Developmental changes in nicotinic receptor mRNAs and responses to nicotine in the suprachiasmatic nucleus and other brain regions.

Our previous studies demonstrated that nicotine induces c-fos expression in the suprachiasmatic nucleus (SCN) of the rat during a narrow developmental window occurring in the perinatal period. We have extended these observations by showing that c-fos cannot be induced in the adult SCN by nicotine even during the subjective night, when phase shifts do occur. In contrast to the SCN, significant induction of c-fos and NGFI-A was observed in the medial habenula and paraventricular nucleus at all circadian times. In the fetal rat SCN we show that NGFI-A and junB are also induced by nicotine, but not c-jun. To investigate whether changes in nicotinic acetylcholine receptor (nAChR) expression in the SCN may underlie this change in sensitivity during the perinatal period, we examined nAChR mRNAs across this developmental period. By Northern analyses, alpha2, alpha3 and alpha4 subunit mRNAs are relatively abundant in the fetal SCN but decline substantially in the adult. alpha7 mRNA increases substantially while beta2 mRNA is relatively abundant throughout development. We also examine expression in the whole mouse brain beginning at embryonic day 11. Many mRNA sizes for nAChR subunits in both the rat and mouse are characterized here for the first time by Northern analyses and some show very large changes in expression across development. In particular, a small 1.4 kb alpha2-related mRNA is highly expressed during early development, perhaps indicating an important novel function for this subunit.

Nicotine and nicotinic receptors in the circadian system.

Considerable data support a role for cholinergic influences on the circadian system. The extent to which these influences are mediated by nicotinic acetylcholine receptors (nAChRs) has been controversial, as have the specific actions of nicotine and acetylcholine in the suprachiasmatic nucleus (SCN) of the hypothalamus. In this article we review the existing literature and present new data supporting an important role for nAChRs in both the developing and adult SCN. Specifically, we present data showing that nicotine is capable of causing phase shifts in the circadian rhythms of rats. Like light and carbachol, nicotine appears to cause phase delays in the early subjective night and phase advances in the late subjective night. In the isolated SCN slice, however, only phase advances are seen, and, surprisingly, nicotine appears to cause the inhibition rather than the excitation of neurons. Among nAChR subunit mRNAs, alpha 7 appears to be the most abundant subunit in the adult SCN, whereas in the perinatal period, the more typical nAChRs with higher affinity for nicotine predominate in the SCN. This developmental change in subunit expression may explain the dramatic sensitivity of the perinatal SCN to nicotine that we have previously observed. The effects of nicotine on the SCN may contribute to alterations caused by nicotine in other physiological systems. These effects might also contribute to the dependence properties of nicotine through influences on arousal.

Thermal effects on neuronal activity in suprachiasmatic nuclei of hibernators and nonhibernators.

The temperature sensitivity of neuronal firing rates in the suprachiasmatic nuclei (SCN) of the hypothalami of rats and ground squirrels was studied in vitro. SCN from euthermic squirrels were studied during the hibernation season (winter) and during the summer. SCN from hibernating squirrels were also studied. Most properties of SCN cells from hibernators and nonhibernators were similar. Warm- and cold-sensitive neurons were observed in all groups, but cold-sensitive neurons were more common in SCN from hibernating squirrels. No evidence for temperature compensation of firing rate was accumulated; no cell was observed to fire below 16.6 degrees C. If the persistence of circadian rhythmicity is a function of action potential-dependent neurotransmission from the SCN, these results suggest that deep hibernation (5-17 degrees C) should be characterized by an absence of circadian fluctuation in temperature. Two possible adaptations for the shallow torpor seen at somewhat higher temperatures were observed in the SCN: 1) a relatively large population of cold-sensitive neurons and 2) a population of neurons with very high activation energies. Activation energy analysis suggested that most of the temperature-sensitive properties of these cells could be explained in terms of the thermal sensitivity of the sodium channel.