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3. Mass Photometry of Membrane Proteins

Author

Olerinyova, Anna, Sonn-Segev, Adar, Gault, Joseph, Eichmann, Cédric, Schimpf, Johannes, Kopf, Adrian H., Rudden, Lucas S.P., Ashkinadze, Dzmitry, Bomba, Radoslaw, Frey, Lukas, Greenwald, Jason, Degiacomi, Matteo T., Steinhilper, Ralf, Killian, J. Antoinette, Friedrich, Thorsten, Riek, Roland, Struwe, Weston B., and Kukura, Philipp

Published
2021
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9. Mass Photometry of Membrane Proteins

Author

Sub Membrane Biochemistry & Biophysics, Membrane Biochemistry and Biophysics, Olerinyova, Anna, Sonn-Segev, Adar, Gault, Joseph, Eichmann, Cédric, Schimpf, Johannes, Kopf, Adrian H., Rudden, Lucas S.P., Ashkinadze, Dzmitry, Bomba, Radoslaw, Frey, Lukas, Greenwald, Jason, Degiacomi, Matteo T., Steinhilper, Ralf, Killian, J. Antoinette, Friedrich, Thorsten, Riek, Roland, Struwe, Weston B., Kukura, Philipp, Sub Membrane Biochemistry & Biophysics, Membrane Biochemistry and Biophysics, Olerinyova, Anna, Sonn-Segev, Adar, Gault, Joseph, Eichmann, Cédric, Schimpf, Johannes, Kopf, Adrian H., Rudden, Lucas S.P., Ashkinadze, Dzmitry, Bomba, Radoslaw, Frey, Lukas, Greenwald, Jason, Degiacomi, Matteo T., Steinhilper, Ralf, Killian, J. Antoinette, Friedrich, Thorsten, Riek, Roland, Struwe, Weston B., and Kukura, Philipp

Published
2021

10. Quantifying the heterogeneity of macromolecular machines by mass photometry

Author

Massachusetts Institute of Technology. Department of Biology, Sonn-Segev, Adar, Belacic, Katarina, Bodrug, Tatyana, Young, Gavin, VanderLinden, Ryan T, Schulman, Brenda A, Schimpf, Johannes, Friedrich, Thorsten, Dip, Phat Vinh, Schwartz, Thomas U, Bauer, Benedikt, Peters, Jan-Michael, Struwe, Weston B, Benesch, Justin LP, Brown, Nicholas G, Haselbach, David, Kukura, Philipp, Massachusetts Institute of Technology. Department of Biology, Sonn-Segev, Adar, Belacic, Katarina, Bodrug, Tatyana, Young, Gavin, VanderLinden, Ryan T, Schulman, Brenda A, Schimpf, Johannes, Friedrich, Thorsten, Dip, Phat Vinh, Schwartz, Thomas U, Bauer, Benedikt, Peters, Jan-Michael, Struwe, Weston B, Benesch, Justin LP, Brown, Nicholas G, Haselbach, David, and Kukura, Philipp

Abstract

© 2020, The Author(s). Sample purity is central to in vitro studies of protein function and regulation, and to the efficiency and success of structural studies using techniques such as x-ray crystallography and cryo-electron microscopy (cryo-EM). Here, we show that mass photometry (MP) can accurately characterize the heterogeneity of a sample using minimal material with high resolution within a matter of minutes. To benchmark our approach, we use negative stain electron microscopy (nsEM), a popular method for EM sample screening. We include typical workflows developed for structure determination that involve multi-step purification of a multi-subunit ubiquitin ligase and chemical cross-linking steps. When assessing the integrity and stability of large molecular complexes such as the proteasome, we detect and quantify assemblies invisible to nsEM. Our results illustrate the unique advantages of MP over current methods for rapid sample characterization, prioritization and workflow optimization.

Published
2021

12. Mass Photometry of Membrane Proteins

Author

Olerinyova, Anna, Sonn-Segev, Adar, Gault, Joseph, Eichmann, Cédric, Schimpf, Johannes, Kopf, Adrian H., Rudden, Lucas S.P., Ashkinadze, Dzmitry, Bomba, Radoslaw, Frey, Lukas, Greenwald, Jason, Degiacomi, Matteo T., Steinhilper, Ralf, Killian, J. Antoinette, Friedrich, Thorsten, Riek, Roland, Struwe, Weston B., Kukura, Philipp, Sub Membrane Biochemistry & Biophysics, Membrane Biochemistry and Biophysics, Sub Membrane Biochemistry & Biophysics, and Membrane Biochemistry and Biophysics

