Quercetin and Its Derivative Counteract Palmitate-Dependent Lipotoxicity by Inhibiting Oxidative Stress and Inflammation in Cardiomyocytes

Cardiac lipotoxicity plays an important role in the pathogenesis of obesity-related cardiovascular disease. The flavonoid quercetin (QUE), a nutraceutical compound that is abundant in the “Mediterranean diet”, has been shown to be a potential therapeutic agent in cardiac and metabolic diseases. Here, we investigated the beneficial role of QUE and its derivative Q2, which demonstrates improved bioavailability and chemical stability, in cardiac lipotoxicity. To this end, H9c2 cardiomyocytes were pre-treated with QUE or Q2 and then exposed to palmitate (PA) to recapitulate the cardiac lipotoxicity occurring in obesity. Our results showed that both QUE and Q2 significantly attenuated PA-dependent cell death, although QUE was effective at a lower concentration (50 nM) when compared with Q2 (250 nM). QUE decreased the release of lactate dehydrogenase (LDH), an important indicator of cytotoxicity, and the accumulation of intracellular lipid droplets triggered by PA. On the other hand, QUE protected cardiomyocytes from PA-induced oxidative stress by counteracting the formation of malondialdehyde (MDA) and protein carbonyl groups (which are indicators of lipid peroxidation and protein oxidation, respectively) and intracellular ROS generation, and by improving the enzymatic activities of catalase and superoxide dismutase (SOD). Pre-treatment with QUE also significantly attenuated the inflammatory response induced by PA by reducing the release of key proinflammatory cytokines (IL-1β and TNF-α). Similar to QUE, Q2 (250 nM) also significantly counteracted the PA-provoked increase in intracellular lipid droplets, LDH, and MDA, improving SOD activity and decreasing the release of IL-1β and TNF-α. These results suggest that QUE and Q2 could be considered potential therapeutics for the treatment of the cardiac lipotoxicity that occurs in obesity and metabolic diseases.

[1]  V. Di Liberto,et al.  Correlation of Metabolic Syndrome with Redox Homeostasis Biomarkers: Evidence from High-Fat Diet Model in Wistar Rats , 2022, Antioxidants.

[2]  N. Kadoglou,et al.  Potential Pharmaceutical Applications of Quercetin in Cardiovascular Diseases , 2022, Pharmaceuticals.

[3]  Myeong-sok Lee,et al.  Application of chitosan/alginate nanoparticle in oral drug delivery systems: prospects and challenges , 2022, Drug delivery.

[4]  V. Rago,et al.  The Antioxidant Selenoprotein T Mimetic, PSELT, Induces Preconditioning-like Myocardial Protection by Relieving Endoplasmic-Reticulum Stress , 2022, Antioxidants.

[5]  A. Hayes,et al.  Natural and chemical compounds as protective agents against cardiac lipotoxicity. , 2021, Biomedicine & pharmacotherapy = Biomedecine & pharmacotherapie.

[6]  E. Çapanoğlu,et al.  Recent advances on the improvement of quercetin bioavailability , 2021, Trends in Food Science & Technology.

[7]  Heping Zhou,et al.  Role of CD36 in Palmitic Acid Lipotoxicity in Neuro-2a Neuroblastoma Cells , 2021, Biomolecules.

[8]  M. Aschner,et al.  Current Status and Future Perspectives on Therapeutic Potential of Apigenin: Focus on Metabolic-Syndrome-Dependent Organ Dysfunction , 2021, Antioxidants.

[9]  V. Rago,et al.  Carbazole and Simplified Derivatives: Novel Tools toward β-Adrenergic Receptors Targeting , 2021 .

[10]  Jun Ren,et al.  Obesity cardiomyopathy: evidence, mechanisms, and therapeutic implications , 2021, Physiological reviews.

[11]  XiuTeng Zhou,et al.  Quercetin Improves Cardiomyocyte Vulnerability to Hypoxia by Regulating SIRT1/TMBIM6-Related Mitophagy and Endoplasmic Reticulum Stress , 2021, Oxidative medicine and cellular longevity.

