Your search keyword '"Michael Lazarou"' showing total 24 results

1. The influence of aerobic exercise on mitochondrial quality control in skeletal muscle

Author

Ashleigh M. Philp, Nicholas J. Saner, Andrew Philp, Michael Lazarou, and Ian G. Ganley

Subjects

0301 basic medicine, Organelle Biogenesis, Energy demand, Physiology, Mitophagy, Skeletal muscle, Adaptive response, Mitochondrion, Biology, Mitochondria, Mitochondria, Muscle, Cell biology, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, medicine, Humans, Aerobic exercise, Exercise physiology, Muscle, Skeletal, Exercise, 030217 neurology & neurosurgery, Biogenesis

Abstract

Mitochondria are dynamic organelles, intricately designed to meet cellular energy requirements. To accommodate alterations in energy demand, mitochondria have a high degree of plasticity, changing in response to transient activation of numerous stress-related pathways. This adaptive response is particularly relevant in highly metabolic tissues such as skeletal muscle, where mitochondria support numerous biological processes related to metabolism, growth and regeneration. Aerobic exercise is a potent stimulus for skeletal muscle remodelling, leading to alterations in substrate utilisation, fibre-type composition and performance. Underlying these physiological responses is a change in mitochondrial quality control (MQC), a term encompassing the co-ordination of mitochondrial synthesis (biogenesis), remodelling (dynamics) and degradation (mitophagy) pathways. Understanding of MQC in skeletal muscle and the regulatory role of aerobic exercise of this process are rapidly advancing, as are the molecular techniques allowing the study of MQC in vivo. Given the emerging link between MQC and the onset of numerous non-communicable diseases, understanding the molecular regulation of MQC, and the role of aerobic exercise in this process, will have substantial future impact on therapeutic approaches to manipulate MQC and maintain mitochondrial function across health span.

Published

2021

2. Autophagy promotes cell survival by maintaining NAD levels

Author

Tetsushi Kataura, Lucia Sedlackova, Elsje G. Otten, Ruchika Kumari, David Shapira, Filippo Scialo, Rhoda Stefanatos, Kei-ichi Ishikawa, George Kelly, Elena Seranova, Congxin Sun, Dorothea Maetzel, Niall Kenneth, Sergey Trushin, Tong Zhang, Eugenia Trushina, Charles C. Bascom, Ryan Tasseff, Robert J. Isfort, John E. Oblong, Satomi Miwa, Michael Lazarou, Rudolf Jaenisch, Masaya Imoto, Shinji Saiki, Manolis Papamichos-Chronakis, Ravi Manjithaya, Oliver D.K. Maddocks, Alberto Sanz, Sovan Sarkar, Viktor I. Korolchuk, Kataura, T., Sedlackova, L., Otten, E. G., Kumari, R., Shapira, D., Scialo, F., Stefanatos, R., Ishikawa, K. -I., Kelly, G., Seranova, E., Sun, C., Maetzel, D., Kenneth, N., Trushin, S., Zhang, T., Trushina, E., Bascom, C. C., Tasseff, R., Isfort, R. J., Oblong, J. E., Miwa, S., Lazarou, M., Jaenisch, R., Imoto, M., Saiki, S., Papamichos-Chronakis, M., Manjithaya, R., Maddocks, O. D. K., Sanz, A., Sarkar, S., and Korolchuk, V. I.

Subjects

Cell Death, Cell Survival, Cell Biology, Saccharomyces cerevisiae, NAD, General Biochemistry, Genetics and Molecular Biology, PARP, mitochondria, Mice, mitophagy, ageing, Autophagy, DNA damage, Sirtuins, Animals, Humans, Molecular Biology, metabolism, Developmental Biology

Abstract

Autophagy is an essential catabolic process that promotes the clearance of surplus or damaged intracellular components. Loss of autophagy in age-related human pathologies contributes to tissue degeneration through a poorly understood mechanism. Here, we identify an evolutionarily conserved role of autophagy from yeast to humans in the preservation of nicotinamide adenine dinucleotide (NAD) levels, which are critical for cell survival. In respiring mouse fibroblasts with autophagy deficiency, loss of mitochondrial quality control was found to trigger hyperactivation of stress responses mediated by NADases of PARP and Sirtuin families. Uncontrolled depletion of the NAD(H) pool by these enzymes ultimately contributed to mitochondrial membrane depolarization and cell death. Pharmacological and genetic interventions targeting several key elements of this cascade improved the survival of autophagy-deficient yeast, mouse fibroblasts, and human neurons. Our study provides a mechanistic link between autophagy and NAD metabolism and identifies targets for interventions in human diseases associated with autophagic, lysosomal, and mitochondrial dysfunction.

Published

2022

3. Immunofluorescence-Based Measurement of Autophagosome Formation During Mitophagy

Author

Benjamin S, Padman and Michael, Lazarou

Subjects

Ubiquitin-Protein Ligases, Macroautophagy, Autophagosomes, Mitophagy, Protein Kinases, Mitochondria

Abstract

Damaged, dysfunctional, or excess mitochondria are removed from cells via a selective form of macroautophagy termed mitophagy. The clearance of mitochondria during mitophagy is mediated by double-membrane vesicles called autophagosomes, which encapsulate mitochondria that have been tagged for mitophagic removal before delivering them to lysosomes for degradation. A variety of different mitophagy pathways exist that differ in their mechanisms of initiation but share a common pathway of autophagosome formation. Autophagosome biogenesis is regulated by a number of autophagy factors which translocate from the cytosol to spatially defined focal points (foci) on the mitochondrial surface after mitophagy has been initiated. The functional analysis of autophagosome biogenesis requires the use of microscopy-based techniques which assess the recruitment of autophagy factors to mitophagic foci representing autophagosome formation sites. Here, we describe a routine method for the quantitative 3D analysis of mitophagic foci in PINK1/Parkin mitophagy immunofluorescence samples through the application of object-based image analysis (OBIA) to 3D confocal imaging datasets. The approach enables unbiased high-throughput characterisation of autophagosome biogenesis during mitophagy.