Subjects
Chemistry(all), General Chemical Engineering, KcsA potassium channel, membrane proteins, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Biochemistry, medical, label-free, Article, Photometry (optics), Amphiphile, mass photometry, Materials Chemistry, Environmental Chemistry, SDG3: Good health and well-being, Integral membrane protein, Nanodisc, detergent micelle, Biochemistry, medical, Good health and well-being [SDG3], Chemistry, amphipol, Biochemistry (medical), Critical factors, General Chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Membrane, Membrane protein, Biophysics, Chemical Engineering(all), Mass photometry, Membrane proteins, Detergent micelle, Amphipol, Single-molecule, Label-free, single-molecule, 0210 nano-technology, nanodisc
Abstract

Summary Integral membrane proteins (IMPs) are biologically highly significant but challenging to study because they require maintaining a cellular lipid-like environment. Here, we explore the application of mass photometry (MP) to IMPs and membrane-mimetic systems at the single-particle level. We apply MP to amphipathic vehicles, such as detergents and amphipols, as well as to lipid and native nanodiscs, characterizing the particle size, sample purity, and heterogeneity. Using methods established for cryogenic electron microscopy, we eliminate detergent background, enabling high-resolution studies of membrane-protein structure and interactions. We find evidence that, when extracted from native membranes using native styrene-maleic acid nanodiscs, the potassium channel KcsA is present as a dimer of tetramers—in contrast to results obtained using detergent purification. Finally, using lipid nanodiscs, we show that MP can help distinguish between functional and non-functional nanodisc assemblies, as well as determine the critical factors for lipid nanodisc formation., Graphical Abstract, Highlights • We introduce a label-free, single molecule approach for membrane-protein characterization • Mass photometry quantifies membrane proteins in different membrane-mimetic systems • MP reveals carrier and protein heterogeneity • It helps distinguish different functional states of membrane proteins, The Bigger Picture Membrane proteins are some of the most important biological molecules, carrying out vital functions and being frequent drug targets. Yet, preferring lipid environments and so requiring solubilization, they are challenging to study. Here, we show that mass photometry can characterize the heterogeneity of membrane proteins and the carriers in which they are solubilized. It can also distinguish different functional states of membrane proteins. Our approach thus opens the door to more comprehensive studies of function, structure, and interaction of these critical proteins in their native membrane environment at the single-molecule level., Membrane proteins are important in cell signaling and disease. They are also difficult to study as they require solubilization from lipids by membrane-mimetic systems. We show that mass photometry can facilitate the study of membrane proteins in various mimetic systems. With this method, we can distinguish different oligomeric and functional states of membrane proteins, opening the door for in vitro functional studies, structural characterization, and protein-protein interaction analysis of membrane proteins.

Published
2020

13. Mass Photometry of Membrane Proteins

Author

Olerinyova, Anna, primary, Sonn Segev, Adar, additional, Gault, Joseph, additional, Eichmann, Cedric, additional, Schimpf, Johannes, additional, Kopf, Adrian H, additional, Rudden, Lucas S.P., additional, Ashkinadze, Dzmitry, additional, Bomba, Radoslaw, additional, Greenwald, Jason, additional, Degiacomi, Matteo T, additional, Killian, J Antoinette, additional, Friedrich, Thorsten, additional, Riek, Roland, additional, Struwe, Weston B, additional, and Kukura, Philipp, additional

Published
2020
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14. Quantifying the heterogeneity of macromolecular machines by mass photometry

Author

Sonn-Segev, Adar, primary, Belacic, Katarina, additional, Bodrug, Tatyana, additional, Young, Gavin, additional, VanderLinden, Ryan T., additional, Schulman, Brenda A., additional, Schimpf, Johannes, additional, Friedrich, Thorsten, additional, Dip, Phat Vinh, additional, Schwartz, Thomas U., additional, Bauer, Benedikt, additional, Peters, Jan-Michael, additional, Struwe, Weston B., additional, Benesch, Justin L. P., additional, Brown, Nicholas G., additional, Haselbach, David, additional, and Kukura, Philipp, additional

Published
2019
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18. Visualizing the movement of the amphipathic helix in the respiratory complex I using a nitrile infrared probe and SEIRAS.

Author

Santos Seica, Ana Filipa, Schimpf, Johannes, Friedrich, Thorsten, and Hellwig, Petra

Subjects
*INFRARED absorption, *UBIQUINONES, *CHARGE exchange, *CATALYSIS
Abstract

Conformational movements play an important role in enzyme catalysis. Respiratory complex I, an L‐shaped enzyme, connects electron transfer from NADH to ubiquinone in its peripheral arm with proton translocation through its membrane arm by a coupling mechanism still under debate. The amphipathic helix across the membrane arm represents a unique structural feature. Here, we demonstrate a new way to study conformational changes by introducing a small and highly flexible nitrile infrared (IR) label to this helix to visualize movement with surface‐enhanced IR absorption spectroscopy. We find that labeled residues K551CL and Y590CL move to a more hydrophobic environment upon NADH reduction of the enzyme, likely as a response to the reorganization of the antiporter‐like subunits in the membrane arm. [ABSTRACT FROM AUTHOR]

Published
2020
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21. The cbb3-type cytochrome oxidase assembly factor CcoG is a widely distributed cupric reductase.

