Literature DB >> 19298790

Mitochondrial calcium function and dysfunction in the central nervous system.

David G Nicholls1.   

Abstract

The ability of isolated brain mitochondria to accumulate, store and release calcium has been extensively characterized. Extrapolation to the intact neuron led to predictions that the in situ mitochondria would reversibly accumulate Ca(2+) when the concentration of the cation in the vicinity of the mitochondria rose above the 'set-point' at which uptake and efflux were in balance, storing Ca(2+) as a complex with phosphate, and slowly releasing the cation when plasma membrane ion pumps lowered the cytoplasmic free Ca(2+). Excessive accumulation of the cation was predicted to lead to activation of the permeability transition, with catastrophic consequences for the neuron. Each of these predictions has been confirmed with intact neurons, and there is convincing evidence for the permeability transition in cellular Ca(2+) overload associated with glutamate excitotoxicity and stroke, while the neurodegenerative disease in which possible defects in mitochondrial Ca(2+) handling have been most intensively investigated is Huntington's Disease. In this brief review evidence that mitochondrial Ca(2+) transport is relevant to neuronal survival in these conditions will be discussed.

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Year:  2009        PMID: 19298790      PMCID: PMC2752662          DOI: 10.1016/j.bbabio.2009.03.010

Source DB:  PubMed          Journal:  Biochim Biophys Acta        ISSN: 0006-3002


  112 in total

1.  Mitochondria, calcium regulation, and acute glutamate excitotoxicity in cultured cerebellar granule cells.

Authors:  S L Budd; D G Nicholls
Journal:  J Neurochem       Date:  1996-12       Impact factor: 5.372

2.  Mitochondrial iron detoxification is a primary function of frataxin that limits oxidative damage and preserves cell longevity.

Authors:  Oleksandr Gakh; Sungjo Park; Gang Liu; Lee Macomber; James A Imlay; Gloria C Ferreira; Grazia Isaya
Journal:  Hum Mol Genet       Date:  2005-12-21       Impact factor: 6.150

Review 3.  Mechanisms of impaired mitochondrial energy metabolism in acute and chronic neurodegenerative disorders.

Authors:  Lucian Soane; Sibel Kahraman; Tibor Kristian; Gary Fiskum
Journal:  J Neurosci Res       Date:  2007-11-15       Impact factor: 4.164

4.  Calcium buffering and protection from excitotoxic cell death by exogenous calbindin-D28k in HEK 293 cells.

Authors:  G L Rintoul; L A Raymond; K G Baimbridge
Journal:  Cell Calcium       Date:  2001-04       Impact factor: 6.817

5.  Heterogeneity of the calcium-induced permeability transition in isolated non-synaptic brain mitochondria.

Authors:  Tibor Kristián; Tina M Weatherby; Timothy E Bates; Gary Fiskum
Journal:  J Neurochem       Date:  2002-12       Impact factor: 5.372

6.  Mitochondria buffer physiological calcium loads in cultured rat dorsal root ganglion neurons.

Authors:  J L Werth; S A Thayer
Journal:  J Neurosci       Date:  1994-01       Impact factor: 6.167

7.  Transgenic mice expressing a Huntington's disease mutation are resistant to quinolinic acid-induced striatal excitotoxicity.

Authors:  O Hansson; A Petersén; M Leist; P Nicotera; R F Castilho; P Brundin
Journal:  Proc Natl Acad Sci U S A       Date:  1999-07-20       Impact factor: 11.205

8.  Glutamate decreases mitochondrial size and movement in primary forebrain neurons.

Authors:  Gordon L Rintoul; Anthony J Filiano; Jacques B Brocard; Geraldine J Kress; Ian J Reynolds
Journal:  J Neurosci       Date:  2003-08-27       Impact factor: 6.167

9.  Huntingtin phosphorylation acts as a molecular switch for anterograde/retrograde transport in neurons.

Authors:  Emilie Colin; Diana Zala; Géraldine Liot; Hélène Rangone; Maria Borrell-Pagès; Xiao-Jiang Li; Frédéric Saudou; Sandrine Humbert
Journal:  EMBO J       Date:  2008-07-10       Impact factor: 11.598

10.  Early mitochondrial calcium defects in Huntington's disease are a direct effect of polyglutamines.

Authors:  Alexander V Panov; Claire-Anne Gutekunst; Blair R Leavitt; Michael R Hayden; James R Burke; Warren J Strittmatter; J Timothy Greenamyre
Journal:  Nat Neurosci       Date:  2002-08       Impact factor: 24.884
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  95 in total

Review 1.  Cell signaling and mitochondrial dynamics: Implications for neuronal function and neurodegenerative disease.

