Abstract
The intrinsic drivers of migration in glioblastoma (GBM) are poorly understood. To better capture the native molecular imprint of GBM and its developmental context, here we isolate human stem cell populations from GBM (GSC) and germinal matrix tissues and map their chromatin accessibility via ATAC-seq. We uncover two distinct regulatory GSC signatures, a developmentally shared/proliferative and a tumor-specific/migratory one in which TEAD1/4 motifs are uniquely overrepresented. Using ChIP-PCR, we validate TEAD1 trans occupancy at accessibility sites within AQP4, EGFR, and CDH4. To further characterize TEAD’s functional role in GBM, we knockout TEAD1 or TEAD4 in patient-derived GBM lines using CRISPR-Cas9. TEAD1 ablation robustly diminishes migration, both in vitro and in vivo, and alters migratory and EMT transcriptome signatures with consistent downregulation of its target AQP4. TEAD1 overexpression restores AQP4 expression, and both TEAD1 and AQP4 overexpression rescue migratory deficits in TEAD1-knockout cells, implicating a direct regulatory role for TEAD1–AQP4 in GBM migration.
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Introduction
Glioblastoma (GBM) is the most common primary brain tumor in adults, carrying dismal prognosis despite aggressive treatment. The diffusely infiltrative nature of tumor growth in GBM greatly confounds surgical therapy, as infiltrative cells inevitably extend beyond the resection margin. Moreover, glioma cells away from the tumor’s contrast-enhancing core respond poorly to chemotherapy, and have been implicated in tumor recurrence1,2,3. Given the unique microenvironment and transcriptional signatures of tumor cells at the infiltrative edge vs. those at the tumor core4,5, the two populations are likely regulated by distinct molecular pathways.
Epigenetics is critical for allowing plasticity during normal stem-cell development and differentiation6,7 as well as for the maintenance of an aberrant cancer stem-cell state8,9,10. In GBM, chromatin remodeling supports the re-emergence of developmental programs in glioma stem cells (GSCs), leading to progressive tumor growth8,10,11,12,13,14,15. The regulatory promoter/enhancer regions at key developmentally driven oncogenes, such as the epidermal growth factor receptor (EGFR)16, are maintained in a poised or open chromatin state, enabling their accessibility for transcriptional dysregulation in GBM3. In this context, several transcriptional pathways and transcription factor (TF) drivers of cell proliferation have been uncovered in cultured GSC/tumor-initiating cells8,10,11,12,15, and in GSC populations prospectively isolated from human samples17.
Many studies have also identified TF regulators of migration and invasion in cultured GSCs or patient-derived xenografts (PDX) mouse glioma models18, including SMADs acting downstream of the TGFβ signaling pathway19, HIF1/2-alpha20,21, ZEB122,23, STAT324, C/EBPβ25, TWIST126, SNAIs27, and Id228. However, the extent to which these TFs modulate intrinsic cell migration in patients with GBM has been more difficult to discern, due to the complex adaptations of infiltrative tumor cells within their microenvironment for motility, adhesion, hypoxia, metabolism, and immune response1. To this end, transcriptome analysis of primary GBM samples defined STAT3 and C/EBPβ as master regulators of mesenchymal transformation29, a behavior typically associated with increased tumor infiltration and GBM recurrence; and ZEB1 was found to be significantly overexpressed in infiltrative vs. non-infiltrative glioma lesions22. Analysis of TFs in human GSC populations, directly isolated from their niche, may uncover additional intrinsic regulators of migration without the caveats of cell culture and intermixed normal brain parenchyma.
Here, we utilize a recently developed protocol for the prospective isolation of GSCs and neural stem/progenitor cells (NSPCs) directly from human GBM and germinal matrix (GM) tissues17,30 in order to study the intrinsic transcriptional regulators of tumorigenicity in a comparable developmental context. By contrasting chromatin accessibility in developing and neoplastic stem cell populations, we define transcriptionally accessible regions unique to GSCs that specifically relate to cell migration and which are highly enriched for TEAD1/4 motifs. We subsequently provide functional validation for the role of TEAD1 in GBM migration, both in vitro and in vivo, implicate several oncogenic binding targets of TEAD1, and show that TEAD1 directly regulates AQP4 expression to promote cell migration.
Results
Distinct chromatin accessibility regions in uncultured GSCs
Recent studies have highlighted striking similarities in chromatin plasticity between development and cancer, which support progressive GSC growth8,10,16,17. Yet, the two processes are clearly different: neural development is coordinated while glial tumors overtake the brain through uncontrolled growth and infiltrative spread. To better understand the similarities and differences between neural progenitors and GSCs, we performed comparative analysis of chromatin accessibility in acutely isolated human NSPC and GSC populations, using the assay for transposase-accessible chromatin with sequencing (ATAC-seq). ATAC-seq enables broad assessment of open chromatin using the ability of the Tn5 transposase to bind and tagment accessible nucleosome-free regions, accurately identifying regulatory regions for transcription in small populations of cells31. Human NSPCs were isolated from autopsy GM dissections, and GSCs from isocitrate dehydrogenase (IDH)-wildtype GBM surgical specimens, by fluorescence-activated cell sorting (FACS), based on their EGF ligand-binding ability (Fig. 1a, Supplementary Fig. 1); this purification strategy prospectively captures all sphere-forming and tumor-initiating EGF-bound cells in uncultured conditions17. ATAC-seq data were obtained from both EGF-bound (E+) and E− fractions extracted from GBM and GM tissues. We first aligned reads and defined all open chromatin regions (peaks) in our samples. The data showed comparable reads per peak frequency across samples and open chromatin distribution along the genome, with expected enrichment at promoters31,32 (Supplementary Fig. 2). We then performed a series of differential accessibility analyses. To specifically assess the developmental contributions of chromatin plasticity in GSCs, we compared the union of E+GSCs and E+NSPCs stem cell enriched populations to E−GBM sorted cells, the latter lacking stem cell properties in vitro or tumor initiation in vivo17. We obtained a defined set of 5020 differential peaks in both GSCs and NSPCs (Fig. 1b, Supplementary Data 1). Using the Genomic Regions Enrichment of Annotations Tool (GREAT)33, we annotated these peaks with their closest genes and then performed a functional enrichment analysis. The developmentally shared GSC/NSPC peak-associated genes related to biological processes of stem cell maintenance and proliferation (Fig. 1c), paralleling previously observed transcriptome similarities in these populations17. We then focused our analysis on the differences between GSC and NSPC, in an effort to define regulatory elements that are unique to the tumor stem cell phenotype. To do so, we performed differential accessibility analysis in E+GSCs vs. all other cell populations (the union of NSPCs and E−GBMs). This analysis defined a set of 10,509 peaks specifically enriched in tumoral GSCs, corresponding to 4015 protein-coding genes (Fig. 1d, Supplementary Data 1), which showed remarkable association with cell migration, motility, and extracellular matrix (ECM) processes (Fig. 1e). Similar functional gene set associations were seen when comparing E+GSC to NSPC transcriptome (Supplementary Fig. 3a–b). Thus, by uniquely contrasting chromatin accessibility in GBM to early germinal growth, we were able to distinguish developmental and tumor-specific chromatin states within GSCs in uncultured conditions, and to define a regulatory signature that relates to GSC migration.
