Intracytoplasmic sperm injection is more efficient than in vitro fertilization for generating mouse embryos from cryopreserved spermatozoa

Efficient and dependable mouse cryopreservation methods are urgently needed because the production of mice with transgenes and disrupted and mutant genes is now commonplace. Preservation of these unique genomes provides an essential safeguard for future research. Unfortunately, mouse spermatozoa appear more vulnerable to freezing than other species, e.g., bovine and human. In this study, we examined the efficiency of intracytoplasmic sperm injection (ICSI) and in vitro fertilization (IVF) in generating embryos from mouse spermatozoa frozen with 18% raffinose and 3% skim milk for cryoprotection. A comparison was made between the inbred strain C57BL/6J, commonly used in mutagenic and transgenic studies, and a hybrid strain B6D2F1 (C57BL/6J x DBA/2J). C57BL/6J spermatozoa are known to be more sensitive to freezing than B6D2F1. Fertilization of oocytes after IVF was significantly lower with C57BL/6J spermatozoa when compared with B6D2F1 spermatozoa for both fresh and frozen spermatozoa (fresh, 89 vs. 55%; frozen, 56 vs. 9%). Freezing also reduced the fertility of B6D2F1 spermatozoa (89 vs. 56%). Fertilization improved dramatically after ICSI with fresh and frozen C57BL/6J spermatozoa (90 and 85%) and also with frozen B6D2F1 spermatozoa (87%). The development of two-cell embryos to the blastocyst stage was lower for C57BL/6J than B6D2F1 (42-61% and 84-98%) in all treatments but similar for embryos within each strain. The normality of chromosomes from fresh and frozen spermatozoa was assessed in oocytes prior to first cleavage. The majority of oocytes had normal chromosomes after IVF (98-100%) and ICSI (87-95%), indicating that chromosomal abnormalities were not responsible for the poorer development in vitro of C57BL/6J embryos. In conclusion, our data show that ICSI is a more efficient and effective technique than IVF for generating embryos from frozen spermatozoa. More important, ICSI is especially valuable for strains where IVF with fresh spermatozoa produces few or no embryos.     

Intracytoplasmic sperm injection effects in infertile azh mutant mice

Several reports in the literature describe men with infertility resulting from abnormal sperm head shape or decapitation defects of their spermatozoa. These defects are similar to those shown for the spermatozoa from azh (abnormal spermatozoon head shape) mice. The present study examines the efficiency and effects of intracytoplasmic sperm injection (ICSI) in successive generations of azh mice generated with this method. Three successive generations of azh mice were produced with ICSI. In all three ICSI series, more than 80% of 2-cell embryos were obtained, and more than 35% of embryos transferred gave rise to normal live offspring. In addition, ICSI was used to cross homozygous azh/azh males with homozygous azh/azh females, and live offspring were obtained. The ICSI-derived males were tested for their fecundity and abnormalities of sperm morphology. Spermatozoa from ICSI-derived azh/+ males did not show any impairment of fecundity in in vitro fertilization. These spermatozoa successfully fertilized oocytes from both C57BL/6 and B6D2F1 females, with fertilization rates ranging from 70%- 92%. The proportion of morphologically normal spermatozoa was similar in azh/+ males from three successive generations of ICSI (57.8%, 54.8%, and 49.0%, respectively), and no differences were noted when comparing ICSI-derived males with males derived by mating (57.6%) and with wild-type controls (61.6%). Detailed analysis differentiating between specific types of anomalies of sperm morphology did not reveal significant differences among the examined groups. The results of the present study demonstrate that ICSI does not enhance the azh mutation phenotype in the offspring and brings no risks when applied continuously. Moreover, serial (successive generations) ICSI is highly efficient in maintaining valuable mice with fertility problems.     

