Intracytoplasmic sperm injection with mouse spermatozoa preserved without freezing for six months can lead to full-term development

Preservation of mammalian spermatozoa now plays an important role in fertility treatment, in generating hybrid animals, and in protecting endangered or extinct species. To date, the most common method of sperm preservation is freezing in liquid nitrogen (LN(2)). However, this method requires constant supplementation of the LN(2) and also involves some safety issues in transporting LN(2). Here we describe a new sperm preservation method that does not involve freezing. Mouse spermatozoa were cultured in four basic media (HEPES-CZB, potassium simplex optimization medium with amino acids [KSOMaa], K(+)-rich nuclear isolation medium [NIM], and PBS) with or without 10% bovine serum albumin (BSA) or 15% Ficoll as a protectant, and preserved in a refrigerator for up to 6 mo. These preserved sperm were then injected into fresh oocytes and cultured to the blastocyst stage in vitro or transferred into recipient females to demonstrate their genetic integrity. The results of sperm preservation for 1 mo suggested that NIM and PBS were better media than HEPES-CZB or KSOMaa and that BSA and Ficoll could improve either blastocyst or full-term development. Surprisingly, 18 pups were obtained using spermatozoa stored in these media for 6 mo. Moreover, this new method allowed easy production of healthy offspring even after transport of spermatozoa between two countries by aircraft at room temperature. In conclusion, this method allows for easy long-term preservation of mouse spermatozoa in a simple, modified medium at refrigerator temperature with very low cost and wide application.     

Possibility of long-term preservation of freeze-dried mouse spermatozoa

Freeze-dried mouse spermatozoa are capable of participating in normal embryonic development after injection into oocytes. When the freeze-dried spermatozoa are used as a method for storage of genetic materials, however, it is essential to assure the relevance of long-term preservation over several decades or centuries. Thus, we applied the theory of accelerated degradation kinetics to freeze-dried mouse spermatozoa. Thermal denaturation kinetics were determined based on Arrhenius plots derived from transition-state theory analysis at three elevated temperatures: 30, 40, and 50 degrees C. Accelerated degradation kinetics were calculated by extrapolation of Arrhenius plots. This theory also is being applied to the long-term stability of drugs. The estimated rate of development to the blastocyst stage at 3 and 6 mo and at 1, 10, and 100 yr of sperm storage at 4 degrees C were 21.60%, 7.91%, 1.00%, 0%, and 0%, respectively. At -80 degrees C, estimated development rates to the blastocyst stage that would be expected after 100 yr of storage did not decline significantly. In addition, after 3 or 6 mo of storage at 4 or -80 degrees C, preimplantation development of the embryos derived from intracytoplasmic sperm injection (ICSI) was examined. The actual developmental rates to the blastocyst stage from ICSI by freeze-dried sperm stored for 3 mo at 4 and -80 degrees C were 21% and 62%, respectively, and the rates for such sperm stored for 6 mo were 13% and 59%, respectively. These results indicate that the determination of accelerated degradation kinetics can be applied to the preservation of freeze-dried mouse spermatozoa. Furthermore, for long-term preservation, freeze-dried mouse spermatozoa appear to require being kept at lower than -80 degrees C.     

Live rats resulting from injection of oocytes with spermatozoa freeze-dried and stored for one year

