Lisa Storer

Pediatric brain tumor cancer stem cells: cell cycle dynamics, DNA repair, and etoposide extrusion

Reliable model systems are needed to elucidate the role cancer stem cells (CSCs) play in pediatric brain tumor drug resistance. The majority of studies to date have focused on clinically distinct adult tumors and restricted tumor types. Here, the CSC component of 7 newly established primary pediatric cell lines (2 ependymomas, 2 medulloblastomas, 2 gliomas, and a CNS primitive neuroectodermal tumor) was thoroughly characterized. Comparison of DNA copy number with the original corresponding tumor demonstrated that genomic changes present in the original tumor, typical of that particular tumor type, were retained in culture. In each case, the CSC component was approximately 3–4-fold enriched in neurosphere culture compared with monolayer culture, and a higher capacity for multilineage differentiation was observed for neurosphere-derived cells. DNA content profiles of neurosphere-derived cells expressing the CSC marker nestin demonstrated the presence of cells in all phases of the cell cycle, indicating that not all CSCs are quiescent. Furthermore, neurosphere-derived cells demonstrated an increased resistance to etoposide compared with monolayer-derived cells, having lower initial DNA damage, potentially due to a combination of increased drug extrusion by ATP-binding cassette multidrug transporters and enhanced rates of DNA repair. Finally, orthotopic xenograft models reflecting the tumor of origin were established from these cell lines. In summary, these cell lines and the approach taken provide a robust model system that can be used to develop our understanding of the biology of CSCs in pediatric brain tumors and other cancer types and to preclinically test therapeutic agents.

Overcoming multiple drug resistance mechanisms in medulloblastoma

IntroductionMedulloblastoma (MB) is the most common malignant paediatric brain tumour. Recurrence and progression of disease occurs in 15-20% of standard risk and 30-40% of high risk patients. We analysed whether circumvention of chemoresistance pathways (drug export, DNA repair and apoptotic inhibition) can restore chemotherapeutic efficacy in a panel of MB cell lines.ResultsWe demonstrate, by immunohistochemistry in patient tissue microarrays, that ABCB1 is expressed in 43% of tumours and is significantly associated with high-risk. We show that ABCB1, O6-methylguanine-DNA-methyltransferase (MGMT) and BCL2 family members are differentially expressed (by quantitative reverse transcription polymerase chain reaction, Western blotting and flow cytometry) in MB cell lines. Based on these findings, each pathway was then inhibited or circumvented and cell survival assessed using clonogenic assays. Inhibition of ABCB1 using vardenafil or verapamil resulted in a significant increase in sensitivity to etoposide in ABCB1-expressing MB cell lines. Sensitivity to temozolomide (TMZ) was MGMT-dependent, but two novel imidazotetrazine derivatives (N-3 sulfoxide and N-3 propargyl TMZ analogues) demonstrated ≥7 fold and ≥3 fold more potent cytotoxicity respectively compared to TMZ in MGMT-expressing MB cell lines. Activity of the BAD mimetic ABT-737 was BCL2A1 and ABCB1 dependent, whereas the pan-BCL2 inhibitor obatoclax was effective as a single cytotoxic agent irrespective of MCL1, BCL2, BCL2A1, or ABCB1 expression.ConclusionsABCB1 is associated with high-risk MB; hence, inhibition of ABCB1 by vardenafil may represent a valid approach in these patients. Imidazotetrazine analogues of TMZ and the BH3 mimetic obatoclax are promising clinical candidates in drug resistant MB tumours expressing MGMT and BCL2 anti-apoptotic members respectively.

