Nmu/Nms/Gpr176 Triple-Deficient Mice Show Enhanced Light-Resetting of Circadian Locomotor Activity.

The suprachiasmatic nucleus (SCN) is the master circadian clock in mammals and is properly entrained by environmental light cycle. However, the molecular mechanism(s) determining the magnitude of phase shift by light is still not fully understood. The orphan G-protein-coupled receptor Gpr176 is enriched in the SCN, controls the pace (period) of the circadian rhythm in behavior but is not apparently involved in the light entrainment; Gpr176-/- animals display a shortened circadian period in constant darkness but their phase-resetting responses to light are normal. Here, we performed microarray analysis and identified enhanced mRNA expression of neuromedin U (Nmu) and neuromedin S (Nms) in the SCN of Gpr176-/- mice. By generating C57BL/6J-backcrossed Nmu/Nms/Gpr176 triple knockout mice, we noted that the mutant mice had a greater magnitude of phase shift in response to early subjective night light than wildtype mice, while Nmu/Nms double knockout mice as well as Gpr176 knockout mice are normal in the phase shifts induced by light. At the molecular level, Nmu-/-Nms-/-Gpr176-/- mice had a reduced induction of Per1 and cFos mRNA expression in the SCN by light and mildly upregulated circadian expression of Per2, Prok2, Rgs16, and Rasl11b. These expressional changes may underlie the phenotype of the Nmu/Nms/Gpr176 knockout mice. Our data argue that there is a mechanism requiring Nmu, Nms, and Gpr176 for the proper modulation of light-induced phase shift in mice. Simultaneous modulation of Nmu/Nms/Gpr176 may provide a potential target option for modulating the circadian clock.

Minimal upstream open reading frame of Per2 mediates phase fitness of the circadian clock to day/night physiological body temperature rhythm.

Body temperature in homeothermic animals does not remain constant but displays a regular circadian fluctuation within a physiological range (e.g., 35°C-38.5°C in mice), constituting a fundamental systemic signal to harmonize circadian clock-regulated physiology. Here, we find the minimal upstream open reading frame (uORF) encoded by the 5' UTR of the mammalian core clock gene Per2 and reveal its role as a regulatory module for temperature-dependent circadian clock entrainment. A temperature shift within the physiological range does not affect transcription but instead increases translation of Per2 through its minimal uORF. Genetic ablation of the Per2 minimal uORF and inhibition of phosphoinositide-3-kinase, lying upstream of temperature-dependent Per2 protein synthesis, perturb the entrainment of cells to simulated body temperature cycles. At the organismal level, Per2 minimal uORF mutant skin shows delayed wound healing, indicating that uORF-mediated Per2 modulation is crucial for optimal tissue homeostasis. Combined with transcriptional regulation, Per2 minimal uORF-mediated translation may enhance the fitness of circadian physiology.