Human Glioma Cells In Culture Research Articles

The Bi-(AID-1-T) G-Quadruplex Has a Janus Effect on Primary and Recurrent Gliomas: Anti-Proliferation and Pro-Migration.

High-grade gliomas are considered an incurable disease. Despite all the various therapy options available, patient survival remains low, and the tumor usually returns. Tumor resistance to conventional therapy and stimulation of the migratory activity of surviving cells are the main factors that lead to recurrent tumors. When developing new treatment approaches, the effect is most often evaluated on standard and phenotypically depleted cancer cell lines. Moreover, there is much focus on the anti-proliferative effect of such therapies without considering the possible stimulation of migratory activity. In this paper, we studied how glioma cell migration changes after exposure to bi-(AID-1-T), an anti-proliferative aptamer. We investigated the effect of this aptamer on eight human glioma cell cultures (Grades III and IV) that were derived from patients' tumor tissue; the difference between primary and recurrent tumors was taken into account. Despite its strong anti-proliferative activity, bi-(AID-1-T) was shown to induce migration of recurrent tumor cells. This result shows the importance of studying the effect of therapeutic molecules on the invasive properties of glioma tumor cells in order to reduce the likelihood of inducing tumor recurrence.

The Identification and Validation of Plasma Membrane Proteins as Potential Therapeutic Targets for Histone H3 Mutant Paediatric High-Grade Gliomas

Abstract AIMS Paediatric high-grade gliomas (pHGG) are the leading cause of cancer-related death in children. Histone H3.3 mutations are an important hallmark of pHGG, but for which their underlying oncogenic mechanisms are incompletely understood. This research aims to identify potential molecular effectors in these tumours that may be therapeutically effective. METHOD To assess potential molecular effectors, we employed proteomic profiling using LC-MS/MS and determined plasma membrane proteins of the surfactome that are differentially expressed on the surface of H3.3 mutant (G34R, G34V), compared to H3.3-wildtype human glioma cells in culture. RESULTS Profiling of plasma membrane-enriched fractions identified 34 membrane proteins exclusively detected from H3 G34V mutant cells compared to H3 wild-type cells, and 10 membrane proteins exclusively detected from H3 G34R mutant cells, with 39 membrane proteins shared between both H3 G34R/V genotypes. One of these shared membrane proteins, GLUT1 (glucose transporter) has very recently been reported to be over-expressed and linked to tumour phenotypes in mouse glioma cells manipulated to carry the most common DIPG-associated H3.3-K27M mutation [Miya et al. Neuro-Oncology Advances 2021]. Here, we explore the functional significance of GLUT1 differential expression in H3.3 mutant (G34R, G34V) human glioma cells.

MODL-23. The identification and validation of plasma membrane proteins as potential therapeutic targets for histone H3 mutant paediatric high-grade gliomas.

Abstract Paediatric high grade gliomas (pHGG) are the leading cause of cancer-related death in children. Histone H3.3 mutations are an important hallmark of pHGG, but their underlying oncogenic mechanisms are incompletely understood. Towards identifying molecular effectors that may be therapeutically effective, we employed proteomic profiling and determined plasma membrane proteins of the surfactome that are differentially expressed on the surface of H3.3 mutant (G34R, G34V) compared to H3.3-wildtype human glioma cells in culture. Profiling of plasma membrane-enriched fractions identified 34 membrane proteins exclusively detected from H3 G34V mutant cells compared to H3 wild-type cells, and 10 membrane proteins exclusively detected from H3 G34R mutant cells, with 39 membrane proteins shared between both H3 G34R/V genotypes. One of these shared membrane proteins, GLUT1 (glucose transporter), has very recently been reported to be over-expressed and linked to tumour phenotypes in mouse glioma cells manipulated to carry the most common DIPG-associated H3.3-K27M mutation [Miya et al. Neuro-Oncology Advances 2021]. Here, we explore the functional significance of GLUT1 differential expression in H3.3 mutant (G34R, G34V) human glioma cells. Collective observations support a model where different H3.3 mutations converge on changes in GLUT1 expression and reinforce GLUT1 as a potential therapeutic target in paediatric high-grade gliomas.

