Parthenogenetic mouse blastocysts

Imprinting as Basis for Complex Evolutionary Novelties in Eutherians

The epigenetic phenomenon of genomic imprinting is puzzling. While epigenetic modifications in general are widely known in most species, genomic imprinting in the animal kingdom is restricted to autosomes of therian mammals, mainly eutherians, and to a lesser extent in marsupials. Imprinting causes monoallelic gene expression. It represents functional haploidy of certain alleles while bearing the evolutionary cost of diploidization, which is the need of a complex cellular architecture and the danger of producing aneuploid cells by mitotic and meiotic errors. The parent-of-origin gene expression has stressed many theories. Most prominent theories, such as the kinship (parental conflict) hypothesis for maternally versus paternally derived alleles, explain only partial aspects of imprinting. The implementation of single-cell transcriptome analyses and epigenetic research allowed detailed study of monoallelic expression in a spatial and temporal manner and demonstrated a broader but much more complex and differentiated picture of imprinting. In this review, we summarize all these aspects but argue that imprinting is a functional haploidy that not only allows a better gene dosage control of critical genes but also increased cellular diversity and plasticity. Furthermore, we propose that only the occurrence of allele-specific gene regulation mechanisms allows the appearance of evolutionary novelties such as the placenta and the evolutionary expansion of the eutherian brain.

Hyper-polyploid embryos survive after implantation in mice

Polyploids generated by natural whole genome duplication have served as a dynamic force in vertebrate evolution. As evidence for evolution, polyploid organisms exist generally, however there have been no reports of polyploid organisms in mammals. In mice, polyploid embryos under normal culture conditions normally develop to the blastocyst stage. Nevertheless, most tetraploid embryos degenerate after implantation, indicating that whole genome duplication produces harmful effects on normal development in mice. Most previous research on polyploidy has mainly focused on tetraploid embryos. Analysis of various ploidy outcomes is important to comprehend the effects of polyploidization on embryo development. The purpose of this present study was to discover the extent of the polyploidization effect on implantation and development in post-implantation embryos. This paper describes for the first time an octaploid embryo implanted in mice despite hyper-polyploidization, and indicates that these mammalian embryos have the ability to implant, and even develop, despite the harmfulness of extreme whole genome duplication.

Temporal regulation of prenatal embryonic development by paternal imprinted loci

Paternal imprinted genes (H19 and Gtl2) are pivotal for prenatal embryonic development in mice. Nongrowing oocytes and sperm- or oocyte-originated haploid embryonic stem cells (haESCs) carrying both H19-DMR (differentially DNA-methylated region) and IG (intergenic)-DMR deletions that partially mimic paternal imprinting of H19-Igf2 and Dlk1-Dio3 can be employed as sperm replacement to efficiently support full-term embryonic development. However, how H19-DMR and IG-DMR act together to regulate embryonic development is still largely unknown. Here, using androgenetic haESC (AG-haESC)-mediated semi-cloned (SC) technology, we showed that paternal H19-DMR and IG-DMR are not essential for pre-implantation development of SC embryos generated through injection of AG-haESCs into oocytes. H19-DMR plays critical roles before 12.5 days of gestation while IG-DMR is essential for late-gestation of SC embryos. Interestingly, we found that combined deletions of H19 and H19-DMR can further improve the efficiency of normal development of SC embryos at mid-gestation compared to DKO SC embryos. Transcriptome and histology analyses revealed that H19 and H19-DMR combined deletions rescue the placental defects. Furthermore, we showed that H19, H19-DMR and IG-DMR deletions (TKO) give rise to better prenatal and postnatal embryonic development of SC embryos compared to DKO. Together, our results indicate the temporal regulation of paternal imprinted loci during embryonic development.

Derivation and maintenance of mouse haploid embryonic stem cells

Ploidy represents the number of chromosome sets in a cell. Although gametes have a haploid genome (n), most mammalian cells have diploid genomes (2n). The diploid status of most cells correlates with the number of probable alleles for each autosomal gene and makes it difficult to target these genes via mutagenesis techniques. Here, we describe a 7-week protocol for the derivation of mouse haploid embryonic stem cells (hESCs) from female gametes that also outlines how to maintain the cells once derived. We detail additional procedures that can be used with cell lines obtained from the mouse Haplobank, a biobank of >100,000 individual mouse hESC lines with targeted mutations in 16,970 genes. hESCs can spontaneously diploidize and can be maintained in both haploid and diploid states. Mouse hESCs are genomically and karyotypically stable, are innately immortal and isogenic, and can be derived in an array of differentiated cell types; they are thus highly amenable to genetic screens and to defining molecular connectivity pathways.

