Yan Bin Dong

Adenovirus-Mediated Gene Transfer of FKHRL1 Triple Mutant Efficiently Induces Apoptosis in Melanoma Cells

The PTEN/Akt signal pathway plays an important role in tumorigenesis. Mutations or deletions of PTEN have been observed in up to 60% of melanoma cell lines, resulting in PI3K/Akt activation. The Forkhead family of transcription factors induce apoptosis in their unphosphorylated forms and were recently reported to be a substrate of Akt kinase. In the present study, an adenovirus expressing a triple mutant (TM) of FKHRL1, which cannot be phosphorylated by Akt, was assessed for its ability to induce apoptosis in melanoma cells. Marked overexpression of FKHRL1/TM was evident in the SK-MEL-2 cell line 24 hours after infection with Ad-FKHRL1/TM by Western blot analysis. The expression of FKHRL1/TM was moderately delayed in SK-MEL-28 cells. Overexpression of FKHRL1/TM can efficiently inhibit melanoma cell growth and result in rapid loss of cell viability. Cell cycle analysis showed overexpression of FKHRL1/TM in both melanoma cell lines resulted in development of a sub-G1 population, indicating apoptosis by Ad-FKHRL1/TM infection. Apoptosis was confirmed by morphologic inspection, poly-ADP-ribosepolymerase (PARP) cleavage assay, and annexin V-PE analysis. After Ad-FKHRL1/TM infection, the expression of Bax and Bak did not differ markedly, whereas Mcl-1 and Bcl-xL levels decreased markedly. Involvement of caspase 3 and 6 in FKHRL1/TM-mediated apoptosis was demonstrated by cleavage of caspase 3/CPP32 and PARP as well as fragmentation of the caspase 6 substrate lamin B in SK-MEL-2 cells as early as 24 hours after Ad-FKHRL1/TM infection, but those events were delayed 72 hours in SK-MEL-28. In addition, we found that p27kip1 was cleaved in SK-MEL-2 cells at 24 hours after treatment with Ad-FKHRL1/TM. This cleavage was observed in SK-MEL-28 cells until 72 hours after infection with Ad-FKHRL1/TM. Our data suggest that adenovirus expressing a FKHRL1 triple mutant could be a useful vector for gene therapy of cancers resistant to chemotherapy and radiotherapy induced by hyperactivity of PI3K/Akt.

E2F-1 Gene Therapy Induces Apoptosis and Increases Chemosensitivity in Human Pancreatic Carcinoma Cells

Pancreatic cancer is often resistant to conventional chemotherapy. In this study, we examined the role of adenovirus-mediated overexpression of E2F-1 in inducing apoptosis and increasing the sensitivity of pancreatic cancer cells to chemotherapeutic agents. MIA PaCa-2 pancreatic head exocrine adenocarcinoma cells (mutant p53) were treated by mock infection or adenoviruses expressing β-galactosidase or E2F-1 (Ad-E2F-1) alone or in combination with sublethal concentrations of each chemotherapeutic drug. Cell growth and viability were assessed at selected time points. Apoptosis was evaluated by flow cytometry, characteristic changes in cell morphology and poly (ADP-ribose) polymerase (PARP) cleavage. Western blot analysis was used to examine the expression of E2F-1 and Bcl-2 family member proteins and PARP cleavage. Western blot analysis revealed marked overexpression of E2F-1 at a multiplicity of infection (MOI) of 20 and 70. By 3 days after infection, Ad-E2F-1 treatment at an MOI of 70 resulted in approximately a 20-fold reduction in cell growth and 60% reduction in cell viability as compared to mock-infected cells. Cell cycle analysis, PARP cleavage and changes in cell morphology supported apoptosis as the mechanism of cell death in response to E2F-1. In order to test the efficacy of treatment with a combination of gene therapy and chemotherapy, we utilized concentrations of Ad-E2F-1 which reduced viability to 50% in combination with each chemotherapeutic agent. Cotreatment of the cells with E2F-1 virus and roscovitine (ROS) or etoposide resulted in an additive effect on cell growth inhibition and induction of apoptosis. Interestingly, 5-fluorouracil did not cooperate with Ad-E2F-1 in the mediation of tumor death or inhibition of cell growth. Immunoblotting for Bcl-2 family members revealed no significant changes in the expression levels of Bcl-2, Bcl XL, Bax or Bak following gene or ‘chemogene’ therapy with E2F-1. However, a Bax cleavage product was noted which was substantially increased by cotreatment with ROS or etoposide. E2F-1 overexpression initiates apoptosis and suppresses growth in pancreatic MIA PaCa-2 cells in vitro. E2F-1-mediated apoptosis was not associated with significant changes in the expression of Bcl-2 family member proteins in these pancreatic cancer cells. ROS and etoposide, when combined with E2F-1 overexpression, induce apoptosis in an additive manner. This chemogene combination may provide a potentially useful therapeutic strategy for advanced pancreatic cancer.