This study was designed to examine whether rat spermatozoa after freeze-drying and 1-year storage can participate in full-term development following intracytoplasmic sperm injection (ICSI). Cauda epididymal spermatozoa from Crlj:Wistar rats were frozen in liquid nitrogen (LN(2)), first dried for 14 hr at 0.37 hPa and then for 3 hr at 0.001 hPa. The dried spermatozoa were stored for 1 year in a desiccator at +25 degrees C, or in a refrigerator at +4 degrees C, or in LN(2) at -196 degrees C. Controls consisted of sperm that had only been frozen and stored in LN(2). After being stored, spermatozoa were sonicated to dissociate the sperm tail and were injected into oocytes from superovulated Slc:SD rats. The respective fertilization rates of oocytes injected with frozen sperm, or with freeze-dried sperm stored at +25, +4, and -196 degrees C were 79%, 75%, 70%, and 73%. However, the corresponding cleavage rates of injected oocytes were 63%, 1%, 38%, and 36%. After transfer of >80 zygotes of each group into recipients, the respective percentages of full-term normal offspring resulting from frozen sperm or from freeze-dried sperm stored at +25, +4, and -196 degrees C were 36%, 0%, 7%, and 14%. These results demonstrate that the storage temperature significantly influenced the likelihood of term development of rats produced by injection of oocytes with freeze-dried spermatozoa. Chromosomal analysis of the rat spermatozoa in the ICSI oocytes indicated that chromosomal aberration in freeze-dried spermatozoa stored at +25 degrees C (100%) occurred more frequently than in frozen control spermatozoa (41%) and freeze-dried spermatozoa stored at -196 degrees C (35%), and the frequency of chromosomal aberrations in freeze-dried spermatozoa stored at +4 degrees C (65%) was the intermediate. In conclusion, rat spermatozoa freeze-dried and stored at +4 degrees C for 1 year are capable of participating in full-term development after ICSI.     

The ability of freeze-dried bull spermatozoa to induce calcium oscillations and resumption of meiosis

The objective was to investigate the ability of freeze-dried (FD) bull spermatozoa to induce calcium oscillations in mouse oocytes and meiosis resumption in in vitro-matured bovine oocytes after intracytoplasmic sperm injection (ICSI). Bull spermatozoa were freeze-dried and stored for 1 y at +25, +4, or -196 degrees C. In the first experiment, rehydrated sperm heads were microinseminated into hybrid mouse oocytes loaded with fluo-3/AM, and the kinetics of intracellular calcium concentration was monitored for 1h. Repetitive increases of intracellular calcium concentration were recorded in the majority of injected oocytes, with exception of a few oocytes injected with FD sperm heads stored at +4 degrees C (11%) and +25 degrees C (8%) that exhibited a single increase or no response (non-oscillated). The proportion of oocytes that oscillated with high frequency (>or=10 spikes/h) was higher in the non-dried control group (79%; P<0.05) than in the FD groups (58, 55, and 54% for storage at -196, +4, and +25 degrees C, respectively). In the second experiment, control and FD spermatozoa were microinseminated into in vitro-matured, denuded bovine oocytes. The oocytes were fixed and stained 12h after ICSI. A higher proportion of bovine oocytes injected with control spermatozoa (70%; P<0.05) resumed meiosis than those injected with +25, +4 and -196 degrees C stored FD spermatozoa (53, 48, and 57%, respectively). The proportion of ICSI oocytes that developed to the pronuclear stage (complete activation) was higher in the control group (64%; P<0.05) than those in all the FD groups (34, 27, and 28% for storage at -196, +4, and +25 degrees C, respectively). Thus, the ability of bull spermatozoa to induce frequent intracellular calcium spikes in mouse oocytes was impaired by the process of freeze-drying, without differences among storage at +25, +4 or -196 degrees C, probably resulting in a lower proportion of bovine oocytes that resumed meiosis and/or developed to the pronuclear stage.     

Long-term preservation of mouse spermatozoa after freeze-drying and freezing without cryoprotection