Histologically-defined central nervous system primitive neuro-ectodermal tumours (CNS-PNETs) display heterogeneous DNA methylation profiles and show relationships to other paediatric brain tumour types

To the editors: Central nervous system primitive neuro-ectodermal tumours (CNS-PNETs) are a group of rare childhood embryonal brain tumours associated with a poor prognosis (approximately 50% overall survival) and defined by a common histology according to the current consensus World Health Organisation (WHO) classification [7]. CNS-PNETs occur supratentorially and are defined by histological features shared with cerebellar PNETs (termed medulloblastomas), however the histological classification of CNS-PNET can be challenging. Individual CNS-PNETs are often reclassified as other paediatric supratentorial tumour groups, including anaplastic astrocytoma, atypical teratoid rhabdoid tumour (ATRT), anaplastic oligodendroglioma and anaplastic ependymoma, following central immunophenotypic and histological review [3, 12]. Initial studies have shown that substantial molecular heterogeneity exists within CNS-PNETs; molecular features characteristic of other cerebral brain tumour types (e.g. IDH1 mutation, CDKN2A deletion) have been detected in subsets, but unifying genomic defects have not yet been reported [4, 8, 10, 11]. The recent definition of embryonal tumours with abundant neuropil and true rosettes (ETANTR) as a discrete tumour entity occurring in very young children within the CNS-PNET group - characterised by focal amplification of 19q13.42 and dismal outcome [5, 6, 9] - suggests the existence of currently unrecognised molecular pathological variants, and a refined understanding of CNS-PNET biology could lead to their improved subclassification and the subsequent development of directed therapies. We and others have recently demonstrated the utility of DNA methylation profiling for the discovery and distinction of clinical and molecular sub-classes of brain tumour types including medulloblastomas, gliomas and ependymomas [13-15]. To investigate the potential of DNA methylation profiles to enhance the molecular classification of CNS-PNETs, we assessed 1505 CpG residues across 807 genes in a series of 29 archival CNS-PNETs using established methods [14], alongside assessment of clinical and molecular characteristics (Figure 1h). All biopsies underwent central neuropathological review according to WHO criteria [7] by a three pathologist panel (TSJ, KR and JL). Tumours representing ETANTRs, CNS-PNETs with significant glial (GFAP) or neuronal (synaptophysin) differentiation, and SMARCB1/INI1-negative tumours (by immunohistochemistry (IHC)), were excluded and not assessed, thus defining a study population of morphologically homogeneous CNS-PNETs for analysis (Figure 1a). Finally, DNA methylation profiles from 136 further paediatric brain tumours were generated contemporaneously and assessed in comparison. These included medulloblastomas of defined molecular subgroup (n=60; 15 representative examples each from the WNT (MBWNT), SHH (MBSHH), Group 3 (MBGroup3) and Group 4 (MBGroup4) [14]), alongside ependymomas (n=61; 45 posterior fossa (16 anaplastic, 29 classic; median age at diagnosis, 2.8 years), 16 supratentorial (9 anaplastic, 7 classic; median age, 6.9 years)) and cerebral high-grade gliomas (pHGG; n=15; 12 glioblastoma multiforme, 3 anaplastic astrocytoma; median age 7.1 years) with histology confirmed by central histological review (by WHO criteria [7]). Figure 1 Consensus clustering of CNS-PNETs with other molecularly and histologically-defined paediatric brain tumours does not identify a discrete CNS-PNET tumour subgroup We first undertook unsupervised clustering of the CNS-PNET tumour group based on their DNA methylation patterns using non-negative matrix factorisation (NMF [2, 14]). Three sub-groups produced the most consistent consensus clustering; the majority of tumours clustered confidently into a single large group (21/29), while the two smaller remaining groups (n≤5) were less well defined (Figure 1b). Next, we sought to compare the DNA methylation patterns observed for CNS-PNETs with those of the seven other paediatric brain tumour groups with available data. Prior to the addition of CNS-PNETs into our analysis, these tumours formed seven groups as expected (Figure 1c,d,f), representing discrete confidently-defined (average silhouette width, 0.82) groups of MBWNT, MBSHH, MBGroup3 and MBGroup4, posterior-fossa ependymomas and pHGG tumours, and a mixed tumour group containing all (n=16) supratentorial ependymomas alongside some posterior fossa ependymomas (n=9) and pHGGs (n=3). Whilst the inclusion of CNS-PNETs in the analysis yielded 8 optimal clusters (Figure 1c,e,f), the overall quality of these clusters was reduced (average silhouette width, 0.69) and CNS-PNETs did not form a single discrete group; indeed, CNS-PNETs clustered into six of the different tumour groups observed (Figure 1e,f), showing closer similarities to the other clinically and molecularly-defined paediatric brain tumour groups investigated than to each other. Finally, we made an initial assessment of relationships between the clustered CNS-PNETs and other clinical and molecular disease features (Figure 1g,h). Although numbers were limited, TP53 nuclear stabilisation was common and detected in most clusters, while TP53 mutation and MYCN amplification were rare. Most notably, both IDH1 mutations were exclusively detected in pHGG-like CNS-PNETs arising in adults [4], although no pHGG-characteristic HIST1H3B or H3F3A hotspot mutations were observed [15]. The single WNT pathway-activating CTNNB1 mutation was detected in a MBWNT-like CNS-PNET tumour. No relationships to clinical or pathological disease features were observed in this cohort (Figure 1h). In summary, our data show that despite a defining histological homogeneity using current diagnostic criteria, CNS-PNETs display highly heterogeneous DNA methylation patterns which are more commonly related to other paediatric brain tumour types than to each other. These initial findings raise important issues in the classification of CNS-PNETs and indicate their current clinical definition and grouping by common ‘PNET’ histology [7], and treatment using uniform therapeutic approaches, does not adequately address their underlying biological and clinical complexity. Moreover, our data suggest the potential of refined molecular sub-classification for the improved diagnosis and discrimination of CNS-PNET molecular variants, and to support molecularly-directed clinical trials across tumour types defined currently by clinical and pathological criteria. Despite the modest resolution of our platform, robust discrimination of recognised non-CNS-PNET tumour groups was achieved, both supporting these conclusions and highlighting the potential benefits of higher-resolution molecular investigations in expanded cohorts to validate and extend our findings. The variable DNA methylation patterns observed in CNS-PNETs are likely to represent complex factors, including cellular and developmental origins and ‘driver’ events in tumourigenesis [1]. The collection of snap-frozen tumour cohorts will now be essential to support comprehensive integrated genomic/epigenomic investigations, and comparison with transcriptomic features [11], which were not tractable in our current archival cohort. Finally, understanding the biological significance of epigenetic events in CNS-PNET and related tumour types could lead to the development of novel and/or targeted approaches for the improved therapy of these tumours.

