

9. Insights into the structure-function relationship of the NorQ/NorD chaperones fromParacoccus denitrificansreveal shared principles of interacting MoxR AAA+/VWA domain proteins

Author

Maximilian Kahle, Sofia Appelgren, Arne Elofsson, Marta Carroni, and Pia Ädelroth

Abstract

NorQ, a member of the MoxR-class of AAA+ ATPases, and NorD, a protein containing a Von Willebrand Factor Type A (VWA) domain, are essential for non-heme iron (FeB) cofactor insertion into cytochromec-dependent nitric oxide reductase (cNOR).cNOR catalyzes the NO reduction, a key step of bacterial denitrification. This work aimed at elucidating the specific mechanism of NorQD-catalyzed FeBinsertion, and the general mechanism of the MoxR/VWA interacting protein families. We show that NorQ-catalyzed ATP hydrolysis, an intact VWA-domain in NorD and specific surface carboxylates oncNOR are all features required forcNOR activation. Supported by BN-PAGE, low-resolution cryo-EM structures of NorQ and the NorQD complex show that NorQ forms a circular hexamer with a monomer of NorD binding both to the side and to the central pore of the NorQ ring. Guided by AlphaFold predictions, we assign the density that ‘plugs’ the NorQ ring pore to the VWA domain of NorD with a protruding ‘finger’ inserting through the pore, and suggest this binding mode to be general for MoxR/VWA couples. We present a tentative model for the mechanism of NorQD-catalyzedcNOR remodelling and suggest many of its features to be applicable to the whole MoxR/VWA family.

Published

2022

10. Structure and Mechanism of Respiratory III–IV Supercomplexes in Bioenergetic Membranes

Author

Peter Brzezinski, Pia Ädelroth, and Agnes Moe

Subjects

chemistry.chemical_classification, biology, Cytochrome, 010405 organic chemistry, Cytochrome bc1, Cell Membrane, Respiratory chain, Review, Saccharomyces cerevisiae, General Chemistry, Electron acceptor, 010402 general chemistry, 01 natural sciences, 0104 chemical sciences, Electron Transport, Electron Transport Complex IV, Electron Transport Complex III, Electron transfer, chemistry, Coenzyme Q – cytochrome c reductase, Biophysics, biology.protein, Cytochrome c oxidase, Protons, Electrochemical gradient

Abstract

In the final steps of energy conservation in aerobic organisms, free energy from electron transfer through the respiratory chain is transduced into a proton electrochemical gradient across a membrane. In mitochondria and many bacteria, reduction of the dioxygen electron acceptor is catalyzed by cytochrome c oxidase (complex IV), which receives electrons from cytochrome bc1 (complex III), via membrane-bound or water-soluble cytochrome c. These complexes function independently, but in many organisms they associate to form supercomplexes. Here, we review the structural features and the functional significance of the nonobligate III2IV1/2Saccharomyces cerevisiae mitochondrial supercomplex as well as the obligate III2IV2 supercomplex from actinobacteria. The analysis is centered around the Q-cycle of complex III, proton uptake by CytcO, as well as mechanistic and structural solutions to the electronic link between complexes III and IV.

Published

2021

11. NMR structural analysis of the yeast cytochrome c oxidase subunit Cox13 and its interaction with ATP

Author

Peter Brzezinski, Pontus Pettersson, Hannah Dawitz, Lena Mäler, Markus L. Björck, Pia Ädelroth, and Shu Zhou

Subjects

Magnetic Resonance Spectroscopy, Saccharomyces cerevisiae Proteins, Physiology, QH301-705.5, Protein subunit, Dimer, Saccharomyces cerevisiae, Plant Science, Biology, General Biochemistry, Genetics and Molecular Biology, Electron Transport Complex IV, chemistry.chemical_compound, Adenosine Triphosphate, Structural Biology, Animals, Cytochrome c oxidase, Biology (General), Ecology, Evolution, Behavior and Systematics, chemistry.chemical_classification, C-terminus, Solution structure, Cell Biology, Protein superfamily, biology.organism_classification, Transmembrane protein, NMR, ATP, Enzyme, chemistry, Membrane protein, Biophysics, biology.protein, Cattle, General Agricultural and Biological Sciences, Research Article, Developmental Biology, Biotechnology

Abstract

Background Mitochondrial respiration is organized in a series of enzyme complexes in turn forming dynamic supercomplexes. In Saccharomyces cerevisiae (baker’s yeast), Cox13 (CoxVIa in mammals) is a conserved peripheral subunit of Complex IV (cytochrome c oxidase, CytcO), localized at the interface of dimeric bovine CytcO, which has been implicated in the regulation of the complex. Results Here, we report the solution NMR structure of Cox13, which forms a dimer in detergent micelles. Each Cox13 monomer has three short helices (SH), corresponding to disordered regions in X-ray or cryo-EM structures of homologous proteins. Dimer formation is mainly induced by hydrophobic interactions between the transmembrane (TM) helix of each monomer. Furthermore, an analysis of chemical shift changes upon addition of ATP revealed that ATP binds at a conserved region of the C terminus with considerable conformational flexibility. Conclusions Together with functional analysis of purified CytcO, we suggest that this ATP interaction is inhibitory of catalytic activity. Our results shed light on the structural flexibility of an important subunit of yeast CytcO and provide structure-based insight into how ATP could regulate mitochondrial respiration.

Published

2021

12. Electron and proton transfer in the M. smegmatis III

Author

Sylwia, Król, Olga, Fedotovskaya, Martin, Högbom, Pia, Ädelroth, and Peter, Brzezinski

Subjects

Electron Transport, Electron Transport Complex IV, Oxygen, Electrons, Heme, Protons

Abstract

The M. smegmatis respiratory III

Published

2022

13. Membrane-tethering of cytochrome c accelerates regulated cell death in yeast

Author

Martin Ott, Alexandra Toth, Andreas Aufschnaiter, Olga Fedotovskaya, Hannah Dawitz, Pia Ädelroth, and Sabrina Büttner

Subjects

Cell death, 0301 basic medicine, Cancer Research, Mitochondrial intermembrane space, Immunology, Oxidative phosphorylation, Mitochondrion, Article, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Yeasts, Humans, lcsh:QH573-671, Inner mitochondrial membrane, biology, Chemistry, lcsh:Cytology, Cytochrome c, Intrinsic apoptosis, Cytochromes c, Mitochondrial proteins, Energy metabolism, Cell Biology, Mitochondria, Cell biology, 030104 developmental biology, Mitochondrial respiratory chain, biology.protein, Apoptosome, 030217 neurology & neurosurgery

Abstract

Intrinsic apoptosis as a modality of regulated cell death is intimately linked to permeabilization of the outer mitochondrial membrane and subsequent release of the protein cytochrome c into the cytosol, where it can participate in caspase activation via apoptosome formation. Interestingly, cytochrome c release is an ancient feature of regulated cell death even in unicellular eukaryotes that do not contain an apoptosome. Therefore, it was speculated that cytochrome c release might have an additional, more fundamental role for cell death signalling, because its absence from mitochondria disrupts oxidative phosphorylation. Here, we permanently anchored cytochrome c with a transmembrane segment to the inner mitochondrial membrane of the yeast Saccharomyces cerevisiae, thereby inhibiting its release from mitochondria during regulated cell death. This cytochrome c retains respiratory growth and correct assembly of mitochondrial respiratory chain supercomplexes. However, membrane anchoring leads to a sensitisation to acetic acid-induced cell death and increased oxidative stress, a compensatory elevation of cellular oxygen-consumption in aged cells and a decreased chronological lifespan. We therefore conclude that loss of cytochrome c from mitochondria during regulated cell death and the subsequent disruption of oxidative phosphorylation is not required for efficient execution of cell death in yeast, and that mobility of cytochrome c within the mitochondrial intermembrane space confers a fitness advantage that overcomes a potential role in regulated cell death signalling in the absence of an apoptosome.

