Breaking out of the cycle: Including quiescence in cell cycle classification

Single-cell transcriptomics has unveiled a vast landscape of cellular heterogeneity in which the cell cycle is a significant component. We trained a high-resolution cell cycle classifier (ccAFv2) using single cell RNA-seq (scRNA-seq) characterized human neural stem cells. The ccAFv2 classifies six cell cycle states (G1, Late G1, S, S/G2, G2/M, and M/Early G1) and a quiescent-like G0 state, and it incorporates a tunable parameter to filter out less certain classifications. The ccAFv2 classifier performed better than or equivalent to other state-of-the-art methods even while classifying more cell cycle states, including G0. We showcased the versatility of ccAFv2 by successfully applying it to classify cells, nuclei, and spatial transcriptomics data in humans and mice, using various normalization methods and gene identifiers. We provide methods to regress the cell cycle expression patterns out of single cell or nuclei data to uncover underlying biological signals. The classifier can be used either as an R package integrated with Seurat (https://github.com/plaisier-lab/ccafv2_R) or a PyPI package integrated with scanpy (https://pypi.org/project/ccAFv2/). We proved that ccAFv2 has enhanced accuracy, flexibility, and adaptability across various experimental conditions, establishing ccAFv2 as a powerful tool for dissecting complex biological systems, unraveling cellular heterogeneity, and deciphering the molecular mechanisms by which proliferation and quiescence affect cellular processes.

Multi-level functional genomics reveals molecular and cellular oncogenicity of patient-based 3' untranslated region mutations

3' untranslated region (3' UTR) somatic mutations represent a largely unexplored avenue of alternative oncogenic gene dysregulation. To determine the significance of 3' UTR mutations in disease, we identify 3' UTR somatic variants across 185 advanced prostate tumors, discovering 14,497 single-nucleotide mutations enriched in oncogenic pathways and 3' UTR regulatory elements. By developing two complementary massively parallel reporter assays, we measure how thousands of patient-based mutations affect mRNA translation and stability and identify hundreds of functional variants that allow us to define determinants of mutation significance. We demonstrate the clinical relevance of these mutations, observing that CRISPR-Cas9 endogenous editing of distinct variants increases cellular stress resistance and that patients harboring oncogenic 3' UTR mutations have a particularly poor prognosis. This work represents an expansive view of the extent to which disease-relevant 3' UTR mutations affect mRNA stability, translation, and cancer progression, uncovering principles of regulatory functionality and potential therapeutic targets in previously unexplored regulatory regions.

Gene knock-outs in human CD34+ hematopoietic stem and progenitor cells and in the human immune system of mice

Human CD34+ hematopoietic stem and progenitor cells (HSPCs) are a standard source of cells for clinical HSC transplantations as well as experimental xenotransplantation to generate "humanized mice". To further extend the range of applications of these humanized mice, we developed a protocol to efficiently edit the genomes of human CD34+ HSPCs before transplantation. In the past, manipulating HSPCs has been complicated by the fact that they are inherently difficult to transduce with lentivectors, and rapidly lose their stemness and engraftment potential during in vitro culture. However, with optimized nucleofection of sgRNA:Cas9 ribonucleoprotein complexes, we are now able to edit a candidate gene in CD34+ HSPCs with almost 100% efficiency, and transplant these modified cells in immunodeficient mice with high engraftment levels and multilineage hematopoietic differentiation. The result is a humanized mouse from which we knocked out a gene of interest from their human immune system.

WDR5 represents a therapeutically exploitable target for cancer stem cells in glioblastoma

Glioblastomas (GBMs) are heterogeneous, treatment-resistant tumors driven by populations of cancer stem cells (CSCs). However, few molecular mechanisms critical for CSC population maintenance have been exploited for therapeutic development. We developed a spatially resolved loss-of-function screen in GBM patient-derived organoids to identify essential epigenetic regulators in the SOX2-enriched, therapy-resistant niche and identified WDR5 as indispensable for this population. WDR5 is a component of the WRAD complex, which promotes SET1 family-mediated Lys4 methylation of histone H3 (H3K4me), associated with positive regulation of transcription. In GBM CSCs, WDR5 inhibitors blocked WRAD complex assembly and reduced H3K4 trimethylation and expression of genes involved in CSC-relevant oncogenic pathways. H3K4me3 peaks lost with WDR5 inhibitor treatment occurred disproportionally on POU transcription factor motifs, including the POU5F1(OCT4)::SOX2 motif. Use of a SOX2/OCT4 reporter demonstrated that WDR5 inhibitor treatment diminished cells with high reporter activity. Furthermore, WDR5 inhibitor treatment and WDR5 knockdown altered the stem cell state, disrupting CSC in vitro growth and self-renewal, as well as in vivo tumor growth. These findings highlight the role of WDR5 and the WRAD complex in maintaining the CSC state and provide a rationale for therapeutic development of WDR5 inhibitors for GBM and other advanced cancers.

Functional genomic analysis of adult and pediatric brain tumor isolates

Background

Adult and pediatric tumors display stark differences in their mutation spectra and chromosome alterations. Here, we attempted to identify common and unique gene dependencies and their associated biomarkers among adult and pediatric tumor isolates using functional genetic lethal screens and computational modeling.

Methods

We performed CRISRP-Cas9 lethality screens in two adult glioblastoma (GBM) tumor isolates and five pediatric brain tumor isolates representing atypical teratoid rhabdoid tumors (ATRT), diffuse intrinsic pontine glioma, GBM, and medulloblastoma. We then integrated the screen results with machine learning-based gene-dependency models generated from data from >900 cancer cell lines.

Results

We found that >50% of candidate dependencies of 280 identified were shared between adult GBM tumors and individual pediatric tumor isolates. 68% of screen hits were found as nodes in our network models, along with shared and tumor-specific predictors of gene dependencies. We investigated network predictors associated with ADAR, EFR3A, FGFR1 (pediatric-specific), and SMARCC2 (ATRT-specific) gene dependency among our tumor isolates.

Conclusions

The results suggest that, despite harboring disparate genomic signatures, adult and pediatric tumor isolates share a preponderance of genetic dependences. Further, combining data from primary brain tumor lethality screens with large cancer cell line datasets produced valuable insights into biomarkers of gene dependency, even for rare cancers.

Importance of the Study

Our results demonstrate that large cancer cell lines data sets can be computationally mined to identify known and novel gene dependency relationships in adult and pediatric human brain tumor isolates. Gene dependency networks and lethality screen results represent a key resource for neuro-oncology and cancer research communities. We also highlight some of the challenges and limitations of this approach.

A modular CRISPR screen identifies individual and combination pathways contributing to HIV-1 latency

Transcriptional silencing of latent HIV-1 proviruses entails complex and overlapping mechanisms that pose a major barrier to in vivo elimination of HIV-1. We developed a new latency CRISPR screening strategy, called Latency HIV-CRISPR which uses the packaging of guideRNA-encoding lentiviral vector genomes into the supernatant of budding virions as a direct readout of factors involved in the maintenance of HIV-1 latency. We developed a custom guideRNA library targeting epigenetic regulatory genes and paired the screen with and without a latency reversal agent-AZD5582, an activator of the non-canonical NFκB pathway-to examine a combination of mechanisms controlling HIV-1 latency. A component of the Nucleosome Acetyltransferase of H4 histone acetylation (NuA4 HAT) complex, ING3, acts in concert with AZD5582 to activate proviruses in J-Lat cell lines and in a primary CD4+ T cell model of HIV-1 latency. We found that the knockout of ING3 reduces acetylation of the H4 histone tail and BRD4 occupancy on the HIV-1 LTR. However, the combination of ING3 knockout accompanied with the activation of the non-canonical NFκB pathway via AZD5582 resulted in a dramatic increase in initiation and elongation of RNA Polymerase II on the HIV-1 provirus in a manner that is nearly unique among all cellular promoters.

Both YAP1-MAML2 and constitutively active YAP1 drive the formation of tumors that resemble NF2 mutant meningiomas in mice

YAP1 is a transcriptional coactivator regulated by the Hippo signaling pathway, including NF2. Meningiomas are the most common primary brain tumors; a large percentage exhibit heterozygous loss of chromosome 22 (harboring the NF2 gene) and functional inactivation of the remaining NF2 copy, implicating oncogenic YAP activity in these tumors. Recently, fusions between YAP1 and MAML2 have been identified in a subset of pediatric NF2 wild-type meningiomas. Here, we show that human YAP1-MAML2-positive meningiomas resemble NF2 mutant meningiomas by global and YAP-related gene expression signatures. We then show that expression of YAP1-MAML2 in mice induces tumors that resemble human YAP1 fusion-positive and NF2 mutant meningiomas by gene expression. We demonstrate that YAP1-MAML2 primarily functions by exerting TEAD-dependent YAP activity that is resistant to Hippo signaling. Treatment with YAP-TEAD inhibitors is sufficient to inhibit the viability of YAP1-MAML2-driven mouse tumors ex vivo. Finally, we show that expression of constitutively active YAP1 (S127/397A-YAP1) is sufficient to induce similar tumors, suggesting that the YAP component of the gene fusion is the critical driver of these tumors. In summary, our results implicate YAP1-MAML2 as a causal oncogenic driver and highlight TEAD-dependent YAP activity as an oncogenic driver in YAP1-MAML2 fusion meningioma as well as NF2 mutant meningioma in general.

