Semen extender and seminal plasma alter the extent of neutrophil extracellular traps (NET) formation in cattle

During artificial insemination in bovine, the deposition of semen into the uterus results in an immune reaction which is based on polymorphonuclear neutrophils activity, including the formation of neutrophil extracellular traps. The formation of neutrophil extracellular traps as a reaction of neutrophils to spermatozoa was recently described. However, it is not completely clear which components of the semen are responsible for this reaction. The objective of this study was to quantify and compare the formation of neutrophil extracellular traps following in vitro incubation of bovine polymorphonuclear neutrophils with semen and extenders of different origins and conditions. We investigated the interactions between bovine polymorphonuclear neutrophils and different semen extenders, various seminal plasma concentrations from young and old bulls as well as sexed and non-sexed semen and their corresponding extenders. Three different semen extenders from two companies in fresh and frozen-thawed conditions were compared. Fresh semen extenders showed higher neutrophil extracellular traps induction than did frozen-thawed ones. The formation of neutrophil extracellular traps were also dependent on the presence of seminal plasma. We could show that seminal plasma alone, without any sperm cells, induced the reaction and that the addition of at least 1% seminal plasma already resulted in the formation of neutrophil extracellular traps. Furthermore, seminal plasma from young bulls led to significant higher neutrophil extracellular traps induction. No difference between non-sex-sorted and sex-sorted sperm and its extenders was observed. Taken together, different semen extenders as well as the amount and origin of seminal plasma influence neutrophil extracellular traps formation, whereas sex-sorted sperm did not affect the reaction.

Ram seminal plasma and its functional proteomic assessment

Ejaculation results in the confluence of epididymal spermatozoa with secretions of the accessory sex glands. This interaction is not a prerequisite for fertilisation success, but seminal factors do play a crucial role in prolonging the survival of spermatozoa both in vitro and in vivo by affording protection from handling induced stress and some selective mechanisms of the female reproductive tract. Reproductive biologists have long sought to identify specific factors in seminal plasma that influence sperm function and fertility in these contexts. Many seminal plasma proteins have been identified as diagnostic predictors of sperm function and have been isolated and applied in vitro to prevent sperm damage associated with the application of artificial reproductive technologies. Proteomic assessment of the spermatozoon, and its surroundings, has provided considerable advances towards these goals and allowed for greater understanding of their physiological function. In this review, the importance of seminal plasma will be examined through a proteomic lens to provide comprehensive analysis of the ram seminal proteome and detail the use of proteomic studies that correlate seminal plasma proteins with ram sperm function and preservation ability.

Dialysis of the goat semen and its effect on the quality of frozen/thawed spermatozoa processed in the presence of egg yolk

The aim of the present study was to analyze the effect of dialysis on the quality of frozen/thawed buck semen. Ejaculates (n = 15) from three Saanen bucks were divided into three experimental groups. Semen in Group Ce (centrifugation) was processed by standard method and washed two times at 1.085 × g for 20 min. During this time, the diluted control semen (Co) was stored at room temperature. Semen in Group D was dialyzed using 300 kDa cut-off semi-permeable cellulose tubing. The semen from all groups was diluted with extender containing 20% egg yolk and frozen in liquid nitrogen vapor. After thawing, semen samples were evaluated by microscopic and biochemical analyses. Phospholipase A2 was in amounts that was 72.0 ± 11.7% less after dialysis and 21.3 ± 10.0% less after washing with centrifugation compared to the control semen (P <  0.05). Spermatozoa from Group Co had a lesser motility and viability and greater percentage of morphological abnormal spermatozoa in comparison to Groups D and Ce at 3 h after thawing and incubation on 37 °C. At the same time motility and percentage of HOST positive spermatozoa were greater in Group Ce compared with D (P <  0.05). There, however, was no difference in morphology and viability (CFDA/PI analysis) of spermatozoa between Ce and D group. Results from the present study suggest the dialysis is the promising alternative method for reducing phospholipase A2 in the buck semen before cryopreservation.