Efficient production of intersubspecific hybrid mice and embryonic stem cells by intracytoplasmic sperm injection

Recently, mice and embryonic stem (ES) cells with allelic polymorphisms have been used extensively in the field of genetics and developmental biology. In this study, we examined whether intersubspecific hybrid mice and ES cells with these genotypes can be efficiently produced by intracytoplasmic sperm injection (ICSI). Frozen-thawed spermatozoa from wild-derived strains, JF1 (Mus musculus molossinus), MSM (M. m. molossinus), HMI (M. m. castaneus), and SWN (M. m. spp.), were directly injected into mature oocytes from laboratory mice ([C57BL/6 x DBA2]F1; M. m. domesticus). The in vitro and in vivo developmental capacity of F1 embryos was not significantly different among the groups (P > 0.05), and term offspring were efficiently obtained in all groups (27%-34% of transferred embryos). However, the mean body and placental weights of the offspring differed significantly with genotype (P < 5 x 10(-10)), with the HMI hybrid greatest in both body and placental weights. In an application study using these F1 offspring, we analyzed their mitochondrial DNA using intersubspecific polymorphisms and found the consistent disappearance of sperm mitochondrial DNA in the F1 progeny. In a second series of experiments, we generated F1 blastocysts by injecting MSM spermatozoa into C57BL/6 oocytes and used them to generate hybrid ES cell lines. The ES cell lines were established at a high efficiency (9 lines from 20 blastocysts) and their allelic polymorphisms were confirmed. Thus, ICSI using cryopreserved spermatozoa allows the efficient and immediate production of a number of F1 hybrid mice and ES cell lines, which can be used for polymorphic analysis of mouse genetics.     

Equine blastocyst development after intracytoplasmic injection of sperm subjected to two freeze-thaw cycles

This study was conducted to evaluate the effects of thawing, division into aliquots and refreezing on fertilizing capacity (ability to support embryo development after intracytoplasmic sperm injection; ICSI) of frozen stallion semen. Frozen semen from a fertile stallion was thawed, diluted 1:100 with freezing extender, and refrozen (2F treatment). Control semen was frozen only once. In vitro matured equine oocytes were injected with: (1) motile control spermatozoa; (2) motile 2F spermatozoa; (3) non-motile 2F spermatozoa; or (4) non-motile 2F spermatozoa, followed by injection of sperm extract. Blastocyst development after ICSI was equivalent between control spermatozoa and motile 2F spermatozoa (27 and 23%, respectively). Blastocyst development after injection of non-motile 2F spermatozoa (13%) tended (P=0.07) to be lower than that for control spermatozoa. Injection of sperm extract into oocytes that received non-motile 2F spermatozoa resulted in a significant decrease in blastocyst development (to 2%) compared with injection of non-motile 2F spermatozoa alone. Spermatozoa from a subfertile stallion was similarly processed and used for ICSI; blastocyst development for both motile control (once frozen) spermatozoa and motile 2F spermatozoa was 9%. In conclusion, frozen stallion semen may be thawed, diluted, and refrozen without effect on the ability of motile spermatozoa to initiate embryo development after ICSI. Non-motile spermatozoa from reprocessed semen may also achieve embryo development after ICSI. To our knowledge, this is the first report evaluating the ability of refrozen spermatozoa to produce embryos by ICSI in any species.     

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.     

Evaluation of chromosomal risk following intracytoplasmic sperm injection in the mouse

To investigate whether cytogenetic risks occur using the mouse intracytoplasmic sperm injection (ICSI) technique, the incidence of chromosome aberrations was compared in one-cell embryos produced by ICSI technique and those by conventional in vitro fertilization (IVF) technique. Spermatozoa were incubated in TYH medium for 1.5-2 h before IVF insemination. For the ICSI technique, spermatozoa were incubated in five different media: TYH, Hepes-buffered TYH (H-TYH), modified CZB (mCZB), Hepes-buffered mCZB (H-mCZB), and PB1 for 0.5 h, 2-2.5 h, and 6 h before injection into metaphase II oocytes. The incidence of IVF embryos with structural chromosome aberrations was 2%, whereas the occurrence of structural chromosome aberrations in ICSI embryos was dependent on the kind of medium and sperm incubation time. When spermatozoa were incubated in TYH medium for 2 h or more, the aberration rates in the resultant ICSI embryos (4%) were not significantly different from that of IVF embryos. However, there was a significant increase in aberration rates in ICSI embryos derived from spermatozoa that were incubated in other culture conditions (6%-28%). In addition, a time-dependent increase in aberration rates was found in ICSI embryos when H-TYH, H-mCZB, and PB1 were used for sperm incubation. There was no significant difference in incidence of aneuploidy between IVF and ICSI embryos. The chromosome analysis results of one-cell embryos were reflected by the performance of postimplantation embryo development. The causal mechanism of chromosome damage in ICSI embryos was discussed in relation to the plasma membrane cholesterol, the acrosome, and in vitro aging of spermatozoa.     

