TY - JOUR
T1 - Characterizing calcium influx via voltage- and ligand-gated calcium channels in embryonic Alligator neurons in culture
AU - Ju, Weina
AU - Wu, Jiang
AU - Pritz, Michael B.
AU - Khanna, Rajesh
N1 - Funding Information:
Dr. Joel M. Brittain and Sarah Marie Wilson provided technical assistance; Dr. Fletcher A. White lent us the use of his calcium imaging microscope; and Dr. R. M. Elsey of the Rockefeller Wildlife Refuge generously provided Alligator eggs. Partial support for this publication was provided by: a Project Development Team grant within the ICTSI NIH/NCRR Grant Number RR025761 (to R.K.); grants from the Ralph W. and Grace M. Showalter foundation (to R.K.), and the Elwert Award in Medicine (to R.K.). W.J. is partially supported by a State Scholarship Fund issued by the Graduate Training Department of Jilin University.
PY - 2013/9
Y1 - 2013/9
N2 - Vertebrate brains share many features in common. Early in development, both the hindbrain and diencephalon are built similarly. Only later in time do differences in morphology occur. Factors that could potentially influence such changes include certain physiological properties of neurons. As an initial step to investigate this problem, embryonic Alligator brain neurons were cultured and calcium responses were characterized. The present report is the first to document culture of Alligator brain neurons in artificial cerebrospinal fluid (ACSF) as well as in standard mammalian tissue culture medium supplemented with growth factors. Alligator brain neuron cultures were viable for at least 1 week with unipolar neurites emerging by 24 hours. Employing Fura-2 AM, robust depolarization-induced calcium influx, was observed in these neurons. Using selective blockers of the voltage-gated calcium channels, the contributions of N-, P/Q-, R-, T-, and L-type channels in these neurons were assessed and their presence documented. Lastly, Alligator brain neurons were challenged with an excitotoxic stimulus (glutamate + glycine) where delayed calcium deregulation could be prevented by a classical NMDA receptor antagonist.
AB - Vertebrate brains share many features in common. Early in development, both the hindbrain and diencephalon are built similarly. Only later in time do differences in morphology occur. Factors that could potentially influence such changes include certain physiological properties of neurons. As an initial step to investigate this problem, embryonic Alligator brain neurons were cultured and calcium responses were characterized. The present report is the first to document culture of Alligator brain neurons in artificial cerebrospinal fluid (ACSF) as well as in standard mammalian tissue culture medium supplemented with growth factors. Alligator brain neuron cultures were viable for at least 1 week with unipolar neurites emerging by 24 hours. Employing Fura-2 AM, robust depolarization-induced calcium influx, was observed in these neurons. Using selective blockers of the voltage-gated calcium channels, the contributions of N-, P/Q-, R-, T-, and L-type channels in these neurons were assessed and their presence documented. Lastly, Alligator brain neurons were challenged with an excitotoxic stimulus (glutamate + glycine) where delayed calcium deregulation could be prevented by a classical NMDA receptor antagonist.
KW - Alligator
KW - Calcium mobilization
KW - Immunoblot
KW - NMDA receptor
KW - Neuronal culture
KW - Voltage-gated calcium channels
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U2 - 10.2478/s13380-013-0132-3
DO - 10.2478/s13380-013-0132-3
M3 - Article
AN - SCOPUS:84892973584
SN - 2081-3856
VL - 4
SP - 330
EP - 336
JO - Translational Neuroscience
JF - Translational Neuroscience
IS - 3
ER -