Comparison of two intravaginal progesterone-releasing devices in shortened-timed artificial insemination protocols in beef cattle.

Commercially available intravaginal progesterone (P4) devices differ in shape, surface area and P4 load, which may affect the resulting pregnancy per AI (P/AI) following timed-AI (TAI). The objective of this study was to compare two intravaginal P4 devices on estrus rate, follicular dynamics and P/AI in beef cattle subjected to shortened-TAI protocols. In Expt. 1, nulliparous heifers were randomly assigned to a P4-releasing intravaginal device (PRID-Delta, 1.55 g P4) or a controlled internal drug release (CIDR, 1.38 g P4) at the initiation of a J-synch protocol. Heifers that displayed estrus 72 h following device removal were TAI, or if not in estrus given GnRH at 72 h and TAI at 90 h. In Expt. 2, nulliparous heifers and non-suckling cows were randomly assigned to either PRID or CIDR groups and either 1 or 2 mg of estradiol benzoate (EB) at initiation of a J-synch protocol. All cattle were TAI concurrent with GnRH 72 h after device removal. In Expt. 3, nulliparous heifers and suckling cows were randomly assigned to either PRID or CIDR groups and initiated a 5-d Cosynch protocol, with TAI concurrent with GnRH 72 h following device removal. In each experiment, cattle received estrus detection patches at device removal, which were then scored from 0 to 3 based on color change between initial application and TAI; 0 = unchanged, 1 = ≤50% change, 2 = >50% change, 3 = missing. Estrus was defined to have occurred when the patch was scored 2 or 3. Transrectal ultrasonography was used to determine cyclicity, diagnose pregnancy in all experiments, and the size of the ovulatory follicle in Expt. 3. In Expt. 1, the estrus rate was greater (72.0% vs. 61.0%; P = 0.04) in the PRID compared to the CIDR group. In Expt. 2, a parity by EB dose interaction (P = 0.02) was attributed to an increased estrus rate (52.8% vs. 41.4%; P = 0.05) in heifers given 1 vs. 2 mg EB. In Expt. 3, there was no difference in the ovulatory follicle diameter at device removal (P = 0.22) or TAI (P = 0.28) between P4 groups. Treatment with a PRID tended (P = 0.10) to increase the P/AI in cows compared to a CIDR (73.5% vs. 61.0%). In all experiments combined, the overall P/AI tended to increase (55.2% vs. 51.0%; P = 0.08) and P/AI in cattle exhibiting estrus increased (64.4% vs. 59.7%; P = 0.02) in cattle given a PRID compared to those given a CIDR, respectively. In summary, the type of intravaginal P4 device affected estrus response and P/AI following TAI in beef cows.

A strategy for improvement of postthaw quality of bison sperm.

The objective was to improve the postthaw quality of bison semen using zwitterion (ZI)-based extenders, glycerol addition at a lower temperature (4 °C), adding reduced glutathione (GSH) in extender, or treating bison sperm with cholesterol-loaded cyclodextrin (CLC) before freezing. Postthaw sperm motility and structural characteristics were analyzed using a computer-assisted sperm analyzer and flow cytometer respectively, at 0 and 3 hours postthaw incubation at 37 °C. In experiment 1, each ejaculate (N = 11) was diluted in Triladyl extender (control) or in ZI extenders (Tes-Tris or HEPES-Tris). In addition, glycerol in semen was added either at 37 °C or 4 °C before cryopreservation. Extenders had no significant effect on postthaw sperm motilities at 0 hour. However, sperm velocity parameters were higher (P < 0.05) in ZI extenders than in Triladyl. Sperm population with intact plasma membrane (IPM) and acrosomes (IACR) were higher in Triladyl than in ZI extenders (P < 0.05). Postthaw sperm total and progressive motilities, average path velocity, straight-line velocity, IPM, and IPM-IACR did not improve with the addition of glycerol at 4 °C. In experiment 2, semen was diluted (50 × 10(6) sperm per mL) in Triladyl extender containing 0 (control), 0.5, 1.0, or 2.0 mM GSH (an antioxidant) at 37 °C. Postthaw sperm motility and structural characteristics at 0 hour and percentage declined after 3 hour incubation, but did not differ because of GSH in the extender (P > 0.05). In experiment 3, fresh bison sperm (100 × 10(6) sperm in 1 mL) were pretreated with 0, 1, 2, or 3 mg/mL of CLC at 22 °C for 15 minutes and diluted to 50 × 10(6) sperm per mL in Tris-citric acid-egg yolk-glycerol extender before cryopreservation. The CLC pretreated sperm had higher (P < 0.05) postthaw total and progressive motilities, IPM, and IACR at 0 hour and less percentage of decline in these characteristics after 3 hour postthaw incubation. In conclusion, zwitterion extenders (Tes-Tris and HEPES-Tris), temperatures of glycerol addition, and GSH in extender did not significantly improve postthaw quality of bison sperm. However, pretreatment with CLC significantly improved postthaw quality of bison sperm, which should enhance its use in assisted reproductive technologies.

