Emily Machiela scite author profile

Reactive oxygen species (ROS) are highly reactive, oxygen-containing molecules that can cause molecular damage within the cell. While the accumulation of ROS-mediated damage is widely believed to be one of the main causes of aging, ROS also act in signaling pathways. Recent work has demonstrated that increasing levels of superoxide, one form of ROS, through treatment with paraquat, results in increased lifespan. Interestingly, treatment with paraquat robustly increases the already long lifespan of the clk-1 mitochondrial mutant, but not other long-lived mitochondrial mutants such as isp-1 or nuo-6. To genetically dissect the subcellular compartment in which elevated ROS act to increase lifespan, we deleted individual superoxide dismutase (sod) genes in clk-1 mutants, which are sensitized to ROS. We find that only deletion of the primary mitochondrial sod gene, sod-2 results in increased lifespan in clk-1 worms. In contrast, deletion of either of the two cytoplasmic sod genes, sod-1 or sod-5, significantly decreases the lifespan of clk-1 worms. Further, we show that increasing mitochondrial superoxide levels through deletion of sod-2 or treatment with paraquat can still increase lifespan in clk-1;sod-1 double mutants, which live shorter than clk-1 worms. The fact that mitochondrial superoxide can increase lifespan in worms with a detrimental level of cytoplasmic superoxide demonstrates that ROS have a compartment specific effect on lifespan – elevated ROS in the mitochondria acts to increase lifespan, while elevated ROS in the cytoplasm decreases lifespan. This work also suggests that both ROS-dependent and ROS-independent mechanisms contribute to the longevity of clk-1 worms.

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Mitochondrial unfolded protein response transcription factor ATFS-1 promotes longevity in a long-lived mitochondrial mutant through activation of stress response pathways

Senchuk

Dues

et al. 2018

BMC Biol

123

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BackgroundThe mitochondrial unfolded protein response (mitoUPR) is a stress response pathway activated by disruption of proteostasis in the mitochondria. This pathway has been proposed to influence lifespan, with studies suggesting that mitoUPR activation has complex effects on longevity.ResultsHere, we examined the contribution of the mitoUPR to the survival and lifespan of three long-lived mitochondrial mutants in Caenorhabditis elegans by modulating the levels of ATFS-1, the central transcription factor that mediates the mitoUPR. We found that clk-1, isp-1, and nuo-6 worms all exhibit an ATFS-1-dependent activation of the mitoUPR. While loss of atfs-1 during adulthood does not affect lifespan in any of these strains, absence of atfs-1 during development prevents clk-1 and isp-1 worms from reaching adulthood and reduces the lifespan of nuo-6 mutants. Examining the mechanism by which deletion of atfs-1 reverts nuo-6 lifespan to wild-type, we find that many of the transcriptional changes present in nuo-6 worms are mediated by ATFS-1. Genes exhibiting an ATFS-1-dependent upregulation in nuo-6 worms are enriched for transcripts that function in stress response and metabolism. Consistent, with this finding, loss of atfs-1 abolishes the enhanced stress resistance observed in nuo-6 mutants and prevents upregulation of multiple stress response pathways including the HIF-1-mediated hypoxia response, SKN-1-mediated oxidative stress response and DAF-16-mediated stress response.ConclusionsOur results suggest that in the long-lived mitochondrial mutant nuo-6 activation of the mitoUPR causes atfs-1-dependent changes in the expression of genes involved in stress response and metabolism, which contributes to the extended longevity observed in this mutant. This work demonstrates that the mitoUPR can modulate multiple stress response pathways and suggests that it is crucial for the development and lifespan of long-lived mitochondrial mutants.Electronic supplementary materialThe online version of this article (10.1186/s12915-018-0615-3) contains supplementary material, which is available to authorized users.

