Fotini Nicolaou

Retinoblastoma cells are inhibited by aminoimidazole carboxamide ribonucleotide (AICAR) partially through activation of AMP-dependent kinase

5‐Aminoimidazole‐4‐carboxamide‐1‐β‐4‐ribofuranoside (AICAR), an analog of AMP, is widely used as an activator of AMP‐kinase (AMPK), a protein that regulates the responses of the cell to energy change. We studied the effects of AICAR on the growth of retinoblastoma cell lines (Y79, WERI, and RB143). AICAR inhibited Rb cell growth, induced apoptosis and S‐phase cell cycle arrest, and led to activation of AMPK. These effects were abolished by treatment with dypiridamole, an inhibitor that blocks entrance of AICAR into cells. Treatment with the adenosine kinase inhibitor 5‐iodotubericidin to inhibit the conversion of AICAR to ZMP (the direct activator of AMPK) reversed most of the growth‐inhibiting effects of AICAR, indicating that some of the antiproliferative effects of AICAR are mediated through AMPK activation. In addition, AICAR treatment was associated with inhibition of the mammalian target of rapamycin pathway, decreased phosphorylation of ribosomal protein‐S6 and 4E‐BP1, down‐regulation of cyclins A and E, and decreased expression of p21. Our results indicate that AICAR‐induced activation of AMPK inhibits retinoblastoma cell growth. This is one of the first descriptions of a nonchemotherapeutic drug with low toxicity that may be effective in treating Rb patients.—Theodoropoulou, S., Kolovou, P. E., Morizane, Y., Kayama, M., Nicolaou, F., Miller, J. W., Gragoudas, E., Ksander, B. R., Vavvas, D. G. Retinoblastoma cells are inhibited by aminoimidazole carboxamide ribonucleotide (AICAR) partially through activation of AMP‐dependent kinase. FASEB J. 24, 2620–2630 (2010). www.fasebj.org

Mullerian Inhibiting Substance inhibits invasion and migration of epithelial cancer cell lines

OBJECTIVE Given the fact that Mullerian Inhibiting Substance (MIS) causes complex remodeling of the urogenital ridge and regression of the Mullerian ducts during male embryonic development, we examined whether MIS could affect similar cell properties such as migration and invasion that could contribute ultimately to micro-metastasis of cancers arising from Mullerian tissues. MIS receptor expressing cell lines found to be invasive and migratory in vivo are examined in an in vivo assay that is cost-effective. METHODS We designed in vitro and in vivo experiments to determine if MIS inhibited the movement of cancer lines IGROV-1, HEp3, MDA-MB-231, and HT1080 in cell culture invasion/migration chamber assays and in chick embryo metastasis assays. RESULTS MIS, at concentrations below those that inhibit cell proliferation, blocked in vitro invasion and in vivo migration of epithelial cancer cells that express the MIS receptor. CONCLUSIONS While our laboratory has previously established MIS as an inhibitor of cancer cell proliferation using in vitro assays and in vivo xenografts, we now show that MIS can also inhibit in vivo tumor migration.

Development of an efficiently cleaved, bioactive, highly pure FLAG-tagged recombinant human Mullerian Inhibiting Substance.

Mullerian Inhibiting Substance (MIS), a member of the TGF-beta family, causes regression of the Mullerian duct in male embryos, after binding to Mullerian Inhibiting Substance Receptor II (MISRII). It has also been extensively demonstrated that it can inhibit proliferation of various cancer cell lines such as ovarian, prostate, and breast cancer in vitro and in vivo. Hence, the availability of a recombinant, epitope tagged, bioactive MIS is important for the selection of patients for treatment and for probing novel molecular targets for MIS in various tissues. To this end, we have expressed a recombinant, internally FLAG-tagged form of hMIS with the tag (DYKDDDDK) immediately after the cleavage site (427-428) of MIS at the C-terminus with a modified dibasic cleavage motif sequence. We show that this construct results in a highly pure, endogenously processed (cleaved) FLAG MIS, that causes complete regression of the Mullerian Duct in an organ culture assay. In addition, purified FLAG MIS was able to bind and affinity purify both transfected and endogenous MIS type II receptor. The availability of this fully functional, epitope tagged form of MIS should facilitate scale-up for preclinical and clinical use and should also be used for the study of MIS binding proteins and for tracking in pharmacokinetic studies.

