Boar sperm storage capacity of BTS and Androhep Plus: viability, motility, capacitation, and tyrosine phosphorylation

Androhep Plus, a long-term extender (up to 7 days) and Beltsville Thawing Solution (BTS), a short-term extender (up to 3 days), are commonly used for liquid storage of porcine semen. To test the hypothesis that modifications in sperm viability, motility, chlortetracycline (CTC) fluorescence patterns, and protein tyrosine phosphorylation occur during semen storage in extenders, we compared these end points at different periods of storage in either Androhep Plus or BTS. Sperm from five boars were assessed daily over 12 days of storage (n = 5 ejaculates from different boars). Viability was not different (P < 0.05 between extenders, except on Day 2, when Androhep Plus maintained better viability. Differences in the percentage of motile (total) sperm due to extender were evident on Days 2, 4, 5, and 6, when Androhep Plus was superior to BTS (P < 0.05). The percentages of progressively motile sperm also differed, with Androhep Plus supporting higher rates on Days 2, 4, 5, 7, 8, 9, 10, and 11 (P < 0.05). The CTC fluorescence pattern distribution differed due to extender as early as Day 2; storage in Androhep Plus induced higher levels of pattern B sperm (P < 0.05) than storage in BTS. A tyrosine-phosphorylated protein of Mr 21,000 appeared after 10 days in sperm incubated in BTS, and was identified as a phospholipid hydroperoxide glutathione peroxidase. Therefore, modifications in viability, motility, CTC fluorescence patterns, and sperm protein tyrosine phosphorylation were apparent during sperm storage in extenders; these may affect the fertilizing capacity of the semen.     

Porcine sperm viability, oocyte fertilization and embryo development after staining spermatozoa with SYBR-14

The objective of these experiments was to determine the efficacy of the new membrane permeant nucleic acid stain, SYBR-14, for assessing boar sperm viability and to determine it's effect on fertilization and early embryonic development using the pig as a model. We examined the staining patterns of SYBR-14 and another vital stain, Hoechst 33342, both in combination with the dead cell stain, propidium iodide (PI), to quantify the proportion of living and dead spermatozoa in ejaculated and epididymal semen. Flow cytometry analyses of semen from 4 boars revealed significant differences among boars for the proportion of SYBR-14-stained spermatozoa in both epididymal and ejaculated samples, but not for Hoechst 33342 or PI stained spermatozoa. Gilts were inseminated with unstained spermatozoa or spermatozoa stained with 2 levels of SYBR-14 or 2 levels of the reference stain, Hoechst 33342. Embryos recovered at 42 to 48 h postinsemination were morphologically evaluated, and only 4 to 8-cell embryos were continued in culture. Overall, fluorescent staining of boar spermatozoa with SYBR-14 or Hoechst 33342 neither affected their ability to fertilize oocytes, nor the developmental competence of the resultant embryos.     

哺乳动物精子质量的评价方法

精子的各种功能状态反应了精子的受精能力。检测精子质膜完整性的荧光探针有SYBR－14,SYTO－17,CFDA、CDMFDA、CAM、PI、Hoechst33258、Hoechst33342,其中以SYBR－14结合PI使用效果最好,检测线粒体活性的荧光探针有JC－1、MITO、Rh123,JC-1比MITO和Rh123更适用于检测精子线粒体功能,检测顶体状态的荧光探针有PNA－FITC、PSA－FITC、LYSO－G及CTC等。检测获能状态的荧光探针有CTC。此外,还可以通过检测精子与透明带的结合能力、精子穿入去透明带卵子的能力以及使卵子受精的能力和其后胚胎的发育能力等方面来评价精子的功能状态。     

Effect of staining and sorting on boar sperm membrane integrity, mitochondrial activity and in vitro blastocyst development

The objective of this study was to determine the effects of staining with Hoechst 33342 and of the entire sorting procedure on boar sperm membrane integrity (using Annexin-V/PI), mitochondrial activity (using JC-1/SYBR/PI) and blastocyst development in vitro; the effect of storage at 17 degrees C for 24h prior to Hoechst staining and sorting was also investigated. The Hoechst staining and the whole sorting procedure reduced the percent of live spermatozoa in both fresh (day 0) and stored (day 1) semen, as determined by both assays; nevertheless, there was no increase in live sperm cells showing signs of early damage (Annexin-V positive, propidium negative), whose percentages remained nearly zero. The majority of Annexin-V positive cells were propidium positive, therefore dead. JC-1 staining evidenced a correlation between mitochondrial activity and viability. However, a significant difference between viable sperm cells and sperm cells with active mitochondria was detected in control and stained sperm, whereas almost all viable sorted spermatozoa had active mitochondria. No significant differences in the in vitro produced blastocysts both on day 0 and 1 were observed. In conclusion, despite the damages induced by sorting procedures, semen sorted as fresh or after storage at 17 degrees C can be successfully used for in vitro production of pig embryos.     

