Dendritic calcium transients evoked by single back‐propagating action potentials in rat neocortical pyramidal neurons.

1. Dendrites of rat neocortical layer V pyramidal neurons were loaded with the Ca2+ indicator dye Calcium Green‐1 (CG‐1) or fluo‐3, and the mechanisms which govern action potential (AP)‐evoked transient changes in dendritic cytosolic Ca2+ concentration ([Ca2+]i) were examined. APs were initiated either by synaptic stimulation or by depolarizing the soma or dendrite by current injection, and changes in fluorescence of the indicator dye were measured in the proximal 170 microns of the apical dendrite. 2. Simultaneous two‐pipette recordings of APs from the soma and apical dendrite, and dendritic fluorescence imaging indicated that a single AP propagating from the soma into the apical dendrite evokes a rapid transient increase in fluorescence indicating a transient increase in [Ca2+]i. At 35‐37 degrees C the decay time constant of the fluorescence transient following an AP was around 80 ms. 3. Voltage‐activated Ca2+ channels (VACCs) of several subtypes mediated the AP‐evoked fluorescence transient in the proximal (100‐170 microns) apical dendrite. The AP‐evoked fluorescence transient resulted from Ca2+ entry through L‐type (nifedipine sensitive; 25%), N‐type (omega‐conotoxin GVIA sensitive; 28%) and P‐type (omega‐agatoxin IVA sensitive; 10%) Ca2+ channels and through Ca2+ channels (R‐type) not sensitive to L‐, N‐ and P‐type Ca2+ channel blockers (cadmium ion sensitive; 37%). 4. The decay time course of the dendritic fluorescence transient was prolonged by the blockers of endoplasmic reticulum (ER) Ca(2+)‐ATPase, cyclopiazonic acid and thapsigargin, suggesting that uptake of Ca2+ into the ER in dendrites governs clearance of dendritic Ca2+. 5. The decay time course of the fluorescence transient was slightly prolonged by benzamil, a blocker of plasma membrane Na(+)‐Ca2+ exchange and by calmidazolium, a blocker of the calmodulin‐dependent plasma membrane Ca(2+)‐ATPase, suggesting that these pathways are less important for dendrite Ca2+ clearance following a single AP. Neither the mitochondrial uncoupler carbonyl cyanide p‐(trifluoromethoxy)phenylhydrazone (FCCP) nor the blocker of Ca2+ uptake into mitochondria, Ruthenium Red, had any measurable effect on the decay time course of the fluorescence transient. 6. Dendritic fluorescence transients measured during trains of dendritic APs began to summate at impulse frequencies of 5 APs s‐1. At higher frequencies APs caused a concerted and maintained elevation of dendritic fluorescence during the train.(ABSTRACT TRUNCATED AT 400 WORDS)

[1]  K. Abromeit Music Received , 2023, Notes.

[2]  C. Moore,et al.  Specific inhibition of mitochondrial Ca++ transport by ruthenium red. , 1971, Biochemical and biophysical research communications.

[3]  I. Duce,et al.  Can neuronal smooth endoplasmic reticulum function as a calcium reservoir? , 1978, Neuroscience.

[4]  R. Llinás,et al.  Presynaptic calcium currents in squid giant synapse. , 1981, Biophysical journal.

[5]  H. Belle R 24 571: A potent inhibitor of calmodulin-activated enzymes , 1981 .

[6]  R. Llinás,et al.  Transmission by presynaptic spike-like depolarization in the squid giant synapse. , 1982, Proceedings of the National Academy of Sciences of the United States of America.

[7]  R. McBurney,et al.  Role for microsomal Ca storage in mammalian neurones? , 1984, Nature.

[8]  F. Barros,et al.  Inhibition of Na+/Ca2+ exchange in pituitary plasma membrane vesicles by analogues of amiloride. , 1985, Biochemistry.

[9]  W. N. Ross,et al.  Mapping calcium transients in the dendrites of Purkinje cells from the guinea‐pig cerebellum in vitro. , 1987, The Journal of physiology.

