Amplification of MYCN plays a pivotal role in multiple types of tumors and correlates with poor prognosis in high-risk neuroblastoma. Despite recent advances in the treatment of neuroblastoma, no approaches directly target the master oncogene MYCN. Difficulties in targeting the MYCN protein inspired us to develop a new gene-level-inhibitory strategy using a sequence-specific gene regulator. Here, we generated a MYCN-targeting pyrrole-imidazole (PI) polyamide, MYCN-A3, which directly binds to and alkylates DNA at homing motifs within the MYCN transcript. Pharmacologic suppression of MYCN inhibited the proliferation of cancer cells harboring MYCN amplification compared with MYCN nonamplified cancer cells. In neuroblastoma xenograft mouse models, MYCN-A3 specifically downregulated MYCN expres-sion and suppressed tumor progression with no detectable adverse effects and resulted in prolonged overall survival. Moreover, treatment with MYCN-A3, but not MYCN nontargeting PI polyamide, precipitated a copy number reduction of MYCN in neuroblastoma cells with MYCN amplification. These findings suggest that directly targeting MYCN with MYCN-A3 is a novel therapeutic approach to reduce copy number of the MYCN gene for MYCN-amplified neuroblastoma.Significance: This study presents a novel approach to drugging an amplified oncogene by showing that targeting gene amplification of MYCN suppresses MYCN expression and neuroblastoma growth.
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Self-assembled structures formed from a pyridine-appended zinc chlorophyll derivative are reported. While the zinc complex forms cyclic oligomers in chloroform solution, as indicated by (1)H NMR studies (including diffusion-ordered spectroscopy), vapor pressure osmometry, and cold-spray ionization mass spectrometry, it forms double-stranded helical coordination polymers in the solid state, as revealed by single-crystal X-ray analysis.
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