Verteporfin-induced formation of protein cross-linked oligomers and high molecular weight complexes is mediated by light and leads to cell toxicity

Verteporfin (VP) was first used in Photodynamic therapy, where a non-thermal laser light (689 nm) in the presence of oxygen activates the drug to produce highly reactive oxygen radicals, resulting in local cell and tissue damage. However, it has also been shown that Verteporfin can have non-photoactivated effects such as interference with the YAP-TEAD complex of the HIPPO pathway, resulting in growth inhibition of several neoplasias. More recently, it was proposed that, another non-light mediated effect of VP is the formation of cross-linked oligomers and high molecular weight protein complexes (HMWC) that are hypothesized to interfere with autophagy and cell growth. Here, in a series of experiments, using human uveal melanoma cells (MEL 270), human embryonic kidney cells (HEK) and breast cancer cells (MCF7) we showed that Verteporfin-induced HMWC require the presence of light. Furthermore, we showed that the mechanism of this cross-linking, which involves both singlet oxygen and radical generation, can occur very efficiently even after lysis of the cells, if the lysate is not protected from ambient light. This work offers a better understanding regarding VP’s mechanisms of action and suggests caution when one studies the non-light mediated actions of this drug.

An albumin leader sequence coupled with a cleavage site modification enhances the yield of recombinant C-terminal Mullerian Inhibiting Substance

Mullerian Inhibiting Substance (MIS) has been shown to inhibit ovarian cancer cells both in-vitro and in-vivo. Furthermore, recent evidence suggests that MIS may effectively target a putative ovari...

Type IV collagen drives alveolar epithelial–endothelial association and the morphogenetic movements of septation

BackgroundType IV collagen is the main component of the basement membrane that gives strength to the blood–gas barrier (BGB). In mammals, the formation of a mature BGB occurs primarily after birth during alveologenesis and requires the formation of septa from the walls of the saccule. In contrast, in avians, the formation of the BGB occurs rapidly and prior to hatching. Mutation in basement membrane components results in an abnormal alveolar phenotype; however, the specific role of type IV collagen in regulating alveologenesis remains unknown.ResultsWe have performed a microarray expression analysis in late chick lung development and found that COL4A1 and COL4A2 were among the most significantly upregulated genes during the formation of the avian BGB. Using mouse models, we discovered that mutations in murine Col4a1 and Col4a2 genes affected the balance between lung epithelial progenitors and differentiated cells. Mutations in Col4a1 derived from the vascular component were sufficient to cause defects in vascular development and the BGB. We also show that Col4a1 and Col4a2 mutants displayed disrupted myofibroblast proliferation, differentiation and migration. Lastly, we revealed that addition of type IV collagen protein induced myofibroblast proliferation and migration in monolayer culture and increased the formation of mesenchymal–epithelial septal-like structures in co-culture.ConclusionsOur study showed that type IV collagen and, therefore the basement membrane, play fundamental roles in coordinating alveolar morphogenesis. In addition to its role in the formation of epithelium and vasculature, type IV collagen appears to be key for alveolar myofibroblast development by inducing their proliferation, differentiation and migration throughout the developing septum.

Abstract A42: An albumin leader sequence coupled with a cleavage site modification enhances the yield of recombinant c-terminal Mullerian inhibiting substance

Mullerian Inhibiting Substance (MIS) has been shown to inhibit ovarian cancer cells both in-vitro and in-vivo. Furthermore, recent evidence suggests that MIS may effectively target a putative ovarian cancer progenitor cell population enriched by a panel of CD44+, CD24+, Ep-CAM+, and E-cadherin-cell surface markers. In order to accommodate clinical testing of MIS in ovarian cancer patients, the production of recombinant human MIS must be optimized to increase yield and purity. Here we show that, compared to wild type, the substitution of the MIS leader sequence to that of human serum albumin, combined with a modification of the endogenous cleavage site from RAQR/S to a furin/kex2 RARR/S consensus site results in high expression, increased C-terminus cleavage and a reduction in unwanted cryptic internal cleavage products when produced in CHO cells. Purified MIS containing these alterations retains its capacity to induce regression of the Mullerian duct in fetal rat embryonic urogenital ridge assays.

