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Brain tumours are among the most devastating cancers that present unique challenges to therapy and pose major health problems around the world. Among many different types of tumours, glioblastoma is the most frequent primary malignant brain tumour in adults. Standard therapy includes surgical resection to the extent that is safely feasible, followed by radiation and chemotherapy, which have significant side effects and limited efficacy (Deorah et al, 2006, Peacock and Lesser, 2006). Despite recent advances in surgery, radiation and chemotherapy, median survival is less than 1 year and a cure for brain tumour remains elusive. Multidrug resistance and fast recurrence are some of the challenges in combating brain tumours. Cancer stem cells (CSCs) are a small population of cells in cancer tissues with asymmetric division, self-renewal and tumour initiation capabilities. In acute myeloid leukaemia, CSCs were first identified (Bonnet and Dick, 1997) and subsequently in breast (Al-Hajj et al, 2003), prostate (Patrawala et al, 2006), liver (Yang et al, 2008), colon (Dalerba et al, 2007; O’Brien et al, 2007), pancreas (Li et al, 2007) and skin cancers (Schatton et al, 2008). Brain tumour stem cells (BTSCs) have also been isolated from gliomas that are positive for CD133 and posses tumour initiation potential in NOD/SCID mice (Singh et al, 2004). The BTSCs are resistant to standard therapies and are considered responsible for the recurrence of brain tumours after radiation and chemotherapy in patients (Singh et al, 2004; Bao et al, 2006). The failure to cure brain tumour has been attributed to the fact that typical therapies target rapidly proliferating tumour cells, which respond transiently, while sparing the highly tumourigenic BTSCs (Bao et al, 2006; Stupp and Hegi, 2007).

Nuclear hormone receptors are a family of transcriptional factors that regulate cell growth, differentiation and homoeostasis. Genomic studies have cloned 48 and 50 nuclear receptors in human and rodents, respectively, and many of them have therapeutic values in human diseases (Blumberg and Evans, 1998). The effect of nuclear receptor agonists on brain tumours has been shown recently (Naveilhan et al, 1994; Grommes et al, 2006; Papi et al, 2009), but their use in targeting BTSCs is not known. Constitutive androstane receptor (CAR, NR1I3) is an orphan nuclear receptor that contains a DNA-binding domain but uniquely lacking an activation domain (Baes et al, 1994). The CAR is retained in the cytoplasm by forming a complex with phosphatase 2A, HSP90 and cytosolic CAR retention protein (Kobayashi et al, 2003). Phenobarbital, 5β-pregnane-3,20-dione, and 5-androstan-3-ol are known endogenous CAR ligands (Moore et al, 2000). The hepatomitogen 1,4-Bis[2-(3,5-dichloropyridyloxy)]benzene (TCPOBOP) is a synthetic agonist for murine CAR (Tzameli et al, 2000) and 6-(4-chlorophenyl)imidazo[2,1-b][1,3]thiazole-5-carbaldehydeO-(3,4-dichlorobenzyl)oxime (CITCO) is an imidazothiazole derivative that functions as a selective agonist for human CAR (Maglich et al, 2003). Upon activation with specific agonist, CAR translocates into the nucleus and binds to the response elements as monomers or CAR/RXR heterodimers (Baes et al, 1994). The CAR functions as a xenobiotic receptor that regulates detoxification and clearance of toxic substances from the liver (Qatanani and Moore, 2005); however, its role in cancer is not known.

In this study, we show that CAR agonist CITCO inhibits growth and expansion of BTSCs in culture and xenograft model. Our findings highlight that BTSCs can be targeted through CAR for the treatment of brain tumour patients.

Materials and methods

Tissues, cells and reagents

The T98G and U87MG human glioma cells were obtained from American Type Culture Collection (ATCC, Manassas, VA, USA). The DB29 and DB33 human glioma cells were established in the laboratory by culturing brain tumour samples obtained from the tissue repository at Methodist Research Institute (Indianapolis, IN, USA) with an IRB approved protocol. The glioma cells were cultured in Dulbecco's modified Eagle's medium (DMEM) with 10% FBS, 1 mM sodium pyruvate, 100 U ml−1 penicillin G, 100 μg ml−1 streptomycin, 2 mM glutamine, 1 mM MEM non-essential amino acids and 50 μ M 2β-mercaptoethanol in 5% CO2 incubator at 37°C. The glioma cells were dissociated using 0.25% trypsin with 0.05 mM EDTA solution and subcultured once in 3–5 days. Primary human astrocytes (HAs) were obtained from ScienCell (Carlsbad, CA, USA) and cultured in astrocyte medium. The human CAR agonist CITCO was obtained from BioMol (Plymouth Meeting, PA, USA). The CITCO is an imidazothiazole derivative (MW 436.7) with an EC50 of 49 nm and >50-fold selectivity to CAR over pregnane X receptor (PXR), and no activity on other nuclear receptors.

