Your search keyword '"Mitochondrial Membranes chemistry"' showing total 448 results

1. Lysosomes drive the piecemeal removal of mitochondrial inner membrane.

Author

Prashar A, Bussi C, Fearns A, Capurro MI, Gao X, Sesaki H, Gutierrez MG, and Jones NL

Subjects

Animals, Humans, Mice, Autophagy, Calcium metabolism, Cytosol metabolism, Homeostasis, Oxidative Stress, Reactive Oxygen Species metabolism, Transient Receptor Potential Channels metabolism, Voltage-Dependent Anion Channel 1 metabolism, Cell Compartmentation, Mitochondrial Dynamics, Lysosomes metabolism, Mitochondria metabolism, Mitochondria pathology, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism

Abstract

Mitochondrial membranes define distinct structural and functional compartments. Cristae of the inner mitochondrial membrane (IMM) function as independent bioenergetic units that undergo rapid and transient remodelling, but the significance of this compartmentalized organization is unknown 1 . Using super-resolution microscopy, here we show that cytosolic IMM vesicles, devoid of outer mitochondrial membrane or mitochondrial matrix, are formed during resting state. These vesicles derived from the IMM (VDIMs) are formed by IMM herniation through pores formed by voltage-dependent anion channel 1 in the outer mitochondrial membrane. Live-cell imaging showed that lysosomes in proximity to mitochondria engulfed the herniating IMM and, aided by the endosomal sorting complex required for transport machinery, led to the formation of VDIMs in a microautophagy-like process, sparing the remainder of the organelle. VDIM formation was enhanced in mitochondria undergoing oxidative stress, suggesting their potential role in maintenance of mitochondrial function. Furthermore, the formation of VDIMs required calcium release by the reactive oxygen species-activated, lysosomal calcium channel, transient receptor potential mucolipin 1, showing an interorganelle communication pathway for maintenance of mitochondrial homeostasis. Thus, IMM compartmentalization could allow for the selective removal of damaged IMM sections via VDIMs, which should protect mitochondria from localized injury. Our findings show a new pathway of intramitochondrial quality control., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

2. Inner membrane turns inside out to exit mitochondrial organelles.

Author

Pla-Martín D and Reichert AS

Subjects

Animals, Humans, Cytoplasm metabolism, Mitochondria metabolism, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism

Published

2024

3. Fluorescence Lifetime Super-Resolution Imaging Unveil the Dynamic Relationship between Mitochondrial Membrane Potential and Cristae Structure Using the Förster Resonance Energy Transfer Strategy.

Author

Peng F, Ai X, Sun J, Ge X, Li M, Xi P, and Gao B

Subjects

Humans, Fluorescent Dyes chemistry, Optical Imaging, Mitochondrial Membranes metabolism, Mitochondrial Membranes chemistry, HeLa Cells, Fluorescence Resonance Energy Transfer, Membrane Potential, Mitochondrial, Rhodamines chemistry

Abstract

Mitochondrial cristae, invaginations of the inner mitochondrial membrane (IMM) into the matrix, are the main site for the generation of ATP via oxidative phosphorylation, and mitochondrial membrane potential (MMP). Synchronous study of the dynamic relationship between cristae and MMP is very important for further understanding of mitochondrial function. Due to the lack of suitable IMM probes and imaging techniques, the dynamic relationship between MMP and cristae structure alterations remains poorly understood. We designed a pair of FRET-based molecular probes, with the donor (OR-LA) being rhodamine modified with mitochondrial coenzyme lipoic acid and the acceptor (SiR-BA) being silicon-rhodamine modified with a butyl chain, for simultaneous dynamic monitoring of mitochondrial cristae structure and MMP. The FRET process of the molecular pair in mitochondria is regulated by MMP, enabling more precise visualization of MMP through fluorescence intensity ratio and fluorescence lifetime. By combining FRET with FLIM super-resolution imaging technology, we achieved simultaneous dynamic monitoring of mitochondrial cristae structure and MMP, revealing that during the decline of MMP, there is a progression involving cristae dilation, fragmentation, mitochondrial vacuolization, and eventual rupture. Significantly, we successfully observed that the rapid decrease in MMP at the site of mitochondrial membrane rupture may be a critical factor in mitochondrial fragmentation. These data collectively reveal the dynamic relationship between cristae structural alterations and MMP decline, laying a foundation for further investigation into cellular energy regulation mechanisms and therapeutic strategies for mitochondria-related diseases.

Published

2024

4. Fluorescence Lifetime Imaging of Lipid Heterogeneity in the Inner Mitochondrial Membrane with a Super-photostable Environment-Sensitive Probe.

Author

Wang J, Taki M, Ohba Y, Arita M, and Yamaguchi S

Subjects

Humans, Lipids chemistry, Microscopy, Fluorescence, Reactive Oxygen Species metabolism, Reactive Oxygen Species analysis, HeLa Cells, Mitochondria metabolism, Mitochondria chemistry, Fluorescent Dyes chemistry, Mitochondrial Membranes metabolism, Mitochondrial Membranes chemistry, Optical Imaging

Abstract

The inner mitochondrial membrane (IMM) undergoes dynamic morphological changes, which are crucial for the maintenance of mitochondrial functions as well as cell survival. As the dynamics of the membrane are governed by its lipid components, a fluorescent probe that can sense spatiotemporal alterations in the lipid properties of the IMM over long periods of time is required to understand mitochondrial physiological functions in detail. Herein, we report a red-emissive IMM-labeling reagent with excellent photostability and sensitivity to its environment, which enables the visualization of the IMM ultrastructure using super-resolution microscopy as well as of the lipid heterogeneity based on the fluorescence lifetime at the single mitochondrion level. Combining the probe and fluorescence lifetime imaging microscopy (FLIM) showed that peroxidation of unsaturated lipids in the IMM by reactive oxygen species caused an increase in the membrane order, which took place prior to mitochondrial swelling., (© 2024 The Authors. Angewandte Chemie International Edition published by Wiley-VCH GmbH.)

Published

2024

5. High-resolution in situ structures of mammalian respiratory supercomplexes.

Author

Zheng W, Chai P, Zhu J, and Zhang K

Subjects

Animals, Cryoelectron Microscopy, Mitochondrial Membranes metabolism, Mitochondrial Membranes chemistry, Mitochondrial Membranes ultrastructure, Models, Molecular, Oxidative Phosphorylation, Swine, Ubiquinone analogs & derivatives, Ubiquinone chemistry, Ubiquinone metabolism, Membrane Lipids chemistry, Membrane Lipids metabolism, Cell Respiration, Electron Transport Complex I chemistry, Electron Transport Complex I metabolism, Electron Transport Complex I ultrastructure, Electron Transport Complex III chemistry, Electron Transport Complex III metabolism, Electron Transport Complex III ultrastructure, Mitochondria metabolism, Mitochondria chemistry, Mitochondria ultrastructure

Abstract

Mitochondria play a pivotal part in ATP energy production through oxidative phosphorylation, which occurs within the inner membrane through a series of respiratory complexes 1-4 . Despite extensive in vitro structural studies, determining the atomic details of their molecular mechanisms in physiological states remains a major challenge, primarily because of loss of the native environment during purification. Here we directly image porcine mitochondria using an in situ cryo-electron microscopy approach. This enables us to determine the structures of various high-order assemblies of respiratory supercomplexes in their native states. We identify four main supercomplex organizations: I 1 III 2 IV 1 , I 1 III 2 IV 2 , I 2 III 2 IV 2 and I 2 III 4 IV 2 , which potentially expand into higher-order arrays on the inner membranes. These diverse supercomplexes are largely formed by 'protein-lipids-protein' interactions, which in turn have a substantial impact on the local geometry of the surrounding membranes. Our in situ structures also capture numerous reactive intermediates within these respiratory supercomplexes, shedding light on the dynamic processes of the ubiquinone/ubiquinol exchange mechanism in complex I and the Q-cycle in complex III. Structural comparison of supercomplexes from mitochondria treated under different conditions indicates a possible correlation between conformational states of complexes I and III, probably in response to environmental changes. By preserving the native membrane environment, our approach enables structural studies of mitochondrial respiratory supercomplexes in reaction at high resolution across multiple scales, from atomic-level details to the broader subcellular context., (© 2024. The Author(s).)

Published

2024

6. Motion of VAPB molecules reveals ER-mitochondria contact site subdomains.

Author

Obara CJ, Nixon-Abell J, Moore AS, Riccio F, Hoffman DP, Shtengel G, Xu CS, Schaefer K, Pasolli HA, Masson JB, Hess HF, Calderon CP, Blackstone C, and Lippincott-Schwartz J

Subjects

Humans, Amyotrophic Lateral Sclerosis genetics, Signal Transduction, Microscopy, Electron, Imaging, Three-Dimensional, Binding Sites, Diffusion, Time Factors, Mutation, Homeostasis, Endoplasmic Reticulum chemistry, Endoplasmic Reticulum metabolism, Endoplasmic Reticulum ultrastructure, Mitochondria chemistry, Mitochondria metabolism, Mitochondria ultrastructure, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Mitochondrial Membranes ultrastructure, Vesicular Transport Proteins genetics, Vesicular Transport Proteins metabolism, Vesicular Transport Proteins ultrastructure, Movement

Abstract

To coordinate cellular physiology, eukaryotic cells rely on the rapid exchange of molecules at specialized organelle-organelle contact sites 1,2 . Endoplasmic reticulum-mitochondrial contact sites (ERMCSs) are particularly vital communication hubs, playing key roles in the exchange of signalling molecules, lipids and metabolites 3,4 . ERMCSs are maintained by interactions between complementary tethering molecules on the surface of each organelle 5,6 . However, due to the extreme sensitivity of these membrane interfaces to experimental perturbation 7,8 , a clear understanding of their nanoscale organization and regulation is still lacking. Here we combine three-dimensional electron microscopy with high-speed molecular tracking of a model organelle tether, Vesicle-associated membrane protein (VAMP)-associated protein B (VAPB), to map the structure and diffusion landscape of ERMCSs. We uncovered dynamic subdomains within VAPB contact sites that correlate with ER membrane curvature and undergo rapid remodelling. We show that VAPB molecules enter and leave ERMCSs within seconds, despite the contact site itself remaining stable over much longer time scales. This metastability allows ERMCSs to remodel with changes in the physiological environment to accommodate metabolic needs of the cell. An amyotrophic lateral sclerosis-associated mutation in VAPB perturbs these subdomains, likely impairing their remodelling capacity and resulting in impaired interorganelle communication. These results establish high-speed single-molecule imaging as a new tool for mapping the structure of contact site interfaces and reveal that the diffusion landscape of VAPB at contact sites is a crucial component of ERMCS homeostasis., (© 2024. The Author(s).)