The widespread production of mice with transgenes, disrupted genes and mutant genes, has strained the resources available for maintaining these mouse lines as live populations, and dependable methods for gamete and embryo preservation in these lines are needed. Here we report the results of intracytoplasmic sperm injection (ICSI) with spermatozoa freeze-dried or frozen without a cryoprotectant after storage for periods up to 1.5 years. Freeze-dried samples were stored at 4 degrees C. Samples frozen without cryoprotection were maintained at -196 degrees C. After storage, spermatozoa were injected into the oocytes by ICSI. Zygotic chromosomes and fetal development at Day 15 of gestation were examined after 0, 1, 3, 6, 9, and 12 mo of sperm storage. When fresh spermatozoa were used for ICSI, 96% of resultant zygotes contained normal chromosomes, and 58% of two-cell embryos transferred developed to normal viable fetuses. Similar results were obtained when spermatozoa were frozen without cryoprotection and then used for ICSI (87% and 45%, respectively; P > 0.05) and after 12 mo of sperm storage (mean of six endpoints examined: 87% and 52%, respectively; P > 0.05). Freeze-drying decreased the proportion of zygotes with normal karyoplates (75% vs. 96%; P < 0.001) and the proportion of embryos that developed into fetuses (35% vs. 58%; P < 0.001), but similar to freezing, there was no further deterioration during 12 mo of storage (mean of six endpoints examined: 68% and 34%, respectively; P > 0.05). Live offspring were obtained from both freeze-dried and frozen spermatozoa after storage for 1.5 yr. The results indicate that 1) the freeze-drying procedure itself causes some abnormalities in spermatozoa but freezing without cryoprotection does not and 2) long-term storage of both frozen and freeze-dried spermatozoa is not deleterious to their genetic integrity. Freezing without cryoprotection is highly successful, simple, and efficient but, like all routine sperm storage methods, requires liquid nitrogen. Liquid nitrogen is also required for freeze-drying, but sperm can then be stored at 4 degrees C and shipped at ambient temperatures. Both preservation methods are successful, but rapid freezing without cryoprotection is the preferred method for preservation of spermatozoa from mouse strains carrying unique genes and mutations.     

Factors affecting the efficiency of producing porcine embryos expressing enhanced green fluorescence protein by ICSI-mediated gene transfer method

This study aims to investigate factors that affect the efficiency of blastocyst development and enhanced green fluorescence protein (EGFP) expression in porcine embryos following intracytoplasmic sperm injection (ICSI)-mediated DNA transfer. Frozen-thawed dead spermatozoa were exposed to different concentrations (0.01 microg/mL, 0.05 microg/mL or 0.1 microg/mL) of EGFP DNA solution, and then microinjected into in vitro matured oocytes. The optimal concentration for EGFP expression of resultant embryos was 0.05 microg/mL. When oocytes were microinjected on a warm stage at 30 degrees C, the percentage of EGFP-expressing embryos was higher than that at 38.5 degrees C (40.1% vs. 20.9%, P<0.01). The efficiency of EGFP expression in embryos following ICSI using linear EGFP DNA-exposed spermatozoa was higher than using circular DNA (40.8% vs. 28.2%, P<0.05). ICSI oocytes treated with 6-DMAP after electro-activation had a higher percentage of embryos expressing EGFP than those not treated (52.5% vs. 26.3%, P<0.01). However, neither incubation temperatures of spermatozoa and DNA (4 degrees C, 24 degrees C or 39 degrees C) nor BSA addition to the incubation medium affected the efficiency of producing EGFP-expressing embryos. Furthermore, treatment with DNase I after preincubation of sperm and DNA prevented the embryos from expressing EGFP. The EGFP expression of ICSI oocytes was affected neither by intracytoplasmic injection using sperm heads or whole spermatozoa, nor by washing of the sperm after preincubation. The above-mentioned factors did not affect embryonic developmental competence, apart from 6-DMAP treatment after electro-activation. In conclusion, most exogenous DNA molecules were tightly bound on the membranes of sperm head after incubation of DNA and sperm, and the temperature during ICSI, 6-DMAP treatment, exogenous DNA concentrations and constructs could significantly affect EGFP expression in porcine embryos following ICSI-mediated DNA transfer.     

Sonication per se is not as deleterious to sperm chromosomes as previously inferred

Although sonication is a simple way to immobilize ("kill") spermatozoa prior to injection into oocytes, this has been thought to be destructive to sperm chromosomes. Mouse and human spermatozoa were immobilized by sonication and kept in various media for up to 2 h, then their nuclei were individually injected into mouse oocytes for the analysis of chromosomes at the first cleavage metaphase. In both the mouse and human, incidence of structural chromosome aberrations was much higher in the spermatozoa sonicated and stored in Biggers-Whitten-Whittingham medium for 2 h at 37.5 degrees C than in those stored for 5 min in the same medium. We concluded, therefore, that it is not sonication per se but a prolonged exposure of sperm nuclei to extracellular milieu that is detrimental to sperm chromosomes. The incidence of structural chromosome aberrations of mouse and human spermatozoa was significantly reduced when the spermatozoa were sonicated and stored in K(+)-rich nucleus isolation medium containing EDTA. This suggests that sperm chromosome degradation following sperm immobilization by sonication is partly due to detrimental effects of a Na(+)-rich medium and of DNase on sperm chromatin. Ideally, it should be possible to prepare artificial media that maintain the integrity of sperm chromosomes for many hours after immobilization.     

