Summary High-grade gliomas are aggressive and uniformly fatal tumors, composed of a heterogeneous population of cells that include many with stem cell-like properties. The acquisition of stem-like traits might contribute to glioma initiation, growth and recurrence. Here we investigated the role of the transcription factor myeloid Elf-1 like factor (MEF, also known as ELF4) in glioma. We found that MEF is highly expressed in both human and mouse GBMs and its absence impairs gliomagenesis in a PDGF-driven glioma mouse model. We show that modulation of MEF levels in both mouse neural stem cells and human glioblastoma cells, has a significant impact on neurosphere formation. Moreover, we identify Sox2 as a direct downstream target of MEF. Taken together, our studies implicate MEF as a previously unrecognized gatekeeper gene in gliomagenesis by promoting stem cell characteristics through Sox2 activation.
BackgroundResistance of the highly aggressive glioblastoma multiforme (GBM) to drug therapy is a major clinical problem resulting in a poor patient’s prognosis. Beside promoter methylation of the O 6 -methylguanine-DNA-methyltransferase (MGMT) gene the efflux transporters ABCB1 and ABCG2 have been suggested as pivotal factors contributing to drug resistance, but the methylation of ABCB1 and ABCG2 has not been assessed before in GBM.MethodsTherefore, we evaluated the proportion and prognostic significance of promoter methylation of MGMT, ABCB1 and ABCG2 in 64 GBM patient samples using pyrosequencing technology. Further, the single nucleotide polymorphisms MGMT C-56 T (rs16906252), ABCB1 C3435T (rs1045642) and ABCG2 C421A (rs2231142) were determined using the restriction fragment length polymorphism method (RFLP). To study a correlation between promoter methylation and gene expression, we analyzed MGMT, ABCB1 and ABCG2 expression in 20 glioblastoma and 7 non-neoplastic brain samples.ResultsDespite a significantly increased MGMT and ABCB1 promoter methylation in GBM tissue, multivariate regression analysis revealed no significant association between overall survival of glioblastoma patients and MGMT or ABCB1 promoter methylation. However, a significant negative correlation between promoter methylation and expression could be identified for MGMT but not for ABCB1 and ABCG2. Furthermore, MGMT promoter methylation was significantly associated with the genotypes of the MGMT C-56 T polymorphism showing a higher methylation level in the T allele bearing GBM.ConclusionsIn summary, the data of this study confirm the previous published relation of MGMT promoter methylation and gene expression, but argue for no pivotal role of MGMT, ABCB1 and ABCG2 promoter methylation in GBM patients’ survival.
INTRODUCTION: Recent evidence suggests that glioblastoma is driven by a subset of tumor initiating (TI) cells characterized by their capacity to form tumors in xenograft models and self-renew in vitro. These TI cells share many properties of neural stem/progenitor cells, including the expression of certain cell surface markers. With serial passage, many cells lose their capacity to TI. The transition between TI-proficient and -deficient states remains poorly understood. METHODS AND RESULTS: There are two theoretic models for the maintenance of TI states. In the "elite" model, TI activity is restricted to a predetermined subpopulation of cells. The alternative "stochastic" model suggests that any tumor cell has a finite chance of acquiring TI capacity through random fluctuations in cell physiology. To address this issue, we examined the TI capacity of distinct subclones isolated from a distinct glioblastoma line as well as the TI capacity of single cells derived from each distinct clone. We found that only a subset of subclones from a single glioblastoma line displayed capacity for TI, suggestive of the elite model. However, single cells derived from any single subclone exhibited a wide range of TI capacity, suggesting a stochastic component to this process. Transcriptome profiling of the subclones of differing TI revealed a gene signature associated with TI capacity. Analysis of this signature showed enrichment for genes regulated by c-Myc. Indeed, clones with increased TI capacity tend to harbor increased c-Myc expression. Additionally, over-expression of c-myc increased the TI capacity of glioblastoma cells in xenograft models and led to the formation of intracranial tumor in an Ink4a/ARF null transgenic murine model. CONCLUSION: Our results are most consistent with a threshold model in which TI states in glioblastomas are driven by expression levels of critical factors such as c-Myc.
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