Green tea extract increases adiponectin and PPAR α levels to improve hepatic steatosis.

We postulated that Green tea (GT) improvements in non-alcoholic fatty liver disease (NAFLD) are dependent on adiponectin action in the liver. Male wild-type and adiponectin knockout (adipoKO) mice were induced to obesity for 8 weeks with a high-fat diet and then treated with GT for the last 12 weeks of the experimental protocol. Glucose and insulin tolerance tests, indirect calorimetry, histologic analysis of liver sections, and quantification of mRNA of hepatic genes related to glucose or fatty acid metabolism were performed. In vitro, we assessed the mechanism by which GT catechins act to improve hepatic steatosis by measuring lipid accumulation, and transcript levels of lipogenic genes in HepG2 cells treated with GT in the presence of a PPAR antagonist. Additionally, we performed a PPAR transactivation assay in 293T cells to test if catechins could activate PPARs. Different from wild-type mice, adipoKO animals treated with GT and fed a HFD gain body weight and fat mass, that were associated with a decrease in energy expenditure, were insulin resistant, and had no improvements in hepatic steatosis. Increased lipid levels were associated with no modulation of PPARα levels in the liver of adipoKO mice treated with GT. In vitro, we demonstrated GT catechins act to reduce hepatic steatosis in a PPARα-dependent manner, and especially epigallocatechin and epicatechin can indirectly activate PPARα, although it seems they are not direct ligands. By providing the mechanisms by which GT catechins act in the liver to improve steatosis, our data contribute to the discovery of novel therapeutic agents in the management of NAFLD.

Adipogenic commitment induced by green tea polyphenols remodel adipocytes to a thermogenic phenotype.

The potential contribution of green tea (GT) to the development of thermogenic/beige cells have been scarcely investigated. Here we investigated if the beneficial effects of GT in the induction of thermogenic/beige adipocytes results from an initial cell commitment during adipogenesis. Male C57Bl/6 mice (3 months) were divided into 3 groups: Control (chow diet), Obese (cafeteria diet), and Obese + GT. Mice received GT gavage (500 mg/kg of BW) over 12 weeks (5 days/week), after 4 weeks of diet, totalizing 16 weeks of experimentation. GT treatment increased energy expenditure (EE) in mice fed with cafeteria-diet leading to reduced BW gain, decreased adiposity, reduced inflammation, and improving insulin sensitivity. Those phenotypes were associated with enhanced expression of oxidative, thermogenic and beige genes. GT induced a futile cycle through de novo lipogenesis activating the thermogenic pathway. Induction of beige phenotype occurs autonomously in adipocytes and involves the PPARγ/FGF21/AMPK/UCP1 pathway. Our study identified that metabolic changes caused by GT may involve the temporal expression of PPARγ promoting the induction of thermogenic cells by reprogramming initial steps of adipocyte commitment.