Published

2022

4. LC3/GABARAPs drive ubiquitin-independent recruitment of Optineurin and NDP52 to amplify mitophagy

Author

Lan K. Nguyen, Thanh Ngoc Nguyen, Benjamin S. Padman, Michael Lazarou, Marvin Skulsuppaisarn, and Louise Uoselis

Subjects

0301 basic medicine, Autophagosome, ATG8, Ubiquitin-Protein Ligases, Science, Amino Acid Motifs, General Physics and Astronomy, PINK1, Cell Cycle Proteins, 02 engineering and technology, General Biochemistry, Genetics and Molecular Biology, Parkin, Article, 03 medical and health sciences, Ubiquitin, Transcription Factor TFIIIA, Mitophagy, Autophagy, Humans, lcsh:Science, Optineurin, Adaptor Proteins, Signal Transducing, Multidisciplinary, biology, Autophagosomes, Membrane Transport Proteins, Nuclear Proteins, General Chemistry, Autophagy-Related Protein 8 Family, 021001 nanoscience & nanotechnology, Cell biology, Mitochondria, 030104 developmental biology, biology.protein, lcsh:Q, 0210 nano-technology, Apoptosis Regulatory Proteins, Carrier Proteins, Microtubule-Associated Proteins, Protein Kinases, HeLa Cells, Protein Binding

Abstract

Current models of selective autophagy dictate that autophagy receptors, including Optineurin and NDP52, link cargo to autophagosomal membranes. This is thought to occur via autophagy receptor binding to Atg8 homologs (LC3/GABARAPs) through an LC3 interacting region (LIR). The LIR motif within autophagy receptors is therefore widely recognised as being essential for selective sequestration of cargo. Here we show that the LIR motif within OPTN and NDP52 is dispensable for Atg8 recruitment and selectivity during PINK1/Parkin mitophagy. Instead, Atg8s play a critical role in mediating ubiquitin-independent recruitment of OPTN and NDP52 to growing phagophore membranes via the LIR motif. The additional recruitment of OPTN and NDP52 amplifies mitophagy through an Atg8-dependent positive feedback loop. Rather than functioning in selectivity, our discovery of a role for the LIR motif in mitophagy amplification points toward a general mechanism by which Atg8s can recruit autophagy factors to drive autophagosome growth and amplify selective autophagy., Selective autophagy receptors are thought to selectively recruit Atg8 positive membranes to cargo via their LIR motif. Here, the authors show the LIR motifs in OPTN and NDP52 are dispensable for selectivity, functioning instead to recruit additional receptors and amplify mitophagy.

Published

2019

5. Plant mitophagy: Beware of Friendly or you might get eaten

Author

Thanh Ngoc Nguyen and Michael Lazarou

Subjects

0301 basic medicine, business.industry, fungi, Mitophagy, food and beverages, Plant Development, Garbage disposal, Biology, Plants, General Biochemistry, Genetics and Molecular Biology, Biotechnology, Mitochondria, 03 medical and health sciences, Plant development, 030104 developmental biology, 0302 clinical medicine, General Agricultural and Biological Sciences, business, 030217 neurology & neurosurgery

Abstract

Summary Mitophagy is a selective garbage disposal pathway that rids cells of excess or damaged mitochondria. In this issue, Ma et al. uncover a role for Friendly in driving depolarisation-induced mitophagy in plants and highlight a physiological role for mitophagy during plant development.

Published

2021

6. Insights on autophagosome–lysosome tethering from structural and biochemical characterization of human autophagy factor EPG5

Author

Thanh Ngoc Nguyen, Calvin K. Yip, Michael Lazarou, Yiu Wing Sunny Cheung, Michael Gong, Samuel Chan, and Sung Eun Nam

Subjects

Autophagosome, Protein Conformation, Vesicular Transport Proteins, Autophagy-Related Proteins, Medicine (miscellaneous), Cellular homeostasis, Membrane trafficking, 0302 clinical medicine, Mitophagy, Sf9 Cells, Biology (General), Late endosome, 0303 health sciences, Protein Stability, Mitochondria, Cell biology, Protein Transport, medicine.anatomical_structure, General Agricultural and Biological Sciences, Microtubule-Associated Proteins, Protein Binding, QH301-705.5, GABARAP, PINK1, Biology, Cataract, Article, General Biochemistry, Genetics and Molecular Biology, Structure-Activity Relationship, 03 medical and health sciences, Lysosome, Electron microscopy, Autophagy, medicine, Animals, Humans, Genetic Predisposition to Disease, Protein Interaction Domains and Motifs, Adaptor Proteins, Signal Transducing, X-ray crystallography, 030304 developmental biology, Autophagosomes, Autophagy-Related Protein 8 Family, Mutation, Proteolysis, Agenesis of Corpus Callosum, Apoptosis Regulatory Proteins, Lysosomes, 030217 neurology & neurosurgery, HeLa Cells

Abstract

Pivotal to the maintenance of cellular homeostasis, macroautophagy (hereafter autophagy) is an evolutionarily conserved degradation system that involves sequestration of cytoplasmic material into the double-membrane autophagosome and targeting of this transport vesicle to the lysosome/late endosome for degradation. EPG5 is a large-sized metazoan protein proposed to serve as a tethering factor to enforce autophagosome–lysosome/late endosome fusion specificity, and its deficiency causes a severe multisystem disorder known as Vici syndrome. Here, we show that human EPG5 (hEPG5) adopts an extended “shepherd’s staff” architecture. We find that hEPG5 binds preferentially to members of the GABARAP subfamily of human ATG8 proteins critical to autophagosome–lysosome fusion. The hEPG5–GABARAPs interaction, which is mediated by tandem LIR motifs that exhibit differential affinities, is required for hEPG5 recruitment to mitochondria during PINK1/Parkin-dependent mitophagy. Lastly, we find that the Vici syndrome mutation Gln336Arg does not affect the hEPG5’s overall stability nor its ability to engage in interaction with the GABARAPs. Collectively, results from our studies reveal new insights into how hEPG5 recognizes mature autophagosome and establish a platform for examining the molecular effects of Vici syndrome disease mutations on hEPG5., Nam and Cheung et al. describe the structural and biochemical characterization of human autophagy factor EPG5 that functions in autophagosome–lysosome tethering. They show that hEPG5 adopts an extended shepherd’s staff architecture, binds preferentially to GABARAP proteins, and is recruited to mitochondria during mitophagy.