Published

2024

7. Large-scale column-free purification of bovine F-ATP synthase.

Author

Jiko C, Morimoto Y, Tsukihara T, and Gerle C

Subjects

Animals, Cattle, Adenosine Triphosphate metabolism, Dimerization, Mitochondria, Heart chemistry, Centrifugation, Density Gradient, Mitochondrial Membranes chemistry, Mitochondrial Proton-Translocating ATPases isolation & purification

Abstract

Mammalian F-ATP synthase is central to mitochondrial bioenergetics and is present in the inner mitochondrial membrane in a dynamic oligomeric state of higher oligomers, tetramers, dimers, and monomers. In vitro investigations of mammalian F-ATP synthase are often limited by the ability to purify the oligomeric forms present in vivo at a quantity, stability, and purity that meets the demand of the planned experiment. We developed a purification approach for the isolation of bovine F-ATP synthase from heart muscle mitochondria that uses a combination of buffer conditions favoring inhibitor factor 1 binding and sucrose density gradient ultracentrifugation to yield stable complexes at high purity in the milligram range. By tuning the glyco-diosgenin to lauryl maltose neopentyl glycol ratio in a final gradient, fractions that are either enriched in tetrameric or monomeric F-ATP synthase can be obtained. It is expected that this large-scale column-free purification strategy broadens the spectrum of in vitro investigation on mammalian F-ATP synthase., Competing Interests: Conflict of interest A patent application has been submitted by C. J., Y. M., C. G. and Kyoto University based on the results of this study., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

8. Distinct structural motifs are necessary for targeting and import of Tim17 in Trypanosoma brucei mitochondrion.

Author

Darden C, Donkor JE, Korolkova O, Barozai MYK, and Chaudhuri M

Subjects

Animals, Humans, Mitochondria metabolism, Mitochondrial Membranes chemistry, Protein Transport, Mitochondrial Proteins genetics, Trypanosoma brucei brucei

Abstract

Nuclear-encoded mitochondrial proteins are correctly translocated to their proper sub-mitochondrial destination using location-specific mitochondrial targeting signals and via multi-protein import machineries (translocases) in the outer and inner mitochondrial membranes (TOM and TIMs, respectively). However, targeting signals of multi-pass Tims are less defined. Here, we report the characterization of the targeting signals of Trypanosoma brucei Tim17 (TbTim17), an essential component of the most divergent TIM complex. TbTim17 possesses a characteristic secondary structure including four predicted transmembrane (TM) domains in the center with hydrophilic N- and C-termini. After examining mitochondrial localization of various deletion and site-directed mutants of TbTim17 in T. brucei using subcellular fractionation and confocal microscopy, we located at least two internal targeting signals (ITS): (i) within TM1 (31-50 AAs) and (ii) TM4 + loop 3 (120-136 AAs). Both signals are required for proper targeting and integration of TbTim17 in the membrane. Furthermore, a positively charged residue (K 122 ) is critical for mitochondrial localization of TbTim17. This is the first report of characterizing the ITS for a multipass inner membrane protein in a divergent eukaryote, like T. brucei .IMPORTANCEAfrican trypanosomiasis (AT) is a deadly disease in human and domestic animals, caused by the parasitic protozoan Trypanosoma brucei . Therefore, AT is not only a concern for human health but also for economic development in the vast area of sub-Saharan Africa. T. brucei possesses a single mitochondrion per cell that imports hundreds of nuclear-encoded mitochondrial proteins for its functions. T. brucei Tim17 (TbTim17), an essential component of the TbTIM17 complex, is a nuclear-encoded protein; thus, it is necessary to be imported from the cytosol to form the TbTIM17 complex. Here, we demonstrated that the internal targeting signals within the transmembrane 1 (TM1) and TM4 with loop 3, and residue K122 are required collectively for import and integration of TbTim17 in the T. brucei mitochondrion. This information could be utilized to block TbTim17 function and parasite growth., Competing Interests: The authors declare no conflict of interest.

Published

2024

9. Large-scale purification of mitochondrial protein complexes in yeast expression system for structural analyses.

Author

Kobayashi N, Imai Y, Kita S, Kawai S, and Araiso Y

Subjects

Mitochondrial Membranes metabolism, Mitochondrial Membranes chemistry, Mitochondria metabolism, Saccharomyces cerevisiae Proteins isolation & purification, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins metabolism, Saccharomyces cerevisiae Proteins genetics, Multiprotein Complexes isolation & purification, Multiprotein Complexes chemistry, Mitochondrial Proteins isolation & purification, Mitochondrial Proteins metabolism, Mitochondrial Proteins chemistry, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae genetics, Cryoelectron Microscopy methods

Abstract

Recent developments in cryo-electron microscopy techniques have facilitated intensive research into determining protein structures. Nevertheless, the structures of some mitochondrial membrane protein complexes remain undetermined. One possible reason for this research gap is that mitochondrial membrane protein complexes are difficult to overexpress and purify. Even using high-resolution cryo-electron microscopy, structural determination is not possible without first obtaining purified homogeneous proteins. As determining novel structures of protein complexes would provide opportunities to answer many unresolved biological questions, it is important to generalize purification methods, which often become bottlenecks in protein research. In this chapter, we introduce purification methods for mitochondrial membrane protein complexes and mitochondria-localized soluble protein complexes using a yeast expression system. We also describe the recent development of a mitochondrial membrane isolation method that enables the extraction of large amounts of protein complexes for structural analyses., (Copyright © 2024. Published by Elsevier Inc.)

Published

2024

10. Structure and Elasticity of Mitochondrial Membranes: A Molecular Dynamics Simulation Study.

Author

Mai TL, Derreumaux P, and Nguyen PH

Subjects

Mitochondrial Membranes chemistry, Elasticity, Cholesterol metabolism, Cardiolipins chemistry, Molecular Dynamics Simulation

Abstract

Mitochondria are known as the powerhouse of the cell because they produce energy in the form of adenosine triphosphate. They also have other crucial functions such as regulating apoptosis, calcium homeostasis, and reactive oxygen species production. To perform these diverse functions, mitochondria adopt specific structures and frequently undergo dynamic shape changes, indicating that their mechanical properties play an essential role in their functions. To gain a detailed understanding at the molecular level of the structure and mechanical properties of mitochondria, we carry out atomistic molecular dynamics simulations for three inner mitochondrial membranes and three outer mitochondrial membrane models. These models take into account variations in cardiolipin and cholesterol concentrations as well as the symmetry/asymmetry between the two leaflets. Our simulations allow us to calculate various structural quantities and the bending, twisting, and tilting elastic moduli of the membrane models. Our results indicate that the structures of the inner and outer mitochondrial membranes are quite similar and do not depend much on the variation in lipid compositions. However, the bending modulus of the membranes increases with increasing concentrations of cardiolipin or cholesterol but decreases with a membrane asymmetry. Notably, we found that the dipole potential of the membrane increases with an increasing cardiolipin concentration. Finally, possible roles of cardiolipin in regulating ion and proton currents and maintaining the cristate are discussed in some details.

Published

2023

11. Structural mechanism of mitochondrial membrane remodelling by human OPA1.

Author

von der Malsburg A, Sapp GM, Zuccaro KE, von Appen A, Moss FR 3rd, Kalia R, Bennett JA, Abriata LA, Dal Peraro M, van der Laan M, Frost A, and Aydin H

Subjects

Humans, Biocatalysis, Cardiolipins chemistry, Cardiolipins metabolism, Mutation, Protein Domains, Protein Multimerization, Mitochondrial Dynamics, GTP Phosphohydrolases genetics, GTP Phosphohydrolases metabolism, Membrane Fusion, Mitochondria chemistry, Mitochondria metabolism, Mitochondrial Membranes chemistry, Mitochondrial Membranes enzymology, Mitochondrial Membranes metabolism

Abstract

Distinct morphologies of the mitochondrial network support divergent metabolic and regulatory processes that determine cell function and fate 1-3 . The mechanochemical GTPase optic atrophy 1 (OPA1) influences the architecture of cristae and catalyses the fusion of the mitochondrial inner membrane 4,5 . Despite its fundamental importance, the molecular mechanisms by which OPA1 modulates mitochondrial morphology are unclear. Here, using a combination of cellular and structural analyses, we illuminate the molecular mechanisms that are key to OPA1-dependent membrane remodelling and fusion. Human OPA1 embeds itself into cardiolipin-containing membranes through a lipid-binding paddle domain. A conserved loop within the paddle domain inserts deeply into the bilayer, further stabilizing the interactions with cardiolipin-enriched membranes. OPA1 dimerization through the paddle domain promotes the helical assembly of a flexible OPA1 lattice on the membrane, which drives mitochondrial fusion in cells. Moreover, the membrane-bending OPA1 oligomer undergoes conformational changes that pull the membrane-inserting loop out of the outer leaflet and contribute to the mechanics of membrane remodelling. Our findings provide a structural framework for understanding how human OPA1 shapes mitochondrial morphology and show us how human disease mutations compromise OPA1 functions., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2023

12. A molecular rotor FLIM probe reveals dynamic coupling between mitochondrial inner membrane fluidity and cellular respiration.

Author

Singh G, George G, Raja SO, Kandaswamy P, Kumar M, Thutupalli S, Laxman S, and Gulyani A

Subjects

Molecular Probes chemistry, Cell Respiration, Membrane Fluidity, Osmotic Pressure, Diffusion, Mitochondrial Membranes chemistry

Abstract

The inner mitochondrial membrane (IMM), housing components of the electron transport chain (ETC), is the site for respiration. The ETC relies on mobile carriers; therefore, it has long been argued that the fluidity of the densely packed IMM can potentially influence ETC flux and cell physiology. However, it is unclear if cells temporally modulate IMM fluidity upon metabolic or other stimulation. Using a photostable, red-shifted, cell-permeable molecular-rotor, Mitorotor-1, we present a multiplexed approach for quantitatively mapping IMM fluidity in living cells. This reveals IMM fluidity to be linked to cellular-respiration and responsive to stimuli. Multiple approaches combining in vitro experiments and live-cell fluorescence (FLIM) lifetime imaging microscopy (FLIM) show Mitorotor-1 to robustly report IMM 'microviscosity'/fluidity through changes in molecular free volume. Interestingly, external osmotic stimuli cause controlled swelling/compaction of mitochondria, thereby revealing a graded Mitorotor-1 response to IMM microviscosity. Lateral diffusion measurements of IMM correlate with microviscosity reported via Mitorotor-1 FLIM-lifetime, showing convergence of independent approaches for measuring IMM local-order. Mitorotor-1 FLIM reveals mitochondrial heterogeneity in IMM fluidity; between-and-within cells and across single mitochondrion. Multiplexed FLIM lifetime imaging of Mitorotor-1 and NADH autofluorescence reveals that IMM fluidity positively correlates with respiration, across individual cells. Remarkably, we find that stimulating respiration, through nutrient deprivation or chemically, also leads to increase in IMM fluidity. These data suggest that modulating IMM fluidity supports enhanced respiratory flux. Our study presents a robust method for measuring IMM fluidity and suggests a dynamic regulatory paradigm of modulating IMM local order on changing metabolic demand.

