Effects of myo-inositol on the in-vitro maturation and subsequent development of mouse oocytes

BACKGROUND: The study aim was to assess whether the incorporation of myo-inositol (MI) into culture medium could improve oocyte maturation in vitro. METHODS AND RESULTS: We performed a controlled prospective study using female ICR strain mice superovulated with pregnant mare's serum gonadotrophins. Cumulus-enclosed germinal vesicle (GV) oocytes were randomly cultured in medium with or without MI supplementation. The kinetics of GV breakdown after 4 h of incubation was significantly higher in oocytes incubated with 30 mmol/l of MI than in controls (P < 0.001). Accordingly, this concentration of MI was used for subsequent experiments. The proportion of metaphase II oocytes achieved after 24 h of culture, their fertilization and cleavage rates were significantly higher in the MI-treated group (P < 0.01, P < 0.05, P < 0.05 respectively). This group also demonstrated significant improvement in postimplantation development after transferring the 2-cell embryos to pseudopregnant mice. Confocal microscopy revealed spontaneous intracellular Ca(2+) oscillations within competent GV oocytes and treatment with MI caused an earlier onset of these Ca(2+) signals. CONCLUSIONS: Our results suggest that MI may affect meiotic progression of mouse GV oocytes possibly by enhancing the intracellular Ca(2+) oscillations. Supplementation of MI in culture medium may be useful for human oocyte maturation.     

Sperm-associated oocyte-activating factor is released from the spermatozoon within 30 minutes after injection as a result of the sperm- oocyte interaction

We have previously shown that sperm plasma membrane damage makes the sperm plasma membrane permeable and the sperm nucleus accessible for low molecular weight molecules such as eosin and dithiothreitol. In the present study, we investigated whether this damage is associated with a passive release of the sperm-associated oocyte activating factor (SAOAF) from the spermatozoon and, if so, its time sequence. In a first study, human oocytes remaining unfertilized after conventional in-vitro fertilization (IVF) or intracytoplasmic sperm injection (ICSI) and freshly ovulated mouse oocytes were injected with a whole spermatozoon or a sperm head respectively. They were randomly allocated to one of three groups: oocytes in group 1 were injected with a spermatozoon immobilized or sperm head detached immediately prior to the injection; oocytes in group 2 were injected with a spermatozoon immobilized or sperm head detached 2-4 h before injection; oocytes in group 3 were injected with a spermatozoon or sperm head that had been subjected to heat treatment. The activation rate of oocytes injected with a spermatozoon or sperm head was the same for groups 1 and 2, and significantly higher than in group 3 (P < 0.001). In a second series of experiments, human oocytes remaining unfertilized after IVF or ICSI were injected with a sperm head that was subsequently removed from the ooplasm 20-30 min after injection. The activation rates were compared to that of oocytes injected with heat-treated spermatozoa which subsequently were removed from the ooplasm. We found that the removal of the spermatozoon 30 min after injection did not prevent oocyte activation. Our data indicate that the initial damage to the sperm plasma membrane induced at immobilization, although essential for the onset of sperm nuclear swelling after ICSI, does not by itself lead to the release of SAOAF from the spermatozoon. We postulate, however, that SAOAF is released during the sperm nuclear swelling phase, which is induced by the so-called sperm nucleus decondensing factor (SNDF) of the oocyte.      

Sperm plasma membrane damage prior to intracytoplasmic sperm injection: a necessary condition for sperm nucleus decondensation

In the present study we investigated the relevance of spermimmobilization prior to intracytoplasmic sperm injection (ICSI)in the fertilization process. Using supravital staining of thespermatozoa with eosin and studying sperm decondensation with2 mM dithiothreitol (DTT) in conditions imitating sperm handlingduring ICSI, we demonstrated that immobilization of the spermatozoonby squeezing its tail between the glass pipette and the bottomof the dish damages the sperm plasma membrane. Polyvinylpyrrolidone(PVP), which is usually present in the drop with the spermatozoonto facilitate its handling, was found to impede the access ofboth eosin and DTT to the sperm nucleus. We conclude that (i)sperm immobilization prior to ICSI damages the sperm plasmamembrane, that (ii) this damage is sufficient for thiol-reducingagents to gain access to the sperm nucleus, and finally that(iii) PVP possibly interferes with sperm nucleus decondensation.     