[10]  R. Tsien,et al.  Imaging of cytosolic Ca2+ transients arising from Ca2+ stores and Ca2+ channels in sympathetic neurons , 1988, Neuron.

[11]  D. Tank,et al.  Optical imaging of calcium accumulation in hippocampal pyramidal cells during synaptic activation , 1989, Nature.

[12]  Norbert,et al.  Cyclopiazonic acid is a specific inhibitor of the Ca2+-ATPase of sarcoplasmic reticulum. , 1989, The Journal of biological chemistry.

[13]  W. Catterall,et al.  Subunit structure and localization of dihydropyridine-sensitive calcium channels in mammalian brain, spinal cord, and retina , 1990, Neuron.

[14]  P. C. Schwindt,et al.  High- and low-threshold calcium currents in neurons acutely isolated from rat sensorimotor cortex , 1990, Neuroscience Letters.

[15]  F. Lattanzio,et al.  The effect of pH on rate constants, ion selectivity and thermodynamic properties of fluorescent calcium and magnesium indicators. , 1991, Biochemical and biophysical research communications.

[16]  R. Llinás,et al.  Localization of P-type calcium channels in the central nervous system. , 1991, Proceedings of the National Academy of Sciences of the United States of America.

[17]  S. Snyder,et al.  Localization of an endoplasmic reticulum calcium ATPase mRNA in rat brain by in situ hybridization , 1991, Neuroscience.

[18]  P. Erne,et al.  Calcium binding to fluorescent calcium indicators: calcium green, calcium orange and calcium crimson. , 1991, Biochemical and biophysical research communications.

[19]  W Zieglgänsberger,et al.  Voltage dependence of excitatory postsynaptic potentials of rat neocortical neurons. , 1991, Journal of neurophysiology.

[20]  D. Bleakman,et al.  The properties of intracellular calcium stores in cultured rat cerebellar neurons , 1991, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[21]  Clara Franzini-Armstrong,et al.  The brain ryanodine receptor: A caffeine-sensitive calcium release channel , 1991, Neuron.

[22]  K. Beam,et al.  Action potential waveform voltage-clamp commands reveal striking differences in calcium entry via low and high voltage activated calcium channels , 1991, Neuron.

[23]  W. N. Ross,et al.  The spread of Na+ spikes determines the pattern of dendritic Ca2+ entry into hippocampal neurons , 1992, Nature.

[24]  W. N. Ross,et al.  Calcium transients evoked by climbing fiber and parallel fiber synaptic inputs in guinea pig cerebellar Purkinje neurons. , 1992, Journal of neurophysiology.

[25]  J. Meldolesi,et al.  The endoplasmic reticulum of purkinje neuron body and dendrites: Molecular identity and specializations for Ca2+ transport , 1992, Neuroscience.

[26]  V. Henzi,et al.  Characteristics and function of Ca2+ — and inositol 1,4,5-trisphosphate-releasable stores of Ca2+ in neurons , 1992, Neuroscience.

[27]  B Sabatini,et al.  Evaluation of cellular mechanisms for modulation of calcium transients using a mathematical model of fura-2 Ca2+ imaging in Aplysia sensory neurons. , 1992, Biophysical journal.

[28]  R. Tsien,et al.  Distinctive pharmacology and kinetics of cloned neuronal Ca2+ channels and their possible counterparts in mammalian CNS neurons , 1993, Neuropharmacology.

[29]  T. Knöpfel,et al.  Activity induced elevations of intracellular calcium concentration in neurons of the deep cerebellar nuclei. , 1994, Journal of neurophysiology.

[30]  Daniel Johnston,et al.  Dendritic attenuation of synaptic potentials and currents: the role of passive membrane properties , 1994, Trends in Neurosciences.

[31]  B. Sakmann,et al.  Active propagation of somatic action potentials into neocortical pyramidal cell dendrites , 1994, Nature.

[32]  Samuel Thayer,et al.  Mitochondria buffer physiological calcium loads in cultured rat dorsal root ganglion neurons , 1994, The Journal of neuroscience : the official journal of the Society for Neuroscience.