EXTH-44. DEVELOPMENT OF RETROVIRAL REPLICATING VECTORS ENCODING SEQUENCE-OPTIMIZED NITROREDUCTASE FOR PRODRUG ACTIVATOR GENE THERAPY IN HUMAN GLIOMA MODELS

Abstract Early-phase clinical trials of Toca 511, a retroviral replicating vector (RRV) expressing an optimized form of yeast cytosine deaminase for prodrug activator gene therapy, showed highly promising evidence of therapeutic benefit and increased survival in recurrent high-grade glioma, but an international Phase 3 trial failed to meet primary and secondary endpoints. Nonetheless, promising results observed within predetermined subgroups, combined with the highly favorable safety profile of this approach, make it worthwhile to consider alternative prodrug-activating enzymes in order to increase therapeutic efficacy. In this study, we employed RRV to deliver modified versions of another prodrug activator gene, E.coli nitroreductase (NTR), which activates the prodrug CB1954 to generate a potent bifunctional alkylating agent. We constructed RRV encoding two different isoforms of wild-type E.coli NTR genes (NfsA, NfsB) as well as variants of both isoforms extensively modified to optimize human codon usage and vector stability. Further efforts to improve the potency of these prodrug activator enzymes included the construction of additional new vectors incorporating point mutations at the active site which have previously been demonstrated to improve prodrug conversion efficiency. NTR transgene insertion did not affect RRV replication, which resulted in increasing NTR expression over time in human glioma cells in culture. Sequence optimization resulted in enhanced genomic stability of the vectors upon serial passage and also in significantly reduced cell viability in vitro on treatment of fully transduced U87 and U87-EGFRviii glioma cells with CB1954 prodrug. In orthotopic U87-EGFRviii intracerebral tumor models, stereotactic intratumoral injection of sequence-optimized RRV-NTR and repeated cycles of prodrug treatment resulted in rapid and significant reduction of tumor burden as monitored by bioluminescence imaging, leading to prolonged survival benefit. These data indicate that improved therapeutic efficacy can be achieved with optimized NTR prodrug activator gene therapy delivered by RRV in experimental glioma models.

EDL-360: A Potential Novel Antiglioma Agent

Glioma is a brain tumor that arises from glial cells or glial progenitor cells, and represents 80% of malignant brain tumor incidence in the United States. Glioblastoma multiforme (GBM) is the most aggressive primary brain tumor malignancy with fewer than 8% of patients with GBM surviving for more than 3 years. Over the past 10 years, despite improvement in diagnosis and therapies for cancer, the survival rate for high-grade glioma patients remains dismal. The main focus of our research is to identify potent novel antiglioma small molecules. We previously showed that EDL-360, a tetrahydroisoquinoline (THIQ) analog, as being highly cytotoxic to human glioma cell cultures. Here we show that EDL-360 significantly induced apoptosis in human glioma cell lines (U87 and LN18). However, in normal astrocytic cells, EDL-360 induced a modest G0/G1 cell cycle arrest but did not induce apoptosis. In an attempt to enhance EDL-360 induced cell death, we tested simultaneous treatment with EDL-360 and embelin (an inhibitor of the anti-apoptotic protein, XIAP). We found that, glioma cells had significant lower viability when EDL-360 and embelin were used in combination when compared to EDL-360 alone. We also used combination treatment of EDL-360 with decylubiquinone (dUb), a caspase-9 inhibitor, and found that the combination treatment induced a significant cell death when compared to treatment with EDL-360 alone. This is the first report that suggests that dUb has anticancer activity, and perhaps acts as a XIAP inhibitor. Finally, our in vivo data showed that EDL-360 treatment induced a partial regression in glioma tumorigenesis and induced cell death in the treated tumors as shown by H&E staining. Taken together these data suggests that EDL-360 has a potential therapeutic application for treating glioma, especially when combined with XIAP inhibitors.

Abstract 3343: Upregulation of SOX5 perturbs human glioma cell proliferation and is associated with proneural glioblastoma

