Mice held at an environmental photic cycle oscillating at their tau-like period length do not show the high-fat diet-induced obesity that develops under the 24-hour photic cycle.

Circadian disruptions precede high-fat diet (HFD)-induced obesity (DIO). Deviation of the endogenous circadian rhythm period length (tau) from 24 hours correlates with mice inter-strain DIO under the 24-hour light-dark cycle (T-cycle). Additionally, entrainment to a tau-resembling T-cycle attenuates DIO, to some extent, in muted mice. These phenomena suggest that entrainment to a 24-hour T-cycle promotes DIO beyond that expected from the HFD-induced metabolic disruptions. However, the hypothesis that entrainment to a tau-resembling T-cycle attenuates DIO has not been tested in wild-type mice. Therefore, we examined, in newborn female FVB/N mice, whether DIO found under their 'regular' 24-hour T-cycle is attenuated under a T-cycle oscillating at their tau-resembling period of 23.7 h, which is diverted from 24 hours by only 0.3 h. Compared to mice fed a low-fat diet, those fed an HFD under the 24-hour T-cycle showed a disrupted pattern of circadian locomotor activity prior to DIO onset. Both these phenomena were absent under the tau-like T-cycle. DIO developed under the 24-hour T-cycle despite similar caloric intake, and was associated with the lower locomotor activity of HFD-fed mice compared to the other mouse groups. These results demonstrated that DIO is secondary to HFD-induced circadian disruptions that are not harmonized by the strongest Zeitgeber (light-dark cycle) when oscillating at a period that diverts by as little as ca. 0.3-h from tau. More importantly, imposing a light-dark cycle oscillating at a tau-like period length, which enhances entrainment and presumably reinforces endogenous circadian rhythms, prevented HFD-induced circadian disruptions and enabled tighter control of energy homeostasis, as manifested by the absence of DIO, even under ad-lib HFD feeding. These results support the identification of tau-related biomarkers, which may be considered as risk-factors for DIO. Moreover, these findings may promote the development of clock-related pharmaceutical interventions that will reduce the gap between tau and 24 hours, and increase the robustness of the endogenous and entrained circadian rhythms. This will enable reducing DIO, even without caloric restriction or time-restricted feeding.

Long-Lived αMUPA Mice Show Reduced Sexual Dimorphism in Lifespan, and in Energy and Circadian Homeostasis-Related Parameters.

Female αMUPA (alpha murine urokinase-like plasminogen activator) transgenic mice show increased lifespan, reduced body weight and food intake, and high-amplitude circadian rhythms with an endogenous period length (tau) of 24h, versus their wild types (WT) showing a 23.7-h tau. Our goal was to characterize αMUPA and WT male mice, and their in-strain sexual dimorphism, and to further understand the mechanisms underlying αMUPA's longevity. Male αMUPA mice showed increased lifespan, reduced body weight and food intake, and aligned endogenous rhythm with a tau of 24.0h versus a tau <24h in WT. However, no differences were found when intake was corrected for metabolic mass in male αMUPA mice. αMUPA's sexual dimorphism was damped or lacking in all studied traits, while WTs were sexually dimorphic, concluding that αMUPA's transgene overrides sex-dependent mechanisms involved in lifespan and in energy and circadian homeostasis. As enhanced resonance between tau and external circadian cycle correlates with increased lifespan and reduced body weight in other species, including humans, αMUPA's 24-h tau could contribute to their longevity. Focusing future research on the mechanistic interconnections between energy homeostasis, circadian homeostasis, sexual dimorphism, and aging, using αMUPA mice, may reveal mechanisms promoting reduced body weight and increased lifespan.