Gliosphere culture

To generate gliospheres, we have adopted a culture condition as standardised in our laboratory (Chearwae and Bright, 2008). Briefly, the glioma cells cultured as monolayer in DMEM were dissociated using trypsin–EDTA and cultured in neurobasal medium (NBM) supplemented with B27 (Invitrogen, Madison, WI, USA) in the presence of 10 ng ml−1 EGF and bFGF. The cells were cultured in 12-well plates (5 × 104 per ml per well) with different doses of CITCO in 5% CO2 incubator at 37°C. The gliospheres generated in primary cultures were photographed after 5–10 days using BX40 Olympus microscope (Olympus America Inc., Center Valley, PA, USA).

Isolation of BTSCs and CD133+ BTSCs

To isolate BTSCs, the gliospheres were harvested after 5–7 days and dissociated by incubating (10 × 106 ml−1) in Accutase (Sigma, St Louis, MO, USA) at 37°C for 30 min. The cells were washed and resuspended in fresh NBM, and used as BTSCs for the experiments. To isolate CD133+ BTSCs, the dissociated gliosphere cells (BTSCs) were resuspended (10 × 106) in 200 μl of PBE buffer (PBS, pH7.2, 0.5% BSA, 2 mM EDTA). Biotin conjugated anti-CD133 antibody (20 μl) and FcR blocking reagent (30 μl) (Miltenyi Biotech, Auburn, CA, USA) were added and incubated at 4°C for 30 min. The cells were washed and incubated in 200 μl PBE buffer with 50 μl streptavidin-conjugated magnetic microbeads (Miltenyi Biotech, Auburn, CA, USA) at 4°C for 30 min. The cells were passed through a MACS-LS column equilibrated with PBE buffer placed on a Midi-Macs Magnet (Myltenyi Biotech Inc., Auburn, CA, USA), and the CD133 negative cells in the flow-through were collected. The column was removed from the Magnet, and the CD133-positive cells were flushed out with the buffer using a plunger. The cells were washed and resuspended in fresh NBM for experiments.

Immunostaining and flow cytometry

The gliospheres were cultured in fresh NBM with B27 and 10 ng ml−1 EGF+bFGF in the presence of different concentrations of CITCO in 12-well tissue culture plates in 5% CO2 incubator at 37°C. After 48 h, the gliospheres were fixed in 1% paraformaldehyde and stained with anti-Ki67 Ab (1 : 100, Santa Cruz, Santa Cruz, CA, USA) in PBS with 1% BSA at 4°C for 2 h. Alexa 488-conjugated 2nd Ab (1 : 1500, Cell Signaling, Danvers, MA, USA) diluted in PBS with 1% BSA was added for 1 h and photographed using a fluorescent microscope (DMRB, Leica, Bannockburn, IL, USA). To determine the percentage of CD133+ BTSCs, gliospheres cultured with different doses of CITCO for 48 h were dissociated using Accutase, followed by resuspension in PBS containing 0.1% BSA and incubated with anti-CD133 Ab (1 : 100, Cell Signaling) at 4°C for 2 h. The cells were washed and incubated with Alexa 488-conjugated secondary Ab at 4°C for 1 h, and acquired using FACS Calibur Flow Cytometer (BD Biosciences, San Jose, CA, USA) and analysed using FlowJo 8.2.6 software (Ashland, OR, USA).