[12]  Songtao Li,et al.  Inhibition of TLR4/MAPKs Pathway Contributes to the Protection of Salvianolic Acid A Against Lipotoxicity-Induced Myocardial Damage in Cardiomyocytes and Obese Mice , 2021, Frontiers in Pharmacology.

[13]  F. Giordano,et al.  Cateslytin abrogates lipopolysaccharide-induced cardiomyocyte injury by reducing inflammation and oxidative stress through toll like receptor 4 interaction. , 2021, International immunopharmacology.

[14]  L. Lerman,et al.  Quercetin Reverses Cardiac Systolic Dysfunction in Mice Fed with a High-Fat Diet: Role of Angiogenesis , 2021, Oxidative medicine and cellular longevity.

[15]  T. Pasqua,et al.  Cardiometabolism as an Interlocking Puzzle between the Healthy and Diseased Heart: New Frontiers in Therapeutic Applications , 2021, Journal of clinical medicine.

[16]  P. Li,et al.  Quercetin: Its Main Pharmacological Activity and Potential Application in Clinical Medicine , 2020, Oxidative medicine and cellular longevity.

[17]  I. Perrotta,et al.  Cardiac and Metabolic Impact of Functional Foods with Antioxidant Properties Based on Whey Derived Proteins Enriched with Hemp Seed Oil , 2020, Antioxidants.

[18]  A. Corti,et al.  The chromogranin A1‐373 fragment reveals how a single change in the protein sequence exerts strong cardioregulatory effects by engaging neuropilin‐1 , 2020, Acta physiologica.

[19]  Xiangdong Gao,et al.  A novel oral glucagon-like peptide 1 receptor agonist protects against diabetic cardiomyopathy via alleviating cardiac lipotoxicity induced mitochondria dysfunction. , 2020, Biochemical pharmacology.

[20]  Shin Sato,et al.  Modulation of Chronic Inflammation by Quercetin: The Beneficial Effects on Obesity , 2020, Journal of inflammation research.

[21]  T. Pasqua,et al.  Cardiac damage in anthracyclines therapy: focus on oxidative stress and inflammation. , 2020, Antioxidants & redox signaling.

[22]  P. Macchia,et al.  Quercetin and its derivative Q2 modulate chromatin dynamics in adipogenesis and Q2 prevents obesity and metabolic disorders in rats. , 2019, The Journal of nutritional biochemistry.

[23]  R. Inagi,et al.  Lipotoxicity in Kidney, Heart, and Skeletal Muscle Dysfunction , 2019, Nutrients.

[24]  Y. Anouar,et al.  Progress in the emerging role of selenoproteins in cardiovascular disease: focus on endoplasmic reticulum-resident selenoproteins , 2019, Cellular and Molecular Life Sciences.

[25]  He Huang,et al.  Myeloid differentiation protein 1 protected myocardial function against high‐fat stimulation induced pathological remodelling , 2019, Journal of cellular and molecular medicine.

[26]  Jai-Sing Yang,et al.  High-density lipoprotein ameliorates palmitic acid-induced lipotoxicity and oxidative dysfunction in H9c2 cardiomyoblast cells via ROS suppression , 2019, Nutrition & Metabolism.

[27]  S. Rabkin,et al.  Hypoxia‐inducible factor 1‐alpha (HIF‐1α) as a factor mediating the relationship between obesity and heart failure with preserved ejection fraction , 2019, Obesity reviews : an official journal of the International Association for the Study of Obesity.

[28]  A. Corti,et al.  Physiological levels of chromogranin A prevent doxorubicin‐induced cardiotoxicity without impairing its anticancer activity , 2019, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[29]  A. Kriegel,et al.  miR-21-5p regulates mitochondrial respiration and lipid content in H9C2 cells. , 2019, American journal of physiology. Heart and circulatory physiology.

