Journal
CELL
Volume 162, Issue 4, Pages 836-848Publisher
CELL PRESS
DOI: 10.1016/j.cell.2015.07.036
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Funding
- National Institutes of Health (NIH) [R01NS052903, R01MH092273, NS055293, NS074257, R00GM080107]
- National Science Foundation (NSF) Division of Mathematical Science grant [DMS1412877]
- Defense Advanced Research Projects Agency (DARPA) [D12AP00023]
- Northwestern University Flow Cytometry Facility
- NINDS [NS054850]
- Open Cloud Consortium (OCC)
- Gordon and Betty Moore Foundation
- NSF
- Cancer Center Support Grant [NCI CA060553]
- Direct For Mathematical & Physical Scien
- Division Of Mathematical Sciences [1412877] Funding Source: National Science Foundation
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Circadian clocks regulate membrane excitability in master pacemaker neurons to control daily rhythms of sleep and wake. Here, we find that two distinctly timed electrical drives collaborate to impose rhythmicity on Drosophila clock neurons. In the morning, a voltage-independent sodium conductance via the NA/NALCN ion channel depolarizes these neurons. This current is driven by the rhythmic expression of NCA localization factor-1, linking the molecular clock to ion channel function. In the evening, basal potassium currents peak to silence clock neurons. Remarkably, daily antiphase cycles of sodium and potassium currents also drive mouse clock neuron rhythms. Thus, we reveal an evolutionarily ancient strategy for the neural mechanisms that govern daily sleep and wake.
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