Cellular redox status determines sensitivity to BNIP3-mediated cell death in cardiac myocytes.

The atypical BH3-only protein Bcl-2/adenovirus E1B 19-kDa interacting protein 3 (BNIP3) is an important regulator of hypoxia-mediated cell death. Interestingly, the susceptibility to BNIP3-mediated cell death differs between cells. In this study we examined whether there are mechanistic differences in BNIP3-mediated cell death between neonatal and adult cardiac myocytes. We discovered that BNIP3 is a potent inducer of cell death in neonatal myocytes, whereas adult myocytes are remarkably resistant to BNIP3. When exploring the potential underlying basis for the resistance, we discovered that adult myocytes express significantly higher levels of the mitochondrial antioxidant manganese superoxide dismutase (MnSOD) than neonatal myocytes. Overexpression of MnSOD confers resistance to BNIP3-mediated cell death in neonatal myocytes. In contrast, the presence of a pharmacological MnSOD inhibitor, 2-methoxyestradiol, results in increased sensitivity to BNIP3-mediated cell death in adult myocytes. Cotreatment with the mitochondria-targeted antioxidant MitoTEMPO or the MnSOD mimetic manganese (III) tetrakis (4-benzoic acid) porphyrin chloride abrogates the increased cell death by 2-methoxyestradiol. Moreover, increased oxidative stress also restores the ability of BNIP3 to induce cell death in adult myocytes. Taken together, these data indicate that redox status determines cell susceptibility to BNIP3-mediated cell death. These findings are clinically relevant, given that pediatric hearts are known to be more vulnerable than the adult heart to ischemic injury. Our studies provide important insight into why pediatric hearts are more sensitive to ischemic injury and may help in the clinical management of childhood heart disease.

Differential phosphorylation of perilipin 1A at the initiation of lipolysis revealed by novel monoclonal antibodies and high content analysis.

Lipolysis in adipocytes is regulated by phosphorylation of lipid droplet-associated proteins, including perilipin 1A and hormone-sensitive lipase (HSL). Perilipin 1A is potentially phosphorylated by cAMP(adenosine 3',5'-cyclic monophosphate)-dependent protein kinase (PKA) on several sites, including conserved C-terminal residues, serine 497 (PKA-site 5) and serine 522 (PKA-site 6). To characterize perilipin 1A phosphorylation, novel monoclonal antibodies were developed, which selectively recognize perilipin 1A phosphorylation at PKA-site 5 and PKA-site 6. Utilizing these novel antibodies, as well as antibodies selectively recognizing HSL phosphorylation at serine 563 or serine 660, we used high content analysis to examine the phosphorylation of perilipin 1A and HSL in adipocytes exposed to lipolytic agents. We found that perilipin PKA-site 5 and HSL-serine 660 were phosphorylated to a similar extent in response to forskolin (FSK) and L-γ-melanocyte stimulating hormone (L-γ-MSH). In contrast, perilipin PKA-site 6 and HSL-serine 563 were phosphorylated more slowly and L-γ-MSH was a stronger agonist for these sites compared to FSK. When a panel of lipolytic agents was tested, including multiple concentrations of isoproterenol, FSK, and L-γ-MSH, the pattern of results was virtually identical for perilipin PKA-site 5 and HSL-serine 660, whereas a distinct pattern was observed for perilipin PKA-site 6 and HSL-serine 563. Notably, perilipin PKA-site 5 and HSL-serine 660 feature two arginine residues upstream from the phospho-acceptor site, which confers high affinity for PKA, whereas perilipin PKA-site 6 and HSL-serine 563 feature only a single arginine. Thus, we suggest perilipin 1A and HSL are differentially phosphorylated in a similar manner at the initiation of lipolysis and arginine residues near the target serines may influence this process.

Parkin protein deficiency exacerbates cardiac injury and reduces survival following myocardial infarction.

