附睾精子抗氧化保护机制研究进展

doi:10.16431/j.cnki.1671-7236.2022.01.010

Abstract

Abstract: Through epididymal transport, sperm undergo a series of biochemical and morphological changes and gradually acquire maturation. During the process of sperm maturation, most of its cytoplasmic components are lost, sperm are more sensitive to oxidative stress, which lead to the damage of sperm structure and function. Therefore, the role of antioxidant enzymes in the epididymal cavity microenvironment is very important. Reactive oxygen species(ROS) play a dual role in sperm function:Physiological levels of ROS can promote the pre-fertilization capacitation of sperm, while high levels of ROS can lead to oxidative damage of sperm. Antioxidant enzymes that remove excess ROS from the epididymis include superoxide dismutase(SOD), catalase(CAT), glutathione peroxidase(GPXs) and peroxidase(PRDXs), however, the contents of different antioxidant enzymes in epididymis varied with the parts of epididymis and animal ages, and different antioxidant enzymes have different scavenging mechanisms to ROS. When the epididymis lacks a certain antioxidant enzyme, the sperm DNA is damaged, the sperm quality is reduced, and eventually leads to increased abnormal reproductive outcomes. Obviously antioxidant enzymes in mammalian epididymis need to coordinate with each other to maintain ROS at physiological level, however there are few reports on this topic at present. The antioxidant enzymes secreted by epididymal epithelial cells are transported to sperm in the form of epididymosome, which can eliminate ROS produced by their own aerobic metabolism and abnormal sperm, and ensure the normal maturation of sperm. This paper reviewed the oxidative stress of epididymal sperm and the protective effect of various antioxidant enzymes in epididymis on sperm.

Key words: epididymis; sperm; antioxidant enzymes; reactive oxygen species; oxidative stress

CLC Number:

Q492.4

XU Jiaoxia, ZHANG Jiaxin. Research Progress on Antioxidation Protection of Sperm in Epididymis[J]. China Animal Husbandry & Veterinary Medicine, 2022, 49(1): 91-97.

