E. Palmer

Effect of milk fractions on survival of equine spermatozoa

Milk-based semen diluents are known to be practical and effective in protecting equine spermatozoa during storage. Due to complex composition of milk, the components which are beneficial or harmful to spermatozoa are unknown. To address these unknowns the effect of various milk fractions on motility of stallion spermatozoa was evaluated. The fractions tested were native phosphocaseinate (NPPC), beta-casein, whey protein concentrate (WPC), alpha-lactalbumin, beta-lactoglobulin, microfiltrate, and ultrafiltrate. The standard reference diluents were INRA 82, commercial skim milk, and Hanks salts solution supplemented with Hepes, glucose, lactose (HGLL) supplemented with BSA. After 48 and 96 h storage at 4 or 15 degrees C some milk fractions (ultrafiltrate, microfiltrate, and alpha-lactalbumin fraction) decreased spermatozoal survival. Others (beta-lactoglobulin (BL) and native phosphocaseinate) were protective. Native phosphocaseinate (NPPC) at milk concentration afforted better protection than did the standard reference diluents. The optimal concentration of beta-lactoglobulin afforted significantly better protection than did BSA. The protection afforded by native phophocaseinate was not synergistic with beta-lactoglobulin. This implies a similar mechanism of protective action of these two components. Semen diluted in HGLL supplemented with NPPC (HGLL-NPPC) or in INRA 82 and stored 24 h at 15 degrees C or 4 degrees C, respectively, produced no difference of spermatozoal motility. However, fertility of semen stored in HGLL-NPPC (60%) was higher (p < 0.05) than that stored in INRA 82 (36%).

DELAYED INSEMINATION IS SUCCESSFUL WITH A NEW EXTENDER FOR STORING FRESH EQUINE SEMEN AT 15°C UNDER AEROBIC CONDITIONS

Abstract 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 Kenneys 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 Kenneys diluent) at 4°C under anaerobic conditions with the experimental protocol which consisted of storing in a chemically defined, milk-free diluent (INRA 96), at 15°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

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.

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).

Effect of time during transport of excised mare ovaries on oocyte recovery rate and quality after in vitro maturation

In the mare only a limited number of oocytes can be successfully collected in vivo, so that when large numbers of oocytes are needed for experimentation, ovaries harvested from slaughtered mares must be used. The resulting temperature changes and time intervals mandated by handling and transport of ovaries from the slaughterhouse to the laboratory adversely affect the rate of oocyte recovery and their quality after IVF and maturation. We chose to study the effect of temperature and time in transit of excised ovaries by evaluating rate of oocyte recovery, nuclear maturation stage reached before, and cleavage rate reached after IVF, following short (1.5 to 4 h) and long (6 to 8 h) storage. Temperatures in the storage container decreased from 37-C to 32 degrees and 27.5 degrees C during the short and long interval, respectively. The cumulus-oocytes complexes (COCs) were classified as having a compact cumulus, completely or partially surrounding the oocyte (compact); those having only a corona radiata surrounding the oocyte (corona); those having a completely or partially expanded cumulus, showing a cellular or sparsely cellular, gelatinous cloud around the oocyte (expanded); and those that were completely denuded of both cumulus and corona cells (denuded). All COCs, except the denuded ones, which were discarded, were matured in vitro for 30 h at 38.5 degrees C in 5% CO2. The recovery rate of oocytes was significantly higher after long vs short storage (48 vs 35%; P < 0.01), but the distribution of the collected COCs into the 4 classes was not affected by the storage time. After in vitro maturation nuclear maturity was not affected by the storage time, but oocytes with intact cytoplasmic membranes were more frequently found after short than after long storage (54 vs 34%; P = 0.07), and fully matured oocytes were more often seen with intact membrane (P < 0.01). Moreover, oocytes with intact membranes in metaphase II (MII) were associated with short storage intervals and the corona COC class, while damaged membranes and incomplete maturation were associated with the long storage and the compact COC class.

Fertility prediction in stallions

Abstract The prediction of a stallions fertility is one of the main unresolved problems in horse breeding. Despite many studies of the relationship between seminal characteristics and fertility, we are not able to evaluate with certainty the breeding capacity of a stallion. Stallion selection and fertility prediction are routinely based on the analysis of seminal and behavioural parameters. Basal blood hormone concentrations and their modification after different stimulation are also used for diagnosis. Although the methods developed in some laboratories may explain established subfertility or infertility, mainly detected by abnormal seminal characteristics and/or pregnancy rate, they cannot yet be used for general infertility detection. Such tests are based on spermatozoal morphology, e.g. chromatin and membrane integrity analyses, and spermatozoal functionality, e.g. motility evaluation, zona pellucida-sperm binding assay, and on seminal plasma composition. At this stage we have no idea of the frequency of the abnormalities demonstrated by these methods nor any idea of their correlation with subfertility or infertility.

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.