Preimplantation genetic diagnosis in Welsh pony embryos after biopsy and cryopreservation.

Preimplantation genetic diagnosis and embryo cryopreservation are important tools to improve genetic management in equine species with marked consequences on the economic value, health, biodiversity, and preservation of the animals. This study aimed to develop a biopsy method at the blastocyst stage that provides viable genotyped cryopreserved Welsh pony embryos. Embryos were collected at d 6.75 to 7 after ovulation. Biopsies were performed with either a microblade or a micropipette. After biopsy, embryos were cryopreserved. The survival rate of biopsied embryos was evaluated on fresh and cryopreserved embryos either 24 h after in vitro culture or after transfer to recipients. Fresh and nonbiopsied embryos were used as controls. Sex, coat color genes, myotony (neuromuscular disorder) diagnosis, and markers of parentage were investigated using PCR on biopsied cells after whole-genome amplification and on remaining embryos. The embryo survival rate after transfer was not affected by the micropipette biopsy (50%, = 8; 43%, = 7; and 50%, = 12, at d 30 for fresh biopsied embryos, vitrified biopsied embryos, and control embryos, respectively) but was significantly reduced by the use of microblade biopsy: 9 ( = 11) vs. 67% ( = 12) for control embryos. Successful sex determination was achieved for 82% ( = 28) of the micropipette biopsies and 100% ( = 50) of the microblade biopsies. Sex determined on biopsied cells was found to correspond completely (100%) with that determined on the remaining embryo ( = 37). More than 90% of the parentage checking markers, coat color, and myotony diagnosis were successfully determined on biopsies obtained with either a micropipette or a microblade. Mendelian incompatibility (7.5 and 5.5%) and embryo genotyping errors (6.6 and 8.6%) were low and not significantly different between the 2 methods. In conclusion, for the first time, pregnancy at Day 30 was obtained after transfer of Welsh pony biopsied and vitrified embryos >300 µm in diameter to recipient pony mares. The biopsied cells collected enabled multigenetic embryo diagnoses to be performed to a high degree of accuracy. The micropipette biopsy is the better method to apply on Welsh pony embryos.

Removal of seminal plasma enhances membrane stability on fresh and cooled stallion spermatozoa.

Fertility is reduced after semen cooling for a considerable number of stallions. The main hypotheses include alterations in plasma membrane following cooling and deleterious influence of seminal plasma. However, interindividual variability is controversial. We hypothesized that the removal of seminal plasma could enhance motility in some 'poor cooler' stallions, but could also affect, negatively or positively, membrane quality in some stallions. This study examined the effect of centrifugation, followed or not by removal of seminal plasma, on parameters indicating semen quality after 48 h at 4 °C: motility, plasma membrane integrity as evaluated by hypo-osmotic swelling test, acrosome integrity and response to a pharmacological induction of acrosome reaction using ionophore A23187. Sixty-six ejaculates from 14 stallions were used, including stallions showing high or low sperm motility after cooled storage. Centrifugation without removal of seminal plasma did not affect sperm parameters. Removal of seminal plasma did not affect motility, but significantly stabilized sperm membranes, as demonstrated by a higher response to the osmotic challenge, and a reduced reactivity of the acrosome. Moreover, for the same semen sample, the response to an induction of acrosome reaction was significantly higher when the induction was performed in the presence of seminal plasma, compared with the induction in the absence of seminal plasma. This was observed both for fresh and cooled semen. When the induction of acrosome reaction with ionophore A23187 is used to evaluate sperm quality, care must therefore be taken to standardize the proportion of seminal plasma between samples. For the 10 stallions serving at least 25 mares, the only variable significantly correlated with fertility was motility. The influence of membrane stabilization regarding fertility requires further investigations.

French field results (1985-2005) on factors affecting fertility of frozen stallion semen.