Published

2020

14. Functional interactions between nitrite reductase and nitric oxide reductase from Paracoccus denitrificans

Author

Ingrid Albertsson, Nicholas J. Watmough, Pia Ädelroth, Johannes Sjöholm, Jerker Widengren, and Josy ter Beek

Subjects

0301 basic medicine, Nitrite Reductases, Denitrification, Nitric-oxide reductase, lcsh:Medicine, Electron donor, Nitric Oxide, Article, Nitric oxide, Electron Transport, 03 medical and health sciences, chemistry.chemical_compound, Denitrifying bacteria, lcsh:Science, Nitrites, Paracoccus denitrificans, chemistry.chemical_classification, Nitrates, Multidisciplinary, 030102 biochemistry & molecular biology, biology, lcsh:R, Electron acceptor, Nitrite reductase, biology.organism_classification, Kinetics, 030104 developmental biology, chemistry, Biochemistry, Pseudomonas aeruginosa, lcsh:Q, Oxidoreductases

Abstract

Denitrification is a microbial pathway that constitutes an important part of the nitrogen cycle on earth. Denitrifying organisms use nitrate as a terminal electron acceptor and reduce it stepwise to nitrogen gas, a process that produces the toxic nitric oxide (NO) molecule as an intermediate. In this work, we have investigated the possible functional interaction between the enzyme that produces NO; the cd1 nitrite reductase (cd1NiR) and the enzyme that reduces NO; the c-type nitric oxide reductase (cNOR), from the model soil bacterium P. denitrificans. Such an interaction was observed previously between purified components from P. aeruginosa and could help channeling the NO (directly from the site of formation to the side of reduction), in order to protect the cell from this toxic intermediate. We find that electron donation to cNOR is inhibited in the presence of cd1NiR, presumably because cd1NiR binds cNOR at the same location as the electron donor. We further find that the presence of cNOR influences the dimerization of cd1NiR. Overall, although we find no evidence for a high-affinity, constant interaction between the two enzymes, our data supports transient interactions between cd1NiR and cNOR that influence enzymatic properties of cNOR and oligomerization properties of cd1NiR. We speculate that this could be of particular importance in vivo during metabolic switches between aerobic and denitrifying conditions.

Published

2019

15. Insights into the mechanism of nitric oxide reductase from a Fe B ‐depleted variant

Author

Sascha Jareck, Pia Ädelroth, Margareta R. A. Blomberg, and Maximilian Kahle

Subjects

0303 health sciences, Denitrification, biology, Cytochrome, Nitric-oxide reductase, Stereochemistry, 030302 biochemistry & molecular biology, Biophysics, Active site, Cell Biology, Reductase, Biochemistry, Cofactor, Nitric oxide, 03 medical and health sciences, chemistry.chemical_compound, chemistry, Structural Biology, Genetics, biology.protein, Molecular Biology, Heme, 030304 developmental biology

Abstract

A key step of denitrification, the reduction of toxic nitric oxide to nitrous oxide, is catalysed by cytochrome c-dependent NO reductase (cNOR). cNOR contains four redox-active cofactors: three hemes and a nonheme iron (FeB ). Heme b3 and FeB constitute the active site, but the specific mechanism of NO-binding events and reduction is under debate. Here, we used a recently constructed, fully folded and hemylated cNOR variant that lacks FeB to investigate the role of FeB during catalysis. We show that in the FeB -less cNOR, binding of both NO and O2 to heme b3 still occurs but further reduction is impaired, although to a lesser degree for O2 than for NO. Implications for the catalytic mechanisms of cNOR are discussed.

Published

2019

16. Structure and function of chaperon proteins for activation of nitric oxide reductase in Paracoccus denitrificans

Author

Sofia Appelgren and Pia Ädelroth

Subjects

Biophysics, Cell Biology, Biochemistry

Published

2022

17. Functional studies of the Mycobacterium smegmatis cytochrome bd-I/-II oxidases

Author

Mateusz Janczak and Pia Ädelroth

Subjects

Biophysics, Cell Biology, Biochemistry

Published

2022

18. Proton-Coupled Electron Transfer Dynamics in the Obligate Mycobacterial Supercomplex III2IV2

Author

Daniel Riepl, Ana P. Gamiz-Hernandez, Terezia Kovalova, Sylwia M. Król, Sophie L. Mader, Dan Sjöstrand, Pia Ädelroth, Martin Högbom, Peter Brzezinski, and Ville R.I. Kaila

Subjects

Biophysics, Cell Biology, Biochemistry

Published

2022

19. An Engineered Glutamate in Biosynthetic Models of Heme-Copper Oxidases Drives Complete Product Selectivity by Tuning the Hydrogen-Bonding Network

Author

Maximilian Kahle, Sudharsan Dwaraknath, Igor D. Petrik, Pia Ädelroth, Braddock A. Sandoval, Yi Lu, Roman Davydov, and Brian M. Hoffman

Subjects

Oxidase test, biology, Cytochrome, Escherichia coli Proteins, Active site, Glutamic Acid, Protonation, Reaction intermediate, Heme, Biochemistry, Combinatorial chemistry, Models, Biological, Article, Catalysis, Metabolic engineering, chemistry.chemical_compound, chemistry, Metabolic Engineering, biology.protein, Escherichia coli, Oxidoreductases, Copper

Abstract

Efficiently carrying out the oxygen reduction reaction (ORR) is critical for many applications in biology and chemistry, such as bioenergetics and fuel cells, respectively. In biology, this reaction is carried out by large, transmembrane oxidases such as heme-copper oxidases (HCOs) and cytochrome bd oxidases. Common to these oxidases is the presence of a glutamate residue next to the active site, but its precise role in regulating the oxidase activity remains to be understood. In order to gain insight into the role, we herein report that incorporation of glutamate next to a designed heme-copper center in two biosynthetic models of HCOs improves O(2)-binding affinity, facilitates protonation of reaction intermediates, and eliminates release of reactive oxygen species. High-resolution crystal structures of the models revealed extended, water-mediated hydrogen bonding networks involving the glutamate. Electron paramagnetic resonance of the cryoreduced oxy-ferrous centers at cryogenic temperature followed by thermal annealing allowed observation of the key hydroperoxo intermediate that can be attributed to the hydrogen bonding network. By demonstrating these important roles of glutamate in oxygen reduction biochemistry, this work offers deeper insights into its role in native oxidases, may guide the design of more efficient artificial ORR enzymes or catalysts for applications such as fuel cell cathodes.

