Synergistic combinations of tanshinone IIA and trans-resveratrol toward cisplatin-comparable cytotoxicity in HepG2 human hepatocellular carcinoma cells.

AIM: To determine the combinative effects of tanshinone IIA (Tan IIA) and trans-resveratrol (Resv) on cytotoxicity, apoptosis, cell-cycle arrest and DNA fragmentation in HepG2 human liver cancer cells. MATERIALS AND METHODS: Cytotoxicity was detected by the cell proliferation and cytotoxicity WST-1 assay. Cell-cycle arrest and apoptosis were determined using flow cytometry analysis. DNA fragments were separated by gel electrophoresis. RESULTS: Tan IIA and Resv at mixture ratios of 1/2:1/2 and 1/3:2/3 exerted synergistic cytotoxicity comparable to that of cisplatin. Elevated proportions of sub-G1 and apoptotic cells were respectively found in the combinative treatments in comparison with hypothetic values of additive effects. Moreover, a more intensive pattern of apoptotic DNA fragmentation was visualized in combined treatments than in individual ones. CONCLUSION: Combining Tan IIA and Resv causes synergistic cisplatin-comparable, cytotoxicity and robustly induces apoptosis, sub-G1 cell cycle arrest and DNA fragmentation. This study provides evidence supporting further pre-clinical investigations of the combinational synergism.

Gene expression profiling: cell cycle deregulation and aneuploidy do not cause breast cancer formation in WAP-SVT/t transgenic animals.

Microarray studies revealed that as a first hit the SV40 T/t antigen causes deregulation of 462 genes in mammary gland cells (ME cells) of WAP-SVT/t transgenic animals. The majority of deregulated genes are cell proliferation specific and Rb-E2F dependent, causing ME cell proliferation and gland hyperplasia but not breast cancer formation. In the breast tumor cells a further 207 genes are differentially expressed, most of them belonging to the cell communication category. In tissue culture breast tumor cells frequently switch off WAP-SVT/t transgene expression and regain the morphology and growth characteristics of normal ME cells, although the tumor-revertant cells are aneuploid and only 114 genes regain the expression level of normal ME cells. The profile of retransformants shows that only 38 deregulated genes are tumor-specific, and that none of them is considered to be a typical breast cancer gene.

HBX causes cyclin D1 overexpression and development of breast cancer in transgenic animals that are heterozygous for p53.

Transgenic mice, which selectively express the WAP-HBX transgene in mammary gland epithelial cells (ME-cells), were established in order to elucidate the consequences of HBX gene expression on organ differentiation, cell death program and tumor development. Transgene expression was demonstrable by RT-PCR, Northern and Western blot analysis during pregnancy, lactation and after weaning. HBX synthesis neither affect mammary gland differentiation nor apoptosis in ME-cells. Although breast cancer formation was rare in WAP-HBX animals (<1%), WAP-HBX*p53+/- hybrid animals developed breast tumors at an increased rate (12/85) after a latency period of 8-18 months. We also show here for the first time that HBX can immortalize ME-cells generated from mammary gland tissue segments in a p53-independent fashion. HBX causes cyclin D1 gene overexpression during early pregnancy, and this is maintained in ME-cells isolated either from mammary gland or from breast tumors. Intranuclear cyclin D1 accumulation also occurs in the absence of external growth factors and the BrdU incorporation rate remains high under serum starvation conditions. Finally, both cyclin D1 induction and HBX mitotic activity are dependent on p38 and c-Jun N-terminal kinase, but not on MEK-1 kinase activity.