Project description:Cocaine is one of the most abused psychostimulants in the United States. In addition to its established roles in the regulation of dopaminergic circuitries, cocaine has a broader mechanism of action, including global alterations in brain metabolism and mitochondrial homeostasis. Our group recently identified a subpopulation of non-microvesicular, non-exosomal extracellular vesicles of mitochondrial origin, mitovesicles (mtVs), and provided a method to isolate mtVs from brain parenchyma. Given their origin, we hypothesized that mtVs could be affected by mitochondrial abnormalities induced by chronic cocaine exposure. Therefore, we analyzed mtVs from hemibrains of 3-month-old mice that received for two weeks intraperitoneal injections of cocaine or saline as control. MtVs from the brain extracellular space of cocaine-intoxicated mice were enlarged and more numerous when compared to controls. Moreover, cocaine stimulated higher intracellular mitochondrial fission and higher levels of upstream (but not downstream) mitophagy pathways, suggesting increased mitochondrial fragmentation and a block in mitophagy flux. Lastly, cocaine impaired brain mtV cargo loading as revealed by Mass Spec analysis, causing an alteration in mtV ATP production capacity. These data suggest that mtVs are a previously unidentified player in the biology of cocaine addiction and that target therapies to fine tune brain mtV functionality may be beneficial to mitigate chronic cocaine pathology.

Project description:Senescence phenotypes and mitochondrial dysfunction are implicated in aging and neurodegeneration, and in the premature aging disease, including A-T. Loss of mitochondrial function can drive age-related decline in the brain, but little is known about whether improving mitochondrial homeostasis alleviates senescence phenotypes. Here we demonstrate impaired mitochondrial function and increased senescence growth arrest with senescence-associated secretory phenotype (SASP) in A-T patient fibroblasts, and in ATM-deficient cells and mice. We find that boosting intracellular NAD+ levels with nicotinamide riboside (NR) reduces senescence, suppresses neuroinflammation, and improves motor function in Atm-/- mice. We further show that the senescence responses are mediated by stimulator of interferon genes (STING), which is activated by cytoplasmic mtDNA and that NR prevents senescence and neuroinflammation through stimulation of mitophagy. Our findings suggest a pivotal role for mitochondrial dysfunction induced senescence in A-T pathogenesis, and that enhancing mitophagy is a potential therapeutic intervention.

Project description:Senescence phenotypes and mitochondrial dysfunction are implicated in aging and neurodegeneration, and in the premature aging disease, including A-T. Loss of mitochondrial function can drive age-related decline in the brain, but little is known about whether improving mitochondrial homeostasis alleviates senescence phenotypes. Here we demonstrate impaired mitochondrial function and increased senescence growth arrest with senescence-associated secretory phenotype (SASP) in A-T patient fibroblasts, and in ATM-deficient cells and mice. We find that boosting intracellular NAD+ levels with nicotinamide riboside (NR) reduces senescence, suppresses neuroinflammation, and improves motor function in Atm-/- mice. We further show that the senescence responses are mediated by stimulator of interferon genes (STING), which is activated by cytoplasmic mtDNA and that NR prevents senescence and neuroinflammation through stimulation of mitophagy. Our findings suggest a pivotal role for mitochondrial dysfunction induced senescence in A-T pathogenesis, and that enhancing mitophagy is a potential therapeutic intervention.

