氯化钴通过诱发DNA氧化损伤抑制猪卵泡颗粒细胞增殖的研究

doi:10.11843/j.issn.0366-6964.2022.09.015

Abstract

Abstract: The study aimed to study the effect of DNA oxidative damage induced by cobalt chloride (CoCl₂) on the proliferation of porcine follicular granulosa cells. Porcine follicular granulosa cells were used as experimental materials, and hypoxia model was established by treating porcine follicular granulosa cells with chemical hypoxia model inducer CoCl₂. In the previous study, the optimal treatment concentration of CoCl₂was determined. Porcine follicular granulosa cells were treated with 200 μmol·L^-1 CoCl₂ for 12 h, and the cultured passage cells were divided into 4 groups for treatment, as follows:control group, CoCl₂-induced hypoxia treatment group, GSH treatment group, GSH+CoCl₂ combined treatment group. Cells in control group was cultured in complete medium for 12 h; Cells in CoCl₂-induced hypoxia treatment group was cultured in medium with final concentration of 200 μmol·L^-1 CoCl₂ for 12 h; Cells in GSH treatment group was treated with GSH at a concentration of 2 mmol·L^-1 for 12 h; Cells in the GSH+CoCl₂ combined treatment group was treated with 200 μmol·L^-1 CoCl₂ and 2 mmol·L^-1 GSH for 12 h. After 12 h, the proliferation activity, ROS level, γH2AX protein activity and Oxo-8-G level of each group were detected. CCK-8 assay was used to detect its proliferation activity. ROS levels were determined by 2', 7'-dichlorofluorescin diacetate (DCFH-DA). Western blot was used to detect the protein activity of γH2AX, and FITC fluorescent mouse monoclonal antibody was used to detect Oxo-8-G. In order to further clarify the relationship between CoCl₂-induced granulosa cell proliferation arrest and DNA oxidative damage, this experiment added antioxidant GSH on the basis of CoCl₂ treatment for 12 h to detect cell proliferation, ROS level, DNA oxidative damage and other related indicators. Compared with the control group, the proliferation activity of porcine follicular granulosa cells treated with 200 μmol·L^-1 CoCl₂ was significantly decreased (P<0.000 1), and the ROS level, γH2AX protein expression and Oxo-8-G level in hypoxia group were significantly increased (P<0.000 1). Compared with the hypoxia group, the levels of ROS, Oxo-8-G and γH2AX were significantly decreased by adding GSH on the basis of CoCl₂ treatment (P<0.000 1), and the proliferation activity of cells was significantly recovered by adding GSH (P<0.000 1). CoCl₂ can inhibit the proliferation activity of porcine follicular granulosa cells, and the mechanism is related to the damage of DNA induced by oxidative stress.

Key words: cobalt chloride, chemical hypoxia, porcine follicular granulosa cells, cell proliferation, DNA oxidative damage

CLC Number:

S828.3

WEI Jiayuan, ZHU Qian, YANG Yaxing, SHEN Ming. Inhibition of Porcine Follicular Granulosa Cell Proliferation by Cobalt Chloride Induced DNA Oxidative Damage[J]. Acta Veterinaria et Zootechnica Sinica, 2022, 53(9): 2982-2992.

