J. M. Trentin

Impact of spontaneous Neospora caninum infection on pregnancy loss and subsequent pregnancy in grazing lactating dairy cows.

The impact of spontaneous Neospora caninum infection on pregnancy loss and subsequent pregnancy in grazing lactating dairy cows was evaluated. Data from 1273 females (878 multiparous and 395 first-calving cows) from six preselected dairy herds were analyzed. Cows were classified as seropositive (SP) (prevalence, 24%; range, 11%-33%) or seronegative (SN) by indirect immunofluorescence detection of antibodies against N caninum. Seropositive cows (prevalence, 40.0%) presented higher (P < 0.001) incidence of abortion compared with SN cows (prevalence, 4.1%). Neospora caninum DNA was detected by real-time polymerase chain reaction in 44.4% of intact aborted fetuses from SP cows, whereas none was found in those aborted from SN cows. The average daily milk production adjusted to 305 days was lower (P < 0.001) in SP (22.5 ± 0.3 L/day) than in SN cows (24.8 ± 0.2 L/day). Furthermore, SP cows presented greater occurrence of retained placenta (17.1% vs. 6.0%; P < 0.001) and acute postpartum metritis (9.8% vs. 2.4%; P < 0.001). Despite similar pregnancy rates after first postpartum artificial insemination (27.6% vs. 31.8%; P = 0.40), cumulative pregnancy rates during 300 days in milk (94.7% vs. 98.5%; P = 0.005) were greater in SN cows. A reduced (P = 0.0001) Cox proportional hazard of pregnancy rate at 300 days in milk and a longer interval from parturition or abortion to conception (median, 111 vs. 101 days) were observed in SP compared with SN cows. Spontaneous N caninum infection is a significant contributing factor of pregnancy loss and occurrence of uterine disease (i.e., retained placenta and metritis), negatively affecting subsequent pregnancy in grazing lactating dairy cows.

Response to cooling of pony stallion semen selected by glass wool filtration

The aim of this study was to compare the sperm separation technique using filtration through glass wool compared with just diluted cooled semen. Eighteen ejaculates were collected from 6 pony stallions of the Brazilian pony breed. Evaluations were done on pH, osmolarity, total motility, membrane functionality (HOST), membrane integrity (CFDA/PI), morphology and mitochondrial viability (MTT) in fresh, 24 and 48 h of cooled semen at 5°C. After dilution, the half of the extended semen was cooled (control group). The other half was cooled after filtration trough glass wool (filtered group). Retained semen was considered the portion of cells that did not transpose glass wool barrier. Total motility from the control, filtered and retained groups after 24 h of cooling was 35.5%, 43.3% and 10% (p < .0001) respectively. Sperm membrane integrity percentage at the CFDA/PI test was 37.9%, 44.8% and 14.8% (p < .0001), on the control, filtered and retained groups respectively. The results confirmed that the passage of spermatozoa through glass wool increased the selection of spermatozoa from pony stallions with higher motility, mitochondrial viability and membrane integrity for cooling in milk extender up to 24 h. Moreover, it was not obtained higher sperm parameters to control after cooling 48 h under the conditions that the study was conducted.

Seminal Plasma: Effect on Motility, Membrane Functionality, and Spermatic Chromatin Dispersion of Equine Sperm Treated with N-acetyl-L-cysteine at 5°C

