Hostname: page-component-cd9895bd7-8ctnn Total loading time: 0 Render date: 2024-12-23T14:24:52.417Z Has data issue: false hasContentIssue false
  • English
  • Français

Improving bovine semen diluents: insights from the male and female reproductive tracts, and the potential relevance of cervical mucins

Published online by Cambridge University Press:  28 March 2014

J. A. McGetrick ,
C. J. Reid  and
S. D. Carrington
J. A. McGetrick
Affiliation:
School of Veterinary Medicine, Veterinary Sciences Centre, University College Dublin, Belfield, Dublin 4, Ireland
C. J. Reid
Affiliation:
School of Veterinary Medicine, Veterinary Sciences Centre, University College Dublin, Belfield, Dublin 4, Ireland
S. D. Carrington*
Affiliation:
School of Veterinary Medicine, Veterinary Sciences Centre, University College Dublin, Belfield, Dublin 4, Ireland
*
E-mail: [email protected]
Get access

Abstract

The commercial applicability of bovine artificial insemination (AI) depends on the effectiveness of diluents for maintaining sperm fertility. Challenges faced by the AI industry due to recent advances in assisted reproduction, and the limitations inherent in using fresh and frozen-thawed sperm for AI, could be overcome with the development of better semen diluents. Research into the different microenvironments of bovine sperm as they progress towards maturity, capacitation and fertilisation is revealing various mechanisms that could be exploited to improve the formulation of semen diluents. These are reviewed here. A rationale for a more detailed investigation of bovine cervical mucus for factors that may allow further progress towards this goal are also discussed.

Keywords

bovine spermsemen diluentsartificial insemination
Type
Full Paper
Information
animal , Volume 8 , Supplement s1: New Science ‐ New Practices International Cow Fertility Conference 18‐21 May 2014, Westport, Ireland , May 2014 , pp. 173 - 184
Copyright
© The Animal Consortium 2014 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Abe, H, Sendai, Y, Satoh, T and Hoshi, H 1995. Bovine oviduct-specific glycoprotein: a potent factor for maintenance of viability and motility of bovine spermatozoa in vitro . Molecular Reproduction and Development 42, 226232.Google Scholar
Acott, TS and Carr, DW 1984. Inhibition of bovine spermatozoa by caudal epididymal fluid: II. Interaction of pH and a quiescence factor. Biology of Reproduction 30, 926935.Google Scholar
Al Naib, A, Ward, F, Kelly, AK, Wade, M, Marti, JI and Lonergan, P 2011. Effect of duration of storage at ambient temperature on fertilizing ability and mucus penetration ability of fresh bovine sperm. Theriogenology 76, 10701075.Google Scholar
Alghamdi, AS and Foster, DN 2005. Seminal DNase frees spermatozoa entangled in neutrophil extracellular traps. Biology of Reproduction 73, 11741181.Google Scholar
Alvarez-Gallardo, H, Kjelland, ME, Moreno, JF, Welsh, TH Jr, Randel, RD, Lammoglia, MA, Perez-Martinez, M, Lara-Sagahon, AV, Esperon-Sumano, AE and Romo, S 2013. Gamete therapeutics: recombinant protein adsorption by sperm for increasing fertility via artificial insemination. PLoS One 8, e65083.CrossRefGoogle ScholarPubMed
Ardon, F and Suarez, SS 2013. Cryopreservation increases coating of bull sperm by seminal plasma binder of sperm proteins BSP1, BSP3, and BSP5. Reproduction 146, 111117.Google Scholar
Bailey, JL and Buhr, MM 1994. Cryopreservation alters the Ca2+ flux of bovine spermatozoa. Canadian Journal of Animal Science 74, 4551.Google Scholar
Bailey, JL, Robertson, L and Buhr, MM 1994. Relationships among in vivo fertility, computer-analysed motility and in vitro Ca2+ flux in bovine spermatozoa. Canadian Journal of Animal Science 74, 5358.Google Scholar
