Rhythmic multiunit neural activity in slices of hamster suprachiasmatic nucleus reflect prior photoperiod

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Rhythmic multiunit neural activity in slices of hamster suprachiasmatic nucleus reflect prior photoperiod

Maciej Mrugala¹, Piotr Zlomanczuk¹^,², Anita Jagota¹, and William J. Schwartz¹

¹ Department of Neurology, University of Massachusetts Medical School, Worcester, Massachusetts 01655; and ² Department of Physiology, Rydygier Medical School, Bydgoszcz, Poland

The suprachiasmatic nucleus (SCN) is an endogenous circadian pacemaker, and SCN neurons exhibit circadian rhythms of electrophysiologicalactivity in vitro. In vivo, the functional state of the pacemakerdepends on changes in day length (photoperiod), but it is notknown if this property persists in SCN tissue isolated in vitro.To address this issue, we prepared brain slices from hamsterspreviously entrained to light-dark (LD) cycles of different photoperiodsand analyzed rhythms of SCN multiunit neuronal activity usingsingle electrodes. Rhythms in SCN slices from hamsters entrainedto 8:16-, 12:12-, and 14:10-h LD cycles were characterized bypeak discharge rates relatively higher during subjective day thansubjective night. The mean duration of high neuronal activitywas photoperiod dependent, compressed in slices from the short(8:16 and 12:12 LD) photoperiods, and decompressed (approximatelydoubled) in slices from the long (14:10 LD) photoperiod. In slicesfrom all photoperiods, the mean phase of onset of high neuronalactivity appeared to be anchored to subjective dawn. Our resultsshow that the electrophysiological activity of the SCN pacemakerdepends on day length, extending previous in vivo data, and demonstratethat this capacity is sustained invitro.

circadian rhythm; photoperiodism

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