In vitro development of domestic cat embryos following intra-cytoplasmic sperm injection with testicular spermatozoa

The objective was to assess the ability of testicular spermatozoa to fertilize in vitro matured domestic cat oocytes and support blastocyst formation in vitro following intra-cytoplasmic sperm injection (ICSI). After IVM, oocytes were randomly and equally allocated among treatment groups (ICSI with testicular spermatozoa, ICSI with ejaculated spermatozoa, sham ICSI, and control IVF). At 18 h after either injection or insemination, the percentage of fertilized oocytes (per total metaphase II oocytes) was approximately 65% after ICSI with testicular or ejaculated spermatozoa (P > 0.05), which was less (P < 0.05) than control IVF (approximately 90%). On Day 7, the percentage of cleaved embryos (per total metaphase II oocytes) was approximately 60% after ICSI with testicular or ejaculated spermatozoa (P > 0.05), which also was less (P < 0.05) than control IVF (approximately 85%). After ICSI with testicular spermatozoa, the percentage of blastocysts (per total cleaved embryos) was approximately 11.0%, which was less (P < 0.05) than ICSI with ejaculated spermatozoa (approximately 21.0%); the latter was less (P < 0.05) than control IVF (approximately 43.0%). No blastocyst formation was observed after sham ICSI. For the first time in the domestic cat, this study demonstrated the fertilizing ability and developmental potential of intra-testicular spermatozoa delivered directly into intra-ovarian oocytes matured in vitro.     

利用卵胞浆精子注射（ICSI）技术生产转基因小鼠

在掌握小鼠ICSI技术的基础上,进行了ICSI技术生产转基因小鼠的研究。来自成年KM小鼠附睾尾的精子,使用未加抗冻剂的HEPES-CZB溶液,在液氮中冻融1次后,用于本实验。解冻精子与DNA混匀1min后,精子头被显微注射到B6D2F1小鼠成熟卵母细胞质中。精子头与pEGFP-N1环状DNA共注射生产的ICSI受精卵,在CZB溶液中培养至囊胚期时,39.1%(9/23)的囊胚表达GFP基因。精子注射后6h,直接移植ICSI受精卵后,7只妊娠受体一共产仔30只,效率为23.8%(30/126)。Southernblot分析其中16只小鼠发现,3只(18.8%)转基因小鼠同时整合了GFP和Neomycin基因,它们全部来自精子和线性DNA混合的实验组(阳性效率为33.3%,3/9),相反,精子与环状质粒DNA共注射生产的7只ICSI后代中,没有检测到外源基因。转基因小鼠整合的外源基因能够传递给它们后代。结果说明,利用ICSI技术可以高效地生产转基因小鼠,宿主基因组可能更容易整合线性化的外源基因。     

New preservation method for mouse spermatozoa without freezing

The objective of this study was to investigate the preservation of spermatozoa in a simple medium without freezing and to examine the effects of the preserved sperm on fertilization and development after injection into mature mouse oocytes. Mouse spermatozoa were collected from two caudae epididymides of mature B6D2F1 males and stored under various conditions: 1) in KSOMaa medium (potassium simplex optimized medium with amino acids) supplemented with 0, 1, or 4 mg/ml BSA and held at room temperature (RT, 27 degrees C); 2) in KSOMaa medium containing 4 mg/ml BSA (KSOM-BSA) and held at 4 degrees C, RT, or 37 degrees C (CO2 incubator); 3) in KSOM-BSA with osmolarity ranging from 271 to 2000 mOsmol, adjusted by addition of NaCl and held at 4 degrees C; and 4) a two-step preservation system consisting of storage in 800 mOsmol KSOM-BSA for 1 wk at RT followed by storage at -20 degrees C. Preservation of mouse spermatozoa at 4 degrees C in a medium with high osmolarity (700-1000 mOsmol) resulted in the highest frequency of live births after intracytoplasmic sperm injection (ICSI) into mature oocytes. The optimal conditions for preservation of mouse spermatozoa were 800 mOsmol KSOM containing 4 mg/ml BSA and a holding temperature of 4 degrees C. More than 40% of oocytes injected with sperm heads stored under these conditions for 2 mo developed to the morula/blastocyst stage in vitro and 39% of the embryos developed to term after transfer to recipient mice. Our results also indicate that mouse spermatozoa can be stored in 800 mOsmol KSOM-BSA medium at RT for 1 wk and then at -20 degrees C for up to 3 mo and retain their competence for ICSI. These new preservation methods permit extended conservation of viable spermatozoa that are capable of supporting normal embryonic development and the live birth of healthy offspring after ICSI.     

