Documents

89942178.pdf

Categories
Published
of 25
All materials on our website are shared by users. If you have any questions about copyright issues, please report us to resolve them. We are always happy to assist you.
Related Documents
Share
Description
Int. J. Mol. Sci. 2013, 14, 16617-16637; doi:10.3390/ijms140816617 International Journal of Molecular Sciences ISSN 1422-0067 www.mdpi.com/journal/ijms Article Glycogen Synthase Kinase 3β Inhibition as a Therapeutic Approach in the Treatment of Endometrial Cancer Yan Yin 1,† , Nora T. Kizer 2,† , Premal H. Thaker 2 , Katherine B. Chiappinelli 3 , Kathryn M. Trinkaus 4 , Paul J. Goodfellow 2 and Liang Ma 1,5, * 1 Division of Dermatology, Department of Medicine, Washington
Transcript
   Int. J. Mol. Sci.   2013 , 14 , 16617-16637; doi:10.3390/ijms140816617 International Journal of Molecular Sciences ISSN 1422-0067 www.mdpi.com/journal/ijms  Article   Glycogen Synthase Kinase 3 β  Inhibition as a Therapeutic Approach in the Treatment of Endometrial Cancer Yan Yin 1, † , Nora T. Kizer 2, † , Premal H. Thaker 2 , Katherine B. Chiappinelli 3 , Kathryn M. Trinkaus 4 , Paul J. Goodfellow 2  and Liang Ma 1,5, * 1 Division of Dermatology, Department of Medicine, Washington University School of Medicine, 660 South Euclid Avenue, MO 63110, USA; E-Mail: yyin@dom.wustl.edu 2 Department of Obstetrics and Gynecology, Washington University School of Medicine, 660 South Euclid Avenue, MO 63110, USA; E-Mails: kizern@wudosis.wustl.edu (N.T.K.); thakerp@wustl.edu (P.H.T.); paul.goodfellow@osumc.edu (P.J.G.) 3 Division of Endocrine and Oncologic Surgery, Department of Surgery, Washington University School of Medicine, 660 South Euclid Avenue, MO 63110, USA; E-Mail: kate.chiappinelli@gmail.com 4 Division of Biostatistics, Washington University School of Medicine, 660 South Euclid Avenue, MO 63110, USA; E-Mail: kimt@wubios.wustl.edu 5 Department of Developmental Biology, Washington University School of Medicine, 660 South Euclid Avenue, MO 63110, USA †  These authors contribute equally to this work. *  Author to whom correspondence should be addressed; E-Mail: lima@dom.wustl.edu; Tel.: +1-314-454-8771; Fax: +1-314-454-5626.  Received: 17 May 2013; in revised form: 19 July 2013 / Accepted: 24 July 2013 /  Published: 12 August 2013 Abstract:  Alternative strategies beyond current chemotherapy and radiation therapy regimens are needed in the treatment of advanced stage and recurrent endometrial cancers. There is considerable promise for biologic agents targeting the extracellular signal-regulated kinase (ERK) pathway for treatment of these cancers. Many downstream substrates of the ERK signaling pathway, such as glycogen synthase kinase 3 β  (GSK3 β ), and their roles in endometrial carcinogenesis have not yet been investigated. In this study, we tested the importance of GSK3 β  inhibition in endometrial cancer cell lines and  in vivo  models. Inhibition of GSK3 β  by either lithium chloride (LiCl) or specific GSK3 β  inhibitor VIII showed cytostatic and cytotoxic effects on multiple endometrial cancer cell lines, with OPEN ACCESS    Int. J. Mol. Sci.   2013 , 14 16618 little effect on the immortalized normal endometrial cell line. Flow cytometry and immunofluorescence revealed a G2/M cell cycle arrest in both type I (AN3CA, KLE, and RL952) and type II (ARK1) endometrial cancer cell lines. In addition, LiCl pre-treatment sensitized AN3CA cells to the chemotherapy agent paclitaxel. Administration of LiCl to AN3CA tumor-bearing mice resulted in partial or complete regression of some tumors. Thus, GSK3 β  activity is associated with endometrial cancer tumsrcenesis and its  pharmacologic inhibition reduces cell proliferation and tumor growth. Keywords:  lithium chloride; GSK3 β ; endometrial cancer 1. Introduction Endometrial carcinoma is the fourth most common cancer and the most common invasive gynecological malignancy among U.S. women, with an estimated 47,130 new cases and 8010 deaths in 2012 [1]. Despite advancements in therapy over the last 20 years, both incidence and five-year survival rates have remained roughly unchanged. Endometrial carcinoma is commonly classified into two  pathogenetic groups: type I being less invasive and low-grade with generally good prognosis, and type II being unassociated with exposure to estrogen and often high-grade and more invasive. Standard chemotherapy for metastatic endometrial carcinoma consists of treatments with cytotoxic agents including anthracyclines, platinum