Published

2023

13. Norovirus MLKL-like protein initiates cell death to induce viral egress.

Author

Wang G, Zhang D, Orchard RC, Hancks DC, and Reese TA

Subjects

Animals, Mice, Mitochondria metabolism, Mitochondria pathology, Virus Replication, Protein Sorting Signals, Cardiolipins metabolism, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Cell Death, Norovirus enzymology, Norovirus growth & development, Norovirus pathogenicity, Norovirus physiology, Protein Kinases chemistry, Viral Proteins chemistry, Viral Proteins metabolism, Nucleoside-Triphosphatase chemistry, Nucleoside-Triphosphatase metabolism

Abstract

Non-enveloped viruses require cell lysis to release new virions from infected cells, suggesting that these viruses require mechanisms to induce cell death. Noroviruses are one such group of viruses, but there is no known mechanism that causes norovirus infection-triggered cell death and lysis 1-3 . Here we identify a molecular mechanism of norovirus-induced cell death. We found that the norovirus-encoded NTPase NS3 contains an N-terminal four-helix bundle domain homologous to the membrane-disruption domain of the pseudokinase mixed lineage kinase domain-like (MLKL). NS3 has a mitochondrial localization signal and thus induces cell death by targeting mitochondria. Full-length NS3 and an N-terminal fragment of the protein bound the mitochondrial membrane lipid cardiolipin, permeabilized the mitochondrial membrane and induced mitochondrial dysfunction. Both the N-terminal region and the mitochondrial localization motif of NS3 were essential for cell death, viral egress from cells and viral replication in mice. These findings suggest that noroviruses have acquired a host MLKL-like pore-forming domain to facilitate viral egress by inducing mitochondrial dysfunction., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2023

14. Perfluoroethylcyclohexane sulphonate, an emerging perfluoroalkyl substance, disrupts mitochondrial membranes and the expression of key molecular targets in vitro.

Author

Mahoney H, Cantin J, Xie Y, Brinkmann M, and Giesy JP

Subjects

Animals, Mitochondrial Membranes chemistry, Peroxisome Proliferators metabolism, Glutathione metabolism, Transferases metabolism, Water Pollutants, Chemical toxicity, Fluorocarbons analysis, Oncorhynchus mykiss metabolism

Abstract

Perfluoroethylcyclohexane sulphonate (PFECHS) is an emerging, replacement perfluoroalkyl substance (PFAS) with little information available on the toxic effects or potencies with which to characterize its potential impacts on aquatic environments. This study aimed to characterize effects of PFECHS using in vitro systems, including rainbow trout liver cells (RTL-W1 cell line) and lymphocytes separated from whole blood. It was determined that exposure to PFECHS caused minor acute toxic effects for most endpoints and that little PFECHS was concentrated into cells with a mean in vitro bioconcentration factor of 81 ± 25 L/kg. However, PFECHS was observed to affect the mitochondrial membrane and key molecular receptors, such as the peroxisome proliferator receptor, cytochrome p450-dependent monooxygenases, and receptors involved in oxidative stress. Also, glutathione-S-transferase was significantly down-regulated at a near environmentally relevant exposure concentration of 400 ng/L. These results are the first to report bioconcentration of PFECHS, as well as its effects on the peroxisome proliferator and glutathione-S-transferase receptors, suggesting that even with little bioconcentration, PFECHS has potential to cause adverse effects., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this review., (Copyright © 2023 Elsevier B.V. All rights reserved.)

Published

2023

15. Structural basis of mitochondrial membrane bending by the I-II-III 2 -IV 2 supercomplex.

Author

Mühleip A, Flygaard RK, Baradaran R, Haapanen O, Gruhl T, Tobiasson V, Maréchal A, Sharma V, and Amunts A

Subjects

Electron Transport, Protein Multimerization, Protein Subunits chemistry, Protein Subunits metabolism, Molecular Dynamics Simulation, Binding Sites, Evolution, Molecular, Cryoelectron Microscopy, Electron Transport Complex III chemistry, Electron Transport Complex III metabolism, Electron Transport Complex III ultrastructure, Electron Transport Complex IV chemistry, Electron Transport Complex IV metabolism, Electron Transport Complex IV ultrastructure, Mitochondria chemistry, Mitochondria enzymology, Mitochondria metabolism, Mitochondria ultrastructure, Mitochondrial Membranes chemistry, Mitochondrial Membranes enzymology, Mitochondrial Membranes metabolism, Mitochondrial Membranes ultrastructure, Electron Transport Complex II chemistry, Electron Transport Complex II metabolism, Electron Transport Complex II ultrastructure, Electron Transport Complex I chemistry, Electron Transport Complex I metabolism, Electron Transport Complex I ultrastructure

Abstract

Mitochondrial energy conversion requires an intricate architecture of the inner mitochondrial membrane 1 . Here we show that a supercomplex containing all four respiratory chain components contributes to membrane curvature induction in ciliates. We report cryo-electron microscopy and cryo-tomography structures of the supercomplex that comprises 150 different proteins and 311 bound lipids, forming a stable 5.8-MDa assembly. Owing to subunit acquisition and extension, complex I associates with a complex IV dimer, generating a wedge-shaped gap that serves as a binding site for complex II. Together with a tilted complex III dimer association, it results in a curved membrane region. Using molecular dynamics simulations, we demonstrate that the divergent supercomplex actively contributes to the membrane curvature induction and tubulation of cristae. Our findings highlight how the evolution of protein subunits of respiratory complexes has led to the I-II-III 2 -IV 2 supercomplex that contributes to the shaping of the bioenergetic membrane, thereby enabling its functional specialization., (© 2023. The Author(s).)

Published

2023

16. Single p197 molecules of the mitochondrial genome segregation system of Trypanosoma brucei determine the distance between basal body and outer membrane.

Author

Aeschlimann S, Kalichava A, Schimanski B, Berger BM, Jetishi C, Stettler P, Ochsenreiter T, and Schneider A

Subjects

Basal Bodies chemistry, Epitopes chemistry, Flagella chemistry, DNA Replication, DNA, Mitochondrial genetics, Genome, Mitochondrial, Mitochondrial Membranes chemistry, Protozoan Proteins chemistry, Trypanosoma brucei brucei chemistry, Trypanosoma brucei brucei genetics

Abstract

The tripartite attachment complex (TAC) couples the segregation of the single unit mitochondrial DNA of trypanosomes with the basal body (BB) of the flagellum. Here, we studied the architecture of the exclusion zone filament (EZF) of the TAC, the only known component of which is p197, that connects the BB with the mitochondrial outer membrane (OM). We show that p197 has three domains that are all essential for mitochondrial DNA inheritance. The C terminus of p197 interacts with the mature and probasal body (pro-BB), whereas its N terminus binds to the peripheral OM protein TAC65. The large central region of p197 has a high α-helical content and likely acts as a flexible spacer. Ultrastructure expansion microscopy (U-ExM) of cell lines exclusively expressing p197 versions of different lengths that contain both N- and C-terminal epitope tags demonstrates that full-length p197 alone can bridge the ∼270-nm distance between the BB and the cytosolic face of the OM. Thus U-ExM allows the localization of distinct domains within the same molecules and suggests that p197 is the TAC subunit most proximal to the BB. In addition, U-ExM revealed that p197 acts as a spacer molecule, as two shorter versions of p197, with the repeat domain either removed or replaced by the central domain of the Trypanosoma cruzi p197 ortholog reduced the distance between the BB and the OM in proportion to their predicted molecular weight.

Published

2022

17. Single-Molecule Force Spectroscopy Reveals Stability of mitoNEET and its [2Fe2Se] Cluster in Weakly Acidic and Basic Solutions.

Author

Nie JY, Song GB, Deng YB, and Zheng P

Subjects

Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Single Molecule Imaging, Spectrum Analysis, Iron-Sulfur Proteins analysis, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism

Abstract

The outer mitochondrial membrane protein mitoNEET (mNT) is a recently identified iron-sulfur protein containing a unique Fe 2 S 2 (His) 1 (Cys) 3 metal cluster with a single Fe-N(His87) coordinating bond. This labile Fe-N bond led to multiple unfolding/rupture pathways of mNT and its cluster by atomic force microscopy-based single-molecule force spectroscopy (AFM-SMFS), one of most common tools for characterizing the molecular mechanics. Although previous ensemble studies showed that this labile Fe-N(His) bond is essential for protein function, they also indicated that the protein and its [2Fe2S] cluster are stable under acidic conditions. Thus, we applied AFM-SMFS to measure the stability of mNT and its cluster at pH values of 6, 7, and 8. Indeed, all previous multiple unfolding pathways of mNT were still observed. Moreover, single-molecule measurements revealed that the stabilities of the protein and the [2Fe2S] cluster are consistent at these pH values with only ≈20 pN force differences. Thus, we found that the behavior of the protein is consistent in both weakly acidic and basic solutions despite a labile Fe-N bond., (© 2022 The Authors. Published by Wiley-VCH GmbH.)

Published

2022

18. Optimizing purification of the peripheral membrane protein FAM92A1 fused to a modified spidroin tag.

Author

Wang Z and Mim C

Subjects

Cell Membrane chemistry, Cell Membrane metabolism, Cloning, Molecular, Escherichia coli genetics, Escherichia coli metabolism, Fibroins metabolism, Humans, Membrane Proteins chemistry, Membrane Proteins metabolism, Mitochondria chemistry, Mitochondria metabolism, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Plasmids chemistry, Plasmids metabolism, Protein Stability, Proteins chemistry, Proteins metabolism, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins metabolism, Solubility, Fibroins genetics, Membrane Proteins genetics, Proteins genetics, Recombinant Fusion Proteins genetics

Abstract

Cryo-electron microscopy has revolutionized structural biology. In particular structures of proteins at the membrane interface have been a major contribution of cryoEM. Yet, visualization and characterization of peripheral membrane proteins remains challenging; mostly because there is no unified purification strategy for these proteins. FAM92A1 is a novel peripheral membrane protein that binds to the mitochondrial inner membrane. There, FAM92A1 dimers bind to the membrane and play an essential role in regulating the mitochondrial ultrastructure. Curiously, FAM92A1 has also an important function in ciliogenesis. FAM92A1 is part of the membrane bending Bin1/Amphiphsyin/RVS (BAR) domain protein family. Currently, there is no structure of FAM92A1, mostly because FAM92A1 is unstable and insoluble at high concentrations, like many BAR domain proteins. Yet, pure and concentrated protein is a necessity for screening to generate samples suitable for structure determination. Here, we present an optimized purification and expression strategy for dimeric FAM92A1. To our knowledge, we are the first to use the spidroin tag NT* to successfully purify a peripheral membrane protein. Our results show that NT* not only increases solubility but stabilizes FAM92A1 as a dimer. FAM92A1 fused to NT* is active because it is able to efficiently bend membranes. Taken together, our strategy indicates that this is a possible avenue to express and purify other challenging BAR domain proteins., (Copyright © 2021. Published by Elsevier Inc.)