A simple and high-throughput method to assess maturation status of bovine oocytes: comparison of anti-lamin A/C-DAPI with an aceto-orcein staining technique.

A precise, accurate, nonambiguous and high-throughput method is required to assess nuclear maturation of mammalian oocytes. The objectives of this study were to compare the efficiency and ease of use of a simplified fluorescence imaging (anti-lamin A/C and 4',6-diamidino-2-phenylindole [DAPI]) technique to the existing technique (aceto-orcein staining) for the evaluation of nuclear maturation of bovine oocytes, and to determine the kinetics of bovine oocyte maturation using an anti-lamin A/C-DAPI technique. In Experiment 1, oocytes were matured in vitro and stained with aceto-orcein and anti-lamin A/C-DAPI staining techniques. The proportions of oocytes lost during procedures and those that could not be classified (because of ambiguous morphology) during evaluation were lower (P < 0.0001) in oocytes stained with anti-lamin A/C-DAPI (9% and 2%) than those stained with aceto-orcein (31% and 13%), respectively. Anti-lamin A/C-DAPI was a quick procedure which could be completed within 7 h after completion of the maturation (compared with > 24 h for the aceto-orcein method). Furthermore, > 200 oocytes could be stained in one batch with anti-lamin A/C-DAPI technique. In Experiment 2, nuclear maturation kinetics of bovine oocytes at various time intervals (0, 6, 12, and 22 h) during in vitro maturation (IVM) was evaluated using the anti-lamin A/C-DAPI technique. Germinal vesicle, germinal vesicle breakdown, metaphase I, and metaphase II oocytes were predominant at 0, 6, 12, and 22 h of IVM, respectively. We concluded that the anti-lamin A/C-DAPI was an efficient and simple technique for nonambiguous evaluation of nuclear maturation status of large numbers of oocytes in a short interval.

Cryopreservation of bull semen shipped overnight and its effect on post-thaw sperm motility, plasma membrane integrity, mitochondrial membrane potential and normal acrosomes.

In the Canadian Animal Genetic Resource Program, bull semen is donated in frozen or fresh (diluted) states. This study was designed to assess the cryopreservation of diluted bull semen shipped at 4°C overnight, and to determine the post-thaw quality of shipped semen using different straw volumes and freezing rates. Semen was collected from four breeding bulls (three ejaculates per bull). Semen was diluted in Tris-citric acid-egg yolk-glycerol (TEYG) extender, cooled to 4°C and frozen as per routine (control semen). After cooling to 4°C, a part of semen was removed and shipped overnight to the research laboratory via express courier (shipped semen). Semen was packaged in 0.25 or 0.5 ml straws and frozen in a programmable freezer using three freezing rates, i.e., -10, -25 or -40°C/min. Control semen was also shipped to the research laboratory. Post-thaw sperm motility characteristics were assessed using CASA, and post-thaw sperm plasma membrane, mitochondrial membrane potential and normal acrosomes were assessed using flow cytometry. Post-thaw sperm quality was greater in shipped semen as compared to control (P<0.001). The shipped semen packaged in 0.25 ml straws had better post-thaw sperm quality than in 0.5 ml straws (P<0.001). Freezing rate had no effect on post-thaw sperm quality. In conclusion, bull semen can be shipped overnight for subsequent cryopreservation and gene banking. Overnight shipping of semen was found advantageous for bull semen cryopreservation. Semen packaging in 0.25 ml straws yielded better post-thaw quality than 0.5 ml straws.

Factors affecting nuclear maturation, cleavage and embryo development of vitrified bovine cumulus-oocyte complexes.

