Your search keyword '"Jonathan Lasham"' showing total 4 results

1. Oversized ubiquinones as molecular probes for structural dynamics of the ubiquinone reaction site in mitochondrial respiratory complex I

Author

Tomoo Shiba, Takahiro Masuya, Daniel Ken Inaoka, Vivek Sharma, Masatoshi Murai, Outi Haapanen, Shinpei Uno, Kyoko Shinzawa-Itoh, Jonathan Lasham, Hideto Miyoshi, Materials Physics, Department of Physics, and Institute of Biotechnology

Subjects

Models, Molecular, MECHANISM, 0301 basic medicine, Respiratory chain, bioenergetics, Biochemistry, Mitochondria, Heart, BINDING, CRYSTAL-STRUCTURE, OXIDOREDUCTASE, Plant Proteins, Membrane Potential, Mitochondrial, chemistry.chemical_classification, complex I, Chemistry, Electron acceptor, Quinone, mitochondria, Alkynes, Protons, Oxidoreductases, Proteolipids, Submitochondrial Particles, respiratory chain, chemical biology, INNER MEMBRANE, 114 Physical sciences, Electron Transport, Mitochondrial Proteins, 03 medical and health sciences, Electron transfer, Oxidoreductase, ubiquinone, Animals, Inner membrane, Computer Simulation, Submitochondrial particle, Molecular Biology, Electron Transport Complex I, 030102 biochemistry & molecular biology, PINPOINT CHEMICAL-MODIFICATION, Cell Biology, NAD, 49 KDA, Protein Subunits, REDUCTION, 030104 developmental biology, Structural biology, proton pump, Molecular Probes, NADH, Biophysics, 1182 Biochemistry, cell and molecular biology, Cattle

Abstract

NADH-quinone oxidoreductase (complex I) couples electron transfer from NADH to quinone with proton translocation across the membrane. Quinone reduction is a key step for energy transmission from the site of quinone reduction to the remotely located proton-pumping machinery of the enzyme. Although structural biology studies have proposed the existence of a long and narrow quinone-access channel, the physiological relevance of this channel remains debatable. We investigated here whether complex I in bovine heart submitochondrial particles (SMPs) can catalytically reduce a series of oversized ubiquinones (OS-UQs), which are highly unlikely to transit the narrow channel because their side chain includes a bulky ?block? that is ?13 ? across. We found that some OS-UQs function as efficient electron acceptors from complex I, accepting electrons with an efficiency comparable with ubiquinone-2. The catalytic reduction and proton translocation coupled with this reduction were completely inhibited by different quinone-site inhibitors, indicating that the reduction of OS-UQs takes place at the physiological reaction site for ubiquinone. Notably, the proton-translocating efficiencies of OS-UQs significantly varied depending on their side-chain structures, suggesting that the reaction characteristics of OS-UQs affect the predicted structural changes of the quinone reaction site required for triggering proton translocation. These results are difficult to reconcile with the current channel model; rather, the access path for ubiquinone may be open to allow OS-UQs to access the reaction site. Nevertheless, contrary to the observations in SMPs, OS-UQs were not catalytically reduced by isolated complex I reconstituted into liposomes. We discuss possible reasons for these contradictory results.

Published

2020

2. High-resolution structure and dynamics of mitochondrial complex I—Insights into the proton pumping mechanism

Author

Volker Zickermann, Janet Vonck, Jonathan Lasham, Vivek Sharma, Hao Xie, Deryck J. Mills, Etienne Galemou Yoga, Amina Djurabekova, Kristian Parey, Outi Haapanen, Werner Kühlbrandt, Doctoral Programme in Materials Research and Nanosciences, Materials Physics, and Department of Physics

Subjects

Proton, Protein subunit, Energy metabolism, High resolution, CRYO-EM, 01 natural sciences, STOICHIOMETRY, 114 Physical sciences, Biochemistry, 03 medical and health sciences, Molecular dynamics, Oxidoreductase, Structural Biology, 0103 physical sciences, CRYSTAL-STRUCTURE, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Multidisciplinary, 010304 chemical physics, Chemistry, SciAdv r-articles, 3. Good health, Membrane protein complex, MOLECULAR-DYNAMICS, NADH, SUBUNIT, Biophysics, FORCE-FIELD, VISUALIZATION, Biomedicine and Life Sciences, ORIENTATION, Mitochondrial Complex I, TRANSITION, Research Article

Abstract

Description, High-resolution structure and molecular simulations unravel the inner workings of a redox-driven proton pump., Mitochondrial NADH:ubiquinone oxidoreductase (complex I) is a 1-MDa membrane protein complex with a central role in energy metabolism. Redox-driven proton translocation by complex I contributes substantially to the proton motive force that drives ATP synthase. Several structures of complex I from bacteria and mitochondria have been determined, but its catalytic mechanism has remained controversial. We here present the cryo-EM structure of complex I from Yarrowia lipolytica at 2.1-Å resolution, which reveals the positions of more than 1600 protein-bound water molecules, of which ~100 are located in putative proton translocation pathways. Another structure of the same complex under steady-state activity conditions at 3.4-Å resolution indicates conformational transitions that we associate with proton injection into the central hydrophilic axis. By combining high-resolution structural data with site-directed mutagenesis and large-scale molecular dynamic simulations, we define details of the proton translocation pathways and offer insights into the redox-coupled proton pumping mechanism of complex I.

