Effects of electric stimulation on bovine oocyte activation and embryo development in intracytoplasmic sperm injection procedure

Bovine ICSI: limiting factors, strategies to improve its efficiency and alternative approaches

Intracytoplasmic sperm injection (ICSI) is an assisted reproductive technique mainly used to overcome severe infertility problems associated with the male factor, but in cattle its efficiency is far from optimal. Artificial activation treatments combining ionomycin (Io) with 6-dimethylaminopurine after piezo-ICSI or anisomycin after conventional ICSI have recently increased the blastocyst rate obtained. Compounds to capacitate bovine spermatozoa, such as heparin and methyl-β-cyclodextrin and compounds to destabilize sperm membranes such as NaOH, lysolecithin and Triton X-100, have been assessed, although they have failed to substantially improve post-ICSI embryonic development. Disulfide bond reducing agents, such as dithiothreitol (DTT), dithiobutylamine and reduced glutathione, have been assessed to decondense the hypercondensed head of bovine spermatozoa, the two latter being more efficient than DTT and less harmful. Although piezo-directed ICSI without external activation has generated high fertilization rates and modest rates of early embryo development, other studies have required exogenous activation to improve the results. This manuscript thoroughly reviews the different strategies used in bovine ICSI to improve its efficiency and proposes some alternative approaches, such as the use of extracellular vesicles (EVs) as 'biological methods of oocyte activation' or the incorporation of EVs in the in vitro maturation and/or culture medium as antioxidant defence agents to improve the competence of the ooplasm, as well as a preincubation of the spermatozoa in estrous oviductal fluid to induce physiological capacitation and acrosome reaction before ICSI, and the use of hyaluronate in the sperm immobilization medium.

Intracytoplasmic Sperm Injection in Cattle

Intracytoplasmic sperm injection (ICSI) involves the microinjection of sperm into a matured oocyte. Although this reproductive technology is successfully used in humans and many animal species, the efficiency of this procedure is low in the bovine species mainly due to failed oocyte activation following sperm microinjection. This review discusses various reasons for the low efficiency of ICSI in cattle, potential solutions, and future directions for research in this area, emphasizing the contributions of testis-specific isoforms of Na/K-ATPase (ATP1A4) and phospholipase C zeta (PLC ζ). Improving the efficiency of bovine ICSI would benefit the cattle breeding industries by effectively utilizing semen from elite sires at their earliest possible age.

Microtubule assembly crucial to bovine embryonic development in assisted reproductive technologies

Centrosome integrity and microtubule network are crucial to the events around fertilization, including pronuclear development, migration and fusion, and the first mitotic division. The present review highlights the importance of bull spermatozoal centrosomes to function as a microtubule‐organizing center for successful fertilization and the subsequent embryonic development. Spermatozoal centrosomes need to be blended with ooplasmic pericentriolar materials accurately to nucleate and organize the sperm aster. Dysfunction of the spermatozoal centrosomes is associated with fertilization failure, which has been overcome with supplemental stimuli for oocyte activation following intracytoplasmic sperm injection in humans. Even though the spermatozoal centrosomes are functionally intact, abnormal sperm aster formation was frequently observed in vitrified‐warmed bovine oocytes, with delayed pronuclear development and migration. Treatment of the post‐warm oocytes with Rho‐associated coiled‐coil kinase inhibitor or α‐tocopherol inhibited the incidence of the abnormal aster formation, resulting in higher blastocyst yields following in vitro fertilization and culture. Thus, understanding of centrosomal function made it possible to improve the performance of advanced reproductive technologies.

A preliminary report of successful cleavage after calcium ionophore activation at ICSI in cases with previous arrest at the pronuclear stage

Artificial oocyte activation (AOA) has been previously suggested as a means to overcome the problem of total fertilization failure, which affects about 1-3% of the intracytoplasmic sperm injection (ICSI) cycles. A preliminary study on the application of chemical AOA was conducted using A23187 Ca(2+) ionophore to improve embryonic development in four women with a history of complete fertilization arrest and inability to transit to cleavage stage during previous ICSI trials. Data indicated that activated oocytes resulted in better fertilization, embryonic development and clinical pregnancy in one of the four couples. Therefore, ICSI combined with AOA using Ca(2+) ionophore may be useful in selected patients with cleavage failure, and may help the zygotes to reach more advanced developmental stages.