The objective was to investigate the effects of cryodevice, vitrification solutions, and equilibration time on in vitro maturation, cleavage, and embryo development of vitrified bovine oocytes. In Experiment 1, the nuclear maturation (MII) rate of immature bovine COCs vitrified was compared between two equilibration times (0 vs 10 min) in vitrification solution 1 (VS1) and two cryodevices (cryotop vs 0.25 mL straw). The MII rate was higher in the non-vitrified control group than in vitrified groups (61 vs 16%, P < 0.0001). Equilibration time did not affect MII rate (P = 0.964); however, the MII rate was higher for COCs vitrified on cryotops than in straws (23 vs 9%, P = 0.007). In Experiment 2, bovine COCs were vitrified on cryotops using two equilibration times (0 vs 5 min) in VS1 and two kinds of vitrification solutions (freshly prepared vs frozen). Cleavage and blastocyst rates were higher (P < 0.0001) in the non-vitrified control group than vitrified groups (cleavage rate 93 vs 42% and blastocysts rate 31 vs 0.4%). Cleavage rate of COCs vitrified using frozen solutions with 5 min equilibration was higher (P = 0.05) than other treatment groups. However, blastocyst rate did not differ (P = 0.993) among treatment groups. In conclusion, cryotop was a better cryodevice than 0.25 mL straw for vitrification of bovine COCs. Furthermore, 5 min equilibration in VS1 improved cleavage. Compared with control, the vitrification procedure per se damaged bovine COCs, resulting in poor nuclear maturation and embryo development. However, vitrification did not immediately kill oocytes, as the cleavage rate was acceptable.

Quantification of damage at different stages of cryopreservation of endangered North American bison (Bison bison) semen and the effects of extender and freeze rate on post-thaw sperm quality.

Semen cryopreservation is an important technique for the banking of animal germplasm from endangered species and exploitation of genetically superior sires through artificial insemination. Being a member of bovidae family, bison semen has poor freezing ability as compared to dairy and beef bulls' semen. This study was designed to quantify the damage to bison sperm at different stages of cryopreservation, and to determine the effects of extender (commercial Triladyl(®) vs. custom made tris-citric acid [TCA]) and freeze rate (-10, -25 and -40°C/min) on post-thaw quality of bison semen. Semen was collected from five bison bulls (three woods and two plains) via electroejaculation. In Experiment 1, semen was diluted in Triladyl® extender and frozen with freeze rate -10°C/min. Sperm motility characteristics were recorded in fresh, diluted, cooled (4°C) and freeze-thawed semen using computer-assisted sperm analyzer (CASA). In Experiment 2, semen was diluted in Triladyl® or TCA extender, and frozen with three different freeze rates, i.e. -10, -25 or -40°C/min. Thawing was performed at 37°C for 60s. Post-thaw sperm motility characteristics were assessed using CASA, and sperm structural characteristics (plasma membrane, mitochondrial membrane potential and acrosomes) were evaluated using flow cytometer, at 0 and 3h while incubating semen at 37°C. In Experiment 1, total and progressive motilities did not differ among pre-freeze stages of cryopreservation (P>0.05). However, sperm total and progressive motilities declined (P<0.001) in freeze-thawed semen by 35% and 42%, respectively, compared to after cooling (pre-freeze) semen. In Experiment 2, Triladyl®, as compared to TCA, yielded greater (P<0.05) post-thaw sperm total motility (41% compared to 36%) and progressive motility (34% compared to 29%) at 0h, respectively. The percent change in post-thaw sperm total and progressive motilities, VAP, VCL, VSL, IPM-high ΔΨm and IPM-IACR during 3h incubation at 37°C, was less (P<0.05) in TCA than in Triladyl®. There was an effect of freeze rate on post-thaw sperm average path velocity at 0h, and total motility, progressive motility, VCL, IPM and IPM-IACR at 3h were the greatest (P<0.05) when bison semen was frozen at -40°C/min. Likewise, the percent change in post-thaw sperm total and progressive motilities, during 3h incubation at 37°C, was less (P<0.05) in bison semen frozen at -40°C/min. All post-thaw bison sperm characteristics decreased (P<0.05) from 0h to 3h, during incubation at 37°C. In conclusion, the maximum damage to bison sperm occurred during freeze-thaw processes. Post-thaw total and progressive motilities of bison sperm were greater in Triladyl® at 0h whereas sperm survival was greater in TCA extender during 3h post-thaw incubation. Bison sperm had greater survival (P<0.05) when frozen at -40°C/min freeze rate.

Response of buffalo spermatozoa to low temperatures during cryopreservation.