Bailey, JL, Bilodeau, JF and Cormier, N 2000. Semen cryopreservation in domestic animals: a damaging and capacitating phenomenon. Journal of Andrology 21, 17.Google Scholar
Bergqvist, AS and Rodriguez-Martinez, H 2006. Sulphated glycosaminoglycans (S-GAGs) and syndecans in the bovine oviduct. Animal Reproduction Science 93, 4660.Google Scholar
Bergqvist, AS, Yokoo, M, Heldin, P, Frendin, J, Sato, E and Rodriguez-Martinez, H 2005. Hyaluronan and its binding proteins in the epithelium and intraluminal fluid of the bovine oviduct. Zygote 13, 207218.CrossRefGoogle ScholarPubMed
Bergqvist, AS, Ballester, J, Johannisson, A, Hernandez, M, Lundeheim, N and Rodriguez-Martinez, H 2006. In vitro capacitation of bull spermatozoa by oviductal fluid and its components. Zygote 14, 259273.Google Scholar
Boice, ML, Geisert, RD, Blair, RM and Verhage, HG 1990. Identification and characterization of bovine oviductal glycoproteins synthesized at estrus. Biology of Reproduction 43, 457465.Google Scholar
Boilard, M, Bailey, J, Collin, S, Dufour, M and Sirard, MA 2002. Effect of bovine oviduct epithelial cell apical plasma membranes on sperm function assessed by a novel flow cytometric approach. Biology of Reproduction 67, 11251132.Google Scholar
Boquest, AC, Smith, JF, Briggs, RM, Duganzich, DM and Summers, PM 1999. Effects of bovine oviductal proteins on bull spermatozoal function. Theriogenology 51, 583595.Google Scholar
Borchersen, S and Peacock, M 2009. Danish A.I. field data with sexed semen. Theriogenology 71, 5963.Google Scholar
Buhi, WC 2002. Characterization and biological roles of oviduct-specific, oestrogen-dependent glycoprotein. Reproduction 123, 355362.Google Scholar
Cancel, AM, Chapman, DA and Killian, GJ 1997. Osteopontin is the 55-kilodalton fertility-associated protein in Holstein bull seminal plasma. Biology of Reproduction 57, 12931301.Google Scholar
Carr, DW, Usselman, MC and Acott, TS 1985. Effects of pH, lactate, and viscoelastic drag on sperm motility: a species comparison. Biology of Reproduction 33, 588595.Google Scholar
Cohen, M and Varki, A 2010. The sialome – far more than the sum of its parts. OMICS 14, 455464.Google Scholar
Collin, S, Sirard, MA, Dufour, M and Bailey, JL 2000. Sperm calcium levels and chlortetracycline fluorescence patterns are related to the in vivo fertility of cryopreserved bovine semen. Journal of Andrology 21, 938943.Google Scholar
Cone, RA 2009. Barrier properties of mucus. Advanced Drug Delivery Reviews 61, 7585.CrossRefGoogle ScholarPubMed
Cortes, PP, Orihuela, PA, Zuniga, LM, Velasquez, LA and Croxatto, HB 2004. Sperm binding to oviductal epithelial cells in the rat: role of sialic acid residues on the epithelial surface and sialic acid-binding sites on the sperm surface. Biology of Reproduction 71, 12621269.Google Scholar
D’Amours, O, Frenette, G, Fortier, M, Leclerc, P and Sullivan, R 2010. Proteomic comparison of detergent-extracted sperm proteins from bulls with different fertility indexes. Reproduction 139, 545556.Google Scholar
DeJarnette, JM, Nebel, RL and Marshall, CE 2009. Evaluating the success of sex-sorted semen in US dairy herds from on farm records. Theriogenology 71, 4958.Google Scholar
DeMott, RP, Lefebvre, R and Suarez, SS 1995. Carbohydrates mediate the adherence of hamster sperm to oviductal epithelium. Biology of Reproduction 52, 13951403.Google Scholar
Doak, RL, Hall, A and Dale, HE 1967. Longevity of spermatozoa in the reproductive tract of the bitch. Journal of Reproduction and Fertility 13, 5158.Google Scholar
Dobrinski, I, Suarez, SS and Ball, BA 1996. Intracellular calcium concentration in equine spermatozoa attached to oviductal epithelial cells in vitro . Biology of Reproduction 54, 783788.Google Scholar