Results on procedures for freezing stallion semen and the subsequent fertility during 20 years are presented. The present system applied in French National Stud includes: (1) a freezing protocol (dilution in milk, centrifugation and addition of freezing extender (INRA82+egg yolk (2%, v/v)+glycerol (2.5%, v/v) at 22 degrees C, a moderate cooling rate to 4 degrees C and freezing at -60 degrees C/min in 0.5-ml straws); (2) selection of ejaculates showing post-thaw rapid motility >35%; and (3) an insemination protocol (mares examined once daily, two AI of 400 x 10(6) spermatozoa 24 h apart before ovulation, sufficient number of straws to have the possibility to perform six AI of 400 x 10(6) total spermatozoa, i.e. 2.4 x 10(9) total spermatozoa available per mare per season). This system was applied to >110 stallions per year, the average post-thaw motility of ejaculates was 50% (>1800 ejaculates) before selection. The semen freezability was defined as the number of selected ejaculates divided by the total number of ejaculates frozen. Of the stallions, 5, 4, 5, 21 and 64% had semen freezability of 0-10, 10-33, 33-60, 60-90 and over 90%, respectively. Per-cycle pregnancy rate was 45-48% (>1500 mares per year, 1.8 cycles per mare) and foaling rate 64%. In comparison, per-cycle pregnancy rate and foaling rate of mares hand-mated to stallions were 57-59% and 64%, respectively. The average number of straws used was 32-35 (1.75 x 10(9) total spermatozoa) per mare per season. According to our results and the literature, the most important factors for improving fertility of frozen equine semen include: (1) a low concentration of glycerol (2-3.5% final concentration); (2) a suitable base extender for freezing like Lactose-Glucose EDTA or INRA82; (3) a post-thaw motility >30-35%; and (4) a sufficient number of spermatozoa per mare per season (1.5-2 x 10(9) total spermatozoa for two to three cycles) divided into small units. Numbers of spermatozoa, lower than 750.10(6) total spermatozoa per cycle, could result in lower per-cycle pregnancy rate with higher additional costs for management of mares. Because there are no particular regulations on quality and quantity of equine semen in the European Community, there is a need for the uniformity of information about frozen semen. A codification is suggested, based on the number of spermatozoa available per mare per season, the post-thaw motility and the final glycerol concentration.

In vitro comparisons of two cryopreservation techniques for equine embryos: slow-cooling and open pulled straw (OPS) vitrification.

Vitrification using open pulled straw (OPS) has provided encouraging results with embryos from other species. The aim of this study was to compare the survival of 6.5- and 6.75-day-old equine embryos after OPS vitrification and slow-cooling. Eighteen embryos were frozen using a slow-cooling method. Embryos were placed in modified PBS with increasing glycerol concentration (2.5%, 5%, 7.5% and 10% (v/v) 5 min each). Embryos were loaded into 0.25 ml straws then placed in a programmable freezer and subsequently plunged into liquid nitrogen. After thawing, cryoprotectant was removed by five steps with decreasing glycerol and sucrose concentrations. Twenty embryos were vitrified using the OPS method. Embryos were exposed to 7.5% dimethyl-sulfoxide (DMSO)+7.5% ethylene glycol (EG) for 3 min and in 18% DMSO+18% EG+0.4M sucrose for 1 min, loaded in OPS and plunged into liquid nitrogen. After warming, embryos were placed in decreasing sucrose concentrations. All embryos were cultured in synthetic oviduct fluid (SOF) medium for 3h and evaluated using 4',6-diamidino-2-phenylindole (DAPI) staining. The percentage of cells entering in S-phase (%SC) was evaluated by incorporation of BrdU. No significant differences were observed for mean diameter, morphological grade and percentage of degenerate embryos after 3h of culture for slow-cooling and OPS methods. The percentage of dead cells per embryo was similar for the two procedures (42+/-6 versus 46+/-9). The percentage of cells entering in S-phase did not differ significantly between the two procedures (27+/-5 versus 26+/-6). OPS vitrification may be as efficient as slow-cooling for the cryopreservation of equine embryos. However, these results should be confirmed by the transfer of OPS vitrified embryos to recipient mares.

Comparison of cell proliferation index in equine and caprine embryos using a modified BrdU incorporation assay.