TEAD motifs are prioritized at GSC-specific open chromatin
Analysis of chromatin accessibility via ATAC-seq not only identifies regulatory regions for transcription, but can also infer TF activity within them31,32 and has been recently used to identify regulators of neuronal fate and de-differentiation in cultured GBM cells and cortical neural progenitors12,34,35. Given this, we set to define TF candidates at accessible chromatin regions in GSCs and GM NSPCs without cell culture exposure. Using the HOMER de novo motif-discovery algorithm, we identified a list of 27 and 26 TF motifs, significantly enriched within GSC tumor-specific or within developmentally shared peak sets, respectively, compared to all-peaks background (Fig. 2a, b, Supplementary Data 1). Of these, we only considered those motifs, which were exclusively enriched in only one of the two peak set analyses (in tumor-specific or in developmentally shared) but not in both (Fig. 2a, b, in bold). For example, NFIC was not considered because it was enriched at #4 in the tumor-specific analysis but also at #11 in the developmentally shared analysis. This highlighted TEAD1/4 as the most highly and uniquely overrepresented motifs in GSC tumor-specific peaks. Other top GSC tumor-specific candidates included ATF3, RFX1, SOX10, ATF2, EGR1, RORg, ZNF416, EBF1, FOXA1, etc. (Fig. 2a, in bold). In contrast, the most highly uniquely overrepresented TF motifs at developmentally shared GSC peaks included RFX5, LHX2, SOX1, IRF3, NFIA, ASCL2, SIX6, STAT6, POU6F2, SMAD4, etc. (Fig. 2b) and PAX6 (Supplementary Data 1). We then considered the gene expression levels of tumor-specific TF candidates, using previously generated RNA-seq data from similar E+/E–GBM cells17. Four TFs with enriched tumor-specific motifs showed high gene expression (top 25th percentile) of which only TEAD1 was differentially overexpressed in E+GSCs (Fig. 2c).
TEAD1 is the most highly expressed TEAD member across GBMs
To evaluate the relevance of TEAD1 across GBM subtypes, we analyzed the expression levels of all TEAD family members (1–4) in RNA-seq data obtained from The Cancer Genome Atlas (TCGA) database36,37. We found TEAD1 to be the most highly expressed TEAD family member across 150 primary GBM samples (Fig. 2d), which paralleled expression patterns observed in acutely isolated GSC populations (Fig. 2e). Of note, genes significantly coexpressed with TEAD1 in TCGA GBM samples were highly enriched for terms related to cell migration and cell adhesion (Supplementary Fig. 3c). At the protein level, we noted expression of TEAD1 but not of other TEAD members in PDX gliomas previously generated from acutely sorted GBM GSCs17 (Supplementary Fig. 4). Overall, this analysis prioritized TEAD1 as the most highly and widely expressed TEAD family member across GBM tumors.
Ablation of TEAD1/4 impairs migration in primary GBM lines
TEAD2/4 activity has been recently implicated in GBM motility and mesenchymal transformation38. However, the specific role of TEAD1, the most highly expressed TEAD member in GBM, remains undefined. To validate experimentally the role of TEAD1 in GBM migration, we generated stable population knockout of TEAD1, and its better studied paralog TEAD4, in patient-derived, low-passaged GBM cells, by using CRISPR-Cas9 genome editing to introduce loss-of-function mutations (Fig. 3a, Supplementary Fig. 5a–b). As a negative control, we generated a sham CRISPR-Cas9 knockout targeting the non-human GFP gene.
First, we assessed whether knockout (KO) of TEAD1 or TEAD4 affected GBM growth in vitro. Cell proliferation in serum-free conditions was evident in all groups at ~36 h after laminin attachment, and TEAD1KO cells were less proliferative compared to sham at 48–72 h after attachment (Fig. 3b). Under low attachment conditions, in the absence of a substrate, sham and TEAD1/4KO cells formed a similar number of spheres (Fig. 3c), but interestingly, TEAD1KO spheres were significantly smaller in size (Fig. 3d) and showed reduced frequency for self-renewal in extreme limited dilution assays (ELDA) (Supplementary Fig. 5c). We then assessed whether elimination of TEAD1 or TEAD4 affects cell migration at early time points, 24 and 36 h, when proliferation differences are not yet evident.
Genetic ablation of TEAD1 or TEAD4 resulted in substantial reduction of cell migration, compared to sham treatment, in two independent in vitro migration assays, the transwell invasion assay (Fig. 3e) and the spheroid dispersion assay (Fig. 3f, Supplementary Movies 1 and 2). To confirm the observed phenotype across additional GBM subtypes, we generated CRISPR-Cas9 population TEAD1 and TEAD4 knockouts in three additional primary GBM cell lines, G-13306, G-12746, and G-16302 (Supplementary Fig. 5d), representing various GBM molecular subtypes (Supplementary Table 1). We observed migratory deficits in these additional lines after knockout of TEAD1 or TEAD4 (Supplementary Fig. 5e–f). Finally, to test if TEAD1 activity is regulating cell migration directly, we overexpressed TEAD1 in TEAD1KO cells and assessed their spheroid migration behavior. TEAD1 overexpression rescued migration deficits in TEAD1KO spheroids by ~50% (Fig. 3g, Supplementary Movie 3), strengthening further the regulatory role of TEAD1 for GBM migration in vitro.
TEAD1-knockout GBM cells show infiltrative deficits in vivo
To confirm whether the anti-migratory deficits observed in cell culture are recapitulated in vivo, we performed orthotopic xenotransplantation using sham and TEAD1KO primary GBM cells, choosing the TEAD1KO line with the most robust in vitro anti-migratory effect. Histological analysis at 3.5 months after transplantation, a relatively early time point in PDX formation, confirmed tumor engraftment in both sham and TEAD1KO cells (Fig. 4a) as well as the stable loss of TEAD1 protein in TEAD1KO cells (Fig. 4b). Sham and TEAD1KO cells also showed similar cell proliferation index (Fig. 4c). In contrast, TEAD1KO cells displayed significant deficits in two and three-dimensional infiltrative tumor spread across the mouse brain, compared to sham (Fig. 4d). While sham cells had infiltrated extensively into the striatum, away from the tumor injection site, and across the corpus callosum, TEAD1KO cells were found primarily around the site of injection with only occasional infiltrative cells counted throughout the rest of the brain (11 serial coronal sections examined entirely) (Fig. 4d, e). This provided additional evidence for the role of TEAD1 in GBM migration and prompted further studies to define its downstream pro-migratory targets.
Validation of TEAD1 binding targets
The transcriptional targets of TEADs have been predominantly studied in tumors outside of the brain, where they have been implicated in tumor invasion, metastasis, and epithelial-to-mesenchymal transition (EMT)39,40,41,42,43,44. To embark on the complex characterization of TEAD1 targets in GBM migration, tumors known for their heterogeneous nature and unique diffusely infiltrative growth, we undertook two initial approaches: (1) analysis of putative TEAD1 targets ex vivo using parallel ATAC-seq and RNA-seq datasets generated from acutely isolated GSCs17 and (2) analysis of putative TEAD1 targets in vitro using TEAD1KO vs. Sham RNA-seq data generated from four different GBM cell lines.