The initial fertilizing capacity of longerm-stored liquid boar semen following pre- and postovulatory insemination

In pigs, high variation is seen in the duration of estrus and in the time of ovulation. This is one of a wide range of factors not related to semen quality, which possibly influences the results of field insemination trials. Experiment 1 (n=81 gilts) was performed to determine the influence of the time of ovulation on the fertilizing capacity of liquid boar semen stored up to 118 h. The objective of Experiment 2 (n=102 gilts) was to study the fertilizing potential of semen stored up to 120 h in 2 different extenders, Androhep and Beltsville Thawing Solution (BTS), by means of postovulatory AI. Inseminations were performed 0 to 4 h after ovulation in order to standardize the trial conditions. Fertilization rates based on Day-2 to Day-4 embryos, and the number of accessory spermatozoa per zona pellucida did not differ between semen stored for 0 to 48 and 48 to 87 h in gilts ovulating within 12 after insemination (Experiment 1). Gilts with an interval of 12 to 24 h between AI and ovulation had lower fertility results using semen stored for more than 48 h. A further decrease was observed when semen storage exceeded 87 h in those gilts ovulating later than 24 h after insemination. The time of ovulation has to be considered as being a major factor of variation in the fertility results of AI trials. In Experiment 2, fertilization rates and numbers of accessory spermatozoa decreased between semen stored for 0 to 24 and 24 to 48 h in BTS, and between semen stored for 0 to 24 and 48 to 72 h in Androhep. Significant differences in fertility between diluents were seen only when using semen stored for more than 96 h, with semen extended with Androhep giving the higher results. The results indicate that the decrease in fertilizing capacity due to in vitro aging of spermatozoa cannot be prevented even during the first days of storage.     

Liquid storage of miniature boar semen.

The effects of liquid storage at 15 degrees C on the fertilizing ability of miniature pig semen were investigated. Characterization of ejaculated semen from 3 miniature boars was carried out. Semen volume and pH were similar among these boars. In one of the boars, sperm motility was slightly low, and sperm concentration and total number of sperm were significantly lower than in the others (P < 0.01). Seminal plasma of the semen was substituted with various extenders (Kiev, Androhep, BTS and Modena) by centrifugation and semen was stored for 7 days at 15 degrees C. Sperm motility was estimated daily at 37 degrees C. For complete substitution of seminal plasma, Modena was significantly more efficient than the other extenders (P < 0.001) in retaining sperm motility. Semen from each of the 3 miniature boars that had been stored for 5 to 7 days at 15 degrees C in Modena was used for artificial insemination of 15 miniature sows. The farrowing rates were 100, 100 and 60%, and litter sizes were 6.4 +/- 1.5, 5.8 +/- 0.8 and 5.0 +/- 1.0 for each boar semen, respectively. The boar that sired the smallest farrowing rate was the same one that showed lower seminal quality with respect to sperm motility, sperm concentration and total number of sperm. These results suggest that miniature boar semen can be stored for at least 5 days at 15 degrees C by the substitution of seminal plasma with Modena extender.     

The effect of melatonin on the quality of extended boar semen after long-term storage at 17 °C