Easily decapitated spermatozoa defect: a possible cause of unexplained infertility.

We report the first 16 cases of a new sperm abnormality which we call 'easily decapitated spermatozoa defect'. This was discovered during intracytoplasmic sperm injection (ICSI) in couples with unexplained infertility. Semen analysis was normal, but minimal micromanipulation for ICSI resulted in decapitation of the spermatozoon during immobilization. For some oocytes the head and tail were injected separately, in others the intact sperm was injected after minimal immobilization. A fertilization rate of 47.5% was obtained using ICSI. Conventional in-vitro fertilization (IVF) on sibling oocytes (three cases) or in a previous cycle (three cases) resulted in total failure of fertilization. All patients reached the embryo transfer stage and three pregnancies resulted. Findings on electron microscopy in four cases included spermatozoa with degeneration or absence of the basal plate, abnormalities of the proximal centriole and degeneration of the midpiece with a large cytoplasmic droplet. We conclude that an occult sperm abnormality presenting as easily decapitated spermatozoa during ICSI could be a cause of unexplained infertility, as it resulted in total failure of fertilization in conventional IVF. Further research is necessary to investigate this sperm abnormality.     

Preimplantation development of mouse oocytes activated by different levels of human phospholipase C zeta

BACKGROUND: A sperm-specific phospholipase C zeta (PLCzeta) has been shown to trigger Ca(2+) oscillations in mouse and human oocytes and appears to be the sperm factor responsible for activation at fertilization. Previously, complementary RNA (cRNA) injection was used to introduce PLCzeta into oocytes, but it was unclear how much PLCzeta protein is required for development. Here we have injected cRNA encoding luciferase-tagged human PLCzeta (hPLCzeta-luc) into mouse oocytes and established the relationship between hPLCzeta-luc expression, Ca(2+) oscillations and development. METHODS: Mouse oocytes were injected with hPLCzeta-luc cRNA and a fluorescent Ca(2+)dye to monitor hPLCzeta-luc expression and Ca(2+) oscillations, respectively. After inducing diploidy, development in vitro was monitored in hPLCzeta-luc cRNA microinjected oocytes and compared with parallel oocytes activated by incubation in Sr(2+). RESULTS: Repetitive Ca(2+) oscillations and oocyte activation were triggered by hPLCzeta over a wide range of luciferase expression levels. However, subsequent development of embryos to the blastocyst stage was observed only when expression of hPLCzeta-luc was optimized within a specific range. The blastocyst cell number was also affected by the level of hPLCzeta expression. CONCLUSIONS: Human PLCzeta can readily activate mouse oocytes, however, effective development to blastocyst stages is only achieved within a specific window of hPLCzeta-luc protein expression levels.     

Nucleocytoplasmic ratio of fully grown germinal vesicle oocytes is essential for mouse meiotic chromosome segregation and alignment, spindle shape and early embryonic development

BACKGROUND: This study examined the effect of nucleocytoplasmic ratio of fully grown germinal vesicle (GV) oocytes on meiotic chromosome segregation and alignment, spindle shape, Ca(2+) oscillations and capacity of early embryonic development in mouse. METHODS: GV oocytes with reduced volume (equal to 1/5 to 4/5 of an intact oocyte) were made by micromanipulation to remove different amounts of cytoplasm, and then matured and fertilized in vitro. RESULTS: When >1/2 of GV oocyte cytoplasm was removed, the time-course of GV breakdown (GVBD) was delayed and oocyte maturation rate decreased significantly. Abnormal chromosome segregation rate increased if >1/2 of the cytoplasm was removed from the oocyte. Length and structure of meiotic spindle and chromosome alignment were also impaired by the reduction of cytoplasmic volume. Once matured in vitro, the oocytes could undergo Sr(2+)-induced Ca(2+) oscillations and form pronuclei in a manner independent of nucleocytoplasmic ratio, but their ability to develop to 2-cell embryos was affected if >1/2 of their cytoplasm was removed from the GV oocytes. CONCLUSIONS: These results suggest that nucleocytoplasmic ratio is essential for normal meiotic chromosome segregation, spindle formation and chromosome alignment over the metaphase spindle, and development to 2-cell stage, for which 1/2 of the volume of the GV oocyte appears to be a threshold.     