Published

2022

19. Calcium-induced release of cytochrome c from cardiolipin nanodisks: Implications for apoptosis.

Author

Fox CA, Lethcoe K, and Ryan RO

Subjects

Animals, Apolipoproteins chemistry, Binding Sites genetics, Calcium metabolism, Calcium Chloride chemistry, Cardiolipins chemistry, Cell Communication genetics, Cytochromes c chemistry, Lipid Bilayers chemistry, Locusta migratoria genetics, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Phagocytosis genetics, Phospholipids chemistry, Phospholipids genetics, Protein Domains genetics, Apolipoproteins genetics, Apoptosis genetics, Cardiolipins genetics, Cytochromes c genetics, Protein Binding genetics

Abstract

Miniature bilayer membranes comprised of phospholipid and an apolipoprotein scaffold, termed nanodisks (ND), have been used in binding studies. When ND formulated with cardiolipin (CL), but not phosphatidylcholine, were incubated with cytochrome c, FPLC gel filtration chromatography provided evidence of a stable binding interaction. Incubation of CL ND with CaCl 2 resulted in a concentration-dependent increase in sample turbidity caused by ND particle disruption. Prior incubation of CL ND with cytochrome c increased CL ND sensitivity to CaCl 2 -induced effects. Centrifugation of CaCl 2 -treated CL ND samples yielded pellet and supernatant fractions. Whereas the ND scaffold protein, apolipophorin III, was recovered in the pellet fraction along with CL, the majority of the cytochrome c pool was in the supernatant fraction. Moreover, when cytochrome c CL ND were incubated with CaCl 2 at concentrations below the threshold to induce ND particle disruption, FPLC analysis showed that cytochrome c was released. Pre-incubation of CL ND with CaCl 2 under conditions that do not disrupt ND particle integrity prevented cytochrome c binding to CL ND. Thus, competition between Ca 2+ and cytochrome c for a common binding site on CL modulates cytochrome c binding and likely plays a role in its dissociation from CL-rich cristae membranes in response to apoptotic stimuli., (Copyright © 2021 Elsevier B.V. All rights reserved.)

Published

2021

20. Solubilization of artificial mitochondrial membranes by amphiphilic copolymers of different charge.

Author

Janson K, Zierath J, Kyrilis FL, Semchonok DA, Hamdi F, Skalidis I, Kopf AH, Das M, Kolar C, Rasche M, Vargas C, Keller S, Kastritis PL, and Meister A

Subjects

Dynamic Light Scattering, Membrane Proteins genetics, Membranes, Artificial, Mitochondria genetics, Osmolar Concentration, Polyelectrolytes chemistry, Polymers chemistry, Sodium Chloride chemistry, Lipid Bilayers chemistry, Membrane Proteins chemistry, Mitochondria chemistry, Mitochondrial Membranes chemistry

Abstract

Certain amphiphilic copolymers form lipid-bilayer nanodiscs from artificial and natural membranes, thereby rendering incorporated membrane proteins optimal for structural analysis. Recent studies have shown that the amphiphilicity of a copolymer strongly determines its solubilization efficiency. This is especially true for highly negatively charged membranes, which experience pronounced Coulombic repulsion with polyanionic polymers. Here, we present a systematic study on the solubilization of artificial multicomponent lipid vesicles that mimic inner mitochondrial membranes, which harbor essential membrane-protein complexes. In particular, we compared the lipid-solubilization efficiencies of established anionic with less densely charged or zwitterionic and even cationic copolymers in low- and high-salt concentrations. The nanodiscs formed under these conditions were characterized by dynamic light scattering and negative-stain electron microscopy, pointing to a bimodal distribution of nanodisc diameters with a considerable fraction of nanodiscs engaging in side-by-side interactions through their polymer rims. Overall, our results show that some recent, zwitterionic copolymers are best suited to solubilize negatively charged membranes at high ionic strengths even at low polymer/lipid ratios., (Copyright © 2021. Published by Elsevier B.V.)

Published

2021

21. Ablation of mitochondrial DNA results in widespread remodeling of the mitochondrial complexome.

Author

Guerrero-Castillo S, van Strien J, Brandt U, and Arnold S

Subjects

Adenosine Triphosphate metabolism, Cell Line, Tumor, DNA, Mitochondrial genetics, DNA, Mitochondrial metabolism, Gene Expression, Humans, Mitochondria pathology, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Mitochondrial Proteins deficiency, Multiprotein Complexes deficiency, Osteoblasts metabolism, Osteoblasts pathology, Oxidative Phosphorylation, Adaptation, Physiological, Mitochondria metabolism, Mitochondrial Proteins genetics, Multiprotein Complexes genetics

Abstract

So-called ρ0 cells lack mitochondrial DNA and are therefore incapable of aerobic ATP synthesis. How cells adapt to survive ablation of oxidative phosphorylation remains poorly understood. Complexome profiling analysis of ρ0 cells covered 1,002 mitochondrial proteins and revealed changes in abundance and organization of numerous multiprotein complexes including previously not described assemblies. Beyond multiple subassemblies of complexes that would normally contain components encoded by mitochondrial DNA, we observed widespread reorganization of the complexome. This included distinct changes in the expression pattern of adenine nucleotide carrier isoforms, other mitochondrial transporters, and components of the protein import machinery. Remarkably, ablation of mitochondrial DNA hardly affected the complexes organizing cristae junctions indicating that the altered cristae morphology in ρ0 mitochondria predominantly resulted from the loss of complex V dimers required to impose narrow curvatures to the inner membrane. Our data provide a comprehensive resource for in-depth analysis of remodeling of the mitochondrial complexome in response to respiratory deficiency., (© 2021 The Authors. Published under the terms of the CC BY NC ND 4.0 license.)

Published

2021

22. Age-Related Features of the Viscosity of Plasma and Mitochondrial Membranes of Hepatocytes in Liver Cirrhosis.

Author

Skurikhin EG, Afanas'ev SA, Zhukova MA, Rebrova TY, Muslimova EF, Pan ES, Ermakova NN, Pershina OV, Pakhomova AV, Putrova OD, Sandrikina LA, Kogai LV, and Dygai AM

Subjects

Age Factors, Animals, Cell Membrane chemistry, Cell Membrane drug effects, Hepatocytes metabolism, Hepatocytes pathology, Liver metabolism, Liver pathology, Liver Cirrhosis, Experimental chemically induced, Liver Cirrhosis, Experimental pathology, Male, Mitochondria chemistry, Mitochondria drug effects, Mitochondrial Membranes chemistry, Mitochondrial Membranes drug effects, Rats, Rats, Wistar, Viscosity drug effects, Carbon Tetrachloride toxicity, Ethanol toxicity, Hepatocytes drug effects, Liver drug effects, Liver Cirrhosis, Experimental metabolism

Abstract

The viscosity of plasma and mitochondrial membranes of hepatocytes was studied in young (3-month-old) and old (9-month-old) male Wistar rats. It was shown that viscosity of hepatocyte plasma and mitochondrial membranes in young rats under optimal vital functions in the area of protein-lipid membrane contacts was significantly lower than in old rats. No age-related differences in the viscosity of lipid-lipid membrane contacts and in the polarity of protein-lipid contacts and lipid layers were found. Liver cirrhosis induced by carbon tetrachloride and ethanol administration was associated with increased fluidity of the plasma and mitochondrial membranes of hepatocytes in rats of both age groups. The decrease in membrane viscosity in young rats occurred due to a decrease of the viscosity in the area of protein-lipid and lipid-lipid contacts, while in old rats in the area of protein-lipid contacts. Carbon tetrachloride and ethanol did not affect the polarity of lipid contacts and lipid layers., (© 2021. Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2021

23. Long-lived mitochondrial cristae proteins in mouse heart and brain.

Author

Bomba-Warczak E, Edassery SL, Hark TJ, and Savas JN

Subjects

Animals, Binding Sites, Brain enzymology, Citric Acid Cycle genetics, Electron Transport Complex I chemistry, Electron Transport Complex I genetics, Electron Transport Complex II chemistry, Electron Transport Complex II genetics, Electron Transport Complex III chemistry, Electron Transport Complex III genetics, Electron Transport Complex IV chemistry, Electron Transport Complex IV genetics, Gene Expression, Half-Life, Lipid Metabolism genetics, Mice, Mitochondria genetics, Mitochondrial Membranes chemistry, Mitochondrial Membranes enzymology, Models, Molecular, Organ Specificity, Oxidative Phosphorylation, Protein Binding, Protein Conformation, alpha-Helical, Protein Conformation, beta-Strand, Protein Interaction Domains and Motifs, Protein Stability, Proteome chemistry, Proteome genetics, Electron Transport Complex I metabolism, Electron Transport Complex II metabolism, Electron Transport Complex III metabolism, Electron Transport Complex IV metabolism, Mitochondria enzymology, Myocardium enzymology, Proteome metabolism

Abstract

Long-lived proteins (LLPs) have recently emerged as vital components of intracellular structures whose function is coupled to long-term stability. Mitochondria are multifaceted organelles, and their function hinges on efficient proteome renewal and replacement. Here, using metabolic stable isotope labeling of mice combined with mass spectrometry (MS)-based proteomic analysis, we demonstrate remarkable longevity for a subset of the mitochondrial proteome. We discovered that mitochondrial LLPs (mt-LLPs) can persist for months in tissues harboring long-lived cells, such as brain and heart. Our analysis revealed enrichment of mt-LLPs within the inner mitochondrial membrane, specifically in the cristae subcompartment, and demonstrates that the mitochondrial proteome is not turned over in bulk. Pioneering cross-linking experiments revealed that mt-LLPs are spatially restricted and copreserved within protein OXPHOS complexes, with limited subunit exchange throughout their lifetimes. This study provides an explanation for the exceptional mitochondrial protein lifetimes and supports the concept that LLPs provide key structural stability to multiple large and dynamic intracellular structures., (© 2021 Bomba-Warczak et al.)

Published

2021

24. Dynamics of the permeability transition pore size in isolated mitochondria and mitoplasts.

Author

Kruglov AG, Kharechkina ES, Nikiforova AB, Odinokova IV, and Kruglova SA

Subjects

Humans, Mitochondria metabolism, Mitochondrial Membrane Transport Proteins metabolism, Mitochondrial Membranes metabolism, Calcium chemistry, Mitochondria chemistry, Mitochondrial Membrane Transport Proteins chemistry, Mitochondrial Membranes chemistry

Abstract

The size of the permeability transition pore (PTP) is accepted to be ≤1.5 kDa. However, different authors reported values from 650 to 4000 Da. The present study is focused on the variability of the average PTP size in and between mitochondrial samples, its reasons and relations with PTP dynamics. Measurement of PTP size by the standard method revealed its 500 Da-range variability between mitochondrial samples. Sequential measurements in the same sample showed that the PTP size tends to grow with time and Ca 2+ concentration. Selective damage to the mitochondrial outer membrane (MOM) reduced the apparent PTP size by ~200-300 Da. Hypotonic and hypertonic osmotic shock and partial removal of the MOM with the preservation of the mitochondrial inner membrane intactness decreased the apparent PTP size by ~50%. We developed an approach to continuous monitoring of the PTP size that revealed the existence of stable PTP states with different pore sizes (~700, 900-1000, ~1350, 1700-1800, and 2100-2200 Da) and transitions between them. The transitions were accelerated by elevating the Ca 2+ concentration, temperature, and osmotic pressure, which demonstrates an increased capability of PTP to accommodate to large molecules (plasticity). Cyclosporin A inhibited the transitions between states. The analysis of PTP size dynamics in osmotically shocked mitochondria and mitoplasts confirmed the importance of the MOM for the stabilization of PTP structure. Thus, this approach provides a new tool for PTP studies and the opportunity to reconcile data on the PTP size and mitochondrial megachannel conductance., (© 2021 Federation of American Societies for Experimental Biology.)

