Components in seminal plasma regulating sperm transport and elimination.
Abstract: Seminal plasma has been suggested to be involved in sperm transport, and as a modulator of sperm-induced inflammation, which is thought to be an important part of sperm elimination from the female reproductive tract. This article reports on recent experiments on the importance of seminal plasma components in sperm transport and elimination. In Experiment 1, hysteroscopic insemination in the presence (n = 3) or absence (n = 3) of 2 ng/mL PGE showed an increased portion of spermatozoa crossing the utero-tubal junction in the presence of PGE in two mares, while no difference was observed between treatments in a third mare. In Experiment 2, whole seminal plasma, heat-treated seminal plasma (90 degrees C for 45 min), and charcoal-treated seminal plasma were added to: (1) sperm samples during opsonization prior to polymorphonuclear neutrophil(s) (PMN)-phagocytosis assays (n = 5); or to (2) phagocytosis assays (n = 5). Opsonization of spermatozoa was suppressed in the presence of whole seminal plasma, compared with samples without seminal plasma (p < 0.05). Charcoal treatment did not remove the suppressive effect of seminal plasma on opsonization, but heat treatment of seminal plasma reduced its suppressive properties (p < 0.05). The addition of whole seminal plasma to opsonized spermatozoa almost completely blocked phagocytosis (p < 0.05). Charcoal treatment did not remove the suppressive effect of seminal plasma. However, heat-treated fractions of seminal plasma removed the suppressive effect of seminal plasma on phagocytosis (p < 0.05). In Experiment 3, viable and non-viable (snap-frozen/thawed) spermatozoa were subjected to in vitro assays for PMN binding and phagocytosis with the following treatments (n = 3): (1) seminal plasma (SP), (2) extender; (3) ammonium sulfate precipitated seminal plasma proteins with protease inhibitor (SPP+); or (4) ammonium sulfate precipitated seminal plasma proteins without protease inhibitor (SPP-). Treatment was observed to impact binding and phagocytosis of viable and non-viable spermatozoa (p < 0.05). SP and SPP+ suppressed PMN-binding and phagocytosis of viable sperm. This effect was also seen, but to a lesser degree, in SPP- treated samples. Non-viable spermatozoa showed less PMN-binding and phagocytosis than live sperm in the absence of SP. The addition of SP promoted PMN-binding and phagocytosis of non-viable spermatozoa. SPP- treated samples also restored PMN-binding of non-viable spermatozoa. The addition of protease inhibitors removed this effect. In Experiment 4, seminal plasma proteins were fractionated based on MW by Sephacryl S200 HR columns (range 5000-250,000 kDa). Fractionated proteins were submitted to sperm-PMN binding assays. A protein fraction <35 kDa suppressed PMN-binding to live and snap-frozen spermatozoa. A greater MW protein fraction appeared to promote binding between PMNs and snap-frozen spermatozoa. While the addition of protease inhibitors was necessary to maintain the protective effect of seminal plasma proteins on viable spermatozoa, the promotive effect of seminal plasma on non-viable spermatozoa appeared to require some protease activity. It was concluded from these experiments that components of seminal plasma play active roles in transportation and survival of viable spermatozoa in the female reproductive tract and in the elimination of non-viable spermatozoa from the uterus.
Publication Date: 2005-08-17 PubMed ID: 16102920DOI: 10.1016/j.anireprosci.2005.07.005Google Scholar: Lookup
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- Journal Article
- Research Support
- Non-U.S. Gov't
- Review
Summary
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This study delves into the role of seminal plasma in sperm transport and elimination. The researchers conducted several experiments to understand how components of seminal plasma interact with spermatozoa, and determine the significant influences they exert on the survival and removal of viable and non-viable sperm, respectively.
Experiment 1: Seminal Plasma and Sperm Transport
- Animal model experiments were conducted on mares, with seminal plasma present in some experiments while absent in others.
- The study showed that the presence of PGE, a component of seminal plasma, affected the level of spermatozoa crossing the utero-tubal junction.
- The results indicated PGE’s potential role in sperm transport within the reproductive tract.
Experiment 2: Seminal Plasma and Sperm Elimination
- Utilizing polymorphonuclear neutrophil (PMN)-phagocytosis assays, the research observed involving both sperm samples and seminal plasma in different treatment conditions.
- The study noticed that the seminal plasma surpressed the opsonization of spermatozoa – regulators of immune response that make cells more attractive to phagocytes.
- Charcoal treatment of seminal plasma did not remove the suppressive effect, whereas heat treatment reduced these inhibitive properties.
- They discovered that the addition of whole seminal plasma nearly completely blocked phagocytosis – the engulfing of cells by a living host.
Experiment 3: Impact of Seminal Plasma on Phagocytosis
- In vitro assays determining PMN binding and phagocytosis were performed on both viable and non-viable spermatozoa.
- The results pointed out that viable and non-viable sperm had differential interaction characteristics with PMN in the presence of various forms of seminal plasma and its components.
- While viable sperm showed reduced binding and phagocytosis under the influence of seminal plasma and its ammonium sulfate precipitated fractions, non-viable sperm interaction with PMN was boosted by these components.
Experiment 4: Role of Seminal Plasma Proteins
- The study fractionated seminal plasma proteins based on molecular weight and assessed how each protein relate with sperm and PMN binding.
- It was discovered that a protein fraction less than 35kDa suppressed PMN binding, while larger proteins intensified the binding between PMNs and non-viable sperm.