Published

2021

20. Respiration | Cytochrome Oxidases, Bacterial

Author

Peter Brzezinski, Agnes Moe, and Pia Ädelroth

Published

2021

21. Identification of a cytochrome bc

Author

Olga, Fedotovskaya, Ingrid, Albertsson, Gustav, Nordlund, Sangjin, Hong, Robert B, Gennis, Peter, Brzezinski, and Pia, Ädelroth

Subjects

Electron Transport, Electron Transport Complex IV, Electron Transport Complex III, Kinetics, Cell Membrane, Rhodobacter sphaeroides, Oxidation-Reduction, Hydroquinones

Abstract

Respiration is carried out by a series of membrane-bound complexes in the inner mitochondrial membrane or in the cytoplasmic membrane of bacteria. Increasing evidence shows that these complexes organize into larger supercomplexes. In this work, we identified a supercomplex composed of cytochrome (cyt.) bc

Published

2020

22. Structure of a functional obligate complex III2IV2 respiratory supercomplex from Mycobacterium smegmatis

Author

Martin Högbom, Peter Brzezinski, Samir Benlekbir, Jacob Schäfer, Pia Ädelroth, Hui Guo, Olga Fedotovskaya, John L. Rubinstein, Dan Sjöstrand, Benjamin Wiseman, Ram Gopal Nitharwal, and Qie Kuang

Subjects

0301 basic medicine, chemistry.chemical_classification, biology, Cytochrome, Stereochemistry, Cytochrome c, Mycobacterium smegmatis, 030106 microbiology, biology.organism_classification, Electron transport chain, 03 medical and health sciences, 030104 developmental biology, Cytochrome C1, chemistry, Structural Biology, Oxidoreductase, Coenzyme Q – cytochrome c reductase, biology.protein, Electrochemical gradient, Molecular Biology

Abstract

In the mycobacterial electron-transport chain, respiratory complex III passes electrons from menaquinol to complex IV, which in turn reduces oxygen, the terminal acceptor. Electron transfer is coupled to transmembrane proton translocation, thus establishing the electrochemical proton gradient that drives ATP synthesis. We isolated, biochemically characterized, and determined the structure of the obligate III2IV2 supercomplex from Mycobacterium smegmatis, a model for Mycobacterium tuberculosis. The supercomplex has quinol:O2 oxidoreductase activity without exogenous cytochrome c and includes a superoxide dismutase subunit that may detoxify reactive oxygen species produced during respiration. We found menaquinone bound in both the Qo and Qi sites of complex III. The complex III-intrinsic diheme cytochrome cc subunit, which functionally replaces both cytochrome c1 and soluble cytochrome c in canonical electron-transport chains, displays two conformations: one in which it provides a direct electronic link to complex IV and another in which it serves as an electrical switch interrupting the connection.

Published

2018

23. Mechanism of proton transfer through the KC proton pathway in the Vibrio cholerae cbb3 terminal oxidase

Author

Pia Ädelroth, Young O. Ahn, Ingrid Albertsson, and Robert B. Gennis

Subjects

0301 basic medicine, 030102 biochemistry & molecular biology, biology, Proton, Chemiosmosis, Chemistry, Protein subunit, Biophysics, Wild type, Respiratory chain, Active site, Cell Biology, Biochemistry, 03 medical and health sciences, Electron transfer, Metabolic pathway, biology.protein

Abstract

The heme‑copper oxidases (HCuOs) are terminal components of the respiratory chain, catalyzing oxygen reduction coupled to the generation of a proton motive force. The C-family HCuOs, found in many pathogenic bacteria under low oxygen tension, utilize a single proton uptake pathway to deliver protons both for O2 reduction and for proton pumping. This pathway, called the KC-pathway, starts at Glu-49P in the accessory subunit CcoP, and connects into the catalytic subunit CcoN via the polar residues Tyr-(Y)-227, Asn (N)-293, Ser (S)-244, Tyr (Y)-321 and internal water molecules, and continues to the active site. However, although the residues are known to be functionally important, little is known about the mechanism and dynamics of proton transfer in the KC-pathway. Here, we studied variants of Y227, N293 and Y321. Our results show that in the N293L variant, proton-coupled electron transfer is slowed during single-turnover oxygen reduction, and moreover it shows a pH dependence that is not observed in wildtype. This suggests that there is a shift in the pKa of an internal proton donor into an experimentally accessible range, from >10 in wildtype to ~8.8 in N293L. Furthermore, we show that there are distinct roles for the conserved Y321 and Y227. In Y321F, proton uptake from bulk solution is greatly impaired, whereas Y227F shows wildtype-like rates and retains ~50% turnover activity. These tyrosines have evolutionary counterparts in the K-pathway of B-family HCuOs, but they do not have the same roles, indicating diversity in the proton transfer dynamics in the HCuO superfamily.

Published

2018

24. The insertion of the non-heme FeB cofactor into nitric oxide reductase from P. denitrificans depends on NorQ and NorD accessory proteins

Author

Maximilian Kahle, Pia Ädelroth, Josy ter Beek, and Jonathan P. Hosler

Subjects

0301 basic medicine, Cofactor binding, biology, Operon, Nitric-oxide reductase, Structural gene, Biophysics, Cell Biology, Biochemistry, Cofactor, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, chemistry, Gene cluster, biology.protein, Heterologous expression, Heme

Abstract

Bacterial NO reductases (NOR) catalyze the reduction of NO into N2O, either as a step in denitrification or as a detoxification mechanism. cNOR from Paracoccus (P.) denitrificans is expressed from the norCBQDEF operon, but only the NorB and NorC proteins are found in the purified NOR complex. Here, we established a new purification method for the P. denitrificans cNOR via a His-tag using heterologous expression in E. coli. The His-tagged enzyme is both structurally and functionally very similar to non-tagged cNOR. We were also able to express and purify cNOR from the structural genes norCB only, in absence of the accessory genes norQDEF. The produced protein is a stable NorCB complex containing all hemes and it can bind gaseous ligands (CO) to heme b3, but it is catalytically inactive. We show that this deficient cNOR lacks the non-heme iron cofactor FeB. Mutational analysis of the nor gene cluster revealed that it is the norQ and norD genes that are essential to form functional cNOR. NorQ belongs to the family of MoxR P-loop AAA+ ATPases, which are in general considered to facilitate enzyme activation processes often involving metal insertion. Our data indicates that NorQ and NorD work together in order to facilitate non-heme Fe insertion. This is noteworthy since in many cases Fe cofactor binding occurs spontaneously. We further suggest a model for NorQ/D-facilitated metal insertion into cNOR.

Published

2018

25. Structural and functional heterogeneity of cytochrome c oxidase in S. cerevisiae

Author

Martin Ott, Pia Ädelroth, Peter Brzezinski, Jacob Schäfer, and Hannah Dawitz

Subjects

0301 basic medicine, Saccharomyces cerevisiae Proteins, Protein Conformation, Protein subunit, Kinetics, Saccharomyces cerevisiae, Biophysics, Respiratory chain, Biochemistry, Electron Transport Complex IV, Structure-Activity Relationship, 03 medical and health sciences, Electron transfer, Catalytic Domain, Cytochrome c oxidase, 030102 biochemistry & molecular biology, biology, Chemistry, Cell Biology, Ligand (biochemistry), biology.organism_classification, Oxygen, 030104 developmental biology, Membrane protein, Mitochondrial Membranes, Mutation, biology.protein

Abstract

Respiration in Saccharomyces cerevisiae is regulated by small proteins such as the respiratory supercomplex factors (Rcf). One of these factors (Rcf1) has been shown to interact with complexes III (cyt. bc1) and IV (cytochrome c oxidase, CytcO) of the respiratory chain and to modulate the activity of the latter. Here, we investigated the effect of deleting Rcf1 on the functionality of CytcO, purified using a protein C-tag on core subunit 1 (Cox1). Specifically, we measured the kinetics of ligand binding to the CytcO catalytic site, the O2-reduction activity and changes in light absorption spectra. We found that upon removal of Rcf1 a fraction of the CytcO is incorrectly assembled with structural changes at the catalytic site. The data indicate that Rcf1 modulates the assembly and activity of CytcO by shifting the equilibrium of structural sub-states toward the fully active, intact form.