Effects of sperm pretreatment and embryo activation methods on the development of bovine embryos produced by intracytoplasmic sperm injection

The aim of the study was to examine the effects of different embryo activation methods and sperm pretreatments on the activation and development of bovine embryos produced by intracytoplasmic sperm injection (ICSI). Four activation agents, i.e., calcium ionophore (A23187), ionomycin (Ion), electric pulse (EP) and ethanol (Eth) were used in various combinations to activate bovine ICSI embryos. The normal fertilization rate was similar in bovine ICSI embryos activated by A23187+Eth, Ion+Eth, Ion+EP+Eth, and 2-Ion (Ion administered two times)+Eth. Increasing the frequency of ionomycin stimulation from two (2-Ion+Eth) to three times (3-Ion+Eth) significantly (p<0.05) increased the cell number per embryo at the blastocyst stage. In addition, spermatozoa were pretreated with dithiothreitol (DTT), glutathione (GSH) or GSH+lysolecithin (LL) and used for producing bovine ICSI embryos. The blastocyst rate of bovine ICSI embryos produced from sperm pretreated with GSH was significantly (p<0.05) higher than those of embryos produced from sperm pretreated with DTT and GSH+LL. In conclusion, the embryo activation methods and sperm pretreatments examined in the present study did not affect the normal fertilization rate of bovine ICSI embryos. However, activation with 3-Ion+Eth and sperm pretreatment with GSH increased the cell number per embryo at blastocyst stage and the blastocyst rate, respectively, in bovine ICSI embryos.

Production of female bovine embryos with sex-sorted sperm using intracytoplasmic sperm injection: efficiency and in vitro developmental competence

The production of embryos with a preselected sex sperm is important in the livestock industry. In this study, we examined the efficiency of producing female embryos by intracytoplasmic sperm injection (ICSI) with flow cytometry sorted (ssICSI) and unsorted (usICSI) bovine sperm, and their developmental competence in vitro. For comparison, bovine embryos were also produced by in vitro fertilization (IVF) with sorted (ssIVF) and unsorted (usIVF) bovine sperm. The semen used in this study was from a bull selected for its high fertility and blastocyst developmental competence among four bulls. We first examined and compared pronuclear (PN) formation and cleavage rates of the produced embryos among the treatment groups. Our results demonstrated that PN formation rates (judged by two pronucleus [2PN]) and cleavage rates in ssIVF group (23.1% and 43.6%) were lower than those in the usIVF (71.1% and 71.6%), usICSI (73.1% and 92.8%) and ssICSI (75% and 79.1%) groups, respectively (P < 0.05). Moreover, the blastocyst formation rate in the ssIVF group was less than those in the usIVF, usICSI, and ssICSI groups (2.7% vs. 30.2%, 28.7% and 24.7%, respectively; P < 0.05). Importantly, we reported that the blastocyst formation rate in the ssICSI group was similar to that in the usICSI group, which indicated that ICSI can rescue the damage introduced to sperm by flow cytometry-mediated sex-sorting. Of note, we achieved a blastocyst formation rate in the ssICSI group to be comparable with the usIVF group. We then examined embryo quality by counting the number of normal and apoptotic cells in blastocysts. It was found that, despite the fact that blastocyst formation rate in the ssIVF group was significantly lower than those in the usIVF, usICSI and ssICSI groups, there was no difference in total and apoptotic cell numbers among these groups (P > 0.05). Finally, karyotyping analysis demonstrated that the proportion of female embryos in the ssICSI and ssIVF groups was 100%, whereas it was 58.8% and 57.8% in the usIVF and usICSI groups, respectively. In conclusion, ICSI with flow cytometry sorted bovine sperm provides an alternative approach to produce embryos with predetermined sex.

Electrical activation of rabbit oocytes increases fertilization and embryo development by intracytoplasmic sperm injection using sperm from deceased male

PURPOSE

We investigated the effect of electrical stimulation on rabbit oocyte activation using intracytoplasmic sperm injection (ICSI) to determine whether viable offspring can be produced from deceased rabbit sperm using ICSI.

METHODS

Sperm were collected from a heterozygote GFP male rabbit 5 h after sacrifice and cryopreserved in liquid nitrogen. Mature oocytes were fertilized using ICSI. A series of electrical pulse procedures were used to activate oocytes before and/or after ICSI. Following ICSI, zygotes were cultured in B2 medium for 4 days or transferred into the oviducts of recipient rabbits at the 2- or 4-cell stage.

