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1.
Neurobiol Dis ; 134: 104678, 2020 02.
Article in English | MEDLINE | ID: mdl-31740269

ABSTRACT

Wallerian degeneration of physically injured axons involves a well-defined molecular pathway linking loss of axonal survival factor NMNAT2 to activation of pro-degenerative protein SARM1. Manipulating the pathway through these proteins led to the identification of non-axotomy insults causing axon degeneration by a Wallerian-like mechanism, including several involving mitochondrial impairment. Mitochondrial dysfunction is heavily implicated in Parkinson's disease, Charcot-Marie-Tooth disease, hereditary spastic paraplegia and other axonal disorders. However, whether and how mitochondrial impairment activates Wallerian degeneration has remained unclear. Here, we show that disruption of mitochondrial membrane potential leads to axonal NMNAT2 depletion in mouse sympathetic neurons, increasing the substrate-to-product ratio (NMN/NAD) of this NAD-synthesising enzyme, a metabolic fingerprint of Wallerian degeneration. The mechanism appears to involve both impaired NMNAT2 synthesis and reduced axonal transport. Expression of WLDS and Sarm1 deletion both protect axons after mitochondrial uncoupling. Blocking the pathway also confers neuroprotection and increases the lifespan of flies with Pink1 loss-of-function mutation, which causes severe mitochondrial defects. These data indicate that mitochondrial impairment replicates all the major steps of Wallerian degeneration, placing it upstream of NMNAT2 loss, with the potential to contribute to axon pathology in mitochondrial disorders.


Subject(s)
Armadillo Domain Proteins/metabolism , Cytoskeletal Proteins/metabolism , Mitochondria/metabolism , Nicotinamide-Nucleotide Adenylyltransferase/metabolism , Wallerian Degeneration/metabolism , Wallerian Degeneration/pathology , Animals , Axons/metabolism , Axons/pathology , Drosophila , Male , Membrane Potential, Mitochondrial , Mice, Inbred C57BL
2.
Hum Mol Genet ; 25(12): 2378-2392, 2016 06 15.
Article in English | MEDLINE | ID: mdl-27056981

ABSTRACT

Amyotrophic lateral sclerosis (ALS) is characterized by the degeneration of motor neurons resulting in a catastrophic loss of motor function. Current therapies are severely limited owing to a poor mechanistic understanding of the pathobiology. Mutations in a large number of genes have now been linked to ALS, including SOD1, TARDBP (TDP-43), FUS and C9orf72. Functional analyses of these genes and their pathogenic mutations have provided great insights into the underlying disease mechanisms. Defective axonal transport is hypothesized to be a key factor in the selective vulnerability of motor nerves due to their extraordinary length and evidence that ALS occurs as a distal axonopathy. Axonal transport is seen as an early pathogenic event that precedes cell loss and clinical symptoms and so represents an upstream mechanism for therapeutic targeting. Studies have begun to describe the impact of a few pathogenic mutations on axonal transport but a broad survey across a range of models and cargos is warranted. Here, we assessed the axonal transport of different cargos in multiple Drosophila models of ALS. We found that axonal transport defects are common across all models tested, although they often showed a differential effect between mitochondria and vesicle cargos. Motor deficits were also common across the models and generally worsened with age, though surprisingly there was not a clear correlation between the severity of axonal transport defects and motor ability. These results further support defects in axonal transport as a common factor in models of ALS that may contribute to the pathogenic process.


Subject(s)
Amyotrophic Lateral Sclerosis/genetics , Axonal Transport/genetics , DNA-Binding Proteins/genetics , Proteins/genetics , RNA-Binding Protein FUS/genetics , Amyotrophic Lateral Sclerosis/metabolism , Amyotrophic Lateral Sclerosis/pathology , Animals , Animals, Genetically Modified , Axons/metabolism , Axons/pathology , C9orf72 Protein , DNA-Binding Proteins/biosynthesis , Disease Models, Animal , Drosophila/genetics , Humans , Larva/genetics , Mitochondria/metabolism , Mitochondria/pathology , Motor Neurons/metabolism , Motor Neurons/pathology , Mutation , RNA-Binding Protein FUS/biosynthesis , Superoxide Dismutase-1/genetics
3.
Biochim Biophys Acta ; 1840(4): 1246-53, 2014 Apr.
Article in English | MEDLINE | ID: mdl-23994494