Published

2018

26. 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

27. Identification of a cytochrome bc1-aa3 supercomplex in Rhodobacter sphaeroides

Author

Pia Ädelroth, Robert B. Gennis, Peter Brzezinski, Ingrid Albertsson, Gustav Nordlund, Sangjin Hong, and Olga Fedotovskaya

Subjects

0303 health sciences, Oxidase test, biology, Cytochrome, Chemistry, Cytochrome bc1, Size-exclusion chromatography, Biophysics, Cell Biology, biology.organism_classification, Biochemistry, 03 medical and health sciences, Rhodobacter sphaeroides, Electron transfer, 0302 clinical medicine, Membrane, biology.protein, Inner mitochondrial membrane, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Respiration is carried out by a series of membrane-bound complexes in the inner mitochondrial membrane or in the cytoplasmic membrane of bacteria. Increasing evidence shows that these complexes organize into larger supercomplexes. In this work, we identified a supercomplex composed of cytochrome (cyt.) bc1 and aa3-type cyt. c oxidase in Rhodobacter sphaeroides. We purified the supercomplex using a His-tag on either of these complexes. The results from activity assays, native and denaturing PAGE, size exclusion chromatography, electron microscopy, optical absorption spectroscopy and kinetic studies on the purified samples support the formation and coupled quinol oxidation:O2 reduction activity of the cyt. bc1-aa3 supercomplex. The potential role of the membrane-anchored cyt. cy as a component in supercomplexes was also investigated.

Published

2021

28. Modulation of protein function in membrane mimetics: Characterization of P. denitrificans cNOR in nanodiscs or liposomes

Author

Pia Ädelroth, Maximilian Kahle, and Josy ter Beek

Subjects

0301 basic medicine, Cytochrome, Nitric-oxide reductase, Proteolipids, Detergents, Biophysics, Nitric Oxide, Biochemistry, Micelle, Electron Transport, 03 medical and health sciences, Electron transfer, Bacterial Proteins, Micelles, Paracoccus denitrificans, chemistry.chemical_classification, Carbon Monoxide, Liposome, Membranes, biology, Chemistry, Cytochromes c, Membrane Proteins, Cell Biology, Lipids, Oxygen, 030104 developmental biology, Membrane, Enzyme, Membrane protein, Liposomes, biology.protein, Protons, Oxidoreductases

Abstract

For detailed functional characterization, membrane proteins are usually studied in detergent. However, it is becoming clear that detergent micelles are often poor mimics of the lipid environment in which these proteins function. In this work we compared the catalytic properties of the membrane-embedded cytochrome c-dependent nitric oxide reductase (cNOR) from Paracoccus (P.) denitrificans in detergent, lipid/protein nanodiscs, and proteoliposomes. We used two different lipid mixtures, an extract of soybean lipids and a defined mix of synthetic lipids mimicking the original P. denitrificans membrane. We show that the catalytic activity of detergent-solubilized cNOR increased threefold upon reconstitution from detergent into proteoliposomes with the P. denitrificans lipid mixture, and above two-fold when soybean lipids were used. In contrast, there was only a small activity increase in nanodiscs. We further show that binding of the gaseous ligands CO and O2 are affected differently by reconstitution. In proteoliposomes the turnover rates are affected much more than in nanodiscs, but CO-binding is more significantly accelerated in liposomes with soybean lipids, while O2-binding is faster with the P. denitrificans lipid mix. We also investigated proton-coupled electron transfer during the reaction between fully reduced cNOR and O2, and found that the pKa of the internal proton donor was increased in proteoliposomes but not in nanodiscs. Taking our results together, the liposome-reconstituted enzyme shows significant differences to detergent-solubilized protein. Nanodiscs show much more subtle effects, presumably because of their much lower lipid to protein ratio. Which of these two membrane-mimetic systems best mimics the native membrane is discussed.

Published

2017

29. Insights Into How Heme Reduction Potentials Modulate Enzymatic Activities of a Myoglobin‐based Functional Oxidase

Author

Ambika Bhagi-Damodaran, Pia Ädelroth, Yelu Shi, Maximilian Kahle, Yi Lu, and Yong Zhang

Subjects

inorganic chemicals, animal structures, Hemeprotein, Heme, 010402 general chemistry, digestive system, Redox, Models, Biological, 01 natural sciences, Catalysis, Article, Substrate Specificity, Electron Transport, chemistry.chemical_compound, Electron transfer, fluids and secretions, Catalytic Domain, Histidine, Respiratory enzymes, chemistry.chemical_classification, Oxidase test, urogenital system, Myoglobin, 010405 organic chemistry, Spectrum Analysis, General Chemistry, General Medicine, 0104 chemical sciences, Oxygen, Enzyme, Biochemistry, chemistry, Mutagenesis, Oxidoreductases, Oxidation-Reduction

Abstract

Heme-copper oxidase (HCO) is a class of respiratory enzymes that use a heme-copper center to catalyze O2 reduction to H2O. While heme reduction potential (E°′) of different HCO types has been found to vary >500 mV, its impact on HCO activity remains poorly understood. Here, we use a set of myoglobin-based functional HCO models to investigate the mechanism by which heme E°′ modulates oxidase activity. Rapid stopped-flow kinetic measurements show that increasing heme E°′ by ca. 210 mV results in increases in electron transfer (ET) rates by 30-fold, rate of O2 binding by 12-fold, O2 dissociation by 35-fold, while decreasing O2 affinity by 3-fold. Theoretical calculations reveal that E°′ modulation has significant implications on electronic charge of both heme iron and O2, resulting in increased O2 dissociation and reduced O2 affinity at high E°′ values. This work suggests fine-tuning E°′ in HCOs and other heme enzymes can modulate their substrate affinity, ET rate and enzymatic activity.

Published

2017

30. Reaction of S. cerevisiae mitochondria with ligands: Kinetics of CO and O2 binding to flavohemoglobin and cytochrome c oxidase

Author

Markus L. Björck, Peter Brzezinski, Pia Ädelroth, Shu Zhou, Martin Ott, and Camilla Rydström Lundin

Subjects

0301 basic medicine, education.field_of_study, 030102 biochemistry & molecular biology, Cytochrome, Cytochrome c, Population, Biophysics, Cell Biology, Biology, Mitochondrion, Biochemistry, 03 medical and health sciences, Cytosol, 030104 developmental biology, Mitochondrial matrix, biology.protein, Cytochrome c oxidase, Intermembrane space, education

Abstract

Kinetic methods used to investigate electron and proton transfer within cytochrome c oxidase (Cyt c O) are often based on the use of light to dissociate small ligands, such as CO, thereby initiating the reaction. Studies of intact mitochondria using these methods require identification of proteins that may bind CO and determination of the ligand-binding kinetics. In the present study we have investigated the kinetics of CO-ligand binding to S. cerevisiae mitochondria and cellular extracts. The data indicate that CO binds to two proteins, Cyt c O and a (yeast) flavohemoglobin (yHb). The latter has been shown previously to reside in both the cell cytosol and the mitochondrial matrix. Here, we found that yHb resides also in the intermembrane space and binds CO in its reduced state. As observed previously, we found that the yHb population in the mitochondrial matrix binds CO, but only after removal of the inner membrane. The mitochondrial yHb (in both the intermembrane space and the matrix) recombines with CO with τ ≅ 270 ms, which is significantly slower than observed with the cytosolic yHb (main component τ ≅ 1.3 ms). The data indicate that the yHb populations in the different cell compartments differ in structure.