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.     

Cross species fertilization and development investigated by cat sperm injection into mouse oocytes

The use of intracytoplasmic sperm injection (ICSI) in model animals is a powerful approach for the study of species-specific fertilization processes and multiploidy embryogenesis. In this study, we examined the fertilization process in mouse oocytes following injection of a single mouse or cat sperm, two mouse spermatozoa or mouse and cat spermatozoa. These treatments did not affect histone H3K9 acetylation or methylation, although the pattern of DNA methylation differed following the injection of cat sperm. Immunocytochemical staining revealed that sperm chromatin was normally incorporated with female mouse chromatin following any of the four injection scenarios. Furthermore, metaphase was successfully entered to reach a normal two-cell stage, and cell division could even persist to produce blastocyst stage embryos. In addition, both mouse and cat Pou5l and Nanog mRNA were expressed in the hybrid embryos. These results suggest that, although epigenetic modification of DNA is affected by the sperm injection treatment, fertilization and cleavage occur in a non-species-specific manner. In addition, despite abnormal division of the chromosomes, intra- and inter-species ICSI produced embryos that could develop into blastocysts.     

Mouse ICSI with frozen-thawed sperm: the impact of sperm freezing procedure and sperm donor strain

Normal mouse offspring can be obtained from oocytes injected with frozen-thawed spermatozoa without cryoprotection, however, embryo development can be affected by sperm freezing procedure and sperm donor strain. In this study we observed that direct contact of mouse spermatozoa with liquid nitrogen did not affect their ability to activate injected oocytes but severely restricted subsequent in vitro embryo development to blastocyst stage. Tris-EDTA buffer and M2 were also shown to be better sperm freezing extenders than DPBS, allowing higher developmental potential. In addition, differences in embryo development obtained by intracytoplasmic sperm injection (ICSI) with frozen-thawed spermatozoa were observed between hybrid sperm donor strains. Frozen-thawed B6D2F1 spermatozoa provided higher embryo development than sperm cells from C57CBAF1.     

Injection of somatic cell cytoplasm into oocytes before intracytoplasmic sperm injection impairs full-term development and increases placental weight in mice

This study investigated the effects on fertilized embryo development of somatic cytoplasm after its injection into intact mouse oocytes. Mature oocytes collected from female B6D2F1 mice were injected with cumulus cell cytoplasm of different volumes and from different mouse strains (B6D2F1, ICR, and C57BL/6), or with embryonic cytoplasm. After culture for 1 h, B6D2F1 sperm were injected into those oocytes by intracytoplasmic sperm injection (ICSI). The oocytes were examined for pre- and postimplantation developmental competence. Increases in the volume of the somatic cytoplasm from onefold to fourfold resulted in an impairment of blastocyst development and full-term development (28% and 7%, respectively, vs. 96% and 63%, respectively, in the control group; P < 0.01). An increase in the volume of somatic cytoplasm reduced the expression of POU5F1 (more commonly known as OCT4) in expanded blastocysts. The frequency of embryos that developed to the blastocyst stage did not differ when B6D2F1 or ICR somatic cytoplasm was injected, but injection of C57BL/6 somatic cytoplasm induced a two-cell block in embryo development. Injection of the cytoplasm from fertilized embryos did not reduce the frequency of embryos attaining full-term development. Interestingly, somatic cytoplasm significantly increased the placental weight of ICSI embryos, even the injection of onefold cytoplasm (0.20 +/- 0.02 [n = 32] vs. 0.12 +/- 0.02 in the control group [n = 87]; P < 0.01). These findings indicate that the injection of somatic cytoplasm into oocytes before ICSI causes a decrease in preimplantation development, clearly impairs full-term development, and causes placental overgrowth in fertilized embryos. To our knowledge, placental overgrowth phenotypes are only caused by interspecies hybridization and cloning, and in genetically modified mice. Here, we report for the first time that somatic cytoplasm causes abnormal placentas in fertilized embryos. This study suggests that somatic cell cytoplasmic material is one cause of the low rate of full-term development in cloned mammals.     

