Depletion of JunB increases adipocyte thermogenic capacity and ameliorates diet-induced insulin resistance.
Xing ZhangXiaofeng DingChunqing WangQue LeDandan WuAnying SongGuixiang HuangLiping LuoYan LuoXin YangAleyah E GoinsSharina P DesaiChengrui QiuFloyd D SilvaLily Elizabeth FeldmanJianlin ZhouMichael F SpaffordNathan H BoydEric R ProssnitzXuexian O YangQiong A WangMeilian LiuPublished in: Nature metabolism (2024)
The coexistence of brown adipocytes with low and high thermogenic activity is a fundamental feature of brown adipose tissue heterogeneity and plasticity. However, the mechanisms that govern thermogenic adipocyte heterogeneity and its significance in obesity and metabolic disease remain poorly understood. Here we show that in male mice, a population of transcription factor jun-B (JunB)-enriched (JunB + ) adipocytes within the brown adipose tissue exhibits lower thermogenic capacity compared to high-thermogenic adipocytes. The JunB + adipocyte population expands in obesity. Depletion of JunB in adipocytes increases the fraction of adipocytes exhibiting high thermogenic capacity, leading to enhanced basal and cold-induced energy expenditure and protection against diet-induced obesity and insulin resistance. Mechanistically, JunB antagonizes the stimulatory effects of PPARγ coactivator-1α on high-thermogenic adipocyte formation by directly binding to the promoter of oestrogen-related receptor alpha, a PPARγ coactivator-1α downstream effector. Taken together, our study uncovers that JunB shapes thermogenic adipocyte heterogeneity, serving a critical role in maintaining systemic metabolic health.
Keyphrases
- insulin resistance
- adipose tissue
- high fat diet induced
- high fat diet
- polycystic ovary syndrome
- transcription factor
- metabolic syndrome
- skeletal muscle
- single cell
- healthcare
- dna methylation
- mental health
- public health
- gene expression
- dendritic cells
- risk assessment
- physical activity
- mouse model
- climate change
- health information
- diabetic rats
- body mass index
- social media
- weight gain
- dna binding