Kinetic parameters of calcium currents in maturing acutely isolated CA1 cells

Developmental changes in hyperexcitability of CA1 pyramidal neurons induced by repeated brief episodes of hypoxia in the rat hippocampal slices

We have previously demonstrated that repeated exposure of adult rat hippocampal slices to brief episodes of hypoxia induce a sustained decrease in the threshold of stimulus-evoked population spike discharges in CA1 pyramidal neurons [O. Godukhin, A. Savin, S. Kalemenev, S. Levin, Neuronal hyperexcitability induced by repeated brief episodes of hypoxia in rat hippocampal slices: involvement of ionotropic glutamate receptors and L-type Ca2+ channels, Neuropharmacology 42 (2002) 459-466, S.V. Kalemenev, A.V. Savin, S.G. Levin, O.V. Godukhin, Long-term potentiation and epileptiform activity induced by brief hypoxic episodes in CA1 area of the rat hippocampal slices. Russ. Physiol. J. 86 (2000) 1676-1681]. In the present study, using the above-mentioned in vitro model of epileptogenesis, we compared the developmental changes in hypoxia-induced hyperexcitability of CA1 neuronal network in the rat hippocampal slices prepared from three age rat groups: postnatal days (P) 13-14 (young), P60-70 (adult) and P600-650 (old). Furthermore, we were interested in learning about an age dependence of the hypoxia-induced changes in the efficacies of glutamatergic transmission and paired-pulse inhibition in CA3-CA1 synapses that may underlie ontogenetic differences in seizure susceptibility in hippocampal network. The principal results of this work are summarized as follow. In comparison with P60-70 hippocampal slices, CA1 pyramidal neurons in P13-14 and P600-650 slices showed intrinsically (without repeated brief hypoxa) an increased propensity to generate epileptiform stimulus-evoked population spike discharges. However, in contrast to adult and old animals, repeated brief episodes of hypoxia are incapable to induce a sustained decrease in the threshold of stimulus-evoked population spike discharges in CA1 pyramidal neurons of hippocampal slices prepared from of P13-14 rats, though they transform paired-pulse inhibition to paired-pulse facilitation and induce hypoxic LTP in CA3-CA1 synapses. The role of some other factors in the developmental changes in hyperexcitability of CA1 pyramidal neurons in response to repeated brief episodes of hypoxia is discussed.

The sensitivity of sodium channels in immature and mature rat CA1 neurones to the local anaesthetics procaine and lidocaine

Sodium currents were recorded in CA1 hippocampal cells from new-born (P(4-10)) and older (P(>22)) rats, using whole-cell voltage clamp techniques. The effects of local anaesthetics (procaine and lidocaine) were studied in both cell populations. Parameters defining steady-state inactivation, removal of inactivation and the affinity of the anaesthetic molecules to the inactivated state were determined at both stages of maturation. Procaine and lidocaine induced a hyperpolarizing shift in steady-state inactivation curves, and slowed the rate of recovery from the inactivated state. Procaine disclosed differences between immature and older cells in what concerns block of the closed (resting) channels, drug affinity and binding to the inactivated state, i.e. the binding rate of procaine was found higher and the affinity lower in younger cells. The characteristics of procaine and lidocaine block on CA1 sodium currents differed in some particular aspects: magnitude of block on resting channels, shift in the voltage dependence and voltage sensitivity of steady-state inactivation, slow recovery from inactivation and use-dependent block.

Sodium channel currents in maturing acutely isolated rat hippocampal CA1 neurones

Sodium channel currents were recorded in excised inside-out patches from immature (P(4-10)) and older (P(20-46)) rat CA1 neurones. Channel conductance was 16.6+/-0.013 pS (P(20-46)) and 19.0+/-0.031 pS (P(4-10)). Opening patterns varied with step voltage and with age. In some patches bursting was apparent at voltages positive to -30 mV. Non-bursting behaviour was more dominant in patches from younger animals. In older animals mean open time (m.o.t.) was best described by two exponentials especially in the older cells; in the immature, there were fewer cases with two exponentials. The time constant of inactivation (tau(h)) estimated in ensemble averages was best described by two exponentials (tau(hf) and tau(hs)) in most patches from older cells. tau(hf) decreased with depolarization; tau(hs) increased in the range -30 to 0 mV. The voltage dependence of tau(hf) in the older cells is identical to that of the single tau(h) found in the younger; the results indicate a dominance of tau(hf) in the younger. Patches from younger cells more often showed one apparent active channel; in such cases, m.o.t. was described by a single exponential. However, in two cases, channels showed bursting behaviour with one of these channels showing a shift between bursting and non-bursting modes. Our findings are consistent with a heterogeneous channel population and with changes in the population in the course of maturation.