精子和卵母细胞质量控制对山羊卵胞质内精子注射（ICSI）受精的影响

ABSTRACT Effects of sperm and oocyte quality control on the efficiency of ICSI of in vitro matured goat oocytes were studied in this paper. The results showed that when injected intracytoplasmically, spermatozoa from caput, corpus and cauda epididymidis resulted in similar rates of fertilization, cleavage and morulae/blastocysts, but when injected subzonally, spermatozoa from caput and corpus gave rise to significantly lower rates of fertilization and embryo development than spermatozoa from the cauda epididymidis and ejaculates. When dead spermatozoa collected from semen that had been preserved in different ways were used for ICSI, those dead from liquid storage at 20 degrees C for 24 h gave rise to the best, but those dead from liquid storage at 5 degrees C for 15 days produced the poorest fertilization and embryo development. When spermatozoa were treated with different concentrations of Triton X-100 before ICSI, significantly higher rates of fertilization, cleavage and morulae/blastocysts were obtained with 0.0005% Triton X-100 than with other concentrations and manual immobilization. Oocytes were classified as of good and poor qualities by treatment in hypertonic sucrose solution, and rates of fertilization and embryo development were significantly higher in the good than in the poor oocytes after ICSI. Post-injection activation of oocytes with either A23187 or ionomycin/6-DMAP significantly increased the rates of fertilization, cleavage and morulae/blastocysts after ICSI. It is therefore concluded that (i) epididymal maturation mainly endowed spermatozoa with the capacity to fuse with the egg plasma membrane; (ii) different methods of semen storage caused different impairment of sperm fertilizing capacity; (iii) pre-injection treatment of spermatozoa with proper concentrations of Triton X-100 might be used to replace manual immobilization for ICSI; (iv) oocyte quality was a major factor influencing the efficiency of ICSI; (v) post-injection activation treatment of oocytes improved fertilization and embryo development after ICSI.     

The birth of mice from testicular spermatozoa retrieved from frozen testicular sections

Male gamete cryopreservation has been widely used for both human reproduction and animal breeding. We investigated whether testicular spermatozoa retrieved from frozen testicular sections (10 or 25 mum thick) could support the full-term development of normal progeny. For this purpose, frozen testicular sections were prepared from two genetic backgrounds (BDF1 or B6 GFP transgenic mice), and the functional ability of testicular spermatozoa after preservation for 1 day, 1 mo, and 3 mo was assessed by intracytoplasmic sperm injection (ICSI). Testicular spermatozoa were successfully retrieved from frozen testicular sections for the use of ICSI, regardless of the preservation period. The ICSI technique revealed that oocytes (BDF1 or B6 background) injected with testicular spermatozoa prepared from frozen testicular sections developed into normal progeny, even though the sections had been cryopreserved for 3 mo at -30 degrees C. Approximately 15% and 5% of the embryos preserved for 3 mo developed to full term if the testicular spermatozoa were prepared from the 25- and 10-mum sections, respectively. These results clearly indicate that male gametes can be viably preserved in frozen testicular sections. The technique described herein will allow the preservation of male gametes in the form of a "book" or "file" by mounting the sections on a paper-thin sheet. Furthermore, this technique may be of value in the clinical treatment of severe male infertility, since testicular spermatozoa can easily be found through examination of testicular cross sections rather than by attempts to identify them in testicular cell suspension.     