Melatonin (MLT) is an efficient antioxidant that protects cells and tissues and initiates a host of receptor-mediated effects. In order to enhance the life span of refrigerated boar semen, our aim was to evaluate the effects of addition of 1 μM MLT to commercially produced pig semen (33 seminal doses from 14 boars) that had been preserved at 17 °C for 7 days. Samples without MLT served as controls. On Days 1, 4 and 7, we evaluated motility parameters and the percentage of total motile and progressively motile spermatozoa by a computer-aided sperm analysis system. Viability (SYBR-14/PI), acrosomal status (FITC-PNA/PI), membrane fluidity (M-540/YoPro-1) and mitochondrial membrane potential status (JC-1) were evaluated by flow cytometry. MLT treatment significantly enhanced the percentage of static spermatozoa after 7 days of storage and significantly reduced the percentage of progressively motile spermatozoa on Day 7. The velocity characteristics (VCL, VSL and VAP) were significantly higher for MLT-treated samples on Day 1 and were their lowest on Day 7. With regard to flow cytometry results, the percentage of viable spermatozoa with an intact acrosome was higher in MLT samples throughout the entire storage period. In addition, there was a significantly higher proportion of live spermatozoa on Day 7 in the samples that had not been treated with MLT. The proportion of spermatozoa showing a high mitochondrial membrane potential remained at similar levels (P > 0.05) throughout the trial. Although the findings of the present study revealed that 1 μM MLT increased the proportion of live sperm with an intact acrosome, this treatment did not enhance the spermatic quality of refrigerated boar semen.     

Identification of capacitation in boar spermatozoa by chlortetracycline staining

The functional status of boar spermatozoa undergoing capacitation in vitro was investigated. Two fluorescent stains were used: chlortetracycline (CTC) and a FITC-conjugated lectin (FITC-PSA). The first has been used for the direct identification of the capacitated boar spermatozoa, while the second, based on the identification of capacitated spermatozoa by their ability to undergo zona-induced acrosome reaction (AR), was used to confirm and validate the CTC assay in this species. Spermatozoa obtained from 5 different boars was washed and incubated under capacitating conditions. Aliquots of spermatozoa were collected at 0, 90 and 180 min of incubation and then stained with CTC or FITC-PSA. After CTC staining, 3 different fluorescent patterns were observed: Pattern A with the fluorescence uniformly distributed on the sperm head, Pattern B with the fluorescence concentrated in the post-acrosomial region, and Pattern C with the fluorescence concentrated in the acrosomial region. The percentage of spermatozoa displaying fluorescent Pattern A decreased throughout the incubation while that of spermatozoa with Pattern C showed a concomitant progressive increase. Pattern B fluorescence remained unchanged throughout the maturation period. Exposure to zonae pellucidae (ZP) brought back the levels of Pattern C fluorescence to basal values. Since only the capacitated spermatozoa are believed to react to ZP, this observation together with the rising incidence of Pattern C throughout maturation suggests that fluorescence in the acrosomial region identifies capacitated spermatozoa. The analysis of acrosome integrity carried out with FITC-PSA showed that the proportion of zona-induced AR was nearly the same as that of spermatozoa displaying Pattern C, thus confirming that CTC staining is suitable for the detection of boar sperm capacitation. In the second part of this study, CTC was used to investigate the effects of sperm origin and storage on the capacitation process. Our finding demonstrates that capacitation kinetics show wide variations in sperm samples derived from different boars; moreover, capacitation is also affected by sperm storage. While fresh semen showed a progressive increase in capacitated spermatozoa, ranging from low levels at the beginning of the culture to 46% at the end of incubation, the refrigerated semen had a relatively high percentage of capacitated spermatozoa at the beginning of culture, but this proportion increased only slightly during the following 90 to 180 min of treatment. These data indicate that CTC can be used to identify capacitated boar spermatozoa, and, because of its rapid and easy execution, it can be used routinely to identify the optimal capacitation time for different sperm samples.     

The fecundity of porcine semen stored for 2 to 6 days in Androhep and X-CELL extenders

