MTSS1 is epigenetically regulated in glioma cells and inhibits glioma cell motility.

Epigenetic silencing by DNA methylation in brain tumors has been reported for many genes, however, their function on pathogenesis needs to be evaluated. We investigated the MTSS1 gene, identified as hypermethylated by differential methylation hybridization (DMH). Fifty-nine glioma tissue samples and seven glioma cell lines were examined for hypermethylation of the MTSS1 promotor, MTSS1 expression levels and gene dosage. GBM cell lines were treated with demethylating agents and interrogated for functional consequences of MTSS1 expression after transient transfection. Hypermethylation was significantly associated with IDH1/2 mutation. Comparative SNP analysis indicates higher incidence of loss of heterozygosity of MTSS1 in anaplastic astrocytomas and secondary glioblastomas as well as hypermethylation of the remaining allele. Reversal of promoter hypermethylation results in an increased MTSS1 expression. Cell motility was significantly inhibited by MTSS1 overexpression without influencing cell growth or apoptosis. Immunofluorescence analysis of MTSS1 in human astrocytes indicates co-localization with actin filaments. MTSS1 is down-regulated by DNA methylation in glioblastoma cell lines and is part of the G-CIMP phenotype in primary glioma tissues. Our data on normal astrocytes suggest a function of MTSS1 at focal contact structures with an impact on migratory capacity but no influence on apoptosis or cellular proliferation.

Genetic Analysis of Diffuse High-Grade Astrocytomas in Infancy Defines a Novel Molecular Entity.

Pediatric high-grade gliomas are considered to be different when compared to adult high-grade gliomas in their pathogenesis and biological behavior. Recently, common genetic alterations, including mutations in the H3F3A/ATRX/DAXX pathway, have been described in approximately 30% of the pediatric cases. However, only few cases of infant high-grade gliomas have been analyzed so far. We investigated the molecular features of 35 infants with diffuse high-grade astrocytomas, including 8 anaplastic astrocytomas [World Health Organization (WHO) grade III] and 27 glioblastomas (WHO grade IV) by immunohistochemistry, multiplex ligation probe-dependent amplification (MLPA), pyrosequencing of glioma-associated genes and molecular inversion probe (MIP) assay. MIP and MLPA analyses showed that chromosomal alterations are significantly less frequent in infants compared with high-grade gliomas in older children and adults. We only identified H3F3A K27M in 2 of 34 cases (5.9%), with both tumors located in the posterior fossa. PDGFRA amplifications were absent, and CDKN2A loss could be observed only in two cases. Conversely, 1q gain (22.7%) and 6q loss (18.2%) were identified in a subgroup of tumors. Loss of SNORD located on chromosome 14q32 was observed in 27.3% of the infant tumors, a focal copy number change not previously described in gliomas. Our findings indicate that infant high-grade gliomas appear to represent a distinct genetic entity suggesting a different pathogenesis and biological behavior.

FGFR1 mutations in Rosette-forming glioneuronal tumors of the fourth ventricle.

Rosette-forming glioneuronal tumors (RGNTs) are rare glioneuronal tumors of the fourth ventricle region that preferentially affect young adults. Despite their histologic similarity with pilocytic astrocytomas (PAs), RGNTs do not harbor KIAA1549-BRAF fusions or BRAF mutations, which represent the most common genetic alteration in PAs. Recently, mutations affecting the hotspot codons Asn546 and Lys656 of fibroblast growth factor receptor 1 (FGFR1) have been described in PAs. They are considered to be the most frequent mechanism of mitogen-activated protein kinase activation, alternative to KIAA1549-BRAF fusion and BRAF mutations. To uncover possible molecular similarities between RGNTs and PAs, we performed a mutational study of FGFR1 in 8 RGNTs. An FGFR1 N546K mutation and an FGFR1 K656E mutation were found in the tumors of 2 patients. Notably, the patient with an FGFR1 K656E mutated RGNT had undergone a resection of a diencephalic pilocytic astrocytoma with pilomyxoid features 5 years before the discovery of the fourth ventricle tumor; the mutational analysis uncovered the presence of the same FGFR1 K656E mutation in the diencephalic tumor. These results indicate that, in addition to histologic similarities, at least a subgroup of RGNTs may show close molecular relationships with PAs. Whether FGFR1 mutated RGNTs represent a specific subset of this rare tumor entity remains to be determined.

