Project description:Large-scale cancer genomics projects are profiling hundreds of tumors at multiple molecular layers, including copy number, mRNA and miRNA expression, but the mechanistic relationships between these layers are often excluded from computational models. We developed a supervised learning framework for integrating molecular profiles with regulatory sequence information to reveal regulatory programs in cancer, including miRNA-mediated regulation. We applied our approach to 320 glioblastoma profiles and identified key miRNAs and transcription factors as common or subtype-specific drivers of expression changes. We confirmed that predicted gene expression signatures for proneural subtype regulators were consistent with in vivo expression changes in a PDGF-driven mouse model. We tested two predicted proneural drivers, miR-124 and miR-132, both underexpressed in proneural tumors, by overexpression in neurospheres and observed a partial reversal of corresponding tumor expression changes. Computationally dissecting the role of miRNAs in cancer may ultimately lead to small RNA therapeutics tailored to subtype or individual.

Project description:The AVAglio and RTOG-0825 randomized, placebo-controlled phase III trials in newly diagnosed glioblastoma reported prolonged progression-free survival (PFS), but not overall survival (OS), with the addition of bevacizumab to radiotherapy/temozolomide. To establish whether certain patient subgroups derived OS benefit from the addition of bevacizumab to first-line standard-of-care therapy, AVAglio patients were retrospectively evaluated for molecular subtype, and bevacizumab efficacy assessed for each patient subgroup. A multivariate analysis accounting for prognostic covariates revealed that bevacizumab conferred a significant OS advantage versus placebo for patients with Proneural IDH1 wild-type tumors (17.1 v 12.8 months, respectively; hazard ratio, 0.43; 95% CI, 0.26 to 0.73; P = .002). This analysis also revealed an interaction between the Proneural subtype biomarker and treatment arm (P = .023). The group of patients with Mesenchymal and Proneural tumors derived a PFS benefit from bevacizumab, compared with placebo; however, this translated to an OS benefit in the Proneural subset only. Retrospective analysis of AVAglio data suggests that patients with IDH1 wild-type Proneural glioblastoma may derive OS benefit from first-line bevacizumab treatment. The predictive value of the Proneural subtype observed in AVAglio should be validated in an independent dataset. A total of 349 (bevacizumab arm, n = 171; placebo arm, n = 178) pretreatment specimens from AVAglio patients (total n = 921) were available for biomarker analysis. Samples were profiled for gene expression and isocitrate dehydrogenase 1 (IDH1) mutation status and classified into previously identified molecular subtypes. PFS and OS were assessed within each subtype.

Project description:The AVAglio and RTOG-0825 randomized, placebo-controlled phase III trials in newly diagnosed glioblastoma reported prolonged progression-free survival (PFS), but not overall survival (OS), with the addition of bevacizumab to radiotherapy/temozolomide. To establish whether certain patient subgroups derived OS benefit from the addition of bevacizumab to first-line standard-of-care therapy, AVAglio patients were retrospectively evaluated for molecular subtype, and bevacizumab efficacy assessed for each patient subgroup. A multivariate analysis accounting for prognostic covariates revealed that bevacizumab conferred a significant OS advantage versus placebo for patients with Proneural IDH1 wild-type tumors (17.1 v 12.8 months, respectively; hazard ratio, 0.43; 95% CI, 0.26 to 0.73; P = .002). This analysis also revealed an interaction between the Proneural subtype biomarker and treatment arm (P = .023). The group of patients with Mesenchymal and Proneural tumors derived a PFS benefit from bevacizumab, compared with placebo; however, this translated to an OS benefit in the Proneural subset only. Retrospective analysis of AVAglio data suggests that patients with IDH1 wild-type Proneural glioblastoma may derive OS benefit from first-line bevacizumab treatment. The predictive value of the Proneural subtype observed in AVAglio should be validated in an independent dataset.

Project description:Identification of critical survival determinants of PDGF-driven proneural glioma. Results provided information about the genes and pathways that are regulated by PDGF signaling in PDGF-driven proneural glioma and led to the assessment of the importance of the USP1-ID2 axis in proneural glioma. Total RNA obtained from PDGF-driven glioma spheroid cells (PDGF-GSC) and primary tumors arising in the Gfap-tTa/Tre-PDGFB mouse model used in our study was analyzed to determine to which subtype of GBM these specimens belonged.

Project description:In glioblastoma, a mesenchymal phenotype is associated with especially poor patient outcomes. Various glioblastoma microenvironmental factors and therapeutic interventions are purported drivers of the mesenchymal transition, but the degree to which these cues promote the same mesenchymal transitions and the uniformity of those transitions, as defined by molecular subtyping systems, is unknown. Here, we investigate this question by analyzing publicly available patient data, surveying commonly measured transcripts for mesenchymal transitions in glioma-initiating cells (GIC), and performing next-generation RNA sequencing of GICs. Analysis of patient tumor data reveals that TGFβ, TNFα, and hypoxia signaling correlate with the mesenchymal subtype more than the proneural subtype. In cultured GICs, the microenvironment-relevant growth factors TGFβ and TNFα and the chemotherapeutic temozolomide promote expression of commonly measured mesenchymal transcripts. However, next-generation RNA sequencing reveals that growth factors and temozolomide broadly promote expression of both mesenchymal and proneural transcripts, in some cases with equal frequency. These results suggest that glioblastoma mesenchymal transitions do not occur as distinctly as in epithelial-derived cancers, at least as determined using common subtyping ontologies and measuring response to growth factors or chemotherapeutics. Further understanding of these issues may identify improved methods for pharmacologically targeting the mesenchymal phenotype in glioblastoma.