Extending the raw ejaculate prior to artificial insemination (AI) is beneficial, in part, due to the increased number of females that are bred from an ejaculate, along with prolonged shelf life of the semen. The objective of this study was to examine the affects of storage time on the fecundity of porcine semen diluted in 2 semen extenders, Androhep and X-CELL. A completely randomized design with a factorial arrangement of treatments was utilized in which 429 high quality, gel-free ejaculates from 48 boars were used in a timed, double insemination of 1,431 first-service gilts. The gilts were divided into groups and inseminated with semen stored in Androhep or X-CELL for 2 to 3 d, 3 to 4 d, 4 to 5 d, or 5 to 6 d prior to use (day of collection = Day 0). Sperm age was identical, and both extenders were used concurrently each day of the trial. Farrowing rate and litter size data were recorded. Farrowing rates did not differ between extenders through Days 4 to 5 of storage. Gilts inseminated with Androhep diluted stored semen showed a decrease (P < 0.001) in farrowing rate compared with those inseminated with semen extended in X-CELL stored for 5 to 6 d. Mean litter sizes did not differ between extenders through Days 2 to 3 of storage. Compared with the X-CELL extended semen, gilts inseminated with Androhep extended semen produced smaller litters when semen was stored for 4 to 5 d (P < 0.05). Within the Androhep treatment, smaller mean litter sizes (P < 0.05) were evident when the semen was stored for 3 to 4 and 4 to 5 d. No differences were detected in litter size or farrowing rate for gilts bred with semen stored for 2 to 6 d in the X-CELL extender (P > 0.1). The results of this study indicate that extender type influences the fertility potential of fresh porcine semen stored for 2 to 6 d. For optimal fecundity in gilts, semen extended with Androhep extender should be used for AI within 3 d. The X-CELL extended semen can be used for up to 6 d without significant decrease in litter size or farrowing rate. These recommendations are dependent upon using high quality semen that is properly handled from collection through insemination.     

Permeability of boar and bull spermatozoa to the nucleic acid stains propidium iodide or Hoechst 33258, or to eosin: accuracy in the assessment of cell viability

This study was designed to assess whether nucleic acid stains such as propidium iodide and Hoechst 33258 and the cytosolic stain eosin identified equivalent proportions of non-viable cells. Sub-samples of boar spermatozoa stored for up to 72 h, and frozen bull spermatozoa stored in straws and thawed before staining, were exposed to either propidium iodide or Hoechst 33258 alone or in combination. Additional sub-samples were stained with eosin-nigrosin and subsequently with Giemsa. The proportion of non-viable cells identified by propidium iodide alone was equivalent to that observed when it was used in combination with the other fluorescent probe. Similar results were observed for Hoechst 33258. However, direct microscopic examination of sub-samples exposed to both stains revealed that a proportion of spermatozoa stained with propidium iodide did not incorporate Hoechst 33258. This was found consistently in boar and bull spermatozoa under the different experimental conditions used. Quantification showed that the proportion of propidium iodide-positive cells was significantly higher than Hoechst 33258-positive cells. Furthermore, the proportion of propidium iodide-positive cells was higher than cells stained with eosin, but no differences were found between the number of cells stained with Hoechst 33258 or eosin. The proportion of cells stained with propidium iodide was positively correlated with the proportion stained with either Hoechst 33258 or eosin, despite the observation that more cells incorporated propidium iodide. Taken together, these results indicate that there are differences in the ability of fluorescent probes to identify non-viable sperm cells and that this should be considered when staining protocols are used to analyse sperm viability, or when viability is used as a discriminating factor in functional studies, such as those related to acrosomal exocytosis.     

Arylsulfatases are present in seminal plasma of several domestic mammals.

Mammalian spermatozoa and seminal plasma both contain high levels of arylsulfatases (AS), enzymes that remove sulfate from sulfated glycoconjugates. In ejaculated semen of boars, 85% of AS was found in seminal plasma whereas only 13% was found in spermatozoa. A comparable distribution of AS between spermatozoa and seminal plasma was observed in other domestic mammals. The presence of AS in seminal plasma was not due to leakage from spermatozoa because sperm cells had intact acrosomes and plasma membranes after their separation from seminal plasma, and because 84% of the acrosomal marker enzyme hyaluronidase was retained in washed spermatozoa. Spermatozoa in boar semen diluted with Beltsville Thawing Solution (BTS) deteriorated faster during storage at 17 degrees C than spermatozoa stored in BTS without seminal plasma. This suggests that seminal plasma has a deleterious effect on mammalian spermatozoa. We propose that (1) sulfated glycoconjugates stabilize sperm plasma membranes; (2) AS present in seminal plasma contribute to the deterioration of spermatozoa by desulfating these glycoconjugates; and (3) AS present in seminal plasma could well play a role in sperm capacitation.     