Quantitative real-time RT–PCR

Total RNA was extracted from glioma and BTSCs using RNesy kit (Qiagen, Valencia, CA, USA). Equal amount of RNA was reverse transcribed into cDNA, and quantitative RT–PCR (qRT–PCR) was performed using 384-well TaqMan Low Density Human Nuclear Receptor Array Card (384 well) in 7900 HT Fast Real time PCR system (Applied Biosystems, Foster City, CA, USA). To detect CAR transcription, 5 μg total RNA was reverse transcribed into cDNA by incubating in 10 μl reaction of random hexamer primers and master mix from TaqMan reverse transcription kit (Applied Biosystems, Branchburg, NJ, USA). For qRT–PCR, 2 μl of the cDNA was amplified using TaqMan Universal Master Mix with optimised concentrations of CAR primer sets and probes in a standard optical 96-well reaction plate. The results were analysed using the Prism 7900 (Applied Biosystems, Carlsbad, CA, USA) relative quantification (delta delta Ct) study software (Mo et al, 2008). The level of CAR transcription was normalised to 18S and expressed as fold change compared with control.

The SDS–PAGE and western blot

The glioma and BTSCs were cultured in the absence or presence of CITCO at 37°C for different time points. Whole-cell lysates were prepared by boiling in lysis buffer (0.2 M Tris-HCl, pH 6.8, 0.8 μg ml−1 SDS, 4% glycerol, 0.59 M β-mercaptoethanol, 0.05 M EDTA, 8 μg ml−1 bromophenol blue) for 5 min. Total proteins were resolved on 10% SDS–PAGE (BioRad, Hercules, CA, USA) and transferred to nylon/PVDF membrane (Millipore, Bedford, MA, USA) using Novablot transfer system (Pharmacia, Piscataway, NJ, USA). The residual binding sites in the membrane were blocked with PBST (PBS and 0.1% Tween 20) containing 5% non-fat milk powder for 1 h and incubated with anti-CAR (1 : 1000), anti-GAPDH (1 : 1000) or anti-β-actin (1 : 5000) antibody in PBST containing 1% milk powder at 4°C overnight. The membranes were washed in PBST, incubated with peroxidase-conjugated anti-IgG antibody (1 : 10 000) for 1 h and developed by superior signal West Pico chemiluminescence reagent (ThermoScientific, Rockford, IL, USA).

Proliferation assay

The proliferation of glioma and BTSCs was measured by WST-1 (4-(3-(4-iodophenyl)-2-(4-nitrophenyl)-2H-5-tetrazolio)-1,3-benzene disulfonate) and 3H thymidine uptake assay. Briefly, the glioma cells were cultured in 96-well tissue culture plates (5000 cells per well) in DMEM without phenol red with L-glutamine, pyruvic acid, sodium salt in the presence of 10% charcoal-stripped FBS (Invitrogen) and 1% penicillin–streptomycin. The glioma cells were also cultured in 96-well tissue culture plates (1 × 104 per 200 μl per well) in NBM with B27 in the presence of 10 ng ml−1 EGF+bFGF (gliosphere). The dissociated gliosphere cells (BTSCs) and purified CD133+ BTSCs were cultured in 96-well tissue culture plates (1 × 104 per 200 μl per well) in NBM with B27 and 10 ng ml−1 EGF+bFGF. Increasing concentrations of CITCO were added at the initiation of cultures. The WST-1 reagent (10 μl per well, Roche, Indianapolis, IN, USA) was added after 48 h, and the OD measured at 480 nm after 1–3 h using a titre plate reader. The 3H thymidine (0.5 μCi ml−1) was added at 24 h, and the cells were harvested after 48 h manually or using a Tomtech harvester 96 (Hamden, CT, USA). The amount of 3H thymidine uptake was counted on a Wallac Microbeta liquid scintillation counter (Perkin Elmer, Fremont, CA, USA).

Cell cycle analysis

To determine the effect of CITCO on cell cycle progression, gliospheres were cultured in NBM with B27 and 10 ng ml−1 EGF+bFGF in the presence of different concentrations of CITCO. After 48 h, the cells were dissociated with Accutase and incubated in PBS containing 100 μg ml−1 propidium iodide, 0.6% NP-40 and 20 μg ml−1 RNase (Sigma Chemicals, St Louis, MO, USA) at 4°C for 1 h. The percentages of BTSCs at different cell cycle stages (G0/G1, G2/M and S phases) were determined based on DNA content by flow cytometry using FACS Calibur Flow Cytometer (BD Biosciences), and analysed using ModFit LT2.0 software (Verity software house, Topsham, ME, USA).

