Plasticity manifolds and ion-channel degeneracy govern circadian oscillations of neuronal intrinsic properties in the suprachiasmatic nucleus

Abstract

ABSTRACTMotivation and methodsThe suprachiasmatic nucleus (SCN) is the master circadian clock of the mammalian brain that sustains a neural code for circadian time through oscillations in the firing rate of constituent neurons. These cell-autonomous oscillations in intrinsic properties are mediated by plasticity in a subset of ion-channels expressed in SCN neurons and are maintained despite widespread neuron-to-neuron variability in ion channel expression profiles. How do SCN neurons undergo stable transitions and maintain precision in intrinsic properties spanning the day-night cycle if several ion channels change concomitantly in a heterogeneous neuronal population? Here, we address this important question using unbiased stochastic searches on the parametric and the plasticity spaces using populations of SCN models, each explored for multiple valid transitions spanning one complete circadian cycle (day-to-night followed by night-to-day transitions).ResultsOur analyses provided three fundamental insights about the impact of heterogeneities on the circadian oscillations of SCN intrinsic properties. First, SCN neurons could achieve signature electrophysiological characteristics (day-like or night-like) despite pronounced heterogeneity in ion channel conductances, with weak pairwise correlations between their conductance values. This ion-channel degeneracy precluded the need to maintain precise ionchannel expression profiles for achieving characteristic electrophysiological signatures of SCN neurons, thus allowing for parametric heterogeneities despite functional precision. Second, it was not essential that specific conductances had to change by precise values for obtaining valid day-to-night or night-to-day transitions. This plasticity degeneracy, the ability of disparate combinations of ion-channel plasticity to yield the same functional transition, confers flexibility on individual neurons to take one of several routes to achieve valid transitions. Finally, we performed nonlinear dimensionality reduction analyses on the valid plasticity spaces and found the manifestation of a low-dimensional plasticity manifold in day-to-night transitions, but not in night-to-day transitions. These observations demonstrated that the concomitant changes in multiple ion channels are not arbitrary, but follow a structured plasticity manifold that provides a substrate for stability in achieving stable circadian oscillations.ImplicationsOur analyses unveil an elegant substrate, involving a synthesis of the degeneracy and the plasticity manifold frameworks, to effectuate stable circadian oscillations in a heterogeneous population of SCN neurons. Within this framework, the ability of multiple ion channels to change concomitantly provides robustness and flexibility to effectively achieve precise transitions despite widespread heterogeneities in ion-channel expression and plasticity.