Elliott, RM, Lloyd, RE, Fazeli, A, Sostaric, E, Georgiou, AS, Satake, N, Watson, PF and Holt, WV 2009. Effects of HSPA8, an evolutionarily conserved oviductal protein, on boar and bull spermatozoa. Reproduction 137, 191203.Google Scholar
Eriksen, GV, Carlstedt, I, Uldbjerg, N and Ernst, E 1998. Cervical mucins affect the motility of human spermatozoa in vitro . Fertility and Sterility 70, 350354.Google Scholar
Fazeli, A, Elliott, RM, Duncan, AE, Moore, A, Watson, PF and Holt, WV 2003. In vitro maintenance of boar sperm viability by a soluble fraction obtained from oviductal apical plasma membrane preparations. Reproduction 125, 509517.Google Scholar
Free, MJ, Schluntz, GA and Jaffe, RA 1976. Respiratory gas tensions in tissues and fluids of the male rat reproductive tract. Biology of Reproduction 14, 481488.Google Scholar
Frijters, ACJ, Mullaart, E, Roelofs, RMG, van Hoorne, RP, Moreno, JF, Moreno, O and Merton, JS 2009. What affects fertility of sexed bull semen more, low sperm dosage or the sorting process? Theriogenology 71, 6467.Google Scholar
Gabler, C, Chapman, DA and Killian, GJ 2003. Expression and presence of osteopontin and integrins in the bovine oviduct during the oestrous cycle. Reproduction 126, 721729.Google Scholar
Gagnon, A, Sullivan, R and Sirard, MA 2000. Epididymal epithelial cells cultured in vitro prolong the motility of bovine sperm. Journal of Andrology 21, 842847.Google Scholar
Galantino-Homer, HL, Visconti, PE and Kopf, GS 1997. Regulation of protein tyrosine phosphorylation during bovine sperm capacitation by a cyclic adenosine 3’,5’-monophosphate-dependent pathway. Biology of Reproduction 56, 707719.Google Scholar
Gervasi, MG, Rapanelli, M, Ribeiro, ML, Farina, M, Billi, S, Franchi, AM and Perez Martinez, S 2009. The endocannabinoid system in bull sperm and bovine oviductal epithelium: role of anandamide in sperm-oviduct interaction. Reproduction 137, 403414.Google Scholar
Gervasi, MG, Marczylo, TH, Lam, PM, Rana, S, Franchi, AM, Konje, JC and Perez-Martinez, S 2013. Anandamide levels fluctuate in the bovine oviduct during the oestrous cycle. PLoS One 8, e72521.CrossRefGoogle ScholarPubMed
Gervasi, MG, Osycka-Salut, C, Caballero, J, Vazquez-Levin, M, Pereyra, E, Billi, S, Franchi, A and Perez-Martinez, S 2011. Anandamide capacitates bull spermatozoa through CB1 and TRPV1 activation. PLoS One 6, e16993.Google Scholar
Gipson, IK 2001. Mucins of the human endocervix. Frontiers in Bioscience 6, D1245D1255.Google Scholar
Gwathmey, TM, Ignotz, GG, Mueller, JL, Manjunath, P and Suarez, SS 2006. Bovine seminal plasma proteins PDC-109, BSP-A3, and BSP-30-kDa share functional roles in storing sperm in the oviduct. Biology of Reproduction 75, 501507.Google Scholar
Hansson, GC 2010. Sparkling water – bicarbonate for cervix and cystic fibrosis. The Journal of Physiology 588, 2685.Google Scholar
Harrison, RAP 2004. Rapid PKA-catalysed phosphorylation of boar sperm proteins induced by the capacitating agent bicarbonate. Molecular Reproduction and Development 67, 337352.Google Scholar
Harshan, HM, Singh, LP, Arangasamy, A, Ansari, MR and Kumar, S 2006. Effect of buffalo seminal plasma heparin binding protein (HBP) on freezability and in vitro fertility of buffalo cauda spermatozoa. Animal Reproduction Science 93, 124133.Google Scholar
Healy, AA, House, JK and Thomson, PC 2013. Artificial insemination field data on the use of sexed and conventional semen in nulliparous Holstein heifers. Journal of Dairy Science 96, 19051914.Google Scholar
Hickey, DK, Patel, MV, Fahey, JV and Wira, CR 2011. Innate and adaptive immunity at mucosal surfaces of the female reproductive tract: stratification and integration of immune protection against the transmission of sexually transmitted infections. Journal of Reproductive Immunology 88, 185194.Google Scholar