- These findings indicated the critical role these proteins play in the survival and elimination of viable and non-viable spermatozoa, respectively.
Overall, the research concludes that seminal plasma components are key players in the transportation and survival of viable sperm in the female reproductive tract, and in the removal of non-viable sperm from the uterus.
Cite This Article
APA
Troedsson MH, Desvousges A, Alghamdi AS, Dahms B, Dow CA, Hayna J, Valesco R, Collahan PT, Macpherson ML, Pozor M, Buhi WC.
(2005).
Components in seminal plasma regulating sperm transport and elimination.
Anim Reprod Sci, 89(1-4), 171-186.
https://doi.org/10.1016/j.anireprosci.2005.07.005 Publication
Researcher Affiliations
- Department of Large Animal Clinical Sciences, University of Florida, Gainesville, FL 32610, USA. troedssonm@mail.vetmed.ufl.edu
MeSH Terms
- Animals
- Female
- Horses
- Hot Temperature
- Insemination, Artificial / methods
- Insemination, Artificial / veterinary
- Male
- Neutrophils / physiology
- Phagocytosis
- Prostaglandins E / administration & dosage
- Prostaglandins E / physiology
- Semen / chemistry
- Semen / physiology
- Sperm Transport / drug effects
- Sperm Transport / physiology
Citations
This article has been cited 15 times.- Li Y, Wang H, Wang S, Zhang Q, Zhang H, Li T, Wang Q, Guo M, Feng H, Song Y, Wei G, Li J. Methylprednisolone improves the quality of liquid preserved boar spermatozoa in vitro and reduces polymorphonuclear neutrophil chemotaxis and phagocytosis.. Front Vet Sci 2023;10:1177873.
- Alghamdi AS, Fedorka CE, Scoggin KE, Esteller-Vico A, Beatty K, Davolli G, Ball BA, Troedsson MHT. Binding of Equine Seminal Lactoferrin/Superoxide Dismutase (SOD-3) Complex Is Biased towards Dead Spermatozoa.. Animals (Basel) 2022 Dec 23;13(1).
- Bazzano M, Zhu C, Laus F, Giambattista AD, Laghi L. Exploring the metabolome of seminal plasma in two different horse types: Light versus draft stallions.. Reprod Domest Anim 2023 Jan;58(1):109-116.
- Catalán J, Yánez-Ortiz I, Tvarijonaviciute A, González-Arostegui LG, Rubio CP, Yeste M, Miró J, Barranco I. Impact of Seminal Plasma Antioxidants on Donkey Sperm Cryotolerance.. Antioxidants (Basel) 2022 Feb 18;11(2).
- Mayoral Andrade G, Vásquez Martínez G, Pérez-Campos Mayoral L, Hernández-Huerta MT, Zenteno E, Pérez-Campos Mayoral E, Martínez Cruz M, Martínez Cruz R, Matias-Cervantes CA, Meraz Cruz N, Romero Díaz C, Cruz-Parada E, Pérez-Campos E. Molecules and Prostaglandins Related to Embryo Tolerance.. Front Immunol 2020;11:555414.
- Parrilla I, Martinez EA, Gil MA, Cuello C, Roca J, Rodriguez-Martinez H, Martinez CA. Boar seminal plasma: current insights on its potential role for assisted reproductive technologies in swine.. Anim Reprod 2020 Jul 21;17(3):e20200022.
- Schöniger S, Schoon HA. The Healthy and Diseased Equine Endometrium: A Review of Morphological Features and Molecular Analyses.. Animals (Basel) 2020 Apr 5;10(4).
- Álvarez-Rodríguez M, Martinez CA, Wright D, Rodríguez-Martinez H. The role of semen and seminal plasma in inducing large-scale genomic changes in the female porcine peri-ovulatory tract.. Sci Rep 2020 Mar 19;10(1):5061.
- Ross KA, Kolb DS, Macedo A, Anderson M, Klein C. Seminal plasma does not aid in the transport of phenolsulfonphthalein across the uterotubal junction in mares.. Can Vet J 2018 Sep;59(9):988-992.
- Domingo P, Olaciregui M, González N, De Blas I, Gil L. Effects of seminal plasma and different cryoprotectants on rabbit sperm preservation at 16°C.. Exp Anim 2018 Nov 1;67(4):413-420.
- Brazdova A, Senechal H, Peltre G, Poncet P. Immune Aspects of Female Infertility.. Int J Fertil Steril 2016 Apr-Jun;10(1):1-10.
- Sasanami T, Izumi S, Sakurai N, Hirata T, Mizushima S, Matsuzaki M, Hiyama G, Yorinaga E, Yoshimura T, Ukena K, Tsutsui K. A unique mechanism of successful fertilization in a domestic bird.. Sci Rep 2015 Jan 9;5:7700.
- Maischberger E, Irwin J, Carrington S, Duggan V. Equine post-breeding endometritis: A review.. Ir Vet J 2008 Mar 1;61(3):163-8.
- Morrell JM, Rodriguez-Martinez H. Practical applications of sperm selection techniques as a tool for improving reproductive efficiency.. Vet Med Int 2010 Aug 4;2011.
- Robert C, Caille A, Zumoffen C, Cabada M, Ghersevich S. Effect of human oviductal in vitro secretion on human sperm DNA integrity.. J Assist Reprod Genet 2008 Jun;25(6):263-70.
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