Abstract
Hyperexcited states, including depolarization block and depolarized low amplitude membrane oscillations (DLAMOs), have been observed in neurons of the suprachiasmatic nuclei (SCN), the site of the central mammalian circadian (∼24-hour) clock. The causes and consequences of this hyperexcitation have not yet been determined. Here, we explore how individual ionic currents contribute to these hyperexcited states, and how hyperexcitation can then influence molecular circadian timekeeping within SCN neurons. We developed a mathematical model of the electrical activity of SCN neurons, and experimentally verified its prediction that DLAMOs depend on post-synaptic L-type calcium current. The model predicts that hyperexcited states cause high intracellular calcium concentrations, which could trigger transcription of clock genes. The model also predicts that circadian control of certain ionic currents can induce hyperexcited states. Putting it all together into an integrative model, we show how membrane potential and calcium concentration provide a fast feedback that can enhance rhythmicity of the intracellular circadian clock. This work puts forward a novel role for electrical activity in circadian timekeeping, and suggests that hyperexcited states provide a general mechanism for linking membrane electrical dynamics to transcription activation in the nucleus.
Highlights
The conventional theory of neuronal information processing is based on action potential (AP) firing [1,2]
We propose that electrical activity is not just an output of the clock, and part of the core circadian timekeeping mechanism that plays an important role in health and disease
The improved model more closely replicates the biophysical properties of suprachiasmatic nuclei (SCN) neurons as individual APs are followed by an appropriate after hyperpolarization (AHP)
Summary
The conventional theory of neuronal information processing is based on action potential (AP) firing [1,2]. Neurons that receive input that induces large inward currents (hyperexcitation) may display depolarization block, and be unable to fire APs due to voltage– gated sodium channel inactivation. Large inward currents can induce depolarized electrical states with low amplitude membrane oscillations (DLAMOs). Such depolarized states occur in intrinsically photosensitive retinal ganglion cells in the presence of bright light [10]. Spontaneous depolarization block has been reported in cerebellar nuclear neurons [14,15]. These various depolarized states add complexity to the repertoire of neuronal communication
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