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Metabolic Brain Disease
Published in: Metabolic Brain Disease 2/2014

01-06-2014 | Original Paper

NMDA-R inhibition affects cellular process formation in Tilapia Melanocytes; a model for pigmented adrenergic neurons in process formation and retraction

Authors: Olalekan Michael Ogundele, Adetokunbo Adedotun Okunnuga, Temitope Deborah Fabiyi, Olayemi Joseph Olajide, Ibukun Dorcas Akinrinade, Philip Adeyemi Adeniyi, Abiodun Ayodele Ojo

Published in: Metabolic Brain Disease | Issue 2/2014

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Abstract

Parkinson’s disease has long been described to be a product of dopamine and (or) melanin loss in the substanstia nigra (SN). Although most studies have focused on dopaminergic neurons, it is important to consider the role of pigment cells in the etiology of the disease and to create an in vitro live cell model for studies involving pigmented adrenergic cells of the SN in Parkinsonism. The Melanocytes share specific features with the pigmented adrenergic neurons as both cells are pigmented, contain adrenergic receptors and have cellular processes. Although the melanocyte cellular processes are relatively short and observable only when stimulated appropriately by epinephrine and other factors or molecules. This study employs the manipulation of N-Methyl-D-Aspartate Receptor (NMDA-R), a major receptor in neuronal development, in the process formation pattern of the melanocyte in order to create a suitable model to depict cellular process elongation and shortening in pigmented adrenergic cells. NMDA-R is an important glutamate receptor implicated in neurogenesis, neuronal migration, maturation and cell death, thus we investigated the role of NMDA-R potentiation by glutamate/KCN and its inhibition by ketamine in the behavior of fish scale melanocytes in vitro. This is aimed at establishing the regulatory role of NMDA-R in this cell type (melanocytes isolated form Tilapia) in a similar manner to what is observable in the mammalian neurons. In vitro live cell culture was prepared in modified Ringer’s solution following which the cells were treated as follows; Control, Glutamate, Ketamine, Glutamate + Ketamine, KCN + Ketamine and KCN. The culture was maintained for 10 min and the changes were captured in 3D-Time frame at 0, 5 and 10 min for the control and 5, 7 and 10 min for each of the treatment category. Glutamate treatment caused formation of short cellular processes localized directly on the cell body while ketamine treatment (inhibition of NMDA-R) facilitated elongation of secondary cellular processes (highly branched) from primary major processes (Less branched); co-incubation of glutamate and ketamine induced short and highly branched process formation. Cyanide toxicity induced degeneration and reduction of cell size while co-treatment of cyanide and ketamine gave changes similar to that observed in glutamate-ketamine co-incubation. NMDA-R is present in the melanocytes. Activation of the receptor reduced elongation process, while inhibition of the receptor facilitated cell process elongation and branching. This confirms that like pigmented adrenergic cells of the nervous system, this cell contains NMDA-R and this receptor also regulates cell process elongation. The study also showed that inhibition of NMDA-R in melanocytes gave opposite outcomes to the role of the receptor in developing neurons; a function that is protective in adult neurons.