ABSTRACT

BACKGROUND: Mitochondrial biogenesis is an essential process in all eukaryotes. Import of proteins from the cytosol into mitochondria is a key step in organelle biogenesis. Recent evidence suggests that a given mitochondrial protein does not take the same import route in all organisms, suggesting that pathways of mitochondrial protein import can be rewired through evolution. Examples of this process so far involve proteins destined to the mitochondrial intermembrane space (IMS). SCOPE OF REVIEW: Here we review the components, substrates and energy sources of the known mechanisms of protein import into the IMS. We discuss evolutionary rewiring of the IMS import routes, focusing on the example of the lactate utilisation enzyme cytochrome b2 (Cyb2) in the model yeast Saccharomyces cerevisiae and the human fungal pathogen Candida albicans. MAJOR CONCLUSIONS: There are multiple import pathways used for protein entry into the IMS and they form a network capable of importing a diverse range of substrates. These pathways have been rewired, possibly in response to environmental pressures, such as those found in the niches in the human body inhabited by C. albicans. GENERAL SIGNIFICANCE: We propose that evolutionary rewiring of mitochondrial import pathways can adjust the metabolic fitness of a given species to their environmental niche. This article is part of a Special Issue entitled Frontiers of Mitochondrial.


Subject(s)
Biological Evolution , Mitochondria/metabolism , Mitochondrial Membranes/metabolism , Mitochondrial Proteins/metabolism , Animals , Candida albicans/genetics , Candida albicans/metabolism , Humans , Mitochondria/genetics , Mitochondrial Proteins/genetics , Protein Transport/physiology , Saccharomyces cerevisiae/enzymology , Saccharomyces cerevisiae/genetics , Saccharomyces cerevisiae/metabolism , Saccharomyces cerevisiae Proteins/metabolism
4.
Proc Natl Acad Sci U S A ; 109(49): E3358-66, 2012 Dec 04.
Article in English | MEDLINE | ID: mdl-23151513

ABSTRACT

The controlled biogenesis of mitochondria is a key cellular system coordinated with the cell division cycle, and major efforts in systems biology currently are directed toward understanding of the control points at which this coordination is achieved. Here we present insights into the function, evolution, and regulation of mitochondrial biogenesis through the study of the protein import machinery in the human fungal pathogen, Candida albicans. Features that distinguish C. albicans from baker's yeast (Saccharomyces cerevisiae) include the stringency of metabolic control at the level of oxygen consumption, the potential for ATP exchange through the porin in the outer membrane, and components and domains in the sorting and assembling machinery complex, a molecular machine that drives the assembly of proteins in the outer mitochondrial membrane. Analysis of targeting sequences and assays of mitochondrial protein import show that components of the electron transport chain are imported by distinct pathways in C. albicans and S. cerevisiae, representing an evolutionary rewiring of mitochondrial import pathways. We suggest that studies using this pathogen as a model system for mitochondrial biogenesis will greatly enhance our knowledge of how mitochondria are made and controlled through the course of the cell-division cycle.


Subject(s)
Biological Evolution , Candida albicans/physiology , Carrier Proteins/metabolism , Electron Transport Chain Complex Proteins/metabolism , Mitochondria/physiology , Mitochondrial Proteins/metabolism , Models, Biological , Cluster Analysis , Computational Biology , Electrophoresis, Polyacrylamide Gel , Markov Chains , Mitochondrial Precursor Protein Import Complex Proteins , Oxygen Consumption/physiology , Phylogeny , Protein Transport/physiology , Saccharomyces cerevisiae , Species Specificity
5.
Nat Commun ; 15(1): 2142, 2024 Mar 08.
Article in English | MEDLINE | ID: mdl-38459070

ABSTRACT

Neuronal mitochondria play important roles beyond ATP generation, including Ca2+ uptake, and therefore have instructive roles in synaptic function and neuronal response properties. Mitochondrial morphology differs significantly between the axon and dendrites of a given neuronal subtype, but in CA1 pyramidal neurons (PNs) of the hippocampus, mitochondria within the dendritic arbor also display a remarkable degree of subcellular, layer-specific compartmentalization. In the dendrites of these neurons, mitochondria morphology ranges from highly fused and elongated in the apical tuft, to more fragmented in the apical oblique and basal dendritic compartments, and thus occupy a smaller fraction of dendritic volume than in the apical tuft. However, the molecular mechanisms underlying this striking degree of subcellular compartmentalization of mitochondria morphology are unknown, precluding the assessment of its impact on neuronal function. Here, we demonstrate that this compartment-specific morphology of dendritic mitochondria requires activity-dependent, Ca2+ and Camkk2-dependent activation of AMPK and its ability to phosphorylate two direct effectors: the pro-fission Drp1 receptor Mff and the recently identified anti-fusion, Opa1-inhibiting protein, Mtfr1l. Our study uncovers a signaling pathway underlying the subcellular compartmentalization of mitochondrial morphology in dendrites of neurons in vivo through spatially precise and activity-dependent regulation of mitochondria fission/fusion balance.