Functional dissection of human mitotic genes using CRISPR-Cas9 tiling screens

In this Resource/Methodology, Herman et al. developed a method that leverages CRISPR–Cas9-induced mutations across protein-coding genes for the a priori identification of functional regions at the sequence level. As a test case, they applied this method to 48 human mitotic genes, revealing hundreds of regions required for cell proliferation, including domains that were experimentally characterized, ones that were predicted based on homology, and novel ones.

The identity of human protein-coding genes is well known, yet our in-depth knowledge of their molecular functions and domain architecture remains limited by shortcomings in homology-based predictions and experimental approaches focused on whole-gene depletion. To bridge this knowledge gap, we developed a method that leverages CRISPR–Cas9-induced mutations across protein-coding genes for the a priori identification of functional regions at the sequence level. As a test case, we applied this method to 48 human mitotic genes, revealing hundreds of regions required for cell proliferation, including domains that were experimentally characterized, ones that were predicted based on homology, and novel ones. We validated screen outcomes for 15 regions, including amino acids 387–402 of Mad1, which were previously uncharacterized but contribute to Mad1 kinetochore localization and chromosome segregation fidelity. Altogether, we demonstrate that CRISPR–Cas9-based tiling mutagenesis identifies key functional domains in protein-coding genes de novo, which elucidates separation of function mutants and allows functional annotation across the human proteome.

Global and context-specific transcriptional consequences of oncogenic Fbw7 mutations

The Fbw7 ubiquitin ligase targets many proteins for proteasomal degradation, which include oncogenic transcription factors (TFs) (e.g., c-Myc, c-Jun, and Notch). Fbw7 is a tumor suppressor and tumors often contain mutations in FBXW7, the gene that encodes Fbw7. The complexity of its substrate network has obscured the mechanisms of Fbw7-associated tumorigenesis, yet this understanding is needed for developing therapies. We used an integrated approach employing RNA-Seq and high-resolution mapping (cleavage under target and release using nuclease) of histone modifications and TF occupancy (c-Jun and c-Myc) to examine the combinatorial effects of misregulated Fbw7 substrates in colorectal cancer (CRC) cells with engineered tumor-associated FBXW7 null or missense mutations. Both Fbw7 mutations caused widespread transcriptional changes associated with active chromatin and altered TF occupancy: some were common to both Fbw7 mutant cell lines, whereas others were mutation specific. We identified loci where both Jun and Myc were coregulated by Fbw7, suggesting that substrates may have synergistic effects. One coregulated gene was CIITA, the master regulator of MHC Class II gene expression. Fbw7 loss increased MHC Class II expression and Fbw7 mutations were correlated with increased CIITA expression in TCGA colorectal tumors and cell lines, which may have immunotherapeutic implications for Fbw7-associated cancers. Analogous studies in neural stem cells in which FBXW7 had been acutely deleted closely mirrored the results in CRC cells. Gene set enrichment analyses revealed Fbw7-associated pathways that were conserved across both cell types that may reflect fundamental Fbw7 functions. These analyses provide a framework for understanding normal and neoplastic context-specific Fbw7 functions.

Neural G0: a quiescent-like state found in neuroepithelial-derived cells and glioma

Single‐cell RNA sequencing has emerged as a powerful tool for resolving cellular states associated with normal and maligned developmental processes. Here, we used scRNA‐seq to examine the cell cycle states of expanding human neural stem cells (hNSCs). From these data, we constructed a cell cycle classifier that identifies traditional cell cycle phases and a putative quiescent‐like state in neuroepithelial‐derived cell types during mammalian neurogenesis and in gliomas. The Neural G0 markers are enriched with quiescent NSC genes and other neurodevelopmental markers found in non‐dividing neural progenitors. Putative glioblastoma stem‐like cells were significantly enriched in the Neural G0 cell population. Neural G0 cell populations and gene expression are significantly associated with less aggressive tumors and extended patient survival for gliomas. Genetic screens to identify modulators of Neural G0 revealed that knockout of genes associated with the Hippo/Yap and p53 pathways diminished Neural G0 in vitro, resulting in faster G1 transit, down‐regulation of quiescence‐associated markers, and loss of Neural G0 gene expression. Thus, Neural G0 represents a dynamic quiescent‐like state found in neuroepithelial‐derived cells and gliomas.

BuGZ facilitates loading of spindle assembly checkpoint proteins to kinetochores in early mitosis

BuGZ is a kinetochore component that binds to and stabilizes Bub3, a key player in mitotic spindle assembly checkpoint signaling. Bub3 is required for kinetochore recruitment of Bub1 and BubR1, two proteins that have essential and distinct roles in the checkpoint. Both Bub1 and BubR1 localize to kinetochores through interactions with Bub3, which are mediated through conserved GLEBS domains in both Bub1 and BubR1. BuGZ also has a GLEBS domain, which is required for its kinetochore localization as well, presumably mediated through Bub3 binding. Although much is understood about the requirements for Bub1 and BubR1 interaction with Bub3 and kinetochores, much less is known regarding BuGZ's requirements. Here, we used a series of mutants to demonstrate that BuGZ kinetochore localization requires only its core GLEBS domain, which is distinct from the requirements for both Bub1 and BubR1. Furthermore, we found that the kinetics of Bub1, BubR1, and BuGZ loading to kinetochores differ, with BuGZ localizing prior to BubR1 and Bub1. To better understand how complexes containing Bub3 and its binding partners are loaded to kinetochores, we carried out size-exclusion chromatography and analyzed Bub3-containing complexes from cells under different spindle assembly checkpoint signaling conditions. We found that prior to kinetochore formation, Bub3 is complexed with BuGZ but not Bub1 or BubR1. Our results point to a model in which BuGZ stabilizes Bub3 and promotes Bub3 loading onto kinetochores in early mitosis, which, in turn, facilitates Bub1 and BubR1 kinetochore recruitment and spindle assembly checkpoint signaling.

A simple and highly efficient method for multi-allelic CRISPR-Cas9 editing in primary cell cultures

BACKGROUND

CRISPR-Cas9-based technologies have revolutionized experimental manipulation of mammalian genomes. None-the-less, limitations of the delivery and efficacy of these technologies restrict their application in primary cells.

AIMS

To create an optimized protocol for penetrant, reproducible, and fast targeted genome editing in cell cultures derived from primary cells, using patient-derived glioblastoma stem-like cells (GSCs) and human neural stem/progenitor cells (NSCs) for proof-of-concept experiments.

METHODS AND RESULTS

We employed transient nucleofection of Cas9:sgRNA ribonucleoprotein complexes composed of chemically synthesized 2'-O-methyl 3'phosphorothioate-modified sgRNAs and purified Cas9 protein. Insertion-deletion mutation (indel) frequency and size distribution were measured via computational deconvolution of Sanger sequencing trace data. We found that this optimized technique routinely allows for >90% indel formation in only 3 days, without the need to create clonal lines for simple loss-of-function experiments. Using Western blotting, we observed near-total protein loss of target genes in cell pools. Additionally, we found that this approach allows for the creation of targeted genomic deletions. Furthermore, by using RNA-seq in edited NSCs to assess gene expression changes resulting from knockout of tumor suppressors commonly altered in glioblastoma, we also demonstrated the utility of this method for quickly creating a series of gene knockouts that allow for the study of oncogenic activities.

CONCLUSION

Our data suggest that this relatively simple method can be used for highly efficient and fast gene knockout, as well as for targeted genomic deletions, even in hyperdiploid cells (such as GSCs). This represents an extremely useful tool for the cancer research community when wishing to inactivate not only coding genes, but also non-coding RNAs, UTRs, enhancers, and promoters. This method can be readily applied to diverse cell types by varying the nucleofection conditions.

Histone deposition pathways determine the chromatin landscapes of H3.1 and H3.3 K27M oncohistones

Lysine 27-to-methionine (K27M) mutations in the H3.1 or H3.3 histone genes are characteristic of pediatric diffuse midline gliomas (DMGs). These oncohistone mutations dominantly inhibit histone H3K27 trimethylation and silencing, but it is unknown how oncohistone type affects gliomagenesis. We show that the genomic distributions of H3.1 and H3.3 oncohistones in human patient-derived DMG cells are consistent with the DNAreplication-coupled deposition of histone H3.1 and the predominant replication-independent deposition of histone H3.3. Although H3K27 trimethylation is reduced for both oncohistone types, H3.3K27M-bearing cells retain some domains, and only H3.1K27M-bearing cells lack H3K27 trimethylation. Neither oncohistone interferes with PRC2 binding. Using Drosophila as a model, we demonstrate that inhibition of H3K27 trimethylation occurs only when H3K27M oncohistones are deposited into chromatin and only when expressed in cycling cells. We propose that oncohistones inhibit the H3K27 methyltransferase as chromatin patterns are being duplicated in proliferating cells, predisposing them to tumorigenesis.

