Gab2 deficiency suppresses high-fat diet-induced obesity by reducing adipose tissue inflammation and increasing brown adipose function in mice.
Xinhui WangYinan ZhaoDekun ZhouYingpu TianGensheng FengZhong-Xian LuPublished in: Cell death & disease (2021)
Obesity is caused by a long-term imbalance between energy intake and consumption and is regulated by multiple signals. This study investigated the effect of signaling scaffolding protein Gab2 on obesity and its relevant regulation mechanism. Gab2 knockout (KO) and wild-type (WT) mice were fed with a standard diet (SD) or high-fat diet (HFD) for 12 weeks. The results showed that the a high-fat diet-induced Gab2 expression in adipose tissues, but deletion of Gab2 attenuated weight gain and improved glucose tolerance in mice fed with a high-fat diet. White adipose tissue and systemic inflammations were reduced in HFD-fed Gab2 deficiency mice. Gab2 deficiency increased the expression of Ucp1 and other thermogenic genes in brown adipose tissue. Furthermore, the regulation of Gab2 on the mature differentiation and function of adipocytes was investigated in vitro using primary or immortalized brown preadipocytes. The expression of brown fat-selective genes was found to be elevated in differentiated adipocytes without Gab2. The mechanism of Gab2 regulating Ucp1 expression in brown adipocytes involved with its downstream PI3K (p85)-Akt-FoxO1 signaling pathway. Our research suggests that deletion of Gab2 suppresses diet-induced obesity by multiple pathways and Gab2 may be a novel therapeutic target for the treatment of obesity and associated complications.
Keyphrases
- high fat diet induced
- insulin resistance
- high fat diet
- adipose tissue
- signaling pathway
- metabolic syndrome
- poor prognosis
- skeletal muscle
- type diabetes
- weight gain
- binding protein
- body mass index
- wild type
- long non coding rna
- epithelial mesenchymal transition
- physical activity
- genome wide
- high resolution
- dna methylation
- small molecule
- pi k akt
- risk factors
- transcription factor
- atomic force microscopy
- high speed