Michele K. Montagna

Molecular phenotyping of human ovarian cancer stem cells unravels the mechanisms for repair and chemoresistance

A major burden in the treatment of ovarian cancer is the high percentage of recurrence and chemoresistance. Cancer stem cells (CSCs) provide a reservoir of cells that can self-renew, can maintain the tumor by generating differentiated cells [non-stem cells (non-CSCs)] which make up the bulk of the tumor and may be the primary source of recurrence. We describe the characterization of human ovarian cancer stem cells (OCSCs). These cells have a distinctive genetic profile that confers them with the capacity to recapitulate the original tumor, proliferate with chemotherapy, and promote recurrence. CSC identified in EOC cells isolated form ascites and solid tumors are characterized by: CD44+, MyD88+, constitutive NFκB activity and cytokine and chemokine production, high capacity for repair, chemoresistance to conventional chemotherapies, resistance to TNFα-mediated apoptosis, capacity to form spheroids in suspension, and the ability to recapitulate in vivo the original tumor. Chemotherapy eliminates the bulk of the tumor but it leaves a core of cancer cells with high capacity for repair and renewal. The molecular properties identified in these cells may explain some of the unique characteristics of CSCs that control self-renewal and drive metastasis. The identification and cloning of human OCSCs can aid in the development of better therapeutic approaches for ovarian cancer patients.

Targeting the Mitochondria Activates Two Independent Cell Death Pathways in Ovarian Cancer Stem Cells

Cancer stem cells are responsible for tumor initiation and chemoresistance. In ovarian cancer, the CD44+/MyD88+ ovarian cancer stem cells are also able to repair the tumor and serve as tumor vascular progenitors. Targeting these cells is therefore necessary to improve treatment outcome and patient survival. The previous demonstration that the ovarian cancer stem cells are resistant to apoptotic cell death induced by conventional chemotherapy agents suggests that other forms of targeted therapy should be explored. We show in this study that targeting mitochondrial bioenergetics is a potent stimulus to induce caspase-independent cell death in a panel of ovarian cancer stem cells. Treatment of these cells with the novel isoflavone derivative, NV-128, significantly depressed mitochondrial function exhibited by decrease in ATP, Cox-I, and Cox-IV levels, and by increase in mitochondrial superoxide and hydrogen peroxide. This promotes a state of cellular starvation that activates two independent pathways: (i) AMPKα1 pathway leading to mTOR inhibition; and (ii) mitochondrial MAP/ERK kinase/extracellular signal-regulated kinase pathway leading to loss of mitochondrial membrane potential. The demonstration that a compound can specifically target the mitochondria to induce cell death in this otherwise chemoresistant cell population opens a new venue for treating ovarian cancer patients. Mol Cancer Ther; 10(8); 1385–93. ©2011 AACR.

Constitutive proteasomal degradation of TWIST-1 in epithelial–ovarian cancer stem cells impacts differentiation and metastatic potential

Epithelial–mesenchymal transition (EMT) is a critical process for embryogenesis but is abnormally activated during cancer metastasis and recurrence. This process enables epithelial cancer cells to acquire mobility and traits associated with stemness. It is unknown whether epithelial stem cells or epithelial cancer stem cells are able to undergo EMT, and what molecular mechanism regulates this process in these specific cell types. We found that epithelial–ovarian cancer stem cells (EOC stem cells) are the source of metastatic progenitor cells through a differentiation process involving EMT and mesenchymal–epithelial transition (MET). We demonstrate both in vivo and in vitro the differentiation of EOC stem cells into mesenchymal spheroid-forming cells (MSFCs) and their capacity to initiate an active carcinomatosis. Furthermore, we demonstrate that human EOC stem cells injected intraperitoneally in mice are able to form ovarian tumors, suggesting that the EOC stem cells have the ability to ‘home’ to the ovaries and establish tumors. Most interestingly, we found that TWIST-1 is constitutively degraded in EOC stem cells, and that the acquisition of TWIST-1 requires additional signals that will trigger the differentiation process. These findings are relevant for understanding the differentiation and metastasis process in EOC stem cells.

Distinct Subpopulations of Epithelial Ovarian Cancer Cells Can Differentially Induce Macrophages and T Regulatory Cells Toward a Pro-Tumor Phenotype

Citation Alvero AB, Montagna MK, Craveiro V, Liu L, Mor G. Distinct subpopulations of epithelial ovarian cancer cells can differentially induce macrophages and T regulatory cells toward a pro‐tumor phenotype. Am J Reprod Immunol 2012; 67: 256–265

NV-128, a novel isoflavone derivative, induces caspase-independent cell death through the Akt/mammalian target of rapamycin pathway.

Resistance to apoptosis is 1 of the key events that confer chemoresistance and is mediated by the overexpression of antiapoptotic proteins, which inhibit caspase activation. The objective of this study was to evaluate whether the activation of an alternative, caspase‐independent cell death pathway could promote death in chemoresistant ovarian cancer cells. The authors report the characterization of NV‐128 as an inducer of cell death through a caspase‐independent pathway.

