The C. elegans Opa1 Homologue EAT-3 is Essential for Resistance to Free Radicals

Kanazawa, Takayuki; Zappaterra, Mauro; Hasegawa, Ayako; Wright, Ashley P.; Newman-Smith, Erin; Buttle, Karolyn; McDonald, Kent L.; Mannella, Carmen A.; Bliek, Alex van der

doi:10.1371/journal.pgen.0040039.eor

Cited by 31 publications

(60 citation statements)

References 38 publications

(52 reference statements)

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“…Moreover, we reported that the loss of outer mitochondrial membrane (OMM) fusion results in lactic acidosis, whereas the loss of inner mitochondrial membrane (IMM) fusion occurs independently of lactic acidosis but can be suppressed by treatment with the antioxidant compound N-acetylcysteine (NAC). This is consistent with a heightened sensitivity to the oxidant paraquat (28) and demonstrable oxidation of the mitochondrial matrix in these worms (26), leading to the hypothesis that oxidative signaling may underlie acidification following loss of IMM fusion.…”

supporting

confidence: 70%

“…In the nematode Caenorhabditis elegans, mitochondrial fusion is controlled by the inner mitochondrial membrane GTPase EAT-3 (OPA1) and the outer mitochondrial membrane GTPase FZO-1 (MFN1/2) (28). We have previously demonstrated that chronic fragmentation of the mitochondrial network causes intracellular acidification in both C. elegans and mammalian cells (26).…”

mentioning

confidence: 99%

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Regulation of acid-base transporters by reactive oxygen species following mitochondrial fragmentation

Johnson¹,

Allman²,

Nehrke

2012

American Journal of Physiology-Cell Physiology

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Mitochondrial morphology is determined by the balance between the opposing processes of fission and fusion, each of which is regulated by a distinct set of proteins. Abnormalities in mitochondrial dynamics have been associated with a variety of diseases, including neurodegenerative conditions such as Alzheimer's disease, Parkinson's disease, and dominant optic atrophy. Although the genetic determinants of fission and fusion are well recognized, less is known about the mechanism(s) whereby altered morphology contributes to the underlying pathophysiology of these disease states. Previous work from our laboratory identified a role for mitochondrial dynamics in intracellular pH homeostasis in both mammalian cell culture and in the genetic model organism Caenorhabditis elegans. Here we show that the acidification seen in mutant animals that have lost the ability to fuse their mitochondrial inner membrane occurs through a reactive oxygen species (ROS)-dependent mechanism and can be suppressed through the use of pharmacological antioxidants targeted specifically at the mitochondrial matrix. Physiological approaches examining the activity of endogenous mammalian acid-base transport proteins in rat liver Clone 9 cells support the idea that ROS signaling to sodium-proton exchangers contributes to acidification. Because maintaining pH homeostasis is essential for cell function and viability, the results of this work provide new insight into the pathophysiology associated with the loss of inner mitochondrial membrane fusion.

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supporting

confidence: 70%

mentioning

confidence: 99%

Regulation of acid-base transporters by reactive oxygen species following mitochondrial fragmentation

Johnson¹,

Allman²,

Nehrke

2012

American Journal of Physiology-Cell Physiology

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“…Cite this article as Cold Spring Harb Perspect Biol 2013;5:a011072 fusion defect, because complete loss of the C. elegans Opa1 homolog is not suppressed by fission defects (Kanazawa et al 2008). Similar dual functions were proposed for mammalian Opa1 and yeast Mgm1 Meeusen et al 2006).…”

Section: Mitochondrial Fission and Fusionmentioning

confidence: 71%

“…This was noted for yeast Fzo1 and Mgm1, where Mgm1 appears to have additional functions in helping to preserve mtDNA and cristae morphology (Guan et al 1993;Meeusen et al 2006). Differences in viability and tissue-specific effects have also been noted with mutations in the analogous C. elegans and Drosophila proteins (Kanazawa et al 2008;Yarosh et al 2008). Whereas homozygous mutations in mice are lethal, there are differences in the most severely affected stages and in heterozygous animals (Chen et al 2003;White et al 2009).…”

Section: Additional Roles Of Fusion Proteinsmentioning

confidence: 86%

“…These organisms do not release cytochrome c release as part of their apoptotic program. Instead, the C. elegans and Drosophila mutants become very sensitive to reactive oxygen species (ROS) producing agents such as Paraquat (Kanazawa et al 2008;Yarosh et al 2008). This effect is distinct from the (C) Oma1 cleaves the S1 site in isoforms that were not already cleaved by Yme1L, but only when mitochondria lose membrane potential.…”

Section: Additional Roles Of Fusion Proteinsmentioning

confidence: 99%

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Mechanisms of Mitochondrial Fission and Fusion

Bliek

Shen

Kawajiri

2013

Cold Spring Harbor Perspectives in Biology

640

483

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Mitochondria continually change shape through the combined actions of fission, fusion, and movement along cytoskeletal tracks. The lengths of mitochondria and the degree to which they form closed networks are determined by the balance between fission and fusion rates. These rates are influenced by metabolic and pathogenic conditions inside mitochondria and by their cellular environment. Fission and fusion are important for growth, for mitochondrial redistribution, and for maintenance of a healthy mitochondrial network. In addition, mitochondrial fission and fusion play prominent roles in disease-related processes such as apoptosis and mitophagy. Three members of the Dynamin family are key components of the fission and fusion machineries. Their functions are controlled by different sets of adaptor proteins on the surface of mitochondria and by a range of regulatory processes. Here, we review what is known about these proteins and the processes that regulate their actions.

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Loss of functional OPA 1 unbalances redox state: implications in dominant optic atrophy pathogenesis

Millet

Bertholet

Daloyau

et al. 2016

Ann Clin Transl Neurol

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Objective OPA1 mutations cause protein haploinsufficiency leading to dominant optic atrophy (DOA), an incurable retinopathy with variable severity. Up to 20% of patients also develop extraocular neurological complications. The mechanisms that cause this optic atrophy or its syndromic forms are still unknown. After identifying oxidative stress in a mouse model of the pathology, we sought to determine the consequences of OPA1 dysfunction on redox homeostasis.MethodsMitochondrial respiration, reactive oxygen species levels, antioxidant defenses, and cell death were characterized by biochemical and in situ approaches in both in vitro and in vivo models of OPA1 haploinsufficiency.ResultsA decrease in aconitase activity suggesting an increase in reactive oxygene species and an induction of antioxidant defenses was observed in cortices of a murine model as well as in OPA1 downregulated cortical neurons. This increase is associated with a decline in mitochondrial respiration in vitro. Upon exogenous oxidative stress, OPA1‐depleted neurons did not further exhibit upregulated antioxidant defenses but were more sensitive to cell death. Finally, low levels of antioxidant enzymes were found in fibroblasts from patients supporting their role as modifier factors.InterpretationOur study suggests that the pro‐oxidative state induced by OPA1 loss may contribute to DOA pathogenesis and that differences in antioxidant defenses can explain the variability in expressivity. Furthermore, antioxidants may be used as therapy as they could prevent or delay DOA symptoms in patients.

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The C. elegans Opa1 Homologue EAT-3 is Essential for Resistance to Free Radicals

Cited by 31 publications

References 38 publications

Regulation of acid-base transporters by reactive oxygen species following mitochondrial fragmentation

Regulation of acid-base transporters by reactive oxygen species following mitochondrial fragmentation

Mechanisms of Mitochondrial Fission and Fusion

Loss of functional OPA 1 unbalances redox state: implications in dominant optic atrophy pathogenesis

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