Aetiology of failed and abnormal fertilization after intracytoplasmic sperm injection1

The aim of this study was to determine why oocytes remain unfertilizedor develop three pronuclei after intracytoplasmic sperm injection(ICSI). Unfertilized and abnormally fertilized oocytes werefixed in glutaraldehyde,stained with Hoechst 33342 and examinedby fluorescence microscopy to identify oocyte, sperm and polarbody DNA.One-pronuclear oocytes were considered to be unfertilized.Atotal of 285 unfertilized oocytes were examined (104 ICSI cycles).Overall, 83% of these oocytes were not activated (still at metaphaseII) while 17% had activated and formed a single (female) pronucleus.About 66% of the unfertilized, metaphase II oocytes containeda swollen sperm head, indicating that the oocyte was correctlyinjected but had failed to activate and complete the secondmeiotic division. Premature chromosome condensation of the spermDNA was evident in 6% of these metaphase II oocytes (4% of theunfertilized oocytes). The swollen sperm head was located amongthe oocyte chromosomes in 5%of the metaphase II oocytes. Othercauses of failed fertilization in the metaphase II oocytes werethe failure of sperm head decondensation (11%) and ejectionof the spermatozoon from the oocyte (23%). A similar patternwas observed in one-pronuclear oocytes (52%, swollen sperm head;28%, intact, undecondensed sperm head; 20%, ejection of thespermatozoon), which indicates that asynchronous pronucleardevelopment does not explain the presence of one-pronuclearoocytes. A total of 41 threepronuclear oocytes were examinedand all had a single polar body, which indicates that the retentionof the second polar body leads to the formation of the thirdpronucleus.In conclusion, this study demonstrates that: (i)the major cause of fertilization failure after ICSI is failureof oocyte activation; (ii) ejection of the spermatozoon intothe perivitelline space is not a major cause of fertilizationfailure;and (iii) sperm head decondensation and oocyte activationafter ICSI can occur independently.     

The ability to generate normal Ca(2+) transients in response to spermatozoa develops during the final stages of oocyte growth and maturation

Intracellular Ca(2+) oscillations at fertilization are responsible for triggering egg activation. The aim of this study was to examine the effect of the age of the oocyte donor and in-vitro maturation on the generation of Ca(2+) transients at fertilization. The results show that <10% of in-vivo and in-vitro matured oocytes from 19-day old mice develop to the blastocyst stage in vitro. In contrast, 43% of in-vivo and 25% of in-vitro matured oocytes from 24-day old mice developed to the blastocyst stage. In parallel experiments, intracellular Ca(2+) was monitored at fertilization. Oocytes from 19-day old mice generate significantly fewer transients than oocytes from 24-day old mice. In-vitro maturation significantly decreased the ability of oocytes from 19-day old mice but not 24-day old mice to generate Ca(2+) transients in response to spermatozoa. Furthermore, we investigated the effect of oocyte maturation on Ca(2+) signalling. Immature oocytes generated fewer Ca(2+) oscillations and ceased oscillating earlier than mature oocytes. These studies suggest that the ability to generate Ca(2+) transients in response to spermatozoa increases in the final stages of oocyte development and during oocyte maturation. This may contribute to the acquisition of developmental competence in the final stages of oogenesis.     

Strontium promotes calcium oscillations in mouse meiotic oocytes and early embryos through InsP3 receptors, and requires activation of phospholipase and the synergistic action of InsP3