An optimized electroporation approach for efficient CRISPR/Cas9 genome editing in murine zygotes

Electroporation of zygotes represents a rapid alternative to the elaborate pronuclear injection procedure for CRISPR/Cas9-mediated genome editing in mice. However, current protocols for electroporation either require the investment in specialized electroporators or corrosive pre-treatment of zygotes which compromises embryo viability. Here, we describe an easily adaptable approach for the introduction of specific mutations in C57BL/6 mice by electroporation of intact zygotes using a common electroporator with synthetic CRISPR/Cas9 components and minimal technical requirement. Direct comparison to conventional pronuclear injection demonstrates significantly reduced physical damage and thus improved embryo development with successful genome editing in up to 100% of living offspring. Hence, our novel approach for Easy Electroporation of Zygotes (EEZy) allows highly efficient generation of CRISPR/Cas9 transgenic mice while reducing the numbers of animals required.

Generation and application of mammalian haploid embryonic stem cells

Haploid cells contain one set of chromosomes and are amenable for genetic analyses. In mammals, haploidy exists only in gametes. An intriguing question is whether haploid cells can be derived from gametes. Recently, by application of haploid cell enrichment using fluorescence-activated cell sorting, stable haploid embryonic stem cells (haESCs) have been successfully derived from oocyte-derived parthenogenetic and sperm-derived androgenetic embryos from several species. Whilst both parthenogenetic and androgenetic (AG)-haESCs enable whole-genome genetic screening at the cellular level, such as screening of drug resistance or disease-related genes, AG-haESCs, after intracytoplasmic injection into oocytes, can also be used to produce alive semi-cloned mice. Nevertheless, one major drawback associated with wild-type AG-haESCs is the very low birth rate of healthy semi-cloned mice. Of interest, after inhibiting the expression of two paternally imprinted genes (H19 and Gtl2) in AG-haESCs by removal of their differentially DNA methylated regions, double-knockout AG-haESCs can efficiently and stably support the generation of healthy semi-cloned pups. Importantly, double-knockout AG-haESCs are feasible for multiple genetic manipulations, followed by efficient generation of semi-cloned mice carrying multiple genetic traits; thus they could be used to validate candidate loci that have been identified in genome-wide association studies of multigenic diseases by generation of mouse models carrying multiple alterations. Of note, by combining a CRISPR-Cas9 library and double-knockout AG-haESCs, semi-cloned mice carrying different mutant genes can be efficiently generated in one step, enabling functional mutagenic screening in mice. HaESCs, therefore, provide a powerful tool for genetic analyses in mammals at both the cellular and organismal levels.

Androgenetic development of X- and Y-chromosome bearing haploid rainbow trout embryos

Haploid fish embryos are important in studies regarding role of the recessive traits during early ontogeny. In fish species with the male heterogamety, androgenetic haploid embryos might be also useful tool in studies concerning role of the sex chromosomes during an embryonic development. Morphologically differentiated X and Y chromosomes have been found in a limited number of fish species including rainbow trout (Oncorhynchus mykiss Walbaum 1792). To evaluate role of the sex chromosomes during rainbow trout embryonic development, survival of the androgenetic haploids in the presence of X or Y sex chromosomes has been examined. Androgenetic haploid rainbow trout were produced by fertilization of X-irradiated eggs with spermatozoa derived from the normal males (XY) and neomales, that is, sex-reversed females (XX) to produce X- and Y-bearing haploids, and all X-bearing haploids, respectively. Survival rates of the androgenetic progenies of normal males and neomales examined during embryogenesis and at hatching did not differ significantly. However, all haploids died within next few days after hatching. Cytogenetic analysis of the androgenetic embryos confirmed their haploid status. Moreover, apart from the intact paternal chromosomes, residues of the irradiated maternal chromosomes observed as chromosome fragments were identified in some of the haploids. Provided results suggested that rainbow trout X and Y chromosomes despite morphological and genetic differences are at the early stage of differentiation and still share genetic information responsible for the proper embryonic development.