This is the first detailed report on the response of buffalo spermatozoa to low temperatures during freezing. The study determined the critical temperature zone for buffalo spermatozoa and developed a suitable freezing rate for this species. Semen from four Nili-Ravi buffalo bulls diluted in Tris-citric acid was frozen in a programmable freezer. Motion characteristics, plasma membrane integrity and acrosome morphology were determined at +4, 0, -5, -10, -20, -30, -40, -50, -80 and -196 degrees C by removing semen straws from the freezer at exactly these temperatures and rewarming them at 37 degrees C. The first statistical decline in sperm motility and lateral head displacement was observed at -40 degrees C. For all other parameters, there was biphasic decline: for curvilinear velocity, at 0 degrees C and -50 degrees C; and for plasma membrane integrity and acrosome morphology, at -30 degrees C and -50 degrees C. In a second series of experiments, buffalo spermatozoa were frozen using slow (-10 degrees C min(-1)), medium (-20 degrees C min(-1)) or fast (-30 degrees C min(-1)) freezing rates, between -10 degrees C and -80 degrees C. Freezing of buffalo spermatozoa at a rate of -30 degrees C min(-1) yielded higher post-thaw motion characteristics, plasma membrane integrity and normal acrosomes. In conclusion, different sperm characteristics respond differently at low temperatures and the freezing of buffalo spermatozoa at a higher rate ensures higher post-thaw semen quality.

Cryopreservation of immature porcine testis tissue to maintain its developmental potential after xenografting into recipient mice.

The purpose of this study was to develop effective strategies for cooling and cryopreservation of immature porcine testis tissue that maintain its developmental potential. Testes from 1-wk-old piglets (Sus domestica) were subjected to 1 of 12 cooling/cryopreservation protocols: as intact testes, cooling at 4 degrees C for 24, 48, or 72h (Experiment 1); as fragments, programmed slow-freezing with dimethyl sulfoxide (DMSO), glycerol, or ethylene glycol (Experiment 2); or solid-surface vitrification using DMSO, glycerol, or ethylene glycol, each using 5-, 15-, or 30-min cryoprotectant exposure times (Experiment 3). For testis tissue xenografting, four immunodeficient recipient mice were assigned to each protocol, and each mouse received eight grafts. Recipient mice were killed 16 wk after grafting to assess the status of graft development. Based on morphology and in vitro assessment of cell viability, cooling of testis tissue for up to 72h maintained structural integrity, cell viability, in vivo growth, and developmental potential up to complete spermatogenesis comparable with that of fresh tissue (control). In frozen-thawed testis tissues, higher numbers of viable cells were present after programmed slow-freezing using glycerol compared with that after DMSO or ethylene glycol (P<0.001). Among the vitrified groups, exposure to DMSO for 5min yielded numerically higher viable cell numbers than that of other groups. Cryopreserved tissue fragments recovered after xenografting had normal spermatogenesis; germ cells advanced to round and elongated spermatids after programmed slow-freezing using glycerol, as well as after vitrification using glycerol with 5- or 15-min exposures, or using DMSO for a 5-min exposure.

Apoptosis in fresh and cryopreserved buffalo sperm.

The objectives of present study were (a) validation of annexin V/PI assay for estimation of sperm apoptosis in buffalo (Experiment 1) and (b) determining the effect of stages of cryopreservation on sperm apoptosis and its correlation with sperm motility and plasma membrane integrity (Experiment 2). In Experiment 1, different levels of apoptosis were artificially induced in buffalo semen (100x10(6)sperm/aliquot) through graded doses of camptothecin (5, 10 and 20microM/aliquot). Higher concentrations of camptothecin (10 and 20microM) successfully (P<0.05) induced apoptosis as compared to the lower (5microM) dose and/or control. In Experiment 2, semen samples (n=9, three pooled semen samples from each of the three buffalo bulls separately) were cryopreserved using vapor freezing. The mean percentage of apoptotic, necrotic and viable sperm did not differ between fresh and before freezing stages. However, freezing and thawing increased (P<0.05) the percentage of apoptotic sperm (25.4+/-0.6 vs. 36.5+/-1.9) while decreased (P<0.05) the necrotic (35.1+/-1.2 vs. 29.7+/-0.7) and viable sperm (37.2+/-1.3 vs. 32.8+/-1.9, (P<0.07). Likewise, the mean percent motility and plasma membrane integrity decreased (P<0.05) (64+/-2.1 vs. 49.4+/-1.3) and (79.6+/-0.5 vs. 38.7+/-0.3) respectively, at post thaw compared to other stages. Coefficient of correlation, combined at all stages for each variable revealed that sperm apoptosis was inversely correlated with sperm motility and plasma membrane integrity. It is concluded that (a) the annexin V/PI assay can be used as a tool to determine the buffalo semen apoptosis and (b) freezing and thawing induces apoptosis in buffalo sperm.