Apoptosis assay

To determine the effect of CITCO on apoptosis, BTSCs were cultured in NBM with B27 and 10 ng ml−1 EGF+bFGF in the presence of CITCO. After 48 h, the cells were harvested, washed in PBS and stained with Annexin V-FITC (Roche, Indianapolis, IN, USA) in binding buffer (0.1 M Hepes/NaOH, pH 7.4, 1.4 M NaCl, 0.2 μ M) containing 100 μg ml−1 propidium iodide according to the manufacturer's instruction (Roche). The cells were incubated at room temperature for 30 min in dark, acquired using FACS Calibur Flow Cytometer (BD Biosciences) and analysed using FlowJo 8.2.6 software.

Induction, treatment and evaluation of BTSC xenograft

To determine the in vivo effect of CAR agonists on BTSCs, we induced BTSC xenograft in nude mice. All the animal protocols used for in vivo experiments were reviewed and approved by the institutional animal care and use committees at Methodist Research Institute, and performed accordingly. Six- to eight-week-old male athymic nude mice were obtained from Harlan (Indianapolis, IN, USA) and maintained under specific pathogen-free conditions in the animal care facility at Methodist Research Institute. The BTSCs were isolated by dissociating U87MG gliospheres and transplanted (25 × 104) subcutaneously in 100 μl NBM in the dorsum of 8-week-old nude mice. The mice were treated intraperitoneally with 25 and 100 μg CITCO in 25 μl DMSO on days 22, 24, 26, 30 and 36 following xenograft. The control mice received only 25 μl DMSO. Tumours were measured once a week till day 50 using a digital Vernier Calipers (Marathon, Ontario, Canada), and the tumour volume (TV) was calculated as follows: TV=½(lw2) (l=length, w=width) (Euhus et al, 1986; Jiang et al, 2010; Johns et al, 2010). Each group contained at least four mice, and the experiments were repeated twice. On day 50, the BTSC xenografts were dissected, fixed in buffered formalin, embedded in paraffin and sliced into 6 μm thick sections. The sections were stained with haematoxylin and eosin (H&E), and photographed using a phase-contrast microscope (DMRB, Leica) (Mo et al, 2008). The tissue sections were deparafinised, followed by incubation with 10% goat serum in PBS to block non-specific binding sites and stained overnight with anti-Ki67 Ab (1 : 100, Santa Cruz) in PBS with 1% BSA at 4°C. Alexa 488-conjugated 2nd Ab (Cell Signaling) diluted in PBS with 1% BSA was added for 1 h ,and the sections were photographed using a fluorescent microscope (DMRB, Leica).

Statistical analysis

The data were analysed by ANOVA (Graphpad Prism 5.0, Graphpad Software, La Jolla, CA, USA), and the *P<0.05, **P<0.01, ***P<0.001 were considered significant.

Results

Altered expression of nuclear receptors in BTSCs

To identify novel therapeutic targets for BTSCs, we examined the expression of nuclear receptors by qRT–PCR using TaqMan Low Density Human Nuclear Receptor Array Card (384 well). We found that T98G–BTSCs express altered levels of many nuclear receptors compared with the glioma cells (Table 1). Among the 48 nuclear receptors examined, BTSCs expressed detectable levels of ERRβ and RXRγ that were not detected in glioma cells. The BTSCs also showed 100-fold increase in the transcription of TLX and HNF4α, and between 10- and 100-fold increase in PXR, RORα, RORγ, NORI and LRH compared with glioma cells. Moreover, 15 nuclear receptors showed 0- to 10-fold increase in BTSCs (Table 1). On the other hand, 10 genes showed 0- to 2-fold decrease, 6 genes showed 2- to 10-fold decrease and RORβ, SF1 and PNR showed more than 10-fold decrease in BTSCs compared with glioma. Five nuclear receptors tested were not detected either in glioma or BTSCs (Table 1). These results suggest that BTSCs express altered levels of nuclear receptors, which may serve as novel therapeutic targets for the treatment of brain tumour.

