Development of two types of calcium channels in cultured mammalian hippocampal neurons.

Calcium influx through voltage-gated membrane channels plays a crucial role in a variety of neuronal processes, including long-term potentiation and epileptogenesis in the mammalian cortex. Recent studies indicate that calcium channels in some cell types are heterogeneous. This heterogeneity has now been shown for calcium channels in mammalian cortical neurons. When dissociated embryonic hippocampal neurons from rat were grown in culture they first had only low voltage-activated, fully inactivating somatic calcium channels. These channels were metabolically stable and conducted calcium better than barium. Appearing later in conjunction with neurite outgrowth and eventually predominating in the dendrites, were high voltage-activated, slowly inactivating calcium channels. These were metabolically labile and more selective to barium than to calcium. Both types of calcium currents were reduced by classical calcium channel antagonists, but the low voltage-activated channels were more strongly blocked by the anticonvulsant drug phenytoin. These findings demonstrate the development and coexistence of two distinct types of calcium channels in mammalian cortical neurons.

Unique properties of NMDA receptors enhance synaptic excitation of radiatum giant cells in rat hippocampus.

In the hippocampus, fast excitatory synaptic transmission of principal projection neurons is mediated by non-NMDA glutamate receptors, whereas NMDA glutamate receptors serve a slower modulatory role. We used the whole-cell patch-clamp technique in adult hippocampal slices to assess the role of NMDA receptors in synaptic excitation of a recently discovered excitatory projection neuron, the CA1 radiatum giant cell (RGC). Glutamatergic synaptic activation, even after blocking non-NMDA receptors, fired an NMDA receptor-dependent burst of action potentials in RGCs. In contrast, the contribution of NMDA receptors to synaptic activation of pyramidal cells (PCs) was minimal. Stimulation of the same synaptic inputs evoked greater than threefold larger EPSCs in RGCs than in PCs. Isolated NMDA receptor-mediated EPSCs were significantly less sensitive to blockade by extracellular Mg(2+) and had slower decay kinetics in RGCs than in PCs. Thus, unique properties of synaptic NMDA receptors underlie enhanced synaptic excitability in a newly discovered excitatory hippocampal projection neuron.

Extracellular calcium modulates persistent sodium current-dependent burst-firing in hippocampal pyramidal neurons.

The generation of high-frequency spike bursts ("complex spikes"), either spontaneously or in response to depolarizing stimuli applied to the soma, is a notable feature in intracellular recordings from hippocampal CA1 pyramidal cells (PCs) in vivo. There is compelling evidence that the bursts are intrinsically generated by summation of large spike afterdepolarizations (ADPs). Using intracellular recordings in adult rat hippocampal slices, we show that intrinsic burst-firing in CA1 PCs is strongly dependent on the extracellular concentration of Ca(2+) ([Ca(2+)](o)). Thus, lowering [Ca(2+)](o) (by equimolar substitution with Mn(2+) or Mg(2+)) induced intrinsic bursting in nonbursters, whereas raising [Ca(2+)](o) suppressed intrinsic bursting in native bursters. The induction of intrinsic bursting by low [Ca(2+)](o) was associated with enlargement of the spike ADP. Low [Ca(2+)](o)-induced intrinsic bursts and their underlying ADPs were suppressed by drugs that reduce the persistent Na(+) current (I(NaP)), indicating that this current mediates the slow burst depolarization. Blocking Ca(2+)-activated K(+) currents with extracellular Ni(2+) or intracellular chelation of Ca(2+) did not induce intrinsic bursting. This and other evidence suggest that lowering [Ca(2+)](o) may induce intrinsic bursting by augmenting I(NaP). Because repetitive neuronal activity in the hippocampus is associated with marked decreases in [Ca(2+)](o), the regulation of intrinsic bursting by extracellular Ca(2+) may provide a mechanism for preferential recruitment of this firing mode during certain forms of hippocampal activation.

Presynaptic and postsynaptic actions of halothane at glutamatergic synapses in the mouse hippocampus.

