Project description:Advances in preclinical models that recapitulate chemorefractory and relapsed disease are needed to better predict the efficacy of an expanding and promising armamentarium of drug candidates being tested in early-phase pediatric clinical trials. Here, we used longitudinal magnetic resonance imaging to design an individualized, dose-escalating treatment regimen that induces evolution of neuroblastoma in the Th-MYCN genetically-engineered mouse model, concomitant with the acquisition of resistance to Temozolomide, a standard chemotherapy used in treatment of refractory, relapsed neuroblastoma patients within European early-phase clinical trials. MRI longitudinally identified the development of intra-tumoral heterogeneity. Molecular profiling of expanding, treatment-refractory regions identified prominent up-regulation of the nor-adrenergic core regulatory signature and deregulation of the CDK2 pathway. Treatment with the CDK2/9 inhibitor fadraciclib led to significant response and an overall survival benefit in temozolomide-resistant Th-MYCN tumors and allografts generated from these resistant tumors. These findings demonstrate the utility of genetically-engineered mouse models as platforms to dissect the evolution of chemoresistance in neuroblastoma and they provide a mechanistic rationale to support the evaluation of fadraciclib in ongoing paediatric phase I studies of chemotherapy combined with Temozolomide in relapsed, treatment refractory neuroblastoma patients.

Project description:Two genes have a synthetic lethal relationship when silencing or inhibition of one gene is only lethal in the context of a mutation or activation of the second gene. This situation offers an attractive therapeutic strategy, as inhibition of such a gene will only trigger cell death in tumor cells with an activated second oncogene but spare normal cells without activation of the second oncogene. Here we present evidence that CDK2 is synthetic lethal to neuroblastoma cells with MYCN amplification and overexpression. Neuroblastomas are childhood tumors with an often lethal outcome. Twenty percent of the tumors have MYCN amplification and these tumors are ultimately refractory to any therapy. Targeted silencing of CDK2 by three RNA interference techniques induced apoptosis in MYCN-amplified neuroblastoma cell lines, but not in MYCN single copy cells. Silencing of MYCN abrogated this apoptotic response in MYCN-amplified cells. Inversely, silencing of CDK2 in MYCN single copy cells did not trigger apoptosis, unless a MYCN transgene was activated. The MYCN induced apoptosis after CDK2 silencing was accompanied by nuclear stabilization of P53 and mRNA profiling showed up-regulation of P53 target genes. Silencing of P53 rescued the cells from MYCN-driven apoptosis. The synthetic lethality of CDK2 silencing in MYCN activated neuroblastoma cells can also be triggered by inhibition of CDK2 with a small molecule drug. Treatment of neuroblastoma cells with Roscovitine, a CDK inhibitor, at clinically achievable concentrations induced MYCN-dependent apoptosis. The synthetic lethal relation between CDK2 and MYCN indicates CDK2 inhibitors as potential MYCN-selective cancer therapeutics. CDK2 shRNA in a tet repressor system was stably transfected in the IMR32 cell line. Time course analysis was performed in triplicate after induction of CDK2 shRNA at 5 time points.

Project description:Two genes have a synthetic lethal relationship when silencing or inhibition of one gene is only lethal in the context of a mutation or activation of the second gene. This situation offers an attractive therapeutic strategy, as inhibition of such a gene will only trigger cell death in tumor cells with an activated second oncogene but spare normal cells without activation of the second oncogene. Here we present evidence that CDK2 is synthetic lethal to neuroblastoma cells with MYCN amplification and overexpression. Neuroblastomas are childhood tumors with an often lethal outcome. Twenty percent of the tumors have MYCN amplification and these tumors are ultimately refractory to any therapy. Targeted silencing of CDK2 by three RNA interference techniques induced apoptosis in MYCN-amplified neuroblastoma cell lines, but not in MYCN single copy cells. Silencing of MYCN abrogated this apoptotic response in MYCN-amplified cells. Inversely, silencing of CDK2 in MYCN single copy cells did not trigger apoptosis, unless a MYCN transgene was activated. The MYCN induced apoptosis after CDK2 silencing was accompanied by nuclear stabilization of P53 and mRNA profiling showed up-regulation of P53 target genes. Silencing of P53 rescued the cells from MYCN-driven apoptosis. The synthetic lethality of CDK2 silencing in MYCN activated neuroblastoma cells can also be triggered by inhibition of CDK2 with a small molecule drug. Treatment of neuroblastoma cells with Roscovitine, a CDK inhibitor, at clinically achievable concentrations induced MYCN-dependent apoptosis. The synthetic lethal relation between CDK2 and MYCN indicates CDK2 inhibitors as potential MYCN-selective cancer therapeutics.

Project description:The undruggable nature of oncogenic Myc transcription factors poses a therapeutic challenge in neuroblastoma, a paediatric cancer in which MYCN amplification is strongly associated with unfavourable outcome. Here, we show that CYC065, a clinical inhibitor of CDK2 and CDK9, selectively targets MYCN-amplified neuroblastoma via blockade of CDK9-dependent, MYCN-driven transcriptional elongation and CDK2-dependent proliferation. CYC065 also targets nascent transcription of short half-life genes including MYCN and MCL-1 leading to downregulation of MYCN-driven ‘adrenergic’ gene expression programs, growth inhibition, and apoptosis in vitro and in vivo. These data highlight the clinical potential of CDK2/9 inhibition in the treatment of MYCN-amplified neuroblastoma.