In vitro survival of bovine spermatozoa stored at room temperature under epididymal conditions

In this study, environmental conditions mimicking those prevailing in the epididymis were used for storing ejaculated bull spermatozoa in vitro during 4 days at ambient temperature. These conditions were low pH, high osmolarity, high sperm concentration and low oxygen tension. Hepes-TALP was used as basic storage medium. Fresh spermatozoa were stored at a concentration of 10 x 10(6)spermatozoa/ml in Hepes-TALP of different pH (pH 4, 5, 6, 7 or 8), and osmolarity (100, 300, 400, 500, 600 or 800 mOsm/kg), and under different atmospheric conditions (nitrogen gassed or aerobic). Spermatozoa were also stored undiluted or at different concentrations: 10x 10(6), 100 x 10(6), 500 x 10(6) or 1 x 10(9)spermatozoa/ml. Sperm parameters such as membrane integrity, motility, mitochondrial membrane potential or DNA fragmentation were used to assess semen quality after storage. Adjustment of the pH of Hepes-TALP to pH 6 yielded significantly better results than storage at all other pH values. Isotonic Hepes-TALP (300 mOsm/kg) had a less detrimental effect on spermatozoa than hypo- and hyperosmotic versions. No differences in sperm parameters were observed when spermatozoa were incubated under aerobic or under nitrogen gassed storage conditions. Optimal sperm concentration in vitro is 10 x 10(6)spermatozoa/ml. This is in contrast with the in vivo situation, where spermatozoa are stored at high concentration. However, better results at high sperm concentrations were obtained when spermatozoa were diluted for less than 5 min in Triladyl-egg yolk-glycerol diluent immediately after ejaculation.     

Long-term preservation of freeze-dried mouse spermatozoa

Many genetically engineered mice strains have been generated worldwide and sperm preservation is a valuable method for storing these strains as genetic resources. Freeze-drying is a useful sperm preservation method because it requires neither liquid nitrogen nor dry ice for preservation and transportation. We report here successful long-term preservation at 4 °C of mouse spermatozoa freeze-dried using a simple buffer solution (10mM Tris, 1mM EDTA, pH 8.0). Offspring with fertility were obtained from oocytes fertilized with freeze-dried spermatozoa from C57BL/6 and B6D2F1 mouse strains stored at 4 °C for 3 years. This freeze-drying method is a safe and economical tool for the biobanking of valuable mouse strains.     

Sperm capacitation in the domestic cat (Felis catus) and leopard cat (Felis bengalensis) as studied with a salt-stored zona pellucida penetration assay.

The ability of domestic cat or leopard cat spermatozoa to penetrate zonae pellucidae (ZP) of salt-stored, domestic cat oocytes was examined as an assay for sperm capacitation. Ovarian oocytes were recovered after ovariectomy and matured in vitro for 18-36 h. Following removal of cumulus cells, the oocytes were used fresh, or stored (4 degrees C, 0.5-24 weeks) in a HEPES-buffered hypertonic salt solution. Electroejaculated, washed sperm (2-4 x 10(6) sperm/ml) were preincubated for 1.0 h (38 degrees C, 5% CO2 in air) and then co-incubated (2 x 10(5) sperm/ml) with fresh or stored oocytes for 6.0 h. Gametes were incubated in a protein-free, modified Tyrode's solution (TLP-PVA) or in the same medium containing 4.0 mg/ml bovine serum albumin (BSA; TALP-PVA). Treatments were compared for percentage ZP penetration (defined as sperm heads reaching more than halfway through the ZP) as an index of sperm capacitation. In both the domestic cat and leopard cat, there was no difference (P greater than 0.05) in sperm penetration of fresh ZP (domestic cat, 42.5 +/- 5.4%; leopard cat, 38.6 +/- 2.8%) or stored ZP (domestic cat, 32.4 +/- 4.2%; leopard cat, 27.6 +/- 2.3%). Sperm incubated in protein-free medium (TLP-PVA) were less capable (P less than 0.05) of ZP penetration (domestic cat, 14.6 +/- 5.9%; leopard cat, 7.9 +/- 3.0%) than sperm incubated in medium TALP-PVA containing BSA (domestic cat, 60.3 +/- 5.9%; leopard cat, 58.4 +/- 3.0%).(ABSTRACT TRUNCATED AT 250 WORDS)     