Genome-wide DNA copy number analysis of desmoplastic infantile astrocytomas and desmoplastic infantile gangliogliomas.

Little is known about the molecular features of desmoplastic infantile ganglioglioma (DIG) and desmoplastic infantile astrocytoma (DIA). We performed a genome-wide DNA copy number analysis in combination with a multiplex ligation-dependent probe amplification-based analysis of copy number changes of candidate genes in 4 DIAs and 10 DIGs. Molecular inversion probe (MIP) assay showed that large chromosomal alterations were rare among DIG and DIA. Focal recurrent genomic losses were observed in chromosome regions such as 5q13.3, 21q22.11, and 10q21.3 in both DIA and DIG. Principal component analysis did not show any significant differences between the molecular profiles of DIG and DIA, and a hierarchical cluster analysis did not clearly separate the 2 tumor groups according to their molecular profiles. In 6 cases, gain of genomic material at 7q31 (corresponding to MET gene) was found in multiplex ligation-dependent probe amplification (MLPA) analysis. Furthermore, two cases showed gain at 4q12, and a single case showed BRAF mutation. In agreement with previous analyses, this study demonstrates the absence of consistent recurrent chromosomal alterations in DIA and DIG and overall rarity of the BRAF mutation in these tumors. Notably, these results suggest that DIA and DIG represent a histologic spectrum of the same tumor rather than 2 separate entities.

H3F3A K27M mutation in pediatric CNS tumors: a marker for diffuse high-grade astrocytomas.

Brain tumors are one of the most common childhood malignancies. Diffuse high-grade gliomas represent approximately 10% of pediatric brain tumors. Exon sequencing has identified a mutation in K27M of the histone H3.3 gene (H3F3A K27M and G34R/V) in about 20% of pediatric glioblastomas, but it remains to be seen whether these mutations can be considered specific for pediatric diffuse high-grade astrocytomas or also occur in other pediatric brain tumors. We performed a pyrosequencing-based analysis for the identification of H3F3A codon 27 and codon 34 mutations in 338 pediatric brain tumors. The K27M mutation occurred in 35 of 129 glioblastomas (27.1%) and in 5 of 28 (17.9%) anaplastic astrocytomas. None of the other tumor entities showed H3F3A K27M mutation. Because H3F3A K27M mutations occur exclusively in pediatric diffuse high-grade astrocytomas, analysis of codon 27 mutational status could be useful in the differential diagnosis of these neoplasms.

H3.3 G34R mutations in pediatric primitive neuroectodermal tumors of central nervous system (CNS-PNET) and pediatric glioblastomas: possible diagnostic and therapeutic implications?

Pediatric glioblastomas recently have been exon sequenced with evidence that approximately 30 % of cases harbour mutations of the histone H3.3 gene. Although studies to determinate their role in risk stratification are on-going, it remains to be determined whether H3.3 mutations could be found in other tumors such as pediatric primitive neuroectodermal tumors of the central nervous system (CNS-PNETs) and whether the presence of H3.3 mutations in glioblastomas could be used as diagnostic tool in their differential diagnosis with CNS-PNETs. We performed a large mutational pyrosequencing-based screening on 123 pediatric glioblastomas and 33 CNS-PNET. The analysis revealed that 39/123 (31.7 %) glioblastomas carry H3.3 mutations. The K27M (AAG → ATG, lysine → methionine) mutation was found in 33 glioblastomas (26 %); the G34R (GGG → AGG, glycine → arginine) was observed in 6 glioblastomas (5.5 %). However, we also identified 4 of 33 cases (11 %) of CNS-PNETs harbouring a H3.3 G34R mutation. Multiplex ligation-dependent probe amplification analysis revealed PDGFR-alpha amplification and EGFR gain in two cases and N-Myc amplification in one case of H3.3 G34R mutated CNS-PNET. None of H3.3 mutated tumors presented a CDKN2A loss. In conclusion, because pediatric patients with glioblastoma and CNS-PNET are treated according to different therapeutic protocols, these findings may raise further concerns about the reliability of the histological diagnosis in the case of an undifferentiated brain tumor harbouring G34R H3.3 mutation. In this view, additional studies are needed to determine whether H3.3 G34 mutated CNS-PNET/glioblastomas may represent a defined tumor subtype.

