Abstract
Elements of the Notch pathway regulate differentiation; we investigated the expression of such elements in epithelial ovarian tumours. A total of 32 ovarian tumour samples (17 adenocarcinomas, three borderline tumours, 12 adenomas), two human ovarian cancer (A2780, OVCAR3), and one ovarian surface (IOSE 144) cell lines were analysed. The expression of Notch pathway elements was assessed by RT–PCR, real-time PCR (Notch 1), and by immunoblots (Notch 1 extracellular domain (EC), HES1). The proliferation and colony formation of A2780 cells were measured after stable transfection with activated Notch 1 (intracellular domain). Jagged 2, Delta-like-1, Manic Fringe, and TSL1 were expressed more frequently in adenocarcinomas whereas Deltex, Mastermind, and Radical Fringe were more frequent in adenomas. Quantitative PCR revealed decreased Notch 1 mRNA in ovarian adenocarcinomas compared with adenomas. The expression of Notch 1-EC protein was similar in benign and malignant tumours. HES1 protein was strongly expressed in 18/19 ovarian cancers and borderline tumours but not in adenomas. Transfecting A2780 cells with active Notch 1-IC resulted in a proliferative and colony formation advantage compared to mock transfected cells. Thus, Notch pathway elements are expressed in ovarian epithelial tumours and some of them are differentially expressed between adenomas and carcinomas. The Notch pathway could be a target for the development of therapies for ovarian cancer.
Similar content being viewed by others
Main
The cellular origin, histology, and biological properties of ovarian neoplasms is heterogeneous and complex. About 90% of ovarian tumours are adenomas and adenocarcinomas derived from ovarian surface epithelium (OSE) of coelomic origin. Currently, ovarian adenocarcinomas are thought to arise from OSE inclusion cysts that form after OSE injury such as ovulation. The impaired ability of inclusion cyst cells to acquire a mesenchymal phenotype and the appearance of a gland-like differentiation of the otherwise more pluripotent mesodermal precursors resembling OSE cells is a hallmark of carcinogenesis (Scully, 1995). The molecular pathogenesis of ovarian adenocarcinomas is unknown although some mechanisms have been elucidated recently. Loss of function mutations of tumour suppressor genes have been described such as p53 in late stage tumours (Kupryjanczyk et al, 1993), PTEN in endometroid ovarian carcinomas (Obata et al, 1998), BRCA1 and BRCA2 in familial ovarian cancers (Ford et al, 1998; Kote-Jarai and Eeles, 1999). Overexpression or amplification of oncogenes have been described for PI3K (Philp et al, 2001) and its downstream effector AKT2 (Cheng et al, 1992), EGF-R (Kohler et al, 1989), cMyc (Tashiro et al, 1992), K-ras (Enomoto et al, 1991) and c-erbB (HER2/neu) (Slamon et al, 1989). In a recent study we demonstrated that p73, a member of the p53 family, is expressed in ovarian adenocarcinoma but rarely in adenoma (Zwahlen et al, 2000). P73 and p63 increase the expression of the Notch ligands Jagged 1 and 2 (Sasaki et al, 2002) leading to increased expression of the Notch target HES1 in coculture assays. It appears likely that deranged proliferation and cell fate determination processes are of particular importance in the development of ovarian cancer. The Notch pathway with its family of four mammalian Notch receptors and their numerous ligands of the Delta and the Jagged/Serrate group is playing an important role in cell fate determination and organogenesis during the embryonic development and in haematopoiesis (Artavanis-Tsakonas et al, 1999; Miele and Osborne, 1999; Milner and Bigas, 1999). Figure 1 outlines the Notch signalling network: the Notch genes encode transmembrane receptor proteins of about 300 kDa that undergo post-translational modification by intramolecular cleavage and heterodimer formation. Upon interaction with a ligand, a complex cleavage process of the Notch receptor is initiated, resulting in the release of the intracellular c-terminal domain (approximately 110 kDa). The activating ligands, including Jagged 1, Jagged 2 (JAG 1 and JAG 2), Delta-like-1, -3 and -4 (DLL1, DLL3 and DLL4), are mainly expressed on the surface of neighbouring cells. The intracellular Notch domain then translocates to the nucleus to interact with the transcriptional repressor CBFl/RBP-Jk (Hsieh et al, 1996), turning it into a transcriptional activator of numerous target genes such as the HES1 gene, a member of the basic helix–loop–helix family of transcription factors (Bailey and Posakony, 1995; Davis and Turner, 2001). In developmental processes, Notch signalling often results in the preservation of a small subset of proliferating undifferentiated and multipotent progenitor cells. However, the net effect of Notch signalling tends to be highly dependent on the cellular context. In a small subset of human acute lymphoblastic T-cell leukaemia a constitutively active Notch 1 mutant functions as an oncogene (Ellisen et al, 1991). Conversely activated Notch 1 and Notch 2 have been shown to result in a growth arrest of small cell lung cancer cells, where it seems to act as a tumour suppressor gene (Sriuranpong et al, 2001). Furthermore, Notch 1 has been shown to function as a tumour suppressor gene in mouse skin (Nicolas et al, 2003). In the present study, we show that many elements of the Notch pathway are expressed in epithelial ovarian tumours with carcinomas having higher HES1 protein expression levels than adenomas indicating a stronger Notch pathway activation. Furthermore, we demonstrate a proliferative and survival advantage of stably Notch 1-IC (intracellular domain) transfected A2780 ovarian carcinoma cells. We propose that the Notch pathway could be a target for the development of novel therapies for ovarian cancer.