Phenotypic analysis of C57BL/6J and FVB/NJ mice generated using evaporatively dried spermatozoa

Combination of evaporative drying and frozen storage at -80 degrees C has been used successfully to preserve hybrid B6D2F1 mouse spermatozoa. To determine whether this method can be applied equally well to inbred mice, spermatozoa of C57BL/6J and FVB/ NJ mice were evaporatively dried and stored for 1 mo at -80 degrees C before being used for intracytoplasmic sperm injection (ICSI) to produce live offspring. After weaning, 1 male and 1 female mouse from each litter were randomly selected at 8 wk of age for natural mating to produce live offspring. Results showed that spermatozoa from both inbred strains that had been evaporatively dried and subsequently stored at -80 degrees C could be used successfully to derive live, healthy, and reproductively sound offspring by ICSI. No significant differences were found in embryo transfer rate (number of pups born/number of embryos transferred), litter size, weaning rate, body weight, number of pathologic lesions, and amount of contamination by pathogens of mice produced by ICSI using evaporatively dried spermatozoa compared with mice produced by natural mating or by ICSI using fresh (that is, nonpreserved) spermatozoa. Progeny produced by mating mice generated from ICSI using evaporatively dried spermatozoa were normal. Therefore, spermatozoa from inbred mouse strains C57BL/6J and FVB/NJ can be preserved successfully after evaporative drying and frozen storage at -80 degrees C.     

Viable rat offspring derived from oocytes intracytoplasmically injected with freeze-dried sperm heads

A 2 x 3 factorial designed experiment was conducted in order to examine whether freeze-dried rat spermatozoa can participate in full-term development following intracytoplasmic sperm injection (ICSI). A sperm suspension from cauda epididymides of Sprague-Dawley (SD) rats was prepared with or without ultrasonic treatment. The sonicated and non-sonicated sperm suspensions were processed for freeze-thawing (FT groups; 100 microl sample was cooled in liquid nitrogen vapor, stored for 1 day at--196 degrees C, and thawed in a 25 degrees C water bath) and freeze-drying (FD groups; 100 microl sample was frozen in liquid nitrogen for 20 s, lyophilized for 6 h, stored at 4 degrees C for 2 days, and rehydrated with 100 microl ultrapure water), or were subjected to immediate use for ICSI (fresh control groups). The sperm heads were microinjected into denuded SD oocytes using a piezo-driven micropipette 2-4 microm in diameter. The presumptive zygotes were transferred into oviducts of pseudopregnant Wistar female rats. Viable rat offspring were produced from all six experimental groups. Ultrasonic treatment of rat spermatozoa was effective in increasing the offspring rate (23.3% vs 6.7% in fresh control groups, 35.0% vs 7.6% in FT groups, 9.2% vs 2.5% in FD groups). The acrosomal region appeared to be intact even after ultrasonic FT and FD treatments as well as in the fresh controls, while the lateral dorsal region of the sperm membrane was more or less damaged in the sonicated, FT and FD samples. Thus, the successful participation of freeze-dried spermatozoa in full-term development was demonstrated by applying ICSI in the rat.     

Fertilization and development in vitro of bovine oocytes following intracytoplasmic injection of heat-dried sperm heads