Holt, WV 1980. Surface-bound sialic acid on ram and bull spermatozoa: deposition during epididymal transit and stability during washing. Biology of Reproduction 23, 847857.Google Scholar
Holt, WV 2011. Mechanisms of sperm storage in the female reproductive tract: an interspecies comparison. Reproduction in Domestic Animals 46 (suppl. 2), 6874.Google Scholar
Holt, WV and Lloyd, RE 2010. Sperm storage in the vertebrate female reproductive tract: how does it work so well? Theriogenology 73, 713722.Google Scholar
Holt, WV, Elliott, RM, Fazeli, A, Satake, N and Watson, PF 2005. Validation of an experimental strategy for studying surface-exposed proteins involved in porcine sperm-oviduct contact interactions. Reproduction, Fertility and Development 17, 683692.Google Scholar
Hung, PH and Suarez, SS 2012. Alterations to the bull sperm surface proteins that bind sperm to oviductal epithelium. Biology of Reproduction 87, 88.Google Scholar
Hunter, RH 1984. Pre-ovulatory arrest and peri-ovulatory redistribution of competent spermatozoa in the isthmus of the pig oviduct. Journal of Reproduction and Fertility 72, 203211.Google Scholar
Hunter, RH and Nichol, R 1983. Transport of spermatozoa in the sheep oviduct: preovulatory sequestering of cells in the caudal isthmus. The Journal of Experimental Zoology 228, 121128.Google Scholar
Hunter, RH and Wilmut, I 1984. Sperm transport in the cow: peri-ovulatory redistribution of viable cells within the oviduct. Reproduction, Nutrition, Development 24, 597608.Google Scholar
Hutchinson, IA, Shalloo, L and Butler, ST 2013. Expanding the dairy herd in pasture-based systems: the role of sexed semen use in virgin heifers and lactating cows. Journal of Dairy Science 96, 67426752.Google Scholar
Ignotz, GG, Lo, MC, Perez, CL, Gwathmey, TM and Suarez, SS 2001. Characterization of a fucose-binding protein from bull sperm and seminal plasma that may be responsible for formation of the oviductal sperm reservoir. Biology of Reproduction 64, 18061811.Google Scholar
Imam, S, Ansari, MR, Ahmed, N and Kumaresan, A 2008. Effect of oviductal fluid proteins on buffalo sperm characteristics during cryopreservation. Theriogenology 69, 925931.Google Scholar
Iqbal, N and Hunter, AG 1995. Comparison of various bovine sperm capacitation systems for their ability to alter the net negative surface charge of spermatozoa. Journal of Dairy Science 78, 8490.Google Scholar
Jones, R 2004. Sperm survival versus degradation in the Mammalian epididymis: a hypothesis. Biology of Reproduction 71, 14051411.Google Scholar
Kadirvel, G, Machado, SA, Korneli, C, Collins, E, Miller, P, Bess, KN, Aoki, K, Tiemeyer, M, Bovin, N and Miller, DJ 2012. Porcine sperm bind to specific 6-sialylated biantennary glycans to form the oviduct reservoir. Biology of Reproduction 87, 147, 111.Google Scholar
Katz, DF, Slade, DA and Nakajima, ST 1997. Analysis of pre-ovulatory changes in cervical mucus hydration and sperm penetrability. Advances in Contraception 13, 143151.Google Scholar
Killian, G 2011. Physiology and endocrinology symposium: evidence that oviduct secretions influence sperm function: a retrospective view for livestock. Journal of Animal Science 89, 13151322.Google Scholar
Killian, GJ, Chapman, DA and Rogowski, LA 1993. Fertility-associated proteins in Holstein bull seminal plasma. Biology of Reproduction 49, 12021207.Google Scholar
King, RS, Anderson, SH and Killian, GJ 1994. Effect of bovine oviductal estrus-associated protein on the ability of sperm to capacitate and fertilize oocytes. Journal of Andrology 15, 468478.Google Scholar
Kirillov, VS and Mozorov, VA 1936. Duration of survival of bull spermatozoa in an epididymis isolated from the testis. Uspekhi zootekh, Nauk 2, 1922.Google Scholar
Kjellen, L and Lindahl, U 1991. Proteoglycans: structures and interactions. Annual Review of Biochemistry 60, 443475.Google Scholar