Clostridium perfringens enterotoxin carboxy-terminal fragment is a novel tumor-homing peptide for human ovarian cancer

BackgroundDevelopment of innovative, effective therapies against recurrent/chemotherapy-resistant ovarian cancer remains a high priority. Using high-throughput technologies to analyze genetic fingerprints of ovarian cancer, we have discovered extremely high expression of the genes encoding the proteins claudin-3 and claudin-4.MethodsBecause claudin-3 and -4 are the epithelial receptors for Clostridium perfringens enterotoxin (CPE), and are sufficient to mediate CPE binding, in this study we evaluated the in vitro and in vivo bioactivity of the carboxy-terminal fragment of CPE (i.e., CPE290-319 binding peptide) as a carrier for tumor imaging agents and intracellular delivery of therapeutic drugs. Claudin-3 and -4 expression was examined with rt-PCR and flow cytometry in multiple primary ovarian carcinoma cell lines. Cell binding assays were used to assess the accuracy and specificity of the CPE peptide in vitro against primary chemotherapy-resistant ovarian carcinoma cell lines. Confocal microscopy and biodistribution assays were performed to evaluate the localization and uptake of the FITC-conjugated CPE peptide in established tumor tissue.ResultsUsing a FITC-conjugated CPE peptide we show specific in vitro and in vivo binding to multiple primary chemotherapy resistant ovarian cancer cell lines. Bio-distribution studies in SCID mice harboring clinically relevant animal models of chemotherapy resistant ovarian carcinoma showed higher uptake of the peptide in tumor cells than in normal organs. Imunofluorescence was detectable within discrete accumulations (i.e., tumor spheroids) or even single chemotherapy resistant ovarian cancer cells floating in the ascites of xenografted animals while a time-dependent internalization of the FITC-conjugated CPE peptide was consistently noted in chemotherapy-resistant ovarian tumor cells by confocal microscopy.ConclusionsBased on the high levels of claudin-3 and -4 expression in chemotherapy-resistant ovarian cancer and other highly aggressive human epithelial tumors including breast, prostate and pancreatic cancers, CPE peptide holds promise as a lead peptide for the development of new diagnostic tracers or alternative anticancer agents.

Modulation of Apoptosis to Reverse Chemoresistance

Interference with the innate apoptotic activity is a hallmark of neoplastic transformation and tumor formation. Modulation of the apoptotic cascade has been proposed as a new approach for the treatment of cancer. In this chapter, we discuss the role of apoptosis in ovarian cancer and the use of phenoxodiol as a model for the regulation of apoptosis and potential use as chemosensitizer for chemoresistant ovarian cancer cells.

Detection of cancer-related proteins in fresh-frozen ovarian cancer samples using laser capture microdissection.

Tumors are heterogeneous structures that contain different cell populations. Laser capture microdissection (LCM) can be used to obtain pure cancer cells from fresh-frozen cancer tissue and the surrounded environment, thus providing an accurate snapshot of the tumor and its microenvironment in vivo. We describe a new approach to isolate pure cancer cell population and evaluate protein expression. The process includes immunocytochemistry, laser microdissection, and western blot analysis. Using this technique, we can detect proteins such as X-linked inhibitor of apoptosis protein (XIAP) and Fas ligand (FasL) with as little as 1000 cells.

Phenoxodiol-topotecan co-administration exhibit significant anti-tumor activity without major adverse side effects

Objective: We previously showed that Phenoxodiol is able to sensitize epithelial ovarian cancer cells to Paclitaxel, Carboplatin, Gemcitabine, and Docetaxel. The aim of this study was to determine the value of Phenoxodiol-Topotecan co-administration. Methods: Nine epithelial ovarian cancer cell lines isolated from ascites or ovarian tissue were treated with increasing concentrations of Topotecan (5-500 ng/ml) with or without Phenoxodiol pre-treatment (10 μg/ml) for 24h and cell viability was measured using CellTiter 96® AQueous One Solution Cell Proliferation Assay. The effect of Phenoxodiol-Topotecan combination therapy in vivo was determined using the topotecan resistant A2780 mouse xenograft model. Results: In vitro, pre-treatment with Phenoxodiol lowers the topotecan IC50 from >500 ng/ml to 2.5-100 ng/ml in 5 out of 9 cell lines tested. Results from animal experiments confirmed the advantage of Phenoxodiol-Topotecan combination therapy over monotherapy controls. Median tumour kinetics from animals receiving Phenoxodiol-Topotecan in combination was significantly slower compared to those animals receiving the respective monotherapies. In addition, co-administration with Phenoxodiol reversed Topotecan-induced myelosuppression. Conclusion: Phenoxodiol-Topotecan combination therapy allows the administration of both agents at lower doses while retaining significant anti-tumor activity compared to monotherapy. These findings suggest that the Phenoxodiol-Topotecan combination may represent an alternative treatment modality for the management of ovarian cancer and justifies further investigation in the clinical setting.

Correlation of caspase activity and in vitro chemo-response in epithelial ovarian cancer cell lines.

The immediate assessment of response to therapy is most beneficial to ovarian cancer patients. This study shows the correlation of drug-induced caspase activation determined by western blot analysis and by Caspase-Glotrade mark assay. Our findings demonstrate that the use of the Caspase-Glotrade mark assay allows a simple, fast, and sensitive alternative for the evaluation of in vitro response to chemotherapy.