Project description:The undruggable nature of oncogenic Myc transcription factors poses a therapeutic challenge in neuroblastoma, a paediatric cancer in which MYCN amplification is strongly associated with unfavourable outcome. Here, we show that CYC065, a clinical inhibitor of CDK2 and CDK9, selectively targets MYCN-amplified neuroblastoma via blockade of CDK9-dependent, MYCN-driven transcriptional elongation and CDK2-dependent proliferation. CYC065 also targets nascent transcription of short half-life genes including MYCN and MCL-1 leading to downregulation of MYCN-driven ‘adrenergic’ gene expression programs, growth inhibition, and apoptosis in vitro and in vivo. These data highlight the clinical potential of CDK2/9 inhibition in the treatment of MYCN-amplified neuroblastoma.

Project description:Neuroblastoma is the most common extra-cranial malignancy in childhood and accounts for approximately 15% of childhood cancer deaths. Amplification of N-Myc in neuroblastoma is associated with aggressive disease and predicts for poor prognosis. Novel therapeutic approaches are therefore essential to improving patient outcomes in this setting. The histone deacetylases are known to interact with N-Myc and regulate numerous cellular processes, including differentiation in neuroblastoma. We therefore investigated the antitumor activity of the histone deacetylase inhibitor, panobinostat in the setting of N-Myc amplified neuroblastoma using the TH-MYCN murine model. Continuous treatment of tumor bearing TH-MYCN transgenic mice with panobinostat for 9 weeks led to a significant improvement in survival as compared to mice treated with vehicle, or continuous treatment with panobinostat for a three week period. Panobinostat induced rapid tumor regression with no regrowth observed during the treatment period. Tumor response was associated with an initial apoptosis phenotype mediated via up-regulation of BMF and BIM. When treated was stopped at three weeks 100% of mice relapsed with aggressive neuroblastoma. Differentiation of neuroblastoma into benign ganglioneuroma, with a characteristic increase in S100 expression and reduction of N-Myc expression, was observed in mice treated for nine weeks, resulting in a sustained remission on 90% of mice treated. RNA-sequencing analysis of tumors from treated animals confirmed significant up-regulation of gene pathways associated with apoptosis and differentiation as early as 24 hours after treatment. Together our data demonstrate the potential of panobinostat as a therapeutic strategy for high-risk neuroblastoma patients. Eight homozygous TH-MYCN mice bearing neuroblastomas were treated with either 5mg/kg panobinostat (4 animals) or vehicle (4 animals) for 24hr (two doses) and tumours harvested 4hr post the second dose.

Project description:To understand the in vivo transcriptomic response to ATR inhibition, RNA-Seq was performed after treatment of 2 previously developed neuroblastoma mouse models (Alk-F1178S;Th-MYCN and Rosa26_Alkal2;Th-MYCN; see Borenas et al., EMBO J, 2021) with the ATR inhibitor BAY 1895344.

Project description:Despite intensive therapy, children with high-risk neuroblastoma are at risk of treatment failure. We applied a multi-omic system approach to evaluate metabolic vulnerabilities in human neuroblastoma. We combined metabolomics, CRISPR screening and transcriptomic data across >700 solid tumor cell lines and identified dihydroorotate dehydrogenase (DHODH), a critical enzyme in pyrimidine synthesis, as a potential treatment target. Of note, DHODH inhibition is currently under clinical investigation in patients with hematologic malignancies. In neuroblastoma, DHODH expression was identified as an independent risk factor for aggressive disease, and high DHODH levels correlated to worse overall and event-free survival. A subset of tumors with the highest DHODH expression was associated with a dismal prognosis, with a 5-year survival of <10%. In xenograft and transgenic neuroblastoma mouse models treated with the DHODH inhibitor brequinar, tumor growth was dramatically reduced, and survival was extended. Furthermore, brequinar treatment was shown to reduce the expression of MYC targets in three different neuroblastoma models in vivo. A combination of brequinar and temozolomide was curative in the majority of transgenic TH-MYCN neuroblastoma mice, indicating a highly active clinical combination therapy. Overall, DHODH inhibition combined with temozolomide has therapeutic potential in neuroblastoma and we propose this combination for clinical testing.

Project description:Despite intensive therapy, children with high-risk neuroblastoma are at risk of treatment failure. We applied a multi-omic system approach to evaluate metabolic vulnerabilities in human neuroblastoma. We combined metabolomics, CRISPR screening and transcriptomic data across >700 solid tumor cell lines and identified dihydroorotate dehydrogenase (DHODH), a critical enzyme in pyrimidine synthesis, as a potential treatment target. Of note, DHODH inhibition is currently under clinical investigation in patients with hematologic malignancies. In neuroblastoma, DHODH expression was identified as an independent risk factor for aggressive disease, and high DHODH levels correlated to worse overall and event-free survival. A subset of tumors with the highest DHODH expression was associated with a dismal prognosis, with a 5-year survival of <10%. In xenograft and transgenic neuroblastoma mouse models treated with the DHODH inhibitor brequinar, tumor growth was dramatically reduced, and survival was extended. Furthermore, brequinar treatment was shown to reduce the expression of MYC targets in three different neuroblastoma models in vivo. A combination of brequinar and temozolomide was curative in the majority of transgenic TH-MYCN neuroblastoma mice, indicating a highly active clinical combination therapy. Overall, DHODH inhibition combined with temozolomide has therapeutic potential in neuroblastoma and we propose this combination for clinical testing.

Project description:It has been already reported that there are undifferentiated/proliferating neuroblasts in the postnatal sympathetic ganglia in TH-MYCN mice, a neuroblastoma model. We established suitable spheroid culture condition that selectively isolates undifferentiated neuroblasts from superior mesenteric ganligon (SMG) of TH-MYCN mice. In order to investigate the chromosomal alterations (gains or losses) of spheres derived from TH-MYCN mice, we carried out array comparative genomic hybridization. We investigated whether chromosomal alterations occured during early neuroblastoma tumorigenesis in TH-MYCN mice.