Published

2021

7. ATG4 family proteins drive phagophore growth independently of the LC3/GABARAP lipidation system

Author

Susanne Zellner, Grace Khuu, Louise Uoselis, Benjamin S. Padman, Runa S.J. Lindblom, Marvin Skulsuppaisarn, Thanh Ngoc Nguyen, Michael Lazarou, Emily M. Watts, Wai Kit Lam, and Christian Behrends

Subjects

Autophagosome, Proteases, GABARAP, Autophagosome maturation, ATG8, Ubiquitin-Protein Ligases, Vesicular Transport Proteins, Autophagy-Related Proteins, Biology, Parkin, 03 medical and health sciences, 0302 clinical medicine, Imaging, Three-Dimensional, Microscopy, Electron, Transmission, Artificial Intelligence, Mitophagy, Humans, Molecular Biology, 030304 developmental biology, Adaptor Proteins, Signal Transducing, 0303 health sciences, Autophagy, Autophagosomes, Membrane Proteins, Cell Biology, Autophagy-Related Protein 8 Family, Lipid Metabolism, Cell biology, Mitochondria, Cysteine Endopeptidases, Protein Transport, HEK293 Cells, Apoptosis Regulatory Proteins, Microtubule-Associated Proteins, Protein Kinases, 030217 neurology & neurosurgery, HeLa Cells, Signal Transduction

Abstract

The sequestration of damaged mitochondria within double-membrane structures termed autophagosomes is a key step of PINK1/Parkin mitophagy. The ATG4 family of proteases are thought to regulate autophagosome formation exclusively by processing the ubiquitin-like ATG8 family (LC3/GABARAPs). We discover that human ATG4s promote autophagosome formation independently of their protease activity and of ATG8 family processing. ATG4 proximity networks reveal a role for ATG4s and their proximity partners, including the immune-disease protein LRBA, in ATG9A vesicle trafficking to mitochondria. Artificial intelligence-directed 3D electron microscopy of phagophores shows that ATG4s promote phagophore-ER contacts during the lipid-transfer phase of autophagosome formation. We also show that ATG8 removal during autophagosome maturation does not depend on ATG4 activity. Instead, ATG4s can disassemble ATG8-protein conjugates, revealing a role for ATG4s as deubiquitinating-like enzymes. These findings establish non-canonical roles of the ATG4 family beyond the ATG8 lipidation axis and provide an AI-driven framework for rapid 3D electron microscopy.

Published

2020

8. Dissecting the Roles of Mitochondrial Complex I Intermediate Assembly Complex Factors in the Biogenesis of Complex I

Author

Linden Muellner-Wong, David A. Stroud, Diana Stojanovski, Boris Reljic, Michael Lazarou, Luke E. Formosa, Thomas Daniel Jackson, Michael T. Ryan, Alice J. Sharpe, and Traude H. Beilharz

Subjects

0301 basic medicine, Electron Transport Complex I, Organelle Biogenesis, Chemistry, Respiratory chain, Computational biology, Mitochondrion, General Biochemistry, Genetics and Molecular Biology, Oxidative Phosphorylation, Mitochondria, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, lcsh:Biology (General), Humans, Organelle biogenesis, lcsh:QH301-705.5, 030217 neurology & neurosurgery, Mitochondrial Complex I, Biogenesis, TMEM126B

Abstract

Summary: Mitochondrial complex I harbors 7 mitochondrial and 38 nuclear-encoded subunits. Its biogenesis requires the assembly and integration of distinct intermediate modules, mediated by numerous assembly factors. The mitochondrial complex I intermediate assembly (MCIA) complex, containing assembly factors NDUFAF1, ECSIT, ACAD9, and TMEM126B, is required for building the intermediate ND2-module. The role of the MCIA complex and the involvement of other proteins in the biogenesis of this module is unclear. Cell knockout studies reveal that while each MCIA component is critical for complex I assembly, a hierarchy of stability exists centered on ACAD9. We also identify TMEM186 and COA1 as bona fide components of the MCIA complex with loss of either resulting in MCIA complex defects and reduced complex I assembly. TMEM186 enriches with newly translated ND3, and COA1 enriches with ND2. Our findings provide new functional insights into the essential nature of the MCIA complex in complex I assembly. : Formosa et al. investigate the function of the MCIA complex in complex I assembly. They demonstrate the requirement of individual components for the formation of complex I intermediates and assembly of the final enzyme. Finally, they characterize the involvement of TMEM186 and COA1 in this process. Keywords: assembly factors, complex I, MCIA complex, mitochondria, NADH-ubiquinone dehydrogenase, oxidative phosphorylation

Published

2019

9. Parkin inhibits BAK and BAX apoptotic function by distinct mechanisms during mitophagy

Author

Iris K. L. Tan, Shuai Huang, Grant Dewson, Jonathan P. Bernardini, Christopher D. Riffkin, Jason M. Brouwer, Michael Lazarou, Peter E. Czabotar, Aleksandra Bankovacki, Che A. Stafford, Ahmad Wardak, and Jarrod J. Sandow

Subjects

Ubiquitin-Protein Ligases, Apoptosis, PINK1, Mitochondrion, General Biochemistry, Genetics and Molecular Biology, Parkin, Cell Line, Mice, 03 medical and health sciences, 0302 clinical medicine, Bcl-2-associated X protein, Ubiquitin, Mitophagy, Animals, Humans, Molecular Biology, bcl-2-Associated X Protein, 030304 developmental biology, 0303 health sciences, General Immunology and Microbiology, biology, Lysine, General Neuroscience, Ubiquitination, Articles, Mitochondria, nervous system diseases, Cell biology, Ubiquitin ligase, HEK293 Cells, bcl-2 Homologous Antagonist-Killer Protein, biology.protein, biological phenomena, cell phenomena, and immunity, 030217 neurology & neurosurgery, Bcl-2 Homologous Antagonist-Killer Protein, HeLa Cells