Evaluation of swine fertilisation medium (SFM) efficiency in preserving spermatozoa quality during long-term storage in comparison to four commercial swine extenders

In pig production, artificial insemination is widely carried out and the use of fresh diluted semen is predominant. For this reason, there are increasing interests in developing new extenders and in establishing the optimal storage conditions for diluted spermatozoa. In the last few decades, we utilised a homemade diluent (swine fertilisation medium (SFM)) for spermatozoa manipulation and biotechnological application as the production of transgenic pigs utilising the sperm-mediated gene transfer technique. The purpose of the present study is therefore to analyse the ability of SFM, in comparison to four commercial extenders, in preserving the quality of diluted boar semen stored at 16.5°C till 15 days. We utilised some of the main predictive tests as objectively measured motility, acrosome and sperm membrane integrity, high mitochondrial membrane potential and pH. Based on our in vitro study, SFM could be declared as a good long-term extender, able to preserve spermatozoa quality as well as Androhep Enduraguard for up to 6 to 9 days and more.     

Characterization of lower temperature storage limitations of fresh-extended porcine semen

Irreversible damage caused by cold shock has been assumed to occur when boar semen is exposed to temperatures below 15 degrees C. Identification of the lower critical temperature at which extended boar semen undergoes cold shock, however, has yet to be defined. The aims of this study were to 1) identify the cold-shock critical temperature and time on extended boar semen as assessed by sperm motility and morphology, and 2) determine the effects on fertility of using extended porcine semen exposed to this critical temperature and time. For Objective 1, ejaculates from 18 boars were collected, analyzed and extended in Androhep to 50 x 10(6) sperm/mL. Doses (4 x 10(9) sperm) from each ejaculate were exposed to 5 storage temperatures (8, 10, 12, 14 and 17 degrees C). Sperm motility and morphology (including acrosomes) were assessed following collection and at 12-h intervals for 48-h. Decreases in sperm motility occurred within the first 12-h at all temperatures. Sample motility dropped below 70% within 12-h in the 8 degrees C group and by 48-h in the 10 degrees C group. Sample motility was > 75% in the 12, 14 and 17 degrees C (control) groups throughout the trial. The percentage of morphologically abnormal sperm cells, including acrosomes, did not change within or between treatment groups over the 48-h storage period. In Objective 2, boar ejaculates (n = 9) were handled as in the first objective and were equally divided into treated (12 degrees C for < or = 60-h) and control (17 degrees C for < or = 60-h) groups. Using a timed, double insemination technique, 135 sows were bred by AI using either 12 degrees C (n = 74) or 17 degrees C (n = 61) extended, stored semen. No differences were observed in the farrowing rate (93 vs 95%), total offspring born (11.58 vs 11.61) or number live born (10.68 vs 10.63) between 12 and 17 degrees C groups, respectively. The results demonstrate that acceptable fertility can be obtained with Androhep extended boar semen exposed to temperatures as low as 12 degrees C for up to 60-h, and that cold shock appears to occur in vitro when extended boar semen is exposed to storage temperatures below 12 degrees C.     

Chlortetracycline analysis of boar spermatozoa after incubation,flow cytometric sorting,cooling, or cryopreservation

In this study, the effects of staining procedure with chlortetracycline (CTC) and method of analysis of boar spermatozoa after staining were examined. The hypothesis that incubation, flow cytometric sorting, cooling, and cryopreservation cause changes to boar sperm membranes which resemble capacitation and the acrosome reaction was also tested. Membrane status was evaluated by flow cytometry and by fluorescence microscopy after staining with CTC, and acrosome integrity was checked by flow cytometry after staining with FITC-pisum sativum agglutenin and propidium iodide (PI). Flow cytometry was also used to assess viability (percentages of live and dead cells) of boar sperm after staining with SYBR-14 and PI. Staining of spermatozoa with CTC alone and in combination with PI and/or Hoechst 33342 had no effect on the proportion of spermatozoa allocated to the F (uncapacitated), B (capacitated), or AR (acrosome-reacted) CTC fluorescent staining categories. The mean percentages of acrosome-intact and acrosome-reacted cells were 88.4 and 6.8 or 0.8 and 96.5 in semen treated with 0 or 100 μg/ml lysophosphatidylchloine (LPC), respectively (P < 0.001). Most spermatozoa were also in the AR CTC-stained category after treatment with LPC compared with a small proportion in the controls. Using flow cytometry to examine sperm suspensions stained with CTC, a gated population of spermatozoa with low fluorescence (population 1) comprised predominantly F-pattern cells (F-pattern: population 1 vs. population 2, 80.5 vs. 14.4%; P < 0.001), whereas population 2 (high fluorescence) comprised mainly B-pattern cells (B-pattern: population 1 vs. population 2, 8.5 vs. 62.3%; P < 0.001). Incubation (38°C, 4 hr), flow sorting, cooling (to 15 or 5°C) and freezing reduced the proportion of F-pattern and live spermatozoa, and increased the proportion of B-, AR-pattern, and dead spermatozoa, in comparison with fresh semen. There were more membrane changes in spermatozoa cooled to 5°C (30.4, 48.5, 21.1%) than in those cooled to 15°C (56.1, 32.6, 11.5% F-, B-, and AR-pattern spermatozoa, respectively). Mol. Reprod. Dev. 46:408–418, 1997. © 1997 Wiley-Liss, Inc.     