Material and methods
Patient characteristics and tumour specimens
Tumour samples were obtained from 32 patients who underwent surgical resection of an ovarian tumour at the university hospitals of Berne and Zurich, Switzerland. Sample collection was in accordance with Swiss law and approved by the local institutional review board. At the time of surgery no patient had received chemotherapy. The tissues for the present study were selected by the surgeons who were careful to submit large (>1 cm) pieces of tissue that were macroscopically tumourous. Adjacent tissues were used for the pathological diagnosis. The age range of the patients was 40–83 years (median 61 years). Tumours were classified in accordance with the WHO standard criteria (Tavassoli and Devilee, 2003) as ovarian epithelial adenocarcinomas (17 cases), epithelial ovarian cancers of low malignant potential (three cases) and ovarian adenomas (12 cases). Tumour samples were snap frozen in liquid nitrogen in the operating theatre immediately after surgical removal.
Cell lines and culture conditions
Human ovarian adenocarcinoma cell lines A2780 and 2008 (kindly provided by Dr S Howell, University of California San Diego, La Jolla, CA, USA) were maintained in RPMI-1640 medium (Sigma, St Louis, MO, USA) supplemented with 10% heat-inactivated fetal calf serum (FCS, Sigma), the human ovarian adenocarcinoma cell line OVCAR-3 (ATCC, Rockville, MD, USA) was maintained in DMEM (Sigma) supplemented with 10% heat-inactivated FCS. The human Hodgkin's lymphoma cell line L540 (DSMZ, Braunschweig, Germany) was maintained in RPMI-1640 medium supplemented with 10% heat-inactivated FCS, and the human ovarian surface epithelial cell line IOSE-144 (kindly provided by Dr N Auersperg, University of Vancouver, Canada) was maintained in MCDB105 with L-glutamine (Sigma) and 25 mM HEPES+Medium 199 with Earle's salt and L-glutamine (Sigma) (1 : 1) supplemented with 5% heat-inactivated FCS and 50 μg ml−1 gentamicin (Sigma).
RNA extraction and RT–PCR
After homogenisation of tumours using a tissue homogeniser (Polytron, Kinematica, Littau, Switzerland), total RNA was extracted using the RNeasy/QIAamp Kit (Quiagen, Basel, Switzerland). Contaminating genomic DNA was removed by DNase I treatment according to the manufacturer's instructions (RNase-Free DNase Set, Quiagen). Reversed transcription was performed using 1 μg total RNA, 0.8 μg primer oligo dT15 primers (Roche, Rotkreuz, Switzerland), 1.3 μl PCR Nucleotide Mix, 10 mM deoxynucleotide triphosphate (Roche), 28 U rRNasin (Promega, Wallisellen, Switzerland), 5 μl M-MLV 5 × buffer (Promega), 200 U M-MLV reverse transcriptase (Promega) in a final volume of 25 μl. PCR was carried out at least as duplicates as follows: 5 μl cDNA as template were added to a mastermix made of 3 μl 10 × PCR buffer+Mg (Roche), 3 μl glycerol, 3 μl PCR nucleotide mix, 1 mM deoxynucleotide triphosphate (Roche), 0.8 U Taq DNA polymerase (Roche), sense and antisense primers with a final concentration of 266 nM. Thermocycler conditions were as described elsewhere (Zwahlen et al, 2000). The annealing temperature was optimised for each primer pair and 35–37 PCR cycles were applied. The following human glyceraldehyde-3-phosphate dehydrogenase (GAPDH) primers were used for quality control of RT-PCR for each cDNA generated, sense: 5-GAGCTGAACGGGAAGCTCACTGG-3; antisense: 5-CAACTGTGAGGAGGGGAGATTCAG-3. PCR products were separated on a 1% agarose gel containing ethidium bromide. The primers used for the detection of cDNA of Notch pathway genes are shown in Table 1.