[30]  M. He,et al.  Quercetin protects cardiomyocytes against doxorubicin-induced toxicity by suppressing oxidative stress and improving mitochondrial function via 14-3-3γ , 2019, Toxicology mechanisms and methods.

[31]  D. Sriram,et al.  Inhibition of protein kinase R protects against palmitic acid–induced inflammation, oxidative stress, and apoptosis through the JNK/NF‐kB/NLRP3 pathway in cultured H9C2 cardiomyocytes , 2018, Journal of cellular biochemistry.

[32]  B. Rizzuti,et al.  A pilot study on the nutraceutical properties of the Citrus hybrid Tacle® as a dietary source of polyphenols for supplementation in metabolic disorders , 2019, Journal of Functional Foods.

[33]  G. Statti,et al.  Leopoldia comosa prevents metabolic disorders in rats with high-fat diet-induced obesity , 2019, European Journal of Nutrition.

[34]  J. Schaffer,et al.  Manifestations and mechanisms of myocardial lipotoxicity in obesity , 2018, Journal of internal medicine.

[35]  K. Raghu,et al.  Chlorogenic acid attenuates glucotoxicity in H9c2 cells via inhibition of glycation and PKC α upregulation and safeguarding innate antioxidant status. , 2018, Biomedicine & pharmacotherapy = Biomedecine & pharmacotherapie.

[36]  L. Forney,et al.  Dietary Quercetin Attenuates Adipose Tissue Expansion and Inflammation and Alters Adipocyte Morphology in a Tissue-Specific Manner , 2018, International journal of molecular sciences.

[37]  Corby K. Martin,et al.  Obesity: Pathophysiology and Management. , 2018, Journal of the American College of Cardiology.

[38]  Tianyi Liu,et al.  Antioxidants Maintain Cellular Redox Homeostasis by Elimination of Reactive Oxygen Species , 2017, Cellular Physiology and Biochemistry.

[39]  Xiaoyan Li,et al.  Palmitate induces myocardial lipotoxic injury via the endoplasmic reticulum stress‑mediated apoptosis pathway. , 2017, Molecular medicine reports.

[40]  C. Rosano,et al.  New insights for the use of quercetin analogs in cancer treatment. , 2017, Future medicinal chemistry.

[41]  Abdelrahman Ibrahim Abushouk,et al.  Cardioprotective mechanisms of phytochemicals against doxorubicin-induced cardiotoxicity. , 2017, Biomedicine & pharmacotherapy = Biomedecine & pharmacotherapie.

[42]  D. Hădărugă,et al.  Berberis vulgaris extract/β-cyclodextrin complex increases protection of hepatic cells via suppression of apoptosis and lipogenesis pathways , 2017, Experimental and therapeutic medicine.

[43]  N. Giribabu,et al.  Quercetin ameliorates oxidative stress, inflammation and apoptosis in the heart of streptozotocin-nicotinamide-induced adult male diabetic rats. , 2017, Biomedicine & pharmacotherapy = Biomedecine & pharmacotherapie.

[44]  L. Ly,et al.  Oxidative stress and calcium dysregulation by palmitate in type 2 diabetes , 2017, Experimental &Molecular Medicine.

[45]  Xiaokun Li,et al.  Saturated palmitic acid induces myocardial inflammatory injuries through direct binding to TLR4 accessory protein MD2 , 2017, Nature Communications.

[46]  S. Goyal,et al.  Cardioprotective Potentials of Plant-Derived Small Molecules against Doxorubicin Associated Cardiotoxicity , 2016, Oxidative medicine and cellular longevity.

[47]  Yulong Yin,et al.  Quercetin, Inflammation and Immunity , 2016, Nutrients.

[48]  A. Brancale,et al.  Quercetin derivatives as novel antihypertensive agents: Synthesis and physiological characterization. , 2016, European journal of pharmaceutical sciences : official journal of the European Federation for Pharmaceutical Sciences.

[49]  H. Colecraft,et al.  Inhibition of NAPDH Oxidase 2 (NOX2) Prevents Oxidative Stress and Mitochondrial Abnormalities Caused by Saturated Fat in Cardiomyocytes , 2016, PloS one.