The measurement of cell proliferation and cell viability using 5'bromo-2'deoxy-uridine (BrdU) labelling has been described in several cell types and species. The aim of this study was to adapt this technique to equine embryos and to compare the index of DNA replication (S-phase) between equine and caprine embryos. Seventeen equine embryos were recovered at day 6.5 post-ovulation and 20 caprine embryos were recovered at day 7 after the onset of estrus. Equine embryos were incubated during 1h at 39 degrees C in PBS containing 1mM of BrdU. Embryos were then treated in 0.05% trypsin during 15 min at 39 degrees C to permeabilise the capsule, and then embryos were rinsed in PBS containing 10% of foetal calf serum. After washing, embryos were immediately fixed in 2.5% paraformaldehyde with 0.3M NaOH during 15 min at ambient temperature. The S-phase was detected by immunocytochemistry technique. In caprine embryos, BrdU was visualised by the same technique but without the trypsin treatment. The percentage of cells (+/-S.E.M.) with BrdU incorporated into newly synthesised DNA strands was significantly higher in equine embryos (74+/-1) than in caprine (38+/-2). Our results demonstrated that BrdU incorporation assay can be used in equine embryos. This assay allows the determination of the proliferation index of live cells and could be used as an additional tool for evaluating the viability of embryos. The high percentage of cells incorporating BrdU during 1h of incubation with BrdU suggests that in comparison with the caprine embryos the cellular activity of proliferation is more intense in equine embryos and suggests that the cellular cycle is shorter in equine embryos.

Sexual behavior of stallions during in-hand natural service and semen collection: an observation in French studs.

The sexual behavior of 42 stallions from French national and private studs was examined in two contexts: semen collection for artificial insemination (AI) and in-hand natural service (NS). Each stallion was observed twice in the same context. Erection and ejaculation latencies, the number of mounts leading to ejaculation, dismount latency and total breeding time were measured and compared between AI and NS. Mount without erection was rare (6/83 observations). Erection latency was 89+/-11s, and was not different between NS (62+/-22s) and AI (100+/-13s, P=0.128). Stallions ejaculated after either one mount (62/83 observations), or two (11/83 observations) or three mounts (10/83 observations). Ejaculation latency was 85+/-15s (84+/-19 in AI and 86+/-28 in NS). If 1st mount did not lead to ejaculation, then ejaculation latency increased several fold following the 2nd mount during both AI and NS. The results provide reference measures for semen collection in French studs. Difference in erection latency between AI and NS, although not statistically significant, may reflect different contributions of excitatory inputs from the brain and the genital area to the activation of spinal networks controlling erection. In contrast, lack of difference in ejaculation latency between AI and NS suggests that the spinal network that controls ejaculation follows a more rigid motor pattern.

Advances in cooled semen technology.

In the horse industry, milk or milk-based extenders are used routinely for dilution and storage of semen cooled to 4-8 degrees C. Although artificial insemination (AI) with chilled and transported semen has been in use for several years, pregnancy rates are still low and variable related to variable semen quality of stallions. Over the years, a variety of extenders have been proposed for cooling, storage and transport of stallion semen. Fractionation of milk by microfiltration, ultrafiltration, diafiltration and freeze-drying techniques has allowed preparation of purified milk fractions in order to test them on stallion sperm survival. Finally, a high protective fraction, native phosphocaseinate (NPPC), was identified. A new extender, INRA96, based on modified Hanks' salts, supplemented with NPPC was then developed for use with cooled/stored semen. Four experiments were conducted to compare INRA96 and milk-based extenders under various conditions of storage. The diluted semen was maintained under aerobic conditions when stored at 15 degrees C, and anaerobic conditions when stored at 4 degrees C. In experiment 1, split ejaculates from 13 stallions were diluted either in INRA96 extender then stored at 15 degrees C or diluted in Kenney or INRA82 extenders and then stored at 4 degrees C for 24h, until insemination. In experiment 2, semen from two stallions was extended in INRA96 then inseminated immediately or stored at 15 degrees C for 3 days until insemination. In experiment 3, semen from three stallions was diluted in INRA96 then stored at 15 or 4 degrees C for 24h until insemination, finally, in experiment 4, split ejaculates from four stallions were diluted in INRA96 or E-Z Mixin extenders then stored at 4 degrees C for 24h until insemination. Experiment 1 demonstrated that at 15 degrees C, INRA96 extender significantly improved pregnancy rate per cycle compared to Kenney or INRA82 extenders at 4 degrees C after 24h of storage (57%, n=178 versus 40%, n=171, respectively; P<0.01). Experiment 2 showed that semen stored at 15 degrees C for 3 days can achieve pregnancy at a fertility rate per cycle of 48% (n=52) compared to 68% (n=50, immediate insemination, P=0.06). Experiment 3 demonstrated that INRA96 extender can be as efficient at 15 degrees C (54%, n=37) as at 4 degrees C (54%, n=35) after 24h of storage. Finally, experiment 4 showed that INRA96 extender used at 4 degrees C (59%, n=39) seems to improve fertility per cycle compared to E-Z Mixin at 4 degrees C (49%, n=39, P=0.25), but this result has to be confirmed. These results demonstrate that semen diluted in INRA96 extender and stored at 15 degrees C can be an alternative to semen diluted in milk-based extenders and stored at 4 degrees C for "poor cooler" stallions. Furthermore, INRA96 extender can be as efficient at 15 degrees C as at 4 degrees C, for preserving sperm motility and fertility.