Abstract AS25: An adeno-associated virus (AAV) 9 vector delivering modified human mullerian inhibiting substance (MIS) as a gene therapy for ovarian cancer

Abstracts: 10th Biennial Ovarian Cancer Research Symposium; September 8-9, 2014; Seattle, WA Purpose: Ovarian cancer is the most lethal malignancy of the female reproductive tract; as such, effective treatments are needed to improve patient survival. MIS has previously been shown to inhibit growth of a stem-like subset of the total cell population in ovarian cancer cell lines (Wei et al, 2010; Meirelles et al, 2012). We have recently engineered novel peptide modifications to human MIS (LR-MIS), which increase production and potency in vitro and in vivo (Pepin et al, 2013), and inserted it into an AAV vector. AAV delivered gene therapy has undergone a clinical resurgence with a good safety profile and sustained gene expression (Zhang et al, 2011). Therefore, we assessed the efficacy of a single intraperitoneal (ip) dose of AAV9-LR-MIS to inhibit tumor growth of an established cell line for subsequent evaluation in patient-derived ovarian cancer xenografts (PDX). Methods: 6 week old female nude mice were treated with a single ip injection of 3e11 or 1e12 virions of AAV9 LR-MIS or GFP. Serum levels of human MIS were monitored weekly by ELISA. After serum steady state was achieved, the established ovarian cancer cell line, OVCAR5 was xenografted subcutaneously at 1e6 cells per animal. Tumors treated with AAV were measured twice weekly. Additionally, Patient ascites were processed to isolate the cancer cell population, which was specifically amplified in vitro to create low passage primary cell lines. Results: AAV9-LR-MIS treatment resulted in elevated and sustained blood concentrations of MIS ([Fig1A][1]) in nude mice without any signs of toxicity, and significantly inhibited OVCAR5 tumor growth (p=0.0003) ([Fig1B][1]) in two separate experiments. AAV9-GFP revealed that the pancreas, omentum, gut mesentery, and body wall muscles were the primary sites of infection. Treatment with MIS induced downregulation of CCND1 in tumors. A panel of 15 primary ovarian cancer cell lines, all expressing the MIS type II receptor were generated from patient ascites and cells are being tested for their ability to grow as PDX in Nude, NOD/SCID, and NSG mice. ![Figure 1.][2] Figure 1. AAV-LR-MIS treatment results in stable expression of MIS and inhibition of tumor growth of OVCAR5 xenografts. A) Weekly MIS ELISA of serum from mice after single doses of 1e10 to 1e12 virions. B) Tumor growth of 1e6 OVCAR5 cells xenografted into nude mice (N=5) pretreated with 3e11/mouse (1.5e13/kg) LR-MIS or GFP virus (p=0.0003 by two-way ANOVA). Conclusions: AAV9 virally delivered human LR-MIS can produce adequate sustained levels of MIS that inhibited the growth of the human ovarian cancer cell line, OVCAR 5. AAV9 LR MIS provides a well-tolerated, low toxicity treatment of ovarian cancer, which can now be evaluated in a phase 0 trial using PDX models being prepared from human ovarian cancer ascites. Citation Format: David Pepin, Amanda Sosulski, Katherine Hendren, Li Hua Zhang, Fotini Nicolaou, Dan Wang, Guangping Gao, Patricia K Donahoe. An adeno-associated virus (AAV) 9 vector delivering modified human mullerian inhibiting substance (MIS) as a gene therapy for ovarian cancer [abstract]. In: Proceedings of the 10th Biennial Ovarian Cancer Research Symposium; Sep 8-9, 2014; Seattle, WA. Philadelphia (PA): AACR; Clin Cancer Res 2015;21(16 Suppl):Abstract nr AS25. [1]: #F1 [2]: pending:yes