Abstract

The E3 ubiquitin ligase Parkin is a key effector of the removal of damaged mitochondria by mitophagy. Parkin determines cell fate in response to mitochondrial damage, with its loss promoting early onset Parkinson's disease and potentially also cancer progression. Controlling a cell's apoptotic response is essential to co‐ordinate the removal of damaged mitochondria. We report that following mitochondrial damage‐induced mitophagy, Parkin directly ubiquitinates the apoptotic effector protein BAK at a conserved lysine in its hydrophobic groove, a region that is crucial for BAK activation by BH3‐only proteins and its homo‐dimerisation during apoptosis. Ubiquitination inhibited BAK activity by impairing its activation and the formation of lethal BAK oligomers. Parkin also suppresses BAX‐mediated apoptosis, but in the absence of BAX ubiquitination suggesting an indirect mechanism. In addition, we find that BAK‐dependent mitochondrial outer membrane permeabilisation during apoptosis promotes PINK1‐dependent Parkin activation. Hence, we propose that Parkin directly inhibits BAK to suppress errant apoptosis, thereby allowing the effective clearance of damaged mitochondria, but also promotes clearance of apoptotic mitochondria to limit their potential pro‐inflammatory effect.

Published

2018

10. Parkin and mitophagy in cancer

Author

Grant Dewson, Jonathan P. Bernardini, and Michael Lazarou

Subjects

0301 basic medicine, Cancer Research, Ubiquitin-Protein Ligases, Mitochondrial Degradation, PINK1, Biology, Mitochondrion, Parkin, Substrate Specificity, 03 medical and health sciences, Ubiquitin, Neoplasms, Mitophagy, Genetics, Animals, Homeostasis, Humans, Molecular Biology, Autophagy, Ubiquitination, Mitochondria, nervous system diseases, Cell biology, Ubiquitin ligase, 030104 developmental biology, biology.protein, Energy Metabolism, Protein Kinases

Abstract

Mitophagy, the selective engulfment and clearance of mitochondria, is essential for the homeostasis of a healthy network of functioning mitochondria and prevents excessive production of cytotoxic reactive oxygen species from damaged mitochondria. The mitochondrially targeted PTEN-induced kinase-1 (PINK1) and the E3 ubiquitin ligase Parkin are well-established synergistic mediators of the mitophagy of dysfunctional mitochondria. This pathway relies on the ubiquitination of a number of mitochondrial outer membrane substrates and subsequent docking of autophagy receptor proteins to selectively clear mitochondria. There are also alternate Parkin-independent mitophagy pathways mediated by BCL2/adenovirus E1B 19 kDa protein-interacting protein 3 and Nip-3 like protein X as well as other effectors. There is increasing evidence that ablation of mitophagy accelerates a number of pathologies. Familial Parkinsonism is associated with loss-of-function mutations in PINK1 and Parkin. A growing number of studies have observed a correlation between impaired Parkin activity and enhanced cancer development, leading to the emerging concept that Parkin activity, or mitophagy in general, is a tumour suppression mechanism. This review examines the molecular mechanisms of mitophagy and highlights the potential links between Parkin and the hallmarks of cancer that may influence tumour development and progression.

Published

2016

11. Autophagy induced during apoptosis degrades mitochondria and inhibits type I interferon secretion

Author

Kate McArthur, Lisa M Lindqvist, Daniel Frank, Michael Lazarou, Benjamin T. Kile, Toby A. Dite, David L. Vaux, and Jonathan S. Oakhill

Subjects

0301 basic medicine, ATG5, Apoptosis, AMP-Activated Protein Kinases, Article, 03 medical and health sciences, Mice, AMP-activated protein kinase, medicine, Autophagy, Animals, Protein kinase A, Molecular Biology, Mice, Knockout, biology, Chemistry, Cell Biology, Cell biology, Mitochondria, 030104 developmental biology, Type I interferon secretion, Interferon Type I, biology.protein, Apoptosome, biological phenomena, cell phenomena, and immunity, Apoptosis Regulatory Proteins, Interferon type I, medicine.drug

Abstract

Cells undergoing Bax/Bak-mediated apoptosis exhibit signs of autophagy, but how it is activated and its significance is unknown. By directly activating Bax/Bak with BH3-only proteins or BH3 mimetic compounds, we demonstrate that mitochondrial damage correlated with a rapid increase in intracellular [AMP]/[ATP], phosphorylation of 5′ AMP-activated protein kinase (AMPK), and activation of unc-51 like autophagy activating kinase 1 (ULK1). Consequently, autophagic flux was triggered early in the apoptotic pathway, as activation of the apoptosome and caspases were not necessary for its induction. Bax/Bak-triggered autophagy resulted in the clearance of damaged mitochondria in an ATG5/7-dependent manner that did not require Parkin. Importantly, Bax/Bak-mediated autophagy inhibited the secretion of the pro-inflammatory cytokine interferon-β (IFN-β) produced in response to mitochondrial damage, but not another cytokine interleukin-6 (IL-6). These findings show that Bax/Bak stimulated autophagy is essential for ensuring immunological silence during apoptosis.

Published

2017

12. Structure, function, and regulation of mitofusin-2 in health and disease

Author

Brent Neumann, Gursimran Chandhok, and Michael Lazarou

Subjects

0301 basic medicine, Cell signaling, obesity, MFN2, Mitochondrion, Biology, Charcot–Marie–Tooth disease, General Biochemistry, Genetics and Molecular Biology, Gene Expression Regulation, Enzymologic, GTP Phosphohydrolases, Mitochondrial Proteins, 03 medical and health sciences, Mitofusin-2, neurodegenerative disease, medicine, MFN1, Humans, Genetics, diabetes, vascular disease, Original Articles, medicine.disease, mitofusin‐1, mitofusin‐2, mitochondrial dynamics, Cell biology, Mitochondria, 030104 developmental biology, mitochondrial fusion, DNAJA3, Optic Atrophy 1, Original Article, General Agricultural and Biological Sciences

Abstract

Mitochondria are highly dynamic organelles that constantly migrate, fuse, and divide to regulate their shape, size, number, and bioenergetic function. Mitofusins (Mfn1/2), optic atrophy 1 (OPA1), and dynamin‐related protein 1 (Drp1), are key regulators of mitochondrial fusion and fission. Mutations in these molecules are associated with severe neurodegenerative and non‐neurological diseases pointing to the importance of functional mitochondrial dynamics in normal cell physiology. In recent years, significant progress has been made in our understanding of mitochondrial dynamics, which has raised interest in defining the physiological roles of key regulators of fusion and fission and led to the identification of additional functions of Mfn2 in mitochondrial metabolism, cell signalling, and apoptosis. In this review, we summarize the current knowledge of the structural and functional properties of Mfn2 as well as its regulation in different tissues, and also discuss the consequences of aberrant Mfn2 expression.