References 38

[1]	LI C Y, LIU Z J, WU G, et al.FOXO1 mediates hypoxia-induced G0/G1 arrest in ovarian somatic granulosa cells by activating the TP53INP1-p53-CDKN1A pathway[J].Development, 2021, 148(14):dev199453.
[2]	刘召远, 张正红, 吴佳琦, 等.组织缺氧在黄体形成过程中的作用[J].中国医学科学院学报, 2019, 41(6):837-841.LIU Z Y, ZHANG Z H, WU J Q, et al.Contribution of tissue hypoxia to corpus luteum formation[J].Acta Academiae Medicinae Sinicae, 2019, 41(6):837-841.(in Chinese)
[3]	杜秀雅, 马华刚.血管新生相关因子对卵泡生长发育影响的研究进展[J].中国计划生育学杂志, 2014, 22(7):502-504.DU X Y, MA H G.Research on the impact of vascular related factors on the growth and development of follicles[J].Chinese Journal of Family Planning, 2014, 22(7):502-504.(in Chinese)
[4]	傅夏燕, 陈其臻, 尹喆, 等.缺氧诱导因子-1调控卵泡发育的研究进展[J].同济大学学报:医学版, 2021, 42(1):136-141.FU X Y, CHEN Q Z, YIN Z, et al.Research progress of hypoxia inducible factor-1 on follicular development[J].Journal of Tongji University:Medical Science, 2021, 42(1):136-141.(in Chinese)
[5]	LI C Y, MENG X Q, LIU S, et al.Oocytes and hypoxanthine orchestrate the G2-M switch mechanism in ovarian granulosa cells[J]. Development, 2020, 147(13):dev184838.
[6]	WU G, LI C Y, TAO J L, et al.FSH mediates estradiol synthesis in hypoxic granulosa cells by activating glycolytic metabolism through the HIF-1α-AMPK-GLUT1 signaling pathway[J].J Biol Chem, 2022, 298(5):101830.
[7]	TEMPKA D, TOKARZ P, CHMIELEWSKA K, et al.Downregulation of PARP1 transcription by CDK4/6 inhibitors sensitizes human lung cancer cells to anticancer drug-induced death by impairing OGG1-dependent base excision repair[J].Redox Biol, 2018, 15:316-326.
[8]	RANA N K, SINGH P, KOCH B.CoCl2 simulated hypoxia induce cell proliferation and alter the expression pattern of hypoxia associated genes involved in angiogenesis and apoptosis[J].Biol Res, 2019, 52(1):12.
[9]	DAI Z J, GAO J, MA X B, et al.Up-regulation of hypoxia inducible factor-1α by cobalt chloride correlates with proliferation and apoptosis in PC-2 cells[J].J Exp Clin Cancer Res, 2012, 31(1):28.
[10]	CHU C Y, JIN Y T, ZHANG W, et al.CA IX is upregulated in CoCl2-induced hypoxia and associated with cell invasive potential and a poor prognosis of breast cancer[J].Int J Oncol, 2016, 48(1):271-280.
[11]	史华旭, 吴子一, 陈世奇, 等.DNA氧化损伤标志物8-羟基脱氧鸟苷检测方法及其临床意义[J].沈阳医学院学报, 2019, 21(1):79-82.SHI H X, WU Z Y, CHEN S Q, et al.Detection methods of oxidative DNA damage marker 8-hydroxy-2-deoxyguanosine and its clinical significance[J].Journal of Shenyang Medical College, 2019, 21(1):79-82.(in Chinese)
[12]	凌学斌, 王军, 綦苗苗, 等.缺氧、缺氧/复氧对心肌细胞内ROS、MAPKs活性表达的影响[J].海南医学院学报, 2021, 27(7):481-487.LING X B, WANG J, QI M M, et al.Effect of hypoxia and hypoxia/reoxygenation on the viability expression of ROS and MAPKs in myocardial cells[J].Journal of Hainan Medical University, 2021, 27(7) 481-487.(in Chinese)
