Background
Neuroblastoma is the most common and deadly tumor of infancy [
1,
2]. It accounts for about 10% of childhood cancers and the mortality reaches 12% [
1,
3,
4]. Despite a better understanding of the molecular, cellular and genetic events that can lead to neuroblastoma development there is still a need to explore new druggable targets for this disease.
The Hedgehog (HH) signaling pathway has critical roles in embryonic development and tumorigenesis [
5‐
8]. Aberrant activation of HH signaling is involved in several types of malignant tumors, including medulloblastoma, rhabdomyosarcoma, basal cell carcinoma, and cancers of the pancreas, colon, stomach, lung and prostate [
9‐
11]. The pathway is initiated by HH ligand [Sonic HH (SHH), Indian HH (IHH), Desert HH (DHH)] [
12,
13] binding to Patched (PTCH1, PTCH2), a twelve trans-membrane domain receptor protein. In the absence of ligands, PTCH inhibits the signaling of the seven trans-membrane domain protein, the proto-oncogene Smoothened (SMO). Upon HH binding, the inhibition of PTCH on SMO is relieved and the signal is transduced to the terminal effectors, the GLI (GLI1, GLI2, GLI3) transcription factors [
12‐
16]. GLI1 not only acts as a signaling effector but also represents a pathway target gene [
16], amplifying the HH signal. Its expression levels are thus a good marker of pathway activity.
Recent studies indicate that primary neuroblastoma and neuroblastoma cell lines express high levels of proteins involved in HH signaling [
17‐
19]. Additionally, inhibition of this pathway at the level of GLI1 is more potent than SMO blockade in reducing the cellular proliferation of non-MYCN amplified neuroblastoma cell lines [
19]. This suggests that GLI1 inhibition of HH signaling is an effective way to target high-risk neuroblastoma without MYCN amplification and should be considered as an option for neuroblastoma treatment.
The mammalian target of rapamycin (mTOR) has emerged as a critical effector in cell signaling pathways commonly deregulated in human cancers. mTOR regulates cell growth by controlling mRNA translation, ribosome biogenesis, autophagy, and metabolism [
20]. Specifically, mTOR regulates translation by the phosphorylation of the ribosomal p70S6 kinase 1 (S6K1), which promotes cap-dependent translation through phosphorylation of eukaryotic translation initiation factor 4E-binding protein 1 (4E-BP1) [
21]. Full and sustained S6K1 activation requires phosphorylation at amino acid residues T229, located within the catalytic activation loop, and T389, located at the hydrophobic motif [
22]. Furthermore, the phosphorylated and activated form of S6K1 (T389) is decreased after treatment with the mTOR inhibitors rapamycin or CCI-779 in neuroblastoma cells [
23]. Additionally, the PI3K/mTOR inhibitor PI103 induced time- and concentration-dependent inhibition of cell growth in both MYCN and non-MYCN amplified neuroblastoma cell lines [
24].
Recently, the mTOR/S6K1 pathway was shown to mediate the development of esophageal adenocarcinoma (EAC) through GLI1 signaling [
25]. Activation of the mTOR/S6K1 pathway via S6K1 phosphorylation was demonstrated to phosphorylate GLI1, promoting GLI1 transcriptional activity and oncogenic function.
In this context, we explored if a crosstalk between mTOR/S6K1 and HH signaling is relevant in neuroblastoma. Our data provide little support for a role of GLI1 signaling as a mediator of the S6K1 proliferative effects in neuroblastoma cells. S6K1 knockdown has minimal effects on GLI1 signaling, GLI1 overexpression can not rescue the reduced proliferation elicited by S6K1 knockdown, and combinations of mTOR/S6K1 and GLI inhibitors do not reveal additive or synergistic effects. Thus, we conclude that S6K1 and GLI1 signaling exert proliferative effects on neuroblastoma cells through independent mechanisms.
Methods
siRNAs and plasmids
siRNAs against S6K1 (RPS6KB1) (NCBI Reference Sequence: NM_003161.3) were designed and ordered from Dharmacon (SiGenome SMART pools, Thermo Scientific). GLI1 siRNAs and control siRNAs were purchased from Sigma-Aldrich.
S6K1 overexpression plasmids, wild type plasmid S6K1WT, constitutively activated plasmid S6K1T389E and function-loss plasmid S6K1T389A were kind gifts of Mien-Chie Hung (University of Texas, MD Anderson Cancer Center, Houston, TX). The GLI1 expression construct (Flag-tagged) has been described previously [
15].
Cell culture
Neuroblastoma cell lines SK-N-AS (non-MYCN-amplified, high GLI1 expression) and SK-N-BE(2) (MYCN-amplified, low GLI1-expression) [
19,
23,
24], obtained from ATCC (Manassas, VA), were cultured in RPMI-1640 with 10% fetal calf serum and 100 IU/ml penicillin/streptomycin and maintained in a 5% CO
2 humidified incubator. RPMI-1640, penicillin/streptomycin, and trypsin were purchased from Invitrogen. Recombinant tumor necrosis factor alpha (hTNF-α) was obtained from Roche Applied Sciences.