Haploid mouse embryonic stem cells: rapid genetic screening and germline transmission

Most animal genomes are diploid, and mammalian development depends on specific adaptations that have evolved secondary to diploidy. Genomic imprinting and dosage compensation restrict haploid development to early embryos. Recently, haploid mammalian development has been reinvestigated since the establishment of haploid embryonic stem cells (ESCs) from mouse embryos. Haploid cells possess one copy of each gene, facilitating the generation of loss-of-function mutations in a single step. Recessive mutations can then be assessed in forward genetic screens. Applications of haploid mammalian cell systems in screens have been illustrated in several recent publications. Haploid ESCs are characterized by a wide developmental potential and can contribute to chimeric embryos and mice. Different strategies for introducing genetic modifications from haploid ESCs into the mouse germline have been further developed. Haploid ESCs therefore introduce new possibilities in mammalian genetics and could offer an unprecedented tool for genome exploration in the future.

Haploid genomes illustrate epigenetic constraints and gene dosage effects in mammals

Sequencing projects have revealed the information of many animal genomes and thereby enabled the exploration of genome evolution. Insights into how genomes have been repeatedly modified provide a basis for understanding evolutionary innovation and the ever increasing complexity of animal developmental programs. Animal genomes are diploid in most cases, suggesting that redundant information in two copies of the genome increases evolutionary fitness. Genomes are well adapted to a diploid state. Changes of ploidy can be accommodated early in development but they rarely permit successful development into adulthood. In mammals, epigenetic mechanisms including imprinting and X inactivation restrict haploid development. These restrictions are relaxed in an early phase of development suggesting that dosage regulation appears less critical. Here we review the recent literature on haploid genomes and dosage effects and try to embed recent findings in an evolutionary perspective.

Ploidy assessment of porcine haploid and diploid parthenogenetic embryos by fluorescent in situ hybridization detecting a chromosome 1-specific sequence, Sus scrofa Mc1 satellite DNA

The aim of the present study was to examine the feasibility of fluorescent in situ hybridization (FISH) for detecting a chromosome 1-specific sequence as a means of assessing the ploidy of porcine parthenotes. In vitro-matured oocytes with the first polar body (PB) were electrically activated; some were treated with cytochalasin B to prevent second PB extrusion (1PB embryos), and the others extruded the second PB (2PB embryos). At the 2-cell stage, one and two FISH signals were detected in each nucleus of 2PB and 1PB embryos, respectively. Almost all cells of blastocysts derived from 1PB embryos retained two signals. In contrast, cells of blastocysts derived from 2PB embryos had two signals. These data demonstrate that FISH analysis allows precise ploidy assessment of porcine parthenogenetic embryos, hence providing a practical means of detecting ploidy transition during parthenogenetic embryogenesis.

Parthenogenesis: does it occur spontaneously in mice?

If parthenogenesis occurred in bisexual organisms, it would produce an excess of females and depress the sex ratio. The phenotypes of female mice, from matings that produce an excess of females, were examined for evidence of the presence of marker genes of paternal origin. All proved to be hybrids of the maternal and paternal strains, thus excluding parthenogenesis as the cause of the low sex ratio.

Remuscularizing failing hearts with tissue engineered myocardium

Supporting or even replacing diseased myocardium with in vitro engineered heart muscle may become a viable option for patients with heart failure. The key to success will be to (1) generate human heart muscle equivalents in vitro, (2) integrate the latter into a failing heart, (3) ensure long-term functional competence of the grafts, and (4) prevent unwanted effects including arrhythmias, inflammation/rejection, and tumor formation. Several promising tissue engineering technologies have already been developed and are presently being tested in animal models. The rapidly evolving field of human stem cell biology has in parallel identified unique cell sources of potential clinical relevance. Somatic cell reprogramming and nontransduced, nonembryonic pluripotent stem cells may be of particular interest to eventually provide patient-specific cells and tissues. Yet, limited cardiac differentiation and cell immaturity still restrict a broad application of any stem cell type in cardiac muscle engineering. Bioreactor technologies, transgenic "optimization," and growth factor, as well as physical conditioning, have been used to address these caveats. This review summarizes different tissue engineering modalities, speculates on potential clinical uses, provides an overview on cell sources that may ultimately facilitate a patient-specific application, and discusses limitations of tissue engineering-based myocardial repair.