Additive effect of adenovirus-mediated E2F-1 gene transfer and topoisomerase II inhibitors on apoptosis in human osteosarcoma cells.

Recently, it has been demonstrated that Etoposide, a topoisomerase II inhibitor, can induce apoptosis in MDM2-overexpressing tumor cells by inhibition of MDM2 synthesis. We have previously shown that E2F-1 overexpression induces apoptosis of MDM2-overexpressing sarcoma cells, which is related to the inhibition of MDM2 expression. Therefore, the present study was designed to investigate the in vitro and in vivo effect of combined treatment of adenovirus-mediated E2F-1 and topoisomerase II inhibitors on the growth inhibition and apoptosis in human sarcoma cells. Two human sarcoma cell lines, OsACL and U2OS, were treated with topoisomerase II inhibitors (Etoposide and Adriamycin), alone or in combination with adenoviral vectors expressing β-galactosidase (Ad-LacZ) or E2F-1 (Ad-E2F-1). E2F-1 expression was confirmed by Western blot analysis. Ad-E2F-1 gene transfer at a low dose (multiplicity of infection, 2) markedly increased the sensitivity of human sarcoma cells to topoisomerase II inhibitor treatment. This cooperative effect of E2F-1 and topoisomerase II inhibitors was less marked in SAOS-2 cells (p53 and pRb null). Topoisomerase II inhibitors also cooperated with E2F-1 overexpression to enhance tumor cell killing in an in vivo model using xenografts in nude mice. When combined with Adriamycin or Etoposide, E2F-1 adenovirus therapy resulted in approximately 95% and 85% decrease in tumor size, respectively, compared to controls (P<.05). These results suggest a new chemosensitization strategy that is effective in MDM2-overexpressing tumors and may have clinical utility. Cancer Gene Therapy (2001) 8, 241–251

SW-620 cells treated with topoisomerase I inhibitor SN-38: gene expression profiling

BackgroundThe goal of this study was to evaluate changes in gene expression in SW-620 cells in response to SN-38 in order to further elucidate the mechanisms by which SN-38 causes apoptosis and cell cycle arrest.MethodsWe used a quantitative gene expression microarray assay to identify the genes regulated by SN-38 treatment in colon cancer cells and confirmed our results with RT-PCR. By gene expression profiling, we first screened a proprietary list of about 22,000 genes.ResultsTreatment with SN-38 cells resulted in two-fold or greater alteration in the level of expression of 192 genes compared to control treatment. Most of the affected genes were not known to be responsive to SN-38 prior to this study. SN-38 treatment of these cells was found to affect the expression of various genes involved in DNA replication, transcription, signal transduction, growth factors, cell cycle regulation, and apoptosis, as well as other genes with unknown function. Changes in expression of 14 genes were confirmed by quantitative real-time polymerase chain reaction (RT-PCR).ConclusionThis study leads to an increased understanding of the biochemical pathways involved in SN-38-induced apoptosis and possibly to the identification of new therapeutic targets.

C-terminal deletion mutant p21(WAF1/CIP1) enhances E2F-1-mediated apoptosis in colon adenocarcinoma cells