Published

2017

13. Keeping the immune system in check: a role for mitophagy

Author

Michael Lazarou

Subjects

Programmed cell death, Cell Survival, Inflammasomes, T-Lymphocytes, Ubiquitin-Protein Ligases, Immunology, Cell, Population, Biology, Mitochondrion, Mitochondrial Proteins, Immune system, Mitophagy, Autophagy, medicine, Humans, Immunology and Allergy, education, education.field_of_study, Cell Biology, Mitochondria, Cell biology, medicine.anatomical_structure, Gene Expression Regulation, Immune System, Signal transduction, Energy Metabolism, Protein Kinases, Signal Transduction

Abstract

Mitochondria play a central role in many facets of cellular function including energy production, control of cell death and immune signaling. Breakdown of any of these pathways because of mitochondrial deficits or excessive reactive oxygen species production has detrimental consequences for immune system function and cell viability. Maintaining the functional integrity of mitochondria is therefore a critical challenge for the cell. Surveillance systems that monitor mitochondrial status enable the cell to identify and either repair or eliminate dysfunctional mitochondria. Mitophagy is a selective form of autophagy that eliminates dysfunctional mitochondria from the population to maintain overall mitochondrial health. This review covers the major players involved in mitophagy and explores the role mitophagy plays to support the immune system.

Published

2014

14. PINK1 drives Parkin self-association and HECT-like E3 activity upstream of mitochondrial binding

Author

Soojay Banerjee, Michael Lazarou, Ephrem Tekle, Derek P. Narendra, Seok Min Jin, and Richard J. Youle

Subjects

Ubiquitin-Protein Ligases, PINK1, macromolecular substances, Mitochondrion, Models, Biological, Parkin, Cytosol, Ubiquitin, Report, Mitophagy, Humans, Research Articles, chemistry.chemical_classification, DNA ligase, biology, Cell-Free System, Cell Biology, Ubiquitin ligase, nervous system diseases, Mitochondria, chemistry, Biochemistry, biology.protein, Protein Kinases, HeLa Cells

Abstract

PINK1 activates the HECT-like E3 ubiquitin ligase activity and self-association of Parkin upstream of its translocation to mitochondria and induction of mitophagy., Genetic studies indicate that the mitochondrial kinase PINK1 and the RING-between-RING E3 ubiquitin ligase Parkin function in the same pathway. In concurrence, mechanistic studies show that PINK1 can recruit Parkin from the cytosol to the mitochondria, increase the ubiquitination activity of Parkin, and induce Parkin-mediated mitophagy. Here, we used a cell-free assay to recapitulate PINK1-dependent activation of Parkin ubiquitination of a validated mitochondrial substrate, mitofusin 1. We show that PINK1 activated the formation of a Parkin–ubiquitin thioester intermediate, a hallmark of HECT E3 ligases, both in vitro and in vivo. Parkin HECT-like ubiquitin ligase activity was essential for PINK1-mediated Parkin translocation to mitochondria and mitophagy. Using an inactive Parkin mutant, we found that PINK1 stimulated Parkin self-association and complex formation upstream of mitochondrial translocation. Self-association occurred independent of ubiquitination activity through the RING-between-RING domain, providing mechanistic insight into how PINK1 activates Parkin.

Published

2013

15. The porin VDAC2 is the mitochondrial platform for Bax retrotranslocation

Author

Martin van der Laan, Frank Edlich, Thanh Ngoc Nguyen, Joachim Lauterwasser, William J. Craigen, Ralf M. Zerbes, Franziska Todt, and Michael Lazarou

Subjects

0301 basic medicine, Cations, Divalent, Cell, Apoptosis, Mitochondrion, Models, Biological, Article, 03 medical and health sciences, Gene Knockout Techniques, Bcl-2-associated X protein, Cytosol, medicine, Humans, bcl-2-Associated X Protein, Multidisciplinary, biology, Nucleotides, Voltage-Dependent Anion Channel 2, HCT116 Cells, Cell biology, Transport protein, Mitochondria, Protein Transport, 030104 developmental biology, medicine.anatomical_structure, Porin, Mitochondrial Membranes, biology.protein, VDAC2

Abstract

The pro-apoptotic Bcl-2 protein Bax can permeabilize the outer mitochondrial membrane and therefore commit human cells to apoptosis. Bax is regulated by constant translocation to the mitochondria and retrotranslocation back into the cytosol. Bax retrotranslocation depends on pro-survival Bcl-2 proteins and stabilizes inactive Bax. Here we show that Bax retrotranslocation shuttles membrane-associated and membrane-integral Bax from isolated mitochondria. We further discover the mitochondrial porin voltage-dependent anion channel 2 (VDAC2) as essential component and platform for Bax retrotranslocation. VDAC2 ensures mitochondria-specific membrane association of Bax and in the absence of VDAC2 Bax localizes towards other cell compartments. Bax retrotranslocation is also regulated by nucleotides and calcium ions, suggesting a potential role of the transport of these ions through VDAC2 in Bax retrotranslocation. Together, our results reveal the unanticipated bifunctional role of VDAC2 to target Bax specifically to the mitochondria and ensure Bax inhibition by retrotranslocation into the cytosol.