Published

2017

31. Dynamics of the KBProton Pathway in Cytochromeba3fromThermus thermophilus

Author

Pia Ädelroth, Nathalie Gonska, Peter Brzezinski, Christoph von Ballmoos, Hsin-Yang Chang, Irina A. Smirnova, Federica Poiana, and Robert B. Gennis

Subjects

0301 basic medicine, Oxidase test, 030102 biochemistry & molecular biology, Cytochrome, biology, Proton, Chemistry, Stereochemistry, General Chemistry, Thermus thermophilus, biology.organism_classification, environment and public health, enzymes and coenzymes (carbohydrates), 03 medical and health sciences, 030104 developmental biology, biology.protein, bacteria, Cytochrome c oxidase, Biological sciences

Abstract

The ba(3) cytochrome c oxidase from Thermus thermophilus is a B-type oxygen-reducing heme-copper oxidase and a proton pump. It uses only one proton pathway for transfer of protons to the catalytic ...

Published

2017

32. Proton transfer in uncoupled variants of cytochrome c oxidase

Author

Ingrid Albertsson, Jóhanna Vilhjálmsdóttir, Peter Brzezinski, Pia Ädelroth, and Margareta R. A. Blomberg

Subjects

Models, Molecular, Proton, Stereochemistry, Protein Conformation, Biophysics, Protonation, medicine.disease_cause, Biochemistry, Catalysis, Electron Transport Complex IV, 03 medical and health sciences, Electron transfer, Bacterial Proteins, Structural Biology, Catalytic Domain, Genetics, medicine, Cytochrome c oxidase, Molecular Biology, 030304 developmental biology, 0303 health sciences, Mutation, biology, Bacteria, Chemistry, 030302 biochemistry & molecular biology, Energy landscape, Biological Transport, Cell Biology, biology.protein, Cytochrome aa3, Protons

Abstract

Cytochrome c oxidase is a membrane-bound redox-driven proton pump that harbors two proton-transfer pathways, D and K, which are used at different stages of the reaction cycle. Here, we address the question if a D pathway with a modified energy landscape for proton transfer could take over the role of the K pathway when the latter is blocked by a mutation. Our data indicate that structural alterations near the entrance of the D pathway modulate energy barriers that influence proton transfer to the proton-loading site. The data also suggest that during reduction of the catalytic site, its protonation has to occur via the K pathway and that this proton transfer to the catalytic site cannot take place through the D pathway.

Published

2019

33. Insights into the mechanism of nitric oxide reductase from a Fe

Author

Maximilian, Kahle, Margareta R A, Blomberg, Sascha, Jareck, and Pia, Ädelroth

Subjects

Oxygen, Kinetics, Catalytic Domain, Heme, Nitric Oxide, Oxidoreductases, Oxidation-Reduction, Catalysis, Protein Binding

Abstract

A key step of denitrification, the reduction of toxic nitric oxide to nitrous oxide, is catalysed by cytochrome c-dependent NO reductase (cNOR). cNOR contains four redox-active cofactors: three hemes and a nonheme iron (Fe

Published

2019

34. Structure of a functional obligate complex III

Author

Benjamin, Wiseman, Ram Gopal, Nitharwal, Olga, Fedotovskaya, Jacob, Schäfer, Hui, Guo, Qie, Kuang, Samir, Benlekbir, Dan, Sjöstrand, Pia, Ädelroth, John L, Rubinstein, Peter, Brzezinski, and Martin, Högbom

Subjects

Electron Transport, Models, Molecular, Oxygen, Electron Transport Complex III, Electron Transport Chain Complex Proteins, Cell Respiration, Cryoelectron Microscopy, Mycobacterium smegmatis, Oxidation-Reduction, Protein Structure, Tertiary

Abstract

In the mycobacterial electron-transport chain, respiratory complex III passes electrons from menaquinol to complex IV, which in turn reduces oxygen, the terminal acceptor. Electron transfer is coupled to transmembrane proton translocation, thus establishing the electrochemical proton gradient that drives ATP synthesis. We isolated, biochemically characterized, and determined the structure of the obligate III

Published

2018

35. Regulation of cytochrome c oxidase activity by modulation of the catalytic site

Author

Jacob Schäfer, Hannah Dawitz, Martin Ott, Pia Ädelroth, and Peter Brzezinski

Subjects

lcsh:R, Imidazoles, lcsh:Medicine, Electrons, Saccharomyces cerevisiae, Ligands, Models, Biological, Article, Electron Transport Complex IV, Oxygen, Catalytic Domain, lcsh:Q, lcsh:Science, Oxidation-Reduction

Abstract

The respiratory supercomplex factor 1 (Rcf 1) in Saccharomyces cerevisiae binds to intact cytochrome c oxidase (CytcO) and has also been suggested to be an assembly factor of the enzyme. Here, we isolated CytcO from rcf1Δ mitochondria using affinity chromatography and investigated reduction, inter-heme electron transfer and ligand binding to heme a 3. The data show that removal of Rcf1 yields two CytcO sub-populations. One of these sub-populations exhibits the same functional behavior as CytcO isolated from the wild-type strain, which indicates that intact CytcO is assembled also without Rcf1. In the other sub-population, which was shown previously to display decreased activity and accelerated ligand-binding kinetics, the midpoint potential of the catalytic site was lowered. The lower midpoint potential allowed us to selectively reduce one of the two sub-populations of the rcf1Δ CytcO, which made it possible to investigate the functional behavior of the two CytcO forms separately. We speculate that these functional alterations reflect a mechanism that regulates O2 binding and trapping in CytcO, thereby altering energy conservation by the enzyme.

Published

2018

36. Mechanisms for enzymatic reduction of nitric oxide to nitrous oxide - A comparison between nitric oxide reductase and cytochrome c oxidase

Author

Margareta R. A. Blomberg and Pia Ädelroth

Subjects

0301 basic medicine, Models, Molecular, Cytochrome, Nitric-oxide reductase, Aerobic bacteria, Stereochemistry, Biophysics, Respiratory chain, Nitrous Oxide, macromolecular substances, Heme, Reductase, 010402 general chemistry, Nitric Oxide, 01 natural sciences, Biochemistry, Electron Transport Complex IV, 03 medical and health sciences, Cytochrome c oxidase, biology, Chemistry, Cytochrome c, Active site, Cell Biology, 0104 chemical sciences, 030104 developmental biology, biology.protein, Thermodynamics, Oxidoreductases, Oxidation-Reduction

Abstract

Cytochrome c oxidases (CcO) reduce O2 to H2O in the respiratory chain of mitochondria and many aerobic bacteria. In addition, some species of CcO can also reduce NO to N2O and water while others cannot. Here, the mechanism for NO-reduction in CcO is investigated using quantum mechanical calculations. Comparison is made to the corresponding reaction in a "true" cytochrome c-dependent NO reductase (cNOR). The calculations show that in cNOR, where the reduction potentials are low, the toxic NO molecules are rapidly reduced, while the higher reduction potentials in CcO lead to a slower or even impossible reaction, consistent with experimental observations. In both enzymes the reaction is initiated by addition of two NO molecules to the reduced active site, forming a hyponitrite intermediate. In cNOR, N2O can then be formed using only the active-site electrons. In contrast, in CcO, one proton-coupled reduction step most likely has to occur before N2O can be formed, and furthermore, proton transfer is most likely rate-limiting. This can explain why different CcO species with the same heme a3-Cu active site differ with respect to NO reduction efficiency, since they have a varying number and/or properties of proton channels. Finally, the calculations also indicate that a conserved active site valine plays a role in reducing the rate of NO reduction in CcO.

