TFDP3 was expressed in coordination with E2F1 to inhibit E2F1-mediated apoptosis in prostate cancer

TFDP3 has been previously identified as an inhibitor of E2F molecules. It has been shown to suppress E2F1-induced apoptosis dependent P53 and to play a potential role in carcinogenesis. However, whether it indeed helps cancer cells tolerate apoptosis stress in cancer tissues remains unknown. TFDP3 expression was assessed by RT-PCR, in situ hybridization and immunohistochemistry in normal human tissues, cancer tissues and prostate cancer tissues. The association between TFDP3 and E2F1 in prostate cancer development was analyzed in various stages. Apoptosis was evaluated with annexin-V and propidium iodide staining and flow-cytometry. The results show that, in 96 samples of normal human tissues, TFDP3 could be detected in the cerebrum, esophagus, stomach, small intestine, bronchus, breast, ovary, uterus, and skin, but seldom in the lung, muscles, prostate, and liver. In addition, TFDP3 was highly expressed in numerous cancer tissues, such as brain-keratinous, lung squamous cell carcinoma, testicular seminoma, cervical carcinoma, skin squamous cell carcinoma, gastric adenocarcinoma, liver cancer, and prostate cancer. Moreover, TFDP3 was positive in 23 (62.2%) of 37 prostate cancer samples regardless of stage. Furthermore, immunohistochemistry results show that TFDP3 was always expressed in coordination with E2F1 at equivalent expression levels in prostate cancer tissues, and was highly expressed particularly in samples of high stage. When E2F1 was extrogenously expressed in LNCap cells, TFDP3 could be induced, and the apoptosis induced by E2F1 was significantly decreased. It was demonstrated that TFDP3 was a broadly expressed protein corresponding to E2F1 in human tissues, and suggested that TFDP3 is involved in prostate cancer cell survival by suppressing apoptosis induced by E2F1.     

BRCA1 facilitates stress-induced apoptosis in breast and ovarian cancer cell lines

The BRCA1 tumor suppressor gene has previously been implicated in induction of high levels of apoptosis in osteocarcinoma cell lines. Overexpression of BRCA1 was shown to induce an apoptotic signaling pathway involving the c-Jun N-terminal kinase (JNK), but the signaling steps upstream and downstream of JNK were not delineated. To better understand the role of BRCA1 in apoptosis, we examined the effect of wild-type and C-terminal-truncated dominant negative BRCA1 on breast and ovarian cancer cell lines subjected to a number of different pro-apoptotic stimuli, including growth factor withdrawal, substratum detachment, ionizing radiation, and treatment with anticancer agents. All of these treatments were found to induce substantial levels of apoptosis in the presence of wild-type BRCA1, whereas dominant negative BRCA1 truncation mutants diminished the apoptotic response. Subsequent mapping of the apoptotic pathway induced by growth factor withdrawal demonstrated that BRCA1 enhanced signaling through a pathway that sequentially involved H-Ras, MEKK4, JNK, Fas ligand/Fas interactions, and caspase-9 activation. In addition, the pathway functioned independently of the p53 tumor suppressor. These data suggest that BRCA1 is an important modulator of the response to cellular stress and that loss of this apoptotic potential due to BRCA1 mutations may contribute to tumor development.     

Autophagy protects breast cancer cells from epirubicin-induced apoptosis and facilitates epirubicin-resistance development

Epirubicin (EPI) is one of the most effective drugs against cancer. But the acquired resistance of cancer cells to EPI is becoming a major obstacle for successful cancer therapy. Recently, some studies have revealed that macroautophagy (here referred to as autophagy) may protect the cancer cell from anticancer drug-induced death, so autophagy might be related to the development of drug resistance to these reagents. However, the relationship between autophagy and drug resistance has yet to be defined. Our study showed that EPI induced autophagy in human breast cancer MCF-7 cells. And the EPI-induced autophagy protected MCF-7 cells from EPI-induced apoptosis. Furthermore, autophagy was elevated in EPI-resistant MCF-7 cells (MCF-7er cells), and inhibition of autophagy restored the sensitivity of MCF-7er cells to EPI. Therefore, autophagy is a prosurvival factor and has a role in the development of EPI-acquired resistance in EPI-treated MCF-7 cells. Also, this finding indicates that the use of clinically applicable autophagy inhibitors might be one of the important strategies for breast cancer therapy.     

Autophagy protects breast cancer cells from epirubicin-induced apoptosis and facilitates epirubicin-resistance development

Epirubicin (EPI) is one of the most effective drugs against cancer. But the acquired resistance of cancer cells to EPI is becoming a major obstacle for successful cancer therapy. Recently, some studies have revealed that macroautophagy (here referred to as autophagy) may protect the cancer cell from anticancer drug-induced death, so autophagy might be related to the development of drug resistance to these reagents. However, the relationship between autophagy and drug resistance has yet to be defined. Our study showed that EPI induced autophagy in human breast cancer MCF-7 cells. And the EPI-induced autophagy protected MCF-7 cells from EPI-induced apoptosis. Furthermore, autophagy was elevated in EPI-resistant MCF-7 cells (MCF-7er cells), and inhibition of autophagy restored the sensitivity of MCF-7er cells to EPI. Therefore, autophagy is a prosurvival factor and has a role in the development of EPI-acquired resistance in EPI-treated MCF-7 cells. Also, this finding indicates that the use of clinically applicable autophagy inhibitors might be one of the important strategies for breast cancer therapy.     

pRb inactivation in senescent cells leads to an E2F-dependent apoptosis requiring p73

Senescent cells in which pRb is inactivated undergo apoptosis on attempted reinitiation of DNA synthesis. To further explore the cell death resulting from loss of pRb function in senescent cells, we employed a temperature-sensitive pRb mutant protein (tspRb). We found that tspRb inactivation results in rapid E2F reactivation and subsequent S-phase reentry associated with the up-regulation of E2F target gene expression and cyclin E-dependent kinase activity. Total inhibition of cyclin-dependent kinase 2 activity results in a cell cycle arrest on pRb loss and a nearly complete suppression of apoptosis. Furthermore, blocking of E2F activity with a dominant-negative DP1 inhibits S-phase reentry and cell death following tspRb inactivation. Finally, inhibition of p73 activity abolishes apoptosis but not S-phase entry on pRb inactivation, suggesting that activation of E2F in senescent cells can result in the use of p73 as a cell death effector. Interestingly, senescent cells rescued from apoptosis maintain their altered shape and express senescence-associated beta-galactosidase despite loss of pRb function. Thus, maintenance of the terminal cell cycle arrest of senescent cells requires continuous pRb-mediated inactivation of E2F activity, the reappearance of which in these irrevocably altered cells triggers a cell death program instead of an inappropriate resumption of cell cycling.