Project description:The development of targeted therapies has provided new hope for an increasing number of cancer patients affected by previously incurable diseases. The clinical success of this approach, however, is limited by numerous challenges, including a better control of cell plasticity, particularly in refractory and metastatic patients. Here we addressed this question in Neuroblastoma (NB), an aggressive pediatric malignancy, which remains a clinical challenge for high-risk patients. NB originates from neural crest-derived progenitors through defective differentiation programs combined with oncogenic activity due to genetic and epigenetic alterations. In order to identify critical genes responsible for tumor aggressiveness we performed combined chromatin and transcriptome analyses on matched primary xenografts, spheroids and differentiated adherent cultures, which we derived from metastatic non-MYCN amplified (nMNA) NB patients. Our approach identified the kinase BMX among the most differentially regulated genes between patient-derived xenografts and spheroids versus adherent models. We further found that BMX expression is associated with high tumor stage and poor patient survival in multiple NB transcriptomic datasets and critical to maintain the self-renewal and tumorigenic potential of NB spheroids. Moreover, we uncovered a positive correlation between BMX expression and the mesenchymal tumor cell phenotype, which was previously associated with increased chemo-resistance. Finally, we show that BMX inhibitors can readily reverse this cellular state, increase the sensitivity of NB spheroids toward standard of care chemotherapy, and reduce tumor growth in preclinical NB models. Altogether, our study identifies BMX as a novel promising therapeutic target for high-risk patients with relapsed or refractory nMNA NB tumors.

Project description:While clinical benefit has been observed with gilteritinib, most patients relapse through unknown mechanisms. To investigate mechanisms of gilteritinib resistance, we performed targeted genomic sequencing and single cell (sc) RNASeq on primary FLT3-ITD-mutated AML samples. Co-occurring mutations in RAS pathway genes were the most common. In gilteritinib-unresponsive patients, increased expression of bone marrow-derived hematopoietic cytokines and chemokines was observed after treatment compared to gilteritinib-sensitive patients. Expression of the TEK-family kinase, BMX, was higher in gilteritinib-unresponsive patients after treatment compared to gilteritinib-sensitive patients. BMX contributed to gilteritinib resistance in FLT3-mutant cells lines in a hypoxia-dependent manner by promoting pSTAT5 signaling, which was reversed with pharmacological inhibition and genetic knockout. In primary FLT3-mutated AML samples, pharmacological inhibition of BMX enhanced the antileukemic activity of gilteritinib and decreased chemokine expression. Gene module analysis associated gilteritinib responsiveness with lymphocyte differentiation and myeloid leukocyte activation. By contrast, unresponsiveness to gilteritinib associated with upregulation of cell-cycle, DNA/RNA metabolic processes, and protein translation. Together, these data support a role for microenvironment-mediated factors modulated by BMX in the escape from targeted therapy and gilteritinib resistance. This analysis provides a deeper understanding of targets and pathways for potential therapeutic intervention to restore gilteritinib sensitivity.

Project description:Glioblastoma (GBM) patient-derived orthotopic xenografts (PDOXs) were derived from organotypic spheroids obtained from patient tumor samples. To detect whether gene expression profiles of GBM patient tumors are retained in PDOXs, we performed genome-wide transcript analysis by human-specific microarrays . In parallel, we analyzed GBM cell cultures and corresponding intracranial xenografts from stem-like (NCH421k, NCH644) and adherent GBM cell lines (U87, U251). PDOXs show a better transcriptomic resemblance with patient tumors than other preclinical models. The major difference is largely explained by the depletion of human-derived non-malignant cells.