Transfection of siRNAs and expression constructs
Cells were plated in 6-well plates (5 × 105 cells per well) or 10 cm2 dishes (3 × 106 cells per dish), and transfections were performed with Lipofectamine 2000 (Invitrogen) according to the manufacturer’s protocol (5 μl Lipofectamine reagent per well for 6-well plate, and 10 μl for 10 cm2 dish). After each treatment, cells were incubated at 37°C for 6 hours followed by a change to fresh culture medium. Transfection efficiencies were confirmed by siGLO (Green Transfection Indicator, Dharmacon). To evaluate the effect of TNF-α, cells, after a 48-hour transfection and overnight starvation, were treated with TNF-α (5 ng/ml) for 6 hours. Cells were harvested 48 or 72 hours after transfection for cell proliferation assay, mRNA and protein analysis.
Cell proliferation
5 × 105 cells per well were seeded in 6-well plates, treated with siRNAs for 48 hours, followed by a 4 hour 10 μM EdU (5-ethynyl-2′deoxyuridine) incubation. EdU were detected by fluorescent-azide coupling reaction (Click-iT, Invitrogen). For each treatment, 10 000 cells were analyzed on a FACS calibur machine (BD Biosciences, Stockholm, Sweden). Cell cycle distribution was calculated using the CellQuest software (BD Bioscience). All proliferation experiments were done at least in triplicate and representative experiments are shown.
Cell survival analysis
For cytotoxic evaluation, we used the fluorometric microculture cytotoxicity assay (FMCA), described in detail previously [
26]. Cells were seeded into drug-prepared 96- or 384-well microplates (SK-N-AS: 0.055×10
6 cells/ml, SK-N-BE(2): 0.028×10
6 cells/ml) and incubated for 72 hours. The cells were washed, fluorescein diacetate was added and after 40 minutes incubation, fluorescence was measured. Cell survival is presented as survival index (SI, %). The studies were designed as suggested in the CalcuSyn software manual, using a fixed molar ratio between the drugs (GANT61:AR-12 20:1; GANT61:CCI-779 2:1 and GANT61:NVP-BEZ235 100:1), intended to be equipotent. The IC
50 values (inhibitory concentration 50%) were determined from log concentration-effect curves in GraphPad Prism (GraphPad Software) using non-linear regression analysis. Comparison between two groups was made with
t-test.
RNA preparation, cDNA synthesis and real-time PCR
Total RNA was isolated with the RNeasy mini kit (Qiagen, Hamburg, Germany) according to the manufacturer’s protocol. cDNA synthesis was performed with random N6 primers (New England Biolabs) and Superscript III (Invitrogen). Real-time PCR was carried out with Power SYBR Green (Applied Biosystems, Foster City, CA) on a 7500 fast real-time PCR system (Applied Biosystems) with primers designed to detect S6K1, GLI1, GLI2, GLI3, SMO and PTCH2 (Table
1). All amplifications were run at least in triplicate and the fold change was normalized to the expression of TATA binding protein (TBP). The relative expression was determined by the ∆Ct method. All RNA expression experiments were done at least in triplicate and representative experiments are shown.
Table 1
Primers for qPCR analysis
S6K1 | 5′ ACATGCTGACTGGAGCACCCCCAT |
5′ GGCTTCTTGTGTGAGGTAGGGAGGCA |
GLI1 | 5′ AGCTACATCAACTCCGGCCAATAGGG |
5′ TGCTGCGGCGTTCAAGAGAGACTG |
GLI2 | 5′ GACATGCGACACCAGGAAGGAAGGT |
5′ GCCGGATCAAGGAGATGTCAGAGATG |
GLI3 | 5′ TGGACCCCAGGAATGGTTACATGGAG |
5′ TGCAATGGAGGAATCGGAGATGGAT |
SMO | 5′ TTTCTGTCACCCCTGTGGCAACTCC |
5′ CGGGCACACCTCCTTCTTCCTCTTC |
PTCH2 | 5′ TCTTTCTGGGACTGTTGGCCTTTGG |
5′ CCTCCCCCAGCTTCTCCTTGGTGTA |
TBP | 5′ GCCAGCTTCGGAGAGTTCTGGGATT |
5′ CGGGCACGAAGTGCAATGGTCTTTA |
Western blot
For Western blotting, cells were lysed with RIPA buffer (150 mM NaCl, 50 mM Tris base pH 8.0, 1 mM EDTA, 0.5% sodium deoxycholate, 1% NP-40, 0.1% sodium dodecyl sulfate, 1 mM DTT, 1 mM PMSF, and 1 mM Na3VO4) supplemented with Complete Protease Inhibitor Tablets (Roche) and phosphatase inhibitor (Sigma). Proteins were separated on a 7.5% sodium dodecyl sulfate polyacrylamide gel electrophoresis (PAGE) followed by transfer (220 mA for 1 hour) to an Immobilon-P membrane (Millipore). The membrane was incubated at 4°C overnight in 5% skim milk in TBST (Tris Buffered Saline with Tween 20) with anti-rabbit GLI1 Ab (#2553, Cell Signaling) or anti-rabbit S6K1 Ab (sc-230, Santa Cruz Biotechnology) followed by incubation with goat anti-rabbit secondary antibodies for 1 hour in 5% skim milk in TBST and visualized using chemiluminescent substrate (Thermo Scientific). The Western blot experiments were done at least in triplicate and representative experiments are shown.