The present study was designed to investigate the efficacy of combination gene therapy using adenoviral vectors expressing gene products shown to possess apoptotic activity: E2F-1 (Ad-E2F-1) and a C-terminal deletion mutant of p21WAF1/cIP1 (Ad-p21-PCNA), on growth inhibition and apoptosis of human colon cancer cells in vitro and in vivo. Marked E2F-1 and p21-PCNA overexpression in response to adenovirus infection was evident by Western blot analysis. IC25 concentrations of each virus were used for each treatment in vitro to detect cooperative effects on cell death. Coexpression of E2F-1 and p21-PCNA resulted in an additive effect on cell death compared to infection with either virus alone. Cell cycle analysis, poly(ADP-ribose) polymerase (PARP) cleavage and analysis of cell morphology also revealed that coinfection with both Ad-E2F-1 and Ad-p21-PCNA enhanced cellular apoptosis compared to either virus alone. Interestingly, E2F-1 protein expression was markedly enhanced in the E2F-1/p21-PCNA adenovirus combination compared to Ad-E2F-1 infection alone. However, these same effects were not evident in cells coinfected with Ad-E2F-1 and an adenovirus expressing wild-type human p21WAF1/CIP1 (Ad-p21WT). The increase in E2F-1 expression with coexpression of E2F-1 and p21-PCNA was not a result of increased E2F-1 protein stability, but was related to increased transcriptional activity from the CMV promoter. Cell cycle analysis revealed G1 arrest 72 hours following single-gene therapy with either the wild-type or mutant p21, whereas increased accumulation of cells in G2/M phase was demonstrated in the E2F-1–overexpressing cells. In the combined therapies, E2F-1/p21-PCNA treatment still resulted in G1 arrest, but E2F-1 was able to counteract the G1 arrest when coinfected with p21WT. These results provide further evidence of the importance of the p21:PCNA-binding domain in mediating the complex cell cycle interaction between E2F-1 and p21. Simultaneous intratumoral injection of Ad-E2F-1 and Ad-p21-PCNA dramatically reduced tumor burden of SW620 xenografts compared to either treatment alone in our in vivo model but not in HT-29 colon cancer xenografts. When combined with Ad-p21-PCNA, E2F-1 adenovirus therapy resulted in approximately 95% decrease in tumor volume of SW620 tumor xenografts compared with controls (P<.05). In conclusion, although simultaneous delivery of E2F-1 and p21-PCNA transgenes results in increased E2F-1 expression and enhanced apoptosis of both SW620 and HT-29 colon cancer cells in vitro, this combination was only effective in the treatment of SW620 metastatic colon cancer in vivo. This may represent a potentially useful combination gene therapy strategy for metastatic colon cancer.

Increased mdm-2 Expression in a p53-Independent Manner Blocks UV-Induced Cell Cycle Arrest and Apoptosis in Human Osteosarcoma Cells

DNA damage results in an increase in p53 levels, which is required to initiate a p53-mediated cell cycle arrest and/or apoptosis. P53 and MDM-2 form a feedback control loop: while p53 can transactivate the mdm-2 gene, high levels of MDM-2 inhibit p53 transactivation as well as promote rapid degradation of P53. In the present study, we investigated the interaction between endogenous MDM-2 and p53 following UV-induced DNA damage in an MDM-2 overexpression cell line. A human osteosarcoma cell line (OsACL, which contains wild-type p53 and overexpresses MDM-2 protein) was used in this study. Here we show that following UV treatment, p53 levels increased in the OsACL cells despite the presence of high-level endogenous MDM-2; however, CAT assays using a p53 reporter system revealed that this P53 was transcriptionally inactive. Although p53 transactivation was inhibited, MDM-2 levels rose markedly following UV irradiation. Northern blot analysis revealed that the increase in MDM-2 protein levels was a result of increased levels of mdm-2 mRNA, possibly due to increased transcription. Cell cycle analysis revealed that OsACL cells were markedly resistant to UV-induced apoptosis. Transfection of OsACL cells with an anti-sense mdm-2 plasmid dowregulated MDM-2 expression and increased UV-induced apoptosis. In conclusion, MDM-2 overexpression can block UV-induced cell cycle arrest and apoptosis by inhibiting p53 transcriptional activity. Furthermore, increased expression of MDM-2 in OsACL cells following UV irradiation appears to be related to p53-independent mechanisms.