Table 1 Altered expression of nuclear receptors in brain tumour stem cells

The CITCO induces the expression of CAR in BTSCs

Although many altered nuclear receptors are currently under investigation in our laboratory, in this manuscript, we present our findings on the use and mechanism of action of CAR and its agonist CITCO in targeting BTSCs for the treatment of glioma. As shown in Figure 1, qRT–PCR analyses confirmed that T98G–BTSC (A) and U87MG–BTSC (B) express significantly lower levels of CAR mRNA compared with the glioma cells. The CD133+ BTSCs purified from T98G (A) and U87MG (B) gliospheres showed further decrease in CAR transcription. Interestingly, treatment with 2.5 μ M CITCO resulted in a significant increase in the transcription of CAR in both T98G–BTSC and U87MG–BTSCs in 48 h. Western blot analyses showed that the T98G and U87MG glioma, and BTSCs express very low levels of CAR protein that increased significantly following treatment with 2.5 μ M CITCO in 48 h. However, higher concentrations of CITCO (10 μ M) inhibited or abolished CAR expression in both T98G- and U87MG-derived BTSCs. Further analyses showed that the BTSCs isolated from DB29 and DB33 (C) gliospheres express lower levels of CAR compared with glioma cells, and treatment with 2.5 μ M CITCO resulted in significant increase in the transcription of CAR. Western blot analyses also showed that the expression of CAR protein was low in DB29–BTSCs that increased significantly after treatment with 2.5 μ M CITCO in 48 h (C). Higher concentrations of CITCO (5 μ M) abolished the expression of CAR in DB29–BTSCs. These results suggest that CITCO modulates the expression of CAR in BTSCs.

Figure 1
figure 1

The CAR expression in BTSCs. The T98G (A), U87MG (B), DB29 and DB33 (C) glioma cells were cultured as monolayer in DMEM (glioma) or as gliospheres in NBM with B27 and EGF+bFGF for 5 days. The BTSCs and CD133+ BTSCs were purified from gliospheres and cultured in NBM with 0 to 25 μ M CITCO for 48 h. The CAR transcription was determined by qRT–PCR, and the data presented as fold change compared with glioma. The chemical structure of CITCO is shown as an insert (A). The levels of CAR protein was determined by western blot analyses. The blots were reprobed with GAPDH or β-actin Abs as internal controls. The figure is representative of three independent experiments. **P<0.01, ***P<0.001.

The CITCO inhibits the expansion of BTSCs

To study the use of CAR in the regulation of BTSCs, we examined the effect of CITCO on growth and expansion in culture. Microscopic analyses showed that in vitro culture of T98G, U87MG, DB29 and DB33 glioma cells in NBM with B27 and EGF+bFGF resulted in the expansion of BTSCs as gliospheres in 5 days (Figures 2A and B). Interestingly, in vitro treatment with 1 and 5 μ M CITCO for 48 h induced a dose-dependent decrease in gliosphere size in all four cell types tested. Immunofluorescent microscopy showed that the gliospheres are filled with actively dividing BTSCs as evidenced by Ki-67 staining. Treatment with CITCO resulted in a dose-dependent decrease in Ki-67+ BTSCs in T98G (C), U87MG (D), DB29 (E) and DB33 (F) gliospheres.

Figure 2
figure 2

The T98G or U87MG (A) and DB29 or DB33 (B) glioma cells were cultured in NBM with B27 and EGF+bFGF in the presence of 0, 1 or 5 μ M CITCO. The gliospheres generated in 5–10 days were photographed (100 × ) using BX40 Olympus microscope (A and B). The T98G (C), U87MG (D), DB29 (E) and DB33 (F) gliospheres were also cultured in NBM with B27 and EGF+bFGF in the presence of 0, 1 or 5 μ M CITCO. After 48 h, the spheres were stained with DAPI and Ki-67 Ab, and photographed (200 × ) using a fluorescent microscope. The figures are representatives of three independent experiments.

To further determine the use of CAR in targeting BTSCs, we analysed the effect of CITCO on CD133+ cells by flow cytometry. We found that T98G–BTSCs displayed 43% CD133+ cells with a mean fluorescence intensity (MFI) of 186 that decreased dose dependently, reaching 16% with a MFI of 49 after treatment with 5 μ M CITCO for 48 h (Figure 3). Similarly, U87MG–BTSCs showed 56% CD133+ cells with a MFI of 254 that decreased to 16% with a MFI of 47 at a dose of 5 μ M CITCO. Further analyses showed that the DB29–BTSCs consist of 31% CD133+ cells with a MFI of 231 that decreased to 16% with a MFI of 110 at 5 μ M CITCO. Similarly, DB33–BTSCs showed 32% CD133+ cells with MFI of 107 that decreased to 10% with a MFI of 56 at 5 μ M CITCO (Figure 3). These results show that CITCO regulates the expansion of CD133+ BTSCs, suggesting its significance in the treatment of glioma.

