Genetic regulation of the RUNX transcription factor family has antitumor effects
Ken Morita, … , Hiroshi Sugiyama, Yasuhiko Kamikubo
Ken Morita, … , Hiroshi Sugiyama, Yasuhiko Kamikubo
Published May 22, 2017
Citation Information: J Clin Invest. 2017;127(7):2815-2828. https://doi.org/10.1172/JCI91788.
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Research Article Hematology Oncology

Genetic regulation of the RUNX transcription factor family has antitumor effects

Abstract

Runt-related transcription factor 1 (RUNX1) is generally considered to function as a tumor suppressor in the development of leukemia, but a growing body of evidence suggests that it has pro-oncogenic properties in acute myeloid leukemia (AML). Here we have demonstrated that the antileukemic effect mediated by RUNX1 depletion is highly dependent on a functional p53-mediated cell death pathway. Increased expression of other RUNX family members, including RUNX2 and RUNX3, compensated for the antitumor effect elicited by RUNX1 silencing, and simultaneous attenuation of all RUNX family members as a cluster led to a much stronger antitumor effect relative to suppression of individual RUNX members. Switching off the RUNX cluster using alkylating agent–conjugated pyrrole-imidazole (PI) polyamides, which were designed to specifically bind to consensus RUNX-binding sequences, was highly effective against AML cells and against several poor-prognosis solid tumors in a xenograft mouse model of AML without notable adverse events. Taken together, these results identify a crucial role for the RUNX cluster in the maintenance and progression of cancer cells and suggest that modulation of the RUNX cluster using the PI polyamide gene-switch technology is a potential strategy to control malignancies.

Authors

Ken Morita, Kensho Suzuki, Shintaro Maeda, Akihiko Matsuo, Yoshihide Mitsuda, Chieko Tokushige, Gengo Kashiwazaki, Junichi Taniguchi, Rina Maeda, Mina Noura, Masahiro Hirata, Tatsuki Kataoka, Ayaka Yano, Yoshimi Yamada, Hiroki Kiyose, Mayu Tokumasu, Hidemasa Matsuo, Sunao Tanaka, Yasushi Okuno, Manabu Muto, Kazuhito Naka, Kosei Ito, Toshio Kitamura, Yasufumi Kaneda, Paul P. Liu, Toshikazu Bando, Souichi Adachi, Hiroshi Sugiyama, Yasuhiko Kamikubo

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Figure 5

Antitumor activity of Chb-M′ in multiple cancer cell lines.

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Antitumor activity of Chb-M′ in multiple cancer cell lines. (A) Dose-res...
(A) Dose-response curves of Chb-M′ in AML cells (MV4-11, OCI-AML2, OCI-AML3, and MOLM-13 cells). Cells were treated with the indicated concentrations of Chb-M′. Forty-eight hours after treatment, cell viability was examined by WST assay (n = 3). (B) IC50 values of Chb-M′ against human cancer cell lines established from various origins. Forty-eight hours after Chb-M′ treatment, cell viability was examined by WST assay (n = 3). (C) Combination index plots of Chb-M′ and PRIMA-1 in P53-deficient (KG1a and HL60) and P53-mutated (MV4-11NR and Kasumi-1) AML cells (n = 3). (D) Schematic representation of treatment and monitoring schedule in MKN45-transplanted BALB/c-nu mice. (E) Live animal biofluorescence images at 48 hours after treatment with a single dose of FITC-Chb-M′ (320 μg/kg body weight). Scale represents relative fluorescence units, in photons per second per cm2 per steradian (p/s/cm2/sr) detected through a GFP filter. (F) Immunohistochemistry detecting FITC in the MKN45-derived tumor treated with FITC-Chb-M′ in E. Samples were stained either by isotype-matched control antibody (upper) or anti-FITC antibody (lower). Scale bars: 50 μm. Original magnification, ×40 and ×100 (insets). Data are the mean ± SEM values.