Abstract Background: The proneural subtype of glioblastoma (GBM) is characterized by PDGFRα alterations. In a retroviral insertional mutagenesis screen (Johansson et al., PNAS, 2004) the transcription factor Sox5 was identified as a candidate brain tumor locus and the mode of insertions indicated an overexpression of the short version of Sox5 (s-Sox5). This led to an investigation of the role of s-Sox5 in glioma development, and we subsequently found that opposite to our hypothesis, s-Sox5 could inhibit glioma development in mice, reduce cell proliferation and clone formation ability of human glioma cell lines, and induce acute cellular senescence in primary mouse glial cells through regulation of AKT and p27Kip1 (Tchougounova et al., Oncogene, 2009). Aims: To investigate if s-SOX5 alterations are associated with a certain subtype of human GBM, and to identify the mechanism behind the anti-tumoral properties of s-SOX5 in newly established human glioma cell cultures (HGCCs). Methods: The TCGA dataset for GBM was analyzed via the cBio Cancer Genomics Portal (http://cbioportal.org) for alterations in SOX5 + other SOX genes and glioma genes. Endogenous SOX5 + expression of other SOX proteins were analyzed with immunostainings in six newly established HGCCs maintained under stem cell conditions. These HGCCs were also transfected with pcDNA-V5-s-Sox5, and analyzed by flow cytometry for EdU incorporation, cleaved Caspase-3 and V5. Results: We found that the majority of SOX5 alterations were confined to the proneural subtype (10/56 cases) with 90% of the alterations being upregulations. In fact, all upregulations of SOX5 were found in the proneural group. Only a few alterations (3/56; all downregulations) were found in the mesenchymal subtype, and none in the classical or neural subgroups. The upregulated SOX5 expression in the proneural subtype could be connected to a slight increase in patient survival. Co-occurring alterations in s-SOX5, PDGFRα, SOX6 and SOX10 were found in the proneural subtype. These findings are only suggestive and need to be validated in larger set of tumor samples. Immunostainings showed that all HGCCs expressed SOX2, SOX6, SOX9 and SOX10. For SOX5, two were completely negative while the remaining four showed varying expression. The transfection efficiency was very low (10%), but when specifically analyzing the V5-s-SOX5 positive cells, we found in all HGCCs a reduced number of EdU positive cells compared to the uninfected cell population of the same sample (statistically significant in three HGCCs). Conclusion: Our preliminary data suggest that upregulation of s-SOX5 could be a defining alteration in the proneural subgroup of GBM, and that s-SOX5 suppresses proliferation of human glioma cell cultures. Further studies are underway to solidify our findings and clarify the mechanism behind s-SOX5/Sox5 inhibition of glioma cells. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr 3343. doi:1538-7445.AM2012-3343

Anti-tumour effects by a trimodal combination of temozolomide, meloxicam and X-rays in cultures of human glioma cells

Purpose: To investigate the possible cytotoxic interactions between the chemotherapeutic drug temozolomide (TMZ) and the cyclooxygenase-2 inhibitor meloxicam (MLC) or of both drugs combined with X-rays in three human glioma cell lines (D384, Hs 683 and U251).Materials and methods: Cells were exposed to TMZ (96 hours) and MLC was co-incubated during the last 24 h. Thereafter, cells were irradiated with X-rays and plated for a clonogenic assay. Total cell numbers and the numbers of surviving cells were determined to study the recovery of the cell populations (up until 19 days) following different combinations of TMZ, MLC and X-rays.Results: The combination of MLC and TMZ caused an enhanced cytotoxic effect in D384 and Hs 683. Various treatment combinations demonstrated significant radiation enhancement in all three cell lines. Long-term observations of D384 cells demonstrated that the repopulation rates of the surviving cells are far less affected by the various treatment protocols than those from the non-surviving cells.Conclusions: The present study demonstrates that a combination of TMZ and MLC resulted in a significant potentiation of their cytotoxicity in D384 and Hs683. The combination of these two drugs can also cause considerable enhancement of the radiation response in human glioma cell lines, although only D384 cells benefit from trimodal over bimodal treatment.

Synthesis and analysis of 2-[211At]-l-phenylalanine and 4-[211At]-l-phenylalanine and their uptake in human glioma cell cultures in-vitro

2-[211At]-L-phenylalanine and 4-[211At]-L-phenylalanine were prepared from the corresponding iodo and bromo derivatives using the Cu(+)-assisted nucleophilic exchange. 4-[211At]-L-phenylalanine was additionally prepared by destannylation of the BOC-derivatized 4-tributylstannyl-L-phenylalanine. Radiochemical yields of 2-[211At]-L-phenylalanine and 4-[211At]-L-phenylalanine by nucleophilic exchange were 52-74% and 65-85%. Radiochemical yield of 4-[211At]-L-phenylalanine by electrophilic destannylation was 35-50%. HPLC sequence analysis showed that 2-[211At]-L-phenylalanine followed the halogen sequence (F<Cl<Br<I<At) whereas 4-[211At]-L-phenylalanine eluted between 4-Br-L-phenylalanine and 4-I-L-phenylalanine (F<Cl<Br<At<I), independent on the production pathway. Uptake of 4-[211At]-L-phenylalanine and 4-[131I]-L-phenylalanine in DBTRG-05MG glioma cells was inhibited by l-phenylalanine 7-fold and 6-fold, respectively.