Effect of sex sorting on CTC staining, actin cytoskeleton and tyrosine phosphorylation in bull and boar spermatozoa

Sperm sorting is a useful technology that permits sex preselection. It presents some troubles because of low fertility after the process. The main aim of this work was to analyze the putative existence of capacitation-like changes in both boar and bull sperm subjected to sex sorting that could lead to a detriment of semen quality. The parameters used were CTC staining patterns, actin cytoskeleton organization and tyrosine phosphorylation patterns; the last two were determined by both western blotting and immunofluorescence. Sex sorted spermatozoa were compared with fresh, in vitro capacitated and in vitro acrosome reacted sperm. In both species, sex sorted sperm showed a CTC staining pattern similar to that observed after in vitro capacitation. The actin pattern distribution after sperm sorting also tended to be similar to that observed after in vitro capacitation, but this effect was more pronounced in bull than in boar spermatozoa. However, actin expression analysis through western blot did not show any change in either species. The tyrosine phosphorylation pattern in boar sperm was practically unaltered after the sex sorting process, but in bulls about 40% of spermatozoa had a staining pattern indicative of capacitation. Additionally, western blotting analysis evidenced some differences in the expression of protein tyrosine phosphorylation among fresh, capacitated, acrosome reacted and sex sorted sperm cells in both species. Our results indicate that not all the sex-sorted-related modifications of the studied parameters were similar to those occurring after “in vitro” capacitation, thus suggesting that sex sorting-induced alterations of sperm function and structure do not necessarily indicate the achievement of the capacitated status of sorted sperm.     

Use of chromatin stability assay, mitochondrial stain JC-1, and fluorometric assessment of plasma membrane to evaluate frozen-thawed ram semen

Cryopreservation of semen imposes deleterious effects on spermatozoa, either killing a certain proportion of cells or causing subtle damages on sperm function in the surviving population, changes not easily revealed by conventional assays. We have tested three functional assessment techniques in frozen-thawed ram semen from six adult rams, cryopreserved following eight different protocols (four extenders, and glycerol being added at two temperatures). Semen samples were thawed and the following analyses were carried out: motility (CASA), membrane integrity (Hoescht 33258 and fluorometry), chromatin status (chromatin stability test and fluorescence-assisted cell sorting, FACS) and mitochondrial activity (JC-1 and FACS). Fluorometry outcome did not correlate with the other parameters and showed large variation, albeit discriminating among cryopreservation techniques (P < 0.01). Mitochondrial activity correlated, but with low values, with total and progressive motility. However, good sperm motility and high velocity values were associated to high mitochondrial membrane potential. The chromatin stability assay was also successfully carried out, and had a good relationship with male factor (%COMP alpha(t) and SD alpha(t) parameters). In conclusion, fluorometric assessment of membrane integrity albeit rendering poor results, merits improvement, being a low-cost and handy technique, especially for work in the field. On the other hand, both assessments of chromatin stability and mitochondrial status (JC-1 staining), combined with FACS, are reliable techniques that can be used for the functional assessment of frozen-thawed ram semen.     

