Subcellular expression and neuroprotective effects of SK channels in human dopaminergic neurons

Small-conductance Ca2+-activated K+ channel activation is an emerging therapeutic approach for treatment of neurological diseases, including stroke, amyotrophic lateral sclerosis and schizophrenia. Our previous studies showed that activation of SK channels exerted neuroprotective effects through inhibition of NMDAR-mediated excitotoxicity. In this study, we tested the therapeutic potential of SK channel activation of NS309 (25 μM) in cultured human postmitotic dopaminergic neurons in vitro conditionally immortalized and differentiated from human fetal mesencephalic cells. Quantitative RT-PCR and western blotting analysis showed that differentiated dopaminergic neurons expressed low levels of SK2 channels and high levels of SK1 and SK3 channels. Further, protein analysis of subcellular fractions revealed expression of SK2 channel subtype in mitochondrial-enriched fraction. Mitochondrial complex I inhibitor rotenone (0.5 μM) disrupted the dendritic network of human dopaminergic neurons and induced neuronal death. SK channel activation reduced mitochondrial membrane potential, while it preserved the dendritic network, cell viability and ATP levels after rotenone challenge. Mitochondrial dysfunction and delayed dopaminergic cell death were prevented by increasing and/or stabilizing SK channel activity. Overall, our findings show that activation of SK channels provides protective effects in human dopaminergic neurons, likely via activation of both membrane and mitochondrial SK channels. Thus, SK channels are promising therapeutic targets for neurodegenerative disorders such as Parkinson’s disease, where dopaminergic cell loss is associated with progression of the disease.

[1]  V. Petruzzella,et al.  Dysfunction of mitochondrial respiratory chain complex I in neurological disorders: genetics and pathogenetic mechanisms. , 2012, Advances in experimental medicine and biology.

[2]  Jochen Roeper,et al.  Differential Expression of the Small-Conductance, Calcium-Activated Potassium Channel SK3 Is Critical for Pacemaker Control in Dopaminergic Midbrain Neurons , 2001, The Journal of Neuroscience.

[3]  M. Stocker Ca2+-activated K+ channels: molecular determinants and function of the SK family , 2004, Nature Reviews Neuroscience.

[4]  G. Hu,et al.  Studies of ATP-sensitive potassium channels on 6-hydroxydopamine and haloperidol rat models of Parkinson's disease: Implications for treating Parkinson's disease? , 2005, Neuropharmacology.

[5]  J. Gillespie,et al.  Evidence for mitochondrial Ca(2+)-induced Ca2+ release in permeabilised endothelial cells. , 1998, Biochemical and biophysical research communications.

[6]  P. Pedarzani,et al.  Molecular and cellular basis of small- and intermediate-conductance, calcium-activated potassium channel function in the brain , 2008, Cellular and Molecular Life Sciences.

[7]  M. Rice,et al.  Partial Mitochondrial Inhibition Causes Striatal Dopamine Release Suppression and Medium Spiny Neuron Depolarization via H2O2 Elevation, Not ATP Depletion , 2005, The Journal of Neuroscience.

[8]  J. Mazat,et al.  Modulation of cell calcium signals by mitochondria , 2004, Molecular and Cellular Biochemistry.

[9]  A. H. V. Schapira,et al.  MITOCHONDRIAL COMPLEX I DEFICIENCY IN PARKINSON'S DISEASE , 1989, The Lancet.

[10]  C. Tanner,et al.  Rotenone, Paraquat, and Parkinson’s Disease , 2011, Environmental health perspectives.

[11]  J. Geddes,et al.  Synaptic Mitochondria Are More Susceptible to Ca2+Overload than Nonsynaptic Mitochondria* , 2006, Journal of Biological Chemistry.

[12]  V. Mootha,et al.  MICU1 encodes a mitochondrial EF hand protein required for Ca2+ uptake , 2010, Nature.