[50]  E. Kurutaş The importance of antioxidants which play the role in cellular response against oxidative/nitrosative stress: current state , 2015, Nutrition Journal.

[51]  Amit Jain,et al.  Role of Antioxidants for the Treatment of Cardiovascular Diseases: Challenges and Opportunities. , 2015, Current pharmaceutical design.

[52]  G. Sweeney,et al.  Palmitate Induces ER Stress and Autophagy in H9c2 Cells: Implications for Apoptosis and Adiponectin Resistance , 2015, Journal of cellular physiology.

[53]  K. Otsu,et al.  MicroRNA-451 Exacerbates Lipotoxicity in Cardiac Myocytes and High-Fat Diet-Induced Cardiac Hypertrophy in Mice Through Suppression of the LKB1/AMPK Pathway , 2015, Circulation research.

[54]  Sherven Sharma,et al.  Quercetin attenuates doxorubicin cardiotoxicity by modulating Bmi‐1 expression , 2014, British journal of pharmacology.

[55]  Jae-Ho Kim,et al.  Multiple pathways are involved in palmitic acid-induced toxicity. , 2014, Food and chemical toxicology : an international journal published for the British Industrial Biological Research Association.

[56]  G. Lopaschuk,et al.  Mitochondrial fatty acid oxidation alterations in heart failure, ischaemic heart disease and diabetic cardiomyopathy , 2014, British journal of pharmacology.

[57]  E. Novellino,et al.  Biological activity of 3-chloro-azetidin-2-one derivatives having interesting antiproliferative activity on human breast cancer cell lines. , 2013, Bioorganic & medicinal chemistry letters.

[58]  Linyi Chen,et al.  Cardioprotective Effects of Quercetin in Cardiomyocyte under Ischemia/Reperfusion Injury , 2013, Evidence-based complementary and alternative medicine : eCAM.

[59]  Yan Li,et al.  Palmitate induces H9c2 cell apoptosis by increasing reactive oxygen species generation and activation of the ERK1/2 signaling pathway. , 2013, Molecular medicine reports.

[60]  Xiao-Feng Zhu,et al.  Flavonoids from Malus hupehensis and their cardioprotective effects against doxorubicin-induced toxicity in H9c2 cells. , 2013, Phytochemistry.

[61]  C. Jung,et al.  Quercetin Reduces High‐Fat Diet‐Induced Fat Accumulation in the Liver by Regulating Lipid Metabolism Genes , 2013, Phytotherapy research : PTR.

[62]  H. Zheng,et al.  Globular adiponectin protects H9c2 cells from palmitate-induced apoptosis via Akt and ERK1/2 signaling pathways , 2012, Lipids in Health and Disease.

[63]  Jun Ren,et al.  Pathophysiological Insights into Cardiovascular Health in Metabolic Syndrome , 2012, Experimental diabetes research.

[64]  L. Brown,et al.  Quercetin ameliorates cardiovascular, hepatic, and metabolic changes in diet-induced metabolic syndrome in rats. , 2012, The Journal of nutrition.

[65]  C. Glass,et al.  Inflammation and lipid signaling in the etiology of insulin resistance. , 2012, Cell metabolism.

[66]  W. Koch,et al.  Cardiomyocyte lipids impair β-adrenergic receptor function via PKC activation. , 2011, American journal of physiology. Endocrinology and metabolism.

[67]  H. Choo,et al.  Enhanced stability and intracellular accumulation of quercetin by protection of the chemically or metabolically susceptible hydroxyl groups with a pivaloxymethyl (POM) promoiety. , 2010, Journal of medicinal chemistry.

[68]  C. Chen,et al.  Improvement of mechanical heart function by trimetazidine in db/db mice , 2010, Acta Pharmacologica Sinica.

[69]  E. Abel,et al.  Lipotoxicity in the heart. , 2010, Biochimica et biophysica acta.

