PPARγ Acetylation Orchestrates Adipose Plasticity and Metabolic Rhythms

Systemic glucose metabolism and insulin activity oscillate in response to diurnal rhythms and nutrient availability with the necessary involvement of adipose tissue to maintain metabolic homeostasis. However, the adipose‐intrinsic regulatory mechanism remains elusive. Here, the dynamics of PPARγ acetylation in adipose tissue are shown to orchestrate metabolic oscillation in daily rhythms. Acetylation of PPARγ displays a diurnal rhythm in young healthy mice, with the peak at zeitgeber time 0 (ZT0) and the trough at ZT18. This rhythmic pattern is deranged in pathological conditions such as obesity, aging, and circadian disruption. The adipocyte‐specific acetylation‐mimetic mutation of PPARγ K293Q (aKQ) restrains adipose plasticity during calorie restriction and diet‐induced obesity, associated with proteolysis of a core circadian component BMAL1. Consistently, the rhythmicity in glucose tolerance and insulin sensitivity is altered in aKQ and the complementary PPARγ deacetylation‐mimetic K268R/K293R (2KR) mouse models. Furthermore, the PPARγ acetylation‐sensitive downstream target adipsin is revealed as a novel diurnal factor that destabilizes BMAL1 and mediates metabolic rhythms. These findings collectively signify that PPARγ acetylation is a hinge connecting adipose plasticity and metabolic rhythms, the two determinants of metabolic health. The acetylation of PPARγ is dynamically regulated in diurnal rhythms to orchestrate metabolic oscillation and adipose plasticity. The PPARγ acetylation‐responsive downstream target adipsin is identified as a novel diurnal factor to regulate metabolic rhythm through destabilizing BMAL1 in an adipocyte‐intrinsic manner.