Efficient Multi-Allelic Genome Editing of Primary Cell Cultures via CRISPR-Cas9 Ribonucleoprotein Nucleofection

CRISPR-Cas9-based technologies have revolutionized experimental manipulation of mammalian genomes. However, limitations regarding the delivery and efficacy of these technologies restrict their application in primary cells. This article describes a protocol for penetrant, reproducible, and fast CRISPR-Cas9 genome editing in cell cultures derived from primary cells. The protocol employs transient nucleofection of ribonucleoprotein complexes composed of chemically synthesized 2'-O-methyl-3'phosphorothioate-modified single guide RNAs (sgRNAs) and purified Cas9 protein. It can be used both for targeted insertion-deletion mutation (indel) formation at up to >90% efficiency (via use of a single sgRNA) and for targeted deletion of genomic regions (via combined use of multiple sgRNAs). This article provides examples of the nucleofection buffer and programs that are optimal for patient-derived glioblastoma (GBM) stem-like cells (GSCs) and human neural stem/progenitor cells (NSCs), but the protocol can be readily applied to other primary cell cultures by modifying the nucleofection conditions. In summary, this is a relatively simple method that can be used for highly efficient and fast gene knockout, as well as for targeted genomic deletions, even in hyperdiploid cells such as many cancer stem-like cells. © 2020 Wiley Periodicals LLC Basic Protocol: Cas9:sgRNA ribonucleoprotein nucleofection for insertion-deletion (indel) mutation and genomic deletion generation in primary cell cultures.

Comparison of tumor-associated YAP1 fusions identifies a recurrent set of functions critical for oncogenesis

YAP1 is a transcriptional coactivator and the principal effector of the Hippo signaling pathway, which is causally implicated in human cancer. Several YAP1 gene fusions have been identified in various human cancers and identifying the essential components of this family of gene fusions has significant therapeutic value. Here, we show that the YAP1 gene fusions YAP1-MAMLD1, YAP1-FAM118B, YAP1-TFE3, and YAP1-SS18 are oncogenic in mice. Using reporter assays, RNA-seq, ChIP-seq, and loss-of-function mutations, we can show that all of these YAP1 fusion proteins exert TEAD-dependent YAP activity, while some also exert activity of the C'-terminal fusion partner. The YAP activity of the different YAP1 fusions is resistant to negative Hippo pathway regulation due to constitutive nuclear localization and resistance to degradation of the YAP1 fusion proteins. Genetic disruption of the TEAD-binding domain of these oncogenic YAP1 fusions is sufficient to inhibit tumor formation in vivo, while pharmacological inhibition of the YAP1-TEAD interaction inhibits the growth of YAP1 fusion-expressing cell lines in vitro. These results highlight TEAD-dependent YAP activity found in these gene fusions as critical for oncogenesis and implicate these YAP functions as potential therapeutic targets in YAP1 fusion-positive tumors.

A kinase-deficient NTRK2 splice variant predominates in glioma and amplifies several oncogenic signaling pathways

Independent scientific achievements have led to the discovery of aberrant splicing patterns in oncogenesis, while more recent advances have uncovered novel gene fusions involving neurotrophic tyrosine receptor kinases (NTRKs) in gliomas. The exploration of NTRK splice variants in normal and neoplastic brain provides an intersection of these two rapidly evolving fields. Tropomyosin receptor kinase B (TrkB), encoded NTRK2, is known for critical roles in neuronal survival, differentiation, molecular properties associated with memory, and exhibits intricate splicing patterns and post-translational modifications. Here, we show a role for a truncated NTRK2 splice variant, TrkB.T1, in human glioma. TrkB.T1 enhances PDGF-driven gliomas in vivo, augments PDGF-induced Akt and STAT3 signaling in vitro, while next generation sequencing broadly implicates TrkB.T1 in the PI3K signaling cascades in a ligand-independent fashion. These TrkB.T1 findings highlight the importance of expanding upon whole gene and gene fusion analyses to include splice variants in basic and translational neuro-oncology research.

Tropomyosin receptor kinase B (TrkB), encoded by the neurotrophic tyrosine receptor kinase 2 (NTRK2) gene, exhibits intricate splicing patterns and post-translational modifications. Here, the authors perform whole gene and transcript-level analyses and report the TrkB.T1 splice variant enhances PDGF-driven gliomas in vivo and augments PI3K signaling cascades in vitro.

N6-methyladenosine mRNA marking promotes selective translation of regulons required for human erythropoiesis

Many of the regulatory features governing erythrocyte specification, maturation, and associated disorders remain enigmatic. To identify new regulators of erythropoiesis, we utilize a functional genomic screen for genes affecting expression of the erythroid marker CD235a/GYPA. Among validating hits are genes coding for the N6-methyladenosine (m6A) mRNA methyltransferase (MTase) complex, including, METTL14, METTL3, and WTAP. We demonstrate that m6A MTase activity promotes erythroid gene expression programs through selective translation of ~300 m6A marked mRNAs, including those coding for SETD histone methyltransferases, ribosomal components, and polyA RNA binding proteins. Remarkably, loss of m6A marks results in dramatic loss of H3K4me3 marks across key erythroid-specific KLF1 transcriptional targets (e.g., Heme biosynthesis genes). Further, each m6A MTase subunit and a subset of their mRNAs targets are required for human erythroid specification in primary bone-marrow derived progenitors. Thus, m6A mRNA marks promote the translation of a network of genes required for human erythropoiesis.

Molecular determinants of response to high-dose androgen therapy in prostate cancer

Clinical trials of high-dose androgen (HDA) therapy for prostate cancer (PC) have shown promising efficacy but are limited by lack of criteria to identify likely responders. To elucidate factors that govern the growth-repressive effects of HDAs, we applied an unbiased integrative approach using genetic screens and transcriptional profiling of PC cells with or without demonstrated phenotypic sensitivity to androgen-mediated growth repression. Through this comprehensive analysis, we identified genetic events and related signaling networks that determine the response to both HDA and androgen withdrawal. We applied these findings to develop a gene signature that may serve as an early indicator of treatment response and identify men with tumors that are amenable to HDA therapy.

PIP4K2A as a negative regulator of PI3K in PTEN-deficient glioblastoma

Glioblastoma (GBM) is the most malignant brain tumor with profound genomic alterations. Tumor suppressor genes regulate multiple signaling networks that restrict cellular proliferation and present barriers to malignant transformation. While bona fide tumor suppressors such as PTEN and TP53 often undergo inactivation due to mutations, there are several genes for which genomic deletion is the primary route for tumor progression. To functionally identify putative tumor suppressors in GBM, we employed in vivo RNAi screening using patient-derived xenograft models. Here, we identified PIP4K2A, whose functional role and clinical relevance remain unexplored in GBM. We discovered that PIP4K2A negatively regulates phosphoinositide 3-kinase (PI3K) signaling via p85/p110 component degradation in PTEN-deficient GBMs and specifically targets p85 for proteasome-mediated degradation. Overexpression of PIP4K2A suppressed cellular and clonogenic growth in vitro and impeded tumor growth in vivo. Our results unravel a novel tumor-suppressive role of PIP4K2A for the first time and support the feasibility of combining oncogenomics with in vivo RNAi screen.

Folliculin regulates mTORC1/2 and WNT pathways in early human pluripotency

To reveal how cells exit human pluripotency, we designed a CRISPR-Cas9 screen exploiting the metabolic and epigenetic differences between naïve and primed pluripotent cells. We identify the tumor suppressor, Folliculin(FLCN) as a critical gene required for the exit from human pluripotency. Here we show that FLCN Knock-out (KO) hESCs maintain the naïve pluripotent state but cannot exit the state since the critical transcription factor TFE3 remains active in the nucleus. TFE3 targets up-regulated in FLCN KO exit assay are members of Wnt pathway and ESRRB. Treatment of FLCN KO hESC with a Wnt inhibitor, but not ESRRB/FLCN double mutant, rescues the cells, allowing the exit from the naïve state. Using co-immunoprecipitation and mass spectrometry analysis we identify unique FLCN binding partners. The interactions of FLCN with components of the mTOR pathway (mTORC1 and mTORC2) reveal a mechanism of FLCN function during exit from naïve pluripotency.

The pathways involved in exit from pluripotency in human embryonic stem cells are poorly understood. Here, the authors performed a CRISPR-based screen to identify genes that promote exit from naïve pluripotency and find a role for folliculin (FLCN) by regulating the mTOR and Wnt pathways.

Abstract 413: Emerging principles in synthetic lethality in glioblastoma

Synthetic lethality occurs when mutations in two otherwise nonessential genes are combined to cause lethality. Because cancer is a disease of genetic alteration, synthetic lethality has been heralded as a method to identity candidate therapeutic targets, e.g., where a target gene could be "synthetic lethal" with a cancer driver mutation. To define synthetic lethal relationships in glioblastoma (GBM), we have performed multiple focused-set and genome-wide CRISPR-Cas9 lethality screens in patient-derived GBM stem-like cells (GSCs) and nontransformed human neural progenitor cells. Because GSCs isolates likely represent a sub-clone of the original tumor and we can determine GSCs' genetic and epigenetic makeup, it is possible to address the concept of synthetic lethality for GBM. To this end, we recently performed comprehensive CRISPR-Cas9 retests of all scoring GBM lethal genes (>900) from screens in three patient isolates with different and overlapping genetic drivers. We then performed secondary retests of high-priority gene targets in 13 GSC harboring various alterations commonly found in GBMs, e.g., EGFRamp, NF1mut, PIK3CAmut, PTENloss/mut, TP53mut, etc. The results were surprising, first in what we did not find. We failed to find synthetic lethal targets for TP53loss/mut, RB1mut, or TERT expression, suggesting that synthetic lethal relationships for these alterations may not exist for GBM. Second, NF1mut interactors defined a broader class of synthetic lethal targets with general overactivity of the RTK/Ras pathway, which can arise from various activating lesions. Third, candidate synthetic lethal relationships can be observed, but, so far, only with EGFRamp, MYC/MYCNamp, and PTEN/PIK3CA alterations. Thus, in general our results suggest that the majority of synthetic lethal relationships in GBM arise from oncogenic activation of the RTK/Ras and PI-3 kinase pathway or amplification of MYC/MYCN. (Synthetic lethal targets will be revealed and discussed at the meeting.)

