Chronic epilepsy in developing hippocampal neurons: electrophysiologic and morphologic features.

Despite the susceptibility of immature neurons to seizures, there are few models of epilepsy in the developing brain. By taking advantage of activity-dependent developmental changes in young neurons, we have developed a novel model of chronic epilepsy in cultured hippocampal slices. Incubating slices in tetrodotoxin (TTX) for at least 1 week produced significant changes in the electrical activity and appearance of CA1 pyramidal neurons. Extracellular recordings revealed multiple population spikes, and, in whole-cell recordings, evoked synaptic potentials lasting hundreds of milliseconds with many superimposed action potentials were present. Spontaneous firing with burst-like discharges was also evident. These changes were secondary to increased AMPA-receptor-mediated responses and decreased GABA(A) receptor events. Altered membrane properties involved increased expression of T-type Ca(2+) channels which are normally down-regulated in these neurons. TTX-treated neurons also showed abnormal dendritic branching. This model of chronic epilepsy in developing hippocampal neurons demonstrated many changes at the membrane, cellular and synaptic level that may provide new insights into the nature of epileptogenesis in the young brain.

N-type Ca2+ channels are located on somata, dendrites, and a subpopulation of dendritic spines on live hippocampal pyramidal neurons.

In the nervous system the influx of Ca2+ orchestrates multiple biochemical and electrical events essential for development and function. A major route for Ca2+ entry is through voltage-dependent calcium channels (VDCCs). It is becoming increasingly clear that the precise contribution VDCCs make to neuronal function depends not only upon their specific electrophysiological properties but also on their distribution over the nerve cell surface. One location where the presence of VDCCs may be critical is the dendritic spine, a structure known to be the major site of excitatory synaptic input. On spines, VDCCs are hypothesized to play an essential role in signal processing, learning, and memory. However, direct evidence for the presence of VDCCs on spines is lacking. Attempts to examine the distribution of VDCCs, or indeed any other components, on spines have been hampered since the size of many spines is close to the limits of resolution of conventional light microscopy. Using a new, biologically active, fluorescein conjugate of omega-conotoxin (Fl-omega-CgTx), a selective blocker of N-type VDCCs, and confocal microscopy, we have mapped the distributions of N-type VDCCs on live CA1 neurons in rat hippocampal slices. VDCCs were found on somata, throughout the dendritic arbor, and on dendritic spines in all hippocampal subfields. A comparison of three-dimensional reconstructions of structures labeled by Fl-omega-CgTx with those outlined by 1,1-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine (Dil) or Lucifer yellow confirmed the presence of N-type VDCCs on dendritic spines. However, spine frequency on dendrites labeled with Fl-omega-CgTx was much lower than the spine frequency on dendrites labeled with Lucifer yellow or Dil, suggesting that some spines lack N-type VDCCs. These results offer the first direct evidence for the localization of any voltage-dependent channel on dendritic spines. The presence of N-type VDCCs on dendrites and their spines argues that these channels may participate in the generation of active Ca2+ conductances in distal dendrites, and is consistent with a role for spines as specialized compartments for concentrating Ca2+.

Poliomyelitis-like paralysis during recovery from acute bronchial asthma: possible etiology and risk factors.

A poliomyelitis-like paralytic disease during recovery from an attack of bronchial asthma is described in two young children. They presented at the age of 13 and 22 months, respectively, with acute flaccid paralysis of one or both lower limbs and preserved sensation. Cerebrospinal fluid examinations revealed mild protein elevation in both and pleocytosis in the second infant. Enteroviruses were isolated in a nasal swab and stools of the second patient. Acute onset of flaccid paralysis with absent motor action potential and normal sensory responses, detected by electrophysiologic studies, are highly suggestive of motor anterior horn cell disease in these infants. A multifactorial setup of immune suppression, stress, and neurotoxic drugs during an acute bronchial asthma attack triggered by a viral disease may render the patient vulnerable to viral invasion of the anterior horn cell with enteroviruses other than poliovirus. The overall experience of 22 patients with this serious complication is reviewed.

Modulatory actions of serotonin on ionic conductances of hippocampal dentate granule cells.

Pressure ejection of serotonin (2 x 10(-4) M) onto dentate granule neurons in vitro produced a short-lasting membrane hyperpolarization associated with a 10-30% decrease in the input resistance. The hyperpolarization magnitude depended on the extracellular K+ concentration but not on the extra or intracellular Ca2+ concentration. It was followed by a depolarization, especially when serotonin was applied onto the perisomatic area of the neuron. The post-spike-train afterhyperpolarization, which represents a Ca2+-dependent K+ conductance, was decreased by serotonin by 10-100% and remained reduced for 2-10 min following the serotonin-induced hyperpolarization. Decreased adaptation of cell firing was also observed following serotonin application. Ca2+ action potentials evoked by intracellular depolarizing current pulses in the presence of the Na+ channel blocker tetrodotoxin and the K+ channel blocker tetraethylammonium were followed by a large afterhyperpolarization, which was markedly reduced for several minutes following serotonin application. The preceding Ca2+ action potential was either unaffected or prolonged. The hyperpolarization occurring in response to localized application of serotonin, and the reduction of the afterhyperpolarization, may represent two different mechanisms of serotonin action, probably mediated by different mechanisms. The slow time course of the late depolarization and the afterhyperpolarization depression represent modulatory effects of serotonin on dentate granule neurons.

Reversed ethanol effects on potassium conductances in aged hippocampal dentate granule neurons.

The effect of low dose (20 mM) ethanol superfusion on the membrane and synaptic properties of dentate granule neurons was studied in hippocampal slices from young-mature (6-8 months) and old (25-29 months) Fischer-344 rats. In young neurons, ethanol hyperpolarized the resting membrane potential (RMP) and prolonged the post-spike train afterhyperpolarization (AHP). By contrast, ethanol depolarized old neurons and decreased their AHPs, in addition to reducing IPSP amplitudes and spike frequency adaptation. These effects can be explained by ethanol-enhancing potassium conductance (gK) in young neurons and diminishing gK in old neurons.

Altered modulatory actions of serotonin on dentate granule cells of aged rats.

The effects of serotonin (5-HT) on dentate granule (DG) neurons in hippocampal slices taken from young mature (6-8 months) and old (25-29 months) rats were compared. Intracellular measurements of membrane potential, cell input resistance and slow postspike afterhyperpolarization did not differ significantly between young and old neurons. Neurons recorded in slices taken from old animals responded with less hyperpolarization to increasing doses of the drug, and their responses were significantly reduced after repeated applications of 5-HT. Serotonin-mediated reduction of the slow afterhyperpolarization in young DG neurons was less prominent or totally absent in the old cells. It is concluded that serotonergic postsynaptic actions are impaired in old age.