BACKGROUND: Sr2+ is the most efficient agent for mouse oocyte activation and functions by inducing Ca2+ oscillations. However, its specific mechanism of action remains unknown. Here we investigated the specificity and possible mechanism of Sr2+-induced Ca2+ oscillations in mouse oocytes and early embryos. METHODS: Ca2+ oscillations in oocytes and embryos were measured by ratiometric fluorescence imaging using fura-2AM. The role of phospholipase C (PLC) and inositol trisphosphate (InsP3) receptors in Sr2+-induced Ca2+ oscillations was examined by selective inhibitors. RESULTS: Sr2+ can induce Ca2+ oscillations in both immature and mature oocytes, and in early embryos. A cell cycle stage-dependent phenomenon to Sr2+ stimulation was observed in 1-cell embryos. By using a low molecular weight heparin to antagonize the function of InsP3 receptors, we were able to show that InsP3 receptors are essential for Sr2+-induced Ca2+ oscillations. Treating metaphase II (MII) oocytes with the PLC inhibitor, U73122, abolished Sr2+-induced increases in Ca2+. This inhibitory effect of U73122 could be rescued by microinjection of InsP3, indicating that Sr2+-induced Ca2+ oscillations require the synergistic action of InsP3. CONCLUSIONS: Sr2+-induced calcium oscillations in mouse oocytes and early embryos are mediated through InsP3 receptors, and require PLC activation and the synergistic action of InsP3.     

Does ICSI require acrosomal disruption? An ultrastructural study

BACKGROUND: Aggressive immobilization of sperm prior to ICSI significantly improves fertilization rates, but the mechanism of this effect is not yet clear. This study was performed in order to assess the characteristics of mechanically immobilized human sperm by transmission electron microscope (TEM). METHODS: Sperm obtained from ejaculated semen samples from three different donors were immobilized in a standard manner for ICSI. They were then injected into the perivitelline space of mouse oocytes in order to be able to locate them by TEM. Intact motile sperm injected subzonally served as controls (n=160). Finally, the 'carrier' oocytes were fixed and processed for TEM. RESULTS: A total of 300 sperm were mechanically immobilized and inserted into the perivitelline space of mouse oocytes. Ultrathin sections revealed consistent alterations in the acrosomal region including disruption of the plasma membrane, and disruption, vesiculation or even loss of the acrosome. Thus, all of the sperm assessed had undergone some disorganization of the head, in contrast to a majority of control sperm. CONCLUSIONS: Immobilization of sperm for ICSI by compressing and rolling the sperm tails induces a variable disruption and sometimes loss of the acrosome. This could well be a reason for the higher success rates when ICSI is performed using immobilized sperm.     

Role of protein tyrosine phosphorylation in the thapsigargin-induced intracellular Ca(2+) store depletion during human sperm acrosome reaction

During human sperm capacitation, an increase in phosphotyrosine content of specific proteins results partially from an increase in the intracellular free Ca(2+) concentrations. In the present study, the inter-regulation between protein phosphotyrosine content and the intracellular Ca(2+) concentration during the thapsigargin treatment of capacitated human sperm was investigated. The involvement of a tyrosine kinase pathway in the thapsigargin-induced acrosome reaction was also investigated. In response to thapsigargin, two sperm subpopulations, called LR (low responsive) and HR (high responsive), according to their increase in intracellular Ca(2+), were observed. In addition to their high increase in intracellular Ca(2+), sperm from the HR population expressed a higher protein phosphotyrosine content, and a higher proportion (P < 0.05) of them underwent the acrosome reaction in response to thapsigargin, as compared with LR sperm. Although the tyrosine kinase inhibitor PP2 abolished the thapsigargin-induced increase in protein phosphotyrosine content, it did not affect the intracellular Ca( 2+) concentration or the percentage of acrosome-reacted sperm. The inability of an src-related tyrosine kinase inhibitor to block the thapsigargin-mediated Ca(2+) increase and acrosomal exocytosis suggests that, during the acrosome reaction, the signalling pathway mediated by src-related tyrosine kinases is involved upstream of the capacitative Ca(2+) entry.     