Author

Marckmann, Dorian, Trasnea, Petru-Iulian, Schimpf, Johannes, Winterstein, Christine, Andrei, Andreea, Schmollinger, Stefan, Blaby-Haas, Crysten E., Friedrich, Thorsten, Daldal, Fevzi, and Koch, Hans-Georg

Subjects
CYTOCHROME oxidase, MOLECULAR chaperones, METALLOPROTEINS, ELECTRON donors, EUKARYOTIC cells
Abstract

Copper (Cu)-containing proteins execute essential functions in prokaryotic and eukaryotic cells, but their biogenesis is challenged by high Cu toxicity and the preferential presence of Cu(II) under aerobic conditions, while Cu(I) is the preferred substrate for Cu chaperones and Cu-transport proteins. These proteins form a coordinated network that prevents Cu accumulation, which would lead to toxic effects such as Fenton-like reactions and mismetalation of other metalloproteins. Simultaneously, Cu-transport proteins and Cu chaperones sustain Cu(I) supply for cuproprotein biogenesis and are therefore essential for the biogenesis of Cu-containing proteins. In eukaryotes, Cu(I) is supplied for import and trafficking by cell-surface exposed metalloreductases, but specific cupric reductases have not been identified in bacteria. It was generally assumed that the reducing environment of the bacterial cytoplasm would suffice to provide sufficient Cu(I) for detoxification and cuproprotein synthesis. Here, we identify the proposed cbb3-type cytochrome c oxidase (cbb3-Cox) assembly factor CcoG as a cupric reductase that binds Cu via conserved cysteine motifs and contains 2 low-potential [4Fe-4S] clusters required for Cu(II) reduction. Deletion of ccoG or mutation of the cysteine residues results in defective cbb3-Cox assembly and Cu sensitivity. Furthermore, anaerobically purified CcoG catalyzes Cu(II) but not Fe(III) reduction in vitro using an artificial electron donor. Thus, CcoG is a bacterial cupric reductase and a founding member of a widespread class of enzymes that generate Cu(I) in the bacterial cytosol by using [4Fe-4S] clusters. [ABSTRACT FROM AUTHOR]

Published
2019
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23. Significance of [2Fe-2S] Cluster N1a for Electron Transfer and Assembly of Escherichia coliRespiratory Complex I

Author

Dörner, Katerina, Vranas, Marta, Schimpf, Johannes, Straub, Isabella R., Hoeser, Jo, and Friedrich, Thorsten

Abstract

NADH:ubiquinone oxidoreductase, respiratory complex I, couples electron transfer from NADH to ubiquinone with proton translocation across the membrane. NADH reduces a noncovalently bound FMN, and the electrons are transported further to the quinone reduction site by a 95 Å long chain of seven iron–sulfur (Fe–S) clusters. Binuclear Fe–S cluster N1a is not part of this long chain but is located within electron transfer distance on the opposite site of FMN. The relevance of N1a to the mechanism of complex I is not known. To elucidate its role, we individually substituted the cysteine residues coordinating N1a of Escherichia colicomplex I by alanine and serine residues. The mutations led to a significant loss of the NADH oxidase activity of the mutant membranes, while the amount of the complex was only slightly diminished. N1a could not be detected by electron paramagnetic resonance spectroscopy, and unexpectedly, the content of binuclear cluster N1b located on a neighboring subunit was significantly decreased. Because of the lack of N1a and the partial loss of N1b, the variants did not survive detergent extraction from the mutant membranes. Only the C97AEvariant retained N1a and was purified by chromatographic steps. The preparation showed a slightly diminished NADH/ferricyanide oxidoreductase activity, while the NADH:decyl-ubiquinone oxidoreductase activity was not affected. N1a of this preparation showed unusual spectroscopic properties indicating a different ligation. We discuss whether N1a is involved in the physiological electron transfer reaction.