Antagonist effect of DMSO on the cryoprotection ability of glycerol during cryopreservation of buffalo sperm.

The objective of the present study was to investigate the synergistic effect of DMSO and glycerol added at various temperatures on the post-thaw quality of buffalo sperm. Pooled ejaculates from four Nili-Ravi buffalo bulls were divided into 18 aliquots and extended (1:10) in Tris-citric acid extender differing in glycerol:DMSO ratios (0:0, 0:1.5, 0:3; 3:0, 3:1.5, 3:3; and 6:0, 6:1.5, 6:3, respectively; %, v:v) either at 37 or 4 degrees C. Semen was packaged in 0.5 mL French straws and frozen in a programmable cell freezer. Thawing was performed at 37 degrees C for 50s. Post-thaw motion characteristics, plasma membrane integrity and acrosome morphology of buffalo sperm were determined using computer-assisted semen analyzer (CASA), hypoosmotic swelling (HOS) assay and phase-contrast microscopy, respectively. Glycerol (6%) in extender yielded better post-thaw sperm motility, velocities (straight-line and average path), plasma membrane integrity, and normal acrosomes (P<0.05). Post-thaw sperm motility and plasma membrane integrity declined in the presence of DMSO (P<0.01). The addition of glycerol (6%) at 37 degrees C yielded better post-thaw sperm motility, plasma membrane integrity and velocities than addition at 4 degrees C (P<0.05). In conclusion, glycerol is still an essential cryoprotectant for buffalo sperm. The addition of DMSO antagonized the cryoprotection ability of glycerol and reduced the post-thaw quality of buffalo sperm. Furthermore, 6% glycerol added at 37 degrees C, provided better cryoprotection to the motility apparatus and plasma membrane integrity of buffalo sperm.

Spontaneous uptake of exogenous DNA by bull spermatozoa.

Sperm-mediated DNA transfer can be used to transfer exogenous DNA into the oocyte for the production of transgenic animals. In spite of controversy in the literature, sperm-mediated DNA transfer is a simple and quick technique that can be used in routine breeding programs (AI, embryo transfer and IVF). The main objective of this study was to determine the factors affecting the spontaneous uptake of exogenous DNA by bull spermatozoa. For this purpose, fresh and frozen spermatozoa (0.25 x 10(6)), from the same ejaculate from each of four bulls were co-incubated with fluorescent-labeled green fluorescent protein (GFP) and chloremphenicol acetyltransferase (CAT) plasmids at 37 degrees C for 30 min. Neither bull nor plasmid significantly affected the uptake of exogenous DNA. However, transfection efficiency was higher in frozen-thawed versus fresh spermatozoa (P<0.001). Regardless of whether transfected spermatozoa were alive or dead, all transfected spermatozoa were immotile. It can be concluded that a population of spermatozoa is present in bull semen which has the ability to uptake exogenous DNA spontaneously. There is tremendous scope to improve transfection efficiency of spermatozoa while maintaining motility; this needs to be achieved in order to more easily use this technique in transgenesis. However, live-transfected bull spermatozoa clearly can incorporate exogenous DNA and should be usable in intracytoplasmic sperm injection protocols.

Sephadex and sephadex ion-exchange filtration improves the quality and freezability of low-grade buffalo semen ejaculates.

The effect of sephadex and sephadex ion-exchange filtration on the improvement in quality and freezability of low-grade buffalo semen ejaculates was assessed. Two types of filtration columns were used: one containing only sephadex G-10 (FS) and the other sephadex G-10 along with ion-exchangers (diethyl amino ethane-52 (DEAE-52) cellulose and carboxy methyl-52 (CM-52) cellulose; FS+IE). Unfiltered samples served as controls. Semen ejaculates extended in Tris-citric acid (1:4) (n=16; initial motility 40-50%) were filtered at the rate of 1.5 ml/min under negative pressure at room temperature (28-30 degrees C). The mean recovery rate (%) of motile spermatozoa in the FS (85.9+/-1.51) and FS+IE (77.10+/-2.28) filtrates did not differ significantly. Percentages of sperm motility, normal acrosomes, and intact plasma membranes were highest (P<0.05) in FS+IE, intermediate (P<0.05) in FS and lowest (P<0.05) in controls at the three stages of cryopreservation (postfiltration final dilution, after equilibration, and after freezing). Mean sperm abnormalities were lowest (P<0.05) in the filtrates of FS+IE, moderate (P<0.05) in FS and highest in controls at all stages of freezing. Compared to dilution and equilibration, freezing greatly reduced (P<0.05) the overall percent motility, normal acrosomes and intact plasma membranes. The spermatozoa eluted through FS+IE columns proved more resistant (P<0.05) in bearing dilution, equilibration, freezing and thawing stresses than the spermatozoa from FS and control samples. It is concluded that filtration systems containing an FS+IE column can effectively enhance the quality and freezability of extended, low quality buffalo semen.