Figure 3
figure 3

The CITCO inhibits the expansion of CD133+ BTSCs. The T98G, U87MG, DB29 and DB33 glioma cells were cultured in NBM with B27 and EGF+bFGF for 5 days. The gliospheres generated were further cultured in fresh NBM with 0, 1, 2.5 and 5 μ M CITCO for 2 days. The cells were dissociated and stained with anti-CD133 and Alexa 488-conjugated 2nd Abs, and analysed by flow cytometry. The figure shows percent CD133+ BTSCs (blue) and isotype control (red) with mean fluorescence intensities (MIF) in parenthesis. The figure is representative of three independent experiments.

The CITCO inhibits the proliferation of BTSCs

To further test the therapeutic use of CAR in glioma, we examined the effect of CITCO on tumour cell proliferation in culture. As shown in Figure 4, we found that in vitro culture of T98G (A, B) and U87MG (C, D) cells in DMEM as monolayer (glioma) and in NBM (gliospheres), dissociated gliosphere cells in NBM (BTSCs) and purified CD133+ gliosphere cells in NBM (CD133+ BTSCs) resulted in a significant increase in viable cell count (A, C) and proliferation (B, D) as measured by WST-1 and 3H thymidine uptake assays, respectively. Interestingly, addition of CITCO resulted in a dose-dependent inhibition of viable cell count and proliferation in both T98G and U87MG glioma, and BTSCs. Similarly, in vitro culture of DB29- and DB33-derived CD133+ BTSCs in NBM resulted in a significant increase in viable cell count and proliferation that was inhibited by the addition of CITCO (E). Although CITCO induced a statistically significant inhibition at 1 and 2.5 μ M doses in all cell types tested, its antiproliferative effect was more pronounced in BTSCs than glioma cells. No detectable effect on the morphology, cell viability or proliferation was observed in normal HAs following in vitro culture with CITCO (F), suggesting its selectivity to glioma and BTSCs.

Figure 4
figure 4

The CITCO inhibits the proliferation of BTSCs. The human glioma cells, T98G (A and B), U87MG (C and D), DB29 and DB33 (E), and astrocytes (F) were cultured as monolayers in DMEM in the absence of phenol red in the presence of 10% charcoal-stripped FBS. The glioma cells were also cultured as gliospheres in NBM with B27 and EGF+bFGF (gliosphere). The dissociated gliosphere cells (BTSC) and purified CD133+ gliosphere cells (CD133+ BTSC) were cultured in fresh NBM with B27 and EGF+bFGF. Different doses of CITCO were added at the initiation of culture. The cell viability and proliferation were measured using WST-1 and 3H thymidine uptake assay, respectively. The values are mean of triplicates (±s.e.m.), and *P<0.05, **P<0.01 and ***P<0.001 are considered significant. The astrocyte cultures were photographed (100 × ) under phase-contract microscope. The figure is representative of three independent experiments. ‘The color reproduction of this figure is available on the html full text version of the manuscript.’

The CITCO induces cell cycle arrest in BTSCs

To explore the intrinsic mechanisms by which CAR regulates growth arrest in BTSCs, we analysed the effect of CITCO on cell cycle progression. We found that BTSCs cultured in NBM with B27 and EGF+bFGF showed distribution of cells in G0/G1, G2/M and S phases of cell cycle (Figure 5). Addition of CITCO for 24 h resulted in a dose-dependent cell cycle arrest of BTSCs. Interestingly, data analyses revealed that CITCO induces cell cycle arrest through different mechanisms in different cell types. Although CITCO increased G0/G1 cells with a decrease in G2/M and S phases in T98G–BTSCs, it decreased G0/G1 and increased G2/M without affecting the S-phase cells in U87MG–BTSCs. However, BTSCs isolated from DB29 and DB33 showed comparable responses to CITCO with increased G0/G1 and G2/M with a decrease in S-phase cells (Figure 5). These results suggest that CITCO induces cell cycle arrest differentially in different BTSCs in culture.