Published

2018

37. Mechanism of proton transfer through the K

Author

Young O, Ahn, Ingrid, Albertsson, Robert B, Gennis, and Pia, Ädelroth

Subjects

Electron Transport Complex IV, Oxygen, Kinetics, Mutagenesis, Site-Directed, Hydrogen-Ion Concentration, Protons, Vibrio cholerae, Article

Abstract

The heme-copper oxidases (HCuOs) are terminal components of the respiratory chain, catalyzing oxygen reduction coupled to the generation of a proton motive force. The C-family HCuOs, found in many pathogenic bacteria under low oxygen tension, utilize a single proton uptake pathway to deliver protons both for O(2) reduction and for proton pumping. This pathway, called the K(C)-pathway, starts at Glu-49(P) in the accessory subunit CcoP, and connects into the catalytic subunit CcoN via the polar residues Tyr-(Y)-227, Asn (N)-293, Ser (S)-244, Tyr (Y)-321 and internal water molecules, and continues to the active site. However, although the residues are known to be functionally important, little is known about the mechanism and dynamics of proton transfer in the K(C)-pathway. Here, we studied variants of Y227, N293 and Y321. Our results show that in the N293L variant, proton-coupled electron transfer is slowed during single-turnover oxygen reduction, and moreover it shows a pH dependence that is not observed in wildtype. This suggests that there is a shift in the pK(a) of an internal proton donor into an experimentally accessible range, from >10 in wildtype to ~8.8 in N293L. Furthermore, we show that there are distinct roles for the conserved Y321 and Y227. In Y321F, proton uptake from bulk solution is greatly impaired, whereas Y227F shows wildtype-like rates and retains ~50% turnover activity. These tyrosines have evolutionary counterparts in the K-pathway of B- family HCuOs, but they do not have the same roles, indicating diversity in the proton transfer dynamics in the HCuO superfamily.

Published

2018

38. The two transmembrane helices of CcoP are sufficient for assembly of the cbb3-type heme-copper oxygen reductase from Vibrio cholerae

Author

Syun Ru Yeh, Denis L. Rousseau, Hyun Ju Lee, Pia Ädelroth, Young O. Ahn, Daniel Kaluka, and Robert B. Gennis

Subjects

Bioenergetics, Biophysics, chemistry.chemical_element, Reductase, medicine.disease_cause, Biochemistry, Oxygen, Article, chemistry.chemical_compound, medicine, Vibrio cholerae, Heme, Oxygen reductase, chemistry.chemical_classification, biology, Chemistry, Cell Biology, biology.organism_classification, Transmembrane domain, Enzyme, Membrane protein assembly, cbb3, Bacteria

Abstract

The C-family (cbb3) of heme-copper oxygen reductases are proton-pumping enzymes terminating the aerobic respiratory chains of many bacteria, including a number of human pathogens. The most common form of these enzymes contains one copy each of 4 subunits encoded by the ccoNOQP operon. In the cbb3 from Rhodobacter capsulatus, the enzyme is assembled in a stepwise manner, with an essential role played by an assembly protein CcoH. Importantly, it has been proposed that a transient interaction between the transmembrane domains of CcoP and CcoH is essential for assembly. Here, we test this proposal by showing that a genetically engineered form of cbb3 from Vibrio cholerae (CcoNOQPX) that lacks the hydrophilic domain of CcoP, where the two heme c moieties are present, is fully assembled and stable. Single-turnover kinetics of the reaction between the fully reduced CcoNOQPX and O2 are essentially the same as the wild type enzyme in oxidizing the 4 remaining redox-active sites. The enzyme retains approximately 10% of the steady state oxidase activity using the artificial electron donor TMPD, but has no activity using the physiological electron donor cytochrome c4, since the docking site for this cytochrome is presumably located on the absent domain of CcoP. Residue E49 in the hydrophobic domain of CcoP is the entrance of the KC-channel for proton input, and the E49A mutation in the truncated enzyme further reduces the steady state activity to less than 3%. Hence, the same proton channel is used by both the wild type and truncated enzymes.

Published

2015

39. NMR Study of Rcf2 Reveals an Unusual Dimeric Topology in Detergent Micelles

Author

Pia Ädelroth, Shu Zhou, Peter Brzezinski, Pontus Pettersson, and Lena Mäler

Subjects

0301 basic medicine, Saccharomyces cerevisiae Proteins, Stereochemistry, Dimer, Saccharomyces cerevisiae, Detergents, Biochemistry, Micelle, Protein Structure, Secondary, Electron Transport Complex IV, 03 medical and health sciences, chemistry.chemical_compound, Molecular Biology, Protein secondary structure, Nuclear Magnetic Resonance, Biomolecular, Micelles, biology, Chemistry, Organic Chemistry, Nuclear magnetic resonance spectroscopy, biology.organism_classification, Transmembrane protein, 030104 developmental biology, Membrane topology, Helix, Molecular Medicine, Protein Multimerization

Abstract

The Saccharomyces cerevisiae mitochondrial respiratory supercomplex factor 2 (Rcf2) plays a role in assembly of supercomplexes composed of cytochrome bc1 (complex III) and cytochrome c oxidase (complex IV). We expressed the Rcf2 protein in Escherichia coli, refolded it, and reconstituted it into dodecylphosphocholine (DPC) micelles. The structural properties of Rcf2 were studied by solution NMR, and near complete backbone assignment of Rcf2 was achieved. The secondary structure of Rcf2 contains seven helices, of which five are putative transmembrane (TM) helices, including, unexpectedly, a region formed by a charged 20-residue helix at the C terminus. Further studies demonstrated that Rcf2 forms a dimer, and the charged TM helix is involved in this dimer formation. Our results provide a basis for understanding the role of this assembly/regulatory factor in supercomplex formation and function.

Published

2017

40. Extraction and Reconstitution of S. cerevisiae Cytochrome c Oxidase in Liposomes without the Use of Detergent

Author

Irina A. Smirnova, Pia Ädelroth, and Peter Brzezinski

Subjects

Liposome, Chromatography, biology, Chemistry, Extraction (chemistry), Biophysics, biology.protein, Cytochrome c oxidase, Cell Biology, Biochemistry

Published

2018

41. The role of Rcf1 as a modulator of the respiratory chain in yeast

Author

Jacob Schäfer, Martin Ott, Tobias Nilsson, Peter Brzezinski, Hannah Dawitz, and Pia Ädelroth

Subjects

Chemistry, Biophysics, Respiratory chain, Cell Biology, Biochemistry, Yeast, Cell biology

Published

2018

42. The Nitric-oxide Reductase from Paracoccus denitrificans Uses a Single Specific Proton Pathway

Author

Pia Ädelroth, Peter Lachmann, Joachim Reimann, Nils Krause, and Josy ter Beek

Subjects

biology, Cytochrome, Chemistry, Cytochrome c, Active site, Cell Biology, Bioenergetics, Nitric Oxide, biology.organism_classification, Biochemistry, Electron transport chain, Electron Transport, Oxygen, Electron transfer, Bacterial Proteins, Proton transport, biology.protein, Biophysics, Protons, Paracoccus denitrificans, Oxidoreductases, Electrochemical gradient, Molecular Biology