Targeting human glioma cells using HSV-1 amplicon peptide display vector

Targeting cell infection using herpes simplex virus type 1 (HSV-1) vectors is a complicated issue as the process involves multiple interactions of viral envelope glycoproteins and cellular host surface proteins. In this study, we have inserted a human glioma-specific peptide sequence (denoted as MG11) into a peptide display HSV-1 amplicon vector replacing the heparan sulfate-binding domain of glycoprotein C (gC). The modified MG11:gC envelope recombinant vectors were subsequently packaged into virions in the presence of helper virus deleted for gC. Our results showed that the tropism of these HSV-1 recombinant virions was increased for human glioma cells in culture as compared with wild-type virions. The binding of these recombinant virions could also be blocked effectively by pre-incubating the cells with the glioma-specific peptide, indicating that MG11 peptide and the recombinant virions competed for the same or similar receptor-binding sites on the cell surface of human glioma cells. Furthermore, preferential homing of these virions was shown in xenograft glioma mouse model following intravascular delivery. Taken together, these results validated the hypothesis that HSV-1 binding to cells can be redirected to human gliomas through the incorporation of MG11 peptide sequence to the virions.

Cell surface expression of system xc− is upregulated in non‐confluent cell cultures

System xc− is a transport system that exchanges extracellular cystine for intracellular glutamate. The transporter plays an important role in providing cysteine as a precursor for glutathione synthesis and in maintaining the redox balance within the cell. We recently reported that oxidants regulate the activity of System xc− by altering the rate of trafficking of the transporter to the plasma membrane. Additionally, we have demonstrated that cell surface expression of System xc− is influence by cell culture density. Using cell surface biotinylation assays, we showed that only 35‐45% of the transporter is localized to the plasma membrane in confluent cultures of human glioma cells, while 90% of the transporter is localized to the membrane in cultures which are only 50% confluent. In this study, we tested the hypothesis that the difference in membrane localization of System xc− is a result of a greater glutathione demand in actively dividing non‐confluent cells compared to confluent cells which are no longer actively dividing. We used enzymatic assays and immunotcytochemical methods to measure the glutathione levels in confluent and non‐confluent cultures of human glioma cells. These studies reported here combined with our previous studies suggest that the localization of System xc− is influenced by the glutathione levels in the cells independent of the mechanism by which gluathione levels are modulated.

Hypericin uptake: A prognostic marker for survival in high-grade glioma

Currently adjuvant chemotherapy for glioblastoma patients can prolong survival time relative to patients who receive only surgery and radiotherapy. Despite these improvements and experimental and clinical efforts the prognosis for glioblastoma patients remains poor. At present, interest is focused on individual prognostic factors influencing patient responses to therapy. Photodynamic therapy may be a promising therapeutic option in the treatment of glioblastoma. In this investigation we examined whether uptake of hypericin (HY), a fluorescent photosensitization agent, by ex vivo glioblastoma cell lines correlates with prognosis of the individual from which the cell lines were derived. Twelve primary human glioma cell cultures were incubated with 20 μmol HY. Fluorescence intensity was measured using fluorescence microscopy. Three patients suffered from an anaplastic astrocytoma, WHO grade III, nine had a glioblastoma, WHO grade IV. In 6/12 patients complete tumour resection was possible. The mean survival time of the six patients in whom complete tumour resection was performed was 26 months, compared with 5 months for those who underwent incomplete resection. Eleven patients received radiation therapy. The five patients who received chemotherapy survived for a mean duration of 26 months, compared with the seven patients who survived for a mean duration of 5 months without chemotherapy. Statistical analysis using a parametric survival model based on the Weibull distribution showed that fluorescence intensity was the variable with the lowest p-value associated with survival ( p = 0.0225). An increase of 553 arbitrary units of fluorescence intensity is predicted to double survival time. Uptake of HY, a lipophilic molecule, is assumed to be related to low-density lipoprotein (LDL) uptake and metabolism. Cell proliferation is associated with a high turnover of cholesterol and membrane growth, which is related to cholesterol uptake by LDL. In summary, HY uptake by ex vivo glioblastoma cell cultures seems to be positively associated with survival of patients with malignant glioma.

