Chaperone-mediated autophagy manipulates PGC1α stability and governs energy metabolism under thermal stress
Yixiao Zhuang, Xinyi Zhang, Shuang Zhang, Yunpeng Sun, Hui Wang, Yuxuan Chen, Hanyin Zhang, Peng Zou, Yonghao Feng, Xiaodan Lü, Peijie Chen, Yi Xu, John Li, Huanqing Gao, Jin Li, Xingxing Kong
Abstract
Thermogenic proteins are down-regulated under thermal stress, including PGC1α· However, the molecular mechanisms are not fully understood. Here, we addressed that chaperone-mediated autophagy could regulate the stability of PGC1α under thermal stress. In mice, knockdown of Lamp2a, one of the two components of CMA, in BAT showed increased PGC1α protein and improved metabolic phenotypes. Combining the proteomics of brown adipose tissue (BAT), structure prediction, co-immunoprecipitation- mass spectrum and biochemical assays, we found that PARK7, a Parkinson’s disease causative protein, could sense the temperature changes and interact with LAMP2A and HSC70, respectively, subsequently manipulate the activity of CMA. Knockout of Park7 specific in BAT promoted BAT whitening, leading to impaired insulin sensitivity and energy expenditure at thermoneutrality. Moreover, inhibiting the activity of CMA by knockdown of LAMP2A reversed the effects induced by Park7 ablation. These findings suggest CMA is required for BAT to sustain thermoneutrality-induced whitening through degradation of PGC1α. Thermogenic proteins like PGC1α are downregulated under thermal stress, but the underlying mechanisms are unclear. Here, the authors show that chaperone-mediated autophagy, regulated by PARK7, controls PGC1α stability and BAT function at thermoneutrality.