Immunoprecipitation (IP)
For immunoprecipitation, cell lysates were generated with lysis buffer (25 mM Tris, pH 7.4, 150 mM NaCl, 1 mM EDTA, 5% glycerol, 1% NP-40 and Protease/phosphatase inhibitor cocktail), and proteins immunoprecipitated using anti-rabbit GLI1 Ab or healthy rabbit serum and Protein A-Agarose according to the manufacturer’s protocol (Santa Cruz Biotechnology). The protein/antibody/Protein A-Agarose complex was washed with PBS containing 0.05% Tween 20. Cell lysates and immunoprecipitated proteins on the transferred membrane were incubated with anti-mouse GLI1 Ab (#2643, Cell Signaling) for GLI1 or anti-mouse phosphoserine/threonine Ab (612548, BD Transduction Laboratories) for phosphorylated GLI1, followed by incubation with goat anti-mouse Ab. The immunoprecipitation experiments were done at least in triplicate and representative experiments are shown.
Discussion
Deregulation of the HH signaling pathway has long been known to be associated with various human cancers. Recently, neuroblastoma was added to this list based on a series of observations. GLI2, GLI3 and especially GLI1 knockdown reduced neuroblastoma cell growth compared with siRNA control [
19]. Moreover, GANT61, a GLI inhibitor, reduced the
in vivo growth of high-risk neuroblastoma lacking MYCN amplification [
19]. These findings extend earlier reports, which indicated that inhibition of HH signaling by cyclopamine induced apoptosis, blocked proliferation and abrogated the tumorigenicity of neuroblastoma cells [
18].
The HH signaling pathway is known to interact with other signal transduction cascades during cancer development, exemplified by the TGFβ – HH crosstalk in pancreatic adenocarcinoma [
10]. Recently, a connection between the mTOR/S6K1 and the HH pathway has been reported in EAC, through an S6K1-mediated GLI1 phosphorylation at Ser84, which increases its transcriptional/oncogenic activity [
25]. It should be noted that the S6K1 impact on GLI1 was observed following TNF-α treatment, which activates S6K1. Without administration of this cytokine there is little detection of active (phosphorylated) S6K1 and phosphorylated GLI1. Furthermore, knocking down S6K1 in HeLa cells had little effect on GLI activity, unless AKT or ERK signaling was activated [
25]. In this study, we found that S6K1 knockdown is more effective than GLI1 knockdown in reducing the cellular proliferation of the non-MYCN amplified SK-N-AS cell line. Additionally, knocking down S6K1 did not affect GLI1 expression, irrespective of the treatment of the cells with TNF-α. When the MYCN amplified and lowly GLI1 expressing SK-N-BE(2) neuroblastoma cell line was used, S6K1 knockdown did not change GLI1 expression in the absence of TNF-α. TNF-α treatment increased GLI1 mRNA levels but this upregulation was insensitive to S6K1 knockdown, arguing for the lack of involvement of this kinase. Moreover, we could not detect changes in the phosphorylation status of GLI1 by S6K1 knockdown in SK-N-AS cells. The most likely reason for this is that the endogenous level of phosphorylated GLI1, if any, is beyond the detection limit of the assay used. Another possibility could be that the endogenous level of active S6K1 may be too low to phosphorylate GLI1. However, this is not supported by the fact that overexpression of S6K1 does not elicit proliferation changes, while S6K1 knockdown does, arguing that the endogenous S6K1 levels are sufficient for biological effects. In fact, active (phosphorylated) S6K1 is readily detectable in the SK-N-AS cell line [
23]. Thus, our data suggest that GLI1 is not a target of S6K1 and the impact of S6K1 on cellular proliferation is independent of GLI1. This is further supported by the inability of GLI1 overexpression to rescue the reduced proliferation elicited by S6K1 knockdown. Additionally, the combination of small molecule inhibitors of GLI and PI3K/mTOR signaling revealed no additive or synergistic effects on the suppression of neuroblastoma cell growth.
It should be also noted that a recent kinome-wide siRNA screen in a non-small cell lung cancer cell line revealed that S6K1 silencing does not alter the expression of GLI1 protein and GLI1 regulated genes [
29], in line with our observations in neuroblastoma. Further analysis examining possible interactions between S6K1 and GLI1 in other cell types will provide additional clarity on these issues.
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Competing interests
The authors declare that they have no competing interests.
Authors’ contributions
YD performed the molecular analysis of the effects of knocking down S6K1 and GLI1 and drafted the manuscript, MFR and VEV contributed to the experimental design and analysis, MW performed the cell cytotoxicity tests, JIJ contributed to the data analysis and proofread the manuscript, PGZ designed the study and helped to draft the manuscript. All authors read and approved the final manuscript.