For the first (ex vivo) analysis, we made the assumption that transcription and TF-chromatin accessibility are functionally linked, which was supported by the strong correspondence between moderate-high levels of gene expression and the presence of open chromatin within gene promoters in parallel RNA-seq and ATAC-seq E+GSC datasets (Fig. 5a). The most highly differentially expressed genes (log2(fold change) >3; E+GSCs vs. E-GBM+NSPCs analysis) with enriched TEAD-accessible chromatin peaks corresponded to WNT, Cadherin, EGFR, and metabolism-related signaling pathways, many of them previously implicated in tumor invasion18, and included EGFR, CDH4, TNC, AQP4, ETV1, ITGA7, ENO1, PCDHGC5, NRCAM, PTPRZ1, ACSBG1, MEOX2, OSMR, and ACSS3 (Supplementary Fig. 6a–b). Most of these genes were significantly coexpressed with TEAD1 in the TCGA GBM RNA-seq data analysis (Supplementary Data 2). We also considered the number of TEAD-associated peaks present within a gene with linked GSC overexpression and their TEAD motif scores. The highest number of peaks/gene, by far, was at EGFR (18), and five or more peaks were noted at NRCAM (9), the cadherins CDH2/4/11 (8), ETV1 (7), AQP4 (6), and TNC (5) (Supplementary Data 1). This analysis provided several potential (cis) binding targets for TEAD1 in acutely isolated GSC populations.
To validate whether the above TEAD1-associated loci are binding targets of TEAD1 in trans, we performed chromatin immunoprecipitation (ChIP-PCR) in human GBM tumors of different subtypes (Supplementary Table 1), using previously validated TEAD1 and TEAD4 antibodies38,39,45. We assessed several regulatory regions for which we had previously demonstrated chromatin accessibility peak enrichment associated with robust TEAD motif score (Fig. 5b). As an internal negative control, we also measured TEAD1 binding at a region lacking open chromatin16 and TEAD accessibility (EGFR IN2). ChIP-PCR detected significant enrichment of TEAD1 at TF-accessible regions associated with EGFR, AQP4, and CDH4 (Fig. 5c) but not with TNC, ETV1, NRCAM, CDH11, or CDH2 (Supplementary Fig. 6c). Accordingly, expression of the TEAD1-binding targets AQP4, CDH4, and EGFR was downregulated in TEAD1KO (but not in TEAD4KO) cells (Figs. 5d and 6a, b).
TEAD1 is a direct but transient regulator of EGFR in vitro
Given the known role of EGFR signaling in GBM tumorigenesis3, we focused further on the relationship between TEAD1 and EGFR activity. In vivo, we found co-expression of TEAD1 with EGFR in PDX GBM tumors (Supplementary Fig. 4a) and observed decreased expression of EGFR in TEAD1KO xenografts (Fig. 6a). In vitro, we detected decreased expression of EGFR after TEAD1 knockout, with a trend for partial rescue after TEAD1 overexpression (Fig. 6b). We extended our analysis to downstream EGFR signaling components and found consistent downregulation of pERK but not pAKT in TEAD1KO cells, compared to sham (Fig. 6c). The downregulation of EGFR in TEAD1KO cells, however, appeared to be transient. After several months of cell culture with growth factor supplementation, TEAD1KO cells regained EGFR expression but continued to show deficits in spheroid migration (Supplementary Fig. 6e, Supplementary Data 3). This indicated that TEAD1’s effect on EGFR expression is not directly related to cell migration in vitro and prompted a more global, agnostic search for TEAD1-dependent regulators within a migration-specific framework.
TEAD1 regulates migration by modulating AQP4 expression
To gain further insight into the regulatory targets of TEAD1 in the context of GBM migration, we analyzed RNA-seq data from sham, TEAD1KO, and TEAD4KO samples generated from four different cell lines (“overall target” analysis, Supplementary Fig. 7a) as well as from sham and TEAD1KO spheroids, the latter showing robust anti-migratory behavior (“migratory target” analysis, Supplementary Fig. 7b). Principal component analysis of all samples revealed expected clustering by patient-specific cell line (Supplementary Fig. 7a), as well as strong separation by migration phenotype in TEAD1KO vs. Sham spheroids (Supplementary Fig. 7b). Functional enrichment analysis of differentially downregulated TEAD1KO genes was statistically significant for terms related to cell migration and “EMT” gene set (Supplementary Fig. 7c–e). In contrast, differential analysis of TEAD4KO vs. Sham samples did not reveal a significant number of dysregulated genes (Supplementary Fig. 7c). To narrow down potential TEAD1 migratory targets that are relevant across GBM subtypes, we analyzed the intersection between TEAD1KO-dysregulated genes in the “overall target” and “migratory target” analyses. We found 392 overlapping genes, and out of all downregulated ones, 32 had TEAD-associated chromatin accessibility peaks (Fig. 7a). Again, we noted downregulation of several pro-migratory genes (Supplementary Data 3), including CDH1146 and AQP447,48,49, the latter also found to be a direct TEAD1 (trans)binding target in GBM, in vivo (Fig. 5).
To gain mechanistic insight into how TEAD1 regulates tumor migration, we overexpressed AQP4 and CDH11 in sham and TEAD1KO spheroids and studied their migratory behavior. Overexpression of either AQP4 or CDH11 partially restored confluent migration in TEAD1KO spheroids when grown under laminin plus PDL substrate (Fig. 7b, Supplementary Movies 4 and 5). In the case of AQP4 overexpression, migratory abilities of TEAD1KO cells improved by ~50%, recapitulating the effect seen after TEAD1 overexpression (Fig. 3g, Supplementary Movie 3). The effect of CDH11 overexpression was less pronounced but still significant. Notably, along with promoting spheroid migration, overexpression of TEAD1 also upregulated endogenous expression of AQP4 (Fig. 7c). In contrast, CDH11 expression was not rescued after TEAD1 overexpression (Supplementary Fig. 6d). Overall, these data provide further evidence that both AQP4 and CDH11 play a role in GBM migration. Importantly, it also demonstrates a direct mechanistic link between TEAD1 and downstream AQP4 expression for promoting migratory properties in primary GBM cells.
Discussion
Understanding the intrinsic molecular mechanisms that control GBM cell migration may uncover opportunities for more effective therapy aimed at inhibiting infiltration early in the disease course, in order to optimize surgical resection and chemoradiation. An attractive strategy to study the intricate biology of migration is to use epigenetics to define its transcriptional regulators in a system that recapitulates the cell’s native tumor state3,50. Here we hypothesized that the analysis of chromatin accessibility in glioma and neural stem cell populations, isolated prospectively from GBM and GM niches without prior culture or genetic manipulations, may capture some of the intrinsic and perhaps distinct TF drivers for cell migration in GSCs.
The recently described chromatin accessibility (ATAC-seq) assay allows for the high-resolution sequencing of TF-accessible chromatin in low number of cells, thus providing an ideal platform to infer TF activity in our rare, fresh tissue-derived human stem cell populations. Importantly, we had previously demonstrated that such FACS-isolated E+NSPC and E+GSC populations capture all sphere-forming cells in vitro, with the capacity for both self-renewal and tri-lineage differentiation, and that E+GSC populations are tumor-initiating in vivo, capable of re-forming GBM-like tumors after orthotopic xenotransplantation17. To hone in on the unique regulatory signature of GSCs and to minimize their heterogeneity, we computationally extracted the developmental and non-GSC chromatin contributions from the E+GSC ATAC-seq data, by performing differential peak analysis of E+GSC vs. E−GBM+NSPCs. By contrasting the chromatin landscape in tumor GSCs to that of the highly proliferative early GM progenitors, we were able to expose a unique regulatory signature in GSCs that specifically relates to tumoral cell migration. This analysis allowed us to uncover several enriched GSC-specific TF motifs, some of which had been previously implicated in GBM invasion51,52,53. We focused our downstream experimental validation studies on TEAD1, the most highly and uniquely overrepresented motif candidate within the migratory GSC accessibility signature, whose expression was highest among TEAD family members across the GBM TCGA database, yet its role in GBM tumorigenesis had not been previously established.