Androgenetic embryonic stem cells form neural progenitor cells in vivo and in vitro

Uniparental zygotes with two paternal (androgenetic [AG]) or two maternal (gynogenetic [GG]; parthenogenetic [PG]) genomes are not able to develop into viable offspring but can form blastocysts from which embryonic stem cells (ESCs) can be derived. Although some aspects of the in vitro and in vivo differentiation potential of PG and GG ESCs of several species have been studied, the developmental capacity of AG ESCs is much less clear. Here, we investigate the potential of murine AG ESCs to undergo neural differentiation. We observed that AG ESCs differentiate in vitro into pan-neural progenitor cells (pnPCs) that further give rise to cells that express neuronal- and astroglial-specific markers. Neural progeny of in vitro-differentiated AG ESCs exhibited fidelity of expression of six imprinted genes analyzed, with the exception of Ube3a. Bisulfite sequencing for two imprinting control regions suggested that pnPCs predominantly maintained their methylation pattern. Following blastocyst injection of AG and biparental (normal fertilized [N]) ESCs, we found widespread and evenly distributed contribution of ESC-derived cells in both AG and N chimeric early fetal brains. AG and N ESC-derived cells isolated from chimeric fetal brains by fluorescence-activated cell sorting exhibited similar neurosphere-initiating cell frequencies and neural multilineage differentiation potential. Our results indicate that AG ESC-derived neural progenitor/stem cells do not differ from N neural progenitor/stem cells in their self-renewal and neural multilineage differentiation potential. Disclosure of potential conflicts of interest is found at the end of this article.

Apoptosis in Parthenogenetic Preimplantation Porcine Embryos1

Parthenogenesis (PA) of the oocyte is essential to a number of oocyte- or embryo-related technologies such as intracytoplasmic sperm injection and cloning by nuclear transfer. This study investigated the onset and frequency of apoptosis in PA- porcine embryos and the morphological changes that conform to the general criteria of apoptotic cell death by using a terminal deoxynucleatidyl transferase-mediated deoxyuridine 5-triphosphate nick-end labeling (TUNEL) assay. PA embryos had a higher degree of apoptotic cell death during in vitro culture, a lower cleavage rate (45% vs. 71%), and a lower development rate to the blastocyst stage (16% vs. 29%), relative to in vitro fertilization (IVF). The earliest positive TUNEL signal in the PA embryos was detected on Day 6, 1 day later than that in IVF embryos. Apoptosis in PA embryos increased from 15% of the embryos on Day 6 to 29% on Day 8. The mean level of apoptosis of the PA embryos was statistically higher than that of IVF embryos, except on Day 5. In particular, apoptosis in PA embryos was twice that of IVF embryos on Day 6 (15% vs. 6.7%) and Day 8 (29% vs. 13%). The mean cell number in PA blastocysts was significantly lower than that of IVF blastocysts, whereas the percentage of apoptosis in PA blastocysts was significantly higher than that of IVF blastocysts. There was a high percentage of haploid (62.5%) PA blastocysts. The ploidy may contribute to a high level of apoptosis. These results may help to explain the mechanism of parthenogenetic developmental failure and may lead to methods that will improve parthenogenetic development.