Real-time quantitative RT–PCR for hNotch 1
TaqMan real-time RT–PCR (TaqMan PCR detector 7700, Perkin-Elmer Applied BioSystems, Rotkreuz, Switzerland) was used for relative quantification of hNotch 1 (Gene Bank accession no. AF308602) gene expression in human ovarian tumour samples and cell lines as described previously (Leonard et al, 2000). The preparation of cDNA was carried out as described above. Dual labelled (FAM/TAMRA) gene-specific probes and TaqMan Universal PCR Master Mix (Perkin-Elmer Applied BioSystems, Rotkreuz, Switzerland) were used. Sequences of hNotch 1 specific oligonucleotides were as follows, probe: 5′-CCGCTCTGCAGCCGGGACA-3′; forward primer: 5′-CACTGTGGGCGGGTCC-3′; reverse primer, 5′-GTTGTATTGGTTCGGCACCAT-3′ (Shou et al, 2001). Notch 1 gene expression was normalised to the expression level of the housekeeping gene porphobilinogen deaminase (PBGD, Gene Bank accession no. Ml8799). Sequences for PBGD-specific oligonucleotides were as follows, probe: 5′-TGCGGCTGCAACGGCGGAAGAAA-3′; forward primer: 5′-GGAGCCATGTCTGGTAACGGCA-3′; reverse primer: 5′-GGTACCCACGCGAATCACTCTCA-3′. Primers were used at a final concentration of 300 μ M; the final probe concentration used was 150 μ M. In total, 2.5 μl cDNA and 12.5 μl TaqMan Universal PCR Master Mix were added to a final reaction volume of 25 μl. A total of 45 TaqMan PCR-cycles were run under standard conditions.
Western blot analysis
Cell extracts were prepared as described (Zwahlen et al, 2000). Briefly, after tissue homogenisation and sonication, cells were lysed in RIPA buffer (150 mM NaCl, 1.0% Nonidet P-40, 0.5% sodium desoxycholate, 0.1% sodium dodecyl sulfate, 50 mM Tris, pH 8.0) on ice for 30 min, followed by centrifugation for 20 min at 4°C. Quantification was done by Bradford assay (Bio-Rad, Glattbrugg, Switzerland). In all, 50 μg total cellular protein per lane were size fractioned on a 7% tris-acetate gel (Invitrogen, Paisley, UK) for Notch 1 detection or on a 4–12% tris-glycine gradient gel (Invitrogen) for HES1 detection and blotted onto nitrocellulose (Protan; Schleicher and Schuell, Kassel, Germany). Equal loading and transfer efficiency was visually checked by Ponceau staining. Membranes were blocked for 3 h at room temperature with 5% w/v nonfat dry milk/TBS and Tween-20 (0.05% w/v). Membranes were incubated with rabbit polyclonal anti-Notch 1 antibodies (H-131, Santa Cruz, Nunningen, Switzerland) for the detection of the extracellular domain of Notch 1. For the detection of HES1, membranes were incubated with a rabbit polyclonal anti-HESl antibody (kindly provided by Dr Sudo, Toray Industries, Kanagawa, Japan). Detection of primary antibody binding was done with donkey antirabbit horseradish peroxidase conjugated antibodies, followed by enhanced chemiluminescence detection (all from Amersham, Zurich, Switzerland). Equal loading was assessed visually by detection of actin with a rabbit polyclonal antibody (A2066, Sigma) after stripping and reblocking of the membranes. The Hodgkin's Lymphoma cell line L540 served as a positive control for Notch 1 extracellular domain expression (Jundt et al, 2002). HES1 protein was in vitro synthesised by the TNT T7 Quick Coupled Transcription/Translation System (Promega) from the mHESl cDNA in pBluescript SK+ (kindly provided by Dr R Kageyama, Kyoto University, Japan). Each experiment was repeated at least twice, and the strenght of expression was scored visually by assigning one of four scores (strong, intermediate, weak, and absent; cf, Figure 2).
Transfection and colony forming assay+proliferation assay
The ovarian adenocarcinoma cell line A2780 was transfected with hNotch 1-IC-HA (pCDNA3 Invitrogen) as previously described (Chen et al, 1997). Empty vector transfected cells were used as controls. Transfection was done by electroporation, applying 5 μg plasmid DNA per 1 million cells. Selection was performed with G418 at 600 μg ml−1. The resultant G418 resistant clones were pooled and used directly for colony forming and proliferation assays. The latter was carried out by the XTT method according to the manufacturer's instructions (Biological Industries, Beit Haemek, Israel). In total, 1000 cells were seeded in 9 cm wells in selection medium as indicated above. XTT assay was performed on days 4, 7, 8, 10 and 12. For the colony forming assays 300 cells of a single cell suspension were seeded in 10 cm Petri dishes and counted 7 days after when the colonies were visible by eye. All experiments were performed in triplicate.
Dual luciferase-assay
Notch pathway activation of the stably hNotch 1-IC-HA transfected A2780 was tested by transient transfection of 1 million cells from pooled G418-resistant clones, using electroporation, with 5 μg of a reporter plasmid containing the Notch/RBP-Jκ-responsive region of the Hairy and Enhancer of Split homologue-1 (HES1) promoter as described previously (Rangarajan et al, 2001). Empty vector transfected cells served as controls. In all cases 100 ng of a renilla luciferase expression plasmid (pRL-CMV, Promega) were cotransfected. The Dual-Luciferase reporter assay (Promega) was performed according to the manufacturer's specifications 48 and 72 h after transfection.
