Background Mutations of the isocitrate dehydrogenase (IDH) gene occur in over 80% of low-grade gliomas and secondary glioblastomas. Despite considerable efforts, endogenous in vitro IDH-mutated glioma models remain scarce. Availability of these models is key for the development of new therapeutic interventions. Methods Cell cultures were established from fresh tumor material and expanded in serum-free culture media. D-2-Hydroxyglutarate levels were determined by mass-spectrometry. Genomic and transcriptomic profiling were carried out on the Illumina Novaseq platform, methylation profiling was performed with the Infinium MethylationEpic BeadChip array. Mitochondrial respiration was measured with the Seahorse XF24 Analyzer. Drug screens were performed with an NIH FDA-approved anti-cancer drug set and two IDH-mutant specific inhibitors. Results A set of twelve patient-derived IDHmt cell cultures was established. We confirmed high concordance in driver mutations, copy number and methylation profiles between the tumors and derived cultures. Homozygous deletion of CDKN2A/B was observed in all cultures. IDH-mutant cultures had lower mitochondrial reserve capacity. IDH-mutant specific inhibitors did not affect cell viability or global gene expression. Screening of 107 FDA-approved anti-cancer drugs identified nine compounds with potent activity against IDHmt gliomas, including three compounds with favorable pharmacokinetic characteristics for CNS penetration: teniposide, omacetaxine mepesuccinate, and marizomib. Conclusions Our twelve IDH-mutant cell cultures show high similarity to the parental tissues and offer a unique tool to study the biology and drug sensitivities of high-grade IDHmt gliomas in vitro. Our drug screening studies reveal lack of sensitivity to IDHmt inhibitors, but sensitivity to a set of nine available anti-cancer agents.
Glioblastoma (GBM) remains one of the most difficult tumors to treat. The mean overall survival rate of 15 months and the 5-year survival rate of 5% have not significantly changed for almost 2 decades. Despite progress in understanding the pathophysiology of the disease, no new effective treatments to combine with radiation therapy after surgical tumor debulking have become available since the introduction of temozolomide in 1999. One of the main reasons for this is the scarcity of compounds that cross the blood–brain barrier (BBB) and reach the brain tumor tissue in therapeutically effective concentrations. In this review, we focus on the role of the BBB and its importance in developing brain tumor treatments. Moreover, we discuss drug repurposing, a drug discovery approach to identify potential effective candidates with optimal pharmacokinetic profiles for central nervous system (CNS) penetration and that allows rapid implementation in clinical trials. Additionally, we provide an overview of repurposed candidate drug currently being investigated in GBM at the preclinical and clinical levels. Finally, we highlight the importance of phase 0 trials to confirm tumor drug exposure and we discuss emerging drug delivery technologies as an alternative route to maximize therapeutic efficacy of repurposed candidate drug.
Background: Mutations of the isocitrate dehydrogenase (IDH) gene occur in over 80% of low-grade gliomas and secondary glioblastomas. Despite considerable efforts, endogenous in vitro IDH-mutated glioma models remain scarce. Availability of these models is key for the development of new therapeutic interventions. Methods: Cell cultures were established from fresh tumor material and expanded in serum-free culture media. D-2-Hydroxyglutarate levels were determined by mass-spectrometry. Genomic and transcriptomic profiling were carried out on the Illumina Novaseq platform, methylation profiling was performed with the Infinium MethylationEpic BeadChip array. Mitochondrial respiration was measured with the Seahorse XF24 Analyzer. Drug screens were performed with an NIH FDA-approved anti-cancer drug set and two IDH-mutant specific inhibitors. Results: A set of twelve patient-derived IDHmt cell cultures were established. We confirmed high concordance in driver mutations, copy number and methylation profiles between the tumors and derived cultures. Homozygous deletion of CDKN2A/B was observed in all cultures. IDH-mutant cultures had lower mitochondrial reserve capacity. IDH-mutant specific inhibitors did not affect cell viability or global gene expression. Screening of 107 FDA-approved anti-cancer drugs identified nine compounds with potent activity against IDHmt gliomas, including three compounds with favorable pharmacokinetic characteristics for CNS penetration: teniposide, omacetaxine mepesuccinate, and marizomib. Conclusions: Our twelve IDH-mutant cell cultures show high similarity to the parental tissues and offer a unique tool to study the biology and drug sensitivities of high-grade IDHmt gliomas in vitro. Our drug screening studies reveal lack of sensitivity to IDHmt inhibitors, but sensitivity to a set of nine available anti-cancer agents.