This study investigated the development of bovine oocytes following intracytoplasmic injection of sperm heads from spermatozoa dried by heating. When sperm suspension was heated in a dry oven at 50, 56, 90, and 120 degrees C, the mean amounts of residual water were about 0.3 g water/g dry weight within 8 h, 6 h, 1.5 h, and 20 min of heating, respectively. Oocyte activation, cleavage of oocytes, and development of cleaved embryos to the morula stage were better in oocytes injected with spermatozoa stored at 25 degrees C for 7-10 days following drying at 50 and 56 degrees C than at 90 and 120 degrees C; however, only a small proportion of oocytes developed to the blastocyst stage. When spermatozoa were dried at 50 degrees C for 16 h, activation, male pronucleus (MPN) formation, cleavage, and development to the morula stage were less good than when spermatozoa were dried for 8 and 10 h and no blastocysts were obtained. The development of oocytes was significantly better when spermatozoa were stored for 7-10 days at 4 degrees C than 25 degrees C after drying at 50 degrees C for 8 h. Longer storage (7 days-12 mo) of heat-dried spermatozoa at 4 degrees C did not affect MPN formation in activated oocytes, but blastocyst development was significantly lower when spermatozoa were stored for 3 mo or more. These results demonstrate that bovine oocytes can be fertilized with heat-dried spermatozoa and that the fertilized oocytes can develop at least to the blastocyst stage.     

Penetration by bull spermatozoa into the zona pellucida of dead bovine oocytes recovered from frozen-thawed ovaries

The present study was carried out to determine if the zona pellucida of dead bovine oocytes obtained from ovaries stored at -196 degrees C could be used to assess penetrability of capacitated bull spermatozoa. Follicular oocytes were recovered from bovine ovaries which were frozen slowly in a box containing dry ice, plunged into liquid nitrogen, and thawed at 37 degrees C. The dead oocytes were inseminated with various concentrations of spermatozoa preincubated for 0 to 4 h. Sperm penetration rates of the dead oocytes were significantly altered by sperm concentration and preincubation time. Dead and living oocytes matured in vitro (control) gave similar patterns of penetrability based on sperm preincubation time. When sperm concentration was increased, the rate of multiple sperm penetration into the dead oocytes also increased significantly, but the rate of penetration into living oocytes did not alter significantly. All dead oocytes from ovaries stored at -196 degrees C for 1 d to 3 mo were penetrated at similar rates by spermatozoa preincubated for 1-h. Thus, we conclude that dead follicular oocytes recovered from frozen ovaries are useful for the assessment of sperm capacitation and/or the acrosome reaction in cattle.     

Ability to activate oocytes and chromosome integrity of mouse spermatozoa preserved in EGTA Tris-HCl buffered solution supplemented with antioxidants

Potential methods for cryopreservation of mouse spermatozoa are freeze-drying, desiccation, and suspension in EGTA Tris-HCl buffered solution (ETBS: 50 mM NaCl, 50 mM EGTA, and 10 mM Tris-HCl). To determine the duration that mouse spermatozoa suspended in ETBS-based solutions could retain their normal characteristics without freezing, spermatozoa collected from the cauda epididymis were suspended in ETBS or in ETBS supplemented with the antioxidants, dimethyl sulfoxide (DMSO), or DL-alpha-tocopherol acetate (Vitamin E acetate; VEA) diluted in DMSO, then held at ambient temperature (22-24 degrees C) for up to 9 days. When oocytes were injected with spermatozoa preserved in ETBS alone, activation rates of oocytes and chromosome integrity at the first cleavage metaphase decreased at 1 day (P < 0.001) and 2-4 days (P < 0.01) following treatment. When oocytes were injected with spermatozoa preserved in ETBS supplemented with DMSO or VEA/DMSO, chromosome integrity did not decrease significantly (through 9 days of preservation). Although DMSO maintained sperm chromosome integrity more effectively than VEA/DMSO up to 2-4 days (91 and 67%, normal karyotypes in DMSO and VEA/DMSO, respectively), VEA/DMSO helped to maintain the ability of spermatozoa to activate oocytes, but did not enhance the maintenance of sperm chromosome integrity. These results suggested that deterioration of spermatozoa preserved in ETBS alone was delayed by supplementation with antioxidants.     