Tumour compartment transcriptomics demonstrates the activation of inflammatory and odontogenic programmes in human adamantinomatous craniopharyngioma and identifies the MAPK/ERK pathway as a novel therapeutic target

Adamantinomatous craniopharyngiomas (ACPs) are clinically challenging tumours, the majority of which have activating mutations in CTNNB1. They are histologically complex, showing cystic and solid components, the latter comprised of different morphological cell types (e.g. β-catenin-accumulating cluster cells and palisading epithelium), surrounded by a florid glial reaction with immune cells. Here, we have carried out RNA sequencing on 18 ACP samples and integrated these data with an existing ACP transcriptomic dataset. No studies so far have examined the patterns of gene expression within the different cellular compartments of the tumour. To achieve this goal, we have combined laser capture microdissection with computational analyses to reveal groups of genes that are associated with either epithelial tumour cells (clusters and palisading epithelium), glial tissue or immune infiltrate. We use these human ACP molecular signatures and RNA-Seq data from two ACP mouse models to reveal that cell clusters are molecularly analogous to the enamel knot, a critical signalling centre controlling normal tooth morphogenesis. Supporting this finding, we show that human cluster cells express high levels of several members of the FGF, TGFB and BMP families of secreted factors, which signal to neighbouring cells as evidenced by immunostaining against the phosphorylated proteins pERK1/2, pSMAD3 and pSMAD1/5/9 in both human and mouse ACP. We reveal that inhibiting the MAPK/ERK pathway with trametinib, a clinically approved MEK inhibitor, results in reduced proliferation and increased apoptosis in explant cultures of human and mouse ACP. Finally, we analyse a prominent molecular signature in the glial reactive tissue to characterise the inflammatory microenvironment and uncover the activation of inflammasomes in human ACP. We validate these results by immunostaining against immune cell markers, cytokine ELISA and proteome analysis in both solid tumour and cystic fluid from ACP patients. Our data support a new molecular paradigm for understanding ACP tumorigenesis as an aberrant mimic of natural tooth development and opens new therapeutic opportunities by revealing the activation of the MAPK/ERK and inflammasome pathways in human ACP.