[13]	郑坤, 嘎鲁, 马宇衡, 等.活性氧(ROS)依赖性抗肿瘤药物的研究进展[J].广东药科大学学报, 2022, 38(1):130-136.ZHENG K, GA L, MA Y H, et al.Research progress of reactive oxygen species(ROS)-dependent anticancer drugs[J].Journal of Guangdong Pharmaceutical University, 2022, 38(1):130-136.(in Chinese)
[14]	ORTMANN B, DRUKER J, ROCHA S.Cell cycle progression in response to oxygen levels[J].Cell Mol Life Sci, 2014, 71(18):3569-3582.
[15]	FADHILLAH, YOSHIOKA S, NISHIMURA R, et al.Hypoxia promotes progesterone synthesis during luteinization in bovine granulosa cells[J].J Reprod Dev, 2014, 60(3):194-201.
[16]	朱轶轩, 董晓英.基于氧感知通路探讨早发性卵巢功能不全发生机制的研究进展[J].中国医药导报, 2021, 18(22):55-58.ZHU Y X, DONG X Y.Research progress in the pathogenesis of premature ovarian insufficiency based on oxygen sensing pathway[J].China Medical Herald, 2021, 18(22):55-58.(in Chinese)
[17]	REDMER D A, REYNOLDS L P.Angiogenesis in the ovary[J].Rev Reprod, 1996, 1(3):182-192.
[18]	BASINI G, BIANCO F, GRASSELLI F, et al.The effects of reduced oxygen tension on swine granulosa cell[J].Regul Pept, 2004, 120(1-3):69-75.
[19]	GARDNER L B, LI Q, PARK M S, et al.Hypoxia inhibits G1/S transition through regulation of p27 expression[J].J Biol Chem, 2001, 276(11):7919-7926.
[20]	LIU Y, ZHANG S L, SU D C, et al.Inhibiting (pro)renin receptor-mediated p38 MAPK signaling decreases hypoxia/reoxygenation-induced apoptosis in H9c2 cells[J].Mol Cell Biochem, 2015, 403(1-2):267-276.
[21]	肖婷婷, 王莉, 曹相玫, 等.氯化钴对小鼠海马神经元细胞缺氧损伤的影响[J].神经解剖学杂志, 2020, 36(4):439-444.XIAO T T, WANG L, CAO X M, et al. Effects of cobalt chloride on hypoxic injury of hippocampal neurons in mice[J].Chinese Journal of Neuroanatomy, 2020, 36(4):439-444.(in Chinese)
[22]	PIRET J P, MOTTET D, RAES M, et al.CoCl2, a chemical inducer of hypoxia-inducible factor-1, and hypoxia reduce apoptotic cell death in hepatoma cell line HepG2[J].Ann N Y Acad Sci, 2002, 973(1):443-447.
[23]	CIAFRō S A, NIOLA F, GIORDA E, et al.CoCl2-simulated hypoxia in skeletal muscle cell lines:role of free radicals in gene up-regulation and induction of apoptosis[J].Free Radic Res, 2007, 41(4):391-401.
[24]	刘菲, 张昊, 刘博, 等.氯化钴诱导的N2a细胞缺氧损伤模型的机制研究[J].广东药科大学学报, 2020, 36(2):249-253.LIU F, ZHANG H, LIU B, et al.Mechanism of cobalt chloride induced hypoxia on N2a cells[J].Journal of Guangdong Pharmaceutical University, 2020, 36(2):249-253.(in Chinese)
[25]	马雪, 张晓馨, 史清海, 等.氯化钴诱导大鼠原代脑微血管内皮细胞缺氧损伤的实验研究[J].新疆医科大学学报, 2017, 40(8):1051-1055, 1060.MA X, ZHANG X X, SHI Q H, et al.Experimental study on primary rat brain microvascular endothelial cells in hypoxia injury induced by cobalt chloride[J].Journal of Xinjiang Medical University, 2017, 40(8):1051-1055, 1060.(in Chinese)
[26]	GAO X X, LIU C H, HU Z L, et al.The biological effect of cobalt chloride mimetic-hypoxia on nucleus pulposus cells and the comparability with physical hypoxia in vitro[J].Front Biosci (Landmark Ed), 2021, 26(10):799-812.