References

[1] SULLIVAN R,LÉGARÉ C,LAMONTAGNE-PROULX J,et al.Revisiting structure/functions of the human epididymis[J].Andrology,2019,7(5):748-757.
[2] BASKARAN S,PANNER SELVAM M K,et al.Exosomes of male reproduction[J].Advances in Clinical Chemistry,2020,95:149-163.
[3] GERVASI M G,VISCONTI P E.Molecular changes and signaling events occurring in spermatozoa during epididymal maturation[J].Andrology,2017,5(2):204-218.
[4] JAMES E R,CARRELL D T,ASTON K I,et al.The role of the epididymis and the contribution of epididymosomes to mammalian reproduction[J].International Journal of Molecular Sciences,2020,21(15):5377.
[5] O'FLAHERTY C.Orchestrating the antioxidant defenses in the epididymis[J].Andrology,2019,7(5):662-668.
[6] MORIELLI T,O'FLAHERTY C.Oxidative stress impairs function and increases redox protein modifications in human spermatozoa[J].Reproduction,2015,149(1):113-123.
[7] BARATI E,NIKZAD H,KARIMIAN M.Oxidative stress and male infertility:Current knowledge of pathophysiology and role of antioxidant therapy in disease management[J].Cellular and Molecular Life Sciences,2020,77(1):93-113.
[8] KINO K,SUGIYAMA H.GC——>CG transversion mutation might be caused by 8-oxoguanine oxidation product[J].Nucleic Acids Symposium Series,2000,44:139-140.
[9] ZHONG H,YIN H.Role of lipid peroxidation derived 4-hydroxynonenal (4-HNE) in cancer:Focusing on mitochondria[J].Redox Biology,2015,4:193-199.
[10] AITKEN R J,DREVET J R.The importance of oxidative stress in determining the functionality of mammalian spermatozoa:A two-edged sword[J].Antioxidants (Basel),2020,9(2):111.
[11] BARATI E,NIKZAD H,KARIMIAN M.Oxidative stress and male infertility:Current knowledge of pathophysiology and role of antioxidant therapy in disease management[J].Cellular and Molecular Life Sciences,2020,77(1):93-113.
[12] WU P Y,SCARLATA E,O'FLAHERTY C.Long-term adverse effects of oxidative stress on rat epididymis and spermatozoa[J].Antioxidants (Basel),2020,9(2):170.
[13] BARROSO G,MORSHEDI M,OEHNINGER S.Analysis of DNA fragmentation,plasma membrane translocation of phosphatidylserine and oxidative stress in human spermatozoa[J].Human Reproduction,2000,15(6):1338-1144.
[14] DAS M,AL-HATHAL N,SAN-GABRIEL M,et al.High prevalence of isolated sperm DNA damage in infertile men with advanced paternal age[J].Journal of Assisted Reproduction and Genetics,2013,30(6):843-848.
[15] NOBLANC A,KOCER A,CHABORY E,et al.Glutathione peroxidases at work on epididymal spermatozoa:An example of the dual effect of reactive oxygen species on mammalian male fertilizing ability[J].Journal of Andrology,2011,32(6):641-650.
[16] RANA M,ROY S C,DIVYASHREE B C.Sperm antioxidant defences decrease during epididymal transit from caput to cauda in parallel with increases in epididymal fluid in the goat (Capra hircus)[J].Reproduction,Fertility,and Development,2017,29(9):1708-1719.
[17] O'FLAHERTY C.Orchestrating the antioxidant defenses in the epididymis[J].Andrology,2019,7(5):662-668.
[18] PEEKER R,ABRAMSSON L,MARKLUND S L.Superoxide dismutase isoenzymes in human seminal plasma and spermatozoa[J].Molecular Human Reproduction,1997,3(12):1061-1066.
[19] AITKEN R J,BUCKINGHAM D W,CARRERAS A,et al.Superoxide dismutase in human sperm suspensions:Relationship with cellular composition,oxidative stress,and sperm function[J].Free Radical Biology and Medicine,1996,21(4):495-504.
[20] ZUBKOVA E V,ROBAIRE B.Effect of glutathione depletion on antioxidant enzymes in the epididymis,seminal vesicles,and liver and on spermatozoa motility in the aging Brown Norway rat[J].Biology Reproduction,2004,71(3):1002-1008.
[21] NEGRI L,BENAGLIA R,MONTI E,et al.Effect of superoxide dismutase supplementation on sperm DNA fragmentation[J].Archivio Italiano di Urologia,Andrologia,2017,89(3):212-218.
[22] JEMEC A,DROBNE D,TISLER T,et al.Biochemical biomarkers in environmental studies——Lessons learnt from enzymes catalase,glutathione S-transferase and cholinesterase in two crustacean species[J].Environmental Science and Pollution Research International,2010,17(3):571-581.
[23] GAETANI G F,KIRKMAN H N,MANGERINI R,et al.Importance of catalase in the disposal of hydrogen peroxide within human erythrocytes[J].Blood,1994,84(1):325-330.
[24] HOLLAND M K,STOREY B T.Oxygen metabolism of mammalian spermatozoa.Generation of hydrogen peroxide by rabbit epididymal spermatozoa[J].Biochemical Journal,1981,198(2):273-280.
[25] ALVAREZ J G,STOREY B T.Lipid peroxidation and the reactions of superoxide and hydrogen peroxide in mouse spermatozoa[J].Biology of Reproduction,1840,30(4):833-841.
[26] JEAN-FRANÇOIS B,CHATTERJEE S,MARC-ANDRÉ S,et al.Levels of antioxidant defenses are decreased in bovine spermatozoa after a cycle of freezing and thawing[J].Molecular Reproduction and Development,2000,55(3):282-288.