Factors affecting fertilization of porcine oocytes following intracytoplasmic injection of sperm

The objective of this study was to optimize intracytoplasmic sperm injection (ICSI), and to assess the effects of membrane-damaged sperm on development of porcine oocytes following ICSI. For optimization of development following the ICSI process, sperm injected oocytes were activated 0.5-1.0 hr after ICSI with 1 x 30 micros pulse of 1.2, 1.7, 2.2, and 2.7 kV/cm DC in experiment 1. After 7-days of culture ICSI oocytes activated with [x1]2.2 kV/cm produced more blastocyts ([x2]34.4%, P < 0.05) than other treatment groups. In experiment 2, oocytes were activated with 1 x 30 micros pulse of 2.2 kV/cm at either 0, 1.5, 3, or 6 hr after ICSI. Oocytes activated 1.5 hr after [x3]ICSI yielded more blastocysts (27.6%)[M4] than in other treatments. In experiment 3, sperm were briefly exposed to 0.1% Triton X-100 to induce membrane damage. Live-dead staining of Percoll-sorted untreated spermatozoa (frozen-thawed) used in this study showed that over 96% were "alive" whereas none were "alive" after Triton X-100 treatment. The rate of development to blastocyst of oocytes injected with Triton X-100 treated sperm combined with electrical activation (EA) at 1 x 30 micros pulse of 2.2 kV/cm (EA, 40.0%) was the best, when compared with those injected with untreated sperm plus EA (P < 0.05). In experiment 4, the development rate of oocytes to the blastocyst stage ([x5]32.1%) following injection of a sperm head only was not significantly different from that of oocytes injected with whole sperm (31.0%). In conclusion, we found that an intact membrane and tail structures of pig spermatozoa are not essential for embryo development by ICSI, and furthermore, dead porcine spermatozoa, at an early stage of necrosis caused by plasma membrane damage, support better embryo development than do live non-damaged sperm.     

In vitro production of llama (Lama glama) embryos by intracytoplasmic sperm injection: effect of chemical activation treatments and culture conditions

Assisted reproductive technologies in the llama (Lama glama) are needed to provide alternative methods for the propagation, selection and genetic improvement; however, recovery of adequate quantity and quality of spermatozoa for conventional IVF is problematic. Therefore, an effort was made to adapt the intracytoplasmic sperm injection (ICSI) procedure for the in vitro production of llama embryos. The specific objectives of this study were: (1) to determine in vitro maturation rates of oocytes recovered by transvaginal ultrasound-guided oocyte aspiration (TUGA) or flank laparotomy; (2) to evaluate the effects of activation treatments following ICSI; (3) to evaluate the development of llama ICSI embryos in CR1aa medium or in an oviduct cell co-culture system. Llamas were superstimulated by double dominant follicle reduction followed by oFSH administered in daily descending doses over a 3-day interval. Oocytes were harvested by flank laparotomy or TUGA and matured in vitro for 30 h. Mature oocytes were subjected to ICSI followed by no chemical activation (Treatment A), ionomycin only (Treatment B) or ionomycin/DMAP activation (Treatment C). More oocytes were recovered by flank laparotomy procedure compared with TUGA (94% versus 61%, P<0.05) and a greater number of oocytes harvested by flank laparotomy reached the metaphase-II stage (77% versus 44%, P<0.05). After ICSI, the proportion of cleaved and 4-8-cell stages embryos was significantly greater when injected oocytes were activated with ionomycin/DMAP combination (63% and 38%, respectively, P<0.05). The co-culture of ICSI embryos with llama oviduct epithelial cells resulted in progression to morula (25%) and blastocyst (12%) stages; whereas, all embryos cultured in CR1aa medium arrested at the 8-16-cell developmental stage.     

Preservation of ejaculated mouse spermatozoa from fertile C57BL/6 and infertile Hook1/Hook1 mice collected from the uteri of mated females

Methods routinely used to preserve mouse spermatozoa require that the male be killed to recover spermatozoa from the epididymides. Here we obtained multiple samples of ejaculated spermatozoa from normal fertile C57BL/6 and infertile Hook1/Hook1 (formerly known as azh/azh) mutant males from uteri after mating, thus avoiding termination of the males. Ejaculated sperm were preserved by conventional cryopreservation or by rapid freezing without cryoprotection, and were injected into the oocytes by intracytoplasmic sperm injection (ICSI). The proportions of oocytes that survived, became activated, and developed into two-cell embryos were similar when comparing the two preservation methods in wild-type versus Hook1/Hook1 mice and tested mice versus controls (fresh and rapid-frozen epididymal and fresh ejaculated sperm). Two-cell embryos were transferred into the oviducts of pseudopregnant females, and fetal development was examined at Day 15 of gestation. A total of 39%-54% of transferred embryos produced with preserved ejaculated sperm implanted. Live, normal fetuses (11%-17%) were obtained in all examined groups and from all males included in the study. More implants (71%-82%) and fetuses (28%-31%) were noted in controls. Lower developmental potentials of embryos produced with preserved ejaculated sperm might be due to their capacitation status; the majority of sperm retrieved from the uterus were capacitated. This study bears significance for the maintenance and distribution of novel mouse strains. The method is applicable for all types of mice, including those with male infertility syndromes. The sole requirement is that the male of interest is able to copulate and its ejaculate contains spermatozoa.     