Klinc, P and Rath, D 2007. Reduction of oxidative stress in bovine spermatozoa during flow cytometric sorting. Reproduction in Domestic Animals 42, 6367.Google Scholar
Lagow, E, DeSouza, MM and Carson, DD 1999. Mammalian reproductive tract mucins. Human Reproduction Update 5, 280292.CrossRefGoogle ScholarPubMed
Lai, SK, Wang, YY, Wirtz, D and Hanes, J 2009. Micro- and macrorheology of mucus. Advanced Drug Delivery Reviews 61, 86100.Google Scholar
Lapointe, J and Bilodeau, JF 2003. Antioxidant defenses are modulated in the cow oviduct during the estrous cycle. Biology of Reproduction 68, 11571164.Google Scholar
Lapointe, S, Sullivan, R and Sirard, MA 1998. Binding of a bovine oviductal fluid catalase to mammalian spermatozoa. Biology of Reproduction 58, 747753.CrossRefGoogle ScholarPubMed
Lefebvre, R, Lo, MC and Suarez, SS 1997. Bovine sperm binding to oviductal epithelium involves fucose recognition. Biology of Reproduction 56, 11981204.Google Scholar
Lefebvre, R, Chenoweth, PJ, Drost, M, LeClear, CT, MacCubbin, M, Dutton, JT and Suarez, SS 1995. Characterization of the oviductal sperm reservoir in cattle. Biology of Reproduction 53, 10661074.Google Scholar
Lessard, C, Siqueira, LG, D'Amours, O, Sullivan, R, Leclerc, P and Palmer, C 2011. Infertility in a beef bull due to a failure in the capacitation process. Theriogenology 76, 891899.Google Scholar
Lin, M, Zhang, X, Murdoch, R and Aitken, RJ 2000. In vitro culture of brushtail possum (Trichosurus vulpecula) epididymal epithelium and induction of epididymal sperm maturation in co-culture. Journal of Reproduction and Fertility 119, 114.Google Scholar
Liu, Z and Foote, RH 1998. Bull sperm motility and membrane integrity in media varying in osmolality. Journal of Dairy Science 81, 18681873.Google Scholar
Lloyd, RE, Fazeli, A, Watson, PF and Holt, WV 2012. The oviducal protein, heat-shock 70-kDa protein 8, improves the long-term survival of ram spermatozoa during storage at 17 degrees C in a commercial extender. Reproduction, Fertility and Development 24, 543549.Google Scholar
Ma, F, Wu, D, Deng, L, Secrest, P, Zhao, J, Varki, N, Lindheim, S and Gagneux, P 2012. Sialidases on mammalian sperm mediate deciduous sialylation during capacitation. The Journal of Biological Chemistry 287, 3807338079.Google Scholar
Manjunath, P, Lefebvre, J, Jois, PS, Fan, J and Wright, MW 2009. New nomenclature for mammalian BSP genes. Biology of Reproduction 80, 394397.Google Scholar
Martus, NS, Verhage, HG, Mavrogianis, PA and Thibodeaux, JK 1998. Enhancement of bovine oocyte fertilization in vitro with a bovine oviductal specific glycoprotein. Journal of Reproduction and Fertility 113, 323329.Google Scholar
Maxwell, WMC and Johnson, LA 1999. Physiology of spermatozoa at high dilution rates: the influence of seminal plasma. Theriogenology 52, 13531362.Google Scholar
McKee, MD and Nanci, A 1996. Osteopontin: an interfacial extracellular matrix protein in mineralized tissues. Connective Tissue Research 35, 197205.Google Scholar
McNutt, TL and Killian, GJ 1991. Influence of bovine follicular and oviduct fluids on sperm capacitation in vitro . Journal of Andrology 12, 244252.Google Scholar
Miller, DJ, Winer, MA and Ax, RL 1990. Heparin-binding proteins from seminal plasma bind to bovine spermatozoa and modulate capacitation by heparin. Biology of Reproduction 42, 899915.Google Scholar
Moore, HD and Hartman, TD 1986. In-vitro development of the fertilizing ability of hamster epididymal spermatozoa after co-culture with epithelium from the proximal cauda epididymidis. Journal of Reproduction and Fertility 78, 347352.Google Scholar