compounds and taxanes. Response rates of single agent therapy range from 12% to 42%, and those of combinations of cytotoxic chemotherapy range from 33% to 57% [2]. Alternative treatment options beyond chemotherapy and radiation therapy are currently limited. Several biologic agents have been or are currently being investigated, but there is still a clear need for novel single agent or combination therapies for metastatic and recurrent endometrial cancer. Biological therapies that target the extracellular signal-regulated (ERK) pathway for the treatment of endometrial cancer represent a particularly promising avenue of investigation. ERK activation occurs in greater than 50% of endometrial cancers, as evidenced by phospho-ERK positivity measured  by immunohistochemistry ([3] and our unpublished findings). Approximately 15% of endometrial tumors carry fibroblast growth factor receptor (FGFR) 2 mutations and a similar fraction have KRAS mutations [4  –  6]. The fact that FGFR2 and KRAS mutations are mutually exclusive in endometrial cancers points to the importance of activation of the ERK pathway [5]. Additionally, ERK activation is seen in endometrial cancers without mutations in KRAS and FGFR2 [3] (and our unpublished data). At present the role that the ERK signaling pathway plays in both the normal endometrium and endometrial tumsrcenesis is poorly understood. Furthermore, the downstream substrates of ERK signaling that are important in the endometrial epithelium and their roles in endometrial carcinogenesis remain largely unknown. Loss-of-function (LOF) mutations of PTEN, a tumor suppressor gene, are frequently found in endometrial cancers [7,8]. PTEN, a lipid phosphatase, functions as a negative regulator of the  phosphatidylinositol 3-kinase (PI3K) signaling cascade [9]. PTEN LOF mutations thus activate the PI3K pathway, resulting in phosphorylation and activation of the key component protein kinase B (PKB, aka AKT), and elicit a survival signal that promotes cell proliferation and protects cells from   Int. J. Mol. Sci.   2013 , 14 16619 undergoing apoptosis induced by various stresses [10,11]. Other alterations that could result in PI3K/AKT pathway activity changes are mutations in the PIK3CA (p110α)  gene, which encodes the catalytic subunit of PI3K, as well as the PIK3R1 (p85α) and PIK3R2 (p85β) genes, which both encode inhibitory subunits of PI3K. Somatic mutations of these genes were frequently detected in primary endometrial cancers, most of which resulted in gain of function of the PI3K pathway [12  –  14]. In addition, these mutations are often accompanied by PTEN mutations, and are thought to have an additive effect to PTEN monoallelic inactivation in endometrial carcinogenesis [15]. PKB/AKT exerts its functions through phosphorylation of substrates that are involved in the crucial steps of cell survival and cell cycle progression, including the forkhead box transcription factors (FOXO), the cell-cycle inhibitor p27, the mTOR pathway inhibitor tuberous sclerosis complex 2 (TSC2), and glycogen synthase kinase 3 (GSK3) [16  –  19]. GSK3β , a serine/threonine kinase involved in many fundamental cellular processes, is a particularly important downstream mediator of the AKT/PI3K pathway as it regulates a variety of carcinogenic events including cell survival, proliferation and differentiation [20  –  22]. It has been shown that GSK3β can  be phosphorylated by the ERK kinase, and can modulate the activity of several major tumsrcenic pathways including the canonical WNT  pathway, NF- κB signaling, and the p53-induced apoptotic pathway. The most established role for GSK3 β  is to phosphorylate β -catenin, the critical mediator of canonical WNT signaling, which results in its degradation. Notably, the role for GSK3 β  in carcinogenesis is largely context dependent. In certain cancers, GSK3 β  functions as a tumor suppressor gene and its inactivation is associated with Cdc25a overexpression [23]. In contrast, accumulating evidence suggest that GSK3 β  functions as an oncogene and promotes proliferation and augments cell survival, and has been proposed as a potential therapeutic target for cancer treatment[24]. Treatment with LiCl, a chemical inhibitor of GSK3 β ,  promotes survival of mice in a leukemia model [25]. Similarly, LiCl treatment selectively decreased cell proliferation in breast and colon cancer cells with a mutant PIK3CA knock-in [26]. The function of GSK3β in endometrial carcinogen esis has not been fully elucidated. In the current study, we explored effects of GSK3 β  inhibitors, lithium chloride and GSK3 β  inhibitor VIII (AR-A014418), on multiple human endometrial cancer cell lines. Both reagents inhibited endometrial cancer cell growth by inducing cell cycle arrest. Treatment of mice carrying human endometrial cancer xenografts with lithium-supplemented water showed evidence of complete or partial regression in some tumors. Our results indicate that GSK3 β  activity is associated with endometrial cancer tumsrcenesis and that its pharmacologic inhibition reduces cell proliferation and tumor growth. 