Evaluation of a novel antibody to define histone 3.3 G34R mutant brain tumours

Missense somatic mutations affecting histone H3.1 and H3.3 proteins are now accepted as the hallmark of paediatric diffuse intrinsic pontine gliomas (DIPG), non-brain stem paediatric high grade gliomas (pHGG) as well as a subset of adult glioblastoma multiforme (GBM). Different mutations give rise to one of three amino acid substitutions at two critical positions within the histone tails, K27M, G34R/V. Several studies have highlighted gene expression and epigenetic changes associated with histone H3 mutations; however their precise roles in tumourigenesis remain incompletely understood. Determining how such amino acid substitutions in a protein affect its properties can be challenging because of difficulties in detecting and tracking mutant proteins within cells and tissues. Here we describe a strategy for the generation of antibodies to discriminate G34R and G34V mutant histone H3 proteins from their wild-type counterparts. Antibodies were validated by western blotting and immunocytochemistry, using recombinant H3.3 proteins and paediatric GBM cell lines. The H3-G34R antibody demonstrated a high degree of selectivity towards its target sequence. Accordingly, immunostaining on a cohort of 22 formalin-fixed paraffin embedded tumours with a previously known H3.3 G34R mutation status, detected successfully the corresponding mutant protein in 11/11 G34R cases. Since there was a high concordance between genotype and immunohistochemical analysis of G34R mutant tumour samples, we analysed a series of tissue microarrays (TMAs) to assess the specificity of the antibody in a range of paediatric brain tumours, and noted immunoreactivity in 2/634 cases. Importantly, we describe the generation and validation of highly specific antibodies for G34 mutations. Overall our work adds to an extremely valuable portfolio of antibodies, not only for histopathologic detection of tumour-associated mutant histone sequences, but also facilitating the study of spatial/anatomical aspects of tumour formation and the identification of downstream targets and pathways in malignant glioma progression.

Tissue metabolite profiles for the characterisation of paediatric cerebellar tumours

Paediatric brain tumors are becoming well characterized due to large genomic and epigenomic studies. Metabolomics is a powerful analytical approach aiding in the characterization of tumors. This study shows that common cerebellar tumors have metabolite profiles sufficiently different to build accurate, robust diagnostic classifiers, and that the metabolite profiles can be used to assess differences in metabolism between the tumors. Tissue metabolite profiles were obtained from cerebellar ependymoma (n = 18), medulloblastoma (n = 36), pilocytic astrocytoma (n = 24) and atypical teratoid/rhabdoid tumors (n = 5) samples using HR-MAS. Quantified metabolites accurately discriminated the tumors; classification accuracies were 94% for ependymoma and medulloblastoma and 92% for pilocytic astrocytoma. Using current intraoperative examination the diagnostic accuracy was 72% for ependymoma, 90% for medulloblastoma and 89% for pilocytic astrocytoma. Elevated myo-inositol was characteristic of ependymoma whilst high taurine, phosphocholine and glycine distinguished medulloblastoma. Glutamine, hypotaurine and N-acetylaspartate (NAA) were increased in pilocytic astrocytoma. High lipids, phosphocholine and glutathione were important for separating ATRTs from medulloblastomas. This study demonstrates the ability of metabolic profiling by HR-MAS on small biopsy tissue samples to characterize these tumors. Analysis of tissue metabolite profiles has advantages in terms of minimal tissue pre-processing, short data acquisition time giving the potential to be used as part of a rapid diagnostic work-up.