Figure 5
figure 5

The CITCO induces cell cycle arrest in BTSCs. The T98G, U87MG, DB29 and DB33 glioma cells were cultured in NBM with B27 and EGF+bFGF. The gliospheres generated in 5 days were cultured in fresh NBM with B27 and EGF+bFGF in the presence of 0, 2.5 or 5 μ M CITCO. After 48 h, the gliospheres were harvested, dissociated (BTSCs), stained with propidium iodide and analysed based on DNA content by flow cytometry. The percentage of cells in G0/G1, G2/M and S phases of cell cycle are shown. The figure is representative of three independent experiments.

The CITCO induces apoptosis in BTSCs

To further determine the mechanisms by which CAR regulates BTSCs, we examined the effect of CITCO on apoptosis. We found that BTSCs cultured in NBM with B27 and EGF+bFGF showed very low levels of Annexin V-positive apoptotic cells that increased dose dependently following addition of CITCO (Figure 6). The BTSCs from T98G and U87MG cultured in the absence of CITCO showed 6.8 and 11% Annexin V-positive cells that increased to 62 and 68% following addition of 10 μ M CITCO, respectively. Moreover, BTSCs from DB29 and DB33 gliomas showed 3 and 0.5% Annexin V-positive cells that increased to 24 and 41% following treatment with 10 μ M CITCO, respectively (Figure 6). These results suggest that CITCO induces apoptosis in BTSCs in culture.

Figure 6
figure 6

The CITCO induces apoptosis in BTSCs. The T98G, U87MG, DB29 and DB33 glioma cells were cultured in NBM with B27 and EGF+bFGF. The gliospheres generated in 5 days were cultured in fresh NBM with B27 and EGF+bFGF in the presence of 0, 2.5, 5 or 10 μ M CITCO. After 48 h, the gliospheres were dissociated (BTSCs), stained with Annexin V-FITC along with propidium iodide and analysed by flow cytometry. The figure is representative of three independent experiments. The histogram shows the mean Annexin V-positive BTSCs (±s.d.) of three experiments. *P<0.05, **P<0.001, ***P<0.001.

The CITCO inhibits BTSC xenograft in nude mice

To determine the in vivo effect of CITCO on tumour growth, we used a xenograft model in nude mice. As shown in Figure 7, we found that subcutaneous transplantation of U87MG–BTSCs resulted in solid tumour growth by day 21. Interestingly, in vivo treatment with CITCO on days 22, 24, 26, 30 and 36 resulted in a dose-dependent decrease in tumour volume (A). In DMSO-treated control group, the tumour volume increased from 36 mm3 on day 21 to 84 mm3 on day 50, whereas in the 25 μg CITCO-treated group, tumour volume decreased from 31 mm3 (100%) on day 21 to 8 mm3 (90% inhibition) on day 50. Moreover, the tumour volume in mice treated with 100 μg CITCO decreased from 44 mm3 on day 21 to 0 mm3 (100% inhibition) by day 28, with no recurrence observed until day 50. Histological analysis revealed that BTSCs grow and expand as solid tumour in nude mice as evidenced by H&E staining (B). Treatment with 25 μg CITCO resulted in a significant decrease in tumour growth, which further decreased to an undetectable level after treatment with 100 μg CITCO (B). Furthermore, Ki-67 staining revealed that the control group showed actively dividing cells in the tumour, which decreased significantly after treatment with 25 μg CITCO, with the absence of Ki-67+ cells at 100 μg. These results suggest the in vivo effect of CITCO in the treatment of glioma.

Figure 7
figure 7

Nude mice were injected (s.c) with U87MG–BTSCs to induce tumour growth. The mice were treated (intraperitoneal) with 0, 25 or 100 μg CITCO in DMSO on days 22, 24, 26, 30 and 36. (A) The tumour growth was measured using digital Vernier Calipers, and the tumour volume was calculated. The percent inhibition by CITCO was calculated using the mean tumour volume in the group treated with 0 μ M CITCO as 100%. The figure is representative of three independent experiments. (B) The mice were euthanised on day 50, and the BTSC xenografts were dissected; 6 μm thick sections were stained with H&E or anti-Ki67 Ab and photographed (100 × /200 × ) under fluorescent microscope. *P<0.05, **P<0.001, ***P<0.001.

