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박남미,MARQUEZ JUBERT,Garcia Maria Victoria Faith,Shimizu Ippei,이성률,김형규,한진 한국지질동맥경화학회 2021 지질·동맥경화학회지 Vol.10 No.2
Objective: Ischemic cardiomyopathy (ICM) is the leading cause of heart failure. Proteomic and genomic studies have demonstrated ischemic preconditioning (IPC) can assert cardioprotection against ICM through mitochondrial function regulation. Considering IPC is conducted in a relatively brief period, regulation of protein expression also occurs very rapidly, highlighting the importance of protein function modulation by post-translational modifications. This study aimed to identify and analyze novel phosphorylated mitochondrial proteins that can be harnessed for therapeutic strategies for preventing ischemia/reperfusion (I/R) injury. Methods: Sprague-Dawley rat hearts were used in an ex vivo Langendorff system to simulate normal perfusion, I/R, and IPC condition, after which the samples were prepared for phosphoproteomic analysis. Employing human cardiomyocyte AC16 cells, we investigated the cardioprotective role of CKMT2 through overexpression and how site-directed mutagenesis of putative CKMT2 phosphorylation sites (Y159A, Y255A, and Y368A) can affect cardioprotection by measuring CKMT2 protein activity, mitochondrial function and protein expression changes. Results: The phosphoproteomic analysis revealed dephosphorylation of mitochondrial creatine kinase (CKMT2) during ischemia and I/R, while preserving its phosphorylated state during IPC. CKMT2 overexpression conferred cardioprotection against hypoxia/reoxygenation (H/R) by increasing cell viability and mitochondrial adenosine triphosphate level, preserving mitochondrial membrane potential, and reduced reactive oxygen species (ROS) generation, while phosphomutations, especially in Y368, nullified cardioprotection by significantly reducing cell viability and increasing ROS production during H/R. CKMT2 overexpression increased mitochondrial function by mediating the proliferator-activated receptor γ coactivator-1α/estrogen-related receptor-α pathway, and these effects were mostly inhibited by Y368A mutation. Conclusion: These results suggest that regulation of quantitative expression and phosphorylation site Y368 of CKMT2 offers a unique mechanism in future ICM therapeutics.
HS-1793 protects C2C12 cells from oxidative stress via mitochondrial function regulation
MARQUEZ JUBERT,Park Nammi,Maria Victoria Faith Garcia,Kim Hyoung Kyu,Han Jin 대한독성 유전단백체 학회 2020 Molecular & cellular toxicology Vol.16 No.4
Background HS1793, a novel analogue of resveratrol, was previously determined to be more potent at lower dosages by improving mitochondrial function and increased mitochondrial biogenesis-related proteins. In this study, we focused on targeting the mitochondria to address muscle wasting with HS-1793. Method Dosage screening was performed by evaluating for cytotoxicity and cell proliferation. Mitochondrial mass, mitochondrial membrane potential (Δψm), reactive oxygen species (ROS) level, and mitochondria biogenesis-regulated genes and proteins were analyzed to determine the efects on mitochondrial biogenesis. Results HS-1793 reduced ROS generation, but treatment did not interfere with cellular viability at low dosages. HS-1793 also regulated mitochondrial function by increasing cellular and mitochondrial ATP synthesis function, stabilizing Δψm and decreasing ROS. More importantly, these dysfunction in these parameters were ameliorated by HS-1793 in a simulated oxidative stress model with tBHP. We also observed increase in mitochondrial mass and upregulation in vital mitochondrial biogenesis-related gene PGC1-α as a response to HS-1793 treatment. Moreover, phosphorylation of AKT and mTOR proteins, which are considered as regulators of skeletal muscle function were also increased during the treatment. Finally, HS-1793 also demonstrated protective efects against cisplatin-induced skeletal muscle cell injury by increasing expression of mitochondrial biogenesis-relate markers. Conclusion Taken altogether, it shows the viability of HS-1793 as a compound that can restore mitochondrial function and render protection in skeletal muscle cells, especially during high oxidative stress levels.