[27] KAR S,DIVYASHREE B C,ROY S C.Temporal leakage of Cu,Zn superoxide dismutase and loss of two low-molecular-weight forms of glutathione peroxidase-1 from buffalo (Bubalus bubalis) sperm after freezing and thawing[J].Theriogenology,2015,83(4):512-519.
[28] KOZIOROWSKA-GILUN M,KOZIOROWSKI M,FRASER L,et al.Antioxidant defence system of boar cauda epididymidal spermatozoa and reproductive tract fluids[J].Reproduction in Domestic Animals,2011,46(3):527-533.
[29] JEULIN C,SOUFIR J C,WEBER P,et al.Catalase activity in human spermatozoa and seminal plasma[J].Gamete Research,1989,24(2):185-196.
[30] TRAMER F,ROCCO F,MICALI F,et al.Antioxidant systems in rat epididymal spermatozoa[J].Biology of Reproduction,1998,59(4):753-758.
[31] KUMAR A,YADAV B,SWAIN DK,et al.Dynamics of HSPA1A and redox status in the spermatozoa and fluid from different segments of goat epididymis[J].Cell Stress and Chaperones,2020,25(3):509-517.
[32] CHABORY E,DAMON C,LENOIR A,et al.Mammalian glutathione peroxidases control acquisition and maintenance of spermatozoa integrity[J].Journal of Animal Science,2010,88(4):1321-1331.
[33] CHABORY E,DAMON C,LENOIR A,et al.Epididymis seleno-independent glutathione peroxidase 5 maintains sperm DNA integrity in mice[J].Journal of Clinical Investigation,2009,119(7):2074-2085.
[34] ZUBKOVA EV,ROBAIRE B.Effects of ageing on spermatozoal chromatin and its sensitivity to in vivo and in vitro oxidative challenge in the Brown Norway rat[J].Human Reproduction,2006,21(11):2901-2910.
[35] FORESTA C,FLOHÉ L,GAROLLA A,et al.Male fertility is linked to the selenoprotein phospholipid hydroperoxide glutathione peroxidase[J].Biology of Reproduction,2002,67(3):967-971.
[36] SCHNEIDER M,FÖRSTER H,BOERSMA A,et al.Mitochondrial glutathione peroxidase 4 disruption causes male infertility[J].FASEB Journal,2009,23(9):3233-3242.
[37] CONRAD M,MORENO S G,SINOWATZ F,et al.The nuclear form of phospholipid hydroperoxide glutathione peroxidase is a protein thiol peroxidase contributing to sperm chromatin stability[J].Molecular and Cellular Biology,2005,25(17):7637-7644.
[38] DUFAURE J P,LAREYRE J J,SCHWAAB V,et al.Structural organization,chromosomal localization,expression and phylogenetic evaluation of mouse glutathione peroxidase encoding genes[J].Comptes Rendus de l'Académie des Sciences-Series Ⅲ-Sciences de la Vie,1996,319(7):559-568.
[39] GHYSELINCK N B,DUFAURE I,LAREYRE J J,et al.Structural organization and regulation of the gene for the androgen-dependent glutathione peroxidase-like protein specific to the mouse epididymis[J].Molecular Endocrinology,1993,7(2):258-272.
[40] VILAGRAN I,CASTILLO-MARTÍN M,PRIETO-MARTÍNEZ N,et al.Triosephosphate isomerase (TPI) and epididymal secretory glutathione peroxidase (GPX₅) are markers for boar sperm quality[J].Animal Reproduction Science,2016,165:22-30.
[41] BOE-HANSEN G B,CHRISTENSEN P,VIBJERG D,et al.Sperm chromatin structure integrity in liquid stored boar semen and its relationships with field fertility[J].Theriogenology,2008,69(6):728-736.
[42] WILLIAMS K,FRAYNE J,HALL L.Expression of extracellular glutathione peroxidase type 5(GPX5) in the rat male reproductive tract[J].Molecular Human Reproduction,1998,4(9):841-848.
[43] RHEE S G,CHAE H Z,KIM K.Peroxiredoxins:A historical overview and speculative preview of novel mechanisms and emerging concepts in cell signaling[J].Free Radical Biology and Medicine, 2005,38(12):1543-1552.
[44] RHEE S G,KANG S W,CHANG T S,et al.Peroxiredoxin,a novel family of peroxidases[J].IUBMB Life, 2001,52(1-2):35-41.
[45] FERNANDEZ M C,O'FLAHERTY C.Peroxiredoxin 6 is the primary antioxidant enzyme for the maintenance of viability and DNA integrity in human spermatozoa[J].Human Reproduction,2018,33(8):1394-1407.
[46] O'FLAHERTY C.Peroxiredoxins:Hidden players in the antioxidant defence of human spermatozoa[J].Basic and Clinical Andrology,2014,24:4.
[47] GONG S,SAN GABRIEL M C,ZINI A,et al.Low amounts and high thiol oxidation of peroxiredoxins in spermatozoa from infertile men[J].Journal of Andrology,2012,33(6):1342-1351.
[48] WOO H A,JEONG W,CHANG T S,et al.Reduction of cysteine sulfinic acid by sulfiredoxin is specific to 2-Cys peroxiredoxins[J].Journal of Biological Chemistry,2005,280(5):3125-3128.
[49] FISHER A B.Peroxiredoxin 6 in the repair of peroxidized cell membranes and cell signaling[J].Archives of Biochemistry and Biophysic,2017,617:68-83.
[50] OZKOSEM B,FEINSTEIN S I,FISHER A B,et al.Absence of peroxiredoxin 6 amplifies the effect of oxidant stress on mobility and SCSA/CMA3 defined chromatin quality and impairs fertilizing ability of mouse spermatozoa[J].Biology of Reproduction,2016,94(3):68.
[51] OZKOSEM B,FEINSTEIN S I,FISHER A B,et al.Advancing age increases sperm chromatin damage and impairs fertility in peroxiredoxin 6 null mice[J].Redox Biology,2015,5:15-23.
[52] LIU Y,O'FLAHERTY C.In vivo oxidative stress alters thiol redox status of peroxiredoxin 1 and 6 and impairs rat sperm quality[J].Asian Journal of Andrology,2017,19(1):73-79.