[70]  F. Kim,et al.  Activation of NF-&kgr;B by Palmitate in Endothelial Cells: A Key Role for NADPH Oxidase-Derived Superoxide in Response to TLR4 Activation , 2009, Arteriosclerosis, thrombosis, and vascular biology.

[71]  M. Lubberink,et al.  Altered myocardial substrate metabolism is associated with myocardial dysfunction in early diabetic cardiomyopathy in rats: studies using positron emission tomography , 2009, Cardiovascular diabetology.

[72]  B. Lacour,et al.  Protective effect of eicosapentaenoic acid on palmitate-induced apoptosis in neonatal cardiomyocytes. , 2008, Biochimica et biophysica acta.

[73]  Randal J. Kaufman,et al.  From endoplasmic-reticulum stress to the inflammatory response , 2008, Nature.

[74]  Benjamin D. Levine,et al.  Cardiac Steatosis in Diabetes Mellitus: A 1H-Magnetic Resonance Spectroscopy Study , 2007, Circulation.

[75]  Teresa Chen,et al.  Attenuation by metallothionein of early cardiac cell death via suppression of mitochondrial oxidative stress results in a prevention of diabetic cardiomyopathy. , 2006, Journal of the American College of Cardiology.

[76]  L. Cai Suppression of nitrative damage by metallothionein in diabetic heart contributes to the prevention of cardiomyopathy. , 2006, Free radical biology & medicine.

[77]  D. Severson Diabetic cardiomyopathy: recent evidence from mouse models of type 1 and type 2 diabetes. , 2004, Canadian journal of physiology and pharmacology.

[78]  C. Vagianos,et al.  Gut regulatory peptides bombesin and neurotensin reduce hepatic oxidative stress and histological alterations in bile duct ligated rats , 2004, Regulatory Peptides.

[79]  C. Gullion,et al.  The incidence of congestive heart failure in type 2 diabetes: an update. , 2004, Diabetes care.

[80]  G. Shulman,et al.  PKC-theta knockout mice are protected from fat-induced insulin resistance. , 2004, The Journal of clinical investigation.

[81]  Robert V Farese,et al.  Triglyceride accumulation protects against fatty acid-induced lipotoxicity , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[82]  L. Orci,et al.  Lipoapoptosis: its mechanism and its diseases. , 2002, Biochimica et biophysica acta.

[83]  S. Rabkin,et al.  Palmitate-induced apoptosis in cardiomyocytes is mediated through alterations in mitochondria: prevention by cyclosporin A. , 2000, Biochimica et biophysica acta.

[84]  J. Niebauer Inflammatory mediators in heart failure. , 2000, International journal of cardiology.

[85]  S. Anker,et al.  The role of inflammatory mediators in chronic heart failure: cytokines, nitric oxide, and endothelin-1. , 2000, International journal of cardiology.

[86]  S. Grundy,et al.  Diabetes and cardiovascular disease: a statement for healthcare professionals from the American Heart Association. , 1999, Circulation.

[87]  D. Mann,et al.  The role of cytokines in disease progression in heart failure. , 1997, Current opinion in cardiology.

[88]  L. Packer,et al.  Oxidative damage to proteins: spectrophotometric method for carbonyl assay. , 1994, Methods in enzymology.

[89]  G. Schultz,et al.  Morphological, biochemical, and electrophysiological characterization of a clonal cell (H9c2) line from rat heart. , 1991, Circulation research.

[90]  H. Aebi,et al.  Catalase in vitro. , 1984, Methods in enzymology.

[91]  J. Doroshow,et al.  Enzymatic defenses of the mouse heart against reactive oxygen metabolites: alterations produced by doxorubicin. , 1980, The Journal of clinical investigation.

[92]  S. Marklund,et al.  Involvement of the superoxide anion radical in the autoxidation of pyrogallol and a convenient assay for superoxide dismutase. , 1974, European journal of biochemistry.

[93]  M. McQueen Optimal Assay of LDH and α-HBD at 37 °C , 1972 .