Citation Format: Pia Hoellerbauer, Sonali Arora, Megan Kufeld, Lucas Carter, Emily J. Girard, Heather Feldman, Philip Corrin, James M. Olson, Patrick J. Paddison. Emerging principles in synthetic lethality in glioblastoma [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 413.

ZNF131 suppresses centrosome fragmentation in glioblastoma stem-like cells through regulation of HAUS5

Zinc finger domain genes comprise ∼3% of the human genome, yet many of their functions remain unknown. Here we investigated roles for the vertebrate-specific BTB domain zinc finger gene ZNF131 in the context of human brain tumors. We report that ZNF131 is broadly required for Glioblastoma stem-like cell (GSC) viability, but dispensable for neural progenitor cell (NPC) viability. Examination of gene expression changes after ZNF131 knockdown (kd) revealed that ZNF131 activity notably promotes expression of Joubert Syndrome ciliopathy genes, including KIF7, NPHP1, and TMEM237, as well as HAUS5, a component of Augmin/HAUS complex that facilitates microtubule nucleation along the mitotic spindle. Of these genes only kd of HAUS5 displayed GSC-specific viability loss. Critically, HAUS5 ectopic expression was sufficient to suppress viability defects of ZNF131 kd cells. Moreover, ZNF131 and HAUS5 kd phenocopied each other in GSCs, each causing: mitotic arrest, centrosome fragmentation, loss of Augmin/HAUS complex on the mitotic spindle, and loss of GSC self-renewal and tumor formation capacity. In control NPCs, we observed centrosome fragmentation and lethality only when HAUS5 kd was combined with kd of HAUS2 or HAUS4, demonstrating that the complex is essential in NPCs, but that GSCs have heightened requirement. Our results suggest that GSCs differentially rely on ZNF131-dependent expression of HAUS5 as well as the Augmin/HAUS complex activity to maintain the integrity of centrosome function and viability.

Abstract B14: Precision functional genomics for glioblastoma: Identifying molecular therapeutic targets using CRISPR-Cas9 and RNAi technologies in patient isolates

Glioblastoma (GBM) is the most aggressive and common form of adult brain cancer and is among the deadliest cancers, with a median survival of 15 months using standard-of-care therapies. Thus, improved treatments for GBM are desperately needed. To identify new GBM molecular therapeutic targets, our group has performed multiple functional genetic screens in patient-derived GBM stem-like cells (GSCs) and non-transformed human neural stem and progenitor cells (NPCs), which represent non-neoplastic controls. These screens, which have used both RNAi and CRISPR-Cas9 platforms, have led to the identification of several key molecular vulnerabilities in GSCs, including GBM-specific defects in: 3' splice site recognition, kinetochore function, and loss of redundancy between the kinase activities of PKMYT1 and WEE1. At this meeting we will present an overview of these studies, as well as our current efforts to: comprehensively retest all GBM-specific vulnerabilities scoring in these screens; address whether vulnerabilities arise from specific genetic alterations in patient samples (e.g. NF1 loss or PTEN loss); determine whether inhibition of specific molecular targets blocks tumor growth and/or maintenance; and demonstrate the mode of GBM-specific death for particular targets (e.g., cell cycle arrest, apoptosis, etc). In addition, we will highlight both strengths and limitations of applications of CRISPR-Cas9 technologies in patient samples. Collectively, our work illustrates the power of combining functional genetic technologies with the use of patient isolates to identify novel, patient-specific therapeutic strategies for GBM.

Citation Format: Pia Hoellerbauer, Heather Feldman, Sonali Arora, Lucas Carter, Emily J. Girard, Philip Corrin, James M. Olson, Eric C. Holland, Patrick J. Paddison. Precision functional genomics for glioblastoma: Identifying molecular therapeutic targets using CRISPR-Cas9 and RNAi technologies in patient isolates [abstract]. In: Proceedings of the AACR Precision Medicine Series: Opportunities and Challenges of Exploiting Synthetic Lethality in Cancer; Jan 4-7, 2017; San Diego, CA. Philadelphia (PA): AACR; Mol Cancer Ther 2017;16(10 Suppl):Abstract nr B14.

Transcription elongation factors represent in vivo cancer dependencies in glioblastoma

Glioblastoma is a universally lethal cancer with a median survival time of approximately 15 months. Despite substantial efforts to define druggable targets, there are no therapeutic options that notably extend the lifespan of patients with glioblastoma. While previous work has largely focused on in vitro cellular models, here we demonstrate a more physiologically relevant approach to target discovery in glioblastoma. We adapted pooled RNA interference (RNAi) screening technology for use in orthotopic patient-derived xenograft models, creating a high-throughput negative-selection screening platform in a functional in vivo tumour microenvironment. Using this approach, we performed parallel in vivo and in vitro screens and discovered that the chromatin and transcriptional regulators needed for cell survival in vivo are non-overlapping with those required in vitro. We identified transcription pause-release and elongation factors as one set of in vivo-specific cancer dependencies, and determined that these factors are necessary for enhancer-mediated transcriptional adaptations that enable cells to survive the tumour microenvironment. Our lead hit, JMJD6, mediates the upregulation of in vivo stress and stimulus response pathways through enhancer-mediated transcriptional pause-release, promoting cell survival specifically in vivo. Targeting JMJD6 or other identified elongation factors extends survival in orthotopic xenograft mouse models, suggesting that targeting transcription elongation machinery may be an effective therapeutic strategy for glioblastoma. More broadly, this study demonstrates the power of in vivo phenotypic screening to identify new classes of 'cancer dependencies' not identified by previous in vitro approaches, and could supply new opportunities for therapeutic intervention.

Abstract 3200: Targeting PHF5A for the treatment of glioblastoma and other Myc-driven cancers

Glioblastoma multiforme (GBM) is one of the most aggressive and invasive types of brain cancer, but targeted treatment options remain elusive. The standard of care (surgery chemotherapy and radiation) falls far short of where it should be with two-year survival rates less than 10%. Using stem cell isolates from GBM patients, we found that perturbing PHF5A, a component of the spliceosome machinery, was lethal and caused hundreds of genes to be mis-spliced. These mis-splicing events included both exon skipping and intron inclusions. In contrast, similar levels of PHF5A suppression in normal control stem cells and astrocytes failed to induce cell death and mis-splicing, indicating that PHF5A plays a specific role in the cancer biology. Moreover, when normal astrocytes were transformed with the Myc oncogene, they became sensitive to PHF5A perturbation. Taken together, these results suggested that specifically inhibiting PHF5A would be an effective therapy for glioblastoma and other Myc-driven cancers. Specifically targeting PHF5A would also likely result in reduced side-effects seen with general spliceosome inhibitors. Unfortunately, there are currently no known inhibitors that target PHF5A.

In order to discovery novel PHF5A inhibitors, we created a mini-gene mis-splicing reporter assay that was sensitive to both general spliceosome inhibitors and PHF5A perturbation. In a 96-well assay format, the assay was robust with a 200-fold assay window and Z’ values over 0.8. Following miniaturization to a 1536-well format, we conducted a high throughput screening (HTS) campaign testing 450,000 small molecule compounds. The initial hits were retested and counter-screened yielding 381 confirmed actives and we are further interrogating these actives in secondary and tertiary assays. Future efforts will focus on developing an SAR of the lead and backup series and identifying potential liabilities that will be addressed, if necessary, in further lead optimization efforts. We are enthusiastic about the potential of developing a targeted PHF5A inhibitor as a novel and effective therapy for patients and their families fighting GBM and other Myc-driven cancers.

Citation Format: Andrew J. Mhyre, Shanon Turnbaugh, Shelli M. Morris, Hu Xin, Patrick J. Paddison, Marc Ferrer, James M. Olson. Targeting PHF5A for the treatment of glioblastoma and other Myc-driven cancers [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 3200. doi:10.1158/1538-7445.AM2017-3200

Ion channel expression patterns in glioblastoma stem cells with functional and therapeutic implications for malignancy

Ion channels and transporters have increasingly recognized roles in cancer progression through the regulation of cell proliferation, migration, and death. Glioblastoma stem-like cells (GSCs) are a source of tumor formation and recurrence in glioblastoma multiforme, a highly aggressive brain cancer, suggesting that ion channel expression may be perturbed in this population. However, little is known about the expression and functional relevance of ion channels that may contribute to GSC malignancy. Using RNA sequencing, we assessed the enrichment of ion channels in GSC isolates and non-tumor neural cell types. We identified a unique set of GSC-enriched ion channels using differential expression analysis that is also associated with distinct gene mutation signatures. In support of potential clinical relevance, expression of selected GSC-enriched ion channels evaluated in human glioblastoma databases of The Cancer Genome Atlas and Ivy Glioblastoma Atlas Project correlated with patient survival times. Finally, genetic knockdown as well as pharmacological inhibition of individual or classes of GSC-enriched ion channels constrained growth of GSCs compared to normal neural stem cells. This first-in-kind global examination characterizes ion channels enriched in GSCs and explores their potential clinical relevance to glioblastoma molecular subtypes, gene mutations, survival outcomes, regional tumor expression, and experimental responses to loss-of-function. Together, the data support the potential biological and therapeutic impact of ion channels on GSC malignancy and provide strong rationale for further examination of their mechanistic and therapeutic importance.