Whole-cell patch-clamp recordings in adult mouse hippocampal slices were used to test the mechanism by which the volatile anesthetic halothane inhibits glutamate receptor-mediated synaptic transmission. Non-N-methyl-D-aspartate (nonNMDA) and NMDA receptor-mediated currents in CA1 pyramidal cells were pharmacologically isolated by bath application of D,L-2-amino-5-phosphonovaleric acid (APV; 100 microM) or 6-cyano-7-nitro-quinoxaline-2,3-dione (CNQX; 5 microM), respectively. Halothane blocked both nonNMDA and NMDA receptor-mediated excitatory postsynaptic currents (EPSCs) to a similar extent (IC50 values of 0.66 and 0.57 mM, respectively). Partial blockade of the EPSCs by lowering the extracellular concentration of calcium ([Ca2+]o), but not by application of CNQX (1 microM), was accompanied by an increase in paired-pulse facilitation (PPF). Halothane-induced blockade of the EPSCs also was associated with an increase in PPF. The effects of halothane on alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA) and NMDA receptor-mediated currents induced by agonist iontophoresis, were compared. AMPA-induced currents were blocked with an IC50 of 1.7 mM. NMDA-induced currents were significantly less sensitive to halothane (IC50 of 5.9 mM). The effect of halothane on iontophoretic AMPA dose-response curves was tested. Halothane suppressed the maximal response to AMPA without affecting its EC50, suggesting a noncompetitive mechanism of inhibition. All effects of halothane were reversible upon termination of the exposure to the drug. These data suggest that halothane blocks central glutamatergic synaptic transmission by presynaptically inhibiting glutamate release and postsynaptically blocking the AMPA subtype of glutamate receptors.

A novel technique for micro-dissection of neuronal processes.

A simple system for cutting dendrites of single neurons without damaging the viability of the cell is described. The system utilizes a rapidly vibrating (100 Hz) micropipette (<1 microm tip diameter), which is dragged under direct visual control across the dendrite of a selected neuron. We used this system in a thin slice preparation to dissect the apical dendrites of rat hippocampal CA1 pyramidal cells. We then used the patch-clamp technique in the whole-cell configuration to record from the isolated somata of these cells and to inject a dye into them. Both a functional and an anatomical disconnection of the dendrites from their somata were verified.

The action of chlorpromazine at an isolated cholinergic synapse.

The effects of chlorpromazine (CPZ) on cholinergic transmission were studied at the isolated neuromuscular synapse of the frog. It was found that 5 x 10(-6) M CPZ produces the following effects: (1) a reduction in end-plate potential amplitude, mainly through inhibition of transmitter release at presynaptic nerve terminals; (2) a reduction in amplitude of focally recorded end-plate current without detectable change in nerve terminal potential: (3) a decrease in amplitude of miniature end-plate potentials; and (4) an increase in the frequency of spontaneous liberation of transmitter both in normal and calcium-free Ringer's solution. It is concluded that CPZ inhibits cholinergic transmission by a complex action on presynaptic and postsynaptic elements. The relation of these findings to central cholinergic activities of CPZ is discussed.

Frequency-dependent effects of phenytoin on frog junctional transmission: presynaptic mechanisms.

The action of the antiepileptic drug, phenytoin, on junctional transmission at various frequencies of synaptic activation was studied in frog nerve-muscle preparation. Intracellular recordings were made from muscle end-plates, and extracellular focal and subsendothelial recordings were obtained from motor nerve terminals and their parent axons, respectively. When the motor nerve was stimulated at 100-200 Hz, exposure to the drug (0.1-0.3 mM) induced intermittent failures of junctional transmission which appeared faster as the rate of stimulation was increased. At these and at lower stimulation frequencies (30-50 Hz), in which failures of transmission occurred only rarely, phenytoin markedly limited the buildup of end-plate potential amplitude during the period of repetitive nerve stimulation (tetanic potentiation). Several lines of evidence suggest that both drug effects are consequent to a frequency-dependent depression of the action potential at motor axons and terminals, which could lead to an intermittent conduction block at the higher rates of stimulation. The selective action of phenytoin on high frequency synaptic transmission may contribute to the specificity shown by this drug in suppressing epileptic seizures while sparing neuronal activity.

Suppression by phenytoin of convulsant-induced afterdischarges at presynaptic nerve terminals.

