线粒体功能障碍与血管钙化发生的研究进展-《心血管病学进展》

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Title:: Research Progress in Mitochondria Dysfunction and the Development of Vascular Calcification

作者:: 丁姝颖于子翔马依彤; 翔马依彤 (新疆医科大学第一附属医院心脏中心冠心病一科,新疆乌鲁木齐 830054)

Author(s):: DING Shuying; YU Zixiang; MA Yitong; (First Department of Coronary Heart Disease, Heart Center of the First Affiliated Hospital of Xinjiang Medical University,Urumqi 830054,Xinjiang,China)

关键词:: 血管钙化; 血管平滑肌细胞; 线粒体功能障碍

Keywords:: Vascular calcification; Vascular smooth muscle cell; Mitochondrial dysfunction

DOI:: 10.16806/j.cnki.issn.1004-3934.2024.03.014

摘要:: 血管钙化是在衰老、动脉粥样硬化、慢性肾脏病和糖尿病中普遍存在的病理现象。线粒体DNA损伤、线粒体微环境的改变和线粒体自噬异常等均可通过改变线粒体功能影响血管钙化的发生和发展。目前线粒体功能障碍在血管钙化过程中的作用机制尚未完全明确，现将探讨线粒体功能障碍在调控血管钙化的作用和相关机制,为临床治疗血管钙化提供思路。

Abstract:: Vascular calcification is a prevalent pathological phenomenon in senescence, atherosclerosis, chronic kidney disease and diabetes-mellitus. Mitochondrial DNA(mtDNA) damage, alterations in the mitochondrial microenvironment and abnormal mitochondrial autophagy can affect the occurrence and development of vascular calcification by altering mitochondrial function. The role of mitochondrial dysfunction in the process of vascular calcification has not been fully elucidated yet. In this paper we will explore the role of mitochondrial dysfunction and related mechanism in regulating vascular calcification, and provide therapeutic ideas for clinical treatment of vascular calcification

参考文献/References:

[1] Lee SJ,Lee IK,Jeon JH. Vascular calcification-new insights into its mechanism[J]. Int J Mol Sci,2020,21(8):2685.

[2] Tesauro M,Mauriello A,Rovella V,et al. Arterial ageing:from endothelial dysfunction to vascular calcification[J]. J Intern Med,2017,281(5):471-482.

[3] Durham AL,Speer MY,Scatena M,et al. Role of smooth muscle cells in vascular calcification:implications in atherosclerosis and arterial stiffness[J]. Cardiovasc Res,2018,114(4):590-600.

[4] Weber T,Chirinos JA. Pulsatile arterial haemodynamics in heart failure[J]. Eur Heart J,2018,39(43):3847-3854.

[5] Bartolák-Suki E,Imsirovic J,Nishibori Y,et al. Regulation of mitochondrial structure and dynamics by the cytoskeleton and mechanical factors[J]. Int J Mol Sci,2017,18(8):1812.

[6] Luan Y,Luan Y,Yuan RX,et al. Structure and Function of Mitochondria-Associated Endoplasmic Reticulum Membranes (MAMs) and their role in cardiovascular diseases[J]. Oxid Med Cell Longev,2021,2021:4578809.

[7] Liberman M,Marti LC. Vascular Calcification regulation by exosomes in the vascular wall[J]. Adv Exp Med Biol,2017,998:151-160.

[8] Hortells L,Sur S,St Hilaire C. Cell Phenotype Transitions in Cardiovascular Calcification[J]. Front Cardiovasc Med,2018,5:27.

[9] Furmanik M,Chatrou M,van Gorp R,et al. Reactive oxygen-forming Nox5 links vascular smooth muscle cell phenotypic switching and extracellular vesicle-mediated vascular calcification[J]. Circ Res,2020,127(7):911-927.

[10] Zhang ZY,Wang N,Qian LL,et al. Glucose fluctuations promote aortic fibrosis through the ROS/p38 MAPK/Runx2 signaling pathway[J]. J Vasc Res,2020,57(1):24-33.

[11] Tóth A,Balogh E,Jeney V. Regulation of vascular calcification by reactive oxygen species[J]. Antioxidants (Basel),2020,9(10) :963.

[12] Choi Y,Kim MH,Yang WM. Promotion of osteogenesis by Sweroside via BMP2-involved signaling in postmenopausal osteoporosis[J]. Phytother Res,2021,35(12):7050-7063.

[13] Wang P,Zhang N,Wu B,et al. The role of mitochondria in vascular calcification[J]. J Transl Int Med,2020,8(2):80-90.

[14] Li T,Yu H,Zhang D,et al. Matrix vesicles as a therapeutic target for vascular calcification[J]. Front Cell Dev Biol,2022,10:825622.

[15] El-Hattab AW,Craigen WJ,Scaglia F. Mitochondrial DNA maintenance defects[J]. Biochim Biophys Acta Mol Basis Dis,2017,1863(6):1539-1555.

[16] Lee KM,Lee EO,Lee YR,et al. APE1/Ref-1 inhibits phosphate-induced calcification and osteoblastic phenotype changes in vascular smooth muscle cells[J].Int J Mol Sci,2017,18(10):2053.