Abstract

The NO reductase from Paracoccus denitrificans reduces NO to N2O (2NO + 2H(+) + 2e(-) → N2O + H2O) with electrons donated by periplasmic cytochrome c (cytochrome c-dependent NO reductase; cNOR). cNORs are members of the heme-copper oxidase superfamily of integral membrane proteins, comprising the O2-reducing, proton-pumping respiratory enzymes. In contrast, although NO reduction is as exergonic as O2 reduction, there are no protons pumped in cNOR, and in addition, protons needed for NO reduction are derived from the periplasmic solution (no contribution to the electrochemical gradient is made). cNOR thus only needs to transport protons from the periplasm into the active site without the requirement to control the timing of opening and closing (gating) of proton pathways as is needed in a proton pump. Based on the crystal structure of a closely related cNOR and molecular dynamics simulations, several proton transfer pathways were suggested, and in principle, these could all be functional. In this work, we show that residues in one of the suggested pathways (denoted pathway 1) are sensitive to site-directed mutation, whereas residues in the other proposed pathways (pathways 2 and 3) could be exchanged without severe effects on turnover activity with either NO or O2. We further show that electron transfer during single-turnover reduction of O2 is limited by proton transfer and can thus be used to study alterations in proton transfer rates. The exchange of residues along pathway 1 showed specific slowing of this proton-coupled electron transfer as well as changes in its pH dependence. Our results indicate that only pathway 1 is used to transfer protons in cNOR.

Published

2013

43. Single Mutations That Redirect Internal Proton Transfer in the ba3 Oxidase from Thermus thermophilus

Author

Christoph von Ballmoos, Robert B. Gennis, Pia Ädelroth, Hsin Yang Chang, Irina A. Smirnova, and Peter Brzezinski

Subjects

Oxidase test, Proton, biology, Stereochemistry, Chemistry, Thermus thermophilus, Kinetics, Electron Transport Complex IV, Proton Pumps, biology.organism_classification, Biochemistry, Article, Catalysis, Proton pump, Amino Acid Substitution, Mutation, biology.protein, Cytochrome c oxidase, Protons

Abstract

The ba3-type cytochrome c oxidase from Thermus thermophilus is a membrane-bound proton pump. Results from earlier studies have shown that with the aa3-type oxidases proton uptake to the catalytic site and “pump site” occur simultaneously. However, with the ba3 oxidase the pump site is loaded before proton transfer to the catalytic site because the proton transfer to the latter is slower than with the aa3 oxidases. In addition, the timing of formation and decay of catalytic intermediates is different in the two types of oxidases. In the present study, we have investigated two mutant ba3 CytcOs in which residues of the proton pathway leading to the catalytic site as well as the pump site were exchanged, Thr312Val and Tyr244Phe. Even though the ba3 CytcO uses only a single proton pathway for transfer of the substrate and “pumped” protons, the amino-acid residue substitutions had distinctly different effects on the kinetics of proton transfer to the catalytic site and the pump site, respectively. The results indicate that the rates of these reactions can be modified independently by replacement of single residues within the proton pathway. Furthermore, the data suggest that the Thr312Val and Tyr244Phe mutations interfere with a structural rearrangement in the proton pathway that is rate limiting for proton transfer to the catalytic site.

Published

2013

44. Regulatory role of the respiratory supercomplex factors in Saccharomyces cerevisiae

Author

Camilla, Rydström Lundin, Christoph, von Ballmoos, Martin, Ott, Pia, Ädelroth, and Peter, Brzezinski

Subjects

Electron Transport, Electron Transport Complex IV, Electron Transport Complex III, Kinetics, Saccharomyces cerevisiae Proteins, PNAS Plus, Spectrophotometry, Mutation, Saccharomyces cerevisiae, Oxidation-Reduction, Mitochondria, Protein Binding

Abstract

The respiratory supercomplex factors (Rcf) 1 and 2 mediate supramolecular interactions between mitochondrial complexes III (ubiquinol-cytochrome c reductase; cyt. bc1) and IV (cytochrome c oxidase; CytcO). In addition, removal of these polypeptides results in decreased activity of CytcO, but not of cyt. bc1 In the present study, we have investigated the kinetics of ligand binding, the single-turnover reaction of CytcO with O2, and the linked cyt. bc1-CytcO quinol oxidation-oxygen-reduction activities in mitochondria in which Rcf1 or Rcf2 were removed genetically (strains rcf1Δ and rcf2Δ, respectively). The data show that in the rcf1Δ and rcf2Δ strains, in a significant fraction of the population, ligand binding occurs over a time scale that is ∼100-fold faster (τ ≅ 100 μs) than observed with the wild-type mitochondria (τ ≅ 10 ms), indicating structural changes. This effect is specific to removal of Rcf and not dissociation of the cyt. bc1-CytcO supercomplex. Furthermore, in the rcf1Δ and rcf2Δ strains, the single-turnover reaction of CytcO with O2 was incomplete. This observation indicates that the lower activity of CytcO is caused by a fraction of inactive CytcO rather than decreased CytcO activity of the entire population. Furthermore, the data suggest that the Rcf1 polypeptide mediates formation of an electron-transfer bridge from cyt. bc1 to CytcO via a tightly bound cyt. c We discuss the significance of the proposed regulatory mechanism of Rcf1 and Rcf2 in the context of supramolecular interactions between cyt. bc1 and CytcO.

Published

2016

45. Reaction of S. cerevisiae mitochondria with ligands: Kinetics of CO and O

Author

Markus L, Björck, Shu, Zhou, Camilla, Rydström Lundin, Martin, Ott, Pia, Ädelroth, and Peter, Brzezinski

Subjects

Hemeproteins, Carbon Monoxide, Saccharomyces cerevisiae Proteins, Intracellular Membranes, Saccharomyces cerevisiae, Ligands, Dioxygenases, Mitochondria, Electron Transport Complex IV, Oxygen, Kinetics, Cytosol, Mitochondrial Membranes, Protons

Abstract

Kinetic methods used to investigate electron and proton transfer within cytochrome c oxidase (CytcO) are often based on the use of light to dissociate small ligands, such as CO, thereby initiating the reaction. Studies of intact mitochondria using these methods require identification of proteins that may bind CO and determination of the ligand-binding kinetics. In the present study we have investigated the kinetics of CO-ligand binding to S. cerevisiae mitochondria and cellular extracts. The data indicate that CO binds to two proteins, CytcO and a (yeast) flavohemoglobin (yHb). The latter has been shown previously to reside in both the cell cytosol and the mitochondrial matrix. Here, we found that yHb resides also in the intermembrane space and binds CO in its reduced state. As observed previously, we found that the yHb population in the mitochondrial matrix binds CO, but only after removal of the inner membrane. The mitochondrial yHb (in both the intermembrane space and the matrix) recombines with CO with τ≅270ms, which is significantly slower than observed with the cytosolic yHb (main component τ≅1.3ms). The data indicate that the yHb populations in the different cell compartments differ in structure.

