In CA1 pyramidal neurons of the hippocampus, calcium-dependent spikes occur in vivo during specific behavioral states and may be enhanced during epileptiform activity. However, the mechanisms that control calcium spike initiation and repolarization are poorly understood. Using dendritic and somatic patch-pipette recordings, we show that calcium spikes are initiated in the apical dendrites of CA1 pyramidal neurons and drive bursts of sodium-dependent action potentials at the soma. Initiation of calcium spikes at the soma was suppressed in part by potassium channels activated by sodium-dependent action potentials. Low-threshold, putative D-type potassium channels [blocked by 100 microM 4-aminopyridine (4-AP) and 0.5-1 microM alpha-dendrotoxin (alpha-DTX)] played a prominent role in setting a high threshold for somatic calcium spikes, thus restricting initiation to the dendrites. DTX- and 4-AP-sensitive channels were activated during sodium-dependent action potentials and mediated a large component of their afterhyperpolarization. Once initiated, repetitive firing of calcium spikes was limited by activation of putative BK-type calcium-activated potassium channels (blocked by 250 microM tetraethylammonium chloride, 70 nM charybdotoxin, or 100 nM iberiotoxin). Thus, the concerted action of calcium- and voltage-activated potassium channels serves to focus spatially and temporally the membrane depolarization and calcium influx generated by calcium spikes during strong, synchronous network excitation.

Sodium channels in the somata and dendrites of hippocampal CA1 pyramidal neurons undergo a form of long-lasting, cumulative inactivation that is involved in regulating back-propagating action potential amplitude and can influence dendritic excitation. Using cell-attached patch-pipette recordings in the somata and apical dendrites of CA1 pyramidal neurons, we determined the properties of slow inactivation on response to trains of brief depolarizations. We find that the amount of slow inactivation gradually increases as a function of distance from the soma. Slow inactivation is also frequency and voltage dependent. Higher frequency depolarizations increase both the amount of slow inactivation and its rate of recovery. Hyperpolarized resting potentials and larger command potentials accelerate recovery from slow inactivation. We compare this form of slow inactivation to that reported in other cell types, using longer depolarizations, and construct a simplified biophysical model to examine the possible gating mechanisms underlying slow inactivation. Our results suggest that sodium channels can enter slow inactivation rapidly from the open state during brief depolarizations or slowly from a fast inactivation state during longer depolarizations. Because of these properties of slow inactivation, sodium channels will modulate neuronal excitability in a way that depends in a complicated manner on the resting potential and previous history of action potential firing.