The oncogenic activity of TEAD proteins has been predominantly described outside of the CNS and in the context of Hippo pathway signaling, where their interaction with the transcriptional co-activators YAP/TAZ has been implicated in cell growth, invasion, EMT, and metastasis44. Well-characterized TEAD targets in non-CNS tumors include CTGF, Cyr61, MYC, CCNE1, AREG, and EGFR44,54,55. Our study uncovered that EGFR is also a downstream target of TEAD1 in GBM, likely through the direct binding of TEAD1 to an upstream promoter/enhancer region at EGFR. Curiously, in vitro the regulatory effect of TEAD1 on EGFR was transient, and not directly related to migration, while in vivo TEAD1-knockout xenografts showed low levels of EGFR after 3.5 months. The discrepancy may be related to the artificial EGF-driven growth conditions in cell culture and the redundancy of pathways driving EGFR signaling in the context of oncogenic addiction. We cannot exclude compensatory regulation by other TEAD family members as well. Several mechanisms of interaction between EGFR and Hippo pathway effectors YAP/TAZ-TEAD have been recently demonstrated in epithelial tumors55,56,57,58, some of which have been also implicated in tumor chemoresistance55,59,60,61. Whether EGFR also crosstalks with upstream members of the Hippo family in GBM, as seen with other tumors, remains to be determined in future studies.
Recent studies have implicated TEADs as master regulators of cell invasion in melanoma42. Few studies have also begun to investigate YAP-TEAD activity in GBM malignancy38,62,63,64,65,66,67,68. Specifically, disruption of TEAD2/4 binding to TAZ or shRNA-mediated knockdown of TAZ has been shown to result in deficient GBM cell migration38. Our study expands the current literature by also demonstrating a role for TEAD1 in GBM migration, using both in silico and functional analyses, the latter involving stable CRISPR-Cas9-mediated knockout of TEAD1/4 in primary GBM cultures. While both TEAD1- and TEAD4-knockout cells showed migratory deficits in vitro, TEAD1 was the most highly expressed TEAD member across TCGA GBM samples, underscoring its relevance under physiological conditions. Indeed, we found migratory deficits in TEAD1 knockout GBM cells not only in vitro but also in patient-derived xenografts, strengthening the role of this TF for promoting infiltrative spread in human glioblastoma.
To gain further insight into the downstream effectors of TEAD activity in GBM, we characterized extensively TEAD1/4’s transcriptome across four primary GBM lines and in the context of deficient migration. We discovered a defined TEAD1-knockout transcriptome signature related to migration and EMT but did not find consistently dysregulated genes across TEAD4-knockout lines. Given the expected differences between in vivo and in vitro tumor behavior, we did not observe extensive overlap between TEAD targets inferred from ATAC-seq data (in acutely derived cells) and from RNA-seq data (in cultured cells). For instance, while EGFR was a TEAD1-binding target in vivo, its downregulation in TEAD1KO cells was only transient in vitro. Nevertheless, we did observe lasting downregulation of several TEAD-accessible genes previously implicated in glioma migration, consistently across TEAD1-knockout cell lines and spheroids, including AQP447,48,49, CDH1146, MMP1669, SEMA3A70, and CDK1471. AQP4 was also found to be a direct TEAD1-binding target in vivo. Importantly, overexpression of AQP4 (both exogenously and endogenously after TEAD1 overexpression) resulted in nearly 50% rescue of migratory function, implicating AQP4 as one of TEAD1’s direct regulatory targets for migration in the spheroid dispersion model. While CDH11 overexpression also reversed partially migratory deficits in TEAD1-knockout spheroids, its expression was not directly regulated by TEAD1 and we did not detect TEAD1 occupancy in chromatin accessible regions associated with CDH11. This attests to the complex regulatory networks that impact migratory biology, which undoubtedly extend beyond TEAD1 and include other regulators of gene expression, such as other TFs, co-factors, long non-coding and micro RNAs, as well as post-translational modifications.
Several studies have previously demonstrated a role for AQP4, a major water channel expressed in CNS astrocytes, in tumor edema and migration47,48,49,72,73,74,75, the mechanisms of which are still incompletely understood. AQP4 is highly expressed at the leading edge of tumor cells, polarizing to and increasing the number and size of tumor lamellipodia to ensure water influx during cell movement76. AQP4 may also play a role in cytoskeletal organization77. Our study points toward a TEAD1-mediated transcriptional regulation of AQP4, a previously unrecognized TEAD1-target interaction, which affects GBM migration in vitro. The exact mechanism by which TEAD1-AQP4 affect tumor migration under physiological conditions remains to be determined. Given the well-known role of YAP-TEAD Hippo effectors in actin polarization and motility44, it is tempting to speculate that AQP4’s role in cytoskeletal organization may be through the Hippo-TEAD pathway.
Methods
Sample collection and processing
All specimen collection was performed de-identified in accordance with the policies and regulation at the Icahn School of Medicine at Mount Sinai (ISMMS) and its institutional review board. Unfixed tissues from GBM resections and GM postmortem dissections (19–22 weeks of gestation) were dissociated mechanically and enzymatically (papain, 0.3 mg ml−1), following published protocols17,30. Fluorochrome-conjugated EGF ligand (E) (ThermoFisher, E35351, 5 μg per million alive cells) was used along with PE-CD24/CD34/CD45 antibodies (BD, Biosciences, 560991, 550619, 555483, 1:10) to prospectively FACS-isolate GM and GBM cells with stem cell properties (referred to as E+NSPCs and E+GSCs) while excluding ependymal/endothelial/ inflammatory cells17,30,78. DAPI incorporation (4′,6-Diamidino-2-Phenylindole, Dihydrochloride, ThermoFisher, D1306, 1:1000) was used for dead cell exclusion. In GBM, DAPIlow gating was used to further enrich for tumor populations. FACS-sorted E+/E− (CD24−/CD34−CD45−) GM and GBM cells were immediately used for downstream ATAC-seq preparation, without freezing.
Chromatin accessibility data preparation and analysis
ATAC-seq sample and library preparation was performed using the prokaryotic Tn5 transposase system (Nextera DNA library kit, Illumina, FC-121–1030)31, using 13–100 K sorted cells starting material (most samples contained 25 K cells), Tn5 incubation time of 50 min, and 9–14 PCR cycles of amplification, after first optimizing these conditions in U87 technical replicates. Gel size selection for 150–700 bp fragments was added to optimize yield. Libraries were equilibrated and sequenced paired-end on Illumina HiSeq 2500, 32 bp read length, at 70–150 mil depth total reads. Raw sequenced reads were aligned to the hg19/GRCh37 reference assembly using Bowtie2 v2.1.0. Peaks were defined using MACS2 (parameters: –f BAMPE –shift -100 –extsize 200). Peaks separated by fewer than 150 bp were merged. Differential peak calling was performed using the DESeq2 R package. GREAT was employed for functional gene set analysis. Using the “basal plus extension association rule setting” in GREAT, each gene was assigned a basal regulatory domain of a minimal distance of 5 kb upstream and 1 kb downstream of the transcription start site (TSS), and an extended regulatory domain up to 1000 kb upstream and downstream of the gene’s basal domain. The HOMER tool suite (v4.8) was used for de novo TF motif discovery, by analyzing differential motif enrichment in GSC tumor-specific and developmentally shared differential regulatory element datasets against all elements (peaks) background. The selection of differentially enriched motifs was further prioritized by selecting those motifs enriched in only one of the two peak set analyses (tumor-specific or developmental) but not in both. For the RNA-seq/ATAC-seq correspondence analysis (Fig. 5a), we first associated each differential peak with its nearest gene using default Homer settings (where each peak is associated with the nearest gene’s TSS). For each gene, the peak with the highest score among all associated peaks was retained and shown in Fig. 5a.
