Project description:Glioblastoma (GBM) is among the most aggressive of human cancers. Although differentiation therapy has been proposed to be potential approach to treat GBM, the mechanisms of induced differentiation remain poorly defined. Here, we established the induced differentiation model of GBM by using cAMP activators, which specifically directed GBM into astroglia. Next, transcriptomic and proteomic analyses uncovered oxidative phosphorylation and mitochondrial biogenesis were involved in induced differentiation of GBM. Further investigation showed dbcAMP reversed Warburg effect evidenced by increase of oxygen consumption and reduction of lactate production. Stimulated mitochondrial biogenesis downstream of CREB/PGC1α pathway triggered metabolic shift and differentiation. Blocking mitochondrial biogenesis by mdivi1 or silencing PGC1α abrogated differentiation, reversely over-expression of PGC1α elicited differentiation. In GBM xenograft models and patient-derived GBM samples, cAMP activators also induced tumor growth inhibition and differentiation. This study shows mitochondrial biogenesis and metabolic switch to oxidative phosphorylation drive the differentiation process of tumor cells.

Project description:We have data from a previous microarray experiment which shows that C1q elicits macrophages to express genes important for clearance of dead (apoptotic) cells. In this experiment we want to determine the signaling mechanism by which C1q is turning on macrophage gene expression. For our control (sample 1-3) we heated C1q to denature it so it is inactive. We also want to know which portion of C1q is responsible for activation the macrophage so we generated C1qtails (samples 4-5). We also have macrophages treated with the whole C1q molecule (7-9). And finally we have a cell line (J774) treated with C1q but does not activate the cells (samples 10-12).

Project description:We have data from a previous microarray experiment which shows that C1q elicits macrophages to express genes important for clearance of dead (apoptotic) cells. In this experiment we want to determine the signaling mechanism by which C1q is turning on macrophage gene expression. For our control (sample 1-3) we heated C1q to denature it so it is inactive. We also want to know which portion of C1q is responsible for activation the macrophage so we generated C1qtails (samples 4-5). We also have macrophages treated with the whole C1q molecule (7-9). And finally we have a cell line (J774) treated with C1q but does not activate the cells (samples 10-12). Bone marrow derived macrophages or J774 cells were adhered to heat inactivated C1q, C1q tails or C1q for 18 hours. Cells were harvested and RNA was isolated and converted to double stranded cDNA and subsequently labeled and hybridized onto NimbleGen mouse gene expression array [100718_MM9_EXP] using Nimblegen Hybridization system 4 according to manufacturerM-bM-^@M-^Ys instructions (Roche)

Project description:Glioblastoma (GBM, WHO grade IV) is an aggressive, primary brain tumor. Despite gross surgery and forceful radio- and chemotherapy, survival of GBM patients did not improve over decades. Several studies reported transcription deregulation in GBMs but regulatory mechanisms driving overexpression of GBM-specific genes remain largely unknown. Transcription in open chromatin regions is directed by transcription factors (TFs) that bind to specific motifs, recruit co-activators/repressors and a transcriptional machinery. Identification of GBM-related TFs-gene regulatory networks may reveal new, targetable mechanisms of gliomagenesis.

Project description:Glioblastoma (GBM) is the most aggressive form of astrocytoma and is difficult to diagnose at early stage. In this study, our goal is to find and validate biomarkers for GBM through serum proteome expression profiling, which would assist in the early diagnosis, and management of GBMs. In the discovery phase, we performed shotgun proteomics of control and GBM pooled serum samples using untargeted 4-plex iTRAQ (isobaric Tags for Relative and Absolute Quantitation) mass spectrometry to identify candidate biomarkers with differential abundance The two candidates, S100A8 and S100A9 were prioritized for verification based on their maximal abundance in GBM serum in our discovery phase.