Published

2021

25. Deactivation blocks proton pathways in the mitochondrial complex I.

Author

Röpke M, Riepl D, Saura P, Di Luca A, Mühlbauer ME, Jussupow A, Gamiz-Hernandez AP, and Kaila VRI

Subjects

Animals, Binding Sites, Biological Transport, Cell Respiration, Cryoelectron Microscopy, Electron Transport Complex I genetics, Energy Metabolism, Humans, Mitochondrial Diseases genetics, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Molecular Dynamics Simulation, Mutation, Oxidation-Reduction, Protein Conformation, Protein Domains, Protein Structure, Secondary, Quinones chemistry, Quinones metabolism, Water chemistry, Water metabolism, Electron Transport Complex I chemistry, Electron Transport Complex I metabolism, Protons

Abstract

Cellular respiration is powered by membrane-bound redox enzymes that convert chemical energy into an electrochemical proton gradient and drive the energy metabolism. By combining large-scale classical and quantum mechanical simulations with cryo-electron microscopy data, we resolve here molecular details of conformational changes linked to proton pumping in the mammalian complex I. Our data suggest that complex I deactivation blocks water-mediated proton transfer between a membrane-bound quinone site and proton-pumping modules, decoupling the energy-transduction machinery. We identify a putative gating region at the interface between membrane domain subunits ND1 and ND3/ND4L/ND6 that modulates the proton transfer by conformational changes in transmembrane helices and bulky residues. The region is perturbed by mutations linked to human mitochondrial disorders and is suggested to also undergo conformational changes during catalysis of simpler complex I variants that lack the "active"-to-"deactive" transition. Our findings suggest that conformational changes in transmembrane helices modulate the proton transfer dynamics by wetting/dewetting transitions and provide important functional insight into the mammalian respiratory complex I., Competing Interests: The authors declare no competing interest., (Copyright © 2021 the Author(s). Published by PNAS.)

Published

2021

26. NDUFS3 depletion permits complex I maturation and reveals TMEM126A/OPA7 as an assembly factor binding the ND4-module intermediate.

Author

D'Angelo L, Astro E, De Luise M, Kurelac I, Umesh-Ganesh N, Ding S, Fearnley IM, Gasparre G, Zeviani M, Porcelli AM, Fernandez-Vizarra E, and Iommarini L

Subjects

Animals, Binding Sites, CRISPR-Cas Systems, Cell Line, Tumor, Electron Transport Complex I deficiency, Gene Editing, Gene Expression Regulation, Gene Knockout Techniques, HCT116 Cells, Humans, Melanocytes metabolism, Melanocytes pathology, Membrane Proteins metabolism, Mice, Mitochondria metabolism, Mitochondria pathology, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Models, Molecular, NADH Dehydrogenase deficiency, Optic Atrophy metabolism, Optic Atrophy pathology, Osteoblasts metabolism, Osteoblasts pathology, Protein Binding, Protein Conformation, Proteomics, Electron Transport Complex I genetics, Membrane Proteins genetics, Mitochondria genetics, NADH Dehydrogenase genetics, Optic Atrophy genetics

Abstract

Complex I (CI) is the largest enzyme of the mitochondrial respiratory chain, and its defects are the main cause of mitochondrial disease. To understand the mechanisms regulating the extremely intricate biogenesis of this fundamental bioenergetic machine, we analyze the structural and functional consequences of the ablation of NDUFS3, a non-catalytic core subunit. We show that, in diverse mammalian cell types, a small amount of functional CI can still be detected in the complete absence of NDUFS3. In addition, we determine the dynamics of CI disassembly when the amount of NDUFS3 is gradually decreased. The process of degradation of the complex occurs in a hierarchical and modular fashion in which the ND4 module remains stable and bound to TMEM126A. We, thus, uncover the function of TMEM126A, the product of a disease gene causing recessive optic atrophy as a factor necessary for the correct assembly and function of CI., Competing Interests: Declaration of interest The authors declare no competing interests., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

27. Mitochondrial dynamics: Shaping and remodeling an organelle network.

Author

Fenton AR, Jongens TA, and Holzbaur ELF

Subjects

Animals, Cytoskeleton chemistry, Cytoskeleton physiology, Humans, Mitochondria chemistry, Mitochondrial Membranes chemistry, Mitochondrial Membranes physiology, Mitochondrial Proteins chemistry, Mitochondrial Proteins physiology, Organelle Shape, Mitochondria physiology, Mitochondrial Dynamics

Abstract

Mitochondria form networks that continually remodel and adapt to carry out their cellular function. The mitochondrial network is remodeled through changes in mitochondrial morphology, number, and distribution within the cell. Mitochondrial dynamics depend directly on fission, fusion, shape transition, and transport or tethering along the cytoskeleton. Over the past several years, many of the mechanisms underlying these processes have been uncovered. It has become clear that each process is precisely and contextually regulated within the cell. Here, we discuss the mechanisms regulating each aspect of mitochondrial dynamics, which together shape the network as a whole., Competing Interests: Conflict of interest statement Nothing declared., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2021

28. OMA1-An integral membrane protease?

Author

Alavi MV

Subjects

Apoptosis genetics, Humans, Membrane Proteins ultrastructure, Mitochondria enzymology, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Peptide Hydrolases genetics, Signal Transduction genetics, Structural Homology, Protein, Membrane Proteins genetics, Metalloendopeptidases genetics, Metalloendopeptidases ultrastructure, Mitochondria genetics

Abstract

OMA1 is a mitochondrial protease. Among its substrates are DELE1, a signaling peptide, which can elicit the integrated stress response, as well as the membrane-shaping dynamin-related GTPase OPA1, which can drive mitochondrial outer membrane permeabilization. OMA1 is dormant under physiological conditions but rapidly activated upon mitochondrial stress, such as loss of membrane potential or excessive reactive oxygen species. Accordingly, OMA1 was found to be activated in a number of disease conditions, including cancer and neurodegeneration. OMA1 has a predicted transmembrane domain and is believed to be tethered to the mitochondrial inner membrane. Yet, its structure has not been resolved and its context-dependent regulation remains obscure. Here, I review the literature with focus on OMA1's biochemistry. I provide a good homology model of OMA1's active site with a root-mean-square deviation of 0.9 Å and a DALI Z-score of 19.8. And I build a case for OMA1 actually being an integral membrane protease based on OMA1's role in the generation of small signaling peptides, its functional overlap with PARL, and OMA1's homology with ZMPSTE24. The refined understanding of this important enzyme can help with the design of tool compounds and development of chemical probes in the future., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2021

29. Blue-Native Electrophoresis to Study the OXPHOS Complexes.

Author

Fernandez-Vizarra E and Zeviani M

Subjects

Animals, Blood Donors, Humans, Leukocytes cytology, Liver cytology, Mice, Mice, Inbred C57BL, Mitochondria metabolism, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Multiprotein Complexes metabolism, Myocardium cytology, Electrophoresis, Gel, Two-Dimensional methods, Mitochondria chemistry, Multiprotein Complexes chemistry, Native Polyacrylamide Gel Electrophoresis methods, Oxidative Phosphorylation

Abstract

Blue-native polyacrylamide gel electrophoresis (BN-PAGE) is a technique optimized for the analysis of the five components of the mitochondrial oxidative phosphorylation (OXPHOS) system. BN-PAGE is based on the preservation of the interactions between the individual subunits within the integral complexes. To achieve this, the complexes are extracted from the mitochondrial inner membrane using mild detergents and separated by electrophoresis in the absence of denaturing agents. The electrophoretic procedures can then be combined with a variety of downstream detection techniques. Since its development in the 1990s, BN-PAGE has been applied in the study of mitochondria from all kinds of organisms and extensive amounts of data have been produced using this technique, being key for the understanding of many aspects of OXPHOS physiopathology.

Published

2021

30. Mitochondrial Complexome Profiling.

Author

Giese H, Meisterknecht J, Heidler J, and Wittig I

Subjects

Cell Line, Tumor, Chromatography, Liquid methods, Humans, Membrane Proteins chemistry, Membrane Proteins metabolism, Mitochondria metabolism, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Mitochondrial Proteins chemistry, Mitochondrial Proteins metabolism, Peptides chemistry, Peptides metabolism, Tandem Mass Spectrometry methods, Mass Spectrometry methods, Mitochondria chemistry, Native Polyacrylamide Gel Electrophoresis methods

Abstract

Complexome profiling combines blue native gel electrophoresis (BNE) and quantitative mass spectrometry to define an entire protein interactome of a cell, an organelle, or a biological membrane preparation. The method allows the identification of protein assemblies with low abundance and detects dynamic processes of protein complex assembly. Applications of complexome profiling range from the determination of complex subunit compositions, assembly of single protein complexes, and supercomplexes to comprehensive differential studies between patients or disease models. This chapter describes the workflow of complexome profiling from sample preparation, mass spectrometry to data analysis with a bioinformatics tool.

Published

2021

31. The extracellular juncture domains in the intimin passenger adopt a constitutively extended conformation inducing restraints to its sphere of action.

Author

Weikum J, Kulakova A, Tesei G, Yoshimoto S, Jægerum LV, Schütz M, Hori K, Skepö M, Harris P, Leo JC, and Morth JP

Subjects

Bacterial Outer Membrane Proteins chemistry, Bacterial Outer Membrane Proteins metabolism, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Protein Structure, Secondary, Virulence Factors chemistry, Virulence Factors metabolism, Adhesins, Bacterial chemistry, Adhesins, Bacterial metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism

Abstract

Enterohemorrhagic and enteropathogenic Escherichia coli are among the most important food-borne pathogens, posing a global health threat. The virulence factor intimin is essential for the attachment of pathogenic E. coli to the intestinal host cell. Intimin consists of four extracellular bacterial immunoglobulin-like (Big) domains, D00-D2, extending into the fifth lectin subdomain (D3) that binds to the Tir-receptor on the host cell. Here, we present the crystal structures of the elusive D00-D0 domains at 1.5 Å and D0-D1 at 1.8 Å resolution, which confirms that the passenger of intimin has five distinct domains. We describe that D00-D0 exhibits a higher degree of rigidity and D00 likely functions as a juncture domain at the outer membrane-extracellular medium interface. We conclude that D00 is a unique Big domain with a specific topology likely found in a broad range of other inverse autotransporters. The accumulated data allows us to model the complete passenger of intimin and propose functionality to the Big domains, D00-D0-D1, extending directly from the membrane.