The mechanisms underlying the induction of afterdischarges at presynaptic nerve terminals by convulsant aminopyridines and their suppression by the anticonvulsant drug phenytoin were studied at the frog neuromuscular preparation. Addition of aminopyridine to the perfusing solution induced the appearance of afterdischarges in motor nerve fibres following their primary response to a single nerve stimulus. The afterdischarges seemed to originate at or near the nerve terminals and to propagate both antidromically and orthodromically. The latter resulted in repetitive activation of the neuromuscular synapse. Focal recordings of nerve terminal potentials suggested that aminopyridines may induce afterdischarges by slowing spike repolarization and thereby producing a prolonged depolarization of nerve terminals. Phenytoin suppressed the aminopyridine-induced afterdischarges and the resultant repetitive excitation of the postsynaptic muscle fibres. This effect of phenytoin was associated with a depression of the action potential at the motor nerve terminals but not at their parent axons. These results single the presynaptic nerve terminals as preferential sites for convulsant and anticonvulsant actions.

Phenytoin reduces frequency potentiation of synaptic potentials at the frog neuromuscular junction.

The action of the commonly used antiepileptic drug phenytoin on frequency potentials was studied at the frog neuromuscular junction. Whereas the drug, at concentrations of 0.1-0.3 mM, had only a slight effect on EPPs evoked by nerve stimulation at a frequency of 0.5 Hz, it strongly suppressed their potentiation during tetanic nerve stimulation at 30 Hz. The post-tetanic potentiation of the EPPs was also reduced by the drug. These effects occurred without a blockade of invasion of the nerve impulse into the presynaptic terminal during the tetanus, and thus indicate a specific frequency-dependent depressant action of the drug on neurally-evoked transmitter release.

Phenytoin and transmitter release at the neuromuscular junction of the frog.

The effects of phenytoin (diphenylhydantoin, DPH) on transmitter release were studied at the frog neuromuscular junction. It was found that in Ringer's solutions containing a normal concentration of Ca2+ ions, DPH (1-2 X 10(-4) M) depresses neurally evoked transmitter release, whereas in Ca2+-deficient Ringer's solutions it produces an increase in evoked release. Spontaneous transmitter liberation is augmented by DPH under all the above conditions. An abrupt disappearance of the evoked response occasionally occured with stimulation at 0.5 Hz, but a normal response could be elicited by a second stimulus delivered shortly after the first. At 100-200 Hz, DPH regularly induced a partial block in synaptic transmission. In 8 mM MgCl2, this phenomenon appeared at 50 Hz and developed into a total neuromuscular blockade.

Effects of anticonvulsants on spontaneous epileptiform activity which develops in the absence of chemical synaptic transmission in hippocampal slices.

Spontaneous epileptiform activity (SEA) develops in area CA1 of hippocampal slices, when the Ca2+ concentration in the perfusate is lowered to 0.2 mM, at which level evoked chemical synaptic transmission is blocked. We investigated the effects of different anticonvulsants on this autonomous activity, in order to determine whether the antiepileptic effect can be ascribed to an influence on neuronal excitability. Carbamazepine was the most effective to block SEA at concentrations of 1-15 microM. Phenobarbital and phenytoin depressed SEA at concentrations of 25 microM. Valproate was effective at concentrations of 2-5 mM. Midazolam, a water-soluble benzo-diazepine agonist and the N-methyl-D-aspartate antagonists, DL-alpha-aminoadipic acid and 2-amino-7-phosphonoheptanoic acid were ineffective in blocking SEA suggesting that they exert their antiepileptic action by interference with synaptic mechanisms.

Frequency-dependent action of phenytoin on lamprey spinal axons.