Abstract B27: Kinetochore-microtubule attachments as a precision therapy target

Glioblastoma multiforme (GBM) is an aggressive and refractory cancer with limited therapeutic strategies and poor survival. One challenge in treating this disease is the ability of single glioblastoma stem-like cells (GSCs) to initiate tumors. To expand the therapeutic repertoire for GBM we performed RNAi screening in GSCs and a proposed cell of origin, neural crest stem cells (NSCs). In these screens we identified multiple regulators of kinetochore-microtubule attachments as specifically required for GSC survival. Kinetochores are composed of hundreds of proteins that form dynamic attachments between microtubules and chromosomes and are essential for genetic fidelity. Antimitotic agents, including those that target kinetochore proteins, are attractive therapeutics because cell division is essential for tumor expansion, but also because mitotic errors can trigger p53-independent apoptotic signals. However, as mitosis is an essential process, most antimitotic drugs have extremely limited therapeutic windows. We demonstrate that specific activities of the mitotic pseudokinase BubR1 are completely dispensable for non-transformed cells, yet become required for survival in a subset of GBM tumors. Through mutational studies we demonstrate that inactivating either BubR1's GLEBS or KARD domain causes lethal chromosome alignment defects in most GSCs and has no observable on-target toxicity in non-transformed cells. We further demonstrate that this cancer-specific requirement arises from oncogenic activation of the MAP kinase pathway, which ultimately hyperactivates Aurora B kinase at kinetochores. Increased phosphorylation of kinetochore proteins weakens their binding to microtubules and can be indirectly measured by a decrease in the distance between sister kinetochore pairs upon microtubule attachment. In limited samples, this measure serves as a functional biomarker for samples that require BubR1 for chromosome alignment. This work has identified multiple precision targets for GBM with dramatic therapeutic windows; moreover, we have initiated development of a biomarker to identify patients that would respond to such a therapy.

Citation Format: Jacob A. Herman, Patrick J. Paddison, Jennifer DeLuca, James Olson. Kinetochore-microtubule attachments as a precision therapy target. [abstract]. In: Proceedings of the AACR Precision Medicine Series: Cancer Cell Cycle - Tumor Progression and Therapeutic Response; Feb 28-Mar 2, 2016; Orlando, FL. Philadelphia (PA): AACR; Mol Cancer Res 2016;14(11_Suppl):Abstract nr B27.

Abstract 2523: Transcriptional profiling of glioblastoma stem-like cells reveals enrichment of ion channels with functional implications for malignancy

Glioblastoma Multiforme (GBM) is the most prevalent and aggressive form of cancer in the adult central nervous system. Ion channels are increasingly being linked to cancer progression through the regulation of cell proliferation and migration. However, the role of ion channels in GBM tumor formation and progression is not well understood. Glioblastoma stem-like cells (GSCs) are a source of tumor formation and recurrence, suggesting that ion channel expression may be perturbed in this population. Here, we used RNA-sequencing to assess the expression patterns of ion channels and transporters and identify uniquely enriched ion channels in GSCs. Twenty-two patient-derived GSC samples were expression profiled along with human neural stem cell (NSC) and astrocyte control cell populations. Differential expression analysis revealed a set of ion channels highly enriched in GSCs compared with controls. Real-time PCR analysis confirmed the increased expression of ion channels of interest across selected GSC lines compared to NSCs. The expression pattern of ion channel candidates was also more likely to be associated with distinct GBM molecular subtypes. Next, an integrative approach was taken to further identify ion channels unique to GSCs; the abovementioned findings were compared to results from transcriptome analyses of GBM bulk tumor cells (The Cancer Genome Atlas) and region-specific GBM cells (Ivy Glioblastoma Atlas Project). Ion channels that were identified in these analyses were associated with altered clinical outcomes. The functional implications of these expression changes were further assessed with targeted drug screening of GSCs and NSCs. Pharmacological antagonists of GSC-enriched ion channels suppressed stem cell viability. These antagonists similarly hindered BrdU incorporation of dividing GSCs, suggesting that these channels play a role in stem cell proliferative capacity. Finally, calcium imaging was used to test the real-time functional responses of GSCs to channel blockers, and these outcomes will be discussed. Collectively, these findings suggest the presence of ion channels that uniquely identify GSCs from other neural cell types and influence GSC proliferation, a hallmark of GBM tumor recurrence.

Citation Format: Julia Pollak, Karan G. Rai, Patrick J. Paddison, Robert C. Rostomily, Jan-Marino Ramirez. Transcriptional profiling of glioblastoma stem-like cells reveals enrichment of ion channels with functional implications for malignancy. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 2523.

Causal Mechanistic Regulatory Network for Glioblastoma Deciphered Using Systems Genetics Network Analysis

We developed the transcription factor (TF)-target gene database and the Systems Genetics Network Analysis (SYGNAL) pipeline to decipher transcriptional regulatory networks from multi-omic and clinical patient data, and we applied these tools to 422 patients with glioblastoma multiforme (GBM). The resulting gbmSYGNAL network predicted 112 somatically mutated genes or pathways that act through 74 TFs and 37 microRNAs (miRNAs) (67 not previously associated with GBM) to dysregulate 237 distinct co-regulated gene modules associated with patient survival or oncogenic processes. The regulatory predictions were associated to cancer phenotypes using CRISPR-Cas9 and small RNA perturbation studies and also demonstrated GBM specificity. Two pairwise combinations (ETV6-NFKB1 and romidepsin-miR-486-3p) predicted by the gbmSYGNAL network had synergistic anti-proliferative effects. Finally, the network revealed that mutations in NF1 and PIK3CA modulate IRF1-mediated regulation of MHC class I antigen processing and presentation genes to increase tumor lymphocyte infiltration and worsen prognosis. Importantly, SYGNAL is widely applicable for integrating genomic and transcriptomic measurements from other human cohorts.

In vivo RNAi screen identifies NLK as a negative regulator of mesenchymal activity in glioblastoma

Glioblastoma (GBM) is the most lethal brain cancer with profound genomic alterations. While the bona fide tumor suppressor genes such as PTEN, NF1, and TP53 have high frequency of inactivating mutations, there may be the genes with GBM-suppressive roles for which genomic mutation is not a primary cause for inactivation. To identify such genes, we employed in vivo RNAi screening approach using the patient-derived GBM xenograft models. We found that Nemo-Like Kinase (NLK) negatively regulates mesenchymal activities, a characteristic of aggressive GBM, in part via inhibition of WNT/β-catenin signaling. Consistent with this, we found that NLK expression is especially low in a subset of GBMs that harbors high WNT/mesenchymal activities. Restoration of NLK inhibited WNT and mesenchymal activities, decreased clonogenic growth and survival, and impeded tumor growth in vivo. These data unravel a tumor suppressive role of NLK and support the feasibility of combining oncogenomics with in vivo RNAi screen.

CNS Anticancer Drug Discovery and Development Conference White Paper

Following the first CNS Anticancer Drug Discovery and Development Conference, the speakers from the first 4 sessions and organizers of the conference created this White Paper hoping to stimulate more and better CNS anticancer drug discovery and development. The first part of the White Paper reviews, comments, and, in some cases, expands on the 4 session areas critical to new drug development: pharmacological challenges, recent drug approaches, drug targets and discovery, and clinical paths. Following this concise review of the science and clinical aspects of new CNS anticancer drug discovery and development, we discuss, under the rubric "Accelerating Drug Discovery and Development for Brain Tumors," further reasons why the pharmaceutical industry and academia have failed to develop new anticancer drugs for CNS malignancies and what it will take to change the current status quo and develop the drugs so desperately needed by our patients with malignant CNS tumors. While this White Paper is not a formal roadmap to that end, it should be an educational guide to clinicians and scientists to help move a stagnant field forward.

Involvement of DDX6 gene in radio- and chemoresistance in glioblastoma

CCRT (concomitant chemotherapy and radiation therapy) is often used for glioblastoma multiforme (GBM) treatment after surgical therapy, however, patients treated with CCRT undergo poor prognosis due to development of treatment resistant recurrence. Many studies have been performed to overcome these problems and to discover genes influencing treatment resistance. To discover potential genes inducing CCRT resistance in GBM, we used whole genome screening by infecting shRNA pool in patient-derived cell. The cells infected ~8,000 shRNAs were implanted in mouse brain and treated RT/TMZ as in CCRT treated patients. We found DDX6 as the candidate gene for treatment resistance after screening and establishing DDX6 knock down cells for functional validation. Using these cells, we confirmed tumor associated ability of DDX6 in vitro and in vivo. Although proliferation improvement was not found, decreased DDX6 influenced upregulated clonogenic ability and resistant response against radiation treatment in vivo and in vitro. Taken together, we suggest that DDX6 discovered by using whole genome screening was responsible for radio- and chemoresistance in GBM.

Genome-wide CRISPR-Cas9 Screens Reveal Loss of Redundancy between PKMYT1 and WEE1 in Glioblastoma Stem-like Cells

To identify 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-Y15 phosphorylation and to promote timely completion of mitosis in NSCs. However, in GSCs, this redundancy is lost, most likely as a result of oncogenic signaling, causing GBM-specific lethality.