Motility of liquid stored ram spermatozoa is altered by dilution rate independent of seminal plasma concentration

The fertility after use of liquid stored ram semen following cervical AI rapidly decreases if semen is stored beyond 12h. The dilution of seminal plasma is often cited as a key contributor to the diminished motility and fertility of ram spermatozoa subjected to liquid preservation. Two experiments were conducted to assess the effect of spermatozoa concentration (i.e. dilution rate) and percentage of seminal plasma on the motility and viability of liquid stored ram spermatozoa. In Experiment 1, semen was diluted to one of seven concentrations ranging from 0.2 to 1.4×10(9)spermatozoa/ml with milk and assessed for motility after 3 or 24h of storage at 15°C. In Experiment 2, semen was collected and washed to remove seminal plasma before re-dilution to 0.2-1.4×10(9)spermatozoa/ml with milk containing 0%, 20% or 40% (final v/v ratio) seminal plasma and assessed for viability and motility after 3 or 24h of storage at 15°C. Whereas motility was not affected by spermatozoa concentration after 3h of storage, the proportion of progressive spermatozoa decreased after 24h of storage when spermatozoa concentration was greater than 1.0×10(9)spermatozoa/ml. The duration of preservation and the spermatozoa concentration affected spermatozoa motility but had no impact on spermatozoa viability. This negative effect of greater spermatozoa concentrations on motility was independent of the presence and the concentration of seminal plasma. The seminal plasma at both concentrations (20% and 40%) had a protective effect on spermatozoa motility after 24h of storage. These findings have the potential to improve the efficiency of cervical AI with liquid stored ram semen.

Current and future assisted reproductive technologies for mammalian farm animals

Reproduction in domestic animals is under control by man and the technologies developed to facilitate that control have a major impact on the efficiency of food production. Reproduction is an energy-intensive process. In beef cattle, for example, over 50 % of the total feed consumption required to produce a unit of meat protein is consumed by the dam of the meat animal (Anim Prod 27:367-379, 1978). Sows are responsible for about 20 % of the total feed needed to produce animals for slaughter (Adv Pork Prod 19:223-237, 2008). Accordingly, energy input to produce food from animal sources is reduced by increasing number of offspring per unit time a breeding female is in the herd. Using beef cattle as an example again, life-cycle efficiency for production of weaned calves is positively related to early age at puberty and short calving intervals (J Anim Sci 57:852-866, 1983). Reproductive technologies also dictate the strategies that can be used to select animals genetically for traits that improve production. Of critical importance has been artificial insemination (AI) (Anim Reprod Sci 62:143-172, 2000; Stud Hist Philos Biol Biomed Sci 38:411-441, 2007; Reprod Domest Anim 43:379-385, 2008; J Dairy Sci 92:5814-5833, 2009) and, as will be outlined in this chapter, emerging technologies offer additional opportunities for improvements in genetic selection. Given the central role of reproduction as a determinant of production efficiency and in genetic selection, improvements in reproductive technologies will be crucial to meeting the challenges created by the anticipated increases in world population (from seven billion people in 2011 to an anticipated nine billion by 2050; World population prospects: the 2010 revision, highlights and advance tables. Working Paper No. ESA/P/WP.220, New York) and by difficulties in livestock production wrought by climate change (SAT eJournal 4:1-23, 2007).The purpose of this chapter will be to highlight current and emerging reproductive technologies that have the potential to improve efficiency of livestock production. The focus will be on technologies that manipulate male and female gametes as well as the stem cells from which they are derived and the preimplantation embryo. While technology is crucial to other interventions in the reproductive process like control of seasonal breeding, hormonal regulation of ovulation, estrous cyclicity and pregnancy establishment, feeding to optimize reproduction, minimizing environmental stress, and selection of genes controlling reproduction, these will not be considered here. Rather the reader is directed to other chapters in this volume as well as some reviews on other aspects of artificial manipulation of reproduction (Reprod Fertil Dev 24:258-266, 2011; Reprod Domest Anim 43:40-47, 2008; Reprod Domest Anim 43:122-128, 2008; Soc Reprod Fertil Suppl 66:87-102, 2009; Comprehensive biotechnology, Amsterdam, pp 477-485; Dairy production medicine, Chichester, pp 153-163; Theriogenology 76:1619-1631, 2011; Theriogenology 76:1568-1582, 2011; Theriogenology 77:1-11, 2012). Given the large number of mammalian species used for production of products useful for man and the diversity in their biology and management, the review will not be comprehensive but instead will use results from species that are most illustrative of the opportunities generated by assisted reproductive technologies.