Moore, HD, Curry, MR, Penfold, LM and Pryor, JP 1992. The culture of human epididymal epithelium and in vitro maturation of epididymal spermatozoa. Fertility and Sterility 58, 776783.Google Scholar
Moura, AA, Koc, H, Chapman, DA and Killian, GJ 2006. Identification of proteins in the accessory sex gland fluid associated with fertility indexes of dairy bulls: a proteomic approach. Journal of Andrology 27, 201211.Google Scholar
Murphy, C, Fahey, AG, Shafat, A and Fair, S 2013. Reducing sperm concentration is critical to limiting the oxidative stress challenge in liquid bull semen. Journal of Dairy Science 96, 44474454.Google Scholar
Murray, SC and Smith, TT 1997. Sperm interaction with fallopian tube apical membrane enhances sperm motility and delays capacitation. Fertility and Sterility 68, 351357.Google Scholar
Nass, SJ, Miller, DJ and Winer, MA 1990. Male accessory sex glands produce heparin-binding proteins that bind to cauda epididymal spermatozoa and are testosterone dependent. Molecular Reproduction and Development 25, 237246.Google Scholar
Nauc, V and Manjunath, P 2000. Radioimmunoassays for bull seminal plasma proteins (BSP-A1/-A2, BSP-A3, and BSP-30-Kilodaltons), and their quantification in seminal plasma and sperm. Biology of Reproduction 63, 10581066.Google Scholar
Norman, HD, Hutchison, JL and Miller, RH 2010. Use of sexed semen and its effect on conception rate, calf sex, dystocia, and stillbirth of Holsteins in the United States. Journal of Dairy Science 93, 38803890.Google Scholar
Okazaki, T, Yoshida, S, Teshima, H and Shimada, M 2011. The addition of calcium ion chelator, EGTA to thawing solution improves fertilizing ability in frozen-thawed boar sperm. Animal Science Journal 82, 412419.Google Scholar
Pang, PC, Chiu, PC, Lee, CL, Chang, LY, Panico, M, Morris, HR, Haslam, SM, Khoo, KH, Clark, GF, Yeung, WS and Dell, A 2011. Human sperm binding is mediated by the sialyl-Lewis(x) oligosaccharide on the zona pellucida. Science 333, 17611764.Google Scholar
Parrish, JJ, Susko-Parrish, JL and Graham, JK 1999. In vitro capacitation of bovine spermatozoa: role of intracellular calcium. Theriogenology 51, 461472.Google Scholar
Parrish, JJ, Susko-Parrish, JL, Handrow, RR, Sims, MM and First, NL 1989. Capacitation of bovine spermatozoa by oviduct fluid. Biology of Reproduction 40, 10201025.Google Scholar
Petrunkina, AM, Simon, K, Gunzel-Apel, AR and Topfer-Petersen, E 2003. Regulation of capacitation of canine spermatozoa during co-culture with heterologous oviductal epithelial cells. Reproduction in Domestic Animals 38, 455463.Google Scholar
Petrunkina, AM, Simon, K, Gunzel-Apel, AR and Topfer-Petersen, E 2004. Kinetics of protein tyrosine phosphorylation in sperm selected by binding to homologous and heterologous oviductal explants: how specific is the regulation by the oviduct? Theriogenology 61, 16171634.Google Scholar
Pluta, K, Irwin, JA, Dolphin, C, Richardson, L, Fitzpatrick, E, Gallagher, ME, Reid, CJ, Crowe, MA, Roche, JF, Lonergan, P, Carrington, SD and Evans, AC 2011. Glycoproteins and glycosidases of the cervix during the periestrous period in cattle. Journal of Animal Science 89, 40324042.Google Scholar
Reyes-Moreno, C, Boilard, M, Sullivan, R and Sirard, MA 2002a. Characterization and identification of epididymal factors that protect ejaculated bovine sperm during in vitro storage. Biology of Reproduction 66, 159166.Google Scholar
Reyes-Moreno, C, Boilard, M, Sullivan, R and Sirard, MA 2002b. Characterization of secretory proteins from cultured cauda epididymal cells that significantly sustain bovine sperm motility in vitro . Molecular Reproduction and Development 63, 500509.Google Scholar
Robbe, C, Michalski, JC and Capon, C 2006. Structural determination of O-glycans by tandem mass spectrometry. Methods in Molecular Biology 347, 109123.Google Scholar