Published
2017
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24. Biochemical consequences of two clinically relevant ND-gene mutations in Escherichia coli respiratory complex I

Author

Nuber, Franziska, Schimpf, Johannes, Di Rago, Jean-Paul, Tribouillard-Tanvier, Déborah, Procaccio, Vincent, Martin-Negrier, Marie-Laure, Trimouille, Aurélien, Biner, Olivier, Von Ballmoos, Christoph, and Friedrich, Thorsten

Subjects
Adult, Models, Molecular, Electron Transport Complex I, Infant, Newborn, NADH Dehydrogenase, 7. Clean energy, 3. Good health, Mitochondrial Proteins, Mutation, Operon, Benzoquinones, Escherichia coli, Humans, Plasmids
Abstract

NADH:ubiquinone oxidoreductase (respiratory complex I) plays a major role in energy metabolism by coupling electron transfer from NADH to quinone with proton translocation across the membrane. Complex I deficiencies were found to be the most common source of human mitochondrial dysfunction that manifest in a wide variety of neurodegenerative diseases. Seven subunits of human complex I are encoded by mitochondrial DNA (mtDNA) that carry an unexpectedly large number of mutations discovered in mitochondria from patients' tissues. However, whether or how these genetic aberrations affect complex I at a molecular level is unknown. Here, we used Escherichia coli as a model system to biochemically characterize two mutations that were found in mtDNA of patients. The V253AMT-ND5 mutation completely disturbed the assembly of complex I, while the mutation D199GMT-ND1 led to the assembly of a stable complex capable to catalyze redox-driven proton translocation. However, the latter mutation perturbs quinone reduction leading to a diminished activity. D199MT-ND1 is part of a cluster of charged amino acid residues that are suggested to be important for efficient coupling of quinone reduction and proton translocation. A mechanism considering the role of D199MT-ND1 for energy conservation in complex I is discussed.

25. Biochemical consequences of two clinically relevant ND-gene mutations in Escherichia coli respiratory complex I

Author

Nuber, Franziska, Schimpf, Johannes, Di Rago, Jean-Paul, Tribouillard-Tanvier, Déborah, Procaccio, Vincent, Martin-Negrier, Marie-Laure, Trimouille, Aurélien, Biner, Olivier, Von Ballmoos, Christoph, and Friedrich, Thorsten

Subjects
631/45/607/1167, 631/45/607/1168, article, 631/45/612/1237, 7. Clean energy, 3. Good health
Abstract

Funder: Albert-Ludwigs-Universität Freiburg im Breisgau (1016), NADH:ubiquinone oxidoreductase (respiratory complex I) plays a major role in energy metabolism by coupling electron transfer from NADH to quinone with proton translocation across the membrane. Complex I deficiencies were found to be the most common source of human mitochondrial dysfunction that manifest in a wide variety of neurodegenerative diseases. Seven subunits of human complex I are encoded by mitochondrial DNA (mtDNA) that carry an unexpectedly large number of mutations discovered in mitochondria from patients’ tissues. However, whether or how these genetic aberrations affect complex I at a molecular level is unknown. Here, we used Escherichia coli as a model system to biochemically characterize two mutations that were found in mtDNA of patients. The V253AMT-ND5 mutation completely disturbed the assembly of complex I, while the mutation D199GMT-ND1 led to the assembly of a stable complex capable to catalyze redox-driven proton translocation. However, the latter mutation perturbs quinone reduction leading to a diminished activity. D199MT-ND1 is part of a cluster of charged amino acid residues that are suggested to be important for efficient coupling of quinone reduction and proton translocation. A mechanism considering the role of D199MT-ND1 for energy conservation in complex I is discussed.

26. Reduction of the off-pathway iron-sulphur cluster N1a of Escherichia coli respiratory complex I restrains NAD + dissociation.

Author

Gnandt E, Schimpf J, Harter C, Hoeser J, and Friedrich T

Subjects
Catalysis, Cell Membrane metabolism, Electron Transport, NADH, NADPH Oxidoreductases metabolism, Oxidation-Reduction, Protein Binding, Reactive Oxygen Species metabolism, Electron Transport Complex I metabolism, Escherichia coli metabolism, Iron metabolism, Metabolic Networks and Pathways, NAD metabolism, Sulfur metabolism
Abstract

Respiratory complex I couples the electron transfer from NADH to ubiquinone with the translocation of protons across the membrane. The reaction starts with NADH oxidation by a flavin cofactor followed by transferring the electrons through a chain of seven iron-sulphur clusters to quinone. An eighth cluster called N1a is located proximally to flavin, but on the opposite side of the chain of clusters. N1a is strictly conserved although not involved in the direct electron transfer to quinone. Here, we show that the NADH:ferricyanide oxidoreductase activity of E. coli complex I is strongly diminished when the reaction is initiated by an addition of ferricyanide instead of NADH. This effect is significantly less pronounced in a variant containing N1a with a 100 mV more negative redox potential. Detailed kinetic analysis revealed that the reduced activity is due to a lower dissociation constant of bound NAD + . Thus, reduction of N1a induces local structural rearrangements of the protein that stabilise binding of NAD + . The variant features a considerably enhanced production of reactive oxygen species indicating that bound NAD + represses this process.

Published
2017
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