Shifting the feeding of mice to the rest phase creates metabolic alterations, which, on their own, shift the peripheral circadian clocks by 12 hours

Abstract: The molecular mechanisms underlying the events through which alterations in diurnal activities impinge on peripheral circadian clocks (PCCs), and reciprocally how the PCCs affect metabolism, thereby generating pathologies, are still poorly understood. Here, we deciphered how switching the diurnal feeding from the active to the rest phase, i.e., restricted feeding (RF), immediately creates a hypoinsulinemia during the active phase, which initiates a metabolic reprogramming by increasing FFA and glucagon levels.… Show more

“…S1 C and D and In RF Mice, the Expression of PCC-Controlled Output Genes Is Shifted by 12 h with Respect to the Diurnal Active and Rest Phases Controlled by the Central SCN CC), we explored the molecular basis of its maintenance and found that the active phase RF hypoinsulinemia is a recurring event during long-term RF regime ( Fig. 1A and In RF Mice, the Expression of PCC-Controlled Output Genes Is Shifted by 12 h with Respect to the Diurnal Active and Rest Phases Controlled by the Central SCN CC), which, as expected (5,11), leads to an increase in GSK3β-mediated phosphorylated RevErbα (pRevErbα) level at "Zeitgeber" (ZT) 0 ( Fig. 1 E and F and Fig.…”

“…We recently elucidated (5) how the RF-induced decrease in insulin (INS) blood level during the active phase triggers an aberrant activation of nuclear receptor subfamily 1, group D, member 1 (Nr1d1/RevErbα) through phosphorylation by active glycogen synthase kinase 3β (GSK3β; Fig. 1F) (5). This RevErbα phosphorylation prevents its proteasome degradation (10) and is crucial for the repression of RORα/RevErbα response element (RORE)-DNA binding sequence (DBS)-containing genes (e.g., Bmal1, Cry1), which is a critical event in the initiation of the RF-induced shift of PCCs (5).…”

“…1F) (5). This RevErbα phosphorylation prevents its proteasome degradation (10) and is crucial for the repression of RORα/RevErbα response element (RORE)-DNA binding sequence (DBS)-containing genes (e.g., Bmal1, Cry1), which is a critical event in the initiation of the RF-induced shift of PCCs (5).…”

“…However, the molecular mechanisms that confer to the SCN CC an insensitivity to RF, as well as the consequences of the misalignment between the PCCs and the master SCN CC on homeostasis, are still largely unexplored (3,6). In the present study, we elucidated, at the molecular level, how the SCN CC is protected against the RF-induced shift of PCCs, which is induced by metabolic alterations (5), and how the misalignment between the master SCN CC and the PCCs generates a metabolic syndrome-like pathology, similar to that exhibited by shift workers (3, 6-9).…”

“…As the SCN CC is not affected during RF (4), this situation leads to a misalignment between the diurnal active and rest phases and the expression of PCC components. We recently unveiled in mice the origin and the identity of the molecular signals through which RF leads to this 12-h shift in the expression of PCC components (5). However, the molecular mechanisms that confer to the SCN CC an insensitivity to RF, as well as the consequences of the misalignment between the PCCs and the master SCN CC on homeostasis, are still largely unexplored (3,6).…”

Shifting eating to the circadian rest phase misaligns the peripheral clocks with the master SCN clock and leads to a metabolic syndrome

“…S1 C and D and In RF Mice, the Expression of PCC-Controlled Output Genes Is Shifted by 12 h with Respect to the Diurnal Active and Rest Phases Controlled by the Central SCN CC), we explored the molecular basis of its maintenance and found that the active phase RF hypoinsulinemia is a recurring event during long-term RF regime ( Fig. 1A and In RF Mice, the Expression of PCC-Controlled Output Genes Is Shifted by 12 h with Respect to the Diurnal Active and Rest Phases Controlled by the Central SCN CC), which, as expected (5,11), leads to an increase in GSK3β-mediated phosphorylated RevErbα (pRevErbα) level at "Zeitgeber" (ZT) 0 ( Fig. 1 E and F and Fig.…”

“…We recently elucidated (5) how the RF-induced decrease in insulin (INS) blood level during the active phase triggers an aberrant activation of nuclear receptor subfamily 1, group D, member 1 (Nr1d1/RevErbα) through phosphorylation by active glycogen synthase kinase 3β (GSK3β; Fig. 1F) (5). This RevErbα phosphorylation prevents its proteasome degradation (10) and is crucial for the repression of RORα/RevErbα response element (RORE)-DNA binding sequence (DBS)-containing genes (e.g., Bmal1, Cry1), which is a critical event in the initiation of the RF-induced shift of PCCs (5).…”

“…1F) (5). This RevErbα phosphorylation prevents its proteasome degradation (10) and is crucial for the repression of RORα/RevErbα response element (RORE)-DNA binding sequence (DBS)-containing genes (e.g., Bmal1, Cry1), which is a critical event in the initiation of the RF-induced shift of PCCs (5).…”

“…However, the molecular mechanisms that confer to the SCN CC an insensitivity to RF, as well as the consequences of the misalignment between the PCCs and the master SCN CC on homeostasis, are still largely unexplored (3,6). In the present study, we elucidated, at the molecular level, how the SCN CC is protected against the RF-induced shift of PCCs, which is induced by metabolic alterations (5), and how the misalignment between the master SCN CC and the PCCs generates a metabolic syndrome-like pathology, similar to that exhibited by shift workers (3, 6-9).…”

“…As the SCN CC is not affected during RF (4), this situation leads to a misalignment between the diurnal active and rest phases and the expression of PCC components. We recently unveiled in mice the origin and the identity of the molecular signals through which RF leads to this 12-h shift in the expression of PCC components (5). However, the molecular mechanisms that confer to the SCN CC an insensitivity to RF, as well as the consequences of the misalignment between the PCCs and the master SCN CC on homeostasis, are still largely unexplored (3,6).…”

Shifting eating to the circadian rest phase misaligns the peripheral clocks with the master SCN clock and leads to a metabolic syndrome

Special Issue: Circadian Rhythms and Age Related Disorder: How Does Aging Impact Mammalian Circadian Organization?

Circadian Rhythm Effects on the Molecular Regulation of Physiological Systems