[27]	朱梦怡, 柯敏霞, 王皓, 等.氯化钴诱导hiPSC-CMs体外缺氧模型的建立[J].浙江理工大学学报:自然科学版, 2021, 45(1):84-93.ZHU M Y, KE M X, WANG H, et al.Establishment of a CoCl2-mediated in vitro hiPSC-CMs hypoxia model[J].Journal of Zhejiang Sci-Tech University:Natural Sciences Edition, 2021, 45(1):84-93.(in Chinese)
[28]	黄佳诚.低氧模拟剂氯化钴对大鼠脂肪来源间充质干细胞体外增殖、成脂分化及迁移的影响的初步研究[D].广州:南方医科大学, 2014.HUANG J C.The effect of hypoxic condition establish by CoCl2 on the proliferation, adipogenic differentiation and migration of Rat adipose-derived stem cells in vitro[D].Guangzhou:Southern Medical University, 2014.(in Chinese)
[29]	翁苓苓, 高玲, 张闽光.CoCl2化学模拟肝癌体外缺氧模型的建立及对HIF-1α、VEGF基因的影响[J].肝脏, 2019, 24(9):1049-1052.WENG L L, GAO L, ZHANG M G.CoCl2 chemical simulation of the establishment of liver cancer hypoxic models and the impact on the HIF-1α and VEGF genes[J].Chinese Hepatology, 2019, 24(9):1049-1052.(in Chinese)
[30]	刘芳.藏羚羊STAT3、HIF-1α和HIF-2α基因表达的生物学意义[D].西宁:青海大学, 2012.LIU F.Biological Significance of signal transducer and activator of transcription 3, hypoxia inducible factor 1 alpha and hypoxia inducible factor 2 alpha in high altitude hypoxic adaptation species-Tibetan antelope[D].Xining:Qinghai University, 2012.(in Chinese)
[31]	HUANG Y, TAN F B, ZHOU Y, et al.Hypoxia-preconditioned olfactory mucosa mesenchymal stem cells abolish cerebral ischemia/reperfusion-induced pyroptosis and apoptotic death of microglial cells by activating HIF-1α[J].Aging (Albany NY), 2020, 12(11):10931-10950.
[32]	梁楚婷, 郭炜骅, 谭理, 等.低氧诱导因子-1:细胞适应氧供应改变的关键蛋白[J].生物化学与生物物理进展, 2019, 46(11):1041-1049.LIANG C T, GUO W H, TAN L, et al.Hypoxia-inducible factor-1:a key protein for cells adapting to changes in oxygen supply[J]. Progress in Biochemistry and Biophysics, 2019, 46(11):1041-1049.(in Chinese)
[33]	LIU Y H, GUO C, SUN Y Q, et al.Polymorphisms in HIF-1a gene are not associated with diabetic retinopathy in China[J]. World J Diabetes, 2021, 12(8):1304-1311.
[34]	YANG S S, LIAN G J.ROS and diseases:role in metabolism and energy supply[J].Mol Cell Biochem, 2020, 467(1-2):1-12.
[35]	XIONG M Q, ZHAO Y, MO H H, et al.Intermittent hypoxia increases ROS/HIF-1α'related oxidative stress and inflammation and worsens bleomycin-induced pulmonary fibrosis in adult male C57BL/6 J mice[J].Int Immunopharmacol, 2021, 100:108165.
[36]	HUANG L, AO Q L, ZHANG Q H, et al.Hypoxia induced paclitaxel resistance in human ovarian cancers via hypoxia-inducible factor 1α[J].J Cancer Res Clin Oncol, 2010, 136(3):447-456.
[37]	XU X W, CAO W L, SUN W, et al.Knockdown of CCDC132 attenuates gastric cancer cells proliferation and tumorigenesis by facilitating DNA damage signaling[J].Cancer Manag Res, 2019, 11:9585-9597.
[38]	冉茂良, 高环, 尹杰, 等.氧化应激与DNA损伤[J].动物营养学报, 2013, 25(10):2238-2245.RAN M L, GAO H, YIN J, et al.Oxidative stress and DNA injury[J].Chinese Journal of Animal Nutrition, 2013, 25(10):2238-2245.(in Chinese)

Inhibition of Porcine Follicular Granulosa Cell Proliferation by Cobalt Chloride Induced DNA Oxidative Damage

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