Background: N-acetyl-L-cysteine (NAC) is a low molecular weight thiol studied as an antioxidant for stallion semen preservation without changes on sperm viability. Equine seminal plasma is rich in sulfur proteins (cysteine residues) named CRISPS, which, when combined with sulfur-containing antioxidants, can enhance the appearance of DNA lesions. The aim of this study was to assess and compare the effect of different concentrations of NAC by evaluating motility, membrane function and sperm chromatin integrity of equine semen cooled at 5°C in 50% of seminal plasma. Materials, Methods & Results: Nine ejaculates from 9 stallions were divided into 4 aliquots, diluted and divided in nonsupplemented skim milk group (0.0 mM), or supplemented with 5.0, 2.5 and 0.5 mM NAC. Evaluations were made at 0 h, 24 h and 48 h of cooling, except for motility which was evaluated only up to 24 h. The 0.5 (59.7 μM2) and 5.0 mM NAC (55.5 μM2) groups showed similar areas of sperm chromatin dispersion among all groups. However, the area of chromatin dispersion between the non-supplemented group was higher = 65.3 μM2 than the group supplemented with 2.5 mM. The percentage of cells with a functional plasma membrane was similar between supplemented and non-supplemented (0.0 mM) groups, but higher (P < 0.05) in the 0.5 mM NAC (39.7 and 39.8%, respectively) than that of 2.5 mM (34.5%) and 5.0 mM (34.2%) concentrations. Progressive motility was similar among all groups supplemented with NAC. The 0.5 mM NAC group showed 35.2% motile cells while the non-supplemented group exhibited 36.2%. Although 50% seminal plasma was used, NAC did not affect sperm chromatin integrity. Discussion: Seminal plasma interfered more in the results of different concentrations of NAC. This statement is proven by the motility analysis where all NAC concentrations showed similar results. Plasma percentage higher than 20% in diluted semen causes deleterious effects on sperm, such as decreased motility and fertilizing capacity. The membrane analysis in our study was compromised because NAC (2.5 to 5.0 mM) showed high osmolarity. As this was not adjusted, it affected the result. The 2.5 mM NAC group showed a lower area of sperm chromatin dispersion than none-treated sperm, although showing similar results to the other treatments. In a study with semen of Mangalarga Marchador stallions, the 2.5 mM of NAC was able to protect sperm membrane integrity. However, in another study, where semen was kept cooled between 5 and 15°C, no change was observed on sperm quality over different concentrations of NAC. This reinforces that 2.5 mM of NAC provides adequate protection to semen exposed to harmful conditions.The high percentage of plasma associated with this sulfur antioxidant did not compromise DNA integrity, as NAC concentration used was 100 times less than the concentration needed to induce DNA lesions.

Viability of Pony Stallion Semen in Different Temperature and Dilution

Background: Artificial insemination and transport of cooled semen has been routinely used in equine industry in the past 20 years. However, more investigations are needed regarding the methods for long time storage in pony stallion semen. The effect of dilution and cooling temperature on pH, sperm motility, membrane integrity and mitochondrial activity were investigated before and after cooling of stallion semen. Materials, Methods & Results: Two ejaculates each from nine Brazilian ponies were diluted in a nonbuffered powder milk extender cooled at 5°C or 15°C for 48 h using three different dilutions (1:1, 1:2 or 1:3). Data were assessed by analysis of variance and the rate comparison was performed using the Duncan test. Samples diluted 1:1 at 5oC or 15°C showed higher pH values (7.63 ± 0.34 e 7.57 ± 0.27) and lower progressive motility (10.3 ± 11.05, 17.08 ± 9.95). All samples cooled at 15°C also showed lower incidence of morphologically altered spermatozoa (1:1 = 55.84%; 1:2 = 51.84%; 1:3 = 49.95%) [P 0.05) despite time and temperature. The pH, progressive motility, mitochondrial activity and membrane integrity remained similar (P > 0.05) on fresh semen samples independent of the dilution grade used. The best results were obtained when semen was diluted 1:3 and cooled at 15°C. All dilution grades were safe for fresh semen and pH wasincreased when semen was diluted and cooled for 48 h. Discussion: The methodology used to collect and process equine semen and semen from ponies is practically the same. Equine semen when sent for artificial insemination is usually cooled to 5°C. Our results showed that cooling reduces sperm viability, which has also been demonstrated by other studies. In contrast, the best cooling temperature was at 15°C. However, it is easier to keep the temperature at 5°C during transport, due to the large temperature oscillation that may occur during transportation. The semen of ponies can tolerate cooling at both 5 and 15°C. The 1:3 dilution cooled to 15°C provided better viability of pony sperm, and more stable pH during 48 h of cooling. Dilution 1:1 should not be used for cooling in powdered skim milk extender.