Results
RT–PCR analysis of the expression pattern of elements of the notch pathway in ovarian tumours
To test the hypothesis that the Notch pathway could be involved in the pathogenesis of ovarian carcinomas we studied the mRNA expression pattern of some of its elements by RT–PCR in 32 ovarian tumour samples (17 ovarian adenocarcinomas, three ovarian cancers of low malignant potential, 12 ovarian adenomas), three ovarian cancer cell lines (A2780, OVCAR-3, 2008), and one human ovarian surface epithelial cell lines (IOSE-144). GAPDH was detected in all samples, indicating similar quality of extracted mRNA. The results are summarised in Table 2 and representative samples of RT–PCR products are shown in Figure 2. Notch 1 (see below), Jagged 1, Delta-like-2/4, HES1 and Presenillin expression was detectable in all ovarian adenocarcinomas and ovarian adenomas (for Notch 1 only real-time RT–PCR data are shown). In contrast, ovarian adenocarinomas were more frequently positive than adenomas for the Notch ligands Jagged 2 (P=0.04, Fisher's exact test, two-sided probabilities are shown without adjustment for multiple testing) and Delta-like-1 (P=0.056), for the modulator of ligand specificity Manic Fringe (P=0.0007) and for the downstream transcription factor Transducin-like Enhancer of split-1 (TSL1; P=0.01). On the other hand, slightly higher frequencies of expression were found in adenomas for Deltex and Mastermind, and Radical Fringe.
The expression pattern of elements of the Notch pathway in ovarian cancer cell lines was similar to ovarian adenocarcinomas with the exception of Jagged 2, Delta-like-1, Delta-like-2 and TSL4 that were expressed at a lower frequency.
Real-time quantitative RT–PCR for hNotch 1
Altered Notch 1 expression has been found in certain haematologic malignancies and solid tumours. To study the Notch 1 mRNA expression level we used TaqMan real-time quantitative RT–PCR for the screening of human ovarian tumours and cell lines. Primers and probes were selected for the intracellular domain of Notch 1. We did not detect overexpression of Notch 1 mRNA in ovarian adenocarcinomas (median expression level relative to PBGD : 0.35), but a tendency towards decreased Notch 1 expression in comparison to ovarian adenomas (median : 0.705; Figure 3).
Expression pattern of Notch 1 and HES1 protein
We further investigated the protein expression pattern of full length Notch 1 (330–220 kDa), the Notch 1 extracellular domain (Notch 1-EC, 120 kDa) and of the downstream transcription factor HES1 (32 kDa) in 28 of the 32 ovarian tumours (16 ovarian carcinomas, three borderline tumours, nine ovarian adenomas), in three human ovarian cancer cell lines and one ovarian surface epithelium cell line. In four ovarian tumours the amount of extracted protein was insufficient for immunoblotting. The Hodgkin's lymphoma cell line L540 served as positive control for Notch 1-EC expression and in vitro translated mHESl cDNA for HES1 protein expression. Results are summarised in Table 3 and representative samples are depicted in Figure 4. Similar amounts of β-actin protein expression were detected in all tumour and cell line specimens. Notch 1 and Notch 1-EC protein was expressed in all ovarian cancers, borderline tumours and ovarian adenomas at similar levels. In ovarian cancer cell lines the expression of Notch was a strong expression of Notch 1-EC in A2780, an intermediate expression in OVCAR-3, but a lower expression level in IOSE-144.
The expression level of HES 1 protein on the other hand trended to be higher in the malignant than in the benign tumours: in invasive adenocarcinomas and borderline tumours, the expression was intermediate in 11 out of 19 and strong in seven out of 19 samples, whereas in ovarian adenomas five out of nine specimens showed intermediate and four out of nine weak or absent expression. However, in all ovarian adenocarcinoma and surface epithelium cell lines the HESl protein expression was very high at similar levels.
Stable transfection of Notch 1-IC in A2780 ovarian adenocarcinoma cell line
The observation of a consistent expression of Notch 1 protein in ovarian adenocarcinomas and adenomas does not prove that Notch 1 signalling is actually active. The expression of HESl could be induced by other upstream factors such as Notch 2 or possibly Sonic Hedgehog (Shh) (Solecki et al, 2001). Therefore, we investigated the biological relevance of activated Notch 1 by stably transfecting the cell line A2780 with Notch 1-IC, the functionally active intracellular domain of the Notch 1 heterodimer, in order to increase the degree of Notch pathway activation. The biological activity of transfected Notch 1-IC was confirmed by a dual luciferase reporter-plasmid assay. The normalised luciferase activity was 127% higher in hNotch 1-IC-HA stably transfected A2780 than in empty vector controls 48 h after transient transfection and 72% after 72 h. When compared to the wild type, the hNotch 1-IC-HA transfected A2780 cells derived from pooled clones showed a proliferative advantage from day 7 onwards after cells reached confluence (Figure 5). The metabolic activity measured by the XTT-assay, mirroring cell mass, was on average 32±7.5% higher in the Notch 1-IC stably transfected A2780 cells compared to mock controls from day 7 on over the observation period. To test if the survival potential of A2780 was changed due to an increased Notch pathway activation, we carried out colony-forming assays. After 7 days approximately 28±12% more colonies formed from single cells of stably hNotch 1-IC-HA transfected cells compared to mock transfected controls.