Abstract C159: Genome-wide CRISPR-Cas9 screens uncover therapeutic targets and tumor suppressor genes in glioblastoma multiforme

Precision oncology is currently based on the notion that genomic analysis of descriptive molecular signatures from patient tumors will lead to actionable therapeutic targets following the patient's arrival into the clinic. However, this approach has failed to deliver new effective treatments for glioblastoma multiforme (GBM), which is the most common and aggressive form of brain cancer; and thus, ∼90% of adult GBM patients receiving standard of care therapies continue to die within 2 years of diagnosis. In addition, this approach has neglected the importance for using functional genetics in precision oncology. To identify new therapeutic targets for GBM, we applied functional genetics to perform lethal genome-wide CRISPR-Cas9 knockout screens in patient-derived GBM stem-like cells (GSCs) and also non-transformed human neural stem cells (NSCs), non-neoplastic tissue of origin controls.

Here, we present our latest findings from these screens, which include multiple novel GBM-specific lethal genes that were validated by both in vitro and in vivo preclinical studies. Knockout of GBM-specific lethal genes, including the WEE1-like kinase, PKMYT1/Myt1, lead to lethality in GSCs, but not NSCs. Focused mechanistic studies revealed that PKMYT1 acts redundantly with WEE1 to phosphorylate CDK1-Y15 and to promote timely completion of mitosis in NSCs, but that this redundancy is lost in most GBM isolates and in NSCs harboring activated alleles of EGFR and AKT1, which are commonly altered signaling pathways in GBM. Moreover, PKMYT1 depletion in GSCs and genetically altered NSCs requiring PKMYT1 lead to cytokinesis failure and cell death during mitosis.

In addition to lethal genes, genes promoting in vitro expansion of NSCs upon knockout were examined. For this category, we validated multiple genes that are candidate tumor suppressors and involved in: the negative regulation of Hippo signaling, TP53 signaling, epigenetic regulation, promoting neural development, and other cellular functions. Knockout of these genes caused shortened cell cycle transit times and drastic growth advantages in NSCs, and in the case of CREBBP knockout, caused precious entry into S-phase and deregulation of cell cycle gene expression. The identification of these potential tumor suppressors here reveal new genetic drivers in glioma/GBM, which contributes to a growing body of work that will help redefine GBM gene signatures.

Furthermore, we found that the molecular signatures of pathways and genes commonly altered in GBM are not ideal GBM therapeutic targets since most of these targets failed to score as GBM-specific lethal hits in our knockout screens and likely are non-essential or essential in both the GSCs and NSCs. Nonetheless, these common GBM alterations give rise to cancer-specific vulnerabilities, which then lead to genes, such as PKMYT1, that are required to overcome functional impairments in cancer cells. Taken together, we demonstrated here that genomics and functional genetics are equally important for precision oncology, as the combination of both tools can identify genetically altered genes, cancer-specific therapeutic targets, and tumor suppressors. These results are part of a rapidly growing body of work by the science community that will one day allow oncologists to tailor therapies for each patient based upon his or her tumor genetic profile and characteristics.

Citation Format: Chad M. Toledo, Yu Ding, Pia Hoellerbauer, Ryan J. Davis, Ryan Basom, Emily J. Girard, Eunjee Lee, Philip Corrin, Hamid Bolouri, Jerry Davison, Qing Zhang, Do-Hyun Nam, Jeongwu Lee, Steven M. Pollard, Jun Zhu, Jeffery J. Delrow, Bruce E. Clurman, James M. Olson, Patrick J. Paddison. Genome-wide CRISPR-Cas9 screens uncover therapeutic targets and tumor suppressor genes in glioblastoma multiforme. [abstract]. In: Proceedings of the AACR-NCI-EORTC International Conference: Molecular Targets and Cancer Therapeutics; 2015 Nov 5-9; Boston, MA. Philadelphia (PA): AACR; Mol Cancer Ther 2015;14(12 Suppl 2):Abstract nr C159.

Abstract A02: Identification of distinct BUB1B-sensitive and -resistant subtypes of glioblastoma with prognostic value

Glioblastoma multiforme is the most aggressive and common form of brain cancer in adults. The combined analysis of functional genetics with glioblastoma (GBM) network modeling identified BUB1B, a critical mitotic spindle checkpoint player, as a new requirement of glioblastoma tumors to suppress lethal consequences of altered kinetochore (KT) (1). Here, we further collected GBM stem-like cells (GSCs) including both BUB1B-sensitive and -resistant isolates, and performed whole-transcriptome sequencing that capture gene expression levels of each GSC. Based on the expression signature associated with BUB1B-sensitiveness from GSCs, we propose a framework to predict BUB1B sensitiveness of GBM patients or cancer cell lines by using its expression profile. Our framework stratifies GBM patients into two distinct subtypes, BUB1B-sensitive and –resistant that significantly associated with worse and better prognosis using two independent glioblastoma cohort data sets (2,3).

The additional siRNA screens in BUB1B-sensitive, –resistant GSCs, and neuronal stem cell (NSC) provided us the genes specifically required for BUB1B-sensitive and –resistant GSCs expansion. By combining with GBM network, these genes allowed us to build subtype-specific regulatory networks, suggesting candidate subtype specific therapeutic targets for GBM. Additionally, we revealed BUB1B-sensitive subtypes were consistently sensitive to drugs targeting BRAF and EGRF based on predicted BUB1B-sensitiveness of glioma cancer cell lines.

Furthermore, to identify regulatory drivers that determine BUB1B-sensitivity subtypes, we performed exome-sequencing of GSCs, and integrated BUB1B sensitivity subtype specific somatic mutation with other genomic data of GBM patients including somatic mutation and copy number variation from The Cancer Genomic Atlas (TCGA). The integrated analysis using multiple data types allowed us to identify multiple putative driver that determine BUB1B sensitivity status. Taken together, our results demonstrate the potential of a classification of GBM by BUB1B sensitivity signatures for prognostication, the future development of targeted drugs, and identifying regulatory mechanisms underlying each BUB1B sensitivity subtype.

1. Ding, Y., Hubert, C.G., Herman, J., Corrin, P., Toledo, C.M., Skutt-Kakaria, K., Vazquez, J., Basom, R., Zhang, B., Risler, J.K. et al. (2013) Cancer-Specific requirement for BUB1B/BUBR1 in human brain tumor isolates and genetically transformed cells. Cancer discovery, 3, 198-211.

2. Gravendeel, L.A., Kouwenhoven, M.C., Gevaert, O., de Rooi, J.J., Stubbs, A.P., Duijm, J.E., Daemen, A., Bleeker, F.E., Bralten, L.B., Kloosterhof, N.K. et al. (2009) Intrinsic gene expression profiles of gliomas are a better predictor of survival than histology. Cancer research, 69, 9065-9072.

3. Brennan, C.W., Verhaak, R.G., McKenna, A., Campos, B., Noushmehr, H., Salama, S.R., Zheng, S., Chakravarty, D., Sanborn, J.Z., Berman, S.H. et al. (2013) The somatic genomic landscape of glioblastoma. Cell, 155, 462-477.

Citation Format: Eunjee Lee, Patrick J. Paddison, Jun Zhu. Identification of distinct BUB1B-sensitive and -resistant subtypes of glioblastoma with prognostic value. [abstract]. In: Proceedings of the AACR Special Conference: Advances in Brain Cancer Research; May 27-30, 2015; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2015;75(23 Suppl):Abstract nr A02.

Abstract 1106: Genome-wide CRISPR-Cas9 screens reveal candidate therapeutic targets and tumor suppressor genes for human glioma

Glioblastoma multiforme (GBM) is the most aggressive and common form of brain cancer in adults. There are currently no effective therapies for GBM. Even with standard of care treatments, such as surgery, radiation, and chemotherapy, ∼90% of adult patients die within 2 years of diagnosis. Our inability to develop new more effective therapies may arise from pre-clinical models that inadequately predict therapeutic window and the fact that many new GBM drugs are “hand-me-downs” from other cancers, not specifically developed for treating brain tumors. To identify patient-tailored drug targets for GBM, our group has performed a series of functional genetic screens in patient derived GBM stem-like cells (GSCs) and also non-transformed human neural stem cells (NSCs). GSCs retain tumor-initiating potential and tumor-specific genetic and epigenetic signatures, even during extended outgrowth in serum-free culture. NSCs represent non-transformed candidate cell of origin controls, which share similar gene expression signatures and identical in vitro growth conditions. Using these systems along with RNAi or CRISPR/Cas9 platforms, we have identified multiple molecular vulnerabilities specific to GSCs, which appear to be largely driven by oncogenic transformation, in processes ranging from kinetochore regulation to 3′ pre-mRNA splice site recognition. At this meeting, we present our latest findings from genome-wide CRISPR-Cas9 gene knockout screens in multiple GSC and NSC isolates. These include validation studies of patient tumor-lethal genes using gene knockout rather than gene knockdown technology. In addition, we will present validation studies of gene products growth limiting for NSC expansion/self-renewal from these screens, a subset of which are candidate tumor suppressors for glioma. Strengths and weaknesses of using gene editing technology and GSC isolates for identification of therapeutic targets will be discussed.

