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Light sets the brain’s daily clock by regional quickening and slowing of the molecular clockworks at dawn and dusk

Suil Kim, Douglas G McMahon

2021DOAJ (DOAJ: Directory of Open Access Journals)13 citationsDOIOpen Access PDF

Abstract

How daily clocks in the brain are set by light to local environmental time and encode the seasons is not fully understood. The suprachiasmatic nucleus (SCN) is a central circadian clock in mammals that orchestrates physiology and behavior in tune with daily and seasonal light cycles. Here, we have found that optogenetically simulated light input to explanted mouse SCN changes the waveform of the molecular clockworks from sinusoids in free-running conditions to highly asymmetrical shapes with accelerated synthetic (rising) phases and extended degradative (falling) phases marking clock advances and delays at simulated dawn and dusk. Daily waveform changes arise under ex vivo entrainment to simulated winter and summer photoperiods, and to non-24 hr periods. Ex vivo SCN imaging further suggests that acute waveform shifts are greatest in the ventrolateral SCN, while period effects are greatest in the dorsomedial SCN. Thus, circadian entrainment is encoded by SCN clock gene waveform changes that arise from spatiotemporally distinct intrinsic responses within the SCN neural network.

Topics & Concepts

Entrainment (biomusicology)Suprachiasmatic nucleusDuskCircadian clockCircadian rhythmWaveformBiological clockPeriod (music)Light effects on circadian rhythmCLOCKBiologyNeuroscienceQuickeningMolecular clockLight CycleRhythmOptogeneticsBacterial circadian rhythmsNeural activityBiological neural networkPhotic StimulationLight intensityPhase response curveDiencephalonDay lengthCircadian rhythm and melatoninSleep and Wakefulness ResearchNeuroscience of respiration and sleep
Light sets the brain’s daily clock by regional quickening and slowing of the molecular clockworks at dawn and dusk | Litcius