Discussion
In the present study, we have shown differences in the mRNA and protein expression profile for certain elements of the notch pathway (receptors, ligands, modulators and downstream signalling factors) between ovarian adenocarcinomas, borderline tumours and ovarian adenomas: We could show a higher HESl protein expression in ovarian cancers and borderline tumours in comparison to adenomas. Transfection experiments with activated Notch 1 intracellular domain in A2780 ovarian adenocarcinoma cells indicated a proliferative advantage due to Notch 1 that is consistent with an impaired contact inhibition at confluence. The growth advantage of Notch 1-IC transfected A2780 cells in comparison to empty vector controls was also evident by their enhanced ability to form colonies from single cells on plastic surfaces (colony-forming units) (Bashey et al, 1992; Yu et al, 1999). The magnitude of in vitro growth effects was modest, but similar to recent observations with c-Myc (Pelengaris et al, 2002), the contribution to in vivo tumour formation could be significant. Altered Notch expression has already been observed in cervical carcinomas (Zagouras et al, 1995), lung cancer (Dang et al, 2003), pancreatic cancer (Miyamoto et al, 2003), breast cancer (Weijzen et al, 2002), and endometrium carcinomas (Suzuki et al, 2000). In early hematopoietic stem cells Notch-signalling stops differentiation and maintains a pool of proliferating pluripotent cells (Milner and Bigas, 1999; Ohishi et al, 2002; Kunisato et al, 2003). Of interest, the OSE is closer in its differentiation state to the pluripotent mesodermal embryonic precursor cells than other epithelial derivates (Scully, 1995). Although overexpression of Notch 1 mRNA or protein has not been found in ovarian tumours, our data point to a possible role of the Notch pathway in ovarian cancer formation: our transfection experiments indicate, that activation of the Notch pathway could contribute to the malignant phenotype by maintaining proliferative activity against growth control signals and by promoting cell survival. Expression array data have revealed that at least two members of the Notch-signalling network may be involved in the ovarian carcinogenesis: Notch 3 was at least three-fold overexpressed over normal ovarian surface epithelial cells (Lu et al, 2004) and a similar observation was reported for Jagged 2 (Euer et al, 2005). These studies did not identify the same genes as overexpressed in ovarian cancer although they used similar methods; thus, these finding as well as our present study should be considered preliminary. How in detail the Notch pathway exerts its oncogenic function has not been fully elucidated. A recent study showed that CBF1, the first major downstream signalling factor of the Notch pathway, when activated, interacts with the Cyclin Dl promotor, resulting in increased CD1 activity and Gl/S-phase transition (Ronchini and Capobianco, 2001). Furthermore Notch-IC activated CBF1 induces the transcription of NFκB(Oswald et al, 1998).
Besides it has been shown that NFκB controls the expression of the Notch ligand Jagged 1 in a positive feedback loop (Bash et al, 1999). It is likely, however, that Notch alone is not capable of transforming cells but requires the functional collaboration of other oncogenes, namely from the RAS (IRK, MAP kinase, PI3 kinase) (Fitzgerald et al, 2000; Weijzen et al, 2002) and c-Myc pathways (Rao and Kadesch, 2003). PI3K (Philp et al, 2001) and c-Myc (Tashiro et al, 1992) overexpression have been reported for ovarian adenocarcinomas.
Several questions about the function of Notch in ovarian tumours still remain to be answered. The relevance of other receptors of the Notch family has not been elucidated yet. Likewise, it is not known what regulates the degree of Notch pathway activation in ovarian tumours. The expression pattern of Notch ligands might play a crucial role though. Interestingly our preliminary data point to a robust protein expression of Jagged 1 in ovarian tumours. If relevant cell–cell interactions are homotypic (between tumour cells themselves) or heterotypic (between tumour cells and other cells e.g. stroma cells) remains to be determined.
In summary, the Notch-signalling pathway is operative in ovarian cancer, and we propose a positive relationship between Notch pathway activation as indicated by HES1 protein expression levels and tumour growth in ovarian cancer. This hypothesis will need to be addressed in further studies. Moreover, elements of the Notch pathway could be worthwhile targets for future therapies of ovarian cancer (Jang et al, 2000; Nickoloff et al, 2003) such as siRNA and gamma-secretase inhibitors (Elbashir et al, 2001; Kimberly et al, 2003; Micchelli et al, 2003).