Project description:In this study, we investigated the dynamics during differentiation of the in vivo binding sites of ZBTB2, a putative reader for unmethylated DNA. We performed DNA pull-downs followed by mass spectrometry, using a genomic sequence containing either unmethylated or methylated CpGs, to study the influence of DNA methylation on ZBTB2 binding. Additionally, we performed interaction proteomics to identify ZBTB2 interaction partners. We found that ZBTB2 recruits a zinc finger module of three proteins to unmethylated DNA.

Project description:We identified a subgroup of patient-derived glioblastoma (GBM) cells that express high levels of the neurogenic transcription factor, ASCL1, which predicts response to pharmacological inhibition of the Notch signaling pathway. Treatment of ASCL1hi GBM cells with a Notch signaling inhibitor induced a change in cell fate from neoplastic to neuronal. Importantly, acquisition of the neuronal fate was accompanied by a reduction in tumorigenic potential. Loss of ASCL1 in GBM cells rendered cells no longer responsive to Notch signaling inhibition and we determined ASCL1 is required for the competency of GBM cells to undergo neuronal differentiation. Enforced ASCL1 expression directed GBM cells towards a neuronal cell fate reminiscent of terminal differentiation. RNA-seq analysis of GBM cells treated with the Notch signaling inhibitor reveals neuronal target gene activation is associated with increased stoichiometric levels of ASCL1, suggesting threshold levels of ASCL1 in GBM cells governs neuronal differentiation. We demonstrate that neoplastic cells which retain expression of key neurogenic programs can have their fates redirected towards terminal differentiation. Directed fate specification to neuronal cell types by exploiting latent neurogenic programs may be a strategy to treat a subset of GBM patients. Our findings therefore highlight the potential of differentiation therapy for a subset of molecularly defined GBMs.

Project description:In this study, we aimed to determine the fate of GBM cells following cAMP-induced differentiation. We assessed the effect of dbcAMP treatment on the global gene expression pattern of the human GBM cell lines DBTRG and U87 using RNA sequencing (RNA-Seq) analysis

Project description:Using induced pluripotent stem cell (iPSC) technology, we reprogrammed GBM derived cells (GBM-DCs) into embryonic-like cells termed as induced core-GSCs (ic-GSCs). The aim of this experiment was to characterize the transcriptomic profile of ic-GSCs using RNA-seq. For this experiment, we selected three biological replicates of GBM-DCs (GBM-DC1, GBM-DC2 and GBM-DC3) and three independent clonal lines of ic-GSCs (ic-GSC#1, ic-GSC#3 and ic-GSC#7).

Project description:Glioblastoma multiforme (GBM) is the most aggressive malignant brain tumor. Differentiation can attenuate or block tumor growth; thus, phenotypic screenings were performed to search for drugs inducing differentiational morphological changes in mesenchymal recurrent GBM, a temozolomide (TMZ)-resistant brain cancer. Bexarotene, a selective retinoid X receptor agonist, showed strong inhibition of neurospheroidal colony formation and migration of cultured GBM stem cells. Bexarotene decreased nestin expression and significantly increased GFAP expression. Gene expression changes by bexarotene and all-trans retinoic acid (ATRA), a well-known differentiation inducer, were compared. Both drugs largely altered the gene expression pattern into a tumor-ameliorating direction. These drugs increased the gene expression levels of Krüppel-like factor 9 (KLF9), regulator of G-protein signaling 4 (RGS4), growth differentiation factor 15 (GDF15), angiopoietin-like protein 4 (ANGPTL4), and lowered the level of chemokine receptor type 4 (CXCR4). Both drugs also induced a potential oncogene, transglutaminase 2 (TG2), but the fold-change induced by bexarotene was considerably lesser than that by ATRA. Consistently, the TG2 activity in GBM was elevated several folds by ATRA. Because TG2 upregulation is correlated with tumor transformation and resistance, it is important to control its overexpression. Bexarotene does not upregulate TG2 as much as ATRA, and bexarotene showed in vivo tumoricidal effects in a GBM xenograft mouse model. Thus, these findings strongly suggest that bexarotene is more beneficial than ATRA and should be considered as a differentiation therapeutic agent for mesenchymal GBM.