TOM20 and the Heartbreakers: Evidence for the role of mitochondrial transport proteins in cardioprotection

Protective effects of agrimonolide on hypoxia-induced H9c2 cell injury by maintaining mitochondrial homeostasis

Cardiomyocyte death caused by hypoxia is one of the main causes of myocardial infarction or heart failure, and mitochondria play an important role in this process. Agrimonolide (AM) is a monomeric component extracted from Agrimonia pilosa L. and has antioxidant, antitumor, and anti-inflammatory effects. This study aimed to investigate the role and mechanism of AM in improving hypoxia-induced H9c2 cell damage. The results showed that low AM concentrations promote H9c2 cell proliferation and increase cellular ATP content. Transcriptome sequencing showed that AM induces differential expression of genes in H9c2 cells. Gene ontology (GO) function and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment analyses revealed that these genes were concentrated in mitochondrial function. Subsequent experiments confirmed that AM regulates hypoxia-induced cell cycle arrest. AM inhibited the rate of apoptosis by regulating the expression of apoptosis-related proteins, reducing the level of cleaved Caspase 3 and Bax, and increasing the level of Bcl2, thereby protecting H9c2 cells from hypoxia-induced apoptosis. AM restored the mitochondrial membrane potential, inhibited the generation of ROS, maintained the normal shape of the mitochondria, improved the level of the mitochondrial functional proteins OPA1, MFN1, MFN2, Tom20, and increased the level of ATP. In conclusion, AM protects H9c2 cells from hypoxia-induced cell damage.

α-Crystallin B prevents apoptosis after H2O2 exposure in mouse neonatal cardiomyocytes

α-Crystallin B (cryAB) is the most abundant small heat shock protein in cardiomyocytes (CMs) and has been shown to have potent antiapoptotic properties. Because the mechanism by which cryAB prevents apoptosis has not been fully characterized, we examined its protective effects at the cellular level by silencing cryAB in mouse neonatal CMs using lentivector-mediated transduction of short hairpin RNAs. Subcellular fractionation of whole hearts showed that cryAB is cytosolic under control conditions, and after H(2)O(2) exposure, it translocates to the mitochondria. Phosphorylated cryAB (PcryAB) is mainly associated with the mitochondria, and any residual cytosolic PcryAB translocates to the mitochondria after H(2)O(2) exposure. H(2)O(2) exposure caused increases in cryAB and PcryAB levels, and cryAB silencing resulted in increased levels of apoptosis after exposure to H(2)O(2). Coimmunoprecipitation assays revealed an apparent interaction of both cryAB and PcryAB with mitochondrial voltage-dependent anion channels (VDAC), translocase of outer mitochondrial membranes 20 kDa (TOM 20), caspase 3, and caspase 12 in mouse cardiac tissue. Our results are consistent with the conclusion that the cardioprotective effects of cryAB are mediated by its translocation from the cytosol to the mitochondria under conditions of oxidative stress and that cryAB interactions with VDAC, TOM 20, caspase 3, and caspase 12 may be part of its protective mechanism.

Kinetics of the translocation and phosphorylation of alphaB-crystallin in mouse heart mitochondria during ex vivo ischemia

alphaB-crystallin (alphaBC) is a small heat shock protein expressed at high levels in the myocardium where it protects from ischemia-reperfusion damage. Ischemia-reperfusion activates p38 MAP kinase, leading to the phosphorylation of alphaBC on serine 59 (P-alphaBC-S59), enhancing its ability to protect myocardial cells from damage. In the heart, ischemia-reperfusion also causes the translocation of alphaBC from the cytosol to other cellular locations, one of which was recently shown to be mitochondria. However, it is not known whether alphaBC translocates to mitochondria during ischemia-reperfusion, nor is it known whether alphaBC phosphorylation takes place before or after translocation. In the present study, analyses of mitochondrial fractions isolated from mouse hearts subjected to various times of ex vivo ischemia-reperfusion showed that alphaBC translocation to mitochondria was maximal after 20 min of ischemia and then declined steadily during reperfusion. Phosphorylation of mitochondrial alphaBC was maximal after 30 min of ischemia, suggesting that at least in part it occurred after alphaBC association with mitochondria. Consistent with this was the finding that translocation of activated p38 to mitochondria was maximal after only 10 min of ischemia. The overexpression of alphaBC-AAE, which mimics alphaBC phosphorylated on serine 59, has been shown to stabilize mitochondrial membrane potential and to inhibit apoptosis. In the present study, infection of neonatal rat cardiac myocytes with adenovirus-encoded alphaBC-AAE decreased peroxide-induced mitochondrial cytochrome c release. These results suggest that during ischemia alphaBC translocates to mitochondria, where it is phosphorylated and contributes to modulating mitochondrial damage upon reperfusion.