Project description:Mitochondrial dynamics and mitophagy are intimately linked physiological processes that are essential for cardiac homeostasis. Here we show that cardiac Klf9 is dysregulated in human and rodent cardiomyopathy. Young adult global Klf9-knockout mice displayed hypertrophic cardiomyopathy that was characterized by depressed systolic function, increased left ventricular mass and pulmonary congestion. Klf9 knockout led to mitochondrial disarray and fragmentation in cardiomyocytes. Biochemical analysis confirmed that mitochondrial respiratory function was impaired in Klf9-knockout cardiomyocytes, with reduced myocardial ATP levels and elevated ROS. Furthermore, cardiac-specific Klf9-deficient mice phenocopied global Klf9-knockout mice, suggesting that cardiac Klf9 is essential for mitochondrial homeostasis and heart function. Moreover, cardiac Klf9 deficiency inhibited mitophagy induced by angiotensin II (ANGII), thereby leading to accumulation of dysfunctional mitochondria and acceleration of heart failure in mice in response to ANGII treatment. In contrast, cardiac-specific Klf9 transgene improved cardiac systolic function via promoting mitophagy in mice in response to ANGII treatment. Molecular mechanism studies indicated that Klf9 knockout decreased the expression of PGC-1α and its target genes involved in mitochondrial energy metabolism. Moreover, Klf9 controlled the expression of Mfn2 by directly binding to its promoter region, thereby regulating mitochondrial dynamics and mitophagy. Finally, we performed Mfn2 rescue experiments in Klf9-CKO mice and found that AAV-mediated Mfn2 rescue in heart improved cardiac mitochondrial and systolic function in Klf9-CKO mice treated with or without ANGII. Thus, Klf9 integrates cardiac energy metabolism, mitochondrial dynamics and mitophagy. Modulating Klf9 activity may have therapeutic potential in the treatment of heart failure.

Project description:Mitophagy is essential to maintain mitochondrial function and prevent diseases. It activates upon mitochondria depolarization, which causes PINK1 stabilization on the mitochondrial outer membrane. Strikingly, a number of conditions, including mitochondrial protein misfolding, can induce mitophagy without a loss in membrane potential. The underlying molecular details remain unclear. Here, we report that a loss of mitochondrial protein import, mediated by the pre-sequence translocase-associated motor complex PAM, is sufficient to induce mitophagy in polarized mitochondria. A genome-wide CRISPR/Cas9 screen for mitophagy inducers identifies components of the PAM complex. Protein import defects are able to induce mitophagy without a need for depolarization. Upon mitochondrial protein misfolding, PAM dissociates from the import machinery resulting in decreased protein import and mitophagy induction. Our findings extend the current mitophagy model to explain mitophagy induction upon conditions that do not affect membrane polarization, such as mitochondrial protein misfolding.

Project description:Hutchinson-Gilford progeria syndrome (HGPS) is a rare and fatal disease manifested by premature aging and aging-related phenotypes, making it a disease model for physiological aging. The cellular machinery mediating age-associated hallmarks in HGPS remains largely unknown, resulting in limited therapeutic targets for HGPS treatment. In this study, we showed that deficiencies in mitophagy impaired mitochondrial quality and contributed to cellular phenotypes associated with aging in mesenchymal stem cells derived from HGPS patients (HGPS-MSCs). Mechanistically, we discovered that mitophagy affected the aging-related phenotypes of HGPS-MSCs by inhibiting the cGAS-STING-NF-ĸB pathway and the downstream transcription of senescence-associated secretory phenotype (SASP). Furthermore, by utilizing UMI-77, an effective inducer of mitophagy, we showed that mitophagy induction can alleviate aging-associated phenotypes in both HGPS mice and naturally aged mice. In summary, our results uncover that mitophagy defects mediate mitochondrial dysfunction and aging-associated phenotypes in HGPS models, highlight the function of mitochondrial homeostasis in HGPS progression, and suggest that mitophagy could be exploited as a promising therapeutic target for both HGPS and aging.

Project description:Accumulation of damaged mitochondria is a hallmark of human aging and age-related neurodegenerative pathologies, including Alzheimer’s disease (AD). However, the molecular mechanisms of the impaired mitochondrial homeostasis and their relationship to AD are still elusive. Here we provide evidence that mitophagy, a cellular process mediating selective clearance of dysfunctional mitochondria, is impaired in AD patient hippocampus, in iPSC-derived human neurons and in animal AD models. In C. elegans models of AD, pharmacological stimulation of mitophagy reverses memory impairment through a PINK-1, PDR-1 and DCT-1 dependent pathway. Mitophagy induction diminishes the levels of insoluble amyloid-β (Aβ)1-42 and Aβ1-40 peptide isoforms and prevents cognitive impairment in AD mice by a mechanism involving microglial phagocytosis of extracellular Aβ plaques and suppression of neuroinflammation. Furthermore, mitophagy abolishes AD-related Tau hyperphosphorylation in human neuronal cells and reverses memory impairment in transgenic Tau nematodes. Our findings suggest that impaired removal of defective mitochondria is a pivotal event in AD pathogenesis. Interventions that stimulate mitophagy therefore have therapeutic potential in the prevention and treatment of AD.