Advances in cryopreservation of stallion semen in modified INRA82.

In the procedure used in this paper, semen was first diluted in INRA82+2% egg yolk (E1) at 37 degrees C. Before or after cooling to 4 degrees C, semen was centrifuged and diluted in E1+2.5% glycerol (E2). Cooled semen was frozen in 0.5-ml straws. Straws were thawed at 37 degrees C for 30s. For fertility trials, frozen ejaculates were used only if total post-thaw motility was above 35%. Most mares were inseminated two times before ovulation with 400 x 10(6) total spermatozoa every 24h. This paper presents post-thaw motility (CASA) and fertility results obtained when some steps of the procedure were evaluated. Use of the first three jets of ejaculate before the centrifugation did not improve post-thaw motility compared to use of the whole semen (25% versus 25%, 2 stallions x 12 ejaculates, P>0.80). When the first dilution was performed in E2 at 22 degrees C instead of in E1 at 37 degrees C, motility was slightly improved (38% versus 36%, n>283 ejaculates per group, P<0.04) but fertility was similar (51% versus 58%, n>196 cycles per group, P>0.10). Coating the spermatozoa with 0.5, 1, 2, 4 and 8mM of Concanavalin A resulted in unchanged post-thaw motility (6 stallions x 3 ejaculates, P>0.05). The extender E2 was modified or supplemented with different substances. Increasing egg yolk concentration from 2 to 4% (v/v) did not increase post-thaw motility (42% versus 34%, 6 stallions x 2 ejaculates, P>0.05). Different glycerol concentrations (range: 1.7-3.7%) had no significant effect on post-thaw motility even though 2.4-2.8% resulted in a nonsignificant higher motility (7 stallions x 2 ejaculates, P>0.05). Glutamine at 50mM in E2 improved post-thaw motility compared with no glutamine (49% versus 46%, n>584 ejaculates per group, P<0.0001) but not fertility (53% versus 54%, n>451 cycles per group, P>0.80). Thawing at 75 degrees C for 10s slightly increased motility after 120 min at 37 degrees C (6 stallions x 1 ejaculate, P<0.05) but no effect on per-cycle fertility was noted (32% (19 cycles) versus 41% (17 cycles), P>0.50). When post-thaw dilution was performed using a fixed molarity multi-step system (25 mOsm per step) from various osmolarities (900-690 mOsm) to 365 mOsm, motility was unaffected compared with dilution in one step (36% versus 38%, 6 stallions x 1 ejaculate, P>0.20).

Centrifugation and addition of glycerol at 22 degres C instead of 4 degrees C improve post-thaw motility and fertility of stallion spermatozoa.