Optimizing and quantifying fusion of liposomes to mammalian sperm using resonance energy transfer and flow cytometric methods.

BACKGROUND: Liposomes are used to carry pharmaceutical agents and to alter the lipid composition of cell membranes. This study compared resonance energy transfer (RET), fluorescence dequenching, and flow cytometry as monitors and quantifiers of fusion between liposomes and mammalian spermatozoa. METHODS: Preliminary experiments used RET to determine the optimum sperm concentration for fusion of DL-alpha-phosphatidylcholine dipalmitoyl (PC)/DL-alpha-phosphatidylethanolamine dipalmitoyl (PE) liposomes at 35 degrees C +/- 5 mM Ca2+. Microscopy confirmed the fusion of liposomes, not just adhesion (n = 3). Dequenching tested the time-dependent fusion of liposomes of two different lipid compositions to sperm, both, (n = 3) +/- 1 mM Ca2+ and (n = 3) without Ca2+ at two sperm concentrations. Finally, flow cytometry absolutely quantified the percentage of sperm fusing to liposomes at different liposome-to-sperm ratios (n = 4) and with sperm from different donors (n = 3). RESULTS: RET detected fusion of liposomes with sperm and microscopy confirmed the interaction to be true fusion. Dequenching detected more fusion of liposomes with sperm at 100 x 10(6) sperm per milliliter than at lower concentrations (P < 0.05). Fusion dynamics differed with lipid composition but Ca2+ had no effect. Flow cytometry reliably quantified the percentage of sperm fusing with liposomes, which varied from bull to bull (P < 0.05). CONCLUSION: Liposome fusion with mammalian sperm membranes can be quantified cytometrically and varies with lipid composition, sperm-to-liposome ratio, and individual animals.

Changes in motion characteristics, plasma membrane integrity, and acrosome morphology during cryopreservation of buffalo spermatozoa.

Motion characteristics, plasma membrane integrity, and acrosome morphology of buffalo spermatozoa after different stages of cryopreservation (ie, dilution, cooling to 4 degrees C, equilibration at 4 degrees C, and freezing and thawing) were examined. Semen ejaculates from 4 buffalo bulls were pooled (n = 5), diluted in tris-citric acid extender, cooled to 4 degrees C over 2 hours, equilibrated at 4 degrees C for 4 hours, dispensed into 0.5-mL straws, and frozen in a programmable cell freezer before plunging into liquid nitrogen. Frozen semen was thawed at 37 degrees C for 15 seconds. After completion of each stage, sperm motion characteristics, plasma membrane integrity, and acrosomal morphology were determined using computer-assisted semen analysis, hypo-osmotic swelling assay, and phase-contrast microscopy, respectively. Data were presented as mean +/- standard error of the mean. Visual and computerized motility did not differ due to dilution, cooling, or equilibration (77.3% +/- 2.3% and 90.5% +/- 1.2%, respectively), but was reduced (P < .05) after freezing and thawing (53.0% +/- 4.6% and 48.6% +/- 6.5%, respectively). Linear motility of spermatozoa was lower (P < .05) after dilution or equilibration (56.2% +/- 2.4%) than after cooling or freezing and thawing (79.6% +/- 1.4%). Sperm curvilinear velocity was reduced (P < .05) from 112.4 +/- 5.3 microm/sec after dilution to 96.0 +/- 5.8 microm/s after cooling, and from 87.6 +/- 4.1 microm/s after equilibration to 69.4 +/- 2.0 microm/s after freezing and thawing. Sperm lateral head displacement differed (P < .05) after each stage (ie, dilution, 3.9 +/- 0.2 microm; cooling, 2.3 +/- 0.2 microm; equilibration, 3.1 +/- 0.3 microm; and freezing and thawing, 1.7 +/- 0.2 microm). Spermatozoa with intact plasma membranes were 80.2% +/- 3.9% after dilution, reduced (P < .05) to 60.4% +/- 5.6% after equilibration, and then to 32.6% +/- 3.8% after freezing and thawing. The percentage of spermatozoa with normal acrosomes remained higher after dilution, cooling, or equilibration (73.2% +/- 2.4%) than after freezing and thawing (61.8% +/- 2.4%; P < .05). In conclusion, the maximal damage to the motility apparatus, plasma membrane, and acrosomal cap of buffalo spermatozoa occurs during freezing and thawing followed by equilibration.