Research Progress on Antioxidation Protection of Sperm in Epididymis

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	DENG Shuangyi, GAO Li, YANG Liwei, LIU Xiaona, NING Chengcheng, ZHANG Wenjie, GAO Jialiang, WANG Shiyin, ZHANG Wei. Research Progress on Mechanisms of Cryodamage and Differential Cryotolerance of Animal Sperm [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(7): 3202-3213.
[2]	WANG Ru, WANG Jiahao, OU Jingyu, TANG Wenhui, CHENG Xiao, WANG Qiangjun, CHEN Jiahong, ZHANG Zijun, REN Chunhuan. Effect of Antioxidants on Freezing Effect of Semen in Ruminants [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(7): 3242-3255.
[3]	YU Miao, LI Yanjiao, ZHAO Yanling, CHAO Zhe, WANG Feng, LI Menghan, JIANG Zhiqiang, ZHANG Ting, XUE Xinyu, REN Zili, SUN Ruiping. Effects of Weaning Stress on Intestinal Morphology, Antioxidant Capacity and Nrf2 Signaling Pathway of Wuzhishan Piglets [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(5): 2045-2055.
[4]	JIA Yuxuan, LI Yaojiang, ZENG Guanghu, SHEN Xiangyu, GONG Ting. Isolation,Culture and Identification of Testicular Spermatogenic Cells from Congjiang Xiang Pig [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(5): 2198-2207.
[5]	GAO Zihao, LI Jia, ZHANG Linhui, ZHANG Ci, LIU Bingnan, LI Junjie, XIA Wei. Research Progress on the Regulatory Mechanisms of Mitochondria in the Maturation of Domestic Animal Oocytes [J]. China Animal Husbandry and Veterinary Medicine, 2025, 52(5): 2232-2242.
[6]	MIAO Xinyuan, XU Qingyu, XIA Sugan, LIN Tianjin, CAI Guodong, ZOU Hui, GU Jianhong, YUAN Yan, LIU Zongping, BIAN Jianchun. Mechanism of Action of Testosterone Synthesis Disorder in Male Mice Induced by Polystyrene Nanoplastics [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(4): 1488-1498.
[7]	HONG Jiajun, XIAO Jinhua, ZHANG Zheng, YANG Yuting, FANG Chun, HAN Xu. Effect of sod Gene Deletion on the Anti-oxidative Stress in Listeria monocytogenes 10403S [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(4): 1776-1783.
[8]	ZHAO Fanglin, LIU Meng, TANG Zeyu, ZHAO Jianhao, LI Lu, JIA Lijun. Effects of Dihydroartemisinin on Sperm Quality and Spermatogenic Function Gene in Male Mice Infected with Neosporidium neosporidium [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(4): 1796-1806.
[9]	TAO Siming, LIANG Hui, YAN Chang, LONG Runze, XU Ruiqing, LI Zixu, WU Yingjie, LIU Ning, QIN Yinghe. Effects of Dietary Chlorogenic Acid on Reproductive Performance of Female Rabbits and Growth of Suckling Rabbits [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(3): 1080-1088.
[10]	LU Yanan, YUAN Ligang, ZENG Jianlin, QI Yumei, MA Long, LYU Jinhan. Analysis of the Effect of GPx5 on Testis and Epididymis of Normal and Cryptorchidism in Bactrian Camels [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(3): 1180-1190.
[11]	LI Chaocheng, LIU Yaxing, LI Jian, LI Yunlei, JIA Bin. Study on the Mechanism of Zfy Gene in the Development of Sperm Tail [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(3): 1222-1230.
[12]	LI Xi, LIU Jianying, FANG Lihua, YIN Yulong, TANG Yulong. Functional Study on SodA,TrxA and TrxC Genes of Streptococcus suis Type 2 [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(3): 1428-1436.
[13]	TANG Yufei, MO Yeyun, LI Xiaoxiao, YANG Qiuli, LIN Huilyu, HUANG Haifang, LIN Meiying, LI Li. Effect of Total Flavonoids from Melastoma dodecandrum Lour.on Lipid Peroxidation in Diabetic Nephropathy Mice Induced by High-fat Diet Combined with Streptozocin [J]. China Animal Husbandry & Veterinary Medicine, 2025, 52(1): 364-375.
[14]	YANG Wenzhe, LIU Kexiang, WANG Shirui, ZHAO Tong, PAN Feilong, ZHAO Shuchen, ZHAO Lijia. Study on Apoptosis of Mouse Leydig Cells Induced by BPA Based on Mitochondrial Damage [J]. China Animal Husbandry & Veterinary Medicine, 2024, 51(9): 3739-3751.
[15]	TIAN Lanxin, YANG Yuting, QIN Yi, ZHANG Zheng, TIAN Guangming, FANG Chun. Effects of Glutamate Dehydrogenase gdhA Gene Deficiency on Antioxidant Stress in Listeria monocytogenes [J]. China Animal Husbandry & Veterinary Medicine, 2024, 51(9): 3771-3779.