In vitro spontaneous parthenogenetic activation of golden hamster oocytes

Parthenogenetic activation is a major hurdle to be cleared for the examination of the human sperm chromosome after intracytoplasmic injection (ICSI) into golden hamster oocytes. Various factors that affect spontaneous activation of hamster oocytes were, therefore, investigated in this study. We collected cumulus-oocyte complexes (COC) from the oviducts of superovulated females and washed them thoroughly with Ca2+-containing or Ca2+-free TALP-HEPES medium (handling media). We cultured oocytes with intact cumulus or those without cumulus (removed by previous hyaluronidase treatment) in Ca2+-containing or -free m-TALP-3 for 6 or 12 h before examining for their activation. Among the oocytes recovered 17 h post-hCG, 92-94% were parthenogenetically activated by 6 h of in vitro culture. Activation rate in the oocytes collected at 13.5 h post-hCG (53%) was significantly (P < 0.05) lower than that in the oocytes collected 17 h post-hCG (92%), indicating that the spontaneous activation rate increased as the oocytes became older. Both cumulus-intact and cumulus-free oocytes had similar (P > 0.05) activation rates when cultured in vitro, suggesting that hyaluronidase treatment had no effect on the rate of oocyte activation. Omission of Ca2+ from the handling medium also had no effect on the activation of the oocytes. The rate of spontaneous activation of the oocytes cultured in calcium-free medium for 6 (9%) and 12 h (16%) was significantly (P < 0.01) lower than that (94%) of the control oocytes cultured in Ca2+-containing medium, implying a positive influence of Ca2+ on in vitro activation of hamster oocytes. When we cultured the oocytes first in calcium-free medium for 6 h, and then in calcium-containing medium for 6 h, 94% were activated, which is comparable to the rate for oocytes continuously cultured in Ca2+-containing medium. This indicates that the inhibition of hamster oocyte activation in Ca2+-free medium is reversible and can be used to control spontaneous activation of golden hamster oocytes.

Effects of cumulus cells and follicle-stimulating hormone during in vitro maturation on parthenogenetic activation of bovine oocytes

The response to parthenogenetic activation (calcium ionophore A23187) of bovine oocytes after 30 hr of culture in different maturation conditions was evaluated. The activation rates of oocytes in response to 10 mu M A23187 were similar (86% +/- 4 vs. 89% +/- 8) when the oocytes matured with or without cumulus cells were cultured in TCM-199 + 10% fetal calf serum (maturation medium [MM]) alone. However, the activation rates were significantly lower in oocytes matured with than without cumulus cells (48 +/- 10 vs. 79% +/- 16; P < 0.05) when MM was supplemented with 0.5 microgram/ml follicle-stimulating hormone (FSH), 50 micrograms/ml luteinizing hormone (LH), and 1.0 microgram/ml estradiol-1 beta (E2). When oocytes with cumulus cells were cultured in different media, MM along, MM + 0.5 microgram/ml FSH, MM + 50 micrograms/ml LH, MM + 1.0 microgram/ml E2, and MM + all three hormones, the percentages of activated oocytes were 91% +/- 3.52% +/- 14.83% +/- 7, 83% +/- 13, and 54% +/- 7, respectively. Oocytes with or without cumulus cells during culture began to form a pronucleus 5 hr after activation (5% +/- 1 and 7% +/- 1, respectively). Finally, the proteins synthesized by oocytes matured with or without cumulus cells before (3 hr) and after (10 hr) activation was labelled with [35S]methionine for analysis. Before activation, a 47 kD protein complex was produced by cumulus cell-intact oocytes. An active protein synthesis of 60 kD was characteristic for the oocytes with cumulus cells cultured in MM containing 0.5 micrograms/ml FSH. After activation, there was an appearance of proteins at 75 kD and 47 kD in the oocytes with cumulus cells but not in the oocytes without cumulus cells during the maturation period. These results indicate that bovine oocytes matured in vitro have different capacities for parthenogenetic activation depending on the presence or absence of cumulus cells and the presence of FSH in MM during culture.

Parthenogenetic development of activated in vitro matured bovine oocytes

Bovine oocytes matured in vitro for 26 hours were electrically stimulated 1) by a single pulse (Treatment A); 2) by 3 pulses 30 minutes apart (Treatment B); 3) by a single pulse followed by 5 minutes of incubation in the stimulation medium (Treatment C); or 4) by a single pulse at 27 hours of maturation (Treatment D). The oocytes were then cultured for up to 8 days to assess parthenogenetic activation and development. Each electrical stimulation consisted of a 60-mus square wave pulse of 2.5 or 3.6 kV/cm. Treatment A was less effective than the other treatments (P<0.05), activating 47 or 59% of oocytes at 2.5 or 3.6 kV/cm, respectively. However, there were no differences due to voltage nor among the other treatments, which activated 64 to 78% of the oocytes. The cleavage rate, 28 to 38%, was not affected by the activation treatment, but development to the 8-cell stage or beyond was greater after activation with the higher voltage. While the numbers of morulae or blastocysts resulting from any given treatment were too small to support meaningful statistical comparison, the results indicate that bovine parthenogenotes produced in vitro are capable of development to the blastocyst stage.