Fertilization and early embryology: Premature chromosome condensation of the sperm nucleus after intracytoplasmic sperm injection

A cytogenetic-cytological study was performed on unfertilizedhuman oocytes (first polar body visible) after intracytoplasmicsperm injection (ICSI) with respect to the rate of prematurelycondensed sperm chromosomes (G₁-PCC). Out of 163 prepared oocytesderived from 41 ICSI cycles, 133 (-82%) could be analysed successfully.A total of 60 oocytes (45.1%) showed metaphase II chromosomesin the haploid range along with an intact sperm head and 27oocytes (20.3%) were missing the sperm head, but two of themshowed an approximately diploid set of chromosomes; 38 oocytes(28.6%) exhibited the maternal metaphase II chromosomes as wellas G₁-PCC of the sperm nucleus showing a remarkable variationin the degree of condensation. Ten ICSI cycles (each followedby an embryo transfer) were characterized each by 2–3oocytes demonstrating G₁-PCC. It is concluded that the maincause of failed fertilization after ICSI is the failure of oocyteactivation. When the sperm nucleus is able to act with the chromosomecondensing factors and the oocyte does not become activated,this will lead to the induction of PCC. Absence of the spermhead might be due to injection or ejection of the spermatozoonin the perivitelline space except for two cases in which fertilizationmight have occurred. Finally, the observation of both a singlechromatin region (n = 6) or two chromatin regions (n = 2) indicatedoocyte activation which, however, was followed by developmentalarrest.     

A novel method for chromosome analysis of human sperm using enucleated mouse oocytes

BACKGROUND: Mouse oocytes can be used in conjunction with intracytoplasmic sperm injection (ICSI) as a technique to permit chromosomal analysis of human sperm. However, chromosomes derived both from the human sperm and the mouse oocyte appear simultaneously following ICSI. The present study focused on evaluating whether or not previously enucleated mouse oocytes are usable for the analysis of human sperm chromosomes. METHODS: The metaphase chromosome-spindle complex was removed from a mouse oocyte. Human sperm from a donor with proven fertility were injected into mouse enucleated oocytes or intact oocytes. The presence of pronuclei in the oocytes was confirmed approximately 7-11 h after ICSI, and the oocytes were then fixed so that the nuclei could be observed as chromosome samples at 15-16 h after ICSI. RESULTS: The formation rate of one pronucleus in enucleated oocytes after ICSI was 93.9% (186/198) while that of two pronuclei in intact oocytes after ICSI was 85.4% (88/103). The appearance rate of metaphase chromosomes of human sperm in the enucleated oocytes, 89.4% (160/179), was significantly higher than that in intact oocytes, 78.7% (74/94) (P = 0.017). CONCLUSIONS: An efficient ICSI method using enucleated mouse oocytes was established to allow the visualization of the human sperm chromosome complement without the risk of confusion with mouse oocyte chromosomes.     

Comparison of Ca2+ and CaMKII responses in IVF and ICSI in the mouse

Novel methods of egg activation in human assisted reproductive technologies and animal somatic cell nuclear transfer are likely to alter the signalling process that occurs during normal fertilization. Intracytoplasmic sperm injection (ICSI) bypasses the normal processes of the acrosome reaction, sperm-egg fusion, and processing of the sperm plasma membrane, as well as alters some parameters of intracellular calcium ([Ca(2+)](i)) dynamics (reported previously by Kurokawa and Fissore (2003)). Herein, we extend these studies to determine if ICSI alters the activity of the Ca(2+)-dependent protein, Ca(2+)/calmodulin-dependent kinase II (CaMKII), which is responsible for the completion of meiosis in vertebrate eggs. After ICSI or in vitro fertilization (IVF), individual mouse eggs were monitored for their relative changes in both [Ca(2+)](i) and CaMKII activity during the first [Ca(2+)](i) rise and a subsequent rise associated with second polar body extrusion. The duration of the first [Ca(2+)](i) rise was greater in ICSI than in IVF, but the amplitude of the rise was transiently higher for IVF than ICSI. However, a similar mean CaMKII activity was observed in both procedures. During polar body extrusion, the amplitude and duration of the Ca(2+) rises were increased by a small amount in ICSI compared with IVF, whereas the CaMKII activities were similar. Thus, compared with IVF, ICSI is not associated with decreased or delayed CaMKII activity in response to these Ca(2+) signals in the mouse.     

