Functional characterization of the H-current in SCN neurons in subjective day and night: a whole-cell patch-clamp study in acutely prepared brain slices.

Abstract

Neurons of the rat suprachiasmatic nucleus (SCN) exhibit a circadian rhythm in spontaneous firing rate. In this whole-cell patch-clamp study in slices, we examined the possibility that H-current (IH) contributes to the spontaneous firing rate of SCN neurons. Most of our experiments were performed during the subjective day, because this is the time epoch during which one would expect the largest excitatory effect of IH if it were to fluctuate in a circadian rhythm. Current-clamp experiments showed that blockade of IH by Cs+ (1 mM) did not influence the spontaneous firing rate and resting membrane potential. Voltage-clamp experiments revealed that IH, when activated at the resting membrane potential, is probably too small in magnitude and too slow in activation to make a significant contribution to the spontaneous firing rate. Both results suggest that IH does not significantly contribute to the spontaneous firing of SCN neurons. In addition, we investigated whether the kinetics and voltage dependence of IH were modulated in a circadian manner. However, no substantial day-night differences in IH were found. We conclude that IH, as recorded in whole-cell mode, does not contribute significantly to spontaneous firing in most SCN neurons and that this current, is more likely to be involved in 'rescuing' SCN neurons from large and long-lasting hyperpolarizations by depolarizing the membrane.