Browse > Article
http://dx.doi.org/10.12750/JET.2017.32.3.249

Effects of Curcumin from Turmeric Supplementation in Freezing Buffer on Sperm Motilities and Reactive Oxygen Species Generation  

Lee, Eun-Joo (Department of Life Sciences, College of Bio-Nano Technology, Gachon University)
Kim, Dae-Young (Department of Life Sciences, College of Bio-Nano Technology, Gachon University)
Publication Information
Journal of Embryo Transfer / v.32, no.3, 2017 , pp. 249-255 More about this Journal
Abstract
In this experiment, we determined the effect of curcumin supplementation in freezing buffer for miniature pig sperm cryopreservation. Each ejaculate was diluted with modified Modena B extender and mixed with lactose-egg yolk (LEY extender, 80% v/v lactose solution [310 mM], 20% v/v egg yolk, and $100{\mu}g/mL$ kanamycin sulfate) and LEY-glycerol Orvus ES Paste (LEYGO, 89.5% v/v LEY, 5% v/v glycerol, 1.5% v/v Orvus ES Paste), 100 mM trehalose supplemented with 0, 10, 50, 100, and $500{\mu}M$ of curcumin from turmeric, respectively. Following equilibration, the 0.5 mL French straws were frozen and plunged into $LN_2$ tank for 7 days at least. Sperm parameter and oxidative byproducts were determined by the computer assisted sperm motility analysis (CASA) and fluorescence-activated cell sorting (FACS) as compared with each groups. Supplementation of curcumin had no effect on sperm motility, progressive motility and curvilinear velocity. However, average-path velocity and straight-line velocity were significantly higher in $10{\mu}M$ curcumin group ($100.9{\pm}8.8{\mu}m/s$, $61.7{\pm}2.9{\mu}m/s$, respectively) than control group ($77.8{\pm}3.9{\mu}m/s$, $46.4{\pm}3.0{\mu}m/s$, respectively) (p < 0.05). In addition, the level of the O2 radical and H2O2 were comparatively decreased in curcumin groups by evaluation of ethidium and DCF fluorescence. According to the results, curcumin can improve sperm kinetic variables and alleviate ROS induced cryoinjury to pig sperm.
Keywords
Antioxidant; Curcumin; Miniature pig sperm; Reactive oxygen species; Sperm parameter;
Citations & Related Records
연도 인용수 순위
  • Reference
1 Aitken RJ, Jones KT and Robertson SA. 2012. Reactive oxygen species and sperm function--in sickness and in health. J. Androl. 33:1096-1106.   DOI
2 Joe B, Vijaykumar M and Lokesh BR. 2004. Biological properties of curcumin-cellular and molecular mechanisms of action. Crit. Rev. Food Sci. Nutr. 44:97-111.   DOI
3 Kaneko T, Yamamura A, Ide Y, Ogi M, Yanagita T and Nakagata N. 2006. Long-term cryopreservation of mouse sperm. Theriogenology 66:1098-1101.   DOI
4 Lee ES, Hwang YJ and Park JK. 2014. Purification of Curcumin from Turmeric by using Chitosan. J. Chitin Chitosan 19:270-276.
5 Leu TH and Maa MC. 2002. The molecular mechanisms for the antitumorigenic effect of curcumin. Curr. Med. Chem. Anticancer Agents 2:357-370.   DOI
6 Liu JL, Kusakabe H, Chang CC, Suzuki H, Schmidt DW, Julian M, Pfeffer R, Bormann CL, Tian XC, Yanagimachi R and Yang X. 2004. Freeze-dried sperm fertilization leads to full-term development in rabbits. Biol. Reprod. 70:1776-1781.   DOI
7 Mortazavi M, Salehi I., Alizadeh Z, Vahabian M and Roushandeh AM. 2014. Protective Effects of Antioxidants on Sperm Parameters and Seminiferous Tubules Epithelium in High Fat-fed Rats. J. Reprod. Infertil. 15:22-28.
8 Rosato MP and Iaffaldano N. 2013. Cryopreservation of rabbit semen: comparing the effects of different cryoprotectants, cryoprotectant-free vitrification, and the use of albumin plus osmoprotectants on sperm survival and fertility after standard vapor freezing and vitrification. Theriogenology 79:508-516.   DOI
9 Tvrda E, Tusimova E, Kovacik A, Paal D, Greifova H, Abdramanov A and Lukac N. 2016. Curcumin has protective and antioxidant properties on bull spermatozoa subjected to induced oxidative stress. Anim. Reprod. Sci. 172:10-20. Received September 21 2017, Revised September 26, 2017,   DOI
10 Aisen E, Quintana M, Medina V, Morello H and Venturino A. 2005. Ultramicroscopic and biochemical changes in ram spermatozoa cryopreserved with trehalose-based hypertonic extenders. Cryobiology 50:239-249.   DOI
11 Aitken RJ, Buckingham D and Harkiss D. 1993. Use of a xanthine oxidase free radical generating system to investigate the cytotoxic effects of reactive oxygen species on human spermatozoa. J. Reprod. Fertil. 97:441-450.   DOI
12 Chatterjee S and Gagnon C. 2001. Production of reactive oxygen species by spermatozoa undergoing cooling, freezing, and thawing. Mol. Reprod. Dev. 59:451-458.   DOI
13 Alvarez JG and Storey BT. 1992. Evidence for increased lipid peroxidative damage and loss of superoxide dismutase activity as a mode of sublethal cryodamage to human sperm during cryopreservation. J. Androl. 13:232-241.
14 Amidi F, Pazhohan A, Shabani Nashtaei M, Khodarahmian M and Nekoonam S. 2016. The role of antioxidants in sperm freezing: a review. Cell Tissue Bank 17:745-756.   DOI
15 Bucak MN, Atessahin A, Varisli O, Yuce A, Tekin N and Akcay A. 2007. The influence of trehalose, taurine, cysteamine and hyaluronan on ram semen Microscopic and oxidative stress parameters after freeze-thawing process. Theriogenology 67:1060-1067.   DOI
16 Duvoix A, Blasius R, Delhalle S, Schnekenburger M, Morceau F, Henry E, Dicato M and Diederich M. 2005. Chemopreventive and therapeutic effects of curcumin. Cancer Lett. 223:181-190.   DOI
17 Fraser L and Strzezek J. 2007. Is there a relationship between the chromatin status and DNA fragmentation of boar spermatozoa following freezing-thawing? Theriogenology 68:248-257.   DOI
18 Gadea J, Selles E, Marco MA, Coy P, Matas C, Romar R and Ruiz S. 2004. Decrease in glutathione content in boar sperm after cryopreservation. Effect of the addition of reduced glutathione to the freezing and thawing extenders. Theriogenology 62:690-701.   DOI
19 Griveau JF, Dumont E, Renard P, Callegari JP and Le Lannou D. 1995. Reactive oxygen species, lipid peroxidation and enzymatic defence systems in human spermatozoa. J. Reprod. Fertil. 103:17-26.   DOI