Fertilization and embryo development in a mouse ICSI model using human and mouse sperm after immobilization in polyvinylpyrrolidone

BACKGROUND: For human ICSI, sperm are normally immobilized immediately prior to injection. However, there are some situations when only sperm of questionable viability are available. There are few evaluations of fertilization or developmental problems in human or animal models using sperm having known intervals between immobilization and injection. METHODS: Immobilized human sperm were maintained for 1-24 h in 10% polyvinylpyrrolidone (PVP) before injection into mouse oocytes. Mouse sperm heads were similarly maintained in either PVP or a high potassium-containing 'nucleus isolation medium' (NIM) before ICSI and embryo development to the blastocyst stage. RESULTS: Immobilized human sperm activated mouse oocytes comparably to controls even 24 h after immobilization. However, mouse sperm heads showed a decrease in activating ability 6 h after isolation, either in PVP or NIM. A significant reduction in blastocyst development occurred if mouse sperm heads were maintained for even 1 h in PVP. After 6 h, no blastocysts formed, with arrest occurring at the morula stage. NIM provided partial protection for up to 3 h. CONCLUSIONS: Immobilized human sperm maintained oocyte activating activity for 24 h. However, mouse sperm are susceptible to alterations that affect both fertilization and development.     

ICSI-generated mouse zygotes exhibit altered calcium oscillations,inositol 1,4,5-trisphosphate receptor-1 down-regulation,and embryo development

ICSI bypasses not only fusion of the gametes but also a series of signalling events that occur in the sperm prior to and during interaction with the oocyte's vestments. The effect of this altered encounter of the gametes on the fertilization-associated intracellular calcium ([Ca2+]i) oscillations has not been thoroughly investigated. Here, ICSI and IVF were performed using gametes from two mouse strains, B6D2F1 and CD1, and in-vitro development, pattern of [Ca2+]i oscillations and down-regulation of inositol 1,4,5-trisphosphate receptor-1 (IP3R-1) in the produced embryos were compared. ICSI and IVF resulted in comparable rates of activation and pre-implantation development. However, ICSI-generated zygotes cleaved at a slower rate, had lower cell numbers and lower hatching rates. The deleterious effects of ICSI could not be exclusively attributed to the injury by the injection since sham-injected IVF zygotes only exhibited delayed progression to the blastocyst stage. ICSI and IVF induced similar initial [Ca2+]i responses, although ICSI zygotes exhibited shorter durations of [Ca2+]i oscillations and showed diminished degradation of IP3R-1. Importantly, sperm manipulation affected the pattern of oscillations, which further decreased pre-implantation developmental rates. Our results demonstrate that ICSI-induced [Ca2+]i responses are not equivalent to those initiated by IVF and that this may have developmental consequences.     

Healthy births and ongoing pregnancies obtained by preimplantation genetic diagnosis in patients with advanced maternal age and recurrent implantation failure

Preimplantation genetic diagnosis (PGD) and subsequent embryo development was evaluated in 72 couples presenting at our centre for intracytoplasmic sperm injection (ICSI) due to severe male factor. The embryo biopsies were performed in Ca(2+)/Mg(2+)-free medium. These patients were further divided into those with advanced maternal age (AMA, n = 49) and those with recurrent implantation failure (RIF, n = 23). Fluorescence in-situ hybridization (FISH) was carried out on 329 blastomeres (91.3%) with probes for the X, Y, 13, 18 and 21 chromosomes. The chromosomal abnormality rate was 41.3% with no significant difference between the AMA and RIF groups. Aneuploidy accounted for the majority (72.8%) of chromosomal abnormalities. Out of 329 embryos, 84.2% had cleaved after 24 h and 15.1% had arrested. Embryos were transferred in 70 patients and 22 pregnancies were achieved (31.4% with an ongoing pregnancy rate of 28.5%). There were no significant differences between the pregnancy rates of the AMA and RIF groups (32.5 and 30% respectively). Therefore PGD should be offered to patients with AMA and RIF. Furthermore, the use of Ca(2+)/Mg(2+)-free medium during the blastomere biopsy facilitates the procedure, while further embryo cleavage, ongoing pregnancies and healthy births are possible.     

Effect of post-ovulatory age and calcium in the injection medium on the male pronucleus formation and metaphase entry following injection of human spermatozoa into golden hamster oocytes.

