Coupling potentials in CA1 neurons during calcium-free-induced field burst activity

Small amplitude depolarizations (fast prepotentials, spikelets) recorded in mammalian neurons are thought to represent either dendritic action potentials or presynaptic action potentials attenuated by gap junctions. We have used whole-cell recordings in an in vitro calcium- free model of epilepsy to record spikelets from CA1 neurons of the rat hippocampus. It was found that spikelet appearance was closely correlated with the occurrence of dye coupling between pyramidal neurons, indicating that both phenomena share a common substrate. Spikelets were characterized according to waveform (amplitude and shape) and temporal occurrence. Spikelet amplitudes were found to be invariant with neuronal membrane potential, and their pattern of occurrence was indistinguishable from patterns of action potential firing in these cells. Voltage and current recordings revealed a spikelet waveform that was usually biphasic, comprised of a rapid depolarization followed by a slower hyperpolarization. Numerical differentiation of spike bursts resulted in waveforms similar to recorded spikelet sequences, while numerical integration of spikelets yielded waveforms that were indistinguishable from action potentials. Modification of spikelet waveforms by the potassium channel blocker tetraethylammonium chloride suggests that spikelets may arise from both resistive and capacitive transmission of presynaptic action potentials. Intracellular alkalinization and acidification brought about by perfusion with NH4Cl caused changes in spikelet frequency, consistent with reported alterations of field burst activity in this model of epilepsy. These results suggest that spikelets result from gap junctional communication, and may be important determinants of neuronal activity during seizure-like activity.

[1]  F. Dudek,et al.  Dye-coupling between CA3 pyramidal cells in slices of rat hippocampus , 1980, Brain Research.

[2]  J D Pitts,et al.  The Gap Junction , 1986, Journal of Cell Science.

[3]  D C Spray,et al.  Gap junctional conductance is a simple and sensitive function of intracellular pH. , 1981, Science.

[4]  R. Wong,et al.  Synchronization of inhibitory neurones in the guinea‐pig hippocampus in vitro. , 1994, The Journal of physiology.

[5]  Berj L. Bardakjian,et al.  Chaos in coupled nonlinear gastric oscillators , 1990 .

[6]  R. Yuste,et al.  Extensive dye coupling between rat neocortical neurons during the period of circuit formation , 1993, Neuron.

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

[8]  F. Dudek,et al.  Coupling in rat hippocampal slices: Dye transfer between CA1 pyramidal cells , 1982, Brain Research Bulletin.

[9]  J. E. Mann,et al.  Evaluation of electric field changes in the cleft between excitable cells. , 1977, Journal of theoretical biology.

[10]  H. Korn,et al.  Ammonium sulfate induced uncouplings of crayfish septate axons with and without increased junctional resistance , 1982, Neuroscience.

[11]  K G Baimbridge,et al.  Exposure to high-pH medium increases the incidence and extent of dye coupling between rat hippocampal CA1 pyramidal neurons in vitro , 1991, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[12]  D. Spray,et al.  Expression of gap junction channels in communication-incompetent cells after stable transfection with cDNA encoding connexin 32. , 1990, Proceedings of the National Academy of Sciences of the United States of America.

[13]  J. E. Mann,et al.  Further development of a model for electrical transmission between myocardial cells not connected by low-resistance pathways. , 1979, Journal of electrocardiology.

[14]  M. Häusser,et al.  Initiation and spread of sodium action potentials in cerebellar purkinje cells , 1994, Neuron.

[15]  A. Nuñez,et al.  In vivo electrophysiological analysis of lucifer yellow-coupled hippocampal pyramids , 1990, Experimental Neurology.

[16]  F. Dudek,et al.  Electrotonic coupling between granule cells of rat dentate gyrus: physiological and anatomical evidence. , 1982, Journal of neurophysiology.

[17]  R. Thomas Review Lecture: Experimental displacement of intracellular pH and the mechanism of its subsequent recovery. , 1984, The Journal of physiology.

[18]  B. Sakmann,et al.  Quantal components of unitary EPSCs at the mossy fibre synapse on CA3 pyramidal cells of rat hippocampus. , 1993, The Journal of physiology.

[19]  J. Storm Potassium currents in hippocampal pyramidal cells. , 1990, Progress in brain research.

[20]  B. Katz Nerve, Muscle and Synapse , 1966 .

[21]  J. Eccles The Physiology of Synapses , 1964, Springer Berlin Heidelberg.

[22]  J. Storm,et al.  Action potential repolarization and a fast after‐hyperpolarization in rat hippocampal pyramidal cells. , 1987, The Journal of physiology.