Influence of oxygen tension on CD133 phenotype in human glioma cell cultures

Under standard culture conditions, tumor cells are exposed to 20% O 2, whereas the mean tumor oxygen levels within the tumor are much lower. We demonstrate, using low-passaged human tumor cell cultures established from glioma, that a reduction in the oxygen level in these cell cultures dramatically increases the percentage of CD133 expressing cells.

HSV-1 amplicon-mediated post-transcriptional inhibition of Rad51 sensitizes human glioma cells to ionizing radiation

Standard treatment for glioblastoma multiforme and other brain tumors consists of surgical resection followed by combined radio-/chemotherapy. However, radiation resistance of tumor cells limits the success of this treatment, and the tumors invariably recur. Therefore, the selective inhibition of molecular mediators of radiation resistance may provide therapeutic benefit to the patient. One of these targets is the Rad51 protein, which is a key component of the homologous recombinational repair of DNA double-strand breaks. Here, we investigated whether post-transcriptional silencing of Rad51 by herpes simplex virus-type 1 (HSV-1) amplicon vector-mediated short interfering RNA expression can enhance the antitumor effect of radiation therapy. We demonstrate that these vectors specifically and efficiently inhibited the radiation-induced recruitment of Rad51 into nuclear foci in human glioma cells. The combination of vector-mediated silencing of Rad51 expression and treatment with ionizing radiation resulted in a pronounced reduction of the survival of human glioma cells in culture. In athymyc mice, a single intratumoral injection of Rad51-specific HSV-1 amplicon vector followed by a single radiation treatment resulted in a significant decrease in tumor size. In control animals, including mice that received an intratumoral injection of Rad51-specific amplicon vector but no radiation treatment, the tumor sizes increased.

Delta-24 Increases the Expression and Activity of Topoisomerase I and Enhances the Antiglioma Effect of Irinotecan

In this study, we sought to determine whether Delta-24 could sensitize glioma cells to the topoisomerase I inhibitor irinotecan (CPT-11) and to identify the mechanisms underlying this enhanced anticancer effect. We used human glioblastoma cell lines for the in vitro studies. The expression of topoisomerase I was determined in Western blot analyses, and topoisomerase I activity was determined by measuring the relaxation of a supercoiled DNA. The cell cycle distribution of cells was determined by flow cytometry analysis of the cellular DNA content. Cell viability was quantified by a 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide assay. Tissue culture infection dose assays were used to quantitate adenovirus replication. For the in vivo studies, athymic mice received intracranial/intratumoral injections of Delta-24 in combination with CPT-11, after which animal survival was monitored. Delta-24 infection caused human glioma cells to accumulate in the S phase and induced the expression and activity of topoisomerase I as shown by Western blot and in vitro enzymatic activity assays. Further, we showed that the sequential administration of Delta-24 and CPT-11 to human glioma cell cultures potentiated the CPT-11-mediated anticancer effect in vitro without modifying the replicative phenotype of the oncolytic adenovirus. In vivo experiments showed that the single intratumoral administration of Delta-24 to intracranially implanted human glioma xenografts followed by the systemic administration of CPT-11 resulted in significantly prolonged animal survival. The combination of Delta-24 treatment with CPT-11 showed an enhanced anticancer effect, which suggests that the interaction between adenoviral and human proteins can be exploited in rational anticancer therapies comprising replication-competent adenoviruses and conventional chemotherapeutic agents.

Pharmacological blockade of mGlu2/3 metabotropic glutamate receptors reduces cell proliferation in cultured human glioma cells.