Induction of Apoptosis Signal-Regulating Kinase 1 by E2F-1 May Not Be Essential for E2F-1-Mediated Apoptosis in Melanoma Cells

Objectives: In the present study, we investigate the role of apoptosis signal-regulating kinase 1 (ASK1) mitogen-activated protein (MAP) kinase signal pathways in E2F-1-mediated apoptosis. Methods: A gene expression profile in response to E2F-1 overexpression was performed by cDNA microarray analysis and confirmed by real-time reverse-transcription polymerase chain reaction. Kinase activities were assayed by Western blot analysis or kinase assay. Apoptosis was assessed by morphologic inspection and flow-cytometric analysis. Cytotoxicity was monitored by MTT assay. Results:E2F-1 upregulated the expression of ASK1 8-fold compared to the Ad-LacZ-infected control in SK-MEL-2 melanoma cells, which was confirmed by reverse-transcription polymerase chain reaction. Sequence analysis showed that there are 2 putative E2F-1 DNA binding sites in the ASK1 promoter region. Truncated E2F-1 protein, which lacks the transactivation domain, failed to upregulate ASK1, suggesting that ASK1 was regulated at the transcriptional level by E2F-1. E2F-1 overexpression resulted in the transient activation of c-Jun N-terminal kinase (JNK); however, dominant negative mutant ASK1 had no effect on E2F-1 cytotoxicity and JNK activation. p38 was not activated by E2F-1, and inhibition of p38 had no effect on E2F-1-mediated cell death. The ASK1 kinase assay showed that ASK1 activity was not upregulated in response to E2F1 overexpression. The inhibition of ASK1 upstream kinase-AKT can enhance E2F-1-mediated cell death. Moreover, an adenovirus expressing truncated E2F-1 keeps the ability of inducing apoptosis in melanoma cells. Conclusions:ASK1 expression is upregulated by E2F-1 at the transcription level, but the upregulation of ASK1 expression by E2F-1 was not coordinated with an increased ASK1 activity. The ASK1-JNK/p38 pathway does not appear to play a crucial role in E2F-1-induced apoptosis.

Inhibition of Cyclin A Kinase Activity in E2F-1 Chemogene Therapy of Colon Cancer

Adenoviral-mediated gene transfer of the apoptotic gene e2f-1 has been shown to induce apoptosis in a variety of tumor cells and acts in an additive or cooperative fashion with several specific chemotherapeutic agents to induce tumor cell death. The apoptotic function of E2F-1 is dependent on its ability to bind DNA; cyclin A kinase activity has been shown to negatively regulate the DNA-binding capacity of E2F-1. In the present study, we sought to determine whether cyclin A kinase activity is involved in mediating the interaction between E2F-1 and chemotherapeutic agents in colon cancer cells. Therefore, human colon adenocarcinoma (SW620) cells were treated with an adenovirus expressing E2F-1 (Ad-E2F-1, multiplicity of infection 20). Immediately following infection, a panel of conventional chemotherapeutic agents with varying modes of cytotoxic action were administered at LD25 doses. Three days following treatment, viability and growth inhibition were determined by trypan blue exclusion assay. Apoptosis was confirmed using cellular morphology, poly (ADP-ribose) polymerase cleavage, and flow-cytometric analysis. E2F-1 overexpression and cyclin A protein expression were monitored by immunoblot, and cyclin A kinase activity was determined by kinase assay. Vincristine (VIN), camptothecin (CPT), and actinomycin D were found to have a cooperative (>38% over the additive single therapy values) effect on E2F-1-mediated apoptosis. Etoposide, cisplatin (CIS), and 5-fluorouracil (5-FU) showed the least cooperation (≤11.5% over the additive single therapy values) with E2F-1. Ad-E2F-1 treatment alone results in 3.4-fold increase of cyclin A kinase activity compared to Ad-LacZ control (p < 0.05); when combined with chemotherapeutic agents, cyclin A kinase activity was inhibited significantly by VIN, actinomycin D, and etoposide (p < 0.005), but not with CPT, CIS, and 5-FU (p > 0.1) compared to Ad-E2F-1 treatment alone. Combination of Ad-LacZ/5-FU and Ad-LacZ/actinomycin D significantly inhibited cyclin A kinase activity compared to Ad-LacZ treatment alone (p < 0.005). No other Ad-LacZ/drug combinations significantly affected cyclin A kinase activity (p > 0.05). In conclusion, combinations of E2F-1 adenovirus and VIN, CPT, or actinomycin D at LD25 had significant cooperative effects on colon cancer apoptotic cell death in vitro. Although inhibition of cyclin A kinase activity was observed in most Ad-E2F-1/drug combination treatments compared to Ad-E2F-1 treatment alone, there was no consistent correlation between degree of inhibition of cyclin A kinase activity and the cooperative effect. Nonetheless, inhibition of cyclin A kinase activity may be an important mechanism by which the chemogene therapy effects involving E2F-1 are modulated.