ABSTRACT
Aim To determine the effect of FATP5 gene silencing on fatty hepatic cell inflammation and to explore its possible mechanism. Methods Five shR-NA sequences were designed and synthesized. The efficient FATP5-shRNA was screened by the siCHECK™ system. After preparing the FATP5-shRNA lentivirus, the FATP5 gene silence hepatic cell lines was obtained by HepG2 cell infection and puromycin screening. The FATP5 silencing efficiency was detected by Western blot. Then the oleic acid induced ROS and MDA generation, TNF-a and IL-6 protein expression and secretion, and NF-kB activation in FATP5 gene silence cells were analyzed by the detection kit, Western blot, nucleo-plasmic separation and reporter gene system. Results In the gene silence cells, FATP5 protein expression was reduced by 90% and the lipid accumulation was also significantly inhibited. Moreover, the FATP5 knockdown could reduce the oleic acid induced ROS and MDA generation, and suppress the NF-kB activation, thereby inhibiting the protein expression and secretion of TNF-a and IL-6. Conclusions FATP5 gene silence inhibits fatty hepatic cell inflammation, and its mechanism may be related to the inhibition of oxidative stress and lipid peroxidation.
ABSTRACT
Aim To investigate the effects of scutellarein on the macrophage foam cell formation and cholesterol efflux, and the underlying mechanism. Methods THP-1 cells were differentiated with PMA, and the cell viability was detected by MTT assays. The effects of scutellarein on the cholesterol efflux and macrophage foam cell formation were evaluated by using NBD-la-beled cholesterol and the cholesterol detection kit. The effects of scutellarein on the activation of PPARγ-LXRα-ABCA1 signaling pathway were determined by molecular docking, ELISA, dual-luciferase reporter and Western blot. The effects of PPARγ knowdown on scutellarein-induced cholesterol efflux and inhibiting macrophage foaming were analyzed by siRNA interference. Results Scutellarein dose-dependently inhibited oxLDL-induced cholesterol accumulation, accelerated cholesterol efflux and significantly increased the protein expression of LXRα and ABCA1. At the same time, scutellarein could bind PPARγ and initiate its downstream LXRa-ABCAl signaling pathway. In addition, gene silencing of PPARγ not only significantly inhibited scutellarein-induced LXRα-ABCA1 signaling pathway and cholesterol efflux, but also reversed the inhibitory effect of scutellarein on macrophage foaming. Conclusions Scutellarein could promote the cholesterol efflux by activating PPARγ and initiating the downstream LXR-ABCA1 signaling pathway, thereby prevent the macrophage foam cell formation.