Effect of buffering systems on post-thaw motion characteristics, plasma membrane integrity, and acrosome morphology of buffalo spermatozoa.

This study was carried out to identify the suitable buffer for cryopreservation of buffalo semen. Semen was collected with artificial vagina (42 degrees C) from four buffalo bulls. Split pooled ejaculates (n=5), possessing more than 60% visual sperm motility, were extended at 37 degrees C either in tri-sodium citrate (CITRATE), Tris-citric acid (TCA), Tris-Tes (TEST) or Tris-Hepes (HEPEST). Semen was cooled to 4 degrees C in 2 h, equilibrated at 4 degrees C for 4 h, filled in 0.5 ml straws and frozen in a programmable cell freezer before plunging into liquid nitrogen. Thawing of frozen semen was performed after 24 h at 37 degrees C for 15 s. Sperm motion characteristics, plasma membrane integrity, and acrosome morphology of each semen sample were assessed by using computer-assisted semen analyzer (CASA), hypo-osmotic swelling (HOS) assay, and phase-contrast microscope, respectively. Analysis of variance revealed that percent post-thaw visual motility tended (P=0.07) to be higher in HEPEST (61.0+/-2.9) and lowest in CITRATE (48.0+/-2.5). Computerized motility did not vary due to buffering system. Percent post-thaw linear motility tended (P=0.09) to be higher in TCA (78.2+/-5.5) and lower in TEST (52.0+/-6.9). Circular motility (%) was significantly lower (P<0.05) in TCA (11.6+/-2.8) and higher in TEST (29.8+/-5.6). Curvilinear velocity (microm s(-1)) was lower (P<0.05) in TCA (69.4+/-2.0) than in CITRATE (79.0+/-5.8), TEST (87. 2+/-1.6) and HEPEST (82.6+/-3.0). Lateral head displacement (microm) was lowest (P<0.05) in TCA (1.7+/-0.2) and highest in TEST (3.7+/-0. 6). Plasma membrane integrity and normal acrosomes of buffalo spermatozoa did not differ due to buffering system and averaged 40. 0+/-2.7% and 61.4+/-4.6%, respectively. Based upon lower circular motility, curvilinear velocity, and lateral head displacement, it is concluded that post-thaw quality of buffalo semen can be improved using the Tris-TCA buffering system.

Separation of motile spermatozoa from frozen-thawed buffalo semen: swim-up vs filtration procedures.

Three experiments were conducted to maximize the recovery rate of motile spermatozoa from frozen-thawed buffalo semen. In Experiment 1, the swim-up of motile spermatozoa was performed in the presence or absence of HEPES in TALP medium and CO2 in the environment. The recovery rate of motile spermatozoa in TALP medium (control), TALP + HEPES + CO2, TALP + HEPES and TALP + CO2 was 15, 18, 12 and 10%, respectively (P > 0.05), with sperm motility at 87, 89, 90 and 90%, respectively (P > 0.05). In Experiment 2, the pH of TALP medium was adjusted to 7.0, 7.5, 8.0, 8.5 and 9.0, and swim-up procedure was performed in the presence of HEPES and CO2. The recovery rate of motile spermatozoa at different pH was 14, 20, 24, 27 and 16%, respectively (P < 0.05). Motility of separated spermatozoa was 88, 91, 90, 89 and 90%, respectively (P > 0.05). In Experiment 3, the efficiency of ion-exchange filtration and Swim-up procedure in separating motile spermatozoa from frozen-thawed buffalo semen was compared. The recovery rate of motile spermatozoa was 95% in filtration procedure and 33% in swim-up procedure (P < 0.005). In all experiments, normal acrosomes did not vary due to treatments (P > 0.05). In conclusion, HEPES and CO2 had no significant effect on swim-up of buffalo spermatozoa. The pH 8.5 of TALP improved the recovery rate of motile spermatozoa in swim-up procedure. The ion-exchange filtration was found superior to swim-up procedure in harvesting maximum number of motile spermatozoa from frozen-thawed buffalo semen (95 vs 33%; P < 0.001).