Recovery of motile,membrane-intact spermatozoa from canine epididymides stored for 8 days at 4 degrees C

The purpose of this study was to determine how long canine spermatozoa remain motile and with intact membranes when maintained within epididymides stored at 4 degrees C, and to determine whether such stored spermatozoa are able to bind to canine zonae pellucidae. Testes with attached epididymides, obtained from 32 dogs (26 purebred; six mixed breeds) at orchiectomy, were refrigerated at 4 degrees C, and spermatozoa were collected from caudae epididymides at nine time intervals ranging from 5 to 192 h. The effects on spermatozoa that had been refrigerated within epididymides for various times were determined by assaying sperm motility, integrity of plasma membranes and of acrosomes, and measuring binding of membrane-intact spermatozoa to canine zonae pellucidae. Membrane integrity was assessed using a double fluorescent dye, and acrosome integrity by staining with Pisum sativum agglutinin. For the zona-binding assay at various refrigeration time points, duplicate sets of six oocytes each, isolated from ovaries retrieved at elective ovariohysterectomy, were placed into 100 microl droplets of sperm capacitation medium containing 5 x 10(6) spermatozoa/ml. One minute later, oocytes were rinsed vigorously by pipetting, and then incubated for 1 h at 38.5 degrees C in a humidified atmosphere of 5% CO2 in air; the number of membrane-intact spermatozoa bound to zonae were counted. There was no significant decrease in membrane integrity and acrosome integrity of spermatozoa recovered from epididymides stored at 4 degrees C within the first 48 h of refrigeration. In contrast, sperm motility decreased significantly within the first 5 h of refrigeration (P < 0.05), but then declined more gradually thereafter. Some spermatozoa recovered from epididymides that had been refrigerated for 192 h retained their capability to bind to zonae pellucidae, although the mean number of refrigerated spermatozoa (0.4) bound to zonae was less than that of fresh samples (9.0). Membrane integrity of spermatozoa recovered from epididymides refrigerated for various times was highly correlated (r = 0.88) with sperm motility. Even after storage for 192 h (8 days) at 4 degrees C, motile spermatozoa could be recovered from the epididymides, and such refrigerated spermatozoa were capable of binding to zonae. We interpreted these data to indicate that it might be possible to recover functional spermatozoa from postmortem specimens of domestic and nondomestic canids.     

Relation between storage temperature and fertilizing ability of freeze-dried mouse spermatozoa

The advantage of freeze-dried mouse spermatozoa is that samples can be stored in the refrigerator (+4 degrees C). Moreover, the storage of freeze-dried spermatozoa at ambient temperature would permit spermatozoa to be shipped easily and at low cost around the world. To examine the influence of the storage temperature on freeze-dried spermatozoa, we assessed the fertilizing ability of spermatozoa stored at different temperatures. Cauda epididymal spermatozoa were freeze-dried in buffer consisting of 50 mM ethylene glycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid, 50 mM NaCl, and 10 mM Tris-HCl (pH 8.0). Samples of freeze-dried spermatozoa were stored at -70, -20, +4, or +24 degrees C for periods of 1 week and 1, 3, and 5 months. Sperm chromosomes were maintained well at -70, -20, and + 4 degrees C for 5 months, and oocytes fertilized with these spermatozoa developed to normal offspring. Moreover, the chromosomal integrity of spermatozoa stored at -20 or + 4 degrees C did not decrease even after 17 months. In contrast, the chromosomes of spermatozoa stored at +24 degrees C were maintained well for 1 month but became considerably degraded after 3 months. In addition, to investigate the cause of deterioration of sperm chromosomes during storage at +24 degrees C, spermatozoa were freeze-dried in buffer containing DNase I. The chromosomes of spermatozoa freeze-dried with 1 or 0.2 units/ml of DNase I, 100% or 72%, respectively, exhibited chromosomal abnormalities. Our findings suggest that freeze-dried spermatozoa can be stored long-term with stability at +4 degrees C, and the suppression of nucleases present in the buffer or spermatozoa during storage led to the achievement of long-term storage of freeze-dried spermatozoa.     