Subject(s)
Neurons , Pyramidal Cells , Neurons/metabolism , Pyramidal Cells/physiology , Hippocampus , Axons/metabolism , Mitochondria/metabolism , Dendrites/physiology
6.
Eukaryot Cell ; 11(4): 532-44, 2012 Apr.
Article in English | MEDLINE | ID: mdl-22286093

ABSTRACT

Recent studies indicate that mitochondrial functions impinge on cell wall integrity, drug tolerance, and virulence of human fungal pathogens. However, the mechanistic aspects of these processes are poorly understood. We focused on the mitochondrial outer membrane SAM (Sorting and Assembly Machinery) complex subunit Sam37 in Candida albicans. Inactivation of SAM37 in C. albicans leads to a large reduction in fitness, a phenotype not conserved with the model yeast Saccharomyces cerevisiae. Our data indicate that slow growth of the sam37ΔΔ mutant results from mitochondrial DNA loss, a new function for Sam37 in C. albicans, and from reduced activity of the essential SAM complex subunit Sam35. The sam37ΔΔ mutant was hypersensitive to drugs that target the cell wall and displayed altered cell wall structure, supporting a role for Sam37 in cell wall integrity in C. albicans. The sensitivity of the mutant to membrane-targeting antifungals was not significantly altered. The sam37ΔΔ mutant was avirulent in the mouse model, and bioinformatics showed that the fungal Sam37 proteins are distant from their animal counterparts and could thus represent potential drug targets. Our study provides the first direct evidence for a link between mitochondrial function and cell wall integrity in C. albicans and is further relevant for understanding mitochondrial function in fitness, antifungal drug tolerance, and virulence of this major pathogen. Beyond the relevance to fungal pathogenesis, this work also provides new insight into the mitochondrial and cellular roles of the SAM complex in fungi.


Subject(s)
Candida albicans/metabolism , Cell Wall/metabolism , Fungal Proteins/metabolism , Mitochondria/metabolism , Mitochondrial Membranes/metabolism , Mitochondrial Proteins/metabolism , Animals , Antifungal Agents/pharmacology , Candida albicans/drug effects , Candida albicans/growth & development , Candida albicans/pathogenicity , Candidemia/microbiology , Cell Wall/ultrastructure , Cells, Cultured , DNA, Mitochondrial/metabolism , Fluconazole/pharmacology , Fungal Proteins/genetics , Hyphae/metabolism , Kidney/microbiology , Kidney/pathology , Macrophages/microbiology , Membrane Potential, Mitochondrial , Mice , Microbial Sensitivity Tests , Mitochondrial Proteins/genetics , Nematoda/microbiology , Organelle Shape , Phenotype , Protein Structure, Tertiary , Protein Subunits/genetics , Protein Subunits/metabolism , Sequence Homology, Amino Acid , Virulence
7.
bioRxiv ; 2023 Mar 26.
Article in English | MEDLINE | ID: mdl-36993655

ABSTRACT

Neuronal mitochondria play important roles beyond ATP generation, including Ca2+ uptake, and therefore have instructive roles in synaptic function and neuronal response properties. Mitochondrial morphology differs significantly in the axon and dendrites of a given neuronal subtype, but in CA1 pyramidal neurons (PNs) of the hippocampus, mitochondria within the dendritic arbor also display a remarkable degree of subcellular, layer-specific compartmentalization. In the dendrites of these neurons, mitochondria morphology ranges from highly fused and elongated in the apical tuft, to more fragmented in the apical oblique and basal dendritic compartments, and thus occupy a smaller fraction of dendritic volume than in the apical tuft. However, the molecular mechanisms underlying this striking degree of subcellular compartmentalization of mitochondria morphology are unknown, precluding the assessment of its impact on neuronal function. Here, we demonstrate that this compartment-specific morphology of dendritic mitochondria requires activity-dependent, Camkk2-dependent activation of AMPK and its ability to phosphorylate two direct effectors: the pro-fission Drp1 receptor Mff and the recently identified anti-fusion, Opa1-inhibiting protein, Mtfr1l. Our study uncovers a new activity-dependent molecular mechanism underlying the extreme subcellular compartmentalization of mitochondrial morphology in dendrites of neurons in vivo through spatially precise regulation of mitochondria fission/fusion balance.

