Anti-C-Myc Antibody polyclonal antibody

Objective: Ovarian cancer is one of three malignant tumors of the female reproductive system. Our previous studies showed that the traditional Chinese medicine naringin significantly inhibited the proliferation of platinum-resistant ovarian cancer cells in vitro, and that the mechanism may be related to the NF-kappa B pathway. Methods: The MTT assay was used to detect the sensitivity of SKOV3 and SKOV3/CDDP cells to cisplatin, the effect of different naringin concentrations on the proliferation of SKOV3/CDDP cells, and the reversal of cisplatin resistance in naringin-treated SKOV3/CDDP cells. Western blotting was used to detect beta-catenin, c-Myc, and cyclin D1 protein levels in the different cell lines. Results: MTT results showed that different concentrations of naringin inhibited the proliferation of SKOV3 and SKOV3/CDDP cells, and that the inhibition increased with increasing concentrations and prolonged incubation times. Western blotting revealed that compared with controls (SKOV3/CDDP-0), beta-catenin, c-Myc and cyclin D1 proteins levels were significantly decreased in SKOV3/CDDP-C, SKOV3/CDDP-N 20, and SKOV3/CDDP-CN 20 cells, suggesting that naringin inhibited the proliferation of SKOV3/CDDP cells in a concentration and time dependent manner. Conclusions: Non-cytotoxic naringin reduced the expression of beta-catenin, c-Myc, and cyclin D1 in SKOV3/CDDP cells and partially reversed cisplatin resistance in SKOV3/CDDP CN 20 cells.

Cell-cycle entry relies on an orderly progression of signaling events. To start, cells first activate the kinase cyclin D-CDK4/6, which leads to eventual inactivation of the retinoblastoma protein Rb. Hours later, cells inactivate APC/C-CDH1 and cross the final commitment point. However, many cells with genetically deleted cyclin Ds, which activate and confer specificity to CDK4/6, can compensate and proliferate. Despite its importance in cancer, how this entry mechanism operates remains poorly characterized, and whether cells use this path under normal conditions remains unknown. Here, using single-cell microscopy, we demonstrate that cells with acutely inhibited CDK4/6 enter the cell cycle with a slowed and fluctuating cyclin E-CDK2 activity increase. Surprisingly, with low CDK4/6 activity, the order of APC/C-CDH1 and Rb inactivation is reversed in both cell lines and wild-type mice. Finally, we show that as a consequence of this signaling inversion, Rb inactivation replaces APC/C-CDH1 inactivation as the point of no return. Together, we elucidate the molecular steps that enable cell-cycle entry without CDK4/6 activity. Our findings not only have implications in cancer resistance, but also reveal temporal plasticity underlying the G1 regulatory circuit. How normal cells proliferate without CDK4 and CDK6, two cancer-driving kinases, remains unclear. Here, the authors show that without CDK4/6 activity, cells start the cell cycle with a different signaling order and commitment point, revealing unexpected flexibility in cell-cycle entry mechanisms.