Project description:Oncogenic addiction to FLT3 kinase signaling is a hallmark of FLT3-ITD+ acute myeloid leukemia (AML). While FLT3 inhibitors like sorafenib show initial therapeutic efficacy, resistance rapidly develops through mechanisms that are incompletely understood. Here, utilizing RNA-Seq based analysis of patient leukemic cells, we found significant up-regulation of the Tec-family kinase BMX during sorafenib resistance. BMX upregulation was recapitulated in an in vivo FLT3-ITD+ model of sorafenib resistance. Mechanistically, we found that the anti-angiogenic effects of sorafenib led to increased bone-marrow hypoxia, which contributed to HIF-dependent BMX upregulation. In in vitro experiments, hypoxia-dependent BMX up-regulation was observed in both AML and non-AML cell lines. Functional studies in FLT3-ITD+ cell lines showed that BMX is part of a compensatory signaling mechanism that promotes AML cell survival during FLT3 inhibition. Our results demonstrate that hypoxia-dependent up-regulation of BMX contributes to therapeutic resistance through a compensatory pro-survival signaling mechanism. These results also reveal the role of ‘off-target’ drug effects on tumor microenvironment and development of acquired drug resistance. We propose that the bone marrow niche can be altered by anti-cancer therapeutics, resulting in drug resistance through cell non-autonomous microenvironment-dependent effects.

Project description:We show that Bmx-deficiency reduces angiotensin II -induced cardiac hypertrophy and pathological gene expression Angiotensin II or NaCl were infuced for two weeks into wild-type and Bmx-deficient mice to induce cardiac hypertrophy

Project description:We cultured adherent primary cell lines from NB tumor samples. Adherent primary cell lines from NB tumor samples have a subpopulation of neural crest progenitors that grow as spheres when cultured in low-binding conditions.

Project description:We show that Bmx-deficiency reduces angiotensin II -induced cardiac hypertrophy and pathological gene expression

Project description:We cultured adherent primary cell lines from NB tumor samples. Adherent primary cell lines from NB tumor samples have a subpopulation of neural crest progenitors that grow as spheres when cultured in low-binding conditions. We tested the changes in gene expression induced by endothelin-1 (ET1), a cytokine that regulates proliferation, migration, differentiation and survival of NC cells .

Project description:We found that NB expression of TNFR2 and monocyte mTNFα are required for monocyte activation and IL-6 production, while NB TNFR1 and monocyte sTNFα are required for NB NF-κB activation. Treatment of NB-monocyte co-cultures with clinical-grade etanercept completely abrogated release of IL-6, G-CSF, IL-1α, and IL-1β and eliminated monocyte-induced enhancement of NB cell proliferation in vitro. Furthermore, etanercept treatment inhibited tumor growth, ablated tumor angiogenesis, and suppressed oncogenic signaling in mice with subcutaneous NB/human monocyte xenografts. Finally, GSEA revealed significant enrichment for TNFα signaling in NB patients that relapsed.

Project description:Malignant glioblastoma (GBM) is a highly aggressive brain tumor with a dismal prognosis and limited therapeutic options. Genomic profiling of GBM samples in the TCGA database has identified four molecular subtypes (Proneural, Neural, Classical and Mesenchymal), which may arise from different glioblastoma stem-like cell (GSC) populations. In the present study, we identify two GSC populations that produce GBM tumors by subcutaneous and intracranial injection with identical histological features. Gene expression analysis revealed that xenografts of GSCs grown as spheroid cultures had a Classical molecular subtype similar to that of bulk tumor cells. In contrast xenografts of GSCs grown as adherent cultures on laminin-coated plates expressed a Mesenchymal gene signature. Adherent GSC-derived xenografts had high STAT3 and ANGPTL4 expression as well as enrichment for stem cell markers, transcriptional networks and pro-angiogenic markers characteristic of the Mesenchymal subtype. Examination of clinical samples from GBM patients showed that STAT3 expression was directly correlated with ANGPTL4 expression, and that increased expression of these genes correlated with poor patient survival and performance. A pharmacological STAT3 inhibitor abrogated STAT3 binding to the ANGPTL4 promoter and exhibited anticancer activity in vivo. Taken together, we identified two distinct GSC populations that produce histologically identical tumors but with very different gene expression patterns, and a STAT3/ ANGPTL4 pathway in glioblastoma that may serve as a target for therapeutic intervention. 2 samples of each variable were analyzed. Cells were cultured under normal adherent conditon (Bulk tumor cells), non-adherent plates with stem cell medium (Sp-GSC) or laminin-coated plates with stem cell medium (Ad-GSC). Xenografts were generated in NSG mice by subcutaneous inoculation.