Influence of male sexual rest and oocyte aging on parthenogenesis frequency in mice: cytogenetic analysis after in vitro fertilization

This study was conducted to evaluate the influence of male sexual rest and oocyte aging on fertilization rate and parthenogenesis frequency after in vitro fertilization of mouse oocytes. We used a comparison between cleavage rates and fertilization rates according to chromosomal analysis of oocytes to estimate the parthenogenesis frequency. Fertilization rate was not impaired by male sexual rest. Parthenogenesis frequency was increased by male sexual rest. This effect was enhanced by a concomitant moderate oocyte aging. It is concluded that cleavage rate could not be considered as a reliable test of fertilization after attempted in vitro fertilization in such conditions.

Activation of mammalian oocytes by a factor obtained from rabbit sperm

In this study a fraction was prepared from rabbit sperm that activated rabbit and mouse oocytes following injection into the cytoplasm. The sperm factor activated oocytes exhibited cortical granule exocytosis, pronuclear formation, and cleavage. The sperm factor was soluble in aqueous solution and was not active extracellularly. Unlike most artificial activation methods that are only effective with aged oocytes, the sperm factor activated recently ovulated oocytes. The factor appears to be a protein or associated with a protein but not an acrosomal protein. Fractions from both mouse and bull sperm did not activate rabbit or mouse oocytes. Their inactivity may be owing to the techniques used to recover the fractions or differences between species in sperm morphology and fertilization processes. These observations support the hypothesis that oocyte activation is induced by a factor within sperm that is released into the cytoplasm of the oocyte at the time of sperm-oocyte fusion.

Acid Tyrode's solution can stimulate parthenogenetic activation of human and mouse oocytes

Fresh and aged (24 hours after ovulation) human oocytes and recently ovulated mouse oocytes may be activated by exposure to acidified Tyrode's solution. No activation of either type of human oocyte was observed after exposure to hyaluronidase or pronase, but significant numbers of fresh mouse oocytes were activated after exposure to pronase but not to chymotrypsin. The implications of these results for the manipulation of human and mouse eggs in vitro are discussed.

Parthenogenesis of human oocytes as a function of vacuum pressure

The effect of different vacuum pressures on the rate of parthenogenesis was studied in 109 cycles of laparoscopic follicle aspiration. A total of 388 follicles was aspirated at settings of vacuum pressure of 100, 75, and 50 mm Hg. Parthenogenesis occurred at the rates of 5.9, 7, and 1%, respectively. The difference between 100 and 50 mm Hg was statistically significant (P less than 0.025). We conclude that the rate of parthenogenesis is influenced by the magnitude of vacuum pressure.

Age dependence of bovine oocyte activation

The ability of bovine oocytes to undergo parthenogenetic activation using either a Ca++-Mg++-H+ ionophore (A23187) or electric shock was investigated, as a prelude to understanding activation potential following nuclear transfer into ooplasm. Oocytes were collected from slaughterhouse ovaries by aspiration of 1-5-mm follicles. The time of placement into maturation medium was noted, and maturational age (time in culture) measured from that point. After exposure to activating conditions eggs were cultured for a further 12-16 hours, fixed, and stained with aceto-orcein. Oocytes that progressed to telophase or pronuclear formation were considered activated. Concentrations of A23187 ranging from 100 pM to 100 microM showed that 1-100 microM levels resulted in 94-100% activation at 30 hours maturation. Frequency of activation differed from controls (no ionophore) at 100 nM (49%; P less than 0.05). With A23187 maximum response occurred between 26 and 30 hours of maturation (77% and 92%, respectively). A short pulse electric shock, capable of causing oocyte membrane fusion, gave similar results relative to maturational age (82% and 90% activation for 26 and 30 hours, respectively). Therefore, maximum response to the two activating stimuli occurred in oocytes at similar maturational ages. Exposure to activating conditions prior to onset of activating ability (18 hours) followed by another exposure at 26 hours showed that the oocytes were still fully able to activate upon reaching maturational activation competence. Because cytochalasin B is present in the medium used for nuclear transfer, oocytes were incubated with cytochalasin B prior to exposure to an activating stimulus. Frequency of activation was similar to the control treatment (61% and 73%). The effect of mechanical stress of cytoplasm removal and replacement by electrofusion on activation was also not significant. Overall, maturational age of the oocyte was the main determinant of activation ability.