The aims of this study were to evaluate the effects of cooling rate to 4 degrees C and temperature at the time of centrifugation/glycerol-addition (freezing extender: INRA82 + 2% egg yolk + 2.5% glycerol) on postcentrifugation recovery rate, post-thaw motility and per-cycle fertility. When centrifugation/glycerol-addition was performed at 4 degrees C (14 ejaculates), a moderate cooling rate (37 degrees C to 4 degrees C in I h) resulted in higher post-thaw motility (45%) than when using a slow cooling rate (37 degrees C to 4 degrees C in 4 h) (39%; P<0.05). When centrifugation/glycerol-addition was performed at 22 degrees C (37 degrees C to 22 degrees C in 10 min) (10 ejaculates), post-thaw motility was lower when spermatozoa were frozen directly from 22 degrees C (23%) than when spermatozoa were cooled to 4 degrees C (22 degrees C to 4 degrees C in 1 h) before freezing (47%; P<0.0001). When centrifugation/glycerol-addition was performed at 22 degrees C (before cooling at a moderate rate), as opposed to 4 degrees C (after cooling at a moderate rate), a significant improvement of 1) recovery of spermatozoa after centrifugation (P<0,0001), 2) post-thaw motility of spermatozoa at thawing (40% vs 36% (n < or = 291 ejaculates/group), P<0.0001) and 3) per-cycle fertility (56% vs 42% (n > or = 190 cycles/group), P<0.01) was observed. In conclusion, centrifugation/glycerol-addition at 22 degrees C followed by cooling to 4 degrees C at a moderate rate results in an improvement of post-thaw motility, spermatozoa recovery rate and per cycle fertility.

Freezing of stallion semen: interactions among cooling treatments, semen extenders and stallions.

In the present study, the interactions among stallions, semen extenders and cooling treatments before stallion semen samples were frozen were studied. In Expt 1, the effects of four cooling treatments and three semen extenders were investigated (11 stallions x four split ejaculates), whereas in Expt 2, the effects of two semen extenders, two egg yolk concentrations and two glycerol concentrations were investigated (six stallions x five split ejaculates). Sperm motility after thawing was evaluated. In Expt 1, the extender x cooling treatment interaction was significant. Centrifugation and addition of glycerol at 22 degrees C, followed by filling the straws at 4 degrees C and immediate freezing had detrimental effects in INRA82 + 2% (v/v) egg yolk + 2.5% (v/v) glycerol semen extender and in Gent semen extender compared with the same processes in Kenney + 4% (v/v) egg yolk + 3.6% (v/v) glycerol semen extender. The other cooling treatments, including moderate cooling of semen to 4 degrees C before freezing, resulted in higher sperm motility and had similar effects among treatments. Semen samples from some stallions appeared to withstand freezing more effectively after some cooling treatments than other treatments. Some stallion spermatozoa demonstrated higher motility in Kenney semen extender, whereas other semen samples had the same motility in all extenders. In Expt 2, the stallion x extender interaction was not significant. Increasing the glycerol concentrations from 2.5 to 3.5% (v/v) enhanced sperm motility in semen extenders containing 4% (v/v) egg yolk (INRA82 and Kenney). Increasing the egg yolk concentrations from 2 to 4% (v/v) in extenders containing 3.1-3.6% (v/v) glycerol improved sperm motility in Kenney semen extender only. These experiments demonstrate that there are possible differences in the ability of spermatozoa from different stallions to withstand different cooling treatments, but not necessarily in their tolerance to different semen extenders.

Effects of glutamine, proline, histidine and betaine on post-thaw motility of stallion spermatozoa.

The supplementation of the freezing diluent with 3 amino acids (glutamine, proline and histidine) and 1 amino acid-related compound (betaine) in preserving stallion spermatozoa diluted in INRA82 extender containing 2.5% (v/v) glycerol and 2% (v/v) egg yolk (control extender) during freezing and thawing was studied at 0, 40, 80, 120 and 160 mM in 20 split ejaculates (10 stallions x 2 ejaculates; Experiment 1). Glutamine and proline were studied at 0, 10, 20, 30, 40, 50, 60, 70 and 80 mM in 20 split ejaculates (10 stallions x 2 ejaculates; Experiment 2). In each experiment, spermatozoa were evaluated after thawing by computer automated sperm analyzer. The percentage of motile spermatozoa (faster than 30 microns/sec) was assessed. In addition, the velocity of the average path (VAP), the straight line velocity (VSL), the curvilinear velocity (VCL) and the amplitude of the lateral head displacement (ALH) were also measured. In Experiment 1, only glutamine (40 mM) significantly improved sperm motility (56.0% +/- 3.0 vs 49.7% +/- 1.6; P < 0.05) compared with the control extender, while velocities were unaffected at concentrations of 40 to 120 mM. However, at 160 mM, a significant decrease in motility and velocity was observed for all amino acids. In Experiment 2, motility in glutamine (range 41.1% +/- 3.8%; 42.4% +/- 3.6) and proline (43.0% +/- 3.7; 45.6% +/- 3.8) extenders compared with the control (34.7% +/- 1.6) was improved significantly (P < 0.05). Sperm velocity was improved at concentrations higher than 40 mM glutamine and 50 mM proline.