BACKGROUND The development of new therapeutic agents generally takes many years to translate to clinically-effective new treatments. Among the strategies to reduce this time frame, efforts are now being undertaken to investigate drug repurposing. With this approach, compounds available for a specific disease are evaluated for their therapeutic efficacy in other diseases. We have set up a patient-derived cell culture model to apply this strategy for glioblastoma (GBM). MATERIAL AND METHODS Fresh patient-derived tumour tissue was dissociated and cultured in serum-free medium supplemented with EGF and bFGF. MGMT status was determined by methylation-specific PCR.Drug screening was performed using the NIH anti-cancer collection containing 114 approved oncology drugs. Compounds include chemotherapeutic agents as well as small molecule targeted agents. Readout for drug effects is based on ATP-based viability assay. Using systems modelling approaches, integrated analysis of both mutational and expression data of each tumour is applied to identify key pathways involved in response to specific compounds. RESULTS Molecular analysis demonstrated that copy number variations are preserved under serum-free culture conditions and that the MGMT methylation status is retained in over 75% of cases. Screening of the NIH anti-cancer collection on 55 GBM cell cultures revealed high intertumoral variation in response to most drugs. This included subsets of GBM revealing exceptionally high sensitivity to specific agents at clinically-feasible concentrations. Further ranking of the compounds was made based on the therapeutic index (IC50 tumour versus normal human astrocytes) and predicted blood-brain-barrier crossing capability. Currently, integrated analysis of molecular profiles of the tumour in relation to the drug response data is ongoing with the aim of identifying response predictors to these clinically-approved anti-cancer agents. CONCLUSION Our patient-derived in vitro drug screening assay may offer a tool to identify available anti-cancer agents that are effective in a subpopulation of GBM patients and that may be implemented in future stratified clinical trials for this patient group.
BACKGROUND Major obstacles that have impeded the development of effective new therapies for GBM include inter- and intratumoral heterogeneity, the blood-brain-barrier and use of sub-optimal cell line-based preclinical models. Taking these hurdles into account, we have set up a patient-derived GBM drug-screening platform. We optimized protocols to improve cell culture success rate and retrospectively assessed the predictive power of our assay for patient response to TMZ. A large panel of GBM cells was screened for sensitivity to available oncological agents. Drugs of interest were selected based on favorable physicochemical properties for BBB crossing and potent activity in (a subset of) GBM cultures. Finally, we determined the success rate of performing a small-scale screen with 20 selected agents within 4 weeks of receiving tumor tissue. RESULTS By combining both CUSA and tissue piece-derived dissociation protocols, culture success increased to 95%, ensuring representation of the near-complete spectrum of GBM subtypes. Single-cell sequencing studies confirmed heterogeneity in our low-passage cell cultures. In vitro screening of TMZ on a large cohort (n = 55) identified 3 response categories (responders/intermediates/non-responders) for which Cox regression analysis revealed significantly different overall survival curves of corresponding patients. Screening of 107 FDA-approved anticancer agents on 45 GBM cultures underscored the tremendous intertumoral heterogeneity in drug sensitivities. We identified 20 potent agents each effective at clinically-achievable concentrations in (a subset of) GBM cultures and having favorable BBB penetration properties (CNS-MPO score). Screening of these agents on a per patient basis within 4 weeks of receiving tissue was successful in 18 out of 24 (75%) tested tumors. In the remaining cases the tumor cells grew very slowly and longer culture times were required. CONCLUSION Our drug screening platform offers a tool to predict TMZ response and assess sensitivity to candidate treatments, either for GBM subsets or on a per patient basis.