Citation Format: Yu Ding, Chad Toledo, Pia Hoellerbauer, Ryan Basom, Emily Girad, Eunjee Lee, Philip Corrin, Qi Lin, Xiao-Nan Li, Do-Hyun Nam, Jeongwu Lee, Jun Zhu, Steven Pollard, Jeffery Delrow, Jim Olson, Patrick J. Paddison. Genome-wide CRISPR-Cas9 screens reveal candidate therapeutic targets and tumor suppressor genes for human glioma. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 1106. doi:10.1158/1538-7445.AM2015-1106

Pathogenesis of ELANE-mutant severe neutropenia revealed by induced pluripotent stem cells

Severe congenital neutropenia (SCN) is often associated with inherited heterozygous point mutations in ELANE, which encodes neutrophil elastase (NE). However, a lack of appropriate models to recapitulate SCN has substantially hampered the understanding of the genetic etiology and pathobiology of this disease. To this end, we generated both normal and SCN patient-derived induced pluripotent stem cells (iPSCs), and performed genome editing and differentiation protocols that recapitulate the major features of granulopoiesis. Pathogenesis of ELANE point mutations was the result of promyelocyte death and differentiation arrest, and was associated with NE mislocalization and activation of the unfolded protein response/ER stress (UPR/ER stress). Similarly, high-dose G-CSF (or downstream signaling through AKT/BCL2) rescues the dysgranulopoietic defect in SCN patient-derived iPSCs through C/EBPβ-dependent emergency granulopoiesis. In contrast, sivelestat, an NE-specific small-molecule inhibitor, corrected dysgranulopoiesis by restoring normal intracellular NE localization in primary granules; ameliorating UPR/ER stress; increasing expression of CEBPA, but not CEBPB; and promoting promyelocyte survival and differentiation. Together, these data suggest that SCN disease pathogenesis includes NE mislocalization, which in turn triggers dysfunctional survival signaling and UPR/ER stress. This paradigm has the potential to be clinically exploited to achieve therapeutic responses using lower doses of G-CSF combined with targeting to correct NE mislocalization.

G9a/GLP-dependent H3K9me2 patterning alters chromatin structure at CpG islands in hematopoietic progenitors

Background

The formation of chromatin domains is an important step in lineage commitment. In human hematopoietic stem and progenitor cells (HSPCs), G9a/GLP-dependent H3K9me2 chromatin territories form de novo during lineage specification and are nucleated at punctate sites during lineage commitment. Here, we examined the patterning of G9a/GLP-dependent H3K9me2 in HSPCs and the consequences for chromatin structure.

Results

We profiled chromatin accessibility across the genome of HSPCs treated with either a small molecule inhibitor of G9a/GLP or DMSO. We observed that chromatin accessibility is dramatically altered at the regions of H3K9me2 nucleation. We have characterized the regions of H3K9me2 nucleation, with our analysis revealing that H3K9me2 is nucleated in HSPCs at CpG islands (CGIs) and CGI-like sequences across the genome. Our analysis furthermore revealed a bias of H3K9me2 nucleation towards regions with low rates of C- > T deamination, which typically lack DNA methylation. Lastly, we examined the interaction of H3K9me2 and DNA methylation and determined that chromatin accessibility changes upon loss of H3K9me2 are dependent on the presence of DNA methylation.

Conclusions

These results indicate that H3K9me2 nucleation is established at specific sequences that have base composition similar to CGIs. Our results furthermore indicate that H3K9me2 nucleation leads to local changes in chromatin accessibility and that H3K9me2 and DNA methylation work synergistically to regulate chromatin accessibility.

Molecular pathways: regulation and targeting of kinetochore-microtubule attachment in cancer

Kinetochores are large protein structures assembled on centromeric DNA during mitosis that bind to microtubules of the mitotic spindle to orchestrate and power chromosome movements. Deregulation of kinetochore-microtubule (KT-MT) attachments has been implicated in driving chromosome instability and cancer evolution; however, the nature and source of KT-MT attachment defects in cancer cells remain largely unknown. Here, we highlight recent findings suggesting that oncogene-driven changes in kinetochore regulation occur in glioblastoma multiforme (GBM) and possibly other cancers exhibiting chromosome instability, giving rise to novel therapeutic opportunities. In particular, we consider the GLE2p-binding sequence domains of BubR1 and the newly discovered BuGZ, two kinetochore-associated proteins, as candidate therapeutic targets for GBM.

BuGZ is required for Bub3 stability, Bub1 kinetochore function, and chromosome alignment

During mitosis, the spindle assembly checkpoint (SAC) monitors the attachment of kinetochores (KTs) to the plus ends of spindle microtubules (MTs) and prevents anaphase onset until chromosomes are aligned and KTs are under proper tension. Here, we identify a SAC component, BuGZ/ZNF207, from an RNAi viability screen in human glioblastoma multiforme (GBM) brain tumor stem cells. BuGZ binds to and stabilizes Bub3 during interphase and mitosis through a highly conserved GLE2p-binding sequence (GLEBS) domain. Inhibition of BuGZ results in loss of both Bub3 and its binding partner Bub1 from KTs, reduction of Bub1-dependent phosphorylation of centromeric histone H2A, attenuation of KT-based Aurora B kinase activity, and lethal chromosome congression defects in cancer cells. Phylogenetic analysis indicates that BuGZ orthologs are highly conserved among eukaryotes, but are conspicuously absent from budding and fission yeasts. These findings suggest that BuGZ has evolved to facilitate Bub3 activity and chromosome congression in higher eukaryotes.

A high-content small molecule screen identifies sensitivity of glioblastoma stem cells to inhibition of polo-like kinase 1

Glioblastoma multiforme (GBM) is the most common primary brain cancer in adults and there are few effective treatments. GBMs contain cells with molecular and cellular characteristics of neural stem cells that drive tumour growth. Here we compare responses of human glioblastoma-derived neural stem (GNS) cells and genetically normal neural stem (NS) cells to a panel of 160 small molecule kinase inhibitors. We used live-cell imaging and high content image analysis tools and identified JNJ-10198409 (J101) as an agent that induces mitotic arrest at prometaphase in GNS cells but not NS cells. Antibody microarrays and kinase profiling suggested that J101 responses are triggered by suppression of the active phosphorylated form of polo-like kinase 1 (Plk1) (phospho T210), with resultant spindle defects and arrest at prometaphase. We found that potent and specific Plk1 inhibitors already in clinical development (BI 2536, BI 6727 and GSK 461364) phenocopied J101 and were selective against GNS cells. Using a porcine brain endothelial cell blood-brain barrier model we also observed that these compounds exhibited greater blood-brain barrier permeability in vitro than J101. Our analysis of mouse mutant NS cells (INK4a/ARF(-/-), or p53(-/-)), as well as the acute genetic deletion of p53 from a conditional p53 floxed NS cell line, suggests that the sensitivity of GNS cells to BI 2536 or J101 may be explained by the lack of a p53-mediated compensatory pathway. Together these data indicate that GBM stem cells are acutely susceptible to proliferative disruption by Plk1 inhibitors and that such agents may have immediate therapeutic value.

Genome-wide RNAi screens in human brain tumor isolates reveal a novel viability requirement for PHF5A

To identify key regulators of human brain tumor maintenance and initiation, we performed multiple genome-wide RNAi screens in patient-derived glioblastoma multiforme (GBM) stem cells (GSCs). These screens identified the plant homeodomain (PHD)-finger domain protein PHF5A as differentially required for GSC expansion, as compared with untransformed neural stem cells (NSCs) and fibroblasts. Given PHF5A's known involvement in facilitating interactions between the U2 snRNP complex and ATP-dependent helicases, we examined cancer-specific roles in RNA splicing. We found that in GSCs, but not untransformed controls, PHF5A facilitates recognition of exons with unusual C-rich 3' splice sites in thousands of essential genes. PHF5A knockdown in GSCs, but not untransformed NSCs, astrocytes, or fibroblasts, inhibited splicing of these genes, leading to cell cycle arrest and loss of viability. Notably, pharmacologic inhibition of U2 snRNP activity phenocopied PHF5A knockdown in GSCs and also in NSCs or fibroblasts overexpressing MYC. Furthermore, PHF5A inhibition compromised GSC tumor formation in vivo and inhibited growth of established GBM patient-derived xenograft tumors. Our results demonstrate a novel viability requirement for PHF5A to maintain proper exon recognition in brain tumor-initiating cells and may provide new inroads for novel anti-GBM therapeutic strategies.

Abstract A20: Genome-wide RNAi screens in human brain tumor isolates reveal a novel viability requirement for PHF5A

To identify key regulators of human brain tumor maintenance and initiation, we performed multiple genome-wide RNAi screens in patient-derived glioblastoma multiforme (GBM) stem cells (GSCs). These screens identified the PHD-finger domain protein PHF5A as differentially required for GSC expansion gene, as compared to untransformed neural stem cells (NSCs) and fibroblasts. Given PHF5A's known involvement in facilitating interactions between the U2 snRNP complex and ATP-dependent helicases, we examined cancer-specific roles in RNA splicing. We find that in GSCs, but not untransformed controls, PHF5A facilitates recognition of exons with unusual C-rich 3' splice sites in thousands of essential genes. PHF5A knockdown in GSCs, but not untransformed NSCs, astrocytes, or fibroblasts, inhibited splicing of these genes, leading to cell cycle arrest and loss of viability. Notably, pharmacologic inhibition of U2 snRNP activity phenocopied PHF5A knockdown both in GSCs and in multiple genetically transformed cell types, suggesting that a cancer-specific requirement for PHF5A activity may be generalizable to a wide range of cancers. Furthermore, PHF5A inhibition compromises GSC tumor formation in vivo and dramatically inhibits the growth of established GBM patient-derived xenograft tumors. Together, this work demonstrates an additional mechanism for maintaining splicing fidelity in cancer cells and also suggests that PHF5A activity may provide new in-roads for novel anti-GBM therapeutic strategies.