Literature
Barden H (1986) The intragranular location of carboxyl groups in neuromelanin and lipofuscin in human brain and in meningeal melanosomes in mouse brain. J Histochem Cytochem 34(10):1271–1279PubMedCrossRef
Bashkatova VG, Sudakov SK (2012) Role of metabotropic glutamate receptors in the mechanisms of experimental Parkinsonism development. Bull Exp Biol Med 153(5):655–657PubMedCrossRef
Benkler M, Agmon-Levin N, Hassin-Baer S, Cohen OS, Ortega-Hernandez OD, Levy A, Moscavitch SD, Szyper-Kravitz M, Damianovich M, Blank M, Chapman J, Shoenfeld Y (2012) Immunology, autoimmunity, and autoantibodies in Parkinson's disease. Clin Rev Allergy Immunol 42(2):164–171. doi:10.​1007/​s12016-010-8242-y PubMedCrossRef
Bohlega SA, Al-Foghom NB (2013) Drug-induced Parkinson`s disease. A clinical review. Neurosciences (Riyadh) 18(3):215–221
Burns GA, Ulibarri C, Stephens KE (1996) Transiently Chathecolaminergic cells in Fetal rats expresses mRNA for glutamate NMDA-R1 receptor. Brain Res 718(1–2):117–123PubMedCrossRef
Cepeda C, Ariano MA, Calvert CR, Flores-Hernández J, Chandler SH, Leavitt BR, Hayden MR, Levine MS (2001) NMDA receptor function in mouse models of Huntington disease. J Neurosci Res 66(4):525–539PubMedCrossRef
Cull-Candy S, Brickley S, Farrant M (2001) NMDA Receptor Sub-units; Diversity development and disease. Curr Opin Neurobiol 11(3):327–335PubMedCrossRef
Dooley CM, Mongera A, Walderich B, Nusslein-Volhard C (2013) On the embryonic origins of adult melanophores ErbB and Kit Signaling in establishing melanophore stem cell in zebra fish. Development 140(5):1003–1013PubMedCrossRef
Duman R, Aghajanian G (2012) Synaptic dysfunction in depression: potential therapeutic targets. Science 338:68–72PubMedCrossRef
Fedorow H, Tribl F, Halliday G, Gerlach M, Riederer P, Double KL (2005) Neuromelanin in human dopamine neurons: comparison with peripheral melanins and relevance to Parkinson's disease. Prog Neurobiol 75(2):109–124, ReviewPubMedCrossRef
Gutierrez S, Carnes A, Finucane GM et al (2010) Is age-dependent ketamine-induced apoptosis in the rat somatosensory cortex influenced by temperature. Neuroscience 168:253–262PubMedCentralPubMedCrossRef
Han Z, Yang JL, Jiang SX, Hou ST, Zheng RY (Fast non-competitive and reversible inhibition of NMDA activated current by 2-BFI confers Neuroprotection) Fast non-competitive and reversible inhibition of NMDA activated current by 2-BFI confers Neuroprotection. PLos One 8(5):e64894
Himmelseher, S and Kochs E (2004). Neuroprotection by ketamine. Anaesthesia, Pain, Intensive Care and Emergency Medicine — A.P.I.C.E. 2004, pp 893–901
Holmes S, Abbassi B, Su C, Singh M and Cunningham R.L (2013). Oxidative stress determines neuroprotective and neurotoxic properties of androgens in immortalized female rats dopaminergic neuronal cells. Endocrinology. August 19 [Epub Ahead of Print].
Jablonka S, Dombert B, Asan E and Sendtner M (2013). Mechanism of axon maintenance and plasticity in motor neurons. Journal of Anatomy, Sept. 6 [Epub Ahead of Print].
Karlsson O, Lindquist NG (2013). Melanin affinity and its possible role in neurodegeneration. J Neural Transm. 2013 Jul 3. [Epub ahead of print]
Lie OV, Bennett GD, Rosenquist TH (2010) The N-Methyl-D-Aspartate Receptor in heart development: a gene knockdown model using siRNA. Reprod Toxicol 29(1):32
