An Anthelmintic Drug, Pyrvinium Pamoate, Thwarts Fibrosis and Ameliorates Myocardial Contractile Dysfunction in a Mouse Model of Myocardial Infarction

Motoaki Murakoshi,Thomas N Sato,Kyohei Saiki,Kyoji Urayama,Rajesh Gopalrao Katare

doi:10.1371/journal.pone.0079374

Motoaki Murakoshi, Thomas N Sato + Show 3 more

Open Access

https://doi.org/10.1371/journal.pone.0079374

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Abstract

Metabolic adaptation to limited supplies of oxygen and nutrients plays a pivotal role in health and disease. Heart attack results from insufficient delivery of oxygen and nutrients to the heart, where cardiomyocytes die and cardiac fibroblasts proliferate – the latter causing scar formation, which impedes regeneration and impairs contractility of the heart. We postulated that cardiac fibroblasts survive metabolic stress by adapting their intracellular metabolism to low oxygen and nutrients, and impeding this metabolic adaptation would thwart their survival and facilitate the repair of scarred heart. Herein, we show that an anthelmintic drug, Pyrvinium pamoate, which has been previously shown to compromise cancer cell survival under glucose starvation condition, also disables cardiac fibroblast survival specifically under glucose deficient condition. Furthermore, Pyrvinium pamoate reduces scar formation and improves cardiac contractility in a mouse model of myocardial infarction. As Pyrvinium pamoate is an FDA-approved drug, our results suggest a therapeutic use of this or other related drugs to repair scarred heart and possibly other organs.

Highlights

Ischemic heart disease accounts for ~13 % of deaths worldwide and is the leading cause of death for both men and women in all developed countries
We show that pyrvinium pamoate (PP) can disables the survival of cardiac fibroblasts under glucosedeficient media in vitro and thwarts fibrosis and ameliorate myocardial contractile dysfunction in a mouse model of myocardial infarction
We tested cytotoxicity of PP on cardiac fibroblasts cultured under the limited oxygen, glucose and glutamine (3 % oxygen, 300 μM glucose,

Summary

Introduction

Ischemic heart disease accounts for ~13 % of deaths worldwide and is the leading cause of death for both men and women in all developed countries. We postulate that impeding such metabolic adaptation in cardiac fibroblasts serves as a novel and effective therapeutic target to attenuate cardiac fibrosis in ischemic heart diseases including myocardial infarction. The survival of cardiac fibroblasts treated with PP in ischemia could not be rescued by normal levels of O2 (20 - 21%) and glutamine (4 mM) (Figure 1B).

Results

Conclusion