[13]  Peter S. Freestone,et al.  Acute action of rotenone on nigral dopaminergic neurons – involvement of reactive oxygen species and disruption of Ca2+ homeostasis , 2009, The European journal of neuroscience.

[14]  P. Brundin,et al.  Effect of Mutant α-Synuclein on Dopamine Homeostasis in a New Human Mesencephalic Cell Line* , 2002, The Journal of Biological Chemistry.

[15]  A. Gadicherla,et al.  Protection against cardiac injury by small Ca(2+)-sensitive K(+) channels identified in guinea pig cardiac inner mitochondrial membrane. , 2013, Biochimica et biophysica acta.

[16]  J. Mazat,et al.  A model of mitochondrial Ca(2+)-induced Ca2+ release simulating the Ca2+ oscillations and spikes generated by mitochondria. , 1998, Biophysical chemistry.

[17]  C. Culmsee,et al.  Protective Roles for Potassium SK/KCa2 Channels in Microglia and Neurons , 2012, Front. Pharmacol..

[18]  D. Busija,et al.  Diazoxide induces delayed pre‐conditioning in cultured rat cortical neurons , 2003, Journal of neurochemistry.

[19]  Xiao-hong Cai,et al.  Potassium channels: possible new therapeutic targets in Parkinson's disease. , 2008, Medical hypotheses.

[20]  Jeppe Falsig,et al.  Progressive Degeneration of Human Mesencephalic Neuron-Derived Cells Triggered by Dopamine-Dependent Oxidative Stress Is Dependent on the Mixed-Lineage Kinase Pathway , 2005, The Journal of Neuroscience.

[21]  Masahiko Watanabe,et al.  SK2 Channels Are Neuroprotective for Ischemia-Induced Neuronal Cell Death , 2011, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[22]  N. Plesnila,et al.  KCa2 channels activation prevents [Ca2+]i deregulation and reduces neuronal death following glutamate toxicity and cerebral ischemia , 2011, Cell Death and Disease.

[23]  J. T. Williams,et al.  SK2 and SK3 expression differentially affect firing frequency and precision in dopamine neurons , 2012, Neuroscience.

[24]  A. Schapira Mitochondrial pathology in Parkinson's disease. , 2011, The Mount Sinai journal of medicine, New York.

[25]  Christian Haass,et al.  Mitochondrial dysfunction in Parkinson's disease: molecular mechanisms and pathophysiological consequences , 2012, The EMBO journal.

[26]  Lei Duan,et al.  KATP channel openers protect mesencephalic neurons against MPP+‐induced cytotoxicity via inhibition of ROS production , 2010, Journal of neuroscience research.

[27]  Marjan S. Bolouri,et al.  Integrated Analysis of Protein Composition, Tissue Diversity, and Gene Regulation in Mouse Mitochondria , 2003, Cell.

[28]  M. Pool,et al.  NeuriteTracer: A novel ImageJ plugin for automated quantification of neurite outgrowth , 2008, Journal of Neuroscience Methods.

[29]  M. Esiri,et al.  Axonal damage: a key predictor of outcome in human CNS diseases. , 2003, Brain : a journal of neurology.

[30]  A. Schapira,et al.  Evidence for mitochondrial dysfunction in Parkinson's disease—a critical appraisal , 2004, Movement disorders : official journal of the Movement Disorder Society.

[31]  S. Sakoda,et al.  Expression and distribution of a small-conductance calcium-activated potassium channel (SK3) protein in skeletal muscles from myotonic muscular dystrophy patients and congenital myotonic mice , 2003, Neuroscience Letters.

[32]  V. Kaushal,et al.  The Ca2+ activated SK3 channel is expressed in microglia in the rat striatum and contributes to microglia-mediated neurotoxicity in vitro , 2010, Journal of Neuroinflammation.

[33]  D. Strøbæk,et al.  CyPPA, a Positive SK3/SK2 Modulator, Reduces Activity of Dopaminergic Neurons, Inhibits Dopamine Release, and Counteracts Hyperdopaminergic Behaviors Induced by Methylphenidate1 , 2012, Front. Pharmacol..