Transcriptome data preparation and analysis
Whole-transcriptome data were generated via RNA-seq in sham, TEAD1KO, and TEAD4KO cell lines G-13063, G-13306, G-12746, G-16302, and sham and TEAD1KO migration assay spheroids G-13063 (three replicates from separate experiments). cDNA was generated using Clontech SMART-seq v4 (634888) and libraries using Nextera XT (Illumina FC-131–1024). Data were sequenced at 50 bp, 30–40 million paired-end reads/sample, on Illumina HiSeq 2500. Output sequencer files for each sample were subjected to a quality control assessment using the FASTQC package. RNA-seq reads were aligned to the human genome (GRCh38) using STAR with default settings. Gene counts were obtained using the featureCount utility of the subread 5 package. The count data were then rld (rlog transformed counts)-normalized (the rld function transforms the count data to the log2 scale in a way which minimizes differences between samples for rows with small counts, and which normalizes with respect to library size).
Transcriptome analysis was performed on sham/TEAD1KO/TEAD4KO RNA-seq data as well as on previously generated RNA-seq data in acutely sorted E+/E− GBM and NSPC populations (GEO GSE96682, https://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE96682)17. Differential expression analysis was performed using the DESeq2 R package, modeling the data with a negative binomial distribution and using Empirical Bayes shrinkage for dispersion and fold change estimation. Functional enrichment analyses were performed using GSEA, DAVID, and Pantherdb tools (see Supplementary references). All RNA-seq tests were FDR adjusted for multiple testing correction.
The expression of selected genes (AQP4 shown) was validated by RT-qPCR. Total RNA was isolated from cell lines via Trizol/chloroform/isopropanol extraction using standard protocol (ThermoFisher, 15596–026), followed by RNA cleanup-and-concentrator kit with DNase treatment (Zymo Research, R1013). cDNA was generated using the High-Capacity RNA-to-cDNA Kit (Life Technologies, 4387406). RT-qPCR reactions were run in duplicates, and Ct values were normalized to the ACTB housekeeping gene.
TCGA data analysis
GBM RNA-seqV2 normalized count data were downloaded from the Broad Institute Firehose (http://gdac.broadinstitute.org/runs/stddata__2016_01_28/data/GBM/20160128/gdac.broadinstitute.org_GBM.Merge_rnaseqv2__illuminahiseq_rnaseqv2__unc_edu__Level_3__RSEM_genes_normalized__data.Level_3.2016012800.0.0.tar.gz). Primary tumor sample expression data were log2(x + 1) transformed, quantile normalized, and corrected for patient age, gender, and batch. Two samples were identified as outliers based on sample clustering and were removed. Genes with missing values or zero variance were removed. This yielded a final dataset of 150 primary GBM samples and 19,942 genes.
Differences in TEAD family expression in GBM samples were tested using one-sided Wilcoxon matched pairs tests. Genes coexpressed with TEAD1 were defined as those with a TEAD1 Spearman’s ρ > 0 and BH-adjusted p < 0.05. Functional enrichment of correlated genes was carried out using KEGG Pathway gene sets. All analysis was conducted using the R 3.4.1 statistical computing environment.
CRISPR-Cas9 knockout and overexpression studies
CRISPR-Cas9 gene-editing experiments were carried out using the lentiCRISPRv2 lentiviral system (Addgene, 52961). Guide RNAs (gRNAs) targeting exon 3 of TEAD1, exon 3 of TEAD4, and exon 1 of EGFR were designed using CRISPR Design and cloned into the lentiCRISPRv2 vector (Supplementary Fig. 5). The lentiCRISPR v2 vector with a gRNA insert (5000 ng), the packaging plasmid psPAX2 (3750 ng, Addgene, 12260), and the envelope plasmid pMD2.G (1250 ng, Addgene, 12259) were mixed together and then added to a mixture of 60 μl X-tremeGENE™ 9 DNA Transfection Reagent (Roche) and 1 ml OPTI-MEM (Thermo Fisher Scientific, 31985070).
Lenti-X 293T cells (Takara, 632180) were used for transfection and harvesting of the lentivirus at 72 h. Then, cells were infected at 50% confluency with freshly collected CRISPR-Cas9-gRNA lentivirus supplemented with 8 μg ml−1 polybrene (Sigma-Aldrich, TR-1003-G). Infected cells were selected in media using puromycin treatment for up to 14 days (2 μg ml−1). Uninfected mock control cells were used to ensure uniform cell death within 14 days of puromycin treatment. For overexpression studies, the (Myc-DDK-tagged)-TEAD1, -AQP4, and CDH11 human ORF lentivirus constructs were transfected and purified from Lenti-X 293T cells (Origene RC215492L1, RC204693L1, and RC203810L1, respectively). GBM cells were infected for 12 h and allowed to recover for at least 48 h, prior to analysis.
Successful mutation of infected primary GBM cell lines was confirmed with the Surveyor® Mutation Detection Kit (Integrated DNA Technologies; 706025). Briefly, genomic DNA was extracted from infected cells and the region surrounding the PAM sequence was amplified using the high-fidelity PrimeSTAR GXL DNA Polymerase (Clontech, R050A). Purified PCR products were incubated with the surveyor nuclease and enhancer S with additional MgCl2 (0.15 M) for 30 min at 42 °C, following manufacturer’s protocol (Supplementary Fig. 5, Supplementary Table 2 for primer and gRNA sequences). Protein knockout was confirmed by Western immunoblot. For G-13063, each CRISPR-Cas9 gRNA experiment was repeated two independent times, involving separate infections. In each experiment, cells were plated in at least three replicates for sphere and migration assays.
Cell culture (sphere, proliferation, and migration assays)
Functional validation was performed on patient-derived, low-passaged (less than 20) IDH-wildtype primary GBM cell lines, which were selected for sphere-forming cells by growth on laminin (10 μg ml−1) in serum-free NS media supplemented with EGF (20 ng ml−1) and bFGF (20 ng ml−1) (G-13063 was used in initial experiments; G-13306, G-12746, and G-16302 were used in validation set of experiments). Migratory behavior was assessed using spheroid migration and transwell invasion assays. For spheroid migration, spheres were grown in serum-free NS media in low adherent conditions for 1 week, and then placed in poly-D-lysine (PDL) (10 μg ml−1) +/− laminin substrate in serum-free conditions without EGF or bFGF growth factors. Cell migration was assessed at 1 h and 30/36 h by measuring area of confluent migration. To study the migration dynamics, pictures were taken every hour on In Cell Analyzer 2200. For transwell invasion assays, cells were dissociated with Accutase® and counted. About 25,000 live cells were plated in the top chamber of the transwell (Corning, 3470) without growth factors (only containing DMEM/F12, 0.6% D-Glucose, 2 mM L-Glutamine, 1× Antibiotic–Antimycotic, 15 mM HEPES) and allowed to invade through a laminin-coated (20 μg ml−1) porous membrane following growth factor and serum attractants placed in the bottom chamber (DMEM/F12, 1× N2, 1× B27, 1× ITS, 0.6% D-Glucose, 2 mM L-Glutamine, 1× Antibiotic–Antimycotic, 15 mM HEPES, EGF (20 ng ml−1), bFGF (20 ng ml−1), 10% FBS). Percent cell invasion was measured at 24 h by quantitating the number of invasive cells (adherent to the bottom of the membrane) out of total cells plated. For sphere assays, cells were cultured on 96-well low-adherence plates in freshly made NS media with addition of EGF (20 ng ml−1) and bFGF (20 ng ml−1), at a density of 2.5 c μl−1, and their sphere diameter and number were recorded 6 days later. To calculate stem cell frequency, extreme limiting dilution analysis (ELDA) was performed79. Briefly, cells were seeded at 1, 10, 50, and 100 cells/well and their sphere-forming capacity was recorded at 21 days (20 wells per condition, ~20 μM sphere diameter cut off for counting). To analyze cell proliferation, cells were seeded in triplicates on laminin-coated wells at 25 K cell density, and were allowed to attach for 12 h. Cells were harvested at 24, 48, and 72 h, detached, and counted using a hemocytometer.