2. Results 2.1. Cytostatic Effect of Lithium Chloride Treatment in Endometrial Cancer Cell Lines To test the effect of GSK3 β  inhibition on endometrial cancer cell growth, the endometrial cancer cell lines AN3CA (type I) and ARK1 (type II), as well as an immortalized normal endometrial epithelial cell line EM-E6/E7/TERT (hereinafter referred to as EM-TERT) [27] were treated with control media or media with 10 mM LiCl. The effect of LiCl treatment was assessed using the MTT assay at 24-hour intervals out to 96 h. LiCl treatment resulted in reduced cell viability/proliferation in  both the AN3CA and ARK1 cancer cell lines in a time-dependent manner, whereas EM-TERT control   Int. J. Mol. Sci.   2013 , 14 16620 cells were not affected (Figure 1). Treatment of the AN3CA with 10 mM LiCl resulted in a significant reduction in cell viability/proliferation by 48 h (50.3% reduction,  p  = 0.04), and the reduction remained significant through 72 and 96 h (69.1% reduction,  p  < 0.0005 and 63.7% reduction,  p  < 0.0005, respectively compared to controls,). Similar effects on ARK1 cells were observed (54.6% reduction,  p  < 0.005 at 72 h and 76.2% reduction,  p  < 0.005 at 96 h, respectively compared to controls). In both AN3CA and ARK1 cells, treatment of LiCl at a lower concentration of 1 mM showed reduced viability/proliferation; however, these effects varied between replicate experiments and seemed to be affected by seeding density (data not shown). No effect with treatment of 1 mM LiCl was observed in the EM-TERT cell line. Given that treatment with 10 mM LiCl showed an early, consistent and marked cytostatic effect in both cancer cell lines initially studied (AN3CA and ARK1), we used this dose to assess the effect of LiCl on growth of four additional endometrial cancer cell lines. Three out of the four cell lines (HEC1A, ISHIKAWA and RL952) exhibited reduced cell viability/proliferation at 96 h, with HEC1A and RL952 cells showing an early response. KLE cells, like the EM-TERT normal endometrial epithelial cell line, showed no change in growth as measured  by MTT over the time course tested. The KLE cells have a noticeable longer doubling time than the other cell lines investigated (Figure 1, note the reduced steepness of the growth curve of KLE compared to all other cell lines), hence it is possible that the increased length of cell cycle over the 96 h treatment period may have masked any effect of LiCl on its growth. Western blot analysis confirmed the inhibitory effect of LiCl on GSK3 β , as LiCl treatment resulted in increased levels of  phosphorylation of serine 9 residue (pSer9) GSK3 β  [28,29] in both the EM-TERT and AN3CA cell lines, with AN3CA cancer cells showing a higher pSer9/total GSK3 β  ratio (Figure S1). Intriguingly, Western Blot on active form of GSK3β (pTyr216) revealed a m arked higher basal level in untreated AN3CA and ARK1 cell lines than the control EM-TERT cell line (Figure 1C), indicating abnormal hyperactivity of GSK3β in endometrial cancer cell lines. Figure 1.  Growth inhibitory effects of LiCl on endometrial cancer cell lines. ( A , B ) Representative results for MTT assays performed 0  –  96 h post treatment with 10 mM LiCl. Cell proliferation/viability was significantly reduced in five of six endometrial cancer cell lines, with no effects seen with the immortalized human endometrial cell line, EM-TERT or the KLE tumor cell line. *    p  < 0.05; **    p  < 0.01 compared to the control by Student’s t  -test; ( C ) Western blot revealed high level of active GSK3β in AN3CA and ARK1 cancer cell lines.  
We Need Your Support
Thank you for visiting our website and your interest in our free products and services. We are nonprofit website to share and download documents. To the running of this website, we need your help to support us.

Thanks to everyone for your continued support.

No, Thanks