The occurrence of parthenogenetic activation is a major hurdle in obtaining sperm chromosome metaphases after heterospecific intracytoplasmic sperm injection (ICSI) of golden hamster oocytes with human spermatozoa. We addressed two potential contributors to parthenogenetic activation namely, post-ovulatory age of the oocyte and Ca2+ content of the injection medium. In serial experiments, hamster oocytes were retrieved at 11.5, 13, 16 and 21 h after the ovulatory dose of human chorionic gonadotrophin (HCG) and microinjected with human spermatozoa suspended alternately in a regular (1.9 mM Ca2+) or a Ca2+-free medium. A progressive decrease in the rates of male pronucleus (MPN) formation and metaphase entry and increase in the rates of parthenogenetic activation without male pronucleus occurred with increasing post-ovulatory age. The favourable influence of Ca2+-free injection medium on the mean rates of MPN and metaphase entry was restricted to the relatively older oocytes (MPN 16 h: 49.5 versus 32.3%, P< 0.008; 21 h: 22.2 versus 11.1%, P< 0.001; metaphase entry 16 h: 36.8 versus 25.1%, P< 0.02; 21 h: 13.3 versus 5.2%, P< 0.01 in the Ca2+-free and regular groups respectively). Our data confirm the increased activation sensitivity with post-ovulatory ageing and its adverse influence on the MPN formation and metaphase entry after heterospecific ICSI of hamster oocytes.     

Oocyte activation and Ca(2+) oscillation-inducing abilities of mouse round/elongated spermatids and the developmental capacities of embryos from spermatid injection

To investigate differences in fertilization mechanisms and the potential clinical use of round/elongated spermatid, we conducted detailed studies of oocyte activation and Ca(2+) oscillation-inducing abilities in these immature sperm cells and compared these abilities against those of mature spermatozoa. When round spermatids from B(6)D(2)F(1) mice were injected, none of the oocytes was activated and no intracellular Ca(2+) ([Ca(2+)](i)) increases were observed. Elongated spermatids could induce activation normally in 87% of injected oocytes, but Ca(2+) oscillation could not be induced at all and most of the oocytes (94%) exhibited only several transient [Ca(2+)](i) rises (transient patterns). Because normal offspring could be obtained when embryos through elongated spermatid injection were transferred to foster mothers, it seems that a normal oscillation pattern of [Ca(2+)](i) is not essential for normal fertilization and embryo development. [Ca(2+)](i) patterns of injected oocytes changed from transient patterns to oscillation patterns while the injected immature sperm cells were maturing to spermatozoa. Dissociations were seen between the timing of appearance of oocyte activation and that of Ca(2+) oscillation-inducing abilities in maturing sperm cells. These dissociations may be due to differences in the thresholds to oocyte activation and Ca(2+) oscillation-inducing factor for inducing oocyte activation and Ca(2+) oscillation.     

Timing of sperm and oocyte nuclear progression after intracytoplasmic sperm injection

We investigated the time course of human oocyte activation afterintracytoplasmic sperm injection (ICSI) by observing the oocytechromosome configuration at different times after injection.One day old human oocytes were injected with spermatozoa andsubjected to cytogenetic analysis at 2, 3, 4 and 5 h after injection.We found that anaphase is initiated in the vast majority ofthe oocytes between 2 and 3 h after injection, and that by 4–5h after injection most of the oocytes have reached the chromatinmass stage. Two distinguishable stages of sperm nucleus transformationwere observed. The first phase — swelling — wasreached within 2 h after the injection and was independent ofoocyte activation. The second phase — the ‘brush’-likestage or decondensed chromatin stage — was found onlyin activated oocytes. Moreover, this stage was not reached beforethe chromatin mass stage (late telophase) of the oocyte. Thesame proportion of metaphase II oocyte chromosome configurationsand unchanged sperm nuclei was found at any given time afterinjection. We conclude that: (i) ICSI allows users to obtainan almost synchronized population of activated oocytes; (ii)anaphase II is initiated in the majority of oocytes not laterthan 2–3 h after injection and telophase II is reached5 h after injection; and (iii) there are two distinguishablephases of sperm nucleus transformation after ICSI: oocyte activationindependentswelling of the sperm head and oocyte activation-dependent chromatindecondensation which is coupled to the beginning of oocyte chromosomedecondensation.