Intracytoplasmic sperm injection of bovine oocytes with stallion spermatozoa

Five experiments were designed to study the fertilizability and development of bovine oocytes fertilized by intracytoplasmic sperm injection (ICSI) with stallion spermatozoa. Experiment 1 determined the time required for pronuclear formation after ICSI. Equine sperm head decondensation began 3 h after ICSI; 42% were decondensed 6 h after ICSI. Male pronuclei (MPN) began to form 12 h after ICSI. Female pronuclei (FPN), however, formed as early as 6 h after ICSI. In Experiment 2, ionomycin, ionomycin plus 6-dimethylaminopurine (DMAP), and thimerosal were used to activate ICSI ova. None of the ICSI ova cleaved after treatment with thimerosal. Ionomycin activation after 24 and 30 h of oocyte maturation resulted in 29 and 48% cleavage rates, respectively. Ionomycin combined with DMAP resulted in 49, 6 and 3% cleavage, morula and blastocyst rates, respectively, when oocytes were activated after 24 h maturation. In Experiment 3, rates of cleavage (45-60%) and development to morulae (4-13%) and blastocysts (1-5%) stages following ICSI were not different (P>0.05) among three stallions. Treatment of stallion spermatozoa with ionomycin did not affect cleavage or development of ova fertilized by ICSI. The chromosomal constitution of blastocysts derived from ICSI was bovine, not bovine and equine hybrids. In Experiment 4, to make male and FPN form synchronously, colchicine and DMAP were used for 4 h to inhibit oocytes at metaphase during activation; 63% of oocytes were still at metaphase 8h after ICSI when treated with colchicine, and 50% of sperm nuclei were decondensed. About 18 h after ICSI, 21 and 50% male and FPN had formed, respectively, but cleavage rates were low, and only 1% developed to morulae. In Experiment 5, to test if capacitated equine sperm could fuse with the bovine oolemma, capacitated spermatozoa were injected subzonally (SUZI). Of the 182 SUZI oocytes, 49 (27%) contained extruded second polar bodies. After activation of oocytes with second polar bodies, 44, 22 and 15% developed to 2-, 4- and 8-cell stages, respectively, but development stopped at the 8-cell stage. None of the unactivated oocytes cleaved. In conclusion, equine spermatozoa can decondense and form MPN in bovine oocytes after ICSI, but subsequent embryonic development is parthenogenetic with only bovine chromosomes being found.     

Birth of normal calves after intracytoplasmic sperm injection of bovine oocytes: a methodological approach

Intracytoplasmic sperm injection (ICSI) is advantageous when only very few spermatozoa are available for insemination. Bovine spermatozoa were injected individually into matured oocytes using a piezo electric actuator. Spermatozoa were "immobilized", by scoring their tails immediately before injection, or "killed", by repeated freezing and thawing. About 4 h after ICSI, the oocytes with two polar bodies (activated by sperm injection) were selected and treated 5 min with 7% ethanol before further culture. When examined 19-21 h after ICSI, nearly 90% of the oocytes were fertilized normally (two pronuclei and two polar bodies) irrespective of the sperm treatment (immobilization or killing) prior to ICSI, but subsequent preimplantation embryo development was much superior (cleavage 72%: blastocysts 20%) after ICSI with immobilized spermatozoa than by using killed spermatozoa (cleavage 28%; blastocysts 1%). Ethanol activation of bovine oocytes with two polar bodies 4 h after ICSI improved the cleavage (33% versus 72%) and blastocyst (12% versus 20%) rates markedly (P < 0.05). Five normal calves were born after transplantation of ten blastocysts to ten surrogate cows. These results show that piezo-ICSI using immobilized spermatozoa, combined with ethanol treatment of sperm-injected oocytes, is an effective method to produce bovine offspring.