Roncoletta, M, Morani Eda, S, Esper, CR, Barnabe, VH and Franceschini, PH 2006. Fertility-associated proteins in Nelore bull sperm membranes. Animal Reproduction Science 91, 7787.Google Scholar
Rosado, A, Velazquez, A and Lara-Ricalde, R 1973. Cell polarography. II. Effect of neuraminidase and follicular fluid upon the surface characteristics of human spermatozoa. Fertility and Sterility 24, 349354.Google Scholar
Roy, M, Gauvreau, D and Bilodeau, JF 2008. Expression of superoxide dismutases in the bovine oviduct during the estrous cycle. Theriogenology 70, 836842.Google Scholar
Satoh, T, Abe, H, Sendai, Y, Iwata, H and Hoshi, H 1995. Biochemical characterization of a bovine oviduct-specific sialo-glycoprotein that sustains sperm viability in vitro . Biochimica et Biophysica Acta 1266, 117123.Google Scholar
Sendai, Y, Abe, H, Kikuchi, M, Satoh, T and Hoshi, H 1994. Purification and molecular cloning of bovine oviduct-specific glycoprotein. Biology of Reproduction 50, 927934.Google Scholar
Setchell, BP, Sanchez-Partida, LG and Chairussyuhur, A 1993. Epididymal constituents and related substances in the storage of spermatozoa: a review. Reproduction, Fertility and Development 5, 601612.Google Scholar
Sostaric, E, van de Lest, CH, Colenbrander, B and Gadella, BM 2005. Dynamics of carbohydrate affinities at the cell surface of capacitating bovine sperm cells. Biology of Reproduction 72, 346357.Google Scholar
Sprott, LR, Harris, MD, Forrest, DW, Young, J, Zhang, HM, Oyarzo, JN, Bellin, ME and Ax, RL 2000. Artificial insemination outcomes in beef females using bovine sperm with a detectable fertility-associated antigen. Journal of Animal Science 78, 795798.Google Scholar
Srivastava, N, Srivastava, SK, Ghosh, SK, Singh, LP, Prasad, JK, Kumar, Amit, Perumal, P, Jerome, A and Thamizharasan, A 2012. Sequestration of PDC-109 protein improves freezability of crossbred bull spermatozoa. Animal Reproduction Science 131, 5462.CrossRefGoogle ScholarPubMed
Suarez, SS 2001. Carbohydrate-mediated formation of the oviductal sperm reservoir in mammals. Cells, Tissues, Organs 168, 105112.Google Scholar
Suarez, SS 2002. Formation of a reservoir of sperm in the oviduct. Reproduction in Domestic Animals 37, 140143.Google Scholar
Suarez, SS and Pacey, AA 2006. Sperm transport in the female reproductive tract. Human Reproduction Update 12, 2337.Google Scholar
Suarez, SS, Revah, I, Lo, M and Kolle, S 1998. Bull sperm binding to oviductal epithelium is mediated by a Ca2+-dependent lectin on sperm that recognizes Lewis-a trisaccharide. Biology of Reproduction 59, 3944.Google Scholar
Suzuki, F and Yanagimachi, R 1989. Changes in the distribution of intramembranous particles and filipin-reactive membrane sterols during in vitro capacitation of golden hamster spermatozoa. Gamete Research 23, 335347.Google Scholar
Taitzoglou, IA, Kokoli, AN and Killian, GJ 2007. Modifications of surface carbohydrates on bovine spermatozoa mediated by oviductal fluid: a flow cytometric study using lectins. International Journal of Andrology 30, 108114.Google Scholar
Thérien, I, Souberyrand, S and Manjunath, P 1997. Major proteins of bovine seminal plasma modulate sperm capacitation by high-density lipoprotein. Biology of Reproduction 57, 10801088.Google Scholar
Thérien, I, Bergeron, A, Bousquet, D and Manjunath, P 2005. Isolation and characterization of glycosaminoglycans from bovine follicular fluid and their effect on sperm capacitation. Molecular Reproduction and Development 71, 97106.Google Scholar
Thibier, M and Wagner, HG 2002. World statistics for artificial insemination in cattle. Livestock Production Science 74, 203212.Google Scholar