Thermostability of sperm nuclei assessed by microinjection into hamster oocytes

Nuclei isolated from spermatozoa of various species (golden hamster, mouse, human, rooster, and the fish tilapia) were heated at 60 degrees-125 degrees C for 20-120 min and then microinjected into hamster oocytes to determine whether they could decondense and develop into pronuclei. Mature, mammalian sperm nuclei, which are stabilized by protamine disulfide bonds, were moderately heat resistant. For example, they remained capable of pronucleus formation even after pretreatment for 30 min at 90 degrees C. Indeed, a temperature of 125 degrees C (steam) was required to inactivate hamster sperm nuclei completely. On the other hand, nuclei of rooster and tilapia spermatozoa and those of immature hamster and mouse spermatozoa, which are not stabilized by protamine disulfide bonds, were sensitive to heating; although some of them decondensed after exposure to 90 degrees C, none formed male pronuclei. Furthermore, nuclei of mature hamster sperm became heat labile when they were pretreated with dithiothreitol to reduce their protamine disulfide bonds. These observations suggest that the thermostability shown by the nuclei of mature spermatozoa of eutherian mammals is related to disulfide cross-linking of sperm protamines.     

Fertilisability of ovine, bovine or minke whale (Balaenoptera acutorostrata) spermatozoa intracytoplasmically injected into bovine oocytes

This study was conducted to investigate the possibility of using bovine oocytes for a heterologous fertility test by intracytoplasmic sperm injection (ICSI) and to compare the pronuclear formation of ram, bull and minke whale spermatozoa after injection into bovine oocytes. Bovine oocytes were cultured in vitro for 24 h and those with a polar body were selected for ICSI. Frozen-thawed semen from the three species were treated with 5 mM dithiothreitol for 1 h and spermatozoa were killed by storing them in a -20 degrees C refrigerator before use. ICSI was performed using a Piezo system. Three experiments were designed. In experiment 1, a higher (p < 0.05) male pronuclear formation rate was found in the oocytes injected with ram (52.6%) or bull (53.4%) spermatozoa than with minke whale spermatozoa (39.1%). In experiment 2, sperm head decondensation was detected at 2 h after ICSI in the oocytes injected with a spermatozoon of each species. Male pronuclei were first observed at 4 h in the oocytes injected with ram or bull spermatozoa and at 6 h in oocytes injected with minke whale spermatozoa. The mean diameters of male pronuclei derived from both whale and bull spermatozoa were larger than those from ram spermatozoa (30.4 microm and 28.3 microm vs 22.4 microm, p < 0.005). The mean diameter of female pronuclei in the oocytes injected with whale spermatozoa was also larger than with ram spermatozoa (29.3 microm vs 24.7 microm, p < 0.05). The development of male and female pronuclei was synchronous. In experiment 3, ethanol-activated oocytes injected with a spermatozoon from any of the three species achieved significantly higher (p < 0.05-0.001) cleavage rates than control oocytes. Blastocyst formation was only observed when bull spermatozoa were used. The results of this study indicate that dead foreign spermatozoa can participate in fertilisation activities in bovine oocytes after ICSI.     

Effect of sperm immobilisation and demembranation on the oocyte activation rate in the mouse.

To analyse the effect of the state of the sperm plasma membrane on oocyte activation rate following intracytoplasmic sperm injection (ICSI), three types of human and mouse spermatozoa (intact, immobilised and Triton X-100 treated) were individually injected into mouse oocytes. At 30, 60 and 120 min after injection, maternal chromosomes and sperm nuclei within oocytes were examined. Following human sperm injection, the fastest and the most efficient oocyte activation and sperm head decondensation occurred when the spermatozoa were treated with Triton X-100. Intact spermatozoa were the least effective in activating oocytes. Thus, the rate of mouse oocyte activation following human sperm injection is greatly influenced by the state of the sperm plasma membrane during injection. When mouse spermatozoa were injected into mouse oocytes, the rates of oocyte activation and sperm head decondensation within activated oocytes were the same irrespective of the type of sperm treatment prior to injection. We witnessed that live human spermatozoa injected into moue oocytes often kept moving very actively within the ooplasm for more than 60 min, whereas motile mouse spermatozoa usually became immotile within 20 min after injection into the ooplasm. In 0.002% Triton X-100 solution, mouse spermatozoa are immobilised faster than human spermatozoa. These facts seem to suggest that human sperm plasma membranes are physically and biochemically more stable than those of mouse spermatozoa. Perhaps the physical and chemical properties of the sperm plasma membrane vary from species to species. For those species whose spermatozoa have 'stable' plasma membranes, prior removal or 'damage' of sperm plasma membranes would increase the success rate of ICSI.