Published

2016

16. Role of PINK1 Binding to the TOM Complex and Alternate Intracellular Membranes in Recruitment and Activation of the E3 Ligase Parkin

Author

Michael Lazarou, Richard J. Youle, Seok Min Jin, and Lesley A. Kane

Subjects

Translocase of the outer membrane, Ubiquitin-Protein Ligases, PINK1, TIM/TOM complex, General Biochemistry, Genetics and Molecular Biology, Parkin, Article, Immunoenzyme Techniques, Cytosol, Mitophagy, Mitochondrial Precursor Protein Import Complex Proteins, Autophagy, Humans, Kinase activity, Molecular Biology, biology, Cell Biology, Intracellular Membranes, Cell biology, Ubiquitin ligase, nervous system diseases, Mitochondria, Protein Transport, biology.protein, Protein Multimerization, Carrier Proteins, Protein Kinases, HeLa Cells, Protein Binding, Developmental Biology

Abstract

SummaryMutations in the mitochondrial kinase PINK1 and the cytosolic E3 ligase Parkin can cause Parkinson's disease. Damaged mitochondria accumulate PINK1 on the outer membrane where, dependent on kinase activity, it recruits and activates Parkin to induce mitophagy, potentially maintaining organelle fidelity. How PINK1 recruits Parkin is unknown. We show that endogenous PINK1 forms a 700 kDa complex with the translocase of the outer membrane (TOM) selectively on depolarized mitochondria whereas PINK1 ectopically targeted to the outer membrane retains association with TOM on polarized mitochondria. Inducibly targeting PINK1 to peroxisomes or lysosomes, which lack a TOM complex, recruits Parkin and activates ubiquitin ligase activity on the respective organelles. Once there, Parkin induces organelle selective autophagy of peroxisomes but not lysosomes. We propose that the association of PINK1 with the TOM complex allows rapid reimport of PINK1 to rescue repolarized mitochondria from mitophagy, and discount mitochondrial-specific factors for Parkin translocation and activation.

Published

2012

17. Mutations in the Gene Encoding C8orf38 Block Complex I Assembly by Inhibiting Production of the Mitochondria-Encoded Subunit ND1

Author

Michael Lazarou, Elena J. Tucker, Alison G. Compton, David R. Thorburn, Christa George, Michael T. Ryan, and Matthew McKenzie

Subjects

Protein subunit, Biology, Mitochondrion, medicine.disease_cause, DNA, Mitochondrial, Conserved sequence, Mitochondrial Proteins, Structural Biology, Chlorocebus aethiops, medicine, Protein biosynthesis, Animals, Humans, Protein Isoforms, Molecular Biology, Genetics, Mutation, Lentivirus, Translation (biology), Fibroblasts, Mitochondria, Protein Structure, Tertiary, Cell biology, Complementation, HEK293 Cells, Protein Biosynthesis, COS Cells, Leigh Disease, Biogenesis

Abstract

The assembly of complex I (NADH-ubiquinone oxidoreductase) is a complicated process, requiring the integration of 45 subunits encoded by both nuclear and mitochondrial DNAs into a structure of approximately 1 MDa. A number of "assembly factors" that aid complex I biogenesis have recently been described, including C8orf38. This protein was identified as an assembly factor by its evolutionary conservation in organisms containing complex I and by a C8orf38 mutation in a patient presenting with Leigh syndrome and isolated complex I deficiency. In this report, we have undertaken the characterization of C8orf38 and its role in complex I assembly. Analysis of mitochondria from fibroblasts of a patient harboring a C8orf38 mutation showed almost undetectable levels of steady-state complex I and defective biogenesis of the mtDNA-encoded subunit ND1. Complementation with wild-type C8orf38 restored the levels of both ND1 and complex I, confirming the C8orf38 mutation as the cause of the complex I defect in the patient. In the absence of ND1 in patient cells, early- and mid-stage intermediate complexes were still formed; however, assembly of late-stage intermediates was impaired, indicating a convergence point in the assembly process. While C8orf38 appears to behave at a step in complex I biogenesis similar to that of the assembly factor C20orf7, complementation studies showed that both proteins are required for ND1 synthesis/stabilization. We conclude that C8orf38 is a crucial factor required for the translation and/or integration of ND1 into an early-stage assembly intermediate and that mutation of C8orf38 disrupts the initial stages of complex I biogenesis.

Published

2011

18. Mitochondrial Respiratory Chain Supercomplexes Are Destabilized in Barth Syndrome Patients

Author

Matthew McKenzie, David R. Thorburn, Michael T. Ryan, and Michael Lazarou

Subjects

Cardiomyopathy, Dilated, Neutropenia, Cardiolipins, Respiratory chain, Tafazzin, Mitochondrion, Biology, Electron Transport Complex IV, Electron Transport Complex III, chemistry.chemical_compound, Structural Biology, medicine, Cardiolipin, Humans, Lymphocytes, Molecular Biology, Cells, Cultured, Electron Transport Complex I, Muscle Weakness, Monolysocardiolipin, Infant, Proteins, Genetic Diseases, X-Linked, Barth syndrome, Syndrome, medicine.disease, Mitochondria, Cell biology, Mitochondrial respiratory chain, Biochemistry, chemistry, Mitochondrial Membranes, Mutation, Respirasome, biology.protein, Electrophoresis, Polyacrylamide Gel, Acyltransferases, Transcription Factors

Abstract

Mutations in the human TAZ gene are associated with Barth Syndrome, an often fatal X-linked disorder that presents with cardiomyopathy and neutropenia. The TAZ gene encodes Tafazzin, a putative phospholipid acyltranferase that is involved in the remodeling of cardiolipin, a phospholipid unique to the inner mitochondrial membrane. It has been shown that the disruption of the Tafazzin gene in yeast (Taz1) affects the assembly and stability of respiratory chain Complex IV and its supercomplex forms. However, the implications of these results for Barth Syndrome are restricted due to the additional presence of Complex I in humans that forms a supercomplex with Complexes III and IV. Here, we investigated the effects of Tafazzin, and hence cardiolipin deficiency in lymphoblasts from patients with Barth Syndrome, using blue-native polyacrylamide gel electrophoresis. Digitonin extraction revealed a more labile Complex I/III(2)/IV supercomplex in mitochondria from Barth Syndrome cells, with Complex IV dissociating more readily from the supercomplex. The interaction between Complexes I and III was also less stable, with decreased levels of the Complex I/III(2) supercomplex. Reduction of Complex I holoenzyme levels was observed also in the Barth Syndrome patients, with a corresponding decrease in steady-state subunit levels. We propose that the loss of mature cardiolipin species in Barth Syndrome results in unstable respiratory chain supercomplexes, thereby affecting Complex I biogenesis, respiratory activities and subsequent pathology.