Discussion

Despite advances in modern medicine, the prognosis from current surgery, radiation and chemotherapy remains poor in brain tumour patients. The recent identification of BTSCs with resistance and recurrence properties has revolutionised the basic approaches on drug discovery and development for brain tumour. Brain tumours often present a small fraction of BTSCs, making it difficult to isolate sufficient cells for drug discovery. EGF and FGF are growth factors that promote the tumourigenicity of glioma cells (Martens et al, 2008). We have shown recently that EGF+bFGF induce the expansion of CD133+ BTSCs as gliospheres in culture (Chearwae and Bright, 2008). In this study, we show for the first time that the CAR agonist CITCO induces growth arrest and apoptosis of BTSCs in culture and in animal model.

Nuclear hormone receptors have therapeutic values in many human diseases (Blumberg and Evans, 1998). Earlier studies have demonstrated deregulated expression of nuclear receptors in glioma and their activation with specific agonists inhibited tumour growth (Berge et al, 2001; See et al, 2004). In this study, we set out to identify novel nuclear receptors that could be used to target BTSCs for the treatment of glioma. We found that BTSCs express altered levels of many nuclear receptors compared with glioma, which are currently under investigation in our laboratory. In this manuscript, we focused on determining the use of CAR agonist CITCO in targeting BTSCs. We found that the expression of CAR was low in BTSCs derived from different gliomas. The downregulation of CAR could be a mechanism by which BTSCs evade antitumour responses. Interestingly, the upregulation of CAR expression by CITCO suggests its use in targeting BTSCs in the treatment of glioma. This is consistent with our earlier report on the induction of PPARγ expression by its agonists in BTSCs (Chearwae and Bright, 2008). Although the constitutively active CAR is retained in the cytoplasm, CITCO induces its translocation into the nucleus and mediates gene transcription (Baes et al, 1994; Kobayashi et al, 2003). Although the exact mechanisms are not known, our findings suggest an autoregulation of CAR expression through CITCO/CAR axis in BTSCs.

Earlier studies have shown that CAR is highly expressed in the liver and small intestine, and promotes the detoxification and elimination of potentially toxic compounds by modulating the phase I and phase II drug-metabolising enzymes (Forman et al, 1998; Xu et al, 2005; Echchgadda et al, 2007; Veith et al, 2009). Although CAR activation can disrupt thyroid hormone homoeostasis (Qatanani et al, 2005), it also showed protective roles in stress response (Forman et al, 1998; Stedman et al, 2005; Xu et al, 2005; Echchgadda et al, 2007). The CAR-mediated expression of xenobiotic-metabolising enzymes is generally protective, but can be deleterious, if toxic metabolites are produced (Xu et al, 2005). The CAR agonists induce hepatocyte proliferation that depends on c-Myc-FoxM1 function (Blanco-Bose et al, 2008). The CAR agonists also inhibits Fas-induced hepatocyte apoptosis, liver injury, and fatalities by depleting the proapoptotic proteins Bak (Bcl-2 antagonistic killer) and Bax (Bcl-2-associated X protein) and increasing the expression of the antiapoptotic effector myeloid cell leukaemia factor-1 (Baskin-Bey et al, 2006). Thus, the xenobiotic properties of CAR and its agonists have been extensively studied, but its anticancer property was not known.

In this study, we have shown that CITCO inhibits the proliferation of glioma cells in a dose-dependent manner, without affecting primary astrocytes. Interestingly, CITCO inhibits the growth and expansion of BTSCs by inducing cell cycle arrest and apoptosis in culture. Moreover, the inhibition of CD133 expression by CITCO indicates the downregulation of BTSC expansion in culture. The inhibition of solid tumour growth by CITCO in xenograft model suggests the use of CITCO in the regulation of BTSCs in vivo. We have shown earlier that PPARγ agonists inhibit cytokine-induced activation of Jak-Stat pathway in immune cells (Natarajan and Bright, 2002) and LIF-induced activation of Jak-Stat pathway in mouse embryonic stem cells (Rajasingh and Bright, 2006). We have also demonstrated earlier that the PPARγ agonists induce growth arrest and apoptosis in BTSCs by blocking EGF/FGF-induced activation of Tyk2-Stat3 pathway in BTSCs (Chearwae and Bright, 2008). Although the precise molecular basis of CAR-mediated antineoplastic effect is under investigation, our findings suggest the use of CAR agonists as a new therapy to target BTSCs for the treatment of glioma patients.