Citation Format: Christopher G. Hubert, Robert K. Bradley, Yu Ding, Toledo M. Chad, Kyobi Skutt-Kakaria, Emily J. Girard, Jerry Davison, Jason Berndt, Philip Corrin, Ryan Basom, Jeffery J. Delrow, Thomas Webb, Steven M. Pollard, Jeongwu Lee, James M. Olson, Patrick J. Paddison. Genome-wide RNAi screens in human brain tumor isolates reveal a novel viability requirement for PHF5A. [abstract]. In: Proceedings of the AACR Precision Medicine Series: Synthetic Lethal Approaches to Cancer Vulnerabilities; May 17-20, 2013; Bellevue, WA. Philadelphia (PA): AACR; Mol Cancer Ther 2013;12(5 Suppl):Abstract nr A20.

Integrative network analysis of signaling in human CD34(+) hematopoietic progenitor cells by global phosphoproteomic profiling using TiO2 enrichment combined with 2D LC-MS/MS and pathway mapping

Protein kinase signaling regulates human hematopoietic stem/progenitor cell (HSPC) fate, yet little is known about critical pathway substrates. To address this, we have developed and applied a large-scale, empirically optimized phosphopeptide affinity enrichment strategy with high-throughput 2D LC-MS/MS screening to evaluate the phosphoproteome of an isolated human CD34(+) HSPC population. We first used hydrophilic interaction chromatography as a first dimension separation to separate and simplify protein digest mixtures into discrete fractions. Phosphopeptides were then enriched off-line using TiO2 -coated magnetic beads and subsequently detected online by C18 RP nanoflow HPLC using data-dependent MS/MS high-energy collision-activated dissociation fragmentation on a high-performance Orbitrap hybrid tandem mass spectrometer. We identified 15 533 unique phosphopeptides in 3574 putative phosphoproteins. Systematic computational analysis revealed biological pathways and phosphopeptide motifs enriched in CD34(+) HSPC that are markedly different from those observed in an analogous parallel analysis of isolated human T cells, pointing to the possible involvement of specific kinase-substrate relationships within activated cascades driving hematopoietic renewal, commitment, and differentiation.

Cancer-Specific requirement for BUB1B/BUBR1 in human brain tumor isolates and genetically transformed cells

To identify new candidate therapeutic targets for glioblastoma multiforme, we combined functional genetics and glioblastoma network modeling to identify kinases required for the growth of patient-derived brain tumor-initiating cells (BTIC) but that are dispensable to proliferating human neural stem cells (NSC). This approach yielded BUB1B/BUBR1, a critical mitotic spindle checkpoint player, as the top-scoring glioblastoma lethal kinase. Knockdown of BUB1B inhibited expansion of BTIC isolates, both in vitro and in vivo, without affecting proliferation of NSCs or astrocytes. Mechanistic studies revealed that BUB1B's GLE2p-binding sequence (GLEBS) domain activity is required to suppress lethal kinetochore-microtubule (KT-MT) attachment defects in glioblastoma isolates and genetically transformed cells with altered sister KT dynamics, which likely favor KT-MT instability. These results indicate that glioblastoma tumors have an added requirement for BUB1B to suppress lethal consequences of altered KT function and further suggest that sister KT measurements may predict cancer-specific sensitivity to BUB1B inhibition and perhaps other mitotic targets that affect KT-MT stability.

SIGNIFICANCE

Currently, no effective therapies are available for glioblastoma, the most frequent and aggressive brain tumor. Our results suggest that targeting the GLEBS domain activity of BUB1B may provide a therapeutic window for glioblastoma, as the GLEBS domain is nonessential in untransformed cells. Moreover, the results further suggest that sister KT distances at metaphase may predict sensitivity to anticancer therapeutics targeting KT function.

G9a/GLP-dependent histone H3K9me2 patterning during human hematopoietic stem cell lineage commitment

G9a and GLP are conserved protein methyltransferases that play key roles during mammalian development through mono- and dimethylation of histone H3 Lys 9 (H3K9me1/2), modifications associated with transcriptional repression. During embryogenesis, large H3K9me2 chromatin territories arise that have been proposed to reinforce lineage choice by affecting high-order chromatin structure. Here we report that in adult human hematopoietic stem and progenitor cells (HSPCs), H3K9me2 chromatin territories are absent in primitive cells and are formed de novo during lineage commitment. In committed HSPCs, G9a/GLP activity nucleates H3K9me2 marks at CpG islands and other genomic sites within genic regions, which then spread across most genic regions during differentiation. Immunofluorescence assays revealed the emergence of H3K9me2 nuclear speckles in committed HSPCs, consistent with progressive marking. Moreover, gene expression analysis indicated that G9a/GLP activity suppresses promiscuous transcription of lineage-affiliated genes and certain gene clusters, suggestive of regulation of HSPC chromatin structure. Remarkably, HSPCs continuously treated with UNC0638, a G9a/GLP small molecular inhibitor, better retain stem cell-like phenotypes and function during in vitro expansion. These results suggest that G9a/GLP activity promotes progressive H3K9me2 patterning during HSPC lineage specification and that its inhibition delays HSPC lineage commitment. They also inform clinical manipulation of donor-derived HSPCs.

Abstract 5118: A functional genetic approach in patient-derived glioblastoma stem cells reveals pre-mRNA splicing components to be cancer-lethal gene targets

Glioblastoma multiforme (GBM) is the most aggressive and common form of brain cancer in adults and is among the deadliest cancers with a median survival period of 12-14 months. This poor prognosis despite aggressive therapy underscores the need for novel therapeutic targets specifically required by GBM cells. Many GBM are thought to arise from a neural stem cell (NSC) origin and, consistent with this premise, tumor-initiating GBM stem cells (GSCs) isolated from patients retain the NSC-like phenotype and molecular profile of primary tumors. Importantly, unlike serum-cultured cell lines, GSCs retain the developmental potential and specific genetic mutations acquired as each patient's tumor progressed from its cell of origin. We hypothesized that these genetic alterations driving GBM growth might also give rise to unique molecular vulnerabilities within the cancer cells. To identify such novel gene targets required for GBM cell growth, but which are dispensable to normal cells, we performed genome-scale RNAi screens in multiple patient-derived GSC isolates and simultaneously counter-screened against primary untransformed human NSCs. From these results, we identified and validated the existence of GBM-lethal genes that, when inhibited, render patient GSCs sensitive to cellular stresses arising within these transformed cells. From these targets, we show that GSCs have an increased requirement for the expression and function of multiple specific members of the pre-mRNA splicing machinery. Notably, loss of specific key splicing proteins resulted in cell cycle arrest and subsequent cell death only in GSCs, identifying the spliceosome as a specific molecular vulnerability in GBM. New treatment strategies for this disease are urgently needed. The identification of spliceosomal proteins as essential for the growth and maintenance of GSCs both adds to our understanding of glioblastoma biology and suggests novel targets for therapeutic intervention.

Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr 5118. doi:1538-7445.AM2012-5118

Smarcc1/Baf155 couples self-renewal gene repression with changes in chromatin structure in mouse embryonic stem cells

Little is known about the molecular mechanism(s) governing differentiation decisions in embryonic stem cells (ESCs). To identify factors critical for ESC lineage formation, we carried out a functional genetic screen for factors affecting Nanog promoter activity during mESC differentiation. We report that members of the PBAF chromatin remodeling complex, including Smarca4/Brg1, Smarcb1/Baf47, Smarcc1/Baf155, and Smarce1/Baf57, are required for the repression of Nanog and other self-renewal gene expression upon mouse ESC (mESC) differentiation. Knockdown of Smarcc1 or Smarce1 suppressed loss of Nanog expression in multiple forms of differentiation. This effect occurred in the absence of self-renewal factors normally required for Nanog expression (e.g., Oct4), possibly indicating that changes in chromatin structure, rather than loss of self-renewal gene transcription per se, trigger differentiation. Consistent with this notion, mechanistic studies demonstrated that expression of Smarcc1 is necessary for heterochromatin formation and chromatin compaction during differentiation. Collectively, our data reveal that Smarcc1 plays important roles in facilitating mESCs differentiation by coupling gene repression with global and local changes in chromatin structure.

Genome-wide RNA-mediated interference screen identifies miR-19 targets in Notch-induced T-cell acute lymphoblastic leukaemia

MicroRNAs (miRNAs) have emerged as novel cancer genes. In particular, the miR-17-92 cluster, containing six individual miRNAs, is highly expressed in haematopoietic cancers and promotes lymphomagenesis in vivo. Clinical use of these findings hinges on isolating the oncogenic activity within the 17-92 cluster and defining its relevant target genes. Here we show that miR-19 is sufficient to promote leukaemogenesis in Notch1-induced T-cell acute lymphoblastic leukaemia (T-ALL) in vivo. In concord with the pathogenic importance of this interaction in T-ALL, we report a novel translocation that targets the 17-92 cluster and coincides with a second rearrangement that activates Notch1. To identify the miR-19 targets responsible for its oncogenic action, we conducted a large-scale short hairpin RNA screen for genes whose knockdown can phenocopy miR-19. Strikingly, the results of this screen were enriched for miR-19 target genes, and include Bim (Bcl2L11), AMP-activated kinase (Prkaa1) and the phosphatases Pten and PP2A (Ppp2r5e). Hence, an unbiased, functional genomics approach reveals a coordinate clampdown on several regulators of phosphatidylinositol-3-OH kinase-related survival signals by the leukaemogenic miR-19.