Maskos U, McKay RD (2003) Neural cells without functional N-Methyl-D-Aspartate (NMDA) Receptors contribute extensively to normal postnatal brain development in efficiently generated chimaeric NMDA R -/-<- ->+/+ mice. Developmental Biology 262(1):119–136
Menna E, Zambetti S, Morini R, Donzelli A, Disanza A, Calvigioni D, Braida D, Nicolini C, Orlando M, Fossati G, Cristina Regondi M, Pattini L, Frassoni C, Francolini M, Scita G, Sala M, Fahnestock M, Matteoli M (2013) Eps8 controls dendritic spine density and synaptic plasticity through its actin-capping activity. EMBO J 32(12):1730–1744. doi:10.​1038/​emboj.​2013.​107 PubMedCrossRef
Ogundele O.M, Olaniyan T.O, Dare B.J, Omotoso D.R, Omotosho O.D, Akintayo O.C, Memudu A.E and Caxton-Martins E.A (2012). Neuroprotective Properties of NMDA R Antagonist (Ketamine) in Cyanide Treated Neurons in vitro. Annual Review & Research in Biology, ISSN: 2231–4776,Vol.: 2, Issue.: 3 (July-September)
Pachoud B, Adamantidis A, Ravassard P, Luppi PH, Grisar T, Lakaye B, Salin PA (2010) Major impairments of glutamatergic transmission and long-term synaptic plasticity in the hippocampus of mice lacking the melanin-concentrating hormone receptor-1. J Neurophysiol 104(3):1417–1425. doi:10.​1152/​jn.​01052.​2009, Epub 2010 Jun 30PubMedCrossRef
Payer DE, Behzadi A, Kish SJ, Houle S, Wilson AA, Rusjan PM, Tong J, Selby P, George TP, McCluskey T, Boileau I (2013) Heightened D3 Dopamine Receptor Levels in Cocaine Dependence and Contributions to the Addiction Behavioural Phenotype: A Positron Emission Tomography Study with [11C]-(+)-PHNO. Neuropsychopharmacology. doi:10.​1038/​npp.​2013.​192 [Epub ahead of print]PubMed
Saraswat RC, Ram N (1972) Quantification of Amino Acids in Fish scale. Indian J Fishery; 17:21–25
Sheets L, Ransom DG, Mellgren EM, Johnson SL, Schnapp BJ (2007) Zebrafish melanophilin facilitates melanosome dispersion by regulating dynein. Curr Biol 23(20):1721–34, Epub 2007CrossRef
Sköld HN, Aspengren S, Wallin M (2002) The cytoskeleton in fish melanophore melanosome positioning. Microsc Res Tech 58(6):464–469, ReviewPubMedCrossRef
Springer W, Hoppe T, Schmidt E, Baumeister R (2005) A Caenorhabditis elegans Parkin mutant with altered solubility couples alpha-synuclein aggregation to proteotoxic stress. Hum Mol Genet 14(22):3407–3423, Epub 2005PubMedCrossRef
Sugden D, Davidson K, Hough KA, Teh MT (2004) Melatonin, melatonin receptors and melanophores: a moving story. Pigment Cell Res 17(5):454–460PubMedCrossRef
Thobois S, Lhommée E, Klinger H, Ardouin C, Schmitt E, Bichon A, Kistner A, Castrioto A, Xie J, Fraix V, Pelissier P, Chabardes S, Mertens P, Quesada JL, Bosson JL, Pollak P, Broussolle E, Krack P (2013) Parkinsonian apathy responds to dopaminergic stimulation of D2/D3 receptors with piribedil. Brain 136(Pt 5):1568–1577PubMedCrossRef
Zhu Y (2013). The Drosophila visual system: From neural circuits to behavior. Cell Adh Migr. 2013 Jun 27;7(4). [Epub ahead of print].
Metadata
Title
NMDA-R inhibition affects cellular process formation in Tilapia Melanocytes; a model for pigmented adrenergic neurons in process formation and retraction
Authors
Olalekan Michael Ogundele
Adetokunbo Adedotun Okunnuga
Temitope Deborah Fabiyi
Olayemi Joseph Olajide
Ibukun Dorcas Akinrinade
Philip Adeyemi Adeniyi
Abiodun Ayodele Ojo
Publication date
01-06-2014
Publisher
Springer US
Published in
Metabolic Brain Disease / Issue 2/2014
Print ISSN: 0885-7490
Electronic ISSN: 1573-7365
DOI
https://doi.org/10.1007/s11011-013-9447-6

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