RESULTS

The blastocyst formation rate was significantly greater in oocytes that received one or two pulses prior to ICSI compared to controls and other electrically stimulated groups. In the single pulse before ICSI group, 23 % of the blastocysts expressed GFP, which was significantly greater than all other groups. However, those that received treatment before and after, or just following ICSI, showed a significant decrease in embryo survival. Finally, embryos from the single pulse before ICSI group were transferred into recipient female rabbits and a full-term kit was successfully delivered.

CONCLUSIONS

One pulse of electrical stimulation prior to sperm injection was an effective method to activate rabbit oocytes for fertilization. Sperm collected from a deceased rabbit is able to produce viable embryos through ISCI that are capable of normal fetal and kit development.

Application study of intracytoplasmic sperm injection for golden hamster and cattle production

This paper describes several technical improvements and our results in hamster intracytoplasmic sperm injection (ICSI), hamster round spermatid injection (ROSI) and bovine ICSI. The hamster is the mammalian species in which ICSI was first tried to produce fertilized oocytes. However, until recently, no live offspring following ICSI have ever been obtained. We reported the birth of live offspring following hamster ICSI. Improved points to success were 1) performing hamster ICSI in a dark room with a small incandescent lamp and manipulating both oocytes and fertilized eggs under microscope with a red light source and 2) injecting sperm heads without acrosomes. Under controlled illumination, the majority of the oocytes injected with acrosomeless sperm heads were fertilized normally, cleaved, and developed into morulae. Nine live offspring (19%) were born by transfer of hamster ICSI-derived embryos. Furthermore, we reported the birth of live offspring following hamster ROSI. About 70% of oocytes injected with round spermatids broken before injection were fertilized normally and about half of them developed to morulae and blastocysts. Three (5%) live young were born by transfer of hamster ROSI-derived embryos. On the other hand, in cattle, the main improvements were 1) injection of spermatozoa immobilized by scoring their tail just before injection into oocytes, and 2) additional ethanol activation 4 h after ICSI. About 70% of oocytes injected were activated 4 h after ICSI, and about 30% of them developed to blastocysts. Twenty-four live calves (39%) were born by non-surgical transfer of ICSI-derived embryos. Those results shows that, at present, live offspring are able to be obtained following hamster ICSI, ROSI and bovine ICSI, but further improvement is required due to higher production efficiency of offspring.

How long do parthenogenetically activated mouse oocytes maintain the ability to accept sperm nuclei as a genetic partner?

PURPOSE

Cytogenetic risk of intracytoplasmic sperm injection (ICSI) after artificial oocyte activation (post-activation ICSI) was evaluated in the mouse.

METHODS

Mouse zygotes were produced by ICSI into eggs at various intervals after parthenogenetic exposure to strontium (Sr) for 30 min. Male pronucleus formation and the chromosome constitution were studied.

RESULTS

Sperm nuclei injected into oocytes within 1 h after Sr exposure (from early through mid-telophase) transformed normally into male pronuclei, and the number of chromosome aberrations did not significantly increase in the resultant zygotes. When sperm nuclei were injected into eggs at intervals beyond 1 h after Sr exposure (from late telophase through the G1 pronuclear stage), the rate of male pronucleus formation was significantly reduced. The incidence of chromosome aberrations increased with time between oocyte activation and ICSI.

CONCLUSIONS

ICSI into oocytes within 1 h after parthenogenetic activation produces cytogenetically competent embryos in the mouse.

Evaluation of activation treatments for blastocyst production and birth of viable calves following bovine intracytoplasmic sperm injection

The objective of this study was to compare the effectiveness of different methods of bovine oocyte activation following intracytoplasmic sperm injection (ICSI) in terms of oocyte cleavage and blastocyst rates, and calf production. Oocytes were harvested, post mortem, from the ovaries of Japanese Black heifers or cows. ICSI was carried out using a piezo-electric actuator. The injected or sham-injected oocytes that were assigned to three activation treatments, each replicated three times, were studied: (1) exposure to 5 microM ionomycin for 5 min (ionomycin); (2) exposure to 5 microM ionomycin for 5 min followed by culture in TCM199 for 3 h and a further 3h culture in 1.9 mM 6-dimethylaminopurine (DMAP-ionomycin+DMAP); (3) exposure to 7% ethanol in TCM199 for 5 min, 4 h after ICSI (ethanol). One or two blastocysts from the ionomycin+DMAP (8 recipients) and ethanol (17 recipients) oocyte activation treatments were non-surgically transferred into Holsteins for the study of calf production. The highest cleavage and blastocyst production rates were observed in the ionomycin+DMAP treatment (83.9% and 40.1%) by the ICSI. These rates were significantly (P<0.05) higher than those for the ionomycin oocyte activation treatment (57.6% and 18.2%) but did not differ from the ethanol treatment (75.6% and 29.4%). In the sham-injected, the highest blastocyst production rates were observed for the ionomycin+DMAP and ethanol treatments (10.7% and 11.3%). Pregnancy and birth rates for blastocysts derived from the ethanol oocyte activation treatment (58.8% and 47.4%) were significantly higher (P<0.05) than those of the ionomycin+DMAP treatment (12.5% and 9.2%). The results showed that post-ICSI oocyte activation with ethanol is more effective than activation with ionomycin alone or with ionomycin+DMAP for the production of viable blastocysts and calves.