Proteomic characterization and cross species comparison of mammalian seminal plasma

Seminal plasma contains a large protein component which has been implicated in the function, transit and survival of spermatozoa within the female reproductive tract. However, the identity of the majority of these proteins remains unknown and a direct comparison between the major domestic mammalian species has yet to be made. As such, the present study characterized and compared the seminal plasma proteomes of cattle, horse, sheep, pig, goat, camel and alpaca. GeLC-MS/MS and shotgun proteomic analysis by 2D-LC-MS/MS identified a total of 302 proteins in the seminal plasma of the chosen mammalian species. Nucleobindin 1 and RSVP14, a member of the BSP (binder of sperm protein) family, were identified in all species. Beta nerve growth factor (bNGF), previously identified as an ovulation inducing factor in alpacas and llamas, was identified in this study in alpaca and camel (induced ovulators), cattle, sheep and horse (spontaneous ovulators) seminal plasma. These findings indicate that while the mammalian species studied have common ancestry as ungulates, their seminal plasma is divergent in protein composition, which may explain variation in reproductive capacity and function. The identification of major specific proteins within seminal plasma facilitates future investigation of the role of each protein in mammalian reproduction.

BIOLOGICAL SIGNIFICANCE

This proteomic study is the first study to compare the protein composition of seminal plasma from seven mammalian species including two camelid species. Beta nerve growth factor, previously described as the ovulation inducing factor in camelids is shown to be the major protein in alpaca and camel seminal plasma and also present in small amounts in bull, ram, and horse seminal plasma.

Seminal plasma proteins as modulators of the sperm function and their application in sperm biotechnologies

Seminal plasma (SP) is known to play an important role in mammalian fertilization. However, the variability found in its composition among species, males and even fractions of the same ejaculate has made difficult to completely understand its effect in sperm function. Proteins are one of the major SP components that modulate sperm functionality. During the last years, intensive work has been performed to characterize the role of these proteins. They have been found to influence sperm capacitation, formation of the oviductal sperm reservoir and sperm-oocyte interaction. Sperm biotechnologies, such as sperm cryopreservation and flow cytometric sex-sorting, that involve a substantial dilution of the SP are detrimental to sperm quality. Attempts to improve the outcome of these biotechnologies include the restoration of SP, which has produced contradictory results. To overcome this variability, different research groups have proposed the application of isolated SP proteins. Herein, we will review the current knowledge in the role of the major SP proteins as modulators of sperm functionality. Furthermore, we will discuss the possible applications of the SP proteins in sperm cryopreservation and flow cytometric sex-sorting.

Seminal plasma and its effect on ruminant spermatozoa during processing

Seminal plasma can both inhibit and stimulate sperm function, making its use as a supportive medium somewhat contradictory. These effects are directed by the multifunctional action of numerous inorganic and organic components, but it is the direct association of seminal plasma proteins with the sperm membrane that is thought to exert the most significant response. In vitro handling of spermatozoa in preparation for artificial insemination may involve washing, dilution, cooling, freezing, re-warming and sex-sorting. These processes can alter proteins of the sperm surface and reduce seminal plasma in the sperm environment. This, among other factors, may destabilize the sperm membrane and reduce the fertilizable lifespan of spermatozoa. Such handling-induced damage may be prevented or reversed through supplementation of seminal plasma, but the effectiveness of this technique differs with species, and the source and subsequent treatment of both spermatozoa and seminal plasma. Seminal plasma appears to act as a protective medium during in vitro processing of ram spermatozoa, but this does not appear to be the case for bull spermatozoa. The reasons for this divergent effect will be discussed with particular emphasis on the influence of the major proteins of ruminant seminal plasma, known as BSP proteins. The biochemical and biophysical properties of these proteins are well documented, and this information has provided greater insight into the signalling pathways of capacitation and the protective action of extender components.