RANK (TNFRSF11A) is epigenetically inactivated and induces apoptosis in gliomas.

Alterations of DNA methylation play an important role in gliomas. In a genome-wide screen, we identified a CpG-rich fragment within the 5' region of the tumor necrosis factor receptor superfamily, member 11A gene (TNFRSF11A) that showed de novo methylation in gliomas. TNFRSF11A, also known as receptor activator of NF-κB (RANK), activates several signaling pathways, such as NF-κB, JNK, ERK, p38α, and Akt/PKB. Using pyrosequencing, we detected RANK/TNFRSF11A promoter methylation in 8 (57.1%) of 14 diffuse astrocytomas, 17 (77.3%) of 22 anaplastic astrocytomas, 101 (84.2%) of 120 glioblastomas, 6 (100%) of 6 glioma cell lines, and 7 (100%) of 7 glioma stem cell-enriched glioblastoma primary cultures but not in four normal white matter tissue samples. Treatment of glioma cell lines with the demethylating agent 5-aza-2'-deoxycytidine significantly reduced the methylation level and resulted in increased RANK/TNFRSF11A mRNA expression. Overexpression of RANK/TNFRSF11A in glioblastoma cell lines leads to a significant reduction in focus formation and elevated apoptotic activity after flow cytometric analysis. Reporter assay studies of transfected glioma cells supported these results by showing the activation of signaling pathways associated with regulation of apoptosis. We conclude that RANK/TNFRSF11A is a novel and frequent target for de novo methylation in gliomas, which affects apoptotic activity and focus formation thereby contributing to the molecular pathogenesis of gliomas.

Nuclear exclusion of TET1 is associated with loss of 5-hydroxymethylcytosine in IDH1 wild-type gliomas.

The recent identification of isocitrate dehydrogenase 1 (IDH1) gene mutations in gliomas stimulated various studies to explore the molecular consequences and the clinical implications of such alterations. The Cancer Genome Atlas Research Network showed evidence for a CpG island methylator phenotype in glioblastomas that was associated with IDH1 mutations. These alterations were associated with the production of the oncometabolite, 2-hydroxyglutarate, that inhibits oxygenases [ie, ten-eleven translocation (TET) enzymes involved in the oxidation of 5-methylcytosine to 5-hydroxymethylcytosine (5hmC)]. We investigated 60 gliomas for 5hmC presence, 5-methylcytosine content, TET1 expression, and IDH1 mutation to gain insight into their relationships on a histological level. Of gliomas, 61% revealed no immunoreactivity for 5hmC, and no correlation was observed between IDH1 mutations and loss of 5hmC. Interestingly, expression of TET1 showed remarkable differences regarding overall protein levels and subcellular localization. We found a highly significant (P = 0.0007) correlation between IDH1 mutations and nuclear accumulation of TET1, but not with loss of 5hmC. Of 5hmC-negative gliomas, 70% showed either exclusive or dominant cytoplasmic expression, or no detectable TET1 protein (P = 0.0122). Our data suggest that the loss of 5hmC is a frequent event in gliomas, independent of IDH1 mutation, and may be influenced by the nuclear exclusion of TET1 from the nuclei of glioma cells.

Frequent epigenetic inactivation of the chaperone SGNE1/7B2 in human gliomas.