It is known that loss-of-function mutations in the gene encoding Parkin lead to development of Parkinson disease. Recently, Parkin was found to play an important role in the removal of dysfunctional mitochondria via autophagy in neurons. Although Parkin is expressed in the heart, its functional role in this tissue is largely unexplored. In this study, we have investigated the role of Parkin in the myocardium under normal physiological conditions and in response to myocardial infarction. We found that Parkin-deficient (Parkin(-/-)) mice had normal cardiac function for up to 12 months of age as determined by echocardiographic analysis. Although ultrastructural analysis revealed that Parkin-deficient hearts had disorganized mitochondrial networks and significantly smaller mitochondria, mitochondrial function was unaffected. However, Parkin(-/-) mice were much more sensitive to myocardial infarction when compared with wild type mice. Parkin(-/-) mice had reduced survival and developed larger infarcts when compared with wild type mice after the infarction. Interestingly, Parkin protein levels and mitochondrial autophagy (mitophagy) were rapidly increased in the border zone of the infarct in wild type mice. In contrast, Parkin(-/-) myocytes had reduced mitophagy and accumulated swollen, dysfunctional mitochondria after the infarction. Overexpression of Parkin in isolated cardiac myocytes also protected against hypoxia-mediated cell death, whereas nonfunctional Parkinson disease-associated mutants ParkinR42P and ParkinG430D had no effect. Our results suggest that Parkin plays a critical role in adapting to stress in the myocardium by promoting removal of damaged mitochondria.

Microtubule-associated protein 1 light chain 3 (LC3) interacts with Bnip3 protein to selectively remove endoplasmic reticulum and mitochondria via autophagy.

Autophagy plays an important role in cellular quality control and is responsible for removing protein aggregates and dysfunctional organelles. Bnip3 is an atypical BH3-only protein that is known to cause mitochondrial dysfunction and cell death. Interestingly, Bnip3 can also protect against cell death by inducing mitochondrial autophagy. The mechanism for this process, however, remains poorly understood. Bnip3 contains a C-terminal transmembrane domain that is essential for homodimerization and proapoptotic function. In this study, we show that homodimerization of Bnip3 is also a requirement for induction of autophagy. Several Bnip3 mutants that do not interfere with its mitochondrial localization but disrupt homodimerization failed to induce autophagy in cells. In addition, we discovered that endogenous Bnip3 is localized to both mitochondria and the endoplasmic reticulum (ER). To investigate the effects of Bnip3 at mitochondria or the ER on autophagy, Bnip3 was targeted specifically to each organelle by substituting the Bnip3 transmembrane domain with that of Acta or cytochrome b(5). We found that Bnip3 enhanced autophagy in cells from both sites. We also discovered that Bnip3 induced removal of both ER (ERphagy) and mitochondria (mitophagy) via autophagy. The clearance of these organelles was mediated in part via binding of Bnip3 to LC3 on the autophagosome. Although ablation of the Bnip3-LC3 interaction by mutating the LC3 binding site did not impair the prodeath activity of Bnip3, it significantly reduced both mitophagy and ERphagy. Our data indicate that Bnip3 regulates the apoptotic balance as an autophagy receptor that induces removal of both mitochondria and ER.

Mitochondrial autophagy by Bnip3 involves Drp1-mediated mitochondrial fission and recruitment of Parkin in cardiac myocytes.

The Bcl2/adenovirus E1B 19-kDa interacting protein 3 (Bnip3) is an atypical BH3-only protein that is associated with mitochondrial dysfunction and cell death. Bnip3 is also a potent inducer of mitochondrial autophagy, and in this study we have investigated the mechanisms by which Bnip3 induces autophagy in cardiac myocytes. We found that Bnip3 induced mitochondrial translocation of dynamin-related protein 1 (Drp1), a protein involved in mitochondrial fission in adult myocytes. Drp1-mediated mitochondrial fission correlated with increased autophagy, and inhibition of Drp1 reduced Bnip3-mediated autophagy. Overexpression of Drp1K38E, a dominant negative of Drp1, or mitofusin 1 prevented mitochondrial fission and autophagy by Bnip3. Also, inhibition of mitochondrial fission or autophagy resulted in increased death of myocytes overexpressing Bnip3. Moreover, Bnip3 promoted translocation of the E3 ubiquitin ligase Parkin to mitochondria, which was prevented in the presence of a Drp1 inhibitor. Interestingly, induction of autophagy by Bnip3 was reduced in Parkin-deficient myocytes. Thus our data suggest that induction of autophagy in response to Bnip3 is a protective response activated by the cell that involves Drp1-mediated mitochondrial fission and recruitment of Parkin.