Project description:Glioblastoma multiforme (GBM), the most common and aggressive primary brain tumor in adults, can be divided into several molecular subtypes including proneural GBM. Most clinical strategies aimed at directly targeting glioma cells in these tumors have failed. A promising alternative is to target stromal cells in the brain microenvironment, such as tumor-associated microglia and macrophages (TAMs). Macrophages are dependent upon colony stimulating factor (CSF)-1 for differentiation and survival; therefore, we used an inhibitor of its receptor, CSF-1R, to target macrophages in a mouse proneural GBM model. CSF-1R inhibition dramatically increased survival in mice and regressed established GBMs. Tumor cell apoptosis was significantly increased, and proliferation and tumor grade markedly decreased. Surprisingly, TAMs were not depleted in tumors treated with the CSF-1R inhibitor. Instead, analysis of gene expression in TAMs isolated from treated tumors revealed a decrease in alternatively activated/ M2 macrophage markers, consistent with impaired tumor-promoting functions. These gene signatures were also associated with better survival specifically in the proneural subtype of patient gliomas. Collectively, these results establish macrophages as valid therapeutic targets in proneural gliomas, and highlight the clinical potential for CSF-1R inhibitors in GBM. RNA was isolated from sorted tumor associated macrophages (TAMs) from murine gliomas following either 7 days of vehicle or BLZ945 treatment. Samples were collected from 16 total tumor burdened mice, with 8 replicates for each treatment group. BLZ945: a Colony-Stimulating Factor 1 Receptor (CSF-1R) inhibitor

Project description:In this study, we performed miRNA profiles analysis of 84, 17, 20, 83, 718, 1123, 528 and 816 glioma spheres compared to normal progenitor sample (16wf) using microarray to evaluate their potential role in regulation of the biological properties of proneural and mesenchymal glioma spheres miRNA profiling analysis of the 9 samples including 8 patient-derived samples including glioma sphere samples (84, 17, 20, 718, 816, 528, 83 and 1123), as well as one normal progenitor sample (16wf).

Project description:Here, we use a series of genetically-defined murine cortical astrocytes with conditional inactivation of Rb/Pten and activated Kras to systematically investigate the individual and combinatorial roles of these pathways during gliomagenesis. We show that genetic disruption of all three pathways, which frequently occurs in human GBM, leads to maximal in vitro growth, migration, and invasion and produces stem-like transcriptomal profiles similar to the proneural subtype of human GBM. Genetic alterations in all three pathways are also required for efficient tumorigenesis in an orthotopic syngeneic allograft model system in vivo. These findings show that cortical astrocytes can form GBM and identify a potential model for proneural GBM that can be used to test subtype-specific therapies. Transcriptional profiling of transformed murine cortical astrocytes shows correlation between mutated genes, invasive capability, neural lineage, and human astrocytoma/GBM signatures. 10 samples

Project description:To identify new therapeutic targets for Glioblastoma (GBM), we performed genome-wide CRISPR-Cas9 "knockout" (KO) screens in patient-derived GBM stem-like cells (GSCs) and human neural stem/progenitors (NSCs), non-neoplastic stem cell controls, for genes required for their in vitro growth. Surprisingly, the vast majority GSC-lethal hits were found outside of molecular networks commonly altered in GBM and GSCs (e.g., oncogenic drivers). In vitro and in vivo validation of GSC-specific targets revealed several strong hits, including the wee1-like kinase, PKMYT1/Myt1. Mechanistic studies demonstrated that PKMYT1 acts redundantly with WEE1 to inhibit Cyclin B-CDK1 activity via CDK1-Tyr15 phosphorylation and to promote timely completion of mitosis in NSCs. However, in GSCs, this redundancy is lost, likely as a result of oncogenic signaling, causing GBM-specific lethality. A whole-genome CRISPR-Cas9 knockout screens targeting over 18,000 genes using the all-in-one LV-sgRNA:Cas9 platform system were performed using a “shot gun” approach by transducing 2 GBM patient-derived isolates and 2 human neural stem cell isolates with the pool library (2 biological replicates), and cultures were outgrown for ~3 weeks. The end time point of each screen was compared to day 0 in order to determine which sgRNAs were overrepresented or underrepresented in the population.

Project description:A challenge in systems biology is to understand the gene regulatory networks that connect early cellular specification to terminal differentiation of specific cell types. In neurogenesis, neural specification has been well studied, but the link between the proneural transcriptional regulators of specification and the genes that must be activated to construct differentiated neurons is obscure. High resolution temporal profiling of gene expression reveals the events downstream of Atonal (Ato) proneural gene function in Drosophila sensory neurons. Unexpectedly, many differentiation genes are activated soon after specification, even before cell cycle exit and overt neuronal differentiation. Prominent among them are genes required for construction of the ciliary dendrite. Ato activates differentiation both directly and indirectly via several intermediate transcriptional regulators, including Rfx and a new Forkhead family factor. Our analysis of these factors and their regulation provides insight into how proneural factors regulate neuronal subtype differentiation. Investigating the molecular mechanisms of peripheral nervous sytem development in Drosophila melanogaster. Affymetrix Drosophila version 2.0 chips used to measure gene expression from GFP+ and GFP- cells from embryos expressing GFP under the control of the atonal gene enhancer in both wild type and mutant embryos. Data generated for three developmental time-points in quadruplicate.