Significance
We provide new, exciting evidence for a previously unidentified signaling pathway that mechanistically links mitochondrial respiratory chain defects to necrosis and heart failure induced by the chemotherapy agent doxorubicin (DOX). We specifically show that DOX disrupts protein complexes between the key respiratory chain proteins, including uncoupling protein 3 and cytochrome
c
oxidase, resulting in abnormal mitochondrial respiration and necrosis through a mechanism contingent on Bcl-2-like 19kDa-interacting protein 3 (Bnip3). Perhaps most compelling is our finding that inhibiting Bnip3 completely abrogated the cardiotoxic effects of DOX. These exciting findings have important clinical implications not only for preventing heart failure by targeting Bnip3 in cancer patients undergoing chemotherapy, but also for understanding the pathogenesis of other diseases in which mitochondrial function is compromised.
Abstract-Myocardial ischemia and angiotensin II activate the tumor suppressor p53 protein, which promotes cell death.Previously, we showed that the Bcl-2 death gene Bnip3 is highly induced during ischemia, where it triggers mitochondrial perturbations resulting in autophagy and cell death. However, whether p53 regulates Bnip3 and autophagy is unknown. Herein, we provide new compelling evidence for a novel signaling axis that commonly links p53 and Bnip3 for autophagy and cell death. p53 overexpression increased endogenous Bnip3 mRNA and protein levels resulting in mitochondrial defects leading to loss of mitochondrial ∆Ψ m . This was accompanied by an increase in autophagic flux and cell death. Notably, genetic loss of function studies, such as Atg7 knock-down or pharmacological inhibition of autophagy with 3-methyl adenine, suppressed cell death induced by p53-indicating that p53 induces maladaptive autophagy. Our previous work demonstrated that Bnip3 induces mitochondrial defects and autophagic cell death. Conversely, loss of function of Bnip3 in cardiac myocytes or Bnip3 −/− mouse embryonic fibroblasts prevented mitochondrial targeting of p53, autophagy, and cell death. To our knowledge, these data provide the first evidence for the dual regulation of autophagy and cell death of cardiac myocytes by p53 that is mutually dependent on and obligatorily linked to Bnip3 gene activation. Hence, our findings may explain more fundamentally, how, autophagy and cell death are dually regulated during cardiac stress conditions where p53 is activated.
Given the otherwise lethal consequences of deregulated Bnip3FL expression in postmitotic cells, our findings reveal a novel intrinsic defense mechanism that opposes the mitochondrial defects and cell death of ventricular myocytes that is obligatorily linked and mutually dependent on alternative splicing of Bnip3FL during hypoxia or ischemic stress.
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