Published

2016

46. Lipid-mediated Protein-protein Interactions Modulate Respiration-driven ATP Synthesis

Author

Pia Ädelroth, Gustav Nordlund, Tobias Nilsson, Peter Brzezinski, Camilla Rydström Lundin, and Christoph von Ballmoos

Subjects

0301 basic medicine, Models, Molecular, Ubiquinone, Photophosphorylation, Article, 03 medical and health sciences, Adenosine Triphosphate, ATP synthase gamma subunit, F-ATPase, 540 Chemistry, V-ATPase, Protein Interaction Domains and Motifs, Multidisciplinary, 030102 biochemistry & molecular biology, biology, ATP synthase, Chemiosmosis, Phosphatidylglycerols, Mitochondrial Proton-Translocating ATPases, Electron transport chain, Kinetics, 030104 developmental biology, Biochemistry, Liposomes, biology.protein, Phosphatidylcholines, 570 Life sciences, Protons, Energy Metabolism, Oxidoreductases, ATP synthase alpha/beta subunits

Abstract

Energy conversion in biological systems is underpinned by membrane-bound proton transporters that generate and maintain a proton electrochemical gradient across the membrane which used, e.g. for generation of ATP by the ATP synthase. Here, we have co-reconstituted the proton pump cytochrome bo3 (ubiquinol oxidase) together with ATP synthase in liposomes and studied the effect of changing the lipid composition on the ATP synthesis activity driven by proton pumping. We found that for 100 nm liposomes, containing 5 of each proteins, the ATP synthesis rates decreased significantly with increasing fractions of DOPA, DOPE, DOPG or cardiolipin added to liposomes made of DOPC; with e.g. 5% DOPG, we observed an almost 50% decrease in the ATP synthesis rate. However, upon increasing the average distance between the proton pumps and ATP synthases, the ATP synthesis rate dropped and the lipid dependence of this activity vanished. The data indicate that protons are transferred along the membrane, between cytochrome bo3 and the ATP synthase, but only at sufficiently high protein densities. We also argue that the local protein density may be modulated by lipid-dependent changes in interactions between the two proteins complexes, which points to a mechanism by which the cell may regulate the overall activity of the respiratory chain.

Published

2016

47. Isolation of yeast complex IV in native lipid nanodiscs

Author

Irina A. Smirnova, Martin Högbom, Henrik Östbye, Jacob Schäfer, Peter Brzezinski, Christoph von Ballmoos, Fei Li, Gabriel C. Lander, Pia Ädelroth, Markus L. Björck, and Dan Sjöstrand

Subjects

0301 basic medicine, Biophysics, 02 engineering and technology, Saccharomyces cerevisiae, Mitochondrion, Biology, Biochemistry, Article, Electron Transport Complex IV, 03 medical and health sciences, Affinity chromatography, Catalytic Domain, Amphiphile, 540 Chemistry, Cytochrome c oxidase, Inner mitochondrial membrane, Cytochrome bc1, Maleates, Cell Biology, 021001 nanoscience & nanotechnology, Lipids, 030104 developmental biology, Membrane, Membrane protein, biology.protein, Nanoparticles, Polystyrenes, 570 Life sciences, biology, 0210 nano-technology

Abstract

We used the amphipathic styrene maleic acid (SMA) co-polymer to extract cytochrome c oxidase (CytcO) in its native lipid environment from S. cerevisiae mitochondria. Native nanodiscs containing one CytcO per disc were purified using affinity chromatography. The longest cross-sections of the native nanodiscs were 11 nm × 14 nm. Based on this size we estimated that each CytcO was surrounded by ~100 phospholipids. The native nanodiscs contained the same major phospholipids as those found in the mitochondrial inner membrane. Even though CytcO forms a supercomplex with cytochrome bc(1) in the mitochondrial membrane, cyt. bc(1) was not found in the native nanodiscs. Yet, the loosely-bound Respiratory SuperComplex factors were found to associate with the isolated CytcO. The native nanodiscs displayed an O(2)-reduction activity of ~130 electrons CytcO(−1) s(−1) and the kinetics of the reaction of the fully reduced CytcO with O(2) was essentially the same as that observed with CytcO in mitochondrial membranes. The kinetics of CO-ligand binding to the CytcO catalytic site was similar in the native nanodiscs and the mitochondrial membranes. We also found that excess SMA reversibly inhibited the catalytic activity of the mitochondrial CytcO, presumably by interfering with cyt. c binding. These data point to the importance of removing excess SMA after extraction of the membrane protein. Taken together, our data shows the high potential of using SMA-extracted CytcO for functional and structural studies.

Published

2016

48. Timing of Electron and Proton Transfer in the ba3 Cytochrome c Oxidase from Thermus thermophilus

Author

Christoph von Ballmoos, Peter Brzezinski, Robert B. Gennis, Peter Lachmann, and Pia Ädelroth

Subjects

Models, Molecular, Proton, Electrons, Heme, Photochemistry, Biochemistry, Electron Transport, Electron Transport Complex IV, Nuclear magnetic resonance, Catalytic Domain, Kinetic isotope effect, Cytochrome c oxidase, Exergonic reaction, Carbon Monoxide, Oxidase test, biology, Chemistry, Thermus thermophilus, Substrate (chemistry), Cytochrome b Group, biology.organism_classification, Oxygen, Kinetics, Deuterium, biology.protein, Protons, Oxidation-Reduction, Copper

Abstract

Heme-copper oxidases are membrane-bound proteins that catalyze the reduction of O(2) to H(2)O, a highly exergonic reaction. Part of the free energy of this reaction is used for pumping of protons across the membrane. The ba(3) oxidase from Thermus thermophilus presumably uses a single proton pathway for the transfer of substrate protons used during O(2) reduction as well as for the transfer of the protons that are pumped across the membrane. The pumping stoichiometry (0.5 H(+)/electron) is lower than that of most other (mitochondrial-like) oxidases characterized to date (1 H(+)/electron). We studied the pH dependence and deuterium isotope effect of the kinetics of electron and proton transfer reactions in the ba(3) oxidase. The results from these studies suggest that the movement of protons to the catalytic site and movement to a site located some distance from the catalytic site [proposed to be a "proton-loading site" (PLS) for pumped protons] are separated in time, which allows individual investigation of these reactions. A scenario in which the uptake and release of a pumped proton occurs upon every second transfer of an electron to the catalytic site would explain the decreased proton pumping stoichiometry compared to that of mitochondrial-like oxidases.

Published

2012

49. Non-heme Fe cofactor insertion into respiratory nitric oxide reductase from Paracoccus denitrificans

Author

Maximilian Kahle, Josy ter Beek, Jonathan P. Hosler, and Pia Ädelroth

Subjects

biology, Biochemistry, Nitric-oxide reductase, Chemistry, Biophysics, biology.protein, Non heme, Cell Biology, Respiratory system, Paracoccus denitrificans, biology.organism_classification, Cofactor

Published

2018

50. Molecular architecture of the proton diode of cytochrome c oxidase

Author

Joachim Reimann, Pia Ädelroth, and Peter Brzezinski

Subjects

Oxidase test, biology, Proton, Chemistry, Electrons, Electron, Photochemistry, Biochemistry, Catalysis, Proton pump, Electron Transport Complex IV, Electron transfer, Membrane, biology.protein, Cytochrome c oxidase, Protons, Electrochemical gradient

Abstract

CytcO (cytochrome c oxidase) is a membrane-bound multisubunit protein which catalyses the reduction of O2 to H2O. The reaction is arranged topographically so that the electrons and protons are taken from opposite sides of the membrane and, in addition, it is also linked to proton pumping across the membrane. Thus the CytcO moves an equivalent of two positive charges across the membrane per electron transferred to O2. Proton transfer through CytcO must be controlled by the protein to prevent leaks, which would dissipate the proton electrochemical gradient that is maintained across the membrane. The molecular mechanism by which the protein controls the unidirectionality of proton-transfer (cf. proton diode) reactions and energetically links electron transfer to proton translocation is not known. This short review summarizes selected results from studies aimed at understanding this mechanism, and we discuss a possible mechanistic principle utilized by the oxidase to pump protons.

Published

2008