Abstract
The master pacemaker in the suprachiasmatic nucleus (SCN) controls daily rhythms of behavior in mammals. C57BL/6J mice lacking Period1 (Per1−/−) are an anomaly because their SCN molecular rhythm is weak or absent in vitro even though their locomotor activity rhythm is robust. To resolve the contradiction between the in vitro and in vivo circadian phenotypes of Per1−/− mice, we measured the multi-unit activity (MUA) rhythm of the SCN neuronal population in freely-behaving mice. We found that in vivo Per1−/− SCN have high-amplitude MUA rhythms, demonstrating that the ensemble of neurons is driving robust locomotor activity in Per1−/− mice. Since the Per1−/− SCN electrical activity rhythm is indistinguishable from wild-types, in vivo physiological factors or coupling of the SCN to a known or unidentified circadian clock(s) may compensate for weak endogenous molecular rhythms in Per1−/− SCN. Consistent with the behavioral light responsiveness of Per1 −/− mice, in vivo MUA rhythms in Per1 −/− SCN exhibited large phase shifts in response to light. Since the acute response of the MUA rhythm to light in Per1−/− SCN is equivalent to wild-types, an unknown mechanism mediates enhanced light responsiveness of Per1−/− mice. Thus, Per1−/− mice are a unique model for investigating the component(s) of the in vivo environment that confers robust rhythmicity to the SCN as well as a novel mechanism of enhanced light responsiveness.
Highlights
The suprachiasmatic nucleus (SCN) is the master pacemaker in mammals that controls circadian rhythms in locomotor activity
We first measured the rhythm from a large, diverse population of SCN neurons by differential recording from two bipolar electrodes, one electrode implanted in the ventral region and the other electrode in the dorsal region of wild-type and Per12/2 SCN
C57BL/6J Per12/2 mice are unique because their circadian behavioral phenotype, which is indistinguishable from wild-types, is not predicted from their arrhythmic in vitro SCN phenotype
Summary
The suprachiasmatic nucleus (SCN) is the master pacemaker in mammals that controls circadian rhythms in locomotor activity. In vitro monitoring of rhythms of neural activity and circadian gene expression has demonstrated that the periods of rhythmic activity in SCN explants approximate the respective behavioral periodicities of wild-type and mutant rodents [8,9,10,11,12,13]. Together these studies have contributed to the conceptualization that SCN neurons, each having a cell-autonomous rhythm governed by molecular feedback loops, are coupled to each other resulting in an integrated period that drives the periodicity of the locomotor activity rhythm. In C57BL/6J mice lacking the circadian gene, Period (Per12/2 mice), circadian gene promoter activity
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