8.
Life Sci Alliance ; 5(11)2022 11.
Article in English | MEDLINE | ID: mdl-35831024

ABSTRACT

Mitochondria-ER contact sites (MERCs) orchestrate many important cellular functions including regulating mitochondrial quality control through mitophagy and mediating mitochondrial calcium uptake. Here, we identify and functionally characterize the Drosophila ortholog of the recently identified mammalian MERC protein, Pdzd8. We find that reducing pdzd8-mediated MERCs in neurons slows age-associated decline in locomotor activity and increases lifespan in Drosophila. The protective effects of pdzd8 knockdown in neurons correlate with an increase in mitophagy, suggesting that increased mitochondrial turnover may support healthy aging of neurons. In contrast, increasing MERCs by expressing a constitutive, synthetic ER-mitochondria tether disrupts mitochondrial transport and synapse formation, accelerates age-related decline in locomotion, and reduces lifespan. Although depletion of pdzd8 prolongs the survival of flies fed with mitochondrial toxins, it is also sufficient to rescue locomotor defects of a fly model of Alzheimer's disease expressing Amyloid ß42 (Aß42). Together, our results provide the first in vivo evidence that MERCs mediated by the tethering protein pdzd8 play a critical role in the regulation of mitochondrial quality control and neuronal homeostasis.


Subject(s)
Amyloid beta-Peptides , Drosophila Proteins , Drosophila melanogaster , Endoplasmic Reticulum , Mitochondria , Peptide Fragments , Alzheimer Disease , Amyloid beta-Peptides/antagonists & inhibitors , Amyloid beta-Peptides/toxicity , Animals , Cellular Senescence , Disease Models, Animal , Drosophila Proteins/deficiency , Drosophila Proteins/genetics , Drosophila Proteins/metabolism , Drosophila melanogaster/cytology , Drosophila melanogaster/drug effects , Drosophila melanogaster/metabolism , Drosophila melanogaster/physiology , Endoplasmic Reticulum/drug effects , Endoplasmic Reticulum/metabolism , Gene Knockdown Techniques , Genetic Fitness , Locomotion/drug effects , Longevity/drug effects , Mitochondria/drug effects , Mitochondria/metabolism , Mitochondrial Dynamics/drug effects , Mitophagy/drug effects , Neurons/drug effects , Peptide Fragments/antagonists & inhibitors , Peptide Fragments/toxicity
9.
Science ; 375(6586): eabm1670, 2022 03 18.
Article in English | MEDLINE | ID: mdl-35298275

ABSTRACT

Dendritic calcium signaling is central to neural plasticity mechanisms that allow animals to adapt to the environment. Intracellular calcium release (ICR) from the endoplasmic reticulum has long been thought to shape these mechanisms. However, ICR has not been investigated in mammalian neurons in vivo. We combined electroporation of single CA1 pyramidal neurons, simultaneous imaging of dendritic and somatic activity during spatial navigation, optogenetic place field induction, and acute genetic augmentation of ICR cytosolic impact to reveal that ICR supports the establishment of dendritic feature selectivity and shapes integrative properties determining output-level receptive fields. This role for ICR was more prominent in apical than in basal dendrites. Thus, ICR cooperates with circuit-level architecture in vivo to promote the emergence of behaviorally relevant plasticity in a compartment-specific manner.


Subject(s)
CA1 Region, Hippocampal/physiology , Calcium/metabolism , Dendrites/physiology , Endoplasmic Reticulum/metabolism , Neuronal Plasticity , Place Cells/physiology , Action Potentials , Adaptor Proteins, Signal Transducing/genetics , Animals , Calcium Signaling , Cytosol/metabolism , Electroporation , Female , Male , Mice , Optogenetics , Single-Cell Analysis , Spatial Navigation
10.
Cell Rep ; 27(5): 1541-1550.e5, 2019 04 30.
Article in English | MEDLINE | ID: mdl-31042479

ABSTRACT

Mitochondrial Ca2+ uptake is an important mediator of metabolism and cell death. Identification of components of the highly conserved mitochondrial Ca2+ uniporter has opened it up to genetic analysis in model organisms. Here, we report a comprehensive genetic characterization of all known uniporter components conserved in Drosophila. While loss of pore-forming MCU or EMRE abolishes fast mitochondrial Ca2+ uptake, this results in only mild phenotypes when young, despite shortened lifespans. In contrast, loss of the MICU1 gatekeeper is developmentally lethal, consistent with unregulated Ca2+ uptake. Mutants for the neuronally restricted regulator MICU3 are viable with mild neurological impairment. Genetic interaction analyses reveal that MICU1 and MICU3 are not functionally interchangeable. More surprisingly, loss of MCU or EMRE does not suppress MICU1 mutant lethality, suggesting that this results from uniporter-independent functions. Our data reveal the interplay among components of the mitochondrial Ca2+ uniporter and shed light on their physiological requirements in vivo.