Intracytoplasmic injection of spermatozoa and spermatogenic cells: its biology and applications in humans and animals

Intracytoplasmic sperm injection (ICSI) has become the method of choice to overcome male infertility when all other forms of assisted fertilization have failed. Animals in which ICSI has produced normal offspring include many species. Success rate with normal spermatozoa is well above 50% in the mouse but ICSI success rates in other animals have been low, ranging from 0.3 to 16.5%. Mouse ICSI revealed that spermatozoa that cannot participate in normal fertilization can produce normal offspring by ICSI, provided their nuclei are genomically intact. Human ICSI using infertile spermatozoa has been highly successful perhaps because of the intrinsic instability of human sperm plasma membrane. The health of children born after ICSI and other assisted fertilization techniques is of major concern. Careful analyses suggest that higher incidences of congenital malformations and/or low birth weights after assisted fertilization are largely attributable to parental genetic background and increased incidence of multiple births, rather than to the techniques of assisted fertilization. Since the physiological and nutritional environments of developing embryos may cause persisting alteration in DNA methylation, extreme caution must be exercised in handling gametes and embryos in vitro. In the mouse, round spermatid injection (ROSI) has been routinely successful but its use in humans is controversial. Whether human ROSI and assisted fertilization involving younger spermatogenic cells are medically safe must be the subject of further investigations.

Effect of centrifugation and electrical activation on male pronucleus formation and embryonic development of porcine oocytes reconstructed with intracytoplasmic sperm injection

Oocyte centrifugation and electrical activation are commonly used in intracytoplasmic sperm injection (ICSI) of bovine and porcine oocytes, to facilitate visual identification of sperm release into the ooplasm and to support oocyte activation following injection with tail membrane-damaged sperm. The present study evaluated the necessity of these steps in porcine modified ICSI. In the first series of experiments, in vitro-matured gilt oocytes with or without centrifugation were injected with head membrane-damaged spermatozoa aspirated tail first. Oocytes without centrifugation exhibited a significantly higher normal fertilisation rate, defined as male pronucleus (MPN) and female pronucleus (FPN) formation and the presence of two polar bodies, than centrifuged oocytes (40% v. 9%, respectively; P < 0.05). The rate of MPN formation was significantly higher in uncentrifuged oocytes compared with centrifuged oocytes (48% v. 17%, respectively; P < 0.05). The rates of survival, cleavage, blastocyst formation and total cell number in blastocysts did not differ between the two groups of oocytes. Next, the effect of electrical activation after ICSI on uncentrifuged oocytes injected with head membrane-damaged spermatozoa was determined. No significant differences were observed in the rate of MPN formation in sperm-injected oocytes regardless of electrical activation. However, the survival rates of sperm-injected or control oocytes without electrical activation were significantly higher than those of sperm-injected or control oocytes with electrical activation (88% and 84% v. 77% and 64%, respectively; P < 0.05). The cleavage rates of sperm-injected oocytes were significantly higher than those of control oocytes, regardless of electrical activation (77% and 81% v. 47% and 61% in sperm-injected and control oocytes with or without electrical activation, respectively; P < 0.05). Although development to blastocysts was similar in all experimental groups, the total cell numbers in blastocysts from control oocytes were significantly higher than those in sperm-injected oocytes, regardless of electrical activation (40 and 44 v. 22 and 26 in control and sperm-injected oocytes with or without electrical activation, respectively; P < 0.05). In conclusion, the present study clearly demonstrated that oocyte centrifugation before sperm injection is not beneficial to normal fertilisation and that electrical activation is not necessary in the modified porcine ICSI.