Published

2006

19. Tissue-specific splicing of an Ndufs6 gene-trap insertion generates a mitochondrial complex I deficiency-specific cardiomyopathy

Author

Jane Koleff, Adrienne Laskowski, James Pitt, Salvatore Pepe, Michael Lazarou, David R. Thorburn, Michael T. Ryan, Belinda M. Hardman, David R. Grubb, Felicity A. Rodda, Joseph J. Smolich, Michael Cheung, Bi Xia Ke, and Jasper C. Komen

Subjects

Male, medicine.medical_specialty, Mice, 129 Strain, Mitochondrial Diseases, Mitochondrial disease, RNA Splicing, Blotting, Western, Cardiomyopathy, Kaplan-Meier Estimate, Mitochondrion, Biology, In Vitro Techniques, Cell Line, Mice, Adenosine Triphosphate, Fibrosis, Internal medicine, Carnitine, medicine, Animals, Humans, Mice, Knockout, Gene knockdown, NDUFS6, Multidisciplinary, Electron Transport Complex I, Reverse Transcriptase Polymerase Chain Reaction, Gene Expression Profiling, Myocardium, Heart, NADH Dehydrogenase, Biological Sciences, medicine.disease, Molecular biology, Mitochondria, Mice, Inbred C57BL, Microscopy, Electron, Mutagenesis, Insertional, Endocrinology, Animals, Newborn, Heart failure, Female, Cardiomyopathies, medicine.drug

Abstract

Mitochondrial complex I (CI) deficiency is the most common mitochondrial enzyme defect in humans. Treatment of mitochondrial disorders is currently inadequate, emphasizing the need for experimental models. In humans, mutations in the NDUFS6 gene, encoding a CI subunit, cause severe CI deficiency and neonatal death. In this study, we generated a CI-deficient mouse model by knockdown of the Ndufs6 gene using a gene-trap embryonic stem cell line. Ndufs6 gt/gt mice have essentially complete knockout of the Ndufs6 subunit in heart, resulting in marked CI deficiency. Small amounts of wild-type Ndufs6 mRNA are present in other tissues, apparently due to tissue-specific mRNA splicing, resulting in milder CI defects. Ndufs6 gt/gt mice are born healthy, attain normal weight and maturity, and are fertile. However, after 4 mo in males and 8 mo in females, Ndufs6 gt/gt mice are at increased risk of cardiac failure and death. Before overt heart failure, Ndufs6 gt/gt hearts show decreased ATP synthesis, accumulation of hydroxyacylcarnitine, but not reactive oxygen species (ROS). Ndufs6 gt/gt mice develop biventricular enlargement by 1 mo, most pronounced in males, with scattered fibrosis and abnormal mitochondrial but normal myofibrillar ultrastructure. Ndufs6 gt/gt isolated working heart preparations show markedly reduced left ventricular systolic function, cardiac output, and functional work capacity. This reduced energetic and functional capacity is consistent with a known susceptibility of individuals with mitochondrial cardiomyopathy to metabolic crises precipitated by stresses. This model of CI deficiency will facilitate studies of pathogenesis, modifier genes, and testing of therapeutic approaches.

Published

2012

20. Assembly of nuclear DNA-encoded subunits into mitochondrial complex IV, and their preferential integration into supercomplex forms in patient mitochondria

Author

Michael, Lazarou, Stacey M, Smith, David R, Thorburn, Michael T, Ryan, and Matthew, McKenzie

Subjects

Electron Transport Complex IV, Mitochondrial Proteins, Mitochondrial Diseases, Yeasts, Mitochondrial Membranes, Humans, Electrophoresis, Polyacrylamide Gel, Phosphorylation, Cells, Cultured, Protein Structure, Secondary, Mitochondria

Abstract

Complex IV is the terminal enzyme of the mitochondrial respiratory chain. In humans, biogenesis of complex IV involves the coordinated assembly of 13 subunits encoded by both mitochondrial and nuclear genomes. The early stages of complex IV assembly involving mitochondrial DNA-encoded subunits CO1 and CO2 have been well studied. However, the latter stages, during which many of the nuclear DNA-encoded subunits are incorporated, are less well understood. Using in vitro import and assembly assays, we found that subunits Cox6a, Cox6b and Cox7a assembled into pre-existing complex IV, while Cox4-1 and Cox6c subunits assembled into subcomplexes that may represent rate-limiting intermediates. We also found that Cox6a and Cox7a are incorporated into a novel intermediate complex of approximately 250 kDa, and that transition of subunits from this complex to the mature holoenzyme had stalled in the mitochondria of patients with isolated complex IV deficiency. A number of complex IV subunits were also found to integrate into supercomplexes containing combinations of complex I, dimeric complex III and complex IV. Subunit assembly into these supercomplexes was also observed in mitochondria of patients in whom monomeric complex IV was selectively reduced. We conclude that newly imported nuclear DNA-encoded subunits can integrate into the complex IV holoenzyme and supercomplex forms by associating with pre-existing subunits and intermediate assembly complexes.

Published

2009

21. Chapter 18 Analysis of respiratory chain complex assembly with radiolabeled nuclear- and mitochondrial-encoded subunits

Author

Matthew, McKenzie, Michael, Lazarou, and Michael T, Ryan

Subjects

Cell Nucleus, Radioisotopes, Transcription, Genetic, Multienzyme Complexes, Protein Biosynthesis, Biological Transport, Electrophoresis, Polyacrylamide Gel, Mitochondria

Abstract

The mitochondrial respiratory chain is composed of individual complexes that range widely in terms of size and subunit composition. For example, whereas complex II is approximately 260 kDa and is composed of 4 subunits, complex I is almost 1 MDa and contains 45 different subunits. Furthermore, complexes I, III, IV, and V harbor additional complexity, because their subunits are encoded by both nuclear and mitochondrial DNA. Subunits that are encoded by nuclear genes must be imported into mitochondria before undergoing processing, folding, and assembly with other subunits that are synthesized within the organelle. This process requires the coordinated action of assembly factors with the integration of subunits into intermediate assembly complexes. Recent studies have used various techniques to analyze subunit assembly to gain information into the biogenesis of these respiratory chain complexes and to understand how defects in assembly lead to disease. Here we describe methods to monitor the assembly of newly synthesized subunits encoded by mitochondrial DNA from cultured mammalian cells, as well as the import and assembly of individual subunits encoded by nuclear DNA.