Authors:  Theodore J Wilson; Andrew M Slupe; Stefan Strack
Journal:  Neurobiol Dis       Date:  2012-01-24       Impact factor: 5.996

Review 2.  Novel mitochondrial targets for neuroprotection.

Authors:  Miguel A Perez-Pinzon; R Anne Stetler; Gary Fiskum
Journal:  J Cereb Blood Flow Metab       Date:  2012-03-28       Impact factor: 6.200

Review 3.  Calcium and mitochondrial reactive oxygen species generation: how to read the facts.

Authors:  Vera Adam-Vizi; Anatoly A Starkov
Journal:  J Alzheimers Dis       Date:  2010       Impact factor: 4.472

4.  Secretagogin is a Ca2+-binding protein identifying prospective extended amygdala neurons in the developing mammalian telencephalon.

Authors:  Jan Mulder; Lauren Spence; Giuseppe Tortoriello; Jennifer A Dinieri; Mathias Uhlén; Bo Shui; Michael I Kotlikoff; Yuchio Yanagawa; Fabienne Aujard; Tomas Hökfelt; Yasmin L Hurd; Tibor Harkany
Journal:  Eur J Neurosci       Date:  2010-06-07       Impact factor: 3.386

Review 5.  Calcium dysregulation and homeostasis of neural calcium in the molecular mechanisms of neurodegenerative diseases provide multiple targets for neuroprotection.

Authors:  Gregor Zündorf; Georg Reiser
Journal:  Antioxid Redox Signal       Date:  2010-10-06       Impact factor: 8.401

Review 6.  Protective effects of phenelzine administration on synaptic and non-synaptic cortical mitochondrial function and lipid peroxidation-mediated oxidative damage following TBI in young adult male rats.

Authors:  Rachel L Hill; Indrapal N Singh; Juan A Wang; Jacqueline R Kulbe; Edward D Hall
Journal:  Exp Neurol       Date:  2020-04-20       Impact factor: 5.330

Review 7.  Energy deficit in Huntington disease: why it matters.

Authors:  Fanny Mochel; Ronald G Haller
Journal:  J Clin Invest       Date:  2011-02-01       Impact factor: 14.808

8.  Ginsenoside Re rescues methamphetamine-induced oxidative damage, mitochondrial dysfunction, microglial activation, and dopaminergic degeneration by inhibiting the protein kinase Cδ gene.

Authors:  Eun-Joo Shin; Seung Woo Shin; Thuy-Ty Lan Nguyen; Dae Hun Park; Myung-Bok Wie; Choon-Gon Jang; Seung-Yeol Nah; Byung Wook Yang; Sung Kwon Ko; Toshitaka Nabeshima; Hyoung-Chun Kim
Journal:  Mol Neurobiol       Date:  2014-01-16       Impact factor: 5.590

9.  Effects of Phenelzine Administration on Mitochondrial Function, Calcium Handling, and Cytoskeletal Degradation after Experimental Traumatic Brain Injury.

Authors:  Rachel L Hill; Indrapal N Singh; Juan A Wang; Edward D Hall
Journal:  J Neurotrauma       Date:  2018-12-12       Impact factor: 5.269

10.  PKCγ and PKCε are Differentially Activated and Modulate Neurotoxic Signaling Pathways During Oxygen Glucose Deprivation in Rat Cortical Slices.

Authors:  Dayana Surendran
Journal:  Neurochem Res       Date:  2019-09-20       Impact factor: 3.996
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