The roles of the epididymis and prostasomes in the attainment of fertilizing capacity by stallion sperm

The epididymis is a long, tightly coiled tube within the lumen of which sperm matures. Sperm maturation involves morphological and biochemical changes in the sperm plasma membrane in response to epididymal secretions and their various proteins. Some of these proteins become outer membrane components while others become integral membrane proteins; transfer of some proteins to the sperm plasma membrane may be mediated by epididymosomes. Nevertheless, the molecular pathways by which spermatozoa acquire fertilizing capacity during their transit through the epididymis remain ambiguous. In a recent study of stallion epididymal sperm, we found that sperm harvested from different parts of the epididymis (caput, corpus and cauda) had a varying, but generally poor, ability to undergo the acrosome reaction in vitro. At ejaculation, however, sperm mix with seminal plasma which contains various components, including the small membranous vesicles known as prostasomes, that may enable the sperm to undergo physiological activation. Seminal plasma components may have a 'washing' effect and help to remove 'de-capacitation' factors that coat the sperm during storage in the cauda epididymis; alternatively seminal plasma and prostasomes may contain factors that more directly promote sperm activation. This article reviews current information on the roles of epididymal and accessory gland fluids on the acquisition of fertilizing capacity by stallion sperm.     

In vitro fertilization of horse follicular oocytes matured in vitro

In vitro fertilizing ability of stallion spermatozoa was assessed using horse follicular oocytes matured in vitro. After collection, stallion spermatozoa were either: 1) washed and incubated in TALP medium with 3 mg/ml bovine serum albumin (BSA) and 10 micrograms/ml heparin for 4h, 2) washed and incubated in TALP with 3 mg/ml BSA for 3 h and cultured for a further 1 h with 1 mM caffeine and 5 mM dbcAMP, 3) washed and incubated in TALP medium with 3 mg/ml BSA at pH 7.9-8.2 for 2-4 h, or 4) diluted and incubated in TALP medium with 10 mg/ml BSA and 7.14 microM calcium ionophore A 23187 for 5-10 min followed by washing. After a given pretreatment, suspensions were diluted into B2 medium to a concentration of 5 x 10(6) sperm/ml and co-incubated with oocytes for 12 h or 24-48 h. In the ionophore-treated group, 18 of 54 oocytes (33%) were fertilized by 12 h, and 11 of 45 (24%) cleaved by 24-48 h. Evidence of fertilization was not found in the oocytes incubated with spermatozoa from other treatment procedures.     

Colloidal centrifugation with Androcoll-E™ prolongs stallion sperm motility, viability and chromatin integrity

The objective was to investigate the changes in stallion sperm quality (sperm motility, viability, membrane integrity and chromatin integrity) occurring during cool storage, and to study the effect of sperm selection by single layer colloidal centrifugation on these parameters of sperm quality. Spermatozoa from 3 stallions (10 ejaculates, 3–4 per stallion) were selected by centrifugation through a single layer of colloid (SLC). The resulting sperm preparations and the control samples (extended but unselected semen samples) were stored at 5 °C for 48 h. Assessments of sperm quality, such as sperm motility, viability (SYBR-14/PI staining), membrane stability (Annexin-V/PI staining) and chromatin integrity, were performed on aliquots of the selected sperm preparations and unselected samples on the day of collection (3 h) and after 24 and 48 h of storage. In the SLC-selected sperm samples, sperm motility, sperm viability, proportions of spermatozoa with normal morphology and with intact chromatin were significantly better than in unselected samples (motility: 77 ± 4% vs. 64 ± 8% at 3 h; P < 0.001; viability: 79.5 ± 9% vs. 64.7 ± 9%, P < 0.001; normal morphology 89 ± 6% vs. 69 ± 9%; chromatin integrity DFI 11.3 ± 5% vs. 22.1 ± 10%). Membrane stability, however, was not different in the SLC-selected and unselected samples (74.6 ± 8% vs. 69.3 ± 8%). The deterioration seen in sperm quality in the unselected samples was prevented by SLC, so that sperm viability, membrane stability and chromatin integrity were unchanged in the selected samples by 48 h compared to 3 h (P < 0.001), whereas the unselected samples were significantly worse by 48 h (P < 0.001). Furthermore, it should be possible to send an aliquot of a normal insemination dose (i.e. unselected spermatozoa) overnight to a reference laboratory for analysis of both plasma membrane and chromatin integrity. In conclusion, centrifugation of stallion spermatozoa through a single layer of colloid is a useful technique for selecting the best spermatozoa from an ejaculate and, moreover, sperm quality is maintained during storage.     