Activation with Ethanol Improves Embryo Development of ICSI-Derived Oocytes by Regulation of Kinetics of MPF Activity

Developmental potential of bovine embryos that are not artificially activated after intracytoplasmic sperm injection (ICSI) is generally very low. In this study, we investigated effects of artificial activation with ethanol on kinetics of maturation promoting factor (MPF) activity (p34(cdc2) kinase activity) and development of bovine oocytes following ICSI. Treatment of oocytes with ethanol at 4 h after ICSI improved their first cleavage and further preimplantation development (51% vs. 13%, 14% vs. 4%: treatment with vs. without ethanol, respectively). MPF activity of oocytes was lowered until at least 2 h after ICSI. In oocytes without activation after ICSI, MPF activity temporarily elevated at 6 h after ICSI, whereas this phenomena was not observed in the oocytes treated with ethanol. Furthermore, MPF activity was elevated 20 h after ICSI in oocytes activated with ethanol, whereas this elevation of MPF activity was not shown in oocytes without activation. These results indicate that the stimulus of sperm was sufficient to lower MPF activity of oocytes following ICSI, and moreover the activation treatment of bovine oocytes with ethanol after ICSI served to maintain the low levels of MPF activity until the next cell cycle started.

Bovine embryo development following ICSI: effect of activation, sperm capacitation and pre-treatment with dithiothreitol

The development of bovine embryos obtained by intracytoplasmic sperm injection (ICSI) was studied in relation to various treatments applied to the sperm and to the early embryo. We investigated the effect of different activation protocols on ICSI-embryos and the influence of sperm capacitation with heparin and D-penicillamine, hypotaurine, and epinephrine (PHE) prior to ICSI. Finally, we studied the effect of dithiothreitol (DTT) pre-treatment of sperm or of injected oocytes. The activation of ICSI-embryos by ionomycin (Io)-cycloheximide (CHX) and sperm pre-treatment with heparin in combination with PHE did not increase the developmental capacity of ICSI-embryos. By contrast, the treatment of injected oocytes with 2 mM DTT resulted in increased cleavage and blastocyst rates in the group of non-activated embryos and in acceleration of blastocyst development in the group of activated embryos. Similarly, pre-treatment of sperm with DTT, followed by ICSI and activation, determined an increase of embryo development on Day 7 although the total number of blastocysts recorded on Day 8 was not different from untreated controls. The transfer of 11 ICSI-blastocysts, produced without activation, in six recipients gave rise to two pregnancies of which one went to term with the birth of an healthy calf.

Production of piglets using intracytoplasmic sperm injection (ICSI) with flowcytometrically sorted boar semen and artificially activated oocytes

The purpose of the present study was to develop a protocol for the successful production of piglets employing intracytoplasmic sperm injection (ICSI) with flowcytometrically sexed spermatozoa and artificially activated porcine oocytes. In vitro matured oocytes were fertilized by ICSI using non-sorted frozen/thawed epididymal semen. Oocytes were either activated by CaCl(2), Ca(2+)-ionophore or electrical pulse. Activation and fertilization rates of sperm injected oocytes stimulated by CaCl(2)-injection were significantly higher than those without activation (70.4% versus 45.9%; 49.9% versus 33.2%, respectively; P<0.001). Activation rate of sham injected oocytes increased in parallel (11.2% versus 26.3%, P<0.05), parthenogenetic development remained low (2.8% versus 8%). Co-incubation in Ca(2+)-ionophore did not improve activation rates as compared to non-activated oocytes (44.8% versus 42.5%). Fertilization rate decreased as compared to non-treated sperm injected oocytes (36.8% versus 24.5%, P<0.05). Activation of oocytes with a single electrical pulse resulted in significantly higher activation rates in all groups of oocytes as compared to non-stimulated ones (sperm injected oocytes: 65.6% versus 43.1%, P<0.001; sham injected oocytes: 48.5% versus 5.6%, P<0.001; control oocytes: 50.7% versus 0.0%, P<0.001). Fertilization rates (32.3% versus 48.2%) and parthenogenetic development (0.7% versus 38.9%, 0.0% versus 30.9%, P<0.001) increased significantly in parallel. In addition, in four replicates of flowcytometrically sorted Y-chromosome bearing spermatozoa were injected into in vivo matured oocytes, activated with 1.2 pl of a 30 mM CaCl(2) solution. On average 85.3 fertilized oocytes were transferred surgically into four recipients. Pregnancies delivered a total of 13 male piglets. These are the first piglets born from ICSI with sorted spermatozoa.

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.