[23]  H Korn,et al.  Electrical field effects: their relevance in central neural networks. , 1989, Physiological reviews.

[24]  H. Jahnsen,et al.  Gap junctions on CA3 pyramidal cells of guinea pig hippocampus shown by freeze-fracture , 1981, Brain Research.

[25]  W. W. Stewart,et al.  Functional connections between cells as revealed by dye-coupling with a highly fluorescent naphthalimide tracer , 1978, Cell.

[26]  E. Hertzberg,et al.  Gap junction protein in rat hippocampus: Correlative light and electron microscope immunohistochemical localization , 1989, The Journal of comparative neurology.

[27]  P. O’Donnell,et al.  Dopaminergic modulation of dye coupling between neurons in the core and shell regions of the nucleus accumbens , 1993, The Journal of neuroscience : the official journal of the Society for Neuroscience.

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

[29]  L.J. Leon,et al.  A model study of electric field interactions between cardiac myocytes , 1992, IEEE Transactions on Biomedical Engineering.

[30]  W. W. Stewart Lucifer dyes—highly fluorescent dyes for biological tracing , 1981, Nature.

[31]  E. Kandel,et al.  Epileptogenic agents enhance transmission at an identified weak electrical synapse in Aplysia. , 1981, Science.

[32]  P. Schwartzkroin,et al.  Further characteristics of hippocampal CA1 cells in vitro , 1977, Brain Research.

[33]  E. Kandel,et al.  ELECTROPHYSIOLOGY OF HIPPOCAMPAL NEURONS: IV. FAST PREPOTENTIALS. , 1961, Journal of neurophysiology.

[34]  P. Schwartzkroin,et al.  Characteristics of CA1 neurons recorded intracellularly in the hippocampalin vitro slice preparation , 1975, Brain Research.

[35]  B. Bardakjian,et al.  A mapped clock oscillator model for transmembrane electrical rhythmic activity in excitable cells. , 1994, Journal of theoretical biology.

[36]  F. Dudek,et al.  A physiological test for electrotonic coupling between CA1 pyramidal cells in rat hippocampal slices , 1982, Brain Research.

[37]  O Herreras,et al.  Propagating dendritic action potential mediates synaptic transmission in CA1 pyramidal cells in situ. , 1990, Journal of neurophysiology.

[38]  M B Jackson,et al.  Cable analysis with the whole-cell patch clamp. Theory and experiment. , 1992, Biophysical journal.

[39]  P. Schwartzkroin,et al.  Electrophysiology of Hippocampal Neurons , 1987 .

[40]  M. Bennett,et al.  PHYSIOLOGY OF ELECTROTONIC JUNCTIONS * , 1966, Annals of the New York Academy of Sciences.

[41]  F. Dudek,et al.  Synchronous epileptiform bursts without chemical transmission in CA2, CA3 and dentate areas of the hippocampus , 1984, Brain Research.

[42]  J. Barker,et al.  Fast pre-potential generation in rat hippocampal ca1 pyramidal neurons , 1993, Neuroscience.

[43]  M. Gutnick,et al.  Dye coupling and possible electrotonic coupling in the guinea pig neocortical slice. , 1981, Science.

[44]  P. Carlen,et al.  Modulation of gap junctional mechanisms during calcium-free induced field burst activity: a possible role for electrotonic coupling in epileptogenesis , 1994, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[45]  F. Dudek,et al.  Excitation of hippocampal pyramidal cells by an electrical field effect. , 1984, Journal of neurophysiology.

[46]  B. L. Ginsborg THE PHYSIOLOGY OF SYNAPSES , 1964 .

[47]  F. Dudek,et al.  Synchronization without active chemical synapses during hippocampal afterdischarges. , 1984, Journal of neurophysiology.

[48]  F. Dudek,et al.  Synchronous neural afterdischarges in rat hippocampal slices without active chemical synapses. , 1982, Science.

[49]  N. Sperelakis,et al.  Ultrastructural changes produced by hypertonicity in cat cardiac muscle. , 1971, Journal of molecular and cellular cardiology.

[50]  Effects of the propagation velocity of a surface depolarization wave on the extracellular potential of an excitable cell , 1994, IEEE Transactions on Biomedical Engineering.

[51]  A. Tolkovsky,et al.  Na+/H+ exchange is the major mechanism of pH regulation in cultured sympathetic neurons: Measurements in single cell bodies and neurites using a fluorescent pH indicator , 1987, Neuroscience.

[52]  H. Mclennan,et al.  Bursting response to current‐evoked depolarization in rat ca1 pyramidal neurons is correlated with lucifer yellow dye coupling but not with the presence of calbindin‐D28k , 1991, Synapse.