Transcriptomic analysis in pediatric spinal ependymoma reveals distinct molecular signatures

Pediatric spinal ependymomas (SEPN) are important albeit uncommon malignant central nervous system tumors with limited treatment options. Our current knowledge about the underlying biology of these tumors is limited due to their rarity. To begin to elucidate molecular mechanisms that give rise to pediatric SEPN, we compared the transcriptomic landscape of SEPNs to that of intracranial ependymomas using genome-wide mRNA and microRNA (miRNA) expression profiling in primary tumour samples. We found that pediatric SEPNs are characterized by increased expression of genes involved in developmental processes, oxidative phosphorylation, cellular respiration, electron transport chain, and cofactor metabolic process. Next, we compared pediatric spinal and intracranial ependymomas with the same tumours in adults and found a relatively low number of genes in pediatric tumours that were shared with adult tumours (12.5%). In contrast to adult SEPN, down-regulated genes in pediatric SEPN were not enriched for position on chromosome 22. At the miRNA level, we found ten miRNAs that were perturbed in pediatric SEPN and we identified regulatory relationships between these miRNAs and their putative targets mRNAs using the integrative miRNA-mRNA network and predicted miRNA target analysis. These miRNAs include the oncomiR hsa-miR-10b and its family member hsa-miR-10a, both of which are upregulated and target chromatin modification genes that are down regulated in pediatric SEPN. The tumor suppressor, hsa-miR-124, was down regulated in pediatric SEPN and it normally represses genes involved in cell-cell communication and metabolic processes. Together, our findings suggest that pediatric SEPN is characterized by a distinct transcriptional landscape from that of pediatric intracranial EPNs or adult tumors (both SEPNs and intracranial EPNs). Although confirmatory studies are needed, our study reveals novel molecular pathways that may drive tumorigenesis and could serve as biomarkers or rational therapeutic targets.

Long-term exposure to irinotecan reduces cell migration in glioma cells

In spite of considerable research into the therapies for glioblastoma multiforme this tumour type remains very difficult to treat. As well as having a tendency to be inherently resistant to chemotherapy, glioblastoma multiforme also displays local invasion. Cell line studies have a continued and important role to play in understanding the mechanisms associated with both chemotherapy resistance and invasion. In the current study we have utilized the C6 glioma cell line to investigate the response to long-term, clinically relevant application of topoisomerase I and II inhibitors. Treatment with etoposide resulted in an increase in resistance to this topoisomerase II inhibitor. By contrast, the continuous exposure to a topoisomerase I inhibitor did not result in increased drug resistance, but was associated with a reduction in cell migration. This data supports further investigation of topoisomerase I inhibition as a means to inhibit glioma invasion without the development of parallel chemoresistance.

OP20DRUGGABLE PROGNOSTIC MARKERS IN PAEDIATRIC EPENDYMOMA; IS BLBP THE SOLUTION?

INTRODUCTION: Paediatric ependymomas are aggressive treatment resistant tumours with a tendency to relapse. This behaviour is consistent with an underlying sub-population of therapy resistant cancer stem cells. Blbp (brain lipid binding protein) is a marker for radial glial cells, the proposed stem cells of origin in ependymoma. PPARs (peroxisome proliferator activated receptors) are transcription factors; two of which (γ and δ) play a key role in modulating the transcriptional activity of Blbp. METHOD: Blbp immunohistochemistry (IHC) staining was performed on patient samples obtained from two trial cohorts; a chemotherapy-led infant trial (CNS 9204) and a radiotherapy-led trial (CNS 9904). Blbp expression in cell lines and stem cell enriched neurospheres was performed using RT-PCR. Viability assays were carried out to assess proliferation and potentiation of response to chemotherapy in 2D & 3D cultures. Cell migration and invasion were assessed by scratch assays and 3-D migration assays respectively. RESULTS: Blbp expression correlated with reduced overall survival (OS) in both trials (CNS9204- 5yr OS 45% vs 80%, P = 0.011 and CNS9904- 5yr OS 38% vs 85%, P = 0.002). 5/5 ependymoma cell lines expressed Blbp which was elevated in stem cell enriched neurospheres. Treatment with three PPAR antagonists diminished Blbp expression and proliferation in 2D and 3D cultures. Cell migration and invasion were also diminished. CONCLUSION: These findings constitute the first conclusive evidence that Blbp is an independent predictor of poor survival in paediatric ependymomas. In addition, treatment with PPAR antagonists may represent an effective novel therapy to prevent invasion in paediatric ependymoma patients.