Orthotopic transplantations
Animal studies were performed in accordance with the ethical standards of the Icahn School of Medicine at Mount Sinai (ISMMS) under an approved Institutional Animal Care and Use Committee (IACUC) protocol. CRISPR-Cas9 sham and TEAD1KO primary GBM cells from G-13063 (2 × 105) were injected stereotactically into the striatum (2 mm right lateral to bregma and 3 mm deep) of 2-month-old male and female mice with B & T cell ICR-Severe Combined Immunodeficiency (SCID) (IcrTac:ICR-PrkdcSCID strain, Taconic). Mice were sacrificed at 3.5 months for histological analysis of tumor infiltration during early xenograft formation. Area of migration was measured using Zen 2 (blue edition).
Chromatin immunoprecipitation
TEAD1 binding was validated by ChIP using established protocols for TF-ChIP16,80. Briefly, chromatin was extracted from freshly snap-frozen primary GBM tissues, gently cross-linked (1% formalin, 10 min), sheared to approximately 150–400 bp (BioruptorTM Twin, Diagenode), and subjected to immunoprecipitation with antibodies against TEAD1 (BD, 610923, 5 μg per sample), TEAD4 (Santa Cruz, sc-101184, 5 μg per sample), or IgG (12–371, Millipore, 5 μg). The TF/chromatin-associated DNA was purified and quantified by qPCR using primers spanning TEAD1--accessible open chromatin regions in multiple genes, and normalized to input (Supplementary Table 2 for primer sequences).
Western immunoblot and immunofluorescence
Immunoblotting was performed by standard protocol using the following antibodies: TEAD1 (ThermoFisher, PA5-37075, 1:100, and BD, 610923, 1:100), TEAD4 (Santa Cruz sc-101184, 1:500), EGFR (Millipore, 06–847, 1:1000), pEGFR (Abcam, ab40815, 1:2000), AQP4 (Novus, NBP187679m 1:500), ERK (Santa Cruz, sc-135900, 1:500), pERK (Santa Cruz, sc-81492, 1:500), AKT (Cell Signaling, 4691T, 1:500), pAKT (Cell Signaling, 4060T, 1:500), CDH11 (ThermoFisher, 71–7600, 1:250) and ACTB (ThermoFisher, MA5-15739, 1:10,000), which were diluted in 2.5% BSA in TBS-T solution. HRP-linked anti-mouse (GE Healthcare, NA9311ML) and anti-rabbit (GE Healthcare, NA9341ML) secondary antibodies were used (1:500) to detect immunoreactivity. Main experiments were performed at least two independent times. Representative uncropped blot scans are supplied in Supplementary Fig. 8.
Immunofluorescence analysis was performed on mouse PDX tissue sections (mouse brains were perfused with 4% paraformaldehyde (PFA) and post-fixed in 4% PFA for 24 h prior to analysis). All sections underwent: blocking in 10% normal donkey serum (NDS)/0.5% triton-X (TX) for 1 h at RT; primary antibody incubation (1% NDS/0.25% TX overnight at 4 °C) with TEAD1 (ThermoFisher, PA5-37075, 1:100, and BD, 610923, 1:100), TEAD2 (Abcam, ab196669, 1:100), TEAD4 (Santa Cruz, 101184, 1:100), EGFR (Invitrogen, 280005, 1:100, and Millipore, 06–847, 1:100), Ki67 (Abcam, ab15580, 1:250), and HNA (Millipore, MAB1281, 1:400); and species-appropriate fluorochrome-conjugated secondary antibody incubation in 1% NDS/0.25% TX for 4 h at RT. Nuclear counterstain was done with DAPI (ThermoFisher, D1306, 1:1000). Images were captured on a confocal Zeiss LSM710 microscope.
Statistics
For all biochemical experiments, mean ± SEM were used in two-tailed unpaired Student’s t-test to calculate significance (*p < 0.05, **p < 0.01, ***p < 0.001), unless otherwise indicated. For differential ATAC-seq/RNA-seq data analyses, the Wald test was used to calculate p-values, which were FDR-adjusted to <0.05. For TCGA RNA-seq data analyses, one-sided Wilcoxon matched pairs test was used to calculate p-values for TEAD1-4 expression and one-tailed Fisher’s exact test was used to calculate p-values (BH-adjusted) for TEAD1-correlated enrichment.
Data availability
All data generated and analyzed in this study are included in this article (and its Supplementary Information files). TATAC-seq and RNA-seq data generated in this study are deposited in the GEO database under GSE117685. Accession codes or web links of publically available datasets used are provided in the appropriate methods subsections.
References
Xie, Q., Mittal, S. & Berens, M. E. Targeting adaptive glioblastoma: an overview of proliferation and invasion. Neuro. Oncol. 16, 1575–1584 (2014).
Cuddapah, V. A., Robel, S., Watkins, S. & Sontheimer, H. A neurocentric perspective on glioma invasion. Nat. Rev. Neurosci. 15, 455–465 (2014).
Tsankova, N. M. & Canoll, P. Advances in genetic and epigenetic analyses of gliomas: a neuropathological perspective. J. Neurooncol. 119, 481–490 (2014).
Hoelzinger, D. B. et al. Gene expression profile of glioblastoma multiforme invasive phenotype points to new therapeutic targets. Neoplasia 7, 7–16 (2005).
Gill, B. J. et al. MRI-localized biopsies reveal subtype-specific differences in molecular and cellular composition at the margins of glioblastoma. Proc. Natl Acad. Sci. USA 111, 12550–12555 (2014).
Hsieh, J. & Gage, F. H. Epigenetic control of neural stem cell fate. Curr. Opin. Genet. Dev. 14, 461–469 (2004).
Bernstein, B. E., Meissner, A. & Lander, E. S. The mammalian epigenome. Cell 128, 669–681 (2007).
Mack, S. C., Hubert, C. G., Miller, T. E., Taylor, M. D. & Rich, J. N. An epigenetic gateway to brain tumor cell identity. Nat. Neurosci. 19, 10–19 (2015).
Baylin, S. B. & Jones, P. A. A decade of exploring the cancer epigenome - biological and translational implications. Nat. Rev. Cancer 11, 726–734 (2011).
Flavahan, W. A., Gaskell, E. & Bernstein, B. E. Epigenetic plasticity and the hallmarks of cancer. Science 357, eaal2380 (2017).
