MYCN expression

Everolimus (EVER) and tozasertib (TOZA) encapsulated in NP and targeted with dinutuximab β (DTX-β). DTX-β/EVER-TOZA@PEG-b-PLGA may exert cytotoxic and apoptotic effects in NB. The use of targeted nanocarriers in NB treatment may enhance cytotoxic and apoptotic responses specifically in the tumor region.

High-level expression of Oct-1Z increased expression of MYCN and its target gene NEUROD1. Oct-1Z was thus identified as an activator of MYCN expression and a potential target for neuroblastoma therapy in patients with high levels of MYCN.

Additionally, MYCN-induced miR-221 was found to suppress CREB expression. Together, these findings demonstrate MYCN-dependent effects of TrkC signalling and highlight the therapeutic potential of targeting the PKA pathway to induce differentiation in high-risk MYCN-amplified neuroblastoma.

It eliminates both non-MYCN-amplified (SH-SY5Y and SK-N-SH) and MYCN-amplified (SMS-KCNR) NB cells that exhibit PMA-inducible CCL2 expression but not MYCN-amplified NB cells (IMR-32 and NB-1) that exhibit CCL2 repression, and is offset by reciprocal NB cell-induced Fas-mediated Jurkat cell apoptosis. These findings form a solid foundation for further pre-clinical development aimed at identifying clinically relevant physiological immune cell equivalents and alternative PKC activators, with the ultimate goal of translating this mechanism into an effective immune-therapeutic approach for the treatment of high-risk non-immunogenic NBs, especially NBs that exhibit CCL2 and TrkAIII expression.

Leveraging this property, neuroblastoma-derived exosomes can be purified, modified, and loaded with small interfering RNA (siRNA) to silence MYCN expression, combined with chloroquine-an FDA-approved autophagy inhibitor-to simultaneously inhibit autophagy and induce apoptotic signaling...Collectively, exosome-based strategies represent a paradigm shift in formulating combination therapies, offering a multifaceted approach to target MYCN amplification, inhibit autophagy, induce apoptosis, and modulate the tumor-microbiome axis. These innovations hold significant promise for improving clinical outcomes in high-risk MYCN-amplified neuroblastoma patients.

Conversely, in prostate adenocarcinoma models, DNMT1 deletion leads to de-repression of neuroendocrine lineage genes with a loss of H3K27me3 marks. Our findings reveal a functional interplay between two repressive epigenetic machineries that mediates lineage plasticity in prostate cancer.

This score reliably predicted recurrence risk and identified EMT-prone microenvironments, with stronger predictive performance in nontumor tissues, suggesting its potential in detecting precancerous niches predisposed to de novo tumorigenesis. Collectively, our findings establish MYCN as a functional driver and spatial marker of tumor-promoting microenvironments in liver tumorigenesis; additionally, we propose a clinically actionable strategy to identify high-risk patients through transcriptomic profiling of nontumor liver tissue.

P1, N=26, Completed, Dana-Farber Cancer Institute | Active, not recruiting --> Completed

Notably, MI102 effect exhibited superior tumor cell selectivity compared with the MET inhibitor tivantinib. At the transcriptional level, RNA-seq revealed that MI102 globally downregulated MYCN-associated oncogenic programs. Collectively, these findings establish pharmacological downregulation of MYCN as a promising therapeutic strategy for HCC and reveal a functional link between MET signaling and MYCN-driven oncogenic pathways.

Through extensive gene expression profiling and whole-exome sequencing of MYCN/ALK-induced clones, we identified key features of NB, including loss of NF1 and gain of 17q chromosome, which are critical for the development of malignant tumor. This model provides a valuable platform for studying the biological mechanisms driving ALK and MYCN amplification in NB derived from cNCCs.

Tumor growth decreased in animals treated with ATUX-1215, and analysis of tumor specimens confirmed decreased MYCN expression. We conclude that pharmacologic PP2A reactivation may be a relevant therapeutic component in NBL treatment through its targeting of MYCN.

In vivo, volasertib treatment attenuated fibroblast activation and collagen deposition during TGFα-induced pulmonary fibrosis. Together, these findings identify a pathogenic role for the WT1-MYCN-PLK1 axis in fibroblast activation and provide proof-of-concept evidence supporting PLK1 inhibition with volasertib as a potential therapeutic strategy for IPF.