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Mitochondrial pyruvate carrier regulates autophagy, inflammation, and neurodegeneration in experimental models of Parkinson’s disease

et al. 2016

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Mitochondrial and autophagic dysfunction as well as neuroinflammation are involved in the pathophysiology of Parkinson's disease (PD). We hypothesized that targeting the mitochondrial pyruvate carrier (MPC), a key controller of cellular metabolism that influences mTOR (mammalian target of rapamycin) activation, might attenuate neurodegeneration of nigral dopaminergic neurons in animal models of PD. To test this, we used MSDC-0160, a compound that specifically targets MPC, to reduce its activity. MSDC-0160 protected against 1-methyl-4-phenylpyridinium (MPP) insult in murine and cultured human midbrain dopamine neurons and in an α-synuclein-based Caenorhabditis elegans model. In 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-treated mice, MSDC-0160 improved locomotor behavior, increased survival of nigral dopaminergic neurons, boosted striatal dopamine levels, and reduced neuroinflammation. Long-term targeting of MPC preserved motor function, rescued the nigrostriatal pathway, and reduced neuroinflammation in the slowly progressive Engrailed1 (En1) genetic mouse model of PD. Targeting MPC in multiple models resulted in modulation of mitochondrial function and mTOR signaling, with normalization of autophagy and a reduction in glial cell activation. Our work demonstrates that changes in metabolic signaling resulting from targeting MPC were neuroprotective and anti-inflammatory in several PD models, suggesting that MPC may be a useful therapeutic target in PD.

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Delaying aging is neuroprotective in Parkinson’s disease: a genetic analysis in C. elegans models

Cooper

Dues

Spielbauer

et al. 2015

npj Parkinson's Disease

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Aging is the greatest risk factor for the development of Parkinson’s disease (PD). However, the role of aging in the pathogenesis of PD is not known and it is currently uncertain why the symptoms take many decades to develop when inherited mutations that cause the disease can be present from birth. We hypothesize that there are specific changes that take place during the aging process that make cells susceptible to disease-causing mutations that are well-tolerated at younger ages. If so, then interventions that increase lifespan should be beneficial in the treatment of PD. To test this hypothesis, we used the powerful genetics of C. elegans, as this worm has been used extensively in aging research. We crossed transgenic worm models of PD expressing either human mutant α-synuclein (A53T) or LRRK2 (G2019S) with the long-lived insulin-IGF1 receptor mutant, daf-2. The daf-2 mutation increased the lifespan of both PD mutants. The increase in lifespan resulting from the daf-2 mutation rescued the degeneration of dopamine neurons in both worm models of PD and importantly rescued deficits in dopamine-dependent behaviors including basal slowing, ethanol avoidance, and area-restricted searching. Increasing lifespan through daf-2 mutation also delayed the formation of small aggregates in a worm model of PD expressing α-synuclein in the body wall muscle and rescued deficits in resistance to different stresses that were present in the PD mutant worms. Overall, this work suggests that slowing down the aging process may provide an effective treatment for PD.

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Activation of the mitochondrial unfolded protein response promotes longevity and dopamine neuron survival in Parkinson’s disease models

Cooper

Machiela

Dues

et al. 2017

Sci Rep

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While the pathogenesis of Parkinson’s disease (PD) is incompletely understood, mitochondrial dysfunction is thought to play a crucial role in disease pathogenesis. Here, we examined the relationship between mitochondrial function and dopamine neuron dysfunction and death using C. elegans mutants for three mitochondria-related genes implicated in monogenic PD (pdr-1/PRKN, pink-1/PINK1 and djr-1.1/DJ-1). We found that pdr-1 and pink-1 mutants exhibit deficits in dopamine-dependent behaviors, but no loss of dopamine neurons, while djr-1.1 mutants showed an increased sensitivity to oxidative stress. In examining mitochondrial morphology and function, we found that djr-1.1 mutants exhibit increased mitochondrial fragmentation leading to decreased rate of oxidative phosphorylation and ATP levels. pdr-1 and pink-1 mutants show an accumulation of dysfunctional mitochondria with age, which leads to activation of the mitochondrial unfolded protein response (mitoUPR). Preventing the upregulation of the mitoUPR with a deletion in atfs-1 results in decreased lifespan and dopamine neuronal loss in pdr-1 and pink-1 mutants but not in wild-type worms. Overall, our results suggest that mutations in pdr-1 and pink-1 cause the accumulation of dysfunctional mitochondria, which activates the mitoUPR to mitigate the detrimental effect of these mutations on dopamine neuron survival.