Glial cell proliferation in culture is under the control of metabotropic glutamate (mGlu) receptors. We have examined whether this control extends to human glioma cells. Primary cultures were prepared from surgically removed human glioblastomas. RT-PCR combined with western blot analysis showed that most of the cultures (eight out of 11) expressed group-II mGlu receptors. In two selected cultures (MZC-12 and FCN-9), the mGlu2/3 receptor antagonist, LY341495, slowed cell proliferation when applied to the growth medium from the second day after plating. This effect was reversible because linear cell growth was restored after washing out the drug. LY341495 reduced glioma cell proliferation at concentrations lower than 100 nm, which are considered as selective for mGlu2/3 receptors. In addition, its action was mimicked by the putative mGlu2/3 receptor antagonist (2S)-alpha-ethylglutamate. The anti-proliferative effect of LY341495 was confirmed by measuring [methyl-3H]-thymidine incorporation in cultures arrested in G0 phase of the cell cycle and then stimulated to proliferate by the addition of 10% fetal calf serum or 100 ng/mL of epidermal growth factor (EGF). In cultures treated with EGF, LY341495 was also able to reduce the stimulation of the mitogen-activated protein kinase (MAPK) pathway, as well as the induction of cyclin D1. Both effects, as well as decreased [methyl-3H]-thymidine incorporation, were partially reduced by co-addition of the potent mGlu2/3 receptor agonist, LY379268. We conclude that activation of group-II mGlu receptors supports the growth of human glioma cells in culture and that antagonists of these receptors should be tested for their ability to reduce tumour growth in vivo.

Adenovirus-mediated expression of HSV1-TK or Fas ligand induces cell death in primary human glioma-derived cell cultures that are resistant to the chemotherapeutic agent CCNU.

Due to minimal treatment success with surgery, radiotherapy, and chemotherapy, the aim of this study was to test the therapeutic potential of gene therapy for the treatment of glioblastoma multiforme (GBM). We have quantitatively analyzed two gene therapy approaches using short-term human glioma cell cultures derived from surgical biopsies (designated IN859, IN1612, IN2045, IN1760, and IN1265) and compared the results of gene therapy with the chemosensitivity of the same cells. All of the glioma cell cultures tested were susceptible to recombinant adenovirus (RAd)-mediated infection. Expression of herpes simplex virus type 1-thymidine kinase (RAd128), followed by ganciclovir treatment, induced apoptosis in all of the glioma cell cultures studied, including three that are resistant to the chemotherapeutic drug 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea (CCNU). Expression of murine Fas ligand (RAdhCMV-mFasL) also induced cell death in four of the five cell cultures studied. One cell culture that was resistant to CCNU was also resistant to apoptosis induced by mFasL expression. These results suggest that sensitivity to chemotherapeutic agents does not necessarily correlate with the sensitivity to gene therapy treatments. RAds expressing therapeutic gene products in human glioma cell cultures are able to induce apoptosis even in some cells that are resistant to a commonly used chemotherapeutic agent. Therefore, RAd-mediated gene transfer could be a good candidate to further develop gene therapy for the treatment of GBM.

Additive cytotoxic effect of cisplatin and X-irradiation on human glioma cell cultures derived from biopsy-tissue.

Investigation of the in vitro cytotoxic effect of X-rays, either alone or combined with cisplatin on early passage cell cultures derived from human glioblastoma multiforme biopsy tissue. Fresh tumour specimens from four patients were processed to cell cultures. The U373 glioma cell line was used as a reference. Early passage cell cultures were X-irradiated (0-8 Gy) either alone or in combination with cisplatin (0.5-1 microgram/ml). Cell survival was determined by either clonogenic assay or the colorimetric MTT assay. Survival curves were generated and mathematically analysed using the linear quadratic model, to obtain the radiosensitivity parameters alpha, beta, and SF2, i.e., the Surviving Fraction after 2 Gy. Two patient-derived glioma cell cultures and the U373 cell line showed rather high SF2 values of 0.61-0.72 in the clonogenic assay, indicating relative high radiation resistance. Cisplatin alone (1 microgram/ml) reduced cell survival by 10-30% (n = 4). When combined with irradiation, a clear additive cytotoxic effect of cisplatin was demonstrated by the unaltered value of the alpha-parameter for reproductive cell death. Cisplatin exerted an additive rather than radiosensitising cytotoxic effect in uncharacterised patient derived glioma cell cultures.