Suva, M. L. et al. Reconstructing and reprogramming the tumor-propagating potential of glioblastoma stem-like cells. Cell 157, 580–594 (2014).
Bulstrode, H. et al. Elevated FOXG1 and SOX2 in glioblastoma enforces neural stem cell identity through transcriptional control of cell cycle and epigenetic regulators. Genes Dev. 31, 757–773 (2017).
Liau, B. B. et al. Adaptive chromatin remodeling drives glioblastoma stem cell plasticity and drug tolerance. Cell Stem Cell 20, 233–246 (2017).
Gallo, M. et al. MLL5 orchestrates a cancer self-renewal state by repressing the histone variant H3.3 and globally reorganizing chromatin. Cancer Cell 28, 715–729 (2015).
Rheinbay, E. et al. An aberrant transcription factor network essential for Wnt signaling and stem cell maintenance in glioblastoma. Cell Rep. 3, 1567–1579 (2013).
Erfani, P., Tome-Garcia, J., Canoll, P., Doetsch, F. & Tsankova, N. M. EGFR promoter exhibits dynamic histone modifications and binding of ASH2L and P300 in human germinal matrix and gliomas. Epigenetics. 10, 496–507 (2015).
Tome-Garcia, J. et al. Prospective Isolation and comparison of human germinal matrix and glioblastoma EGFR+populations with stem cell properties. Stem Cell Reports. 8, 1421–1429 (2017).
Mehta, S. & Lo Cascio, C. Developmentally regulated signaling pathways in glioma invasion. Cell Mol. Life Sci. 75, 385–402 (2017).
Wesolowska, A. et al. Microglia-derived TGF-beta as an important regulator of glioblastoma invasion--an inhibition of TGF-beta-dependent effects by shRNA against human TGF-beta type II receptor. Oncogene 27, 918–930 (2008).
Bhagat, M. et al. HIF-2alpha mediates a marked increase in migration and stemness characteristics in a subset of glioma cells under hypoxia by activating an Oct-4/Sox-2-Mena (INV) axis. Int. J. Biochem. Cell Biol. 74, 60–71 (2016).
Mendez, O. et al. Knock down of HIF-1alpha in glioma cells reduces migration in vitro and invasion in vivo and impairs their ability to form tumor spheres. Mol. Cancer 9, 133 (2010).
Kahlert, U. D. et al. ZEB1 promotes invasion in human fetal neural stem cells and hypoxic glioma neurospheres. Brain. Pathol. 25, 724–732 (2015).
Joseph, J. V. et al. Hypoxia enhances migration and invasion in glioblastoma by promoting a mesenchymal shift mediated by the HIF1alpha-ZEB1 axis. Cancer Lett. 359, 107–116 (2015).
Senft, C. et al. Inhibition of the JAK-2/STAT3 signaling pathway impedes the migratory and invasive potential of human glioblastoma cells. J. Neurooncol. 101, 393–403 (2011).
Selagea, L. et al. EGFR and C/EBP-beta oncogenic signaling is bidirectional in human glioma and varies with the C/EBP-beta isoform. FASEB J. 30, 4098–4108 (2016).
Mikheeva, S. A. et al. TWIST1 promotes invasion through mesenchymal change in human glioblastoma. Mol. Cancer 9, 194 (2010).
Yang, H. W., Menon, L. G., Black, P. M., Carroll, R. S. & Johnson, M. D. SNAI2/Slug promotes growth and invasion in human gliomas. BMC Cancer 10, 301 (2010).
Coma, S. et al. Id2 promotes tumor cell migration and invasion through transcriptional repression of semaphorin 3F. Cancer Res. 70, 3823–3832 (2010).
Carro, M. S. et al. The transcriptional network for mesenchymal transformation of brain tumours. Nature 463, 318–325 (2010).
Tome-Garcia, J. D., F. & Tsankova, N. M. FACS-based isolation of neural and glioma stem cell populations from fresh human tissues utilizing EGF ligand. Bio Protoc. 7, e2659 (2017).
Buenrostro, J. D., Giresi, P. G., Zaba, L. C., Chang, H. Y. & Greenleaf, W. J. Transposition of native chromatin for fast and sensitive epigenomic profiling of open chromatin, DNA-binding proteins and nucleosome position. Nat. Methods 10, 1213–1218 (2013).
Davie, K. et al. Discovery of transcription factors and regulatory regions driving in vivo tumor development by ATAC-seq and FAIRE-seq open chromatin profiling. PLoS Genet. 11, e1004994 (2015).
McLean, C. Y. et al. GREAT improves functional interpretation of cis-regulatory regions. Nat. Biotechnol. 28, 495–501 (2010).
Caren, H. et al. Glioblastoma stem cells respond to differentiation cues but fail to undergo commitment and terminal cell-cycle arrest. Stem Cell Reports. 5, 829–842 (2015).
Park, N. I. et al. ASCL1 reorganizes chromatin to direct neuronal fate and suppress tumorigenicity of glioblastoma stem cells. Cell Stem Cell 21, 209–224.e207 (2017).
Ceccarelli, M. et al. Molecular profiling reveals biologically discrete subsets and pathways of progression in diffuse glioma. Cell 164, 550–563 (2016).
Cancer Genome Atlas Research, N. et al. Comprehensive, integrative genomic analysis of diffuse lower-grade gliomas. N. Engl. J. Med. 372, 2481–2498 (2015).
Bhat, K. P. et al. The transcriptional coactivator TAZ regulates mesenchymal differentiation in malignant glioma. Genes Dev. 25, 2594–2609 (2011).
Zanconato, F. et al. Genome-wide association between YAP/TAZ/TEAD and AP-1 at enhancers drives oncogenic growth. Nat. Cell Biol. 17, 1218–1227 (2015).
Liu, X. et al. Tead and AP1 coordinate transcription and motility. Cell Rep. 14, 1169–1180 (2016).
Stein, C. et al. YAP1 exerts its transcriptional control via TEAD-mediated activation of enhancers. PLoS Genet. 11, e1005465 (2015).
Verfaillie, A. et al. Decoding the regulatory landscape of melanoma reveals TEADS as regulators of the invasive cell state. Nat. Commun. 6, 6683 (2015).
Rajbhandari, P. et al. Cross-cohort analysis identifies a TEAD4-MYCN positive feedback loop as the core regulatory element of high-risk neuroblastoma. Cancer Discov. 8, 582–599 (2018).
Meng, Z., Moroishi, T. & Guan, K. L. Mechanisms of Hippo pathway regulation. Genes Dev. 30, 1–17 (2016).
Qiu, H., Wang, F., Liu, C., Xu, X. & Liu, B. TEAD1-dependent expression of the FoxO3a gene in mouse skeletal muscle. BMC Mol. Biol. 12, 1 (2011).
Kaur, H. et al. Cadherin-11, a marker of the mesenchymal phenotype, regulates glioblastoma cell migration and survival in vivo. Mol. Cancer Res. 10, 293–304 (2012).
McCoy, E. & Sontheimer, H. Expression and function of water channels (aquaporins) in migrating malignant astrocytes. Glia 55, 1034–1043 (2007).
Lan, Y. L., Wang, X., Lou, J. C., Ma, X. C. & Zhang, B. The potential roles of aquaporin 4 in malignant gliomas. Oncotarget 8, 32345–32355 (2017).
Ding, T. et al. Role of aquaporin-4 in the regulation of migration and invasion of human glioma cells. Int. J. Oncol. 38, 1521–1531 (2011).