Thundathil, J, Gil, J, Januskauskas, A, Larsson, B, Soderquist, L, Mapletoft, R and Rodriguez-Martinez, H 1999. Relationship between the proportion of capacitated spermatozoa present in frozen-thawed bull semen and fertility with artificial insemination. International Journal of Andrology 22, 366373.Google Scholar
Tollner, TL, Dong, Q and VandeVoort, CA 2011. Frozen-thawed rhesus sperm retain normal morphology and highly progressive motility but exhibit sharply reduced efficiency in penetrating cervical mucus and hyaluronic acid gel. Cryobiology 62, 1521.Google Scholar
Tollner, TL, Yudin, AI, Treece, CA, Overstreet, JW and Cherr, GN 2004. Macaque sperm release ESP13.2 and PSP94 during capacitation: the absence of ESP13.2 is linked to sperm-zona recognition and binding. Molecular Reproduction and Development 69, 325337.CrossRefGoogle ScholarPubMed
Tollner, TL, Yudin, AI, Tarantal, AF, Treece, CA, Overstreet, JW and Cherr, GN 2008a. Beta-defensin 126 on the surface of macaque sperm mediates attachment of sperm to oviductal epithelia. Biology of Reproduction 78, 400412.Google Scholar
Tollner, TL, Yudin, AI, Treece, CA, Overstreet, JW and Cherr, GN 2008b. Macaque sperm coating protein DEFB126 facilitates sperm penetration of cervical mucus. Human Reproduction 23, 25232534.Google Scholar
Vazquez, JM, Parrilla, I, Gil, MA, Cuello, C, Caballero, I, Vazquez, JL, Roca, J and Martinez, EA 2008. Improving the efficiency of insemination with sex-sorted spermatozoa. Reproduction in Domestic Animals 43 (suppl. 4), 18.CrossRefGoogle ScholarPubMed
Velasquez, JG, Canovas, S, Barajas, P, Marcos, J, Jimenez-Movilla, M, Gallego, RG, Ballesta, J, Aviles, M and Coy, P 2007. Role of sialic acid in bovine sperm-zona pellucida binding. Molecular Reproduction and Development 74, 617628.Google Scholar
Verberckmoes, S 2004. Preservation of fresh bovine semen and utero-tubal junction insemination in cattle. Thesis PhD, Ghent University, Ghent, Belgium.Google Scholar
Verberckmoes, S, Van Soom, A, Dewulf, J and de Kruif, A 2005. Comparison of three diluents for the storage of fresh bovine semen. Theriogenology 63, 912922.Google Scholar
Verberckmoes, S, Van Soom, A, Dewulf, J, De Pauw, I and de Kruif, A 2004. Storage of fresh bovine semen in a diluent based on the ionic composition of cauda epididymal plasma. Reproduction in Domestic Animals 39, 410416.Google Scholar
Visconti, PE, Westbrook, VA, Chertihin, O, Demarco, I, Sleight, S and Diekman, AB 2002. Novel signaling pathways involved in sperm acquisition of fertilizing capacity. Journal of Reproductive Immunology 53, 133150.Google Scholar
Vishwanath, R 2003. Artificial insemination: the state of the art. Theriogenology 59, 571584.Google Scholar
Vishwanath, R and Shannon, P 1997. Do sperm cells age? A review of the physiological changes in sperm during storage at ambient temperature. Reproduction, Fertility and Development 9, 321331.Google Scholar
Vishwanath, R and Shannon, P 2000. Storage of bovine semen in liquid and frozen state. Animal Reproduction Science 62, 2353.Google Scholar
Watson, PF 1995. Recent developments and concepts in the cryopreservation of spermatozoa and the assessment of their post-thawing function. Reproduction, Fertility and Development 7, 871891.Google Scholar
Yudin, AI, Hanson, FW and Katz, DF 1989. Human cervical mucus and its interaction with sperm: a fine-structural view. Biology of Reproduction 40, 661671.CrossRefGoogle ScholarPubMed
Yudin, AI, Generao, SE, Tollner, TL, Treece, CA, Overstreet, JW and Cherr, GN 2005. Beta-defensin 126 on the cell surface protects sperm from immunorecognition and binding of anti-sperm antibodies. Biology of Reproduction 73, 12431252.Google Scholar
Zahariev, Z, Stefanov, R, Sabev, M, Miteva, K and Nikolov, I 2007. Cytochrome C affects the viability and fertility of bull semen. American-Eurasian Journal of Agricultural and Environmental Sciences 2, 4850.Google Scholar