Activation of the Jak-Stat- and MAPK-pathways by oncostatin M is not sufficient to cause growth inhibition of human glioma cells

We have recently described that oncostatin M (OSM), a member of the IL-6 family of cytokines, induces the differentiation of human glioma cells in culture. In order to extend this studies, we analyzed the effect of OSM on other human glioma cell lines including A172, U343-MG and T98G. All of these cell lines express the receptor components of OSM and leukemia inhibitory factor (LIF) gp130, LIFR and the OSM specific OSMRβ. Therefore, we expected these cell lines to respond to OSM and LIF. Using specific antibodies recognizing proteins of the janus kinase (Jak-)/signal transducers and activator of transcription (Stat-) signaling cascade that has been shown to transduce the signals of the IL-6 cytokines to the nucleus, we could show that Jak1, Jak2 and Tyk2, as well as the Stat proteins Stat1, Stat3 and Stat5b were phosphorylated in all three cell lines by OSM and, at least in part, by LIF. Activation of the Stat proteins was also detected by EMSA which revealed complex formation on the Stat3 DNA-binding element and on a Stat5 binding site. Consistent with our recent findings, OSM treatment also induced the activation of the MAPK erk2 and the tyrosine phosphatase SHP-2 in cells of the A172, T98G and U343-MG cell lines. Although this activation pattern was very close to what we had observed in the GOS3 glioma cells, only T98G showed a growth inhibition in response to OSM while the A172 and the U343-MG cell lines did not respond to OSM treatment in terms of growth inhibition.

Bcl-2 expression in higher-grade human glioma: a clinical and experimental study.

Bcl-2 protein plays an important role in inhibiting apoptosis and protecting normal and neoplastic cells from toxicity. Bcl-2 overexpression in malignant tumors, on the other hand, may cause resistance against adjuvant treatment. Since there are subpopulations of patients with glioma that differ considerably in their treatment benefit, it is important to identify prognostic factors for outcome and to tailor adjuvant protocols in accordance with specific biological features of the respective tumor. The present study aimed at investigating the role of bcl-2 expression in higher-grade glioma (WHO grade III and IV). Bcl-2 expression was correlated with clinical and paraclinical parameters, and evaluated in univariate and multivariate statistical models. In addition, bcl-2-overexpressing human glioma cells in culture were used for modeling the in vivo findings and for investigating the importance of bcl-2 for tumor resistance against cytotoxic treatment. A group of 86 patients with higher-grade glioma were investigated. Anaplastic astrocytoma (AA; WHO G III, n = 29) showed bcl-2 expression in 48% of the cases, and immunohistochemical positivity was associated with a significantly shorter survival time (p = 0.0068). In glioblastoma patients (GBM; WHO G IV, n = 57), 51% of tumors were bcl-2 positive, but bcl-2 expression did not correlate significantly with survival (p = 0.39). In a Cox proportional hazards regression model, bcl-2 positivity was confirmed as a negative prognostic parameter in AA, but not in GBM. Bcl-2 overexpressing and control human glioma cell clones (T98MG line) were treated in culture with the cytotoxic drugs carmustine (BCNU), paclitaxel, vincristine, and doxorubicin. In addition, bcl-2-overexpressing and control cells were infected with a retrovirus carrying the herpes-simplex-virus thymidine kinase gene (HSV-tk), and then treated with ganciclovir (GCV). Bcl-2 overexpression significantly increased tumor cell resistance against all of the above cytotoxic drugs, and also against HSV-TK/GCV mediated gene therapy.

Acetaminophen selectively reduces glioma cell growth and increases radiosensitivity in culture.

Glioblastoma multiforme (GBM) is a highly lethal brain cancer. Using cultures of rodent and human malignant glioma cell lines, we demonstrated that millimolar concentrations of acetylsalicylate, acetaminophen, and ibuprofen all significantly reduce cell numbers after several days of culture. However, their mechanisms of action may vary, as demonstrated by (1) differences in the morphological changes produced by these compounds; (2) varied responses to these drugs with respect to toxicity kinetics; and (3) respective rates of cell proliferation, DNA synthesis, and mitotic index. We studied the effects of acetaminophen on relative cell number further. Evidence is presented that acetaminophen induced cell death by an apoptotic mechanism after a brief burst of mitosis in which cell numbers increased transiently, followed by a reduction in cell number and an increase in DNA fragmentation, as evidenced by terminal deoxytransferase-mediated dUTP-biotin nick end labeling (TUNEL) analysis. Using cultures of adult human brain and embryonic rat brain, we demonstrated that glioma cells were several-fold more sensitive to acetaminophen than normal brain cells in culture. Finally, subtoxic doses of acetaminophen increased the sensitivity of the human glioma cells in culture to ionizing radiation. Taken together, these results suggest that acetaminophen may prove to be a useful therapeutic agent in the treatment of human brain tumors.