Traversing the ovine cervix - a challenge for cryopreserved semen and creative science

This review brings together research findings on cervical relaxation in the ewe and its pharmacological stimulation for enhancement of the penetration needed for transcervical insemination and embryo transfer. On the basis that the success of artificial insemination is the percentage of ewes lambing, a review is made of recent research aimed at understanding and minimising the sub-lethal effects of freezing and thawing on the viability of spermatozoa, their membrane integrity and their ability to migrate through cervical mucus, as these characteristics have a major influence on fertility, particularly when semen is deposited, artificially, in the os cervix. Milestones of achievement are given for transcervical intrauterine insemination, embryo recovery and transfer and the birth of lambs of pre-determined sex, firstly following intracytoplasmic sperm injection, then laparoscopic intrauterine insemination using highly diluted flow-cytometrically sorted fresh semen and subsequently by os cervix insemination using sexed semen that had been frozen and thawed. Diversity of research endeavour (applied, cellular, molecular), research discipline (anatomy, histology, immunology, endocrinology) and research focus (cell, tissue, organ, whole animal) is embraced within the review as each has significant contributions to make in advancing recent scientific findings from the laboratory into robust on-farm transcervical insemination and embryo transfer techniques.

Sperm surface changes and physiological consequences induced by sperm handling and storage

Spermatozoa interact with their immediate environment and this contact remodels the sperm surface in preparation for fertilisation. These fundamental membrane changes will be critically covered in this review with special emphasis on the very specific surface destabilisation event, capacitation. This process involves very subtle and intricate modifications of the sperm membrane including removal of suppression (decapacitation) factors and changes in the lateral organisation of the proteins and lipids of the sperm surface. Processing of sperm for assisted reproduction (storage, sex-sorting, etc.) subjects spermatozoa to numerous stressors, and it is possible that this processing overrides such delicate processes resulting in sperm instability and cell damage. To improve sperm quality, novel mechanisms must be used to stabilise the sperm surface during handling. In this review, different types of membrane stress are considered, as well as novel surface manipulation methods to improve sperm stability.

Flow-sorted ram spermatozoa are highly susceptible to hydrogen peroxide damage but are protected by seminal plasma and catalase

To determine whether flow sorting increased the susceptibility of spermatozoa to reactive oxygen species (ROS), ram semen was either diluted with Tris medium (100 × 106 spermatozoa mL–1; D) or highly diluted (106 spermatozoa mL–1) before being centrifuged (DC) at 750g for 7.5 min at 21°C or flow-sorted (S) before cryopreservation. Thawed spermatozoa were resuspended in graded concentrations of hydrogen peroxide to induce oxidative stress. In Experiment 1, following exposure to 30 or 45 μM hydrogen peroxide (H2O2), the total motility (%) of DC (41.0 ± 7.3 or 25.7 ± 6.7, respectively) and S spermatozoa (33.8 ± 6.3 or 20.1 ± 6.3, respectively) was lower (P < 0.001) than that of D spermatozoa (58.7 ± 5.6 or 44.5 ± 6.7, respectively). In Experiment 2, supplementation of samples containing H2O2 with catalase (150 IU mL–1) or seminal plasma proteins (4 mg protein per 108 spermatozoa) negated oxidative stress, resulting in comparable values to samples receiving no H2O2in terms of the proportion of spermatozoa with stable plasmalemma (as determined using merocyanine-540 and Yo-Pro-1) in the D and S groups, the proportion of viable, acrosome-intact spermatozoa (as determined by fluorescein isothiocyanate and propidium iodide staining) in the D group and the motility of control (undiluted) and S spermatozoa. Neither H2O2 nor sperm type (i.e. D, DC or S) had any effect on intracellular concentrations of ROS. These results show that flow sorting increases the susceptibility of spermatozoa to ROS, but the inclusion of anti-oxidants or seminal plasma as part of the sorting protocol improves resistance to oxidative stress.

Seminal plasma proteins do not consistently improve fertility after cervical insemination of ewes with non-sorted or sex-sorted frozen - thawed ram spermatozoa