[34]  N. Plesnila,et al.  Mitochondrial Small Conductance SK2 Channels Prevent Glutamate-induced Oxytosis and Mitochondrial Dysfunction* , 2013, The Journal of Biological Chemistry.

[35]  Hans Zischka,et al.  Electrophoretic analysis of the mitochondrial outer membrane rupture induced by permeability transition. , 2008, Analytical chemistry.

[36]  P. Christophersen,et al.  Activation of human IK and SK Ca2+ -activated K+ channels by NS309 (6,7-dichloro-1H-indole-2,3-dione 3-oxime). , 2004, Biochimica et biophysica acta.

[37]  J. Marksteiner,et al.  Comparative immunohistochemical distribution of three small-conductance Ca2+-activated potassium channel subunits, SK1, SK2, and SK3 in mouse brain , 2004, Molecular and Cellular Neuroscience.

[38]  Chunnuan Chen,et al.  Mitochondrial complex I inhibitor rotenone-induced toxicity and its potential mechanisms in Parkinson’s disease models , 2012, Critical reviews in toxicology.

[39]  H. Reichmann,et al.  Environmental toxins trigger PD-like progression via increased alpha-synuclein release from enteric neurons in mice , 2012, Scientific Reports.

[40]  Eric S. Lander,et al.  Identification of a gene causing human cytochrome c oxidase deficiency by integrative genomics , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[41]  M. Ungless,et al.  Hyperexcitable substantia nigra dopamine neurons in PINK1- and HtrA2/Omi-deficient mice. , 2010, Journal of neurophysiology.

[42]  M. Leist,et al.  Requirement of a dopaminergic neuronal phenotype for toxicity of low concentrations of 1-methyl-4-phenylpyridinium to human cells. , 2009, Toxicology and applied pharmacology.

[43]  Todd B. Sherer,et al.  Chronic systemic pesticide exposure reproduces features of Parkinson's disease , 2000, Nature Neuroscience.

[44]  G. Wang,et al.  ATP-sensitive potassium channels: novel potential roles in Parkinson’s disease , 2007, Neuroscience Bulletin.

[45]  Shinn-Ying Ho,et al.  NeurphologyJ: An automatic neuronal morphology quantification method and its application in pharmacological discovery , 2011, BMC Bioinformatics.

[46]  A. Baracca,et al.  Rhodamine 123 as a probe of mitochondrial membrane potential: evaluation of proton flux through F(0) during ATP synthesis. , 2003, Biochimica et biophysica acta.

[47]  T. Murphy,et al.  NF-E2-related Factor-2 Mediates Neuroprotection against Mitochondrial Complex I Inhibitors and Increased Concentrations of Intracellular Calcium in Primary Cortical Neurons* , 2003, Journal of Biological Chemistry.

[48]  S. Perry,et al.  Mitochondrial membrane potential probes and the proton gradient: a practical usage guide. , 2011, BioTechniques.

[49]  R. Rimini,et al.  Quantitative expression analysis of the small conductance calcium-activated potassium channels, SK1, SK2 and SK3, in human brain. , 2000, Brain research. Molecular brain research.

[50]  Mark A. Smith,et al.  New insights into the mechanisms of mitochondrial preconditioning-triggered neuroprotection. , 2011, Current pharmaceutical design.

[51]  D. G. Herrera,et al.  Functional reduction of SK3-mediated currents precedes AMPA-receptor-mediated excitotoxicity in dopaminergic neurons , 2011, Neuropharmacology.

[52]  C. Scoppetta,et al.  CENTRAL CERVICAL CORD SYNDROME AFTER HEADING A FOOTBALL , 1978, The Lancet.

[53]  M. Kye,et al.  Small-conductance, Ca2+-activated K+ channel SK3 generates age-related memory and LTP deficits , 2003, Nature Neuroscience.