Post-thaw plasma membrane integrity of bull spermatozoa separated with a Sephadex ion-exchange column.

Previous experiments have established that filtration of bovine semen through a Sephadex ion-exchange column improves its quality before and after freezing. The present study was conducted to determine the post-thaw membrane integrity of bull spermatozoa separated with a Sephadex ion-exchange column and to determine the kind of protection to spermatozoa is provided by glycerol during freezing and thawing. Semen from Holstein bulls diluted in TEST-yolk extender (with and without glycerol) was filtered through a Sephadex ion-exchange column and frozen in liquid nitrogen (-196 degrees C). After thawing, there were more normal acrosomes in filtered spermatozoa than nonfiltered (P < 0.01). Post-thaw plasma membrane integrity and swelling ability in a hypoosmotic solution revealed that the filtered spermatozoa had a stronger (P < 0.005) plasma membranes than the nonfiltered. Filtered spermatozoa demonstrated higher zona-free hamster oocyte penetration than the nonfiltered (30.5 vs 11.5%; P < 0.0005). Spermatozoa extended in TEST-yolk without glycerol had the lowest (P < 0.001) normal acrosomes, intact plasma membranes and swelling ability. Plasma membrane over the post-acrosomal region of the head and post-midpiece region of the tail was more sensitive to damages caused by freezing and thawing than acrosomal and midpiece regions of spermatozoa. Glycerol in the extender provided significant (P < 0.05) protection to the sensitive regions of filtered and nonfiltered spermatozoa during freezing and thawing. Filtered plus glycerolated spermatozoa had the highest (P < 0.01) normal acrosomes, intact plasma membranes and swelling ability. In conclusion, the pre-freezing filtration of bovine semen harvested the spermatozoa possessing stronger plasma membranes which enabled them to endure freezing and thawing stresses. The addition of glycerol to the extender protected the post-acrosomal region of the head and post-midpiece region of the tail of spermatozoa from freezing and thawing shocks.

Role of sperm motility and acrosome integrity in the filtration of bovine semen.

In this study, the role of sperm motility and acrosome integrity in filtration of bovine semen was investigated. In Experiment 1, the treatment of semen with formaldehyde, hyperosmotic buffer, heating and direct freezing immobilized the spermatozoa completely but their acrosomal status varied significantly (P < 0.01). The immotile spermatozoa, of any kind, did not pass through the Sephadex ion-exchange column at room temperature. In Experiment 2, semen samples possessing different percentages of immobilized spermatozoa (0, 50, 75 and 100%) were filtered through the Sephadex ion-exchange column. The immotile/dead spermatozoa were removed proportionately to their number in the semen by Sephadex ion-exchange column. The type and number of immotile spermatozoa in semen had no effect (P > 0.05) on the post-filtration recovery rate of motile spermatozoa. Filtered spermatozoa exhibited higher (P < 0.01) motility (> 90%), progressive motility (> 70%) and normal acrosomes (> 95%) than non-filtered spermatozoa. In conclusion, sperm motility seems to be more important than acrosome integrity for semen filtration, and the Sephadex ion-exchange column can remove the known quantities of different kinds dead/immotile spermatozoa.

Effect of filtration on post-thaw quality of bull semen.

Semen from 4 Holstein bulls was diluted in 4 different extenders, filtered with Sephadex ion-exchange column, and frozen in liquid nitrogen. Sperm motility, progressive motility, path velocity, progressive velocity and the percentage of normal acrosomes of filtered and nonfiltered semen were recorded before and after freezing. Semen characteristics were significantly influenced by extender, filtration and freezing. Before and after freezing, motility measurements and the percentage of normal acrosomes were higher (P < 0.001) in filtered than in nonfiltered spermatozoa. Post-thaw recovery rate of motile spermatozoa was higher in filtered semen than nonfiltered (68 vs 39%, P < 0.0001). The reduction in motility, progressive motility and the percentage of normal acrosomes during freezing and thawing processes were significantly lower (P < 0.0001) in filtered semen (34, 34 and 4%, respectively) than nonfiltered (59, 54 and 15%, respectively). Post-thaw viability of spermatozoa was significantly affected by extender, filtration and time (P < 0.0001). Immediate (0 h) post-thaw motility of nonfiltered semen (29%) was similar to 4-h post-thaw motility of filtered semen (25%; P > 0.05). In conclusion, bull spermatozoa recovered by Sephadex ion-exchange filtration showed better post-thaw viability.