The effect of supplementation of sex-sorted and non-sorted spermatozoa with seminal plasma protein (SPP) on fertility after cervical insemination was examined in the present study. Spermatozoa were sorted into high purity X and Y chromosome-bearing spermatozoa or not sorted and then either supplemented with SPP (>10 kDa) before freezing and/or after thawing (non-sorted only) or processed without supplementation. Inseminations were performed over 2 days with ewes receiving 100 or 25 million motile non-sorted spermatozoa in the cervix or uterus, respectively, or two cervical inseminations of 3.5 million motile sorted spermatozoa. Pregnancy rates in cervically inseminated ewes were unaffected by supplementation of sorted or non-sorted spermatozoa with SPP before freezing compared with no supplementation. The effect of post-thaw supplementation of non-sorted spermatozoa with SPP on pregnancy rates after cervical insemination varied with the day of insemination (P < 0.05); fertility was similar to laparoscopic insemination on Day 1 (56.0 ± 10.2% v. 58.6 ± 10.1%), but not on Day 2 (23.1 ± 7.4% v. 66.7 ± 9.2%). In conclusion, under the conditions of the present study, SPP did not consistently improve pregnancy rates after cervical insemination with frozen–thawed ram spermatozoa. This is the first report of pregnancies (5/56 ewes inseminated) after cervical insemination with frozen–thawed sex-sorted ram spermatozoa. Although the success rate is low, the findings are encouraging because ewes inseminated with the sex-sorted spermatozoa received only 7% of the recommended dose (100 million motile) for cervical insemination of frozen–thawed spermatozoa.

Seasonal variation in the protective effect of seminal plasma on frozen-thawed ram spermatozoa

The response of ram spermatozoa to seminal plasma is highly variable, in part due to the presence of both stimulatory and inhibitory factors. The aim of this study was to assess variation in the protection of ram spermatozoa during freezing by seminal plasma. The seminal plasma variables studied were season of collection, fractionation and method of supplementation. Spermatozoa were supplemented before freezing with 4 mg of seminal plasma proteins (SPPs) per 10(8) cells, and their motility and viability were assessed during post-thaw incubation (37 degrees C). In Experiment 1, semen was (a) frozen with no supplementation (Control) (b) extended with a Tris-based diluent (C + TRIS), or (c) supplemented with seminal plasma collected throughout the year (in the Southern Hemisphere) and pooled for January-March, April-June, July-August and October-December, and either fractionated to produce a concentrated >10 kDa seminal plasma protein retentate (>10 kDa SPP), or kept as crude seminal plasma (CP). There was no effect of season or seminal plasma type (CP or >10 kDa SPP) on motility of spermatozoa. CP and >10 kDa SPP improved the viability of spermatozoa when collected from January-September compared to Control. Supplementation with >10 kDa SPP increased viability of spermatozoa, compared to CP, when collected from January to July. In Experiment 2, >10 kDa SPP were either added directly to the spermatozoa or included in the cryodiluent or >10 kDa SPP were not supplemented (Control). Both supplementation methods improved the motility and the proportion of viable, acrosome-intact spermatozoa but direct supplementation resulted in more viable, acrosome-intact spermatozoa compared with supplementation of the cryodiluent. These results show that supplementation of ram spermatozoa with CP, or its protein component (>10 kDa SPP), before freezing protects them from freeze-thaw damage. The protective effect is greatest when seminal plasma is collected during the breeding season, fractionated with >10 kDa filters and added directly to the spermatozoa.

Does erythropoietin affect motility of spermatozoa?

INTRODUCTION

Erythropoietin, which is a hematopoietic growth factor, has been found to play a role in various physiologic processes within the body including testicular steroidogenesis and spermatogenesis. However, it is not known whether erythropoietin is also essential for the normal physiology of mature sperm cells. In this study, the effects of recombinant human erythropoietin beta (rEPO) on sperm motility were investigated.

MATERIALS AND METHODS

Samples of 37 volunteers (with total motile sperm count>5x10(6)/ml and a total motility of >50% according to WHO criteria) were collected by masturbation following a 3-5 days period of abstinence. After morphometric analysis before and just after washing, samples were either used as control or treated with rEPO at concentrations of 0.1, 1, 10 or 100 mIU/ml, respectively. Control and treated tubes were incubated for 4 h at 37 degrees C.

RESULTS

Total motility, total progressive motility, slow forward and nonmotile sperm counts of 1, 10 and 100 mIU/ml rEPO groups were significantly improved. This effect was dose independent.

CONCLUSION

No significant effect was found at 0.1 mIU/ml concentration. These results suggest that supplementation of media used for sperm preparation techniques with erythropoietin might be beneficial. Further studies are needed to clarify the mechanism of action of erythropoietin on mature sperm cells.