Project description:Mitophagy is one of the most important cellular processes to ensure mitochondrial quality control, which aims to transport damaged, dysfunctional, or excess mitochondria for degradation and reuse. Here, we determined the function of AoAtg11 and AoAtg33, two orthologous autophagy-related proteins involved in yeast mitophagy, in the typical nematode-trapping fungus Arthrobotrys oligospora . Deletion of Aoatg11 and Aoatg33 impairs mitophagy, mitochondrial morphology and activity, autophagy,cell apoptosis, reactive oxygen species levels, lipid droplet accumulation, and endocytosis. These combined effects resulted in slow vegetative growth; reduced conidiation, trap formation, cell nucleus, and extracellular protease activity; increased susceptibility to the stress response; and arthrobotrisin production in the Δ Aoatg11 and Δ Aoatg33 mutants, compared with the wild-type strain. In addition, the absence of Aoatg11 caused an endoplasmic reticulum stress response. Transcriptome analysis revealed that many differentially expressed genes in the Δ Aoatg11 mutants were involved in various important cellular processes, such as lipid metabolism, the TCA cycle, mitophagy, nitrogen metabolism, endocytosis, and the MAPK signaling pathway. In conclusion, our study revealed that Aoatg11 and Aoatg33 mediate autophagy and mitophagy in A. oligospora , and provides a basis for elucidating the links between mitophagy and fungal vegetative growth, conidiation, and pathogenicity.

Project description:Autoantibodies against nucleic acids and excessive type I Interferon (IFN) are hallmarks of human Systemic Lupus Erythematosus (SLE). We previously reported that SLE neutrophils, exposed to TLR7-agonist autoantibodies, release interferogenic DNA, which we now demonstrate to be of mitochondrial origin. We further show that healthy human neutrophils do not complete mitophagy upon induction of mitochondrial damage. Rather, they extrude mitochondrial components, including DNA (mtDNA), devoid of oxidized residues. When MtDNA undergoes oxidation, it is directly routed to lysosomes for degradation. This rerouting requires dissociation from the transcription factor TFAM, a dual high mobility group (HMG) protein involved in maintenance and compaction of the mitochondrial genome into nucleoids. Exposure of SLE neutrophils, or healthy IFNprimed neutrophils, to anti-RNP autoantibodies blocks TFAM phosphorylation, a necessary step for nucleoid dissociation. Consequently, oxidized nucleoids accumulate within mitochondria and are eventually extruded as potent interferogenic complexes. In support of the in vivo relevance of this phenomenon, mitochondrial retention of oxidized nucleoids is a feature of SLE blood neutrophils, and autoantibodies against oxidized mtDNA are present in a fraction of patients. This pathway represents a novel therapeutic target in human SLE. 4 samples, no replicates, 2 controls. 2 samples are Neutrophils cultured with and without CCCP (control). 2 samples are Monocytes cultured with and without CCCP (control).

Project description:Mitochondria are vital for cellular energy supply and intracellular signaling after stress. Here, we aimed to investigate how mitochondria respond to acute DNA damage with respect to mitophagy, which is an important mitochondrial quality control process. Our results show that mitophagy increases after DNA damage in primary fibroblasts, murine neurons, and C. elegans neurons. Our results indicate that modulation of mitophagy after DNA damage is independent of the type of DNA damage stimuli used and that the protein Spata18 is an important player in this process. Knockdown of Spata18 suppresses mitophagy, disturbs mitochondrial Ca2+ homeostasis, affects ATP production, and attenuates DNA repair. Importantly, mitophagy after DNA damage is a vital cellular response to maintain mitochondrial functions and DNA repair.