Change history
16 November 2011
This paper was modified 12 months after initial publication to switch to Creative Commons licence terms, as noted at publication
References
Artavanis-Tsakonas S, Rand MD, Lake RJ (1999) Notch signaling: cell fate control and signal integration in development. Science 284: 770–776. doi:10.1126/science.284.5415.770
Bailey AM, Posakony JW (1995) Suppressor of hairless directly activates transcription of enhancer of split complex genes in response to Notch receptor activity. Genes Dev 9: 2609–2622
Bash J, Zong WX, Banga S, Rivera A, Ballard DW, Ron Y, Gelinas C (1999) Rel/NF-kappaB can trigger the Notch signaling pathway by inducing the expression of Jagged1, a ligand for Notch receptors. EMBO J 18: 2803–2811
Bashey A, Gill R, Levi S, Farr CJ, Clutterbuck R, Millar JL, Pragnell IB, Marshall CJ (1992) Mutational activation of the N-ras oncogene assessed in primary clonogenic culture of acute myeloid leukemia (AML): implications for the role of N-ras mutation in AML pathogenesis. Blood 79: 981–989
Chen Y, Fischer WH, Gill GN (1997) Regulation of the ERBB-2 promoter by RBP Jkappa and NOTCH. J Biol Chem 272: 14110–14114
Cheng JQ, Godwin AK, Bellacosa A, Taguchi T, Franke TF, Hamilton TC, Tsichlis PN, Testa JR (1992) AKT2, a putative oncogene encoding a member of a subfamily of protein-serine/threonine kinases, is amplified in human ovarian carcinomas. Proc Natl Acad Sci USA 89: 9267–9271
Dang TP, Eichenberger S, Gonzalez A, Olson S, Carbone DP (2003) Constitutive activation of Notch3 inhibits terminal epithelial differentiation in lungs of transgenic mice. Oncogene 22: 1988–1997. doi:10.1038/sj.onc.l206230
Davis RL, Turner DL (2001) Vertebrate hairy and Enhancer of split related proteins: transcriptional repressors regulating cellular differentiation and embryonic patterning. Oncogene 20: 8342–8357
Elbashir SM, Harborth J, Lendeckel W, Yalcin A, Weber K, Tuschl T (2001) Duplexes of 21-nucleotide RNAs mediate RNA interference in cultured mammalian cells. Nature 411: 494–498. doi:10.1038/35078107
Ellisen LW, Bird J, West DC, Soreng AL, Reynolds TC, Smith SD, Sklar J (1991) TAN-1, the human homolog of the Drosophila notch gene, is broken by chromosomal translocations in T lymphoblastic neoplasms. Cell 66: 649–661
Enomoto T, Weghorst CM, Inoue M, Tanizawa O, Rice JM (1991) K-ras activation occurs frequently in mucinous adenocarcinomas and rarely in other common epithelial tumors of the human ovary. Am J Pathol 139: 777–785
Euer NI, Kaul S, Deissler H, Mobus VJ, Zeillinger R, Weidle UH (2005) Identification of LI CAM, Jagged2 and Neuromedin U as ovarian cancer-associated antigens. Oncol Rep 13: 375–387
Fitzgerald K, Harrington A, Leder P (2000) Ras pathway signals are required for notch-mediated oncogenesis. Oncogene 19: 4191–4198
Ford D, Easton DF, Stratton M, Narod S, Goldgar D, Devilee P, Bishop DT, Weber B, Lenoir G, Chang-Claude J, Sobol H, Teare MD, Struewing J, Arason A, Scherneck S, Peto J, Rebbeck TR, Tonin P, Neuhausen S, Barkardottir R, Eyfjord J, Lynch H, Ponder BA, Gayther SA, Zelada-Hedman M (1998) Genetic heterogeneity and penetrance analysis of the BRCA1 and BRCA2 genes in breast cancer families. The Breast Cancer Linkage Consortium. Am JHum Genet 62: 676–689
Hsieh JJ, Henkel T, Salmon P, Robey E, Peterson MG, Hayward SD (1996) Truncated mammalian Notch 1 activates CBFl/RBPJk-repressed genes by a mechanism resembling that of Epstein–Barr virus EBNA2. Mol Cell Biol 16: 952–959
Jang MS, Zlobin A, Kast WM, Miele L (2000) Notch signaling as a target in multimodality cancer therapy. Curr Opin Mol Ther 2: 55–65
Jundt F, Anagnostopoulos I, Forster R, Mathas S, Stein H, Dorken B (2002) Activated Notch 1 signaling promotes tumor cell proliferation and survival in Hodgkin and anaplastic large cell lymphoma. Blood 99: 3398–3403. doi:10.1182/blood.V99.8.3060
Kimberly WT, Esler WP, Ye W, Ostaszewski BL, Gao J, Diehl T, Selkoe DJ, Wolfe MS (2003) Notch and the amyloid precursor protein are cleaved by similar gamma-secretase(s). Biochemistry 42: 137–144. doi:10.1021/biO26888g
Kohler M, Janz I, Wintzer HO, Wagner E, Bauknecht T (1989) The expression of EGF receptors, EGF-like factors and c-myc in ovarian and cervical carcinomas and their potential clinical significance. Anticancer Res 9: 1537–1547