In a genome-wide screen using DMH (differential methylation hybridization) we have identified a CpG island within the 5' region and untranslated first exon of the secretory granule neuroendocrine protein 1 gene (SGNE1/7B2) that showed hypermethylation in low- and high-grade astrocytomas compared to normal brain tissue. Pyrosequencing was performed to confirm the methylation status of this CpG island in 89 astrocytic gliomas of different malignancy grades and six glioma cell lines. Hypermethylation of SGNE1/7B2 was significantly more frequent in diffuse low-grade astrocytomas as well as secondary glioblastomas and anaplastic astrocytomas as compared to primary glioblastomas. mRNA expression analysis by real-time RT-PCR indicates that SGNE1/7B2 expression is downregulated in astrocytic gliomas compared to white matter samples. Treatment of glioma cells with the demethylating agent 5-aza-2'-deoxycytidine restores the transcription of SGNE1/7B2. Overexpression of SGNE1/7B2 in T98G, A172 and U373MG glioblastoma cells significantly suppressed focus formation and led to a significant increase in apoptotic cells as determined by flow cytometric analysis in T98G cells. In summary, we have identified SGNE1/7B2 as a novel target silenced by DNA methylation in astrocytic gliomas. The high incidence of this alteration and the significant effects of SGNE1/7B2 on the growth and apoptosis of glioblastoma cells provide a first proof for a functional implication of SGNE1/7B2 inactivation in the molecular pathology of gliomas.

Sensitive determination of BRAF copy number in clinical samples by pyrosequencing.

Pilocytic astrocytoma is the most frequently occurring brain tumor during childhood. It is classified as grade I by the World Health Organization and may rarely evolve into higher-grade tumors. Frequent genetic abnormalities documented in astrocytomas in children are gains on chromosomal arm 7q. Duplications at 7q34 lead to a fusion between genes KIAA1549 and BRAF resulting in constitutive activation of the BRAF kinase. The BRAF gene is located on chromosome 7q34 and a pseudogene has been identified on chromosome Xq13. We have developed a simple and sensitive pyrosequencing method for the determination of the BRAF copy number in clinical samples. The approach is based on the simultaneous amplification of a DNA fragment contained in exon 11 of BRAF and the respective pseudogene that is used as an internal control. Three different bases in the PCR product allow precise sequence assessment of products originating from the BRAF gene and the respective pseudogene and a calculation of gene copy numbers. After the calibration of the assay on 78 control DNA samples, 42 clinical PA samples were analyzed for variation in copy numbers by pyrosequencing and for fusion gene expression by reverse transcription-polymerase chain reaction. The results obtained from tumor DNA by the developed assay and the established reverse transcription-polymerase chain reaction assays show a high concordance. In summary, we have established a pyrosequencing-based assay allowing precise detection of BRAF copy numbers in DNA extracted from clinical samples.

A pyrosequencing-based assay for the rapid detection of IDH1 mutations in clinical samples.

Mutations of both the IDH1 and IDH2 (isocitratedehydrogenase enzyme 1 and 2) genes have recently been described in cases of human glioma. Since IDH1 mutations have been associated with better clinical outcome, they are suitable predictive markers for adult glioma patients. We have developed a pyrosequencing assay that allows both the sensitive and rapid detection of mutant IDH1 alleles in DNA extracted from formalin-fixed, paraffin-embedded tissues. PCR products that span exon 4 of IDH1 were used as a template for pyrosequencing. For validation, PCR products were additionally cloned and sequenced conventionally by Sanger sequencing. Sensitivity was measured by titration of wild-type and mutant sequences. PCR kinetic experiments were performed to investigate the influences of PCR cycle number on the accuracy of the assay. We found that a minimum of 5% of mutant IDH1 alleles can easily be detected with the pyrosequencing approach. So far, there are few data regarding IDH1 mutation status in high-grade gliomas of childhood. Therefore, we applied this assay to 47 pediatric high-grade glioma samples (age range 6 weeks to 23 years). Mutations were found in 5/14 astrocytoma III and in 6/33 glioblastomas. In conclusion, we have developed a pyrosequencing-based assay for the detection of mutations at the hotspot regions of IDH1 and provide proof for its applicability as a molecular diagnostic assay for clinical samples.