The Antimalarial Drug Amodiaquine Stabilizes P53 Through Ribosome Biogenesis Stress, Independently of Its Autophagy-inhibitory Activity

Overview

Journal Cell Death Differ

Specialty Cell Biology

Date 2019 Jul 10

PMID 31285544

Citations 29

Authors

Jaime A Espinoza

Asimina Zisi

Dimitris C Kanellis

Jordi Carreras-Puigvert

Martin Henriksson

Daniela Huhn

Kenji Watanabe

Thomas Helleday

Mikael S Lindstrom

Jiri Bartek

Affiliations

Soon will be listed here.

Abstract

Pharmacological inhibition of ribosome biogenesis is a promising avenue for cancer therapy. Herein, we report a novel activity of the FDA-approved antimalarial drug amodiaquine which inhibits rRNA transcription, a rate-limiting step for ribosome biogenesis, in a dose-dependent manner. Amodiaquine triggers degradation of the catalytic subunit of RNA polymerase I (Pol I), with ensuing RPL5/RPL11-dependent stabilization of p53. Pol I shutdown occurs in the absence of DNA damage and without the subsequent ATM-dependent inhibition of rRNA transcription. RNAseq analysis revealed mechanistic similarities of amodiaquine with BMH-21, the first-in-class Pol I inhibitor, and with chloroquine, the antimalarial analog of amodiaquine, with well-established autophagy-inhibitory activity. Interestingly, autophagy inhibition caused by amodiaquine is not involved in the inhibition of rRNA transcription, suggesting two independent anticancer mechanisms. In vitro, amodiaquine is more efficient than chloroquine in restraining the proliferation of human cell lines derived from colorectal carcinomas, a cancer type with predicted susceptibility to ribosome biogenesis stress. Taken together, our data reveal an unsuspected activity of a drug approved and used in the clinics for over 30 years, and provide rationale for repurposing amodiaquine in cancer therapy.

Citing Articles

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Development of Nurr1 agonists from amodiaquine by scaffold hopping and fragment growing.

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