Published

2020

32. Statins interfere with the attachment of S. cerevisiae mtDNA to the inner mitochondrial membrane.

Author

Cirigliano A, Amelina A, Biferali B, Macone A, Mozzetta C, Bianchi MM, Mori M, Botta B, Pick E, Negri R, and Rinaldi T

Subjects

DNA, Mitochondrial chemistry, Humans, Hydroxymethylglutaryl-CoA Reductase Inhibitors chemistry, Mitochondrial Membranes chemistry, DNA, Mitochondrial metabolism, Hydroxymethylglutaryl-CoA Reductase Inhibitors metabolism, Mitochondria metabolism, Mitochondrial Membranes metabolism, Saccharomyces cerevisiae chemistry

Abstract

The 3-hydroxy-3-methylglutaryl-CoA reductase, a key enzyme of the mevalonate pathway for the synthesis of cholesterol in mammals (ergosterol in fungi), is inhibited by statins, a class of cholesterol lowering drugs. Indeed, statins are in a wide medical use, yet statins treatment could induce side effects as hepatotoxicity and myopathy in patients. We used Saccharomyces cerevisiae as a model to investigate the effects of statins on mitochondria. We demonstrate that statins are active in S.cerevisiae by lowering the ergosterol content in cells and interfering with the attachment of mitochondrial DNA to the inner mitochondrial membrane. Experiments on murine myoblasts confirmed these results in mammals. We propose that the instability of mitochondrial DNA is an early indirect target of statins.

Published

2020

33. Flavonoids modulate liposomal membrane structure, regulate mitochondrial membrane permeability and prevent erythrocyte oxidative damage.

Author

Veiko AG, Sekowski S, Lapshina EA, Wilczewska AZ, Markiewicz KH, Zamaraeva M, Zhao HC, and Zavodnik IB

Subjects

Animals, Erythrocytes metabolism, Flavonoids pharmacology, Liposomes, Mitochondria, Liver metabolism, Mitochondrial Membranes metabolism, Oxidation-Reduction, Permeability, Rats, tert-Butylhydroperoxide chemistry, tert-Butylhydroperoxide pharmacology, Erythrocytes chemistry, Flavonoids chemistry, Mitochondria, Liver chemistry, Mitochondrial Membranes chemistry

Abstract

In the present work, we investigated the interaction of flavonoids (quercetin, naringenin and catechin) with cellular and artificial membranes. The flavonoids considerably inhibited membrane lipid peroxidation in rat erythrocytes treated with tert-butyl hydroperoxide (700 μM), and the IC 50 values for prevention of this process were equal to 9.7 ± 0.8 μM, 8.8 ± 0.7 μM, and 37.8 ± 4.4 μM in the case of quercetin, catechin and naringenin, respectively, and slightly decreased glutathione oxidation. In isolated rat liver mitochondria, quercetin, catechin and naringenin (10-50 μM) dose-dependently increased the sensitivity to Ca 2+ ions - induced mitochondrial permeability transition. Using the probes TMA-DPH and DPH we showed that quercetin rather than catechin and naringenin strongly decreased the microfluidity of the 1,2-dimyristoyl-sn-glycero-3-phosphocholine liposomal membrane bilayer at different depths. On the contrary, using the probe Laurdan we observed that naringenin transfer the bilayer to a more ordered state, whereas quercetin dose-dependently decreased the order of lipid molecule packing and increased hydration in the region of polar head groups. The incorporation of the flavonoids, quercetin and naringenin and not catechin, into the liposomes induced an increase in the zeta potential of the membrane and enlarged the area of the bilayer as well as lowered the temperature and the enthalpy of the membrane phase transition. The effects of the flavonoids were connected with modification of membrane fluidity, packing, stability, electrokinetic properties, size and permeability, prevention of oxidative stress, which depended on the nature of the flavonoid molecule and the nature of the membrane., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2020

34. Lipids glue BAK dimers together.

Author

Flores-Romero H and García-Sáez AJ

Subjects

Animals, Humans, Mitochondrial Membranes chemistry, Protein Binding, Protein Domains, bcl-2 Homologous Antagonist-Killer Protein chemistry, bcl-2-Associated X Protein chemistry, bcl-2-Associated X Protein metabolism, Apoptosis, Mitochondrial Membranes metabolism, Phospholipids metabolism, Protein Multimerization, bcl-2 Homologous Antagonist-Killer Protein metabolism

Published

2020

35. Human HSPA9 (mtHsp70, mortalin) interacts with lipid bilayers containing cardiolipin, a major component of the inner mitochondrial membrane.

Author

Dores-Silva PR, Cauvi DM, Kiraly VTR, Borges JC, and De Maio A

Subjects

Humans, Liposomes, Cardiolipins chemistry, HSP70 Heat-Shock Proteins chemistry, Lipid Bilayers chemistry, Mitochondrial Membranes chemistry, Mitochondrial Proteins chemistry

Abstract

Mitochondrial Hsp70 (HSPA9, mtHsp70, mortalin) in conjunction with a complex set of other proteins is involved in the transport of polypeptides across the mitochondrial matrix. This observation allows us to hypothesize that HSPA9 might interact with membranes directly, similarly to other Hsp70s. Thus, we investigated whether human HSPA9 could also get inserted into lipid membranes. Human HSPA9 was incubated with liposomes made of lipids found within the mitochondrial membrane, such as 1', 3'-bis [1, 2-dimyristoyl-sn-glycero-3-phospho]-glycerol (CL), palmitoyl-oleoyl phosphocholine (POPC), palmitoyl-oleoyl phosphoserine (POPS), and palmitoyl-oleoyl phosphoethanolamine (POPE). HSPA9 displayed a predilection for CL and POPS, and low affinity for POPC and POPE, suggesting that the proteins have high specificity for negatively charged phospholipids. Then, liposomes were made with a composition resembling either the outer or inner mitochondrial membrane (OMM or IMM, respectively). We observed that HSPA9 has a higher affinity for IMM than OMM, which is consistent with the higher content of CL in the IMM. A comparison for the incorporation into POPS or CL liposomes by HSPA9 or HSPA1 indicated that both proteins behaved very similarly when exposed to CL liposomes, but differently with POPS liposomes, which was further corroborated by their susceptibility to proteinase K digestion after incorporation into liposomes. The measurement of thermodynamic parameters also showed that the interaction of both proteins with CL and POPS liposomes was different. Overall, our data showed that HSPA9 is prone to interact with membranes resembling the IMM that may be important for its role in the translocation of proteins into the mitochondria., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2020

36. Type III ATP synthase is a symmetry-deviated dimer that induces membrane curvature through tetramerization.

Author

Flygaard RK, Mühleip A, Tobiasson V, and Amunts A

Subjects

Cryoelectron Microscopy, Membrane Lipids chemistry, Mitochondrial Membranes chemistry, Mitochondrial Membranes enzymology, Mitochondrial Membranes ultrastructure, Mitochondrial Proton-Translocating ATPases classification, Mitochondrial Proton-Translocating ATPases ultrastructure, Models, Molecular, Protein Interaction Domains and Motifs, Protein Multimerization, Protein Structure, Quaternary, Protein Subunits chemistry, Proteins chemistry, Proteins ultrastructure, Protozoan Proteins chemistry, Protozoan Proteins ultrastructure, Tetrahymena thermophila enzymology, Tetrahymena thermophila ultrastructure, ATPase Inhibitory Protein, Mitochondrial Proton-Translocating ATPases chemistry

Abstract

Mitochondrial ATP synthases form functional homodimers to induce cristae curvature that is a universal property of mitochondria. To expand on the understanding of this fundamental phenomenon, we characterized the unique type III mitochondrial ATP synthase in its dimeric and tetrameric form. The cryo-EM structure of a ciliate ATP synthase dimer reveals an unusual U-shaped assembly of 81 proteins, including a substoichiometrically bound ATPTT2, 40 lipids, and co-factors NAD and CoQ. A single copy of subunit ATPTT2 functions as a membrane anchor for the dimeric inhibitor IF 1 . Type III specific linker proteins stably tie the ATP synthase monomers in parallel to each other. The intricate dimer architecture is scaffolded by an extended subunit-a that provides a template for both intra- and inter-dimer interactions. The latter results in the formation of tetramer assemblies, the membrane part of which we determined to 3.1 Å resolution. The structure of the type III ATP synthase tetramer and its associated lipids suggests that it is the intact unit propagating the membrane curvature.

Published

2020

37. Na + controls hypoxic signalling by the mitochondrial respiratory chain.

Author

Hernansanz-Agustín P, Choya-Foces C, Carregal-Romero S, Ramos E, Oliva T, Villa-Piña T, Moreno L, Izquierdo-Álvarez A, Cabrera-García JD, Cortés A, Lechuga-Vieco AV, Jadiya P, Navarro E, Parada E, Palomino-Antolín A, Tello D, Acín-Pérez R, Rodríguez-Aguilera JC, Navas P, Cogolludo Á, López-Montero I, Martínez-Del-Pozo Á, Egea J, López MG, Elrod JW, Ruíz-Cabello J, Bogdanova A, Enríquez JA, and Martínez-Ruiz A

Subjects

Animals, Breast Neoplasms metabolism, Breast Neoplasms pathology, Calcium Phosphates metabolism, Cell Line, Tumor, Chemical Precipitation, Humans, Male, Membrane Fluidity, Mice, Inbred C57BL, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Mitochondrial Proteins metabolism, Oxidative Phosphorylation, Rats, Rats, Wistar, Reactive Oxygen Species metabolism, Sodium-Calcium Exchanger metabolism, Electron Transport, Hypoxia metabolism, Mitochondria metabolism, Second Messenger Systems, Sodium metabolism

Abstract

All metazoans depend on the consumption of O 2 by the mitochondrial oxidative phosphorylation system (OXPHOS) to produce energy. In addition, the OXPHOS uses O 2 to produce reactive oxygen species that can drive cell adaptations 1-4 , a phenomenon that occurs in hypoxia 4-8 and whose precise mechanism remains unknown. Ca 2+ is the best known ion that acts as a second messenger 9 , yet the role ascribed to Na + is to serve as a mere mediator of membrane potential 10 . Here we show that Na + acts as a second messenger that regulates OXPHOS function and the production of reactive oxygen species by modulating the fluidity of the inner mitochondrial membrane. A conformational shift in mitochondrial complex I during acute hypoxia 11 drives acidification of the matrix and the release of free Ca 2+ from calcium phosphate (CaP) precipitates. The concomitant activation of the mitochondrial Na + /Ca 2+ exchanger promotes the import of Na + into the matrix. Na + interacts with phospholipids, reducing inner mitochondrial membrane fluidity and the mobility of free ubiquinone between complex II and complex III, but not inside supercomplexes. As a consequence, superoxide is produced at complex III. The inhibition of Na + import through the Na + /Ca 2+ exchanger is sufficient to block this pathway, preventing adaptation to hypoxia. These results reveal that Na + controls OXPHOS function and redox signalling through an unexpected interaction with phospholipids, with profound consequences for cellular metabolism.