Subject(s)
Calcium-Binding Proteins/metabolism , Cation Transport Proteins/metabolism , Drosophila Proteins/metabolism , Mitochondrial Membrane Transport Proteins/metabolism , Mutation , Animals , Calcium/metabolism , Calcium-Binding Proteins/genetics , Cation Transport Proteins/genetics , Drosophila Proteins/genetics , Drosophila melanogaster , Mitochondria/metabolism , Mitochondrial Membrane Transport Proteins/genetics , Phenotype
11.
mSphere ; 1(3)2016.
Article in English | MEDLINE | ID: mdl-27303738

ABSTRACT

The pathogenic yeast Candida albicans escapes macrophages by triggering NLRP3 inflammasome-dependent host cell death (pyroptosis). Pyroptosis is inflammatory and must be tightly regulated by host and microbe, but the mechanism is incompletely defined. We characterized the C. albicans endoplasmic reticulum (ER)-mitochondrion tether ERMES and show that the ERMES mmm1 mutant is severely crippled in killing macrophages despite hyphal formation and normal phagocytosis and survival. To understand dynamic inflammasome responses to Candida with high spatiotemporal resolution, we established live-cell imaging for parallel detection of inflammasome activation and pyroptosis at the single-cell level. This showed that the inflammasome response to mmm1 mutant hyphae is delayed by 10 h, after which an exacerbated activation occurs. The NLRP3 inhibitor MCC950 inhibited inflammasome activation and pyroptosis by C. albicans, including exacerbated inflammasome activation by the mmm1 mutant. At the cell biology level, inactivation of ERMES led to a rapid collapse of mitochondrial tubular morphology, slow growth and hyphal elongation at host temperature, and reduced exposed 1,3-ß-glucan in hyphal populations. Our data suggest that inflammasome activation by C. albicans requires a signal threshold dependent on hyphal elongation and cell wall remodeling, which could fine-tune the response relative to the level of danger posed by C. albicans. The phenotypes of the ERMES mutant and the lack of conservation in animals suggest that ERMES is a promising antifungal drug target. Our data further indicate that NLRP3 inhibition by MCC950 could modulate C. albicans-induced inflammation. IMPORTANCE The yeast Candida albicans causes human infections that have mortality rates approaching 50%. The key to developing improved therapeutics is to understand the host-pathogen interface. A critical interaction is that with macrophages: intracellular Candida triggers the NLRP3/caspase-1 inflammasome for escape through lytic host cell death, but this also activates antifungal responses. To better understand how the inflammasome response to Candida is fine-tuned, we established live-cell imaging of inflammasome activation at single-cell resolution, coupled with analysis of the fungal ERMES complex, a mitochondrial regulator that lacks human homologs. We show that ERMES mediates Candida escape via inflammasome-dependent processes, and our data suggest that inflammasome activation is controlled by the level of hyphal growth and exposure of cell wall components as a proxy for severity of danger. Our study provides the most detailed dynamic analysis of inflammasome responses to a fungal pathogen so far and establishes promising pathogen- and host-derived therapeutic strategies.

12.
Science ; 349(6255): 1544-8, 2015 Sep 25.
Article in English | MEDLINE | ID: mdl-26404837

ABSTRACT

Mitochondria fulfill central functions in cellular energetics, metabolism, and signaling. The outer membrane translocator complex (the TOM complex) imports most mitochondrial proteins, but its architecture is unknown. Using a cross-linking approach, we mapped the active translocator down to single amino acid residues, revealing different transport paths for preproteins through the Tom40 channel. An N-terminal segment of Tom40 passes from the cytosol through the channel to recruit chaperones from the intermembrane space that guide the transfer of hydrophobic preproteins. The translocator contains three Tom40 ß-barrel channels sandwiched between a central α-helical Tom22 receptor cluster and external regulatory Tom proteins. The preprotein-translocating trimeric complex exchanges with a dimeric isoform to assemble new TOM complexes. Dynamic coupling of α-helical receptors, ß-barrel channels, and chaperones generates a versatile machinery that transports about 1000 different proteins.


Subject(s)
Mitochondrial Membrane Transport Proteins/chemistry , Saccharomyces cerevisiae Proteins/chemistry , Amino Acid Sequence , Cytosol/metabolism , Mitochondrial Membrane Transport Proteins/metabolism , Molecular Chaperones , Molecular Sequence Data , Protein Multimerization , Protein Structure, Secondary , Protein Transport , Saccharomyces cerevisiae Proteins/metabolism
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