Kote-Jarai Z, Eeles RA (1999) BRCA1, BRCA2 and their possible function in DNA damage response. Br J Cancer 81: 1099–1102. doi:10.1038/sj.bjc.6690814
Kunisato A, Chiba S, Nakagami-Yamaguchi E, Kumano K, Saito T, Masuda S, Yamaguchi T, Osawa M, Kageyama R, Nakauchi H, Nishikawa M, Hirai H (2003) HES-1 preserves purified hematopoietic stem cells ex vivo and accumulates side population cells in vivo. Blood 101: 1777–1783. doi:10.1182/blood-2002-07-2051
Kupryjanczyk J, Thor AD, Beauchamp R, Merritt V, Edgerton SM, Bell DA, Yandell DW (1993) p53 gene mutations and protein accumulation in human ovarian cancer. Proc Natl Acad Sci USA 90: 4961–4965
Leonard AE, Kelder B, Bobik EG, Chuang LT, Parker-Barnes JM, Thurmond JM, Kroeger PE, Kopchick JJ, Huang YS, Mukerji P (2000) cDNA cloning and characterization of human Delta5-desaturase involved in the biosynthesis of arachidonic acid. Biochem J 347 (Part 3): 719–724
Lu KH, Patterson AP, Wang L, Marquez RT, Atkinson EN, Baggerly KA, Ramoth LR, Rosen DG, Liu J, Hellstrom I, Smith D, Hartmann L, Fishman D, Berchuck A, Schmandt R, Whitaker R, Gershenson DM, Mills GB, Bast Jr RC (2004) Selection of potential markers for epithelial ovarian cancer with gene expression arrays and recursive descent partition analysis. Clin Cancer Res 10: 3291–3300
Micchelli CA, Esler WP, Kimberly WT, Jack C Berezovska O, Kornilova A, Hyman BT, Perrimon N, Wolfe MS (2003) Gamma-secretase/presenilin inhibitors for Alzheimer's disease phenocopy Notch mutations in Drosophila. FASEB J 17: 79–81. doi:10.1096/fj.02-0394fje
Miele L, Osborne B (1999) Arbiter of differentiation and death: Notch signaling meets apoptosis. J Cell Physiol 181: 393–409
Milner LA, Bigas A (1999) Notch as a mediator of cell fate determination in hematopoiesis: evidence and speculation. Blood 93: 2431–2448
Miyamoto Y, Maitra A, Ghosh B, Zechner U, Argani P, Iacobuzio-Donahue CA, Sriuranpong V, Iso T, Meszoely IM, Wolfe MS, Hruban RH, Ball DW, Schmid RM, Leach SD (2003) Notch mediates TGF alpha-induced changes in epithelial differentiation during pancreatic tumorigenesis. Cancer Cell 3: 565–576. doi:10.1038/nm754
Nickoloff BJ, Osborne BA, Miele L (2003) Notch signaling as a therapeutic target in cancer: a new approach to the development of cell fate modifying agents. Oncogene 22: 6598–6608. doi:10.1038/sj.onc.l206758
Nicolas M, Wolfer A, Raj K, Kummer JA, Mill P, van Noort M, Hui CC, Clevers H, Dotto GP, Radtke F (2003) Notch1 functions as a tumor suppressor in mouse skin. Nat Genet 33: 416–421. doi:10.1038/ngl099
Obata K, Morland SJ, Watson RH, Hitchcock A, Chenevix-Trench G, Thomas EJ, Campbell IG (1998) Frequent PTEN/MMAC mutations in endometrioid but not serous or mucinous epithelial ovarian tumors. Cancer Res 58: 2095–2097
Ohishi K, Varnum-Finney B, Bernstein ID (2002) Delta-1 enhances marrow and thymus repopulating ability of human CD34(+)CD38(−) cord blood cells. J Clin Invest 110: 1165–1174. doi:10.1172/JCI200216167
Oswald F, Liptay S, Adler G, Schmid RM (1998) NF-kappaB2 is a putative target gene of activated Notch-1 via RBP-Jkappa. Mol Cell Biol 18: 2077–2088
Pelengaris S, Khan M, Evan G (2002) c-MYC: more than just a matter of life and death. Nat Rev Cancer 2: 764–776. doi:10.1038/nrc904
Philp AJ, Campbell IG, Leet C Vincan E, Rockman SP, Whitehead RH, Thomas RJ, Phillips WA (2001) The phosphatidylinositol 3′-kinase p85alpha gene is an oncogene in human ovarian and colon tumors. Cancer Res 61: 7426–7429
Rangarajan A, Talora C Okuyama R, Nicolas M, Mammucari C, Oh H, Aster JC, Krishna S, Metzger D, Chambon P, Miele L, Aguet M, Radtke F, Dotto GP (2001) Notch signaling is a direct determinant of keratinocyte growth arrest and entry into differentiation. EMBO J 20: 3427–3436. doi:10.1093/emboj2F20.13.3427
Rao P, Kadesch T (2003) The intracellular form of notch blocks transforming growth factor beta-mediated growth arrest in MvlLu epithelial cells. Mol Cell Biol 23: 6694–6701. doi: 10.1128/MCB.23.18.6694-6701.2003
Ronchini C, Capobianco AJ (2001) Induction of cyclin Dl transcription and CDK2 activity by Notch(ic): implication for cell cycle disruption in transformation by Notch(ic). Mol Cell Biol 21: 5925–5934. doi:10.1128/MCB.21.17.5925-5934.2001