Localization of phosphorylated alphaB-crystallin to heart mitochondria during ischemia-reperfusion

The cytosolic small heat shock protein alphaB-crystallin (alphaBC) is a molecular chaperone expressed in large quantities in the heart, where it protects from stresses such as ischemia-reperfusion (I/R). Upon I/R, p38 MAP kinase activation leads to phosphorylation of alphaBC on Ser(59) (P-alphaBC-S59), which increases its protective ability. alphaBC confers protection, in part, by interacting with and affecting the functions of key components in stressed cells. We investigated the hypothesis that protection from I/R damage in the heart by P-alphaBC-S59 can be mediated by localization to mitochondria. We found that P-alphaBC-S59 localized to mitochondria isolated from untreated mouse hearts and that this localization increased more than threefold when the hearts were subjected to ex vivo I/R. Mitochondrial P-alphaBC-S59 decreased when hearts were treated with the p38 inhibitor SB-202190. Moreover, SB-202190-treated hearts exhibited more tissue damage and less functional recovery upon reperfusion than controls. I/R activates mitochondrial permeability transition (MPT) pore opening, which increases cell damage. We found that mitochondria incubated with a recombinant mutant form of alphaBC that mimics P-alphaBC-S59 exhibited decreased calcium-induced MPT pore opening. These results indicate that mitochondria may be among the key components in stressed cells with which P-alphaBC-S59 interacts and that this localization may protect the myocardium, in part, by modulating MPT pore opening and, thus, reducing I/R injury.

Mitochondria protection from hypoxia/reoxygenation injury with mitochondria heat shock protein 70 overexpression

The majority of mitochondrial proteins are encoded by nuclear genes and synthesized in the cytosol as preproteins containing a mitochondria import sequence. Preproteins traverse the outer mitochondrial membrane in an unfolded state and then translocate through the inner membrane into the matrix via import machinery that includes mitochondrial heat shock protein 70 (mtHSP70). Neonatal rat cardiac myocytes (NCM) infected with an adenoviral vector expressing mtHSP70 or an empty control (Adv(-)) for 48 h were submitted to 8 h of simulated ischemia (hypoxia) followed by 16 h of reperfusion (reoxygenation). Infection with mtHSP70 virus yielded an increase in mtHSP70 protein in NCM mitochondria compared with Adv(-) (P < 0.05). Cell viability after simulated ischemia/reperfusion (I/R) was decreased in both Adv(-) and mtHSP70 groups, relative to control (P < 0.05), but mtHSP70-infected NCM had enhanced viability after I/R relative to Adv-infected NCM (P < 0.05). Simulated I/R caused an increase in reactive oxygen species generation and lipid peroxidation in Adv-infected NCM (P < 0.05, for both) that was not observed in mtHSP70-infected NCM. Mitochondrial complex III and IV activities were greater in mtHSP70-infected NCM after simulated I/R compared with Adv(-) (P < 0.05 for both). After simulated I/R, ATP content increased in mtHSP70-infected NCM, compared with Adv(-) (P < 0.05). Apoptotic markers were decreased in mtHSP70-infected NCM compared with Adv(-) after simulated I/R (P < 0.05). These results indicate that overexpression of mtHSP70 protects the mitochondria against damage from simulated I/R that may be due to a decrease in reactive oxygen species leading to preservation of mitochondrial complex function activities and ATP formation.