Published

2021

3. Hydrogen bonding rearrangement by a mitochondrial disease mutation in cytochrome bc1 perturbs heme bH redox potential and spin state

Author

Patryk Kuleta, Iwona Ekiert, Artur Osyczka, Marcin Sarewicz, Vivek Sharma, Jonathan Lasham, Robert Ekiert, Materials Physics, Department of Physics, and Institute of Biotechnology

Subjects

DYNAMICS, Models, Molecular, Protein Conformation, Antimycin A, BIS-HISTIDINE, 01 natural sciences, Rhodobacter capsulatus, chemistry.chemical_compound, Electron Transport Complex III, UBIQUINOL-CYTOCHROME-C2 OXIDOREDUCTASE, ELECTRON-TRANSFER, BC(1), Heme, 0303 health sciences, Multidisciplinary, biology, Cytochrome bc1, Chemistry, Cytochrome b, Biological Sciences, electron transfer, Mitochondria, COMPLEX-III, INTERFACE, electron paramagnetic resonance, Oxidation-Reduction, Hemeprotein, 010402 general chemistry, Redox, 114 Physical sciences, Cofactor, RHODOBACTER-CAPSULATUS, 03 medical and health sciences, Electron transfer, mitochondrial dysfunction, Q(O) SITE, density functional theory, 030304 developmental biology, Spectrum Analysis, Electron Spin Resonance Spectroscopy, Hydrogen Bonding, CORRELATION-ENERGY, molecular dynamics simulations, Cytochrome b Group, 0104 chemical sciences, Biophysics and Computational Biology, Coenzyme Q – cytochrome c reductase, Mutation, biology.protein, Biophysics

Abstract

Significance To perform their specific electron-transfer relay functions, hemes commonly adopt low spin states with fine-tuned redox potentials. Understanding molecular elements controlling these properties is crucial for the description of natural proteins and engineering redox-active systems. We describe unusual effects of mitochondrial disease-related mutation in cytochrome bc1, based on which we identify a dual role of hydrogen bonding to the propionate group of heme bH. We observe that stabilization of the hydrogen bond in mutant enhances the redox potential but destabilizes the low spin state of oxidized heme. This demonstrates a critical role of the hydrogen bonding, and heme-protein interactions in general, to secure a suitable redox potential and spin state, a notion that might be universal for other heme proteins., Hemes are common elements of biological redox cofactor chains involved in rapid electron transfer. While the redox properties of hemes and the stability of the spin state are recognized as key determinants of their function, understanding the molecular basis of control of these properties is challenging. Here, benefiting from the effects of one mitochondrial disease–related point mutation in cytochrome b, we identify a dual role of hydrogen bonding (H-bond) to the propionate group of heme bH of cytochrome bc1, a common component of energy-conserving systems. We found that replacing conserved glycine with serine in the vicinity of heme bH caused stabilization of this bond, which not only increased the redox potential of the heme but also induced structural and energetic changes in interactions between Fe ion and axial histidine ligands. The latter led to a reversible spin conversion of the oxidized Fe from 1/2 to 5/2, an effect that potentially reduces the electron transfer rate between the heme and its redox partners. We thus propose that H-bond to the propionate group and heme-protein packing contribute to the fine-tuning of the redox potential of heme and maintaining its proper spin state. A subtle balance is needed between these two contributions: While increasing the H-bond stability raises the heme potential, the extent of increase must be limited to maintain the low spin and diamagnetic form of heme. This principle might apply to other native heme proteins and can be exploited in engineering of artificial heme-containing protein maquettes.

Published

2021

4. Targeting respiratory complex I – molecular mechanism and drug design

Author

Outi Haapanen, Vivek Sharma, Jonathan Lasham, Ostojic, Sergej, University of Helsinki, Department of Physics, University of Helsinki, Materials Physics, Department of Physics, Materials Physics, and Helsinki Institute of Life Science HiLIFE

Subjects

chemistry.chemical_classification, 0303 health sciences, Reactive oxygen species, education, 116 Chemical sciences, Respiratory chain, Druggability, Electron transport chain, 114 Physical sciences, 03 medical and health sciences, Metabolic pathway, chemistry.chemical_compound, 0302 clinical medicine, chemistry, 317 Pharmacy, Biophysics, Inner mitochondrial membrane, Adenosine triphosphate, 030217 neurology & neurosurgery, Function (biology), 030304 developmental biology

Abstract

The mitochondrial electron transport chain is a key biochemical pathway responsible for the generation of adenosine triphosphate (ATP). In this process, respiratory complexes catalyze electron transfer reactions that are coupled to proton pumping across the inner mitochondrial membrane. The charge and pH gradient across the membrane drives ATP generation. The first component of the respiratory chain, complex I, plays a central role by contributing up to ∼40% of total proton-motive force generation. Complex I is a major producer of the reactive oxygen species that are detrimental to biomolecules when present in excess quantities and is also host to a large number of point mutations, which cause mitochondrial dysfunction, leading to a number of disease conditions. In this chapter, we briefly discuss the structure and function of complex I, with a focus on computational approaches to study its function and druggability.

Published

2021