Adipose vascular endothelial growth factor B is a major regulator of energy metabolism.

Excessive fat accumulation causes obesity and many diseases. Previous study demonstrates VEGFB universal knockout induces obese phenotypes including expansion of white adipose tissue, whitening of brown adipose tissue, increase of fat accumulation and reduction in energy consumption. However, roles of VEGFB in adipose tissues are not clear. In this study, we have generated a mouse model with adipose-specific VEGFB repression using CRISPR/dCas9 system (Vegfb AdipoDown ) and investigated the roles of VEGFB in adipose development and energy metabolism. VEGFB repression induced significant changes in adipose tissue structure and function. Vegfb AdipoDown mice have larger body sizes, larger volume of white adipose tissues than its wild type littermates. Adipose-specific VEGFB repression induced morphological and functional transformation of adipose tissues toward white adipose for energy storage. Metabolic processes are broadly changed in Vegfb AdipoDown adipose tissues including carbohydrate metabolism, lipid metabolism, nucleotide metabolism and amino acid metabolism. We have demonstrated that adipose VEGFB repression can recapitulate most of the phenotypes of the whole body VEGFB knockout mouse. Intriguingly, approximately 50% VEGFB repression in adipose tissues can almost completely mimic the effects of universal Vegfb deletion, suggesting adipose VEGFB is a major regulator of energy metabolism and may be important in prevention and treatment of obesity.

Repression of adipose vascular endothelial growth factor reduces obesity through adipose browning.

Obesity is the result of excessive energy accumulation and is associated with many diseases. We previously reported that universal repression of vascular endothelial growth factor (VEGF) leads to brown-like adipocyte development in white adipose tissues, and that these mice are resistant to obesity (Lu X et al. Endocrinology 153: 3123-3132, 2012). Using an adipose-specific VEGF repression mouse model (aP2-rtTR-krabtg/+/VEGFtetO/tetO), we show that adipose-specific VEGF repression can repeat the previous phenotypes, including adipose browning, increased energy consumption, and reduction in body weight. Expression of brown adipose-associated genes is increased, and white adipose-associated genes are downregulated under VEGF repression. Our study demonstrates that adipose-specific VEGF repression can lead to antiobesity activity through adipose browning and has potential clinical value.