Objective To investigate the Fsp27 gene's influence on the regulation of hepatic stellate cells (HSCs) in vitro.Methods HSCs were isolated from rat liver,the Fsp27 gene was detected in primary HSCs,and activated HSCs were detected by RT-qPCR.After 72 h of Fsp27 transduction through a lentivirus expressing Fsp27 (pLV-Fsp27),the proliferation of HSCs was tested by the CCK-8 test kit,smooth muscle α-actin (α-SMA) expression of HSCs was tested by Western blot,and the fibrosis-related genes were tested by RT-qPCR.Results The HSCs were isolated and cultured successfully,and the Fsp27 genetic difference between primary and activated HSCs was significant (P＜0.01).After coculture for 72 h,Fsp27 inhibited the proliferation and activation of HSCs (P＜0.05).Fsp27 can enhance expression of the MMP-2 gene and down-regulate expression of the TIMP-1 and TGF-β1 gene in activated HSCs (P＜0.05).Conclusion The Fsp27 gene can inhibit the proliferation and activation of HSCs,regulate the expression of fibrosis-related genes,and may play an important role in maintaining the quiescent phenotype of HSCs.

Pulsed electric fields can induce various kinds of biological effects that are essentially different from the normal electric fields, especially the interactions of Nanosecond Pulsed electric field (nsPEF) with cells. The biological effects of different pulsed electric fields on cell membranes, cytoplasmic matrixes, cell growth are introduced in this paper. Based on these effects, some applications of pulsed electric fields in cancer therapy, gene therapy, and delivery of drugs are reviewed in details.
Cell Membrane ; metabolism ; radiation effects ; Cell Physiological Phenomena ; Electromagnetic Fields ; Electrophysiology ; Electroporation ; Genetic Therapy ; methods ; Neoplasms ; therapy

The mechanical properties of tumor cells adhering to extracellular matrix (ECM) are closely related with their invasion and metastesis. In this study we investigated the adhesive mechanical properties between hepatocellular carcinoma cells(HCC) and the collagen I coated surfaces from the viewpoint of cell cycle by coupling cellular biology and cellular mechanics, using micropipette aspiration and cell synchronization technique. The results showed that the synchronous G1 and S phase HCC cells were achieved by use of thymine-2-desoryriboside, colchicines sequential blockage method and double thymine-2-desoryriboside blockage method, and that the synchronous rates of G1 and S phase HCC amounted to 74.09% and 90.39% respectively. Within the ranges of dosing and timing in this study, the adhesion of HCC cells to collagen I displayed dose dependent and time dependent patterns. S phase cells had small force of adhesion to collagen I as compared with G1 phase and controlled cells(P<0.001), which suggested that G1 phase HCC may play an important role in the step of invading interstitial connective tissue in the metastasis pathway of HCC through blood circulation. These are of significance to unveiling the mechanism of HCC metastasis.
Animals ; Cell Adhesion ; Cell Cycle ; Collagen Type I ; metabolism ; Liver Neoplasms, Experimental ; metabolism ; pathology ; Neoplasm Metastasis ; Rats ; Tumor Cells, Cultured