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Oxidative stress is increased in C. elegans models of Huntington’s disease but does not contribute to polyglutamine toxicity phenotypes

Machiela

Dues

Senchuk

et al. 2016

Neurobiology of Disease

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Disruption of mitochondrial dynamics increases stress resistance through activation of multiple stress response pathways

et al. 2020

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Mitochondria are dynamic organelles that can change shape and size depending on the needs of the cell through the processes of mitochondrial fission and fusion. In this work, we investigated the role of mitochondrial dynamics in organismal stress response. By using C. elegans as a genetic model, we could visualize mitochondrial morphology in a live organism with well‐established stress assays and well‐characterized stress response pathways. We found that disrupting mitochondrial fission (DRP1/drp‐1) or fusion (OPA1/eat‐3, MFN/fzo‐1) genes caused alterations in mitochondrial morphology that impacted both mitochondrial function and physiologic rates. While both mitochondrial fission and mitochondrial fusion mutants showed increased sensitivity to osmotic stress and anoxia, surprisingly we found that the mitochondrial fusion mutants eat‐3 and fzo‐1 are more resistant to both heat stress and oxidative stress. In exploring the mechanism of increased stress resistance, we found that disruption of mitochondrial fusion genes resulted in the upregulation of multiple stress response pathways. Overall, this work demonstrates that disrupting mitochondrial dynamics can have opposite effects on resistance to different types of stress. Our results suggest that disruption of mitochondrial fusion activates multiple stress response pathways that enhance resistance to specific stresses.

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Biological Aging and the Cellular Pathogenesis of Huntington’s Disease

Machiela

Southwell

2020

JHD

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Huntington’s disease (HD) is a fatal, inherited neurodegenerative disorder caused by a mutation in the huntingtin gene ( HTT ). While mutant HTT is present ubiquitously throughout life, HD onset typically occurs in mid-life, suggesting that aging may play an active role in pathogenesis. Cellular aging is defined as the slow decline in stress resistance and accumulation of damage over time. While different cells and tissues can age at different rates, 9 hallmarks of aging have emerged to better define the cellular aging process. Strikingly, many of the hallmarks of aging are also hallmarks of HD pathology. Models of HD and HD patients possess markers of accelerated aging, and processes that decline during aging also decline at a more rapid rate in HD, further implicating the role of aging in HD pathogenesis. Furthermore, accelerating aging in HD mouse and patient-derived neurons unmasks HD-specific phenotypes, suggesting an active role for the aging process in the onset and progression of HD. Here, we review the overlap between the hallmarks of aging and HD and discuss how aging may contribute to pathogenesis in HD.

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Emily Machiela

Mitochondrial and Cytoplasmic ROS Have Opposing Effects on Lifespan

Mitochondrial unfolded protein response transcription factor ATFS-1 promotes longevity in a long-lived mitochondrial mutant through activation of stress response pathways

Mitochondrial pyruvate carrier regulates autophagy, inflammation, and neurodegeneration in experimental models of Parkinson’s disease

Delaying aging is neuroprotective in Parkinson’s disease: a genetic analysis in C. elegans models

Activation of the mitochondrial unfolded protein response promotes longevity and dopamine neuron survival in Parkinson’s disease models

Oxidative stress is increased in C. elegans models of Huntington’s disease but does not contribute to polyglutamine toxicity phenotypes

Disruption of mitochondrial dynamics increases stress resistance through activation of multiple stress response pathways

Biological Aging and the Cellular Pathogenesis of Huntington’s Disease

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