INTRODUCTION Little progress has been made in the development of effective new therapies for glioblastoma (GBM) the past decades. Fresh patient-derived GBM cell culture models have become the gold standard for GBM drug discovery and development. One of the major obstacles in identifying novel candidate drugs against GBM remains the blood-brain barrier (BBB). Therefore, it is crucial to select drugs with favourable physicochemical properties to cross BBB and reach the tumour tissue in therapeutically effective concentrations. In current drug repurposing approach, we evaluated available anti-cancer agents in our patient-derived drug screening platform against GBM. METHODS The FDA-approved Oncology Drug Set II library was tested on 45 primary GBM cell cultures. We developed a drug shortlisting pipeline combining efficacy data with pharmacodynamic and pharmacokinetic characteristics of each compound. The therapeutic efficacy of the selected agent was assessed in an orthotopic mouse PDX model, while penetration into the CNS by LC/MS/MS. RESULTS Omacetaxine mepesuccinate (OMA) was ranked as one of the most promising candidates applying our drug selection approach. In vitro, OMA revealed anti-tumour activity at IC50 values well-below reported Cmax plasma values in approximately 80% of GBM cultures. NanoString nCounter analysis, revealed DNA damage repair as the main pathway involved in OMA’s anti-tumour effect. Activation of caspase 3/7 activity and decrease of glioma cell invasiveness were also linked to its anti-tumour effect. In vivo, 1mg/kg dose of OMA was found to reach the brain tumour tissue in concentrations similar to the reported IC50 values in vitro. No adverse reactions were noted and a survival benefit was observed in a proportion of the treated mice. CONCLUSIONS At 1 mg/kg, OMA reaches the tumour brain tissue in therapeutically effective concentrations in mice while a moderate therapeutic benefit was observed. Additional in vivo experiments are ongoing investigating higher dosages of OMA and longer exposure.
INTRODUCTION The search for effective therapies for gliomas is progressively moving towards patient-specific medicine. In order to test patient-tailored therapies, it is vital to develop protocols for reliable establishment of patient-derived glioma cultures. We present a method for reliable culture establishment, with a 95% success rate in 114 consecutive high-grade samples. METHODS Cell cultures were established from either traditionally-resected tumor tissue or ultrasonic surgical aspirator (CUSA) derived tissue fragments, and expanded in serum-free culture, with selection of astrocytic populations if required. Cultures were started from single cells or small tumor fragments of 0.5-3mm (3D). Whole exome and RNA sequencing were carried out with the Illumina Novaseq and HiSeq platforms. Methylation profiling was performed with the Infinium MethylationEPIC array. Cultures and tumors were compared through analysis of single nucleotide polymorphisms and copy number profiles with the Infinium Global Screening Array. Intra-tumoral heterogeneity in cultures was investigated with single-cell transcriptomic sequencing (SORT-seq). We studied tumor-initiating potential by orthotopic injection of cultures in NOD-SCID mice. RESULTS Cultures started from single cells were established from CUSA material more efficiently (92%) than from traditional resection material (70%). 3D-derived cultures had a higher overall efficiency (95% for CUSA, 85% for traditional resection material). We confirmed high concordance in driver mutations, copy number and methylation profiles between tumors and derived cultures. Transcriptomics analysis, comparing tumors and derived cultures, revealed high consistency in gene expression distribution as demonstrated by correlation analysis (r=0.88). Singe-cell RNA-seq shows increased heterogeneity in CUSA derived-cultures, and decreased heterogeneity with passaging over time. Cultures faithfully produce tumors after orthotopic injection in NOD-SCID mice. CONCLUSION We present a highly successful method for the establishment of glioma cultures from patient material, with CUSA-derived cultures revealing greater heterogeneity. Cultures faithfully represent important molecular characteristics of parental tumors and can be used to test potential therapies in vitro.
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