Sasaki Y, Ishida S, Morimoto I, Yamashita T, Kojima T, Kihara C Tanaka T, Imai K, Nakamura Y, Tokino T (2002) The p53 family member genes are involved in the Notch signal pathway. J Biol Chem 277: 719–724. doi:10.1074/jbc.M108080200
Scully RE (1995) Pathology of ovarian cancer precursors. J Cell Biochem Suppl 23: 208–218
Shou J, Ross S, Koeppen H, de Sauvage FJ, Gao WQ (2001) Dynamics of notch expression during murine prostate development and tumorigenesis. Cancer Res 61: 7291–7297
Slamon DJ, Godolphin W, Jones LA, Holt JA, Wong SG, Keith DE, Levin WJ, Stuart SG, Udove J, Ullrich A, Press MF (1989) Studies of the HER-2/neu proto-oncogene in human breast and ovarian cancer. Science 244: 707–712
Solecki DJ, Liu XL, Tomoda T, Fang Y, Hatten ME (2001) Activated Notch2 signaling inhibits differentiation of cerebellar granule neuron precursors by maintaining proliferation. Neuron 31: 557–568. doi:10.1016/S0896-6273(01)00395-6
Sriuranpong V, Borges MW, Ravi RK, Arnold DR, Nelkin BD, Baylin SB, Ball DW (2001) Notch signaling induces cell cycle arrest in small cell lung cancer cells. Cancer Res 61: 3200–3205
Suzuki T, Aoki D, Susumu N, Udagawa Y, Nozawa S (2000) Imbalanced expression of TAN-1 and human Notch4 in endometrial cancers. Int J Oncol 17: 1131–1139
Tashiro H, Miyazaki K, Okamura H, Iwai A, Fukumoto M (1992) c-myc over-expression in human primary ovarian tumours: its relevance to tumour progression. Int J Cancer 50: 828–833
Tavassoli FA, Devilee P (2003) Pathology and Genetics of Tumours of the Breast and Female Genital Organs. IARC WHO Classification of Tumours. Vol. 4. Lyon: IARC Press
Weijzen S, Rizzo P, Braid M, Vaishnav R, Jonkheer SM, Zlobin A, Osborne BA, Gottipati S, Aster JC, Hahn WC, Rudolf M, Siziopikou K, Kast WM, Miele L (2002) Activation of Notch-1 signaling maintains the neoplastic phenotype in human Ras-transformed cells. Nat Med 8: 979–986. doi:10.1038/nm754
Weng AP, Aster JC (2004) Multiple niches for Notch in cancer: context is everything. Curr Opin Genet Dev 14: 48–54. doi:10.1016/j.gde.2003.11.004
Yu Y, Xu F, Peng H, Fang X, Zhao S, Li Y, Cuevas B, Kuo WL, Gray JW, Siciliano M, Mills GB, Bast Jr RC (1999) NOEY2 (ARHI), an imprinted putative tumor suppressor gene in ovarian and breast carcinomas. Proc Natl Acad Sci USA 96: 214–219
Zagouras P, Stifani S, Blaumueller CM, Carcangiu ML, Artavanis-Tsakonas S (1995) Alterations in Notch signaling in neoplastic lesions of the human cervix. Proc Nad Acad Sci USA 92: 6414–6418
Zwahlen D, Tschan MP, Grob TJ, Peters UR, Fink D, Haenggi W, Altermatt HJ, Cajot JF, Tobler A, Fey MF, Aebi S (2000) Differential expression of p73 splice variants and protein in benign and malignant ovarian tumours. Int J Cancer 88: 66–70. doi:10.1097/00005373-200001000-00008
Acknowledgements
Grant support: Swiss Cancer League SKL 986-02-2000. We thank Dr R Kageyama, Kyoto, Japan, for providing HES1 cDNA, Dr T Sudo, Toray Industries Kanagawa, Japan, for providing the HES1 antibody, Professor D Fink, University Hospital Zurich and Professor HJ Altermatt, Berne for their help in collecting tumour samples.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
From twelve months after its original publication, this work is licensed under the Creative Commons Attribution-NonCommercial-Share Alike 3.0 Unported License. To view a copy of this license, visit http://creativecommons.org/licenses/by-nc-sa/3.0/
About this article
Cite this article
Hopfer, O., Zwahlen, D., Fey, M. et al. The Notch pathway in ovarian carcinomas and adenomas. Br J Cancer 93, 709–718 (2005). https://doi.org/10.1038/sj.bjc.6602719
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1038/sj.bjc.6602719
Keywords
This article is cited by
-
Notch signaling pathway: architecture, disease, and therapeutics
Signal Transduction and Targeted Therapy (2022)
-
Signaling pathways and their potential therapeutic utility in esophageal squamous cell carcinoma
Clinical and Translational Oncology (2022)
-
Targeting of Lung Cancer Stem Cell Self-Renewal Pathway by a Small Molecule Verrucarin J
Stem Cell Reviews and Reports (2019)
-
Notch and its oncogenic activity in human malignancies
European Surgery (2017)
-
Notch signaling in serous ovarian cancer
Journal of Ovarian Research (2014)