Yong, R. L. & Tsankova, N. M. Emerging interplay of genetics and epigenetics in gliomas: a new hope for targeted therapy. Semin. Pediatr. Neurol. 22, 14–22 (2015).
Gao, Y. F. et al. Silencing of Forkhead box D1 inhibits proliferation and migration in glioma cells.Oncol. Rep. 37, 1196–1202 (2017).
Zhang, R. et al. MiR-622 suppresses proliferation, invasion and migration by directly targeting activating transcription factor 2 in glioma cells. J. Neurooncol. 121, 63–72 (2015).
Han, Z. X. et al. Downregulation of PAK5 inhibits glioma cell migration and invasion potentially through the PAK5-Egr1-MMP2 signaling pathway. Brain Tumor Pathol. 31, 234–241 (2014).
Landin-Malt, A., Benhaddou, A., Zider, A. & Flagiello, D. An evolutionary, structural and functional overview of the mammalian TEAD1 and TEAD2 transcription factors.Gene 591, 292–303 (2016).
Song, S. et al. The Hippo coactivator YAP1 mediates EGFR overexpression and confers chemoresistance in esophageal cancer. Clin. Cancer Res. 21, 2580–2590 (2015).
Reddy, B. V. & Irvine, K. D. Regulation of Hippo signaling by EGFR-MAPK signaling through Ajuba family proteins. Dev. Cell 24, 459–471 (2013).
Hong, X. et al. Opposing activities of the Ras and Hippo pathways converge on regulation of YAP protein turnover. EMBO J. 33, 2447–2457 (2014).
Zhang, J. et al. YAP-dependent induction of amphiregulin identifies a non-cell-autonomous component of the Hippo pathway. Nat. Cell Biol. 11, 1444–1450 (2009).
Wang, H. et al. Tankyrase inhibitor sensitizes lung cancer cells to endothelial growth factor receptor (EGFR) inhibition via stabilizing angiomotins and inhibiting YAP signaling. J. Biol. Chem. 291, 15256–15266 (2016).
Guo, L. et al. Knockdown of TAZ modifies triple-negative breast cancer cell sensitivity to EGFR inhibitors by regulating YAP expression.Oncol. Rep. 36, 729–736 (2016).
Hsu, P. C. et al. YAP promotes erlotinib resistance in human non-small cell lung cancer cells. Oncotarget 7, 51922–51933 (2016).
Nawaz, Z. et al. Cbx7 is epigenetically silenced in glioblastoma and inhibits cell migration by targeting YAP/TAZ-dependent transcription. Sci. Rep. 6, 27753 (2016).
Li, W. et al. The role of transcriptional coactivator TAZ in gliomas. Oncotarget 7, 82686–82699 (2016).
Yang, R. et al. The Hippo transducer TAZ promotes cell proliferation and tumor formation of glioblastoma cells through EGFR pathway. Oncotarget 7, 36255–36265 (2016).
Artinian, N. et al. Phosphorylation of the Hippo pathway component AMOTL2 by the mTORC2 kinase promotes YAP signaling, resulting in enhanced glioblastoma growth and invasiveness. J. Biol. Chem. 290, 19387–19401 (2015).
Shah, S. R. et al. 217 YAP is ready to Rac and Rho: elucidation of a novel YAP-driven network that potentiates brain cancer cell dispersal and confers poor survival in patients. Neurosurgery 63(Suppl. 1), 185 (2016).
Ji, J. et al. Actin like-6A promotes glioma progression through stabilization of transcriptional regulators YAP/TAZ. Cell Death Dis. 9, 517 (2018).
Zhang, Y. et al. YAP promotes migration and invasion of human glioma cells. J. Mol. Neurosci. 64, 262–272 (2018).
Xia, H. et al. microRNA-146b inhibits glioma cell migration and invasion by targeting MMPs. Brain Res. 1269, 158–165 (2009).
Bagci, T., Wu, J. K., Pfannl, R., Ilag, L. L. & Jay, D. G. Autocrine semaphorin 3A signaling promotes glioblastoma dispersal.Oncogene 28, 3537–3550 (2009).
Fan, S. et al. Knockdown of PFTK1 inhibits the migration of glioma cells. J. Mol. Neurosci. 57, 257–264 (2015).
Auguste, K. I. et al. Greatly impaired migration of implanted aquaporin-4-deficient astroglial cells in mouse brain toward a site of injury. FASEB J. 21, 108–116 (2007).
Kong, H. et al. AQP4 knockout impairs proliferation, migration and neuronal differentiation of adult neural stem cells. J. Cell Sci. 121, 4029–4036 (2008).
Saadoun, S. et al. Involvement of aquaporin-4 in astroglial cell migration and glial scar formation. J. Cell Sci. 118, 5691–5698 (2005).
Saadoun, S., Papadopoulos, M. C., Hara-Chikuma, M. & Verkman, A. S. Impairment of angiogenesis and cell migration by targeted aquaporin-1 gene disruption. Nature 434, 786–792 (2005).
Huttenlocher, A. Cell polarization mechanisms during directed cell migration. Nat. Cell Biol. 7, 336–337 (2005).
Nicchia, G. P. et al. New possible roles for aquaporin-4 in astrocytes: cell cytoskeleton and functional relationship with connexin43. FASEB J. 19, 1674–1676 (2005).
Codega, P. et al. Prospective identification and purification of quiescent adult neural stem cells from their in vivo niche. Neuron 82, 545–559 (2014).
Hu, Y. & Smyth, G. K. ELDA: extreme limiting dilution analysis for comparing depleted and enriched populations in stem cell and other assays. J. Immunol. Methods 347, 70–78 (2009).
Tsankova, N. M., Kumar, A. & Nestler, E. J. Histone modifications at gene promoter regions in rat hippocampus after acute and chronic electroconvulsive seizures. J. Neurosci. 24, 5603–5610 (2004).
Acknowledgements
We thank members of the Pathology department and Biorepository Core at ISMMS for facilitating collection and procurement of de-identified tissue under appropriate consent; the ISMMS Flow Cytometry Core Facility for accommodation of human tissue sorts 24 h/day; the ISMMS Genomics Core Facility for computing resources; the NYGC for sequencing; Dr. R. Yong for providing some of the GBM cell lines; Members of Dr. J. Silva’s laboratory for assistance with reagents and equipment; Dr. H. Zou for scientific advice; and Dr. M. Olabarria for the graphical art image in Fig. 4d. The research was supported by Mount Sinai seed grant funds (N.M.T.), R03NS104669 (N.M.T.), and R01NS092735 (R.H.F.).
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Conception of project: N.M.T. Experimental design and data interpretation: N.M.T., E.Z., J.T.-G., P.E., and G.N. Bioinformatic analysis: G.N., E.Z., A.T., I.K., B.Z., and M.W. ATAC-seq/RNA-seq library preparation and advice: J.T.-G. and A.T. ChIP-PCR, RT-qPCR, PDX transplantations, and histology: J.T.-G, and R.T.-V. CRISPR-Cas9, Western immunoblot, and cell culture: J.T.-G., P.E., and R.H.F. Manuscript preparation: N.M.T., J.T.-G., and P.E. Editing: all authors.
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Tome-Garcia, J., Erfani, P., Nudelman, G. et al. Analysis of chromatin accessibility uncovers TEAD1 as a regulator of migration in human glioblastoma. Nat Commun 9, 4020 (2018). https://doi.org/10.1038/s41467-018-06258-2
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DOI: https://doi.org/10.1038/s41467-018-06258-2
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