Overexpression of Protein Phosphatase 2 Regulatory Subunit B"Alpha Promotes Glycolysis by Regulating Hexokinase 1 in Hepatocellular Carcinoma.

Objective: To investigate the regulatory relationship of Protein Phosphatase 2 Regulatory Subunit B"Alpha ( PPP2R3A) and hexokinase 1 ( HK1) in glycolysis of hepatocellular carcinoma (HCC). Methods: In HepG2 and Huh7 cells, PPP2R3A expression was silenced by small interfering RNA (siRNA) and overexpression by plasmid transfection. The PPP2R3A-related genes were searched by RNA sequencing. Glycolysis levels were measured by glucose uptake and lactate production. QRT-PCR, ELISA, western blot and immunofluorescence assay were performed to detect the changes of PPP2R3A and HK1. Cell proliferation, migration and invasion assay were used to study the roles of HK1 regulation by PPP2R3A. Results: RNA sequencing data revealed that PPP2R3A siRNA significantly downregulated the expression of HK1. PPP2R3A gene overexpression promotes, while gene silencing suppresses, the level of HK1 and glycolysis in HCC cells. In HCC tissue samples, PPP2R3A and HK1 were colocalized in the cytoplasm, and their expression showed a positive correlation. HK1 inhibition abrogated the promotion of glycolysis, proliferation, migration and invasion by PPP2R3A overexpression in liver cancer cells. Conclusion: Our findings showed the correlation of PPP2R3A and HK1 in the glycolysis of HCC, which reveals a new mechanism for the oncogenic roles of PPP2R3A in cancer.

Mechanical properties of hepatocellular carcinoma cells.

AIM: To study the viscoelastic properties of human hepatocytes and hepatocellular carcinoma (HCC) cells under cytoskeletal perturbation, and to further to study the viscoelastic properties and the adhesive properties of mouse hepatoma cells (HTC) in different cell cycle. METHODS: Micropipette aspiration technique was adopted to measure viscoelastic coefficients and adhesion force to collagen coated surface of the cells. Three kinds of cytoskeleton perturbing agents, colchicines (Col), cytochalasin D (CD) and vinblastine (VBL), were used to treat HCC cells and hepatocytes and the effects of these treatment on cell viscoelastic coefficients were investigated. The experimental results were analyzed with a three-element standard linear solid. Further, the viscoelastic properties of HTC cells and the adhesion force of different cycle HTC cells were also investigated. The synchronous G(1) and S phase cells were achieved through thymine-2-desoryriboside and colchicines sequential blockage method and thymine-2-desoryriboside blockage method respectively. RESULTS: The elastic coefficients, but not viscous coefficient of HCC cells (K(1)=103.6+/-12.6N.m(-2), K(2)=42.5 +/ 10.4N.m(-2), mu=4.5 +/- 1.9Pa.s), were significantly higher than the corresponding value for hepatocytes (K(1)=87.5 +/- 12.1N.m(-2), K(2)=33.3+/-10.3N.m(-2), mu=5.9+/-3.0Pa.s, P<0.01). Upon treatment with CD, the viscoelastic coefficients of both hepatocytes and HCC cells decreased consistently, with magnitudes for the decrease in elastic coefficients of HCC cells (K(1): 68.7 N.m(-2) to 81.7N.m(-2), 66.3% to 78.9%; K(2): 34.5N.m(-2) to 37.1N.m(-2), 81.2% to 87.3%, P<0.001) larger than those for normal hepatocytes (K(1): 42.6N.m(-2) to 49.8N.m(-2), 48.7% to 56.9%; K(2): 17.2N.m(-2) to 20.4N.m(-2), 51.7% to 61.3%, P<0.001). There was a little decrease in the viscous coefficient of HCC cells (2.0 to 3.4Pa.s, 44.4 to 75.6%, P<0.001) than that for hepatocytes (3.0 to 3.9Pa.s, 50.8 to 66.1% P<0.001). Upon treatment with Col and VBL, the elastic coefficients of hepatocytes generally increased or tended to increase while those of HCC cells decreased. HTC cells with 72.1% of G(1) phase and 98.9% of S phase were achieved and high K(1), K(2) value and low mu value were the general characteristics of HTC cells. G(1) phase cells had higher K(1) value and lower mu value than S phase cells had, and G(1) phase HTC cells had stronger adhesive forces ((275.9 +/- 232.8) x 10(-10)N) than S phase cells ((161.2 +/- 120.4) x 10(-10)N, P<0.001). CONCLUSION: The difference in both the pattern and the magnitude of the effect of cytoskeletal perturbing agent on the viscoelastic properties between HCC cells and hepatocytes may reflect differences in the state of the cytoskeleton structure and function and in the sensitivity to perturbing agent treatment between these two types of cells. Change in the viscoelastic properties of cancer cells may affect significantly tumor cell invasion and metastasis as well as interactions between tumor cells and their micro-mechanical environments.

Adhesive properties of hepatoma cells to collagen IV coated surfaces.

OBJECTIVES: To quantitatively study the adhesive properties of hepatoma cells to collagen IV coated artificial basement membrane and to investigate the relevance of cell adhesive forces to the concentration of collagen IV. METHODS: Synchronous G1 and S phase cells were achieved using thymine-2-desoxyriboside and cochicine sequential blockage method and double thymine-2-desoxyriboside blockage method respectively. The adhesive forces of hepatoma cells were investigated by micropipette aspiration technique. RESULTS: The adhesive forces of hepatoma cells to artificial basement membrane were (107.78+/-65.44)x10(-10)N, (182.60+/-107.88)x10(-10)N, (298.91+/-144.13)x10(-10)N when the concentration of the membrane coated by 1, 2, 5 microg/ml collagen IV respectively (P<0.001). The adhesive forces of G1 and S phases hepatoma cells to artificial basement membrane were (275.86+/-232.80)x10(-10)N and (161.16+/-120.40)x10(-10)N respectively when the concentration of the membrane coated by 5 microg/ml collagen IV (P<0.001). CONCLUSIONS: The adhesive forces of hepatoma cells to artificial basement membrane in direct proportion to the concentration of collagen IV suggests that the increase of basement membrane might be conducive to the chemotactic motion and adhesiveness of tumor cells. G1 phase cells are more capable of adhering to basement membrane than S phase cells. Hepatoma cells, especially G1 phase cells, may survive in blood circulation, and sequest and adhere in microcirculation, and get through basement membrane for remote metastasis.