Osmotic tolerance limits and membrane permeability characteristics of stallion spermatozoa treated with cholesterol

Stallion spermatozoa exhibit osmotic damage during the cryopreservation process. Recent studies have shown that the addition of cholesterol to spermatozoal membranes increases the cryosurvival of bull, ram and stallion spermatozoa, but the exact mechanism by which added cholesterol improves cryosurvival is not understood. The objectives of this study were to determine if adding cholesterol to stallion sperm membranes alters the osmotic tolerance limits and membrane permeability characteristics of the spermatozoa. In experiment one, stallion spermatozoa were treated with cholesterol-loaded cyclodextrin (CLC), subjected to anisotonic solutions and spermatozoal motility analyzed. The spermatozoa were then returned to isotonic conditions and the percentages of motile spermatozoa again determined. CLC treatment increased the osmotic tolerance limit of stallion spermatozoa in anisotonic solutions and when returned to isotonic conditions. The second and third experiments utilized an electronic particle counter to determine the plasma membrane characteristics of stallion spermatozoa. In experiment two, stallion spermatozoa were determined to behave as linear osmometers. In experiment three, spermatozoa were treated with CLC, incubated with different cryoprotectants (glycerol, ethylene glycol or dimethyl formamide) and their volume excursions measured during cryoprotectant removal at 5° and 22 °C. Stallion spermatozoa were less permeable to the cryoprotectants at 5 °C than 22 °C. Glycerol was the least permeable cryoprotectant in control cells. The addition of CLC’s to spermatozoa increased the permeability of stallion spermatozoa to the cryoprotectants. Therefore, adding cholesterol to spermatozoal membranes reduces the amount of osmotic stress endured by stallion spermatozoa during cryopreservation.     

Single-layer centrifugation with Androcoll-E can be scaled up to allow large volumes of stallion ejaculate to be processed easily

The objective of the current study was to optimize the volumes of Androcoll-E and sperm sample used in various sizes of centrifuge tube to scale up single-layer centrifugation (SLC) for routine use in the field. Although sperm suspensions of equivalent quality were produced using Androcoll-E in small and large tubes, the sperm yield was much lower in the latter (P < 0.001). In contrast, in 200-mL tubes (XL), the yields were approximately 25% higher than those for the small tubes. An increased volume (4.5 mL) of extended ejaculate in small tubes (SLC-Inc) or 15 to 18 mL extended ejaculate on 15 mL of colloid of a reduced density, Androcoll-E-Large (SLC-Large), in 50-mL tubes were both found to give similar yields of motile spermatozoa as that of the SLC-Small method (SLC-Small, 49.7 ± 18.6%; SLC-Inc, 53.3 ± 17.1%; SLC-Large, 44.9 ± 18.3%) and were found to be equivalent in quality (motility: 88.0 ± 8.8%, 84.0 ± 3.5%, 90.0 ± 5.4%; normal morphology: 69.4 ± 17.0%, 69.4 ± 12.7%, 63.9 ± 15.6%; viability: 78 ± 16.7%, 83.8 ± 12.5%, 80.05 ± 14.6%; DNA fragmentation index: 14.7 ± 10.9%, 12.8 ± 8.1%, 11.6 ± 7.6%, respectively). The processing of an “average” stallion Equus caballus ejaculate in approximately twenty-seven 10-mL tubes (SLC-Inc) or eight 50-mL tubes (SLC-Large) is feasible, the latter being considered more practical for on-stud use.     

Influence of seminal plasma on fertility of fresh and frozen-thawed stallion epididymal spermatozoa

The use of epididymal stallion spermatozoa for routine artificial insemination can secure easy future use of valuable genetics after unforeseen death or injury of a valuable stallion.     

Oxytocin, vasopressin, prostaglandin F2α, luteinizing hormone, testosterone, estrone sulfate, and cortisol plasma concentrations after sexual stimulation in stallions

This experiment was designed to determine the effects of sexual stimulation on plasma concentrations of oxytocin (OT), vasopressin (VP), 15-ketodihydro-PGF_2α (PG-metabolite), luteinizing hormone (LH), testosterone (T), estrone sulfate (ES), and cortisol (C) in stallions. Semen samples were collected from 14 light horse stallions (Equus caballus) of proven fertility using a Missouri model artificial vagina. Blood samples were collected at 15, 12, 9, 6, and 3 min before estrous mare exposure, at erection, at ejaculation, and at 3, 6, and 9 min after ejaculation. Afterwards, blood sampling was performed every 10 min for the following 60 min. Sexual activity determined an increase in plasma concentrations of OT, VP, C, PG-metabolite, and ES and caused no changes in LH and T concentrations. The finding of a negative correlation between C and VP at erection, and between C and T before erection and at the time of erection, could be explained by a possible inhibitory role exerted by C in the mechanism of sexual arousal described for men.     

Lectin-binding sites on ejaculated stallion sperm during breeding and non-breeding periods