Delayed insemination is successful with a new extender for storing fresh equine semen at 15 degrees C under aerobic conditions.

Milk-based semen diluents are known to be practical and effective in protecting equine spermatozoa during storage before artificial insemination. Milk is a biological fluid with a complex composition and contains components which are beneficial or harmful to spermatozoa. The aim of this study was to test the fertility of stallion semen after long-term storage using different milk diluents (INRA 82 or Kenney's diluent) vs one diluent chemically defined (INRA 96), which is composed of efficient milk components and optimized for sperm survival and storage temperature. The milk fraction used was that which best maintained spermatozoal survival based on motility measured in previous studies. Four breeding trials were conducted to determine the influence of combination of new diluent and storage conditions on fertility of the stallion. We compared the standard protocol of storing semen in a skim milk diluent (INRA 82 or Kenney's diluent) at 4 degrees C under anaerobic conditions with the experimental protocol which consisted of storing in a chemically defined, milk-free diluent (INRA 96), at 15 degrees C, under aerobic conditions. After 4 breeding trials, in which the semen was stored for 24 h under the 2 protocols, we obtained 57% (n = 178) and 40% (n = 173) of fertility per cycle using the experimental and the standard protocol respectively (p < 0.001). Another breeding trial was conducted to determine the influence of storage time on the fertility of spermatozoa. We have compared the fertility of semen inseminated immediately (68% of fertility per cycle, n = 50) vs the fertility of semen stored under the experimental protocol for 72 h before insemination (48% of fertility per cycle, n = 52). The experimental protocol improved sperm fertility compared to the standard protocol and seems to be a particular alternative for stallions with cold shock sensitive spermatozoa. Storing semen for 72 h under the experimental protocol seems to be useful in the field.

Equine frozen semen: freezability and fertility field results.

The freezability of stallion semen defined as the number of selected ejaculates/total number of ejaculates frozen from 161 different stallions was analyzed. Of the stallions, 19, 30, 27 and 24% had a freezability of 0%, 0 to 33%, 33 to 66%, over 66%, respectively In 85 different stallions, the correlation of freezability between first and second year was 0.60 (P < 0.001). The relationship between fertility with fresh and frozen semen and freezability was analyzed in 40 stallions whose freezability and fertility information was recorded during 5 years. There was a strong relationship between fertility of fresh semen and semen freezability (P < 0.001). However, the relationship between fertility of frozen semen and freezability was not as marked (P < 0.05). Analysis of the field fertility per cycle results when mares were bred with 300 or 150 x 10(6) total spermatozoa at different frequencies until ovulation indicated that mares that were inseminated 2 times or more per estrus show an improved fertility in comparison with mares inseminated only once (34%, n = 1576 vs 26%, n = 626; P < 0.001). Foaling rate when mares were inseminated with frozen semen (1858 mares during 8 breeding seasons) was mainly influenced by mare age (< 16 years: 54% vs >/= 16 years 42% p < 0.001). Date of first insemination (before May 15: 58% vs after May 15: 37%) also had a significant effect on foaling rate (P < 0.001).

New staining methods for sperm evaluation estimated by microscopy and flow cytometry.

New staining methods and automated instruments are now available to evaluate the sperm cell in vitro. Individual compartments of the sperm cell, such as the nucleus and the plasma and acrosomal membranes, may be investigated, as well as the cell function as shown by mitochondria activity and capacitation. Various probes are used and they can be analyzed by direct light or fluorescent microscopy or by flow cytometry. The automated instruments allow objective and accurate analysis and quantification as well as the ability to evaluate large population of cells in a shorter time, thus providing accurate evaluation of sperm quality. However, before these test can be recommended for routine clinical and investigational use, in the stallion, they need to be confirmed on a larger number of stallions and their correlation with traditional semen parameters and with stallion fertility has to be demonstrated.