Enhancement of ionic currents through voltage-gated channels in the mouse oocyte after fertilization

1. The changes of voltage-gated ion channels in the mouse oocyte after fertilization were investigated under voltage clamp.2. About 60 min after introduction of sperm suspension into the fertilization medium, the amplitude of inward current through Ca(2+)-channels increased, which occurred at anaphase during the second meiotic division. The peak amplitude of the maximum inward current per unit membrane capacity of the oocytes at metaphase was 20+/-3 muA/muF in 50 mM-Sr medium. It was 28+/-8 muA/muF at anaphase, and 32+/-5 muA/muF at telophase. The kinetic properties as well as selectivity among Ca, Sr and Mn ions were not altered after fertilization.3. The outward surge current which was found at the higher membrane potential over +50 mV also increased in amplitude after fertilization, simultaneously with the increase in amplitude of inward current through Ca(2+)-channels. The means and the standard deviations of the surge current per unit membrane capacity at 120 mV were 31+/-8 muA/muF at metaphase, and 48+/-7 muA/muF at telophase. The kinetic properties of the outward surge current were not altered after fertilization.4. Application of colcemid (10(-7) mole/l.) or cytochalasin B (2 x 10(-5) mole/l.) did not prevent the increase in amplitude of both inward current through Ca channels and the outward surge current.5. The membrane currents in N-18 mouse neuroblastoma cells in logarithmic growth phase were examined under voltage clamp. The N-18 neuroblastoma cells possessed the Ca inward current and the delayed outward current. The kinetic properties and the steady-state inactivation of Ca(2+)-channels in N-18 neuroblastoma cells were compared with those in mouse oocytes. It was concluded that they could be regarded as identical between the mouse oocyte and the N-18 neuroblastoma cell.

Cytological events associated with in vitro aged and fertilized rabbit eggs

The morphogenetic events associated with rabbit eggs aged in vitro for 12 to 50 hours prior to mixing with sperm have been examined by light and electron microscopy. After 12 hours in culture, morphological alterations of the meiotic spindle and the cortex of unfertilized eggs were evident. By 24 to 50 hours in culture, unfertilized eggs contained subnuclei, structures which formed when individual and/or groups of meiotic chromosomes dispersed and becmae invested by a double-laminated structure reminiscent of a nuclear envelope. Although most eggs obtained 11.5 to 12 hours after induced ovulation and in vitro fertilized displayed morphogenetic patterns similar to those described for in vivo fertilized ova, some (10%) contained three pronuclei. Many eggs obtained 13 to 15 hours after induced ovulation and subsequently mixed with sperm in vitro appeared to undergo processes of fertilization typical of in vivo fertilized eggs, however, approximately 30% contained subnuclei in association with the male pronucleus. Few eggs (15%) aged 12 hours prior to in vitro fertilization displayed patterns of pronuclear development and association typical of fertilized unaged ova. Subnuclei developed in many of the fertilized ova. Supernumerary sperm nuclei, which did not develop into male pronuclei, were observed in some zygotes. Cleavage of eggs aged 12 hours prior to fertilization was abnormal or retarded. After 24 hours in culture approximately 16% of the eggs fertilized. Seventy percent of the fertilized eggs failed to support the development of a male or female pronucleus.

Parthenogenesis

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The involvement of calcium in the activation of mammalian oocytes

Mouse oocytes with cumulus cells intact were parthenogenetically activated following release from the oviduct into calcium-free medium. The proportion of activated oocytes increased with post ovulatory age both for oocytes initially exposed to calcium-free and calcium-containing medium (control). Apart from oocytes released shortly after ovulation (approximately 1 h) