COMPARISON BETWEEN CELLS AND CANCER STEM-LIKE CELLS ISOLATED FROM GLIOBLASTOMA AND ASTROCYTOMA ON EXPRESSION OF ANTI-APOPTOTIC AND MULTIDRUG RESISTANCE–ASSOCIATED PROTEIN GENES F. JIN,a L. ZHAO,b * H.-Y. ZHAO,a S.-G. GUO,c J. FENG,a X.-B. JIANG,a S.-L. ZHANG,b Y.-J. WEI,a R. FUa AND J.-S. ZHAOa a Department of Neurosurgery, Union Hospital, Tongji Medical College, Huazhong University of Science and Technology, Wuhan, 430022, PR China b Department of Hepatology and Infectious Disease, Union Hospital, Tongji Medical College, Huazhong University of Science and Technology, Wuhan, 430022, PR China c Department of Neurology, Shandong Provincial Hospital, Jinan, 250021, PR China Abstract—This study is to explore and compare the features of the cells and cancer stem-like cells (CSCs) isolated from both glioblastoma and astrocytoma on expression of anti-apoptotic and multidrug resistance–associated protein (MRP) genes. As a result, the mRNA expression of livin, livin␣ and MRP1 was up-regulated in human CSCs from 2 times to 85 times, but the gene expression of MRP3 was down-regulated from 0.09 times to 0.5 times. After just differentiation the mRNA expression of livin, livin␣ and MRP3 was up-regulated from9 times to 64 times, but the mRNA expression of MRP1 was down-regulated from 0.01 times to 0.03 times. It is a rare report that glioma stem-like cells can be induced successfully from a grade 2–3 astrocytoma tissue. The properties of glioblastoma and astrocytoma stem-like cells on anti-apoptotic and MRP genes are: anti-apoptotic gene livin and survivin are elevated in CSCs but are the most increased in just differentiated CSCs; MRP1 gene is significantly increased and MRP3 is decreased in CSCs, but when differentiating the MRP3 gene starts a remarkable increase in CSCs; the expression of anti-apoptotic and MRP genes shows no differences between the CSCs isolated from glioblastoma and astrocytoma tissues. © 2008 IBRO. Published by Elsevier Ltd. All rights reserved. Key words: glioma, cancer stem-like cell, glioblastoma, astrocytoma, livin, multidrug resistance–associated protein. Gliomas are the most common type of primary brain tumor. Nearly two-thirds of gliomas are highly malignant lesions that account for a disproportionate share of brain tumor– related morbidity and mortality (Sathornsumetee et al., 2007). Despite recent advances, 2-year survival for glioblastoma with optimal therapy is less than 30%. While surgery, radiation therapy and chemotherapy have roles to play in the treatment of patients with gliomas, these therapies are self-limited because of the intrinsic resistance of glioma cells to therapy, and the diffusely infiltrating nature of the lesions (Nakada et al., 2007). Even among patients with low-grade gliomas that confer a relatively good prognosis, treatment is almost never curative (Norden and Wen, 2006). Though the last decade produced a number of important advances, some of which have translated directly into survival benefits, the prognosis for many patients with gliomas is poor. It is now known that malignant gliomas arise from a number of well-characterized genetic alterations and activations of oncogenes and inactivation of tumor suppressor genes. Those genetic alterations disrupt critical cell cycle, growth factor activation, apoptotic, cell motility, and invasion pathways that lead to phenotypic changes and neoplastic transformation (Bansal et al., 2006). Recently, the concept of cancer stem cells was focused on increasingly (Schulenburg et al., 2006). The findings of brain cancer stem cells were made by applying the principles for cell culture and analysis of normal neural stem cells (NSCs) to brain cancer cell populations and by identification of cell surface markers that allow for isolation of distinct cancer cell populations that can then be studied in vitro and in vivo. A population of brain cancer cells can be enriched for brain cancer stem cells by cell sorting of dissociated suspensions of cancer cells for the NSC marker CD133. These CD133 positive cells, which also expressed the NSC marker nestin, but not differentiated neural lineage markers, represent a minority fraction of the entire brain cancer cell population, and exclusively generate clonal cancer spheres in suspension culture and exhibit increased self-renewal capacity (Singh et al., 2004a). Moreover, progressive explorations have discovered CD133 positive cancer stem cells have a capacity for unlimited self-renewal, as well as the ability to initiate and drive tumor progression in an animal model (Singh et al., 2004b). The cell-membrane protein CD133 has been identified as a marker of a subset of NSCs in the adult CNS as well as of glioma stem or stem-like cells (Bao et al., 2006; Singh et al., 2003, 2004b). In gliomas, WHO (World Health Organization) system assigns a grade from 1 to 4, with one being the least *Corresponding author. Tel: ϩ86-27-62717387; fax: ϩ86-27-84848153. E-mail address: chinesemd@hotmail.com (L. Zhao). Abbreviations: ACC, autologous cancer cell; bFGF, basic fibroblast growth factor; CSC, cancer stem-like cell; Ct, cycle threshold; DMEM/ F12, Dulbecco’s modified Eagle’s medium/nutrient mixture F-12 Ham’s; EGF, epidermal growth factor; FBS, fetal bovine serum; GFAP, glial fibrillary acidic protein; IAP, inhibitor of apoptosis protein; LIF, leukemia inhibitory factor; MRP, multidrug resistance–associated protein; NSC, neural stem cell; PBS, phosphate-buffered saline; WHO, World Health Organization. Neuroscience 154 (2008) 541–550 0306-4522/08$32.00ϩ0.00 © 2008 IBRO. Published by Elsevier Ltd. All rights reserved. doi:10.1016/j.neuroscience.2008.03.054 541 aggressive and four being the most aggressive. Glioblastoma, also called grade 4 astrocytoma, glioblastoma multiforme, is a fast-growing type of CNS tumor that forms from glial (supportive) tissue of the brain and spinal cord and has cells that look very different from normal cells. Astrocytoma is a tumor that begins in the brain or spinal cord in small, star-shaped cells called astrocytes and includes WHO grades 1–3. As in the past all glioma stemlike cells were isolated from glioblastoma, astrocytoma stem cells have not been known so far, and the properties of stem-like cells isolated from glioblastoma and astrocytoma on expression of anti-apoptotic and multidrug resistance–associated protein (MRP) genes have not been compared before. Thereby, we cultured and disassociated cancer stemlike cells (CSCs) from the cell lines and tumor mass of inpatients suffering from both glioblastoma and astrocytoma, and explored the anti-apoptotic and drug resistant gene expression in order to find novel properties of those CSCs. EXPERIMENTAL PROCEDURES Chemicals and reagents Dulbecco’s modified Eagle’s medium/nutrient mixture F-12 Ham’s (DMEM/F12) with high glucose medium was purchased from HyClone (Logan, UT, USA). Fetal bovine serum (FBS), trypsin, B-27 (1ϫ) serum-free supplements were from Gibco (Grand Island, NY, USA). Epidermal growth factor (EGF), basic fibroblast growth factor (bFGF), leukemia inhibitory factor (LIF) was obtained from Peprotech (Rocky Hill, NJ, USA). Rabbit anti-human nestin, rabbit anti-human glial fibrillary acidic protein (GFAP) and mouse antihuman ␤-tubulin antibody were from Santa Cruz Biotechnology (Santa Cruz, CA, USA). Goat anti-mouse IgG-FITC antibody and goat anti-rabbit IgG-FITC antibody were from Sigma (St. Louis, MO, USA). CD133 cell isolation kit (MACS method) was purchased from Miltenyi Biotec GmbH (Bergisch Gladbach, Germany). Tumor specimens and primary cell culture Glioma specimens were collected from 17 inpatients in China Wuhan Union Hospital and their pathological diagnoses were brain glioma. In those patients 10 subjects were of glioblastoma and the others suffered from astrocytoma. The exsected tissues were washed twice with D-Hanks’ solution in aseptic condition. After clearing out of visible blood vessel and necrotic tissue, the glioma tissues were sheared into paste by eye scissors. Then following digestion with 0.25% trypsin for 20 min and blown and stirred by pipette, cell suspension was made prior to terminating digestion by 10% FBS. The suspension was filtered through a 200-mesh sieve and centrifuged at 1000 r.p.m. After disposing of supernatant, the primary glioma cells were washed again with serum-free medium. Then having been centrifuged, the cells were collected and inoculated into a serum-free medium (NSC medium) which contained DMEM/F12 with high glucose medium, 20 ng/mL EGF, 20 ng/mL bFGF, 10 ng/mL LIF and b27 (1ϫ). Last, the cells were placed in incubator on conditions of 37 °C, 5% CO2 and saturated humidity. Every 3–4 days the medium was renewed. Then the induced glioma stem-like cells were cultured in conditions of DMEM/F12 with high glucose medium with 10% FBS for inducing differentiation. The use of human tissue was authorized by the Ethics Committee of Tongji Medical College, Huazhong University of Science and Technology. Glioma cell line culture Glioblastoma U251 cell line was provided by the China Center for Typical Culture Collection (CCTCC) (Wuhan, China). Astrocytoma GL15 cell line was kindly provided by Institute of Neuroscience, Tongji Medical College, Huazhong University of Science and Technology. The two cell lines were cultured in the same conditions as the primary cell culture. Isolation of CD133 positive glioma stem-like cells After the neurospheres grew a large amount, the spheres were collected and the CD133 positive cells were separated by magnetic cell sorting technique (MACS). The sorting process was conducted according to the instruction of the CD133 cell isolation kit. Immunofluorescence staining on glioma tumor stem cells The well-grown cell spheres were selected for growing on the slides which were coated by polylysine. After drying at 37 °C, the slides were washed by phosphate-buffered saline (PBS) three times in order to clear up medium. At room temperature, the cells were fixed by paraform for 30 min, and then were washed by PBS again three times. After blocked by 5% goat serum at 37 °C for 30 min, rabbit anti-human nestin (1:200) (1st antibody) was added and the cells were placed in a wet box for one night. The day following PBS washing, goat anti-rabbit IgG-FITC antibody (2nd antibody) was added for incubation for 30 min at 37 °C. Meanwhile a negative control in which PBS was used instead of the 1st antibody was performed. The slides were observed with an OlymA B Fig. 1. Glioma tissues with HE staining (20ϫ10). (A) Glioblastoma tissue (No.912110); (B) astrocytoma (WHO 2–3 grade) tissue (No. 916718). F. Jin et al. / Neuroscience 154 (2008) 541–550542 pus BX51 fluorescence microscope. The procedure of immunofluorescent assay on GFAP and ␤-tubulin on differentiated glioma stem cells followed the course of nestin except for respective related antibodies. Real-time quantitative RT-PCR The samples were collected and each 50–100 mg tissue samples or 106 cell samples were collected and added 1 mL TRIzol (Jin et al., 2008). The total RNA from glioma cells and glioma stem cells was prepared by adding TRIzol Reagent (Gibco BRL) according to manufacturer’s protocol. The RNA solution was stored at Ϫ80 °C until used. All reactions were performed in duplicate with a negative control (no template) and the mean value of the threshold cycle (the start of exponential amplification) of each sample was normalized with the threshold cycle of glyceraldehyde-3-phosphate dehydrogenase (GAPD), obtaining the ⌬ cycle threshold (Ct) value. Quantitative PCR was performed in ABI-7700 Sequence Detector (Applied Biosystems, Foster City, CA, USA). The reverse transcription was performed with M-MLV reverse transcriptase. The reverse transcriptional reaction system included: 5.5 ␮L H2O, 1.0 ␮L Oligo(dT18) (50 ␮g/mL), total RNA 6.0 ␮L, 70 °C 5 min to ice for unfolding the secondary structure of mRNA; 0.5 ␮L RNasin (40 U/␮L), 4.0 ␮L 5ϫ buffer, 2.0 ␮L dNTP (10 mM), 1.0 ␮L RTase (200 U/␮L), 42 °C 60 min to 95 °C 5 min to 4 °C. A B Fig. 2. Normal glioma cells (10ϫ10). (A) Normally cultured GL15 cells. (B) Normally cultured U251 cells. BA DC Fig. 3. Glioma cells cultured from tissues and cell lines (20ϫ10). (A) Primary cells derived from glioblastoma tissue (No. 912110) at the 5th culturing day in NSC medium. (B) Primary cells derived from astrocytoma tissue (No. 916718) at the 5th culturing day in NSC medium. (C) GL15 cells at the 3rd culturing day in NSC medium. (D) U251 cells at the 3rd culturing day in NSC medium. F. Jin et al. / Neuroscience 154 (2008) 541–550 543 Real time PCR reaction was performed with SYBR GreenIfluorochrome. The standard curve was obtained and Ct value was calculated. Each 50 ␮L PCR system contained 1/50 of the original cDNA, 7 ␮L (25 mM) MgCl2, 0.8 ␮L (20 pmol/␮L) of each primer, 1 ␮L (10 mM) dNTP, 1 ␮L SYBR GreenI, 0.5 ␮L (5 U/␮L) TaqDNA polymerase (Promega, Madison, WI, USA) and 5 ␮L 10ϫ buffer. Fifty cycles of amplification were performed: after 94 °C 3 min, reaction cycle with 94 °C, 30 s, to 57 °C, 30 s, then to 72 °C, 30 s was carried out. The fluorescence signal was detected at the end of each cycle. Melting curve analysis was used to confirm the specificity of the products. The 2Ϫ⌬⌬CT method was performed to analyze the results (Livak and Schmittgen, 2001). The primer was as below: Homo-livin Forward: 5=-ACAGAGGAGGAAGAGGAGGAGG-3= Reverse: 5=-GCAGTCAGCGGCCAGTCATAG-3= Homo-livin␣ Forward: 5=-CTGTCAGTTCCTGCTCCGGTC-3= Reverse: 5=-GGGCTCAAGAACCCACCAC-3= Homo-survivin Forward: 5=-ACTGCCCCACTGAGAACGAGC-3= Reverse: 5=-AAGGAAAGCGCAACCGGACGAAT-3= Homo-MRP1 Forward: 5=-CACCACTGGAGCATTGACTACC-3= Reverse: 5=-GTAATTACAGCAAGCCTGGAACC-3= Homo-MRP3 Forward: 5=-CCTGTATGTGGGTCAAAGTGCG-3= Reverse: 5=-CCCAGCCTCAGGGAAGTGTTG-3= Homo-␤-actin Forward: 5=-CTTAGTTGCGTTACACCCTTTCTTG-3= Reverse: 5=-CTGCTGTCACCTTCACCGTTCC-3= Statistical analysis Each test was perform and then repeated two times. The data were normalized as ratio of CSC/ACC (autologous cancer cells). The data were presented as meanϮS.D. Comparisons of the data were performed with Student t-test. Statistical significance was considered significant when PϽ0.05. The statistical process was performed with SPSS 12.0 software. RESULTS Induction of glioma stem-like cells We found that the primary cancer cells from two tissues, U251 and GL15 cell line (Figs. 1, 2 and 3) could become floating neurospheres by NSC-medium cultivation. When cultured in NSC medium at the 7th–10th culturing day, the floating neurospheres emerged from primary glioma cells, while at the 5th–7th culturing day the GL15 cells produced neurospheres and at the 15th–20th culturing day the U251 cell generated neurospheres (Fig. 4). By CD133 isolation, glioma stem-like cells were induced successfully from two glioma specimens from one glioblastoma (No. 912110) and one grade 2–3 astrocytoma subject (No. 916718), and from U251 and GL15 cell lines (Fig. 5). The CSCs which were cultured in NSC medium grew in suspension and presented the features of stem cells: sphere-like shape, self-renewal and ability to differentiate. Nestin immunoflu- BA DC Fig. 4. Neurospheres emerged from primary cells and cell lines (20ϫ10). (A) Neurospheres emerged from primary glioblastoma cells (No. 912110) at the 7th culturing day in NSC medium. (B) Neurospheres emerged from astrocytoma cells (No. 916718) at the 7th culturing day in NSC medium. (C) Neurospheres emerged from GL15 cells at the 5th culturing day in NSC medium. (D) Neurospheres emerged from U251 cells at the 15th culturing day in NSC medium. F. Jin et al. / Neuroscience 154 (2008) 541–550544 orescence staining of the stem-like cells presented positive but the glioma cells did not show this feature (Fig. 6). Differentiation of glioma stem-like cells The induced glioma stem-like cells started to differentiate after culture conditions of DMEM/F12 medium with 10% FBS. At the 4th hour after culture, the stem-like spheres derived from glioma tissues adhered to the wall and dendrite- or axon-like pseudopodia emerged at the surface of spheres. At the 3rd–5th day, thick dendrite-like pseudopodia grew from all the spheres. As a contrast, the stem-like cells cultured by NSC medium did not show the similar changes. The differentiated cells presented positive ␤-tubulin and GFAP stain but the glioma stem-like spheres did not show this feature (Fig. 7). Comparison of anti-apoptotic and MRP gene expression between glioma CSC and ACC As shown in Table 1, the mRNA expression of livin, livin␣ and MRP-1 was up-regulated in CSCs in both glioma primary cells and cell lines from 2 times to 62 times in CSC derived from cell line and 2 times to 85 times CSC from primary tissues, but the gene expression of MRP-3 was down-regulated from 0.09 times to 0.5 times. The trends of livin␤ were also coincident with livin␣ according to the changes of livin and livin␣. The increasing extent from GL15 cell line was significantly more than that from U251 cell line (PϽ0.01) but the difference did not exist between the CSC from two tissues. Comparison of anti-apoptotic and MRP gene expression between CSC before and after differentiation As shown in Table 2, the mRNA expression of livin, livin␣ and MRP-3 was up-regulated after differentiation in CSC deriving from both glioma specimens from9 times to 64 times. The trends of livin␤ were also coincident with livin␣ according to the changes of livin and livin␣. However, the mRNA expression of MRP-1 was down-regulated from 0.01 times to 0.03 times. DISCUSSION Stem cells are defined by their ability to self-renew, proliferate, and generate progeny that differentiate into the multiple cell types that make up the tissue from which they are derived. The hypothesis that certain cancers may be the result of unregulated stem cells is founded on the suggested similarities between cancer stem cells and somatic stem cells (Ghods et al., 2007). Recently, it has been confirmed by identification of brain cancer stem cells by CD133 (Bao et al., 2006; Singh et al., 2003, 2004b). Identification of brain cancer stem cells provides a powerful tool for the investigation of the tumorigenic process in the CNS, A B DC Fig. 5. Stem-like cell sphere derived from primary cells and cell lines (20ϫ10). (A) Stem-like cell sphere derived from glioblastoma tissue (No. 912110). (B) Stem-like cell sphere derived from astrocytoma tissue (No. 916718). (C) Stem-like cell sphere derived from GL15 cell line. (D) Stem-like cell sphere derived from U251 cell line. F. Jin et al. / Neuroscience 154 (2008) 541–550 545 BA DC FE HG Fig. 6. Nestin immunofluorescence staining (green fluorescence was positive) on glioma stem-like cell spheres and glioma cells (40ϫ10). (A) On spheres derived from glioblastoma tissue (No. 912110). (B) On cells from glioblastoma tissue (No. 912110). (C) On spheres derived from astrocytoma tissue (No. 916718). (D) On cells from astrocytoma tissue (No. 916718). (E) On spheres derived from GL15 cells. (F) On GL15 cells. (G) On spheres derived from U251 cells. (H) On U251 cells. F. Jin et al. / Neuroscience 154 (2008) 541–550546 and will be crucial in developing therapies that use brain cancer stem cells as a target (Singh et al., 2004a). In our research, we successfully separated CD133 positive cells from glioblastoma, astrocytoma tissues and U251, GL15 cell line, and found the separated cells presented properties of cancer stem cells: sphere-like form, self-renewal, ability to differentiate. Especially, we induced primary glioma stem-like cells from two samples of glioma subjects. One was diagnosed as WHO grade 2–3 astrocytoma. So far almost all glioma stem-like cells have been cultured from glioblastoma tissue. It is a rare report that glioma stem-like cells can be induced from astrocytoma. The finding suggests a mildly malignant tumor still has potential abilities to develop into highly malignant cancer and a clear eradication for cancer tissue is necessary in clinic. As discovered now, cancer stem cells are a very small group of cells in the tumor bulk. Thereby inducing cancer stem cells from cancer tissue is not easy work and a successful induction is limited by operational technology, such as the successful rate of primary cell culture, cell survival condition and so on. Our induction rate is similar to the literature (Liu et al., 2006). More effective methods will be developed in the future. We further checked the other properties of glioma stem-like cells on our separated cells. Nestin was selected A B C ED Fig. 7. GFAP and ␤-tubulin immunofluorescence staining (green fluorescence was positive) on differentiated and undifferentiated glioma stem-like cells (20ϫ10). (A) Differentiated glioma stem-like cell. (B) GFAP immunofluorescence staining on differentiated glioma stem-like cell. (C) GFAP immunofluorescence staining on undifferentiated glioma stem-like cell. (D) ␤-Tubulin immunofluorescence staining on differentiated glioma stem-like cell. (E) ␤-Tubulin immunofluorescence staining on undifferentiated glioma stem-like cell. F. Jin et al. / Neuroscience 154 (2008) 541–550 547 to examine the feature of our separated glioma stem-like cells. Nestin is a marker of progenitor cells or precursor cells and now is recognized as a protein marker of NSCs (Hoffman, 2007; Hwang et al., 2007). Many researches chose nestin as a marker to check the properties of brain CSCs. Recent findings also showed nestin has an upregulated expression in glioma stem cells. In our research, the separated cells were nestin positive, which could support that our induced CD133 positive cells were CSCs. We further cultured the tumor stem cells by NSC medium and found this method could maintain growth of the CSCs. After being induced to differentiation by culture with DMEM/F12 medium, the CSCs from both cancer tissue and glioma cell lines presented GFAP and ␤-tubulin positive. As GFAP is the astrocyte lineage marker and ␤-tubulin is considered as the neuronal lineage marker (Ghods et al., 2007), it could be implied that our induced CD133 positive cells had the potential to differentiate into astrocytes and neurons, which shows the cells possess the property to differentiate into different ACCs. The inhibitor of apoptosis protein (IAP) family encodes a group of baculovirus IAP repeat domain (BIR) –containing proteins that suppress apoptosis (Huang et al., 2006). Survivin is an important member of IAP. This protein is highly expressed in most cancers and associated with chemotherapy resistance, increased tumor recurrence, and shorter patient survival, but rarely is expressed in terminally differentiated adult tissues (Fukuda and Pelus, 2006). Current documents show that biological functions of survivin include inhibition of apoptosis, promotion of mitosis, angiogenesis, which play a causative role in cancer formation and/or progression (Duffy et al., 2007). In our research, it was observed that gene expression of the member of IAP was up-regulated in CSCs, which implies the glioma stem-like cells are a main factor to resist cancer apoptosis and maintain cancer growth and angiogenesis. Furthermore, it was also investigated that survivin continued rising in differentiated glioma stem-like cells. It has been reported that survivin expresses more highly in glioma CSCs (Ghods et al., 2007). Inferred by our finding, the anti-apoptotic gene is the most highly expressed in just differentiated glioma CSCs, which presents a more detailed profile of survivin expression in glioma stem-like cells. Livin is also a member of the IAP family of caspase inhibitors that selectively binds the endogenous IAP antagonist (second mitochondria-derived activator of caspases) SMAC and caspase-3, caspase-7, and caspase-9, which encode negative regulatory proteins that prevent cell apoptosis (Chang and Schimmer, 2007). Livin is selectively expressed in the most common human neoplasms and appears to be involved in tumor cell resistance to chemotherapeutic agents (Liu et al., 2007; Kempkensteffen et al., 2007). In our research, it was observed that gene expression of livin and livin␣ was up-regulated in CSCs. As livin contains two isoforms: livin␣ and livin␤, it could be deduced that livin␤ had a similar elevating expression to livin␣ in the CSCs and differentiated CSCs. Like survivin the rising expression of livin in glioma stem-like cells also shows its causative role for anti-apoptosis and anti-chemotherapy by inhibiting the function of SMAC and caspase molecules. Furthermore, the fact the highest expression of livin in differentiated CSCs also demonstrates the just differentiating or having differentiated glioma stem-like cells are the most tolerant stage to promote growth of cancer cells and to resistant apoptosis and chemotherapeutic drugs. The findings of survivin and livin expression in CSC and just differentiated CSC suggest that the group of CSC may be the highest malignant cell population in cancer bulk. This can be interpreted this way: a relapsing cancer is more malignant after treatments because the relapsing cancer tissue may be developed from uneliminated cancer cells, cancer stem cells. MRP is a 180- to 195-kDa membrane protein associated with resistance of human tumor cells to cytotoxic drugs (Zaman et al., 1994). Numerous members of the Table 1. Anti-apoptotic and MRP gene expression on glioma CSC compared to that on ACC Gene name Glioblastoma No. 912110 Astrocytoma No. 916718 GL15 U251 ACC CSC ACC CSC ACC CSC ACC CSC Livin 1 52.543Ϯ4.281 1 57.084Ϯ5.362 1 6.695Ϯ0.437* 1 3.912Ϯ0.231 Livin␣ 1 11.574Ϯ0.852 1 34.279Ϯ2.935 1 62.336Ϯ5.017* 1 8.699Ϯ0.779 Survivin 1 2.457Ϯ0.205 1 1.943Ϯ0.138 1 4.867Ϯ0.403* 1 2.972Ϯ0.275 MRP-1 1 64.287Ϯ7.803 1 85.736Ϯ8.754 1 54.042Ϯ4.772* 1 2.015Ϯ0.183 MRP-3 1 0.094Ϯ0.004 1 0.275Ϯ0.017 1 0.533Ϯ0.038 1 0.453Ϯ0.047 The value of ACC was normalized as 1 and the value of CSC was expressed as relative value. * PϽ0.01 compared to the value of CSC in U251 group. Table 2. Anti-apoptotic and MRP gene expression on CSC compared to that on differentiated stem-like cells (DSC) Gene name Glioblastoma No. 912110 Astrocytoma No. 916718 CSC DSC CSC DSC Livin 1 24.783Ϯ2.038 1 17.695Ϯ1.894 Livin␣ 1 57.784Ϯ5.832 1 82.196Ϯ7.539 Survivin 1 12.853Ϯ1.439 1 9.361Ϯ1.474 MRP-1 1 0.037Ϯ0.002 1 0.014Ϯ0.003 MRP-3 1 64.739Ϯ5.961 1 52.673Ϯ6.197 The value of CSC was standardized as 1 and the value of DSC was expressed as relative value. F. Jin et al. / Neuroscience 154 (2008) 541–550548 multidrug resistance associated protein family serve as export pumps that prevent the accumulation of anionic conjugates and glutathione disulfide (GSSG) in the cytoplasm, and play, therefore, an essential role in detoxification and defense against oxidative stress (Homolya et al., 2003). The 190 kDa multidrug resistance protein MRP1 is involved in the multidrug resistance phenotype of human gliomas (Benyahia et al., 2004). In gliomas, mainly MRP1 has been studied thus far and was found to be localized to the tumor vasculature and partially also to the tumor cells (Mohri et al., 2000; Aronica et al., 2003; Andersson et al., 2004; Benyahia et al., 2004). In glioma cell lines, MRP1 is shown to confer resistance to various anticancer drugs (Benyahia et al., 2004; Bronger et al., 2005). Apart from MRP1, some research showed gene MRP3 is hyperexpressed in astrocytomas for the primary resistance to chemotherapy (Calatozzolo et al., 2005) and MRP3 can modulate drug sensitivity to certain anticancer agents in human gliomas (Haga et al., 2001). We detected MRP1 and MRP3 gene expression in both glioma stem-like cells and autologous cancer cells and found MRP1 was the most highly expressed in glioma stem-like cells and MRP3 was much less expressed in CSCs, which was different from the past reports (Salmaggi et al., 2006). That is to say, MRP1 plays a more significant role as multidrug resistance transporter than MRP3 in glioma stem-like cells. However, after differentiation, the expression of MRP3 notably rose, which showed when just differentiating or having differentiated, the cells perform resisting chemotherapeutics via MRP3 function. As the MRP family has been considered as a target for reducing chemotherapeutic drug resistance, the variation of MRPs in CSCs may be important in the future therapeutic strategies. GL15 cell line is derived from glioblastoma (Bocchini et al., 1991), while the U251 cell line is cultured from astrocytoma (Akhyani et al., 2006). We compared the gene expression between those two cell lines on livin, survivin and MRP1 and found more up-regulations of those genes existed in CSCs derived from the GL15 cell line, which is coincident with malignant degree of glioblastoma. However, the same trends did not occur in glioma stem-like cells derived from tissues, which showed a more complicated influence in human body and the malignant difference between glioblastoma and astrocytoma is not due to the tested anti-apoptotic and MRP genes. Cancer is among the leading causes of morbidity and mortality in the world (Jin et al., 2008). Despite recent advances, most therapeutic approaches fail to eradicate the entire neoplastic clone. The remaining cells often develop metastasis and/or recurrences and therefore may represent attractive targets of therapy. In this research, we successfully induced and cultured CSCs from both glioma tissues and cell lines. Especially, we induced tumor stem cells from astrocytoma tissue. Moreover, we found the properties of human brain glioma stem-like cells: antiapoptotic gene is elevated in glioma stem-like cells but is the most increased in just differentiated glioma stem-like cells; MRP1 gene is significantly increased but MRP3 is decreased in glioma stem-like cells, and when differentiating the MRP3 gene starts a remarkable increase in glioma stem-like cells; but the difference of malignant grade between glioblastoma and astrocytoma is not due to the tested anti-apoptotic and MRP genes. Acknowledgments—This study is sponsored by the China Shandong Provincial Development Program of Medical Science and Technology (No. 2007HZ019) and Jining City Development Program of Science and Technology (No. 2006-11-33). REFERENCES Akhyani N, Fotheringham J, Yao K, Rashti F, Jacobson S (2006) Efficacy of antiviral compounds in human herpesvirus-6-infected glial cells. J Neurovirol 12:284–293. Andersson U, Malmer B, Bergenheim AT, Brännström T, Henriksson R (2004) Heterogeneity in the expression of markers for drug resistance in brain tumors. Clin Neuropathol 23:21–27. Aronica E, Gorter JA, Jansen GH, van Veelen CW, van Rijen PC, Leenstra S, Ramkema M, Scheffer GL, Scheper RJ, Troost D (2003) Expression and cellular distribution of multidrug transporter proteins in two major causes of medically intractable epilepsy: focal cortical dysplasia and glioneuronal tumors. Neuroscience 118: 417–429. Bansal K, Liang ML, Rutka JT (2006) Molecular biology of human gliomas. Technol Cancer Res Treat 5:185–194. Bao S, Wu Q, McLendon RE, Hao Y, Shi Q, Hjelmeland AB, Dewhirst MW, Bigner DD, Rich JN (2006) Glioma stem cells promote radioresistance by preferential activation of the DNA damage response. Nature 444:756–760. Benyahia B, Huguet S, Declèves X, Mokhtari K, Crinière E, Bernaudin JF, Scherrmann JM, Delattre JY (2004) Multidrug resistance-associated protein MRP1 expression in human gliomas: chemosensitization to vincristine and etoposide by indomethacin in human glioma cell lines overexpressing MRP1. J Neurooncol 66:65–70. Bocchini V, Casalone R, Collini P, Rebel G, Lo Curto F (1991) Changes in glial fibrillary acidic protein and karyotype during culturing of two cell lines established from human glioblastoma multiforme. Cell Tissue Res 265:73–81. Bronger H, König J, Kopplow K, Steiner HH, Ahmadi R, Herold-Mende C, Keppler D, Nies AT (2005) ABCC drug efflux pumps and organic anion uptake transporters in human gliomas and the blood-tumor barrier. Cancer Res 65:11419–11428. Calatozzolo C, Gelati M, Ciusani E, Sciacca FL, Pollo B, Cajola L, Marras C, Silvani A, Vitellaro-Zuccarello L, Croci D, Boiardi A, Salmaggi A (2005) Expression of drug resistance proteins Pgp, MRP1, MRP3, MRP5 and GST-pi in human glioma. J Neurooncol 74:113–121. Chang H, Schimmer AD (2007) Livin/melanoma inhibitor of apoptosis protein as a potential therapeutic target for the treatment of malignancy. Mol Cancer Ther 6:24–30. Duffy MJ, O’Donovan N, Brennan DJ, Gallagher WM, Ryan BM (2007) Survivin: a promising tumor biomarker. Cancer Lett 249:49–60. Fukuda S, Pelus LM (2006) Survivin, a cancer target with an emerging role in normal adult tissues. Mol Cancer Ther 5:1087–1098. Ghods AJ, Irvin D, Liu G, Yuan X, Abdulkadir IR, Tunici P, Konda B, Wachsmann-Hogiu S, Black KL, Yu JS (2007) Spheres isolated from 9L gliosarcoma rat cell line possess chemoresistant and aggressive cancer stem-like cells. Stem Cells 25:1645–1653. Haga S, Hinoshita E, Ikezaki K, Fukui M, Scheffer GL, Uchiumi T, Kuwano M (2001) Involvement of the multidrug resistance protein 3 in drug sensitivity and its expression in human glioma. Jpn J Cancer Res 92:211–219. Hoffman RM (2007) The potential of nestin-expressing hair follicle stem cells in regenerative medicine. Expert Opin Biol Ther 7: 289–291. F. Jin et al. / Neuroscience 154 (2008) 541–550 549 Homolya L, Váradi A, Sarkadi B (2003) Multidrug resistance-associated proteins: Export pumps for conjugates with glutathione, glucuronate or sulfate. Biofactors 17:103–114. Huang RC, Chang CC, Mold D (2006) Survivin-dependent and -independent pathways and the induction of cancer cell death by tetra-O-methyl nordihydroguaiaretic acid. Semin Oncol 33:479– 485. Hwang HS, Cho NH, Maeng YS, Kang MH, Park YW, Kim YH (2007) Differential expression of nestin in normal and pre-eclamptic human placentas. Acta Obstet Gynecol Scand 86:909–914. Jin F, Zhao L, Zhao HY, Guo SG, Feng J, Jiang XB, Zhang SL, Wei YJ, Fu R, Zhao JS (2008) Paradoxical expression of anti-apoptotic and MRP genes on cancer stem-like cell isolated from TJ905 glioblastoma multiforme cell line. Cancer Investigation [Epub ahead of print]. Doi: 10.1080/07357900701788064. Kempkensteffen C, Hinz S, Christoph F, Krause H, Koellermann J, Magheli A, Schrader M, Schostak M, Miller K, Weikert S (2007) Expression of the apoptosis inhibitor livin in renal cell carcinomas: correlations with pathology and outcome. Tumour Biol 28:132– 138. Liu B, Han M, Wen JK, Wang L (2007) Livin/ML-IAP as a new target for cancer treatment. Cancer Lett 250:168–176. Liu G, Yuan X, Zeng Z, Tunici P, Ng H, Abdulkadir IR, Lu L, Irvin D, Black KL, Yu JS (2006) Analysis of gene expression and chemoresistance of CD133ϩ cancer stem cells in glioblastoma. Mol Cancer 5:67. Livak KJ, Schmittgen TD (2001) Analysis of relative gene expression data using real-time quantitative PCR and the 2(-delta delta C(T)) method. Methods 25:402–408. Mohri M, Nitta H, Yamashita J (2000) Expression of multidrug resistance-associated protein (MRP) in human gliomas. J Neurooncol 49:105–115. Nakada M, Nakada S, Demuth T, Tran NL, Hoelzinger DB, Berens ME (2007) Molecular targets of glioma invasion. Cell Mol Life Sci 64:458–478. Norden AD, Wen PY (2006) Glioma therapy in adults. Neurologist 12:279–292. Salmaggi A, Boiardi A, Gelati M, Russo A, Calatozzolo C, Ciusani E, Sciacca FL, Ottolina A, Parati EA, La Porta C, Alessandri G, Marras C, Croci D, De Rossi M (2006) Glioblastoma-derived tumorospheres identify a population of tumor stem-like cells with angiogenic potential and enhanced multidrug resistance phenotype. Glia 54:850–860. Sathornsumetee S, Reardon DA, Desjardins A, Quinn JA, Vredenburgh JJ, Rich JN (2007) Molecularly targeted therapy for malignant glioma. Cancer 110:13–24. Schulenburg A, Ulrich-Pur H, Thurnher D, Erovic B, Florian S, Sperr WR, Kalhs P, Marian B, Wrba F, Zielinski CC, Valent P (2006) Neoplastic stem cells: a novel therapeutic target in clinical oncology. Cancer 107:2512–2520. Singh SK, Clarke ID, Hide T, Dirks PB (2004a) Cancer stem cells in nervous system tumors. Oncogene 23:7267–7273. Singh SK, Hawkins C, Clarke ID, Squire JA, Bayani J, Hide T, Henkelman RM, Cusimano MD, Dirks PB (2004b) Identification of human brain tumour initiating cells. Nature 432:396–401. Singh SK, Clarke ID, Terasaki M, Bonn VE, Hawkins C, Squire J, Dirks PB (2003) Identification of a cancer stem cell in human brain tumors. Cancer Res 63:5821–5828. Zaman GJ, Flens MJ, van Leusden MR, de Haas M, Mülder HS, Lankelma J, Pinedo HM, Scheper RJ, Baas F, Broxterman HJ, Borst P (1994) The human multidrug resistance-associated protein MRP is a plasma membrane drug-efflux pump. Proc Natl Acad Sci U S A 91:8822–8826. (Accepted 15 March 2008) (Available online 1 April 2008) F. Jin et al. / Neuroscience 154 (2008) 541–550550