The effect of the antiepileptic drug phenytoin (diphenylhydantoin, DPH) was tested on the conduction of intracellularly recorded action potentials in lamprey giant reticulospinal axons. When the isolated spinal cord was exposed to 80 microM DPH for up to 4 h, no significant effect was seen on the amplitude or conduction velocity of the action potential, although the maximum rate of rise was reduced from 247.8 to 149.6 V/s after 1 h. However, at higher stimulus frequencies both the amplitude and conduction velocity of the action potential were reduced progressively during a 500 stimulus train. The reduction was greater the higher the stimulus frequency, and was reversed upon return to 1 Hz stimulation. At frequencies greater than 40 Hz an all-or-none block developed. This also developed sooner the higher the stimulus frequency. Axons bathed in drug-free solutions did not show this effect at stimulus frequencies up to 100 Hz. Similar effects were seen in 16 microM DPH when the spinal cord was exposed to the drug overnight. This is close to the human therapeutic CSF level. The frequency-dependent depression of the action potential was greatly potentiated by increasing the extracellular potassium concentration from 2.1 to 5 mM. Under these conditions the axons rapidly developed block at stimulus frequencies as low as 2 Hz, and this was not reversible during a 5 h wash. In the absence of DPH, 5 mM potassium produced a 4-5 mV depolarization, but did not induce a frequency-dependent block. This effect of potassium may be important to the therapeutic effect of DPH because during epileptiform activity the extracellular K+ increases several fold.

Phenytoin suppresses spontaneous ectopic discharge in rat sciatic nerve neuromas.

Afferent fibers ending in nerve-end neuromas generate spontaneous impulse discharge which has been implicated as a cause of paraesthesias and pain following peripheral nerve injury in man. We now show in rats that the anticonvulsant drug phenytoin (PT), applied systemically or topically onto desheathed neuromas, suppresses the generation of neuroma discharge without blocking impulse conduction. The effect is dose-dependent and reversible upon drug washout. Since PT is known to provide effective pain relief in some kinds of neuralgia, the data suggest that the clinical analgesic action of PT in these conditions may, at least in part, involve a direct suppression of ectopic impulses generated in the region of the nerve damage.

Acetylcholine modulates two types of presynaptic potassium channels in vertebrate motor nerve terminals.

Using external microelectrodes to record local circuit currents from preterminal motor nerve axons, two distinct populations of potassium (K) channels were identified in frog motor nerve terminals: delayed rectifier and calcium-activated K channels. Both are sensitive to the transmitter acetylcholine (ACh) which, when externally applied, blocks them in concentrations in the millimolar range. As this action also is not prevented by nicotinic and muscarinic antagonists, it probably is not mediated by classical cholinergic receptors. This cholinergic sensitivity of presynaptic K channels may account for the hyperexcitability of motor nerve terminals manifested when ACh accumulates in the junctional cleft.

Activity-dependent depression of nerve action potential by phenytoin.

The action of the anticonvulsant drug phenytoin was investigated on the responsiveness of isolated amphibian and human nerves to repetitive stimulation. At low frequencies of stimulation (0.5-25 Hz) the drug (at a concentration of 0.1 mM) had no notable effect on the compound nerve action potential. By contrast, at higher rates of stimulation (50-300 Hz), it produced a progressive decrease in amplitude and integral of the compound action potential. This effect was positively correlated with the frequency of nerve activation and was markedly enhanced by elevating the extracellular K+ concentration. Thus, phenytoin induces a use- and frequency-dependent depression of axon conduction, which may contribute to its preferential suppression of the spread of high-frequency seizure discharge in the brain.

Mechanism of action of volatile anesthetics: effects of halothane on glutamate receptors in vitro.

(1) We have investigated the effect of halothane on glutamate receptor-mediated excitation in pyramidal cells and interneurons of the hippocampal CA1 area. (2) Halothane similarly inhibited non-NMDA and NMDA receptor-mediated excitatory postsynaptic currents in both cell types at low concentrations but preferentially blocked responses to exogenously applied AMPA at higher concentrations. (3) Synaptically but not directly evoked action potentials in interneurons were inhibited by halothane.

Plasticity of voltage-gated ion channels in pyramidal cell dendrites.

Dendrites of pyramidal neurons integrate multiple synaptic inputs and transform them into axonal action potential output. This fundamental process is controlled by a variety of dendritic channels. The properties of dendritic ion channels are not static but can be modified by neuronal activity. Activity-dependent changes in the density, localization, or biophysical properties of dendritic voltage-gated channels can persistently alter the integration of synaptic inputs. Furthermore, dendritic intrinsic plasticity can induce neuronal output mode transitions (e.g. from regular spiking to burst firing). Recent advances in the field reviewed here represent an important step toward uncovering the principles of neuronal input/output transformations in response to various patterns of brain activity.