Effect of different extenders and storage temperatures on sperm viability of liquid ram semen

Semen was collected with an artificial vagina from four adult rams. The ejaculates were pooled and diluted, using a split-sample technique, in four different extenders: one for milk (Mi), one for sodium citrate (Na), and two for Tris-based extenders (T1 and T2) including egg yolk. Thereafter, the diluted semen was stored at 5 and 20 degrees C, respectively. We evaluated sperm viability after 0, 6, 12, 24 and 30 h of storage. We assessed sperm motility subjectively, and we determined sperm membrane integrity using both the hypo-osmotic resistance test (ORT) and a fluorophore staining (SYBR-14 and propidium iodide) technique. We evaluated acrosomal status with Spermac and capacitation status with Chlortetracycline (CTC assay). All sperm viability parameters were influenced by storage time and extender, while sperm motility was the only evaluated parameter that was influenced by the interaction between extender and temperature. Semen that was diluted and stored in the commercially available Tris-based extender (T2) maintained sperm motility for a longer period of time, and acrosome and membrane integrity was higher during storage for up to 30 h as compared to the other extenders independent of storage temperature. In general, however, storage of ram semen at 5 degrees C seemed to influence sperm viability parameters less than storage at 20 degrees C. In conclusion, the results of the present study indicate that Tris-based extenders, especially T2, preserved sperm viability better than both the sodium citrate- and the milk-based extender did when liquid ram semen was stored up to 30 h at 5 and 20 degrees C. Whether the differences found between the extenders will be reflected in the fertility results after AI is yet unknown and needs to be further studied.     

Use of triple stain technique for simultaneous assessment of vitality and acrosomal status in boar spermatozoa

The object of this study was to adapt the triple stain technique to diluted and incubated boar spermatozoa. Freshly ejaculated semen was resuspended in MR-A diluent to contain 3x10(7) cells/ml (diluted spermatozoa) and was subsequently capacitated (incubated spermatozoa). Experiments were conducted to show the conditions required for optimal staining quality and validation of triple stain technique. The most satisfactory staining solutions for diluted spermatozoa were 2% Trypan blue at 37 degrees C for 15 minutes, 0.8% Bismarck brown in 30% ethyl alcohol (pH 2.8) at 40 degrees C for 10 minutes and 0.8% rose Bengal in 0.1 M of Tris (pH 4.3) at 21 degrees C for 20 minutes. Satisfactory results were obtained for incubated spermatozoa with rose Bengal when the staining time was 10 minutes. Triple stain technique seemed to be a useful method for the simultaneous assessment of sperm vitality and acrosomal status; consequently, it should be valuable tool, for use in porcine in vitro fertilization systems.     

Determination of acrosin activity of boar spermatozoa by the clinical method: optimization of the assay and changes during short-term storage of semen

A clinical assay to evaluate total acrosin activity developed for human semen has been optimized for use in boar spermatozoa. The main modifications included a decrease of sperm number per assay from 1.0 to 10.0 x 10(6) to 12.5 to 75.0 x 10(3) spermatozoa, and the time of incubation from 180 to 60 min. Linearity of response for differing quantities of spermatozoa was maintained. Extensive washing of spermatozoa was necessary to eliminate seminal plasma, the source of acrosin inhibitors. Seminal plasma that was diluted 1000 times inhibited acrosin activity by about 50%. To abolish the inhibitory effect of seminal plasma it was necessary to use 25,000-fold dilution. Total acrosin activity of boar spermatozoa was about 100 times higher than that of human spermatozoa. Acrosin activity of boar spermatozoa in extended semen decreased during 7 d of storage. These results indicate that the clinical assay of acrosin activity can be used for boar spermatozoa to evaluate the quality of boar semen.     

Effects of in vitro storage time and semen-extender on membrane quality of boar sperm assessed by flow cytometry

The Norwegian AI company Norsvin has used the short-term semen-extender BTS to extend and store boar semen since the late 1980s. Fertility results have been consistent when extended semen has been used for AI within 3 days after collection, however, from a production and economic point of view it is preferable that semen stored for up to 5 days can be used. The aim of this study was to compare membrane quality of sperm stored in BTS for 3 days with sperm stored in the long-term semen-extenders Androstar, Mulberry III and X-cell for 5 days. Using a split-sample design, plasma membrane- and acrosome-integrity were assessed flow cytometrically by use of Yo-Pro-1 and PNA-FITC, and fluidity and phospholipid asymmetry of the membrane were assessed by use of MC540 and Annexin V-FITC. Due to observed sperm fragmentation in Androstar after Day 1, the data for Androstar were excluded from the analyses. After 5 days of storage, the membrane quality of X-cell-stored sperm was not statistically different from that of sperm stored in BTS for 3 days, while membrane quality of sperm stored in Mulberry III was statistically better on Day 5 compared to BTS on Day 3. In conclusion, Mulberry III and X-cell preserve sperm quality, as well as that of BTS on Day 3, for up to 5 days after collection.