[17] Yu E,Calvert PA,Mercer JR,et al. Mitochondrial DNA damage can promote atherosclerosis independently of reactive oxygen species and correlates with higher risk plaques in humans [J]. Atherosclerosis,2014,232(2):e3.

[18] Wang P,Wu B,You S,et al. DNA polymerase gamma recovers mitochondrial function and inhibits vascular calcification by interacted with p53[J]. Int J Biol Sci,2022,18(1):409-425.

[19] Liu YF,Zhu JJ,Yu Tian X,et al. Hypermethylation of mitochondrial DNA in vascular smooth muscle cells impairs cell contractility[J]. Cell Death Dis,2020,11(1):35.

[20] Shoji T,Isao S,Kohei T,et al. Domain structure of the Dnmt1,Dnmt3a,and Dnmt3b DNA methyltransferases[J]. Adv Exp Med Biol,2022,1389:45-68.

[21] Facchinello N,Laquatra C,Locatello L,et al. Efficient clofilium tosylate-mediated rescue of POLG-related disease phenotypes in zebrafish[J]. Cell Death Dis,2021,12(1):100.

[22] Ferrari M,Stagi S. Oxidative stress in down and williams-beuren syndromes:an overview[J]. Molecules,2021,26(11):3139.

[23] Byon CH,Heath JM,Chen Y. Redox signaling in cardiovascular pathophysiology:A focus on hydrogen peroxide and vascular smooth muscle cells[J]. Redox Biol,2016,9:244-253.

[24] Li M,Zhu Y,Jaiswal SK,et al. Mitochondria homeostasis and vascular medial calcification[J]. Calcif Tissue Int,2021,109(2):113-120.

[25] Sena CM,Leandro A,Azul L,et al. Vascular oxidative stress:impact and therapeutic approaches[J]. Front Physiol,2018,9:1668.

[26] Liu Y,Zhu JG,Cheng BC,et al. An association between time-varying serum alkaline phosphatase concentrations and mortality rate in patients undergoing peritoneal dialysis:a five-year cohort study[J]. Sci Rep,2017,7:43314.

[27] Sabouny R,Shutt TE. Reciprocal regulation of mitochondrial fission and fusion[J]. Trends Biochem Sci,2020,45(7):564-577.

[28] Cui L,Li Z,Chang X,et al. Quercetin attenuates vascular calcification by inhibiting oxidative stress and mitochondrial fission[J]. Vascul Pharmacol,2017,88:21-29.

[29] Wang L,Yu T,Lee H,et al. Decreasing mitochondrial fission diminishes vascular smooth muscle cell migration and ameliorates intimal hyperplasia[J]. Cardiovasc Res,2015,106(2):272-283.

[30] Chen WR,Zhou YJ,Sha Y,et al. Melatonin attenuates vascular calcification by inhibiting mitochondria fission via an AMPK/Drp1 signalling pathway[J]. J Cell Mol Med,2020,24(11):6043-6054.

[31] Rogers MA,Maldonado N,Hutcheson JD,et al. Dynamin-related protein 1 inhibition attenuates cardiovascular calcification in the presence of oxidative stress[J]. Circ Res,2017,121(3):220-233.

[32] Phadwal K,Vrahnas C,Ganley IG,et al. Mitochondrial dysfunction:cause or consequence of vascular calcification?[J]. Front Cell Dev Biol,2021,9:611922.

[33] Kim H,Kim HJ,Lee K,et al. alpha-Lipoic acid attenuates vascular calcification via reversal of mitochondrial function and restoration of Gas6/Axl/Akt survival pathway[J]. J Cell Mol Med,2012,16(2):273-286.

[34] Wang J,Zhu P,Li R,et al. Bax inhibitor 1 preserves mitochondrial homeostasis in acute kidney injury through promoting mitochondrial retention of PHB2[J]. Theranostics,2020, 10(1):384-397.

[35] Nguyen NT,Nguyen TT,Da Ly D,et al. Oxidative stress by Ca2+ overload is critical for phosphate-induced vascular calcification[J]. Am J Physiol Heart Circ Physiol,2020,319(6):H1302-H1312.

[36] Al-Aly Z. Phosphate,oxidative stress,and nuclear factor-kappaB activation in vascular calcification [J]. Kidney Int,2011,79(10):1044-1047.

[37] Nguyen TT,Quan X,Xu S,et al. Intracellular alkalinization by phosphate uptake via type III sodium-phosphate cotransporter participates in high-phosphate-induced mitochondrial oxidative stress and defective insulin secretion[J]. FASEB J,2016,30(12):3979-3988.

[38] Phadwal K,Feng D,Zhu D,et al. Autophagy as a novel therapeutic target in vascular calcification[J]. Pharmacol Ther,2020,206:107430.

[39] Bi W,Jia J,Pang R,et al. Thyroid hormone postconditioning protects hearts from ischemia/reperfusion through reinforcing mitophagy[J]. Biomed Pharmacother,2019,118:109220.

[40] Zhu Y,Han XQ,Sun XJ,et al. Lactate accelerates vascular calcification through NR4A1-regulated mitochondrial fission and BNIP3-related mitophagy[J]. Apoptosis,2020,25(5-6):321-340.

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