Stallion sperm from semen collected in Southern Italy during the breeding (June-July) and non-breeding (December-January) periods were analyzed by means of twelve lectins to evaluate the glycoconjugate pattern and to verify whether there are any seasonal differences in the glycosylation pattern of the sperm glycocalyx. The acrosomal cap showed reactivity for Maackia amurensis (MAL II), Sambucus nigra (SNA), Arachis hypogaea (PNA), Glycine max (SBA), Helix pomatia (HPA), Canavalia ensiformis (Con A) Triticum vulgaris (WGA), and Griffonia simplicifolia isolectin II (GSA II) in breeding and non-breeding ejaculated sperm, suggesting the presence of oligosaccharides terminating with Neu5Acα2,3Galβ1,4GlcNAc, Neu5Acα2,6Gal/GalNAc, with Galβ1,3GalNAc, α/βGalNAc and glycans with terminal/internal αMan and GlcNAc. During the non-breeding period, the acrosomal cap expressed oligosaccharides terminating with Galβ1,4GlcNAc (Ricinus communis₁₂₀ affinity) (RCA₁₂₀) and L-Fucα1,2Galβ1,4GlcNAcβ (Ulex europaeus affinity) (UEA I). The equatorial segment placed between the acrosomal cap and post-acrosomal region did not display glycans terminating with GalNAc, GlcNAc, and αL-Fuc. The post-acrosomal region of sperm collected in the breeding and non-breeding periods bound Con A, MAL II, SNA, and SBA, thus showing the presence of N-linked oligosaccharides from high-Man content, terminating with Neu5Acα2,3Galβ1,4GlcNAc, Neu5Acα2,6Gal/GalNAc and GalNAc. In winter, the post-acrosomal region also expressed oligosaccharides terminating with αGalNAc, GlcNAc, and L-Fucα1,2Galβ1,4GlcNAcβ (HPA, GSA II, and UEA I staining). The tail of sperm from semen collected during the breeding and non-breeding periods showed a lectin binding pattern similar to the post-acrosomal region, except for the absence of HPA staining in sperm collected during the winter season. These results indicate that the surface of stallion sperm contains different glycocalyx domains and that the glycosylation pattern undergoes changes during the breeding and non-breeding periods.     

Lactoferrin expression and secretion in the stallion epididymis

Lactoferrin is one of the most abundant proteins secreted by the stallion epididymis, but its cellular localization and regulation remain unknown. This study was designed to address the following objectives: (1) identify the epididymal cell types producing lactoferrin in pre-pubertal, peri-pubertal and post-pubertal animals; (2) demonstrate that lactoferrin binds to stallion sperm; and (3) determine if testosterone and estradiol regulate lactoferrin secretion in vitro. Using an immunohistochemical method, lactoferrin was localized in the cytoplasm of principal cells in the corpus and cauda of peri- and post-pubertal animals. The epididymis of pre-pubertal animals did not express lactoferrin. Immunolabeling of lactoferrin was also observed on the mid-piece and tail of the sperm. The role of estradiol and testosterone in regulating secretion of lactoferrin in the post-pubertal epididymis was investigated using tissue culture methods. Lactoferrin concentration in the culture media was determined by validated enzyme-linked immunosorbent assays (ELISA). Testosterone did not increase the concentration of lactoferrin in the media in any epididymal region. In contrast, estradiol-17β significantly increased the concentration of lactoferrin in the media containing tissue from the cauda. In conclusion, the expression of lactoferrin was found in the cytoplasm of principal cells in the corpus and cauda of the epididymis in peri- and post-pubertal stallions but not pre-pubertal stallions. Furthermore, lactoferrin binds to sperm, suggesting a biological role for protection or regulation of sperm in the corpus and cauda. In addition, estrogen appears to regulate lactoferrin secretion in the cauda of the epididymis in post-pubertal stallions.     

Equine spermatozoa stored in the epididymis for up to 96 h at 4 °C can be successfully cryopreserved and maintain their fertilization capacity

After injury or death of a valuable male, recovery of epididymal spermatozoa may be the last chance to ensure preservation of its genetic material. The objective of this research was to study the effect of sperm storage, at 4 °C up to 96 h, in the epididymides obtained from castrated horses and its effect on different functional sperm parameters. Aims were to study the effect of (1) sperm storage on viability and chromatin condensation; (2) pre-incubation of recovered epididymal sperm in the freezing extender, prior cryopreservation, on viability and chromatin condensation; and (3) freezing–thawing on viability, chromatin condensation, ROS generation, protein tyrosine phosphorylation and heterologous fertilization rate (ICSI and IVF using bovine oocytes) of sperm recovered from the epididymis up to 96 h post castration. The average volume (720 ± 159 μL) and the concentration (6.5 ± 0.4 × 10⁹ spermatozoa/mL) of sperm recovered from the epididymis were not affected by storage. Sperm viability after refrigeration at 4 °C for up to72 h was similar (P < 0.01). The effect of sperm dilution in the freezing media showed similar values up to 48 h, while viability was preserved up to 72 h (P < 0.01). Cryopreserved spermatozoa show similar viability between different storage times. Chromatin condensation was not affected by storage time; however, incubation for 30 min in freezing medium and freezing–thawing process induced an increase in the chromatin decondensation. ROS generation was not affected by storage up to 96 h. Epididymal storage did not affect sperm protein tyrosine phosphorylation patterns; although the pattern of phosphorylation changed to strong staining of the equatorial segment when the sperm where capacitated in sperm–TALP. Finally, successful and similar pronuclear formation (analyzed by ICSI) and in vitro penetration (evaluated with bovine zone free oocyte) was observed using cryopreserved sperm obtained from prolong epididymal storage at 4 °C. In conclusion, cryopreservation of epididymal stallion sperm stored for up to 72 h in the epididymis at 4 °C, maintain both viability and ability to fertilize in vitro.