Published

2009

22. Analysis of the assembly profiles for mitochondrial- and nuclear-DNA-encoded subunits into complex I

Author

David R. Thorburn, Matthew McKenzie, Michael Lazarou, Akira Ohtake, and Michael T. Ryan

Subjects

DNA, Complementary, Transcription, Genetic, Protein subunit, Respiratory chain, Cell Culture Techniques, Mitochondrion, Sulfur Radioisotopes, DNA, Mitochondrial, Models, Biological, Peptide Mapping, Methionine, Humans, Inner mitochondrial membrane, Molecular Biology, Cells, Cultured, Skin, Cell Nucleus, Electron Transport Complex I, biology, NDUFS4, NADH Dehydrogenase, Cell Biology, Articles, Fibroblasts, Mitochondria, Protein Subunits, Biochemistry, Chaperone (protein), Protein Biosynthesis, biology.protein, Biogenesis

Abstract

Complex I of the respiratory chain is composed of at least 45 subunits that assemble together at the mitochondrial inner membrane. Defects in human complex I result in energy generation disorders and are also implicated in Parkinson's disease and altered apoptotic signaling. The assembly of this complex is poorly understood and is complicated by its large size and its regulation by two genomes, with seven subunits encoded by mitochondrial DNA (mtDNA) and the remainder encoded by nuclear genes. Here we analyzed the assembly of a number of mtDNA- and nuclear-gene-encoded subunits into complex I. We found that mtDNA-encoded subunits first assemble into intermediate complexes and require significant chase times for their integration into the holoenzyme. In contrast, a set of newly imported nuclear-gene-encoded subunits integrate with preexisting complex I subunits to form intermediates and/or the fully assembly holoenzyme. One of the intermediate complexes represents a subassembly associated with the chaperone B17.2L. By using isolated patient mitochondria, we show that this subassembly is a productive intermediate in complex I assembly since import of the missing subunit restores complex I assembly. Our studies point to a mechanism of complex I biogenesis involving two complementary processes, (i) synthesis of mtDNA-encoded subunits to seed de novo assembly and (ii) exchange of preexisting subunits with newly imported ones to maintain complex I homeostasis. Subunit exchange may also act as an efficient mechanism to prevent the accumulation of oxidatively damaged subunits that would otherwise be detrimental to mitochondrial oxidative phosphorylation and have the potential to cause disease.

Published

2007

23. Analysis of mitochondrial subunit assembly into respiratory chain complexes using Blue Native polyacrylamide gel electrophoresis

Author

Michael T. Ryan, Matthew McKenzie, David R. Thorburn, and Michael Lazarou

Subjects

Mitochondrial disease, Protein subunit, Biophysics, Respiratory chain, Biology, Biochemistry, DNA, Mitochondrial, Electron Transport, Electron Transport Complex IV, Electron Transport Complex III, medicine, Rosaniline Dyes, Humans, Electrophoresis, Gel, Two-Dimensional, Molecular Biology, Cells, Cultured, Electron Transport Complex I, Staining and Labeling, Native Polyacrylamide Gel Electrophoresis, Cell Biology, medicine.disease, Mitochondrial carrier, Mitochondria, Mitochondrial respiratory chain, Coenzyme Q – cytochrome c reductase, Electrophoresis, Polyacrylamide Gel, Indicators and Reagents

Abstract

The mitochondrial respiratory chain consists of multi-subunit protein complexes embedded in the inner membrane. Although the majority of subunits are encoded by nuclear genes and are imported into mitochondria, 13 subunits in humans are encoded by mitochondrial DNA. The coordinated assembly of subunits encoded from two genomes is a poorly understood process, with assembly pathway defects being a major determinant in mitochondrial disease. In this study, we monitored the assembly of human respiratory complexes using radiolabeled, mitochondrially encoded subunits in conjunction with Blue Native polyacrylamide gel electrophoresis. The efficiency of assembly was found to differ markedly between complexes, and intermediate complexes containing newly synthesized mitochondrial DNA-encoded subunits could be observed for complexes I, III, and IV. In particular, we detected human cytochrome b as a monomer and as a component of a novel approximately 120 kDa intermediate complex at early chase times before being totally assembled into mature complex III. Furthermore, we show that this approach is highly suited for the rapid detection of respiratory complex assembly defects in fibroblasts from patients with mitochondrial disease and, thus, has potential diagnostic applications.

Published

2006

24. Assembly of mitochondrial complex I and defects in disease

Author

Michael Lazarou, David R. Thorburn, Matthew McKenzie, and Michael T. Ryan

Subjects

Mitochondrial Diseases, Mitochondrial disease, Respiratory chain, Mitochondrion, Gene mutation, Models, Biological, Mitochondrial Proteins, Complex I, medicine, Cytochrome c oxidase, Animals, Humans, Oxidative phosphorylation, Molecular Biology, Genetics, Cell Nucleus, Electron Transport Complex I, biology, Apoptosis Inducing Factor, Cell Biology, DNA, medicine.disease, Cell biology, Mitochondria, Protein Subunits, Membrane protein, biology.protein, Apoptosis-inducing factor, Biogenesis

Abstract

Isolated complex I deficiency is the most common cause of respiratory chain dysfunction. Defects in human complex I result in energy generation disorders and they are also implicated in neurodegenerative disease and altered apoptotic signaling. Complex I dysfunction often occurs as a result of its impaired assembly. The assembly process of complex I is poorly understood, complicated by the fact that in mammals, it is composed of 45 different subunits and is regulated by both nuclear and mitochondrial genomes. However, in recent years we have gained new insights into complex I biogenesis and a number of assembly factors involved in this process have also been identified. In most cases, these factors have been discovered through their gene mutations that lead to specific complex I defects and result in mitochondrial disease. Here we review how complex I is assembled and the factors required to mediate this process.