Published

2020

38. Structure of the dimeric ATP synthase from bovine mitochondria.

Author

Spikes TE, Montgomery MG, and Walker JE

Subjects

Animals, Cattle, Mitochondrial Membranes chemistry, Mitochondrial Membranes enzymology, Models, Molecular, Protein Conformation, Protein Subunits chemistry, Protein Subunits metabolism, Protons, Torque, Mitochondria enzymology, Mitochondrial Proton-Translocating ATPases chemistry, Mitochondrial Proton-Translocating ATPases metabolism, Mitochondrial Proton-Translocating ATPases ultrastructure

Abstract

The structure of the dimeric ATP synthase from bovine mitochondria determined in three rotational states by electron cryo-microscopy provides evidence that the proton uptake from the mitochondrial matrix via the proton inlet half channel proceeds via a Grotthus mechanism, and a similar mechanism may operate in the exit half channel. The structure has given information about the architecture and mechanical constitution and properties of the peripheral stalk, part of the membrane extrinsic region of the stator, and how the action of the peripheral stalk damps the side-to-side rocking motions that occur in the enzyme complex during the catalytic cycle. It also describes wedge structures in the membrane domains of each monomer, where the skeleton of each wedge is provided by three α-helices in the membrane domains of the b-subunit to which the supernumerary subunits e, f, and g and the membrane domain of subunit A6L are bound. Protein voids in the wedge are filled by three specifically bound cardiolipin molecules and two other phospholipids. The external surfaces of the wedges link the monomeric complexes together into the dimeric structures and provide a pivot to allow the monomer-monomer interfaces to change during catalysis and to accommodate other changes not related directly to catalysis in the monomer-monomer interface that occur in mitochondrial cristae. The structure of the bovine dimer also demonstrates that the structures of dimeric ATP synthases in a tetrameric porcine enzyme have been seriously misinterpreted in the membrane domains., Competing Interests: The authors declare no competing interest., (Copyright © 2020 the Author(s). Published by PNAS.)

Published

2020

39. Protocol for the Analysis of Yeast and Human Mitochondrial Respiratory Chain Complexes and Supercomplexes by Blue Native Electrophoresis.

Author

Timón-Gómez A, Pérez-Pérez R, Nyvltova E, Ugalde C, Fontanesi F, and Barrientos A

Subjects

Electrophoresis methods, Electrophoresis, Gel, Two-Dimensional methods, Humans, Mitochondrial Membranes chemistry, Rosaniline Dyes chemistry, Saccharomyces cerevisiae, Electron Transport physiology, Multiprotein Complexes analysis, Native Polyacrylamide Gel Electrophoresis methods

Abstract

By using negatively charged Coomassie brilliant blue G-250 dye to induce a charge shift on proteins, blue native polyacrylamide gel electrophoresis (BN-PAGE) allows resolution of enzymatically active multiprotein complexes extracted from cellular or subcellular lysates while retaining their native conformation. BN-PAGE was first developed to analyze the size, composition, and relative abundance of the complexes and supercomplexes that form the mitochondrial respiratory chain and OXPHOS system. Here, we present a detailed protocol of BN-PAGE to obtain robust and reproducible results. For complete details on the use and execution of this protocol, please refer to Lobo-Jarne et al. (2018) and Timón-Gómez et al. (2020)., Competing Interests: DECLARATION OF INTERESTS The authors declare no competing interests.

Published

2020

40. Structural insights into mammalian mitochondrial translation elongation catalyzed by mtEFG1.

Author

Kummer E and Ban N

Subjects

Animals, Cryoelectron Microscopy, Humans, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Mitochondrial Membranes ultrastructure, Mitochondrial Proteins genetics, Mitochondrial Proteins metabolism, Mitochondrial Ribosomes metabolism, Peptide Elongation Factor G genetics, Peptide Elongation Factor G metabolism, RNA, Mitochondrial genetics, RNA, Mitochondrial metabolism, RNA, Transfer genetics, RNA, Transfer metabolism, Swine, Mitochondrial Proteins chemistry, Mitochondrial Ribosomes chemistry, Mitochondrial Ribosomes ultrastructure, Peptide Elongation Factor G chemistry, Protein Biosynthesis, RNA, Mitochondrial chemistry, RNA, Transfer chemistry

Abstract

Mitochondria are eukaryotic organelles of bacterial origin where respiration takes place to produce cellular chemical energy. These reactions are catalyzed by the respiratory chain complexes located in the inner mitochondrial membrane. Notably, key components of the respiratory chain complexes are encoded on the mitochondrial chromosome and their expression relies on a dedicated mitochondrial translation machinery. Defects in the mitochondrial gene expression machinery lead to a variety of diseases in humans mostly affecting tissues with high energy demand such as the nervous system, the heart, or the muscles. The mitochondrial translation system has substantially diverged from its bacterial ancestor, including alterations in the mitoribosomal architecture, multiple changes to the set of translation factors and striking reductions in otherwise conserved tRNA elements. Although a number of structures of mitochondrial ribosomes from different species have been determined, our mechanistic understanding of the mitochondrial translation cycle remains largely unexplored. Here, we present two cryo-EM reconstructions of human mitochondrial elongation factor G1 bound to the mammalian mitochondrial ribosome at two different steps of the tRNA translocation reaction during translation elongation. Our structures explain the mechanism of tRNA and mRNA translocation on the mitoribosome, the regulation of mtEFG1 activity by the ribosomal GTPase-associated center, and the basis of decreased susceptibility of mtEFG1 to the commonly used antibiotic fusidic acid., (© 2020 The Authors.)

Published

2020

41. Cardiolipin remodeling in Barth syndrome and other hereditary cardiomyopathies.

Author

Bertero E, Kutschka I, Maack C, and Dudek J

Subjects

Animals, Barth Syndrome genetics, Barth Syndrome pathology, Biological Transport, Cardiomyopathies genetics, Cardiomyopathies pathology, Cardiomyopathy, Dilated genetics, Cardiomyopathy, Dilated pathology, Cataract genetics, Cataract pathology, Cerebellar Ataxia genetics, Cerebellar Ataxia pathology, Electron Transport genetics, Humans, Metabolism, Inborn Errors genetics, Metabolism, Inborn Errors pathology, Mitochondria pathology, Mitochondrial Dynamics genetics, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Mitochondrial Proteins genetics, Mitophagy genetics, Myocardium metabolism, Myocardium pathology, Phosphatidic Acids metabolism, Barth Syndrome metabolism, Cardiolipins metabolism, Cardiomyopathies metabolism, Cardiomyopathy, Dilated metabolism, Cataract metabolism, Cerebellar Ataxia metabolism, Metabolism, Inborn Errors metabolism, Mitochondria metabolism, Mitochondrial Proteins metabolism

Abstract

Mitochondria play a prominent role in cardiac energy metabolism, and their function is critically dependent on the integrity of mitochondrial membranes. Disorders characterized by mitochondrial dysfunction are commonly associated with cardiac disease. The mitochondrial phospholipid cardiolipin directly interacts with a number of essential protein complexes in the mitochondrial membranes including the respiratory chain, mitochondrial metabolite carriers, and proteins critical for mitochondrial morphology. Barth syndrome is an X-linked disorder caused by an inherited defect in the biogenesis of the mitochondrial phospholipid cardiolipin. How cardiolipin deficiency impacts on mitochondrial function and how mitochondrial dysfunction causes cardiomyopathy has been intensively studied in cellular and animal models of Barth syndrome. These findings may also have implications for the molecular mechanisms underlying other inherited disorders associated with defects in cardiolipin, such as Sengers syndrome and dilated cardiomyopathy with ataxia (DCMA)., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2020

42. Lipid asymmetry of a model mitochondrial outer membrane affects Bax-dependent permeabilization.

Author

Bozelli JC Jr, Hou YH, Schreier S, and Epand RM

Subjects

Apoptosis drug effects, Cell Membrane Permeability drug effects, Humans, Liposomes chemistry, Liposomes ultrastructure, Membrane Proteins chemistry, Membrane Proteins genetics, Mitochondria drug effects, Mitochondrial Membranes ultrastructure, Phospholipids chemistry, Phospholipids genetics, Lipids chemistry, Mitochondria genetics, Mitochondrial Membranes chemistry, bcl-2-Associated X Protein genetics

Abstract

The presence of an asymmetric distribution of lipids in biological membranes was first described ca. 50 years ago. While various studies had reported the role of loss of lipid asymmetry on signaling processes, its effect on membrane physical properties and membrane-protein interactions lacks further understanding. The recent description of new technologies for the preparation of asymmetric model membranes has helped to fill part of this gap. However, the major effort so far has been on plasma membrane models. Here we describe the preparation of liposomes mimicking the mitochondria outer membrane (MOM) in regard to its lipid composition and asymmetry. By employing the methyl-β-cyclodextrin-catalyzed lipid exchange technology and accurate quantification of lipid asymmetry with head group-specific probes we showed the successful preparation of a MOM model bearing a physiologically relevant lipid composition and asymmetry. In addition, by a direct comparison with its lipid symmetrical counterpart it is shown that asymmetric models were more resistant to tBid-promoted Bax-permeabilization, suggesting a role played by MOM lipid asymmetry on the mitochondria pathway of apoptosis. The barrier imposed by lipid asymmetry on membrane permeabilization was in part due to a decrease in the concentration of membrane-bound proteins, which was likely a consequence of the two mutually-dependent properties; i.e., the lower electrostatic surface potential and the higher molecular packing imposed by lipid asymmetry. It is proposed that MOM lipid asymmetry imparts different physical properties on the membrane and might add an additional component of regulation in intricate mitochondrial processes., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2020

43. Orientation of FtsH protease homologs in Trypanosoma brucei inner mitochondrial membrane and its evolutionary implications.

Author

Kovalinka T, Pánek T, Kováčová B, and Horváth A

Subjects

Animals, Arabidopsis classification, Arabidopsis enzymology, Arabidopsis genetics, Conserved Sequence, Euglena gracilis classification, Euglena gracilis enzymology, Euglena gracilis genetics, Euglena longa classification, Euglena longa enzymology, Euglena longa genetics, Gene Expression, Humans, Isoenzymes chemistry, Isoenzymes genetics, Isoenzymes metabolism, Leishmania major classification, Leishmania major enzymology, Leishmania major genetics, Mice, Mitochondria enzymology, Mitochondria genetics, Mitochondrial Membranes chemistry, Mitochondrial Membranes enzymology, Mitochondrial Proteins genetics, Mitochondrial Proteins metabolism, Peptide Hydrolases genetics, Peptide Hydrolases metabolism, Phylogeny, Protein Domains, Protozoan Proteins genetics, Protozoan Proteins metabolism, Saccharomyces cerevisiae classification, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae genetics, Trypanosoma brucei brucei classification, Trypanosoma brucei brucei genetics, Evolution, Molecular, Mitochondrial Proteins chemistry, Peptide Hydrolases chemistry, Protozoan Proteins chemistry, Trypanosoma brucei brucei enzymology

Abstract

Trypanosoma brucei is an important human pathogen. In this study, we have focused on the characterization of FtsH protease, ATP-dependent membrane-bound mitochondrial enzyme important for regulation of protein abundance. We have determined localization and orientation of all six putative T.brucei FtsH homologs in the inner mitochondrial membrane by in silico analyses, by immunofluorescence, and with protease assay. The evolutionary origin of these homologs has been tested by comparative phylogenetic analysis. Surprisingly, some kinetoplastid FtsH proteins display inverted orientation in the mitochondrial membrane compared to related proteins of other examined eukaryotes. Moreover, our data strongly suggest that during evolution the orientation of FtsH protease in T. brucei varied due to both loss and acquisition of the transmembrane domain., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2020

44. ATP synthase c-subunit ring as the channel of mitochondrial permeability transition: Regulator of metabolism in development and degeneration.

Author

Mnatsakanyan N and Jonas EA

Subjects

Animals, Humans, Disease Susceptibility, Energy Metabolism, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Models, Molecular, Neuronal Plasticity, Neurons metabolism, Permeability, Protein Conformation, Mitochondria metabolism, Mitochondrial Proton-Translocating ATPases chemistry, Mitochondrial Proton-Translocating ATPases metabolism, Protein Subunits chemistry, Protein Subunits metabolism

Abstract

The mitochondrial permeability transition pore (mPTP) or mitochondrial megachannel is arguably one of the most mysterious phenomena in biology today. mPTP has been at the center of ongoing extensive scientific research for the last several decades. In this review we will discuss recent advances in the field that enhance our understanding of the molecular composition of mPTP, its regulatory mechanisms and its pathophysiological role. We will describe our recent findings on the role of ATP synthase c-subunit ring as a central player in mitochondrial permeability transition and as an important metabolic regulator during development and in degenerative diseases., (Copyright © 2020 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2020

45. Miro: A molecular switch at the center of mitochondrial regulation.

Author

Eberhardt EL, Ludlam AV, Tan Z, and Cianfrocco MA

Subjects

Animals, Humans, Mitochondria chemistry, Mitochondrial Proteins chemistry, Models, Molecular, rho GTP-Binding Proteins chemistry, rho GTP-Binding Proteins metabolism, Mitochondria metabolism, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Mitochondrial Proteins metabolism

Abstract

The orchestration of mitochondria within the cell represents a critical aspect of cell biology. At the center of this process is the outer mitochondrial membrane protein, Miro. Miro coordinates diverse cellular processes by regulating connections between organelles and the cytoskeleton that range from mediating contacts between the endoplasmic reticulum and mitochondria to the regulation of both actin and microtubule motor proteins. Recently, a number of cell biological, biochemical, and protein structure studies have helped to characterize the myriad roles played by Miro. In addition to answering questions regarding Miro's function, these studies have opened the door to new avenues in the study of Miro in the cell. This review will focus on summarizing recent findings for Miro's structure, function, and activity while highlighting key questions that remain unanswered., (© 2020 The Protein Society.)

Published

2020

46. Effect of a post-translational modification mimic on protein translocation through a nanopore.

Author

Hoogerheide DP, Gurnev PA, Rostovtseva TK, and Bezrukov SM

Subjects

Animals, Protein Transport, Rats, Mitochondria, Liver chemistry, Mitochondria, Liver metabolism, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Nanopores, Protein Processing, Post-Translational, alpha-Synuclein chemistry, alpha-Synuclein metabolism

Abstract

Post-translational modifications (PTMs) of proteins are recognized as crucial components of cell signaling pathways through modulating folding, altering stability, changing interactions with ligands, and, therefore, serving multiple regulatory functions. PTMs occur as covalent modifications of the protein's amino acid side chains or the length and composition of their termini. Here we study the functional consequences of PTMs for α-synuclein (αSyn) interactions with the nanopore of the voltage-dependent anion channel (VDAC) of the outer mitochondrial membrane. PTMs were mimicked by a divalent Alexa Fluor 488 sidechain attached separately at two positions on the αSyn C-terminus. Using single-channel reconstitution into planar lipid membranes, we find that such modifications change interactions drastically in both efficiency of VDAC inhibition by αSyn and its translocation through the VDAC nanopore. Analysis of the on/off kinetics in terms of an interaction "quasipotential" allows the positions of the C-terminal modifications to be determined with an accuracy of about three residues. Moreover, our results uncover a previously unobserved mechanism by which cytosolic proteins control β-barrel channels and thus a new regulatory function for PTMs.

Published

2020

47. Research journey of respirasome.

Author

Wu M, Gu J, Zong S, Guo R, Liu T, and Yang M

Subjects

Animals, Cryoelectron Microscopy, Electron Transport, Electron Transport Chain Complex Proteins chemistry, Humans, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Models, Molecular, Oxidative Phosphorylation, Protons, Cell Respiration, Electron Transport Chain Complex Proteins metabolism

Abstract

Respirasome, as a vital part of the oxidative phosphorylation system, undertakes the task of transferring electrons from the electron donors to oxygen and produces a proton concentration gradient across the inner mitochondrial membrane through the coupled translocation of protons. Copious research has been carried out on this lynchpin of respiration. From the discovery of individual respiratory complexes to the report of the high-resolution structure of mammalian respiratory supercomplex I 1 III 2 IV 1 , scientists have gradually uncovered the mysterious veil of the electron transport chain (ETC). With the discovery of the mammalian respiratory mega complex I 2 III 2 IV 2 , a new perspective emerges in the research field of the ETC. Behind these advances glitters the light of the revolution in both theory and technology. Here, we give a short review about how scientists 'see' the structure and the mechanism of respirasome from the macroscopic scale to the atomic scale during the past decades.

Published

2020

48. Kinetic coupling of the respiratory chain with ATP synthase, but not proton gradients, drives ATP production in cristae membranes.

Author

Toth A, Meyrat A, Stoldt S, Santiago R, Wenzel D, Jakobs S, von Ballmoos C, and Ott M

Subjects

Electron Transport, Hydrogen-Ion Concentration, Kinetics, Mitochondria chemistry, Mitochondria genetics, Mitochondria metabolism, Mitochondria ultrastructure, Mitochondrial Membranes chemistry, Mitochondrial Membranes enzymology, Mitochondrial Proton-Translocating ATPases genetics, Oxidative Phosphorylation, Proteolipids metabolism, Proton Pumps metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Adenosine Triphosphate biosynthesis, Mitochondrial Membranes metabolism, Mitochondrial Proton-Translocating ATPases metabolism, Protons

Abstract

Mitochondria have a characteristic ultrastructure with invaginations of the inner membrane called cristae that contain the protein complexes of the oxidative phosphorylation system. How this particular morphology of the respiratory membrane impacts energy conversion is currently unknown. One proposed role of cristae formation is to facilitate the establishment of local proton gradients to fuel ATP synthesis. Here, we determined the local pH values at defined sublocations within mitochondria of respiring yeast cells by fusing a pH-sensitive GFP to proteins residing in different mitochondrial subcompartments. Only a small proton gradient was detected over the inner membrane in wild type or cristae-lacking cells. Conversely, the obtained pH values did barely permit ATP synthesis in a reconstituted system containing purified yeast F 1 F 0 ATP synthase, although, thermodynamically, a sufficiently high driving force was applied. At higher driving forces, where robust ATP synthesis was observed, a P -side pH value of 6 increased the ATP synthesis rate 3-fold compared to pH 7. In contrast, when ATP synthase was coreconstituted with an active proton-translocating cytochrome oxidase, ATP synthesis readily occurred at the measured, physiological pH values. Our study thus reveals that the morphology of the inner membrane does not influence the subcompartmental pH values and is not necessary for robust oxidative phosphorylation in mitochondria. Instead, it is likely that the dense packing of the oxidative phosphorylation complexes in the cristae membranes assists kinetic coupling between proton pumping and ATP synthesis., Competing Interests: The authors declare no competing interest.

Published

2020

49. Structure of the Bcs1 AAA-ATPase suggests an airlock-like translocation mechanism for folded proteins.

Author

Kater L, Wagener N, Berninghausen O, Becker T, Neupert W, and Beckmann R

Subjects

ATPases Associated with Diverse Cellular Activities chemistry, Electron Transport Complex III chemistry, Electron Transport Complex III metabolism, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Mitochondrial Proteins chemistry, Models, Molecular, Molecular Chaperones chemistry, Nuclear Pore Complex Proteins chemistry, Protein Conformation, Protein Domains, Protein Folding, Protein Multimerization, Protein Transport, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae Proteins chemistry, ATPases Associated with Diverse Cellular Activities metabolism, Mitochondrial Proteins metabolism, Molecular Chaperones metabolism, Nuclear Pore Complex Proteins metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Some proteins require completion of folding before translocation across a membrane into another cellular compartment. Yet the permeability barrier of the membrane should not be compromised and mechanisms have remained mostly elusive. Here, we present the structure of Saccharomyces cerevisiae Bcs1, an AAA-ATPase of the inner mitochondrial membrane. Bcs1 facilitates the translocation of the Rieske protein, Rip1, which requires folding and incorporation of a 2Fe-2S cluster before translocation and subsequent integration into the bc1 complex. Surprisingly, Bcs1 assembles into exclusively heptameric homo-oligomers, with each protomer consisting of an amphipathic transmembrane helix, a middle domain and an ATPase domain. Together they form two aqueous vestibules, the first being accessible from the mitochondrial matrix and the second positioned in the inner membrane, with both separated by the seal-forming middle domain. On the basis of this unique architecture, we propose an airlock-like translocation mechanism for folded Rip1.

Published

2020

50. The Bcl-2 Family: Ancient Origins, Conserved Structures, and Divergent Mechanisms.

Author

Banjara S, Suraweera CD, Hinds MG, and Kvansakul M

Subjects

Amino Acid Sequence, Animals, Apoptosis, Autophagy, Humans, Mitochondrial Membranes chemistry, Mitochondrial Membranes metabolism, Models, Molecular, Protein Interaction Maps, Proto-Oncogene Proteins c-bcl-2 chemistry, Sequence Alignment, Proto-Oncogene Proteins c-bcl-2 metabolism

Abstract

Intrinsic apoptosis, the response to intracellular cell death stimuli, is regulated by the interplay of the B-cell lymphoma 2 (Bcl-2) family and their membrane interactions. Bcl-2 proteins mediate a number of processes including development, homeostasis, autophagy, and innate and adaptive immune responses and their dysregulation underpins a host of diseases including cancer. The Bcl-2 family is characterized by the presence of conserved sequence motifs called Bcl-2 homology motifs, as well as a transmembrane region, which form the interaction sites and intracellular location mechanism, respectively. Bcl-2 proteins have been recognized in the earliest metazoans including Porifera (sponges), Placozoans, and Cnidarians (e.g., Hydra). A number of viruses have gained Bcl-2 homologs and subvert innate immunity and cellular apoptosis for their replication, but they frequently have very different sequences to their host Bcl-2 analogs. Though most mechanisms of apoptosis initiation converge on activation of caspases that destroy the cell from within, the numerous gene insertions, deletions, and duplications during evolution have led to a divergence in mechanisms of intrinsic apoptosis. Currently, the action of the Bcl-2 family is best understood in vertebrates and nematodes but new insights are emerging from evolutionarily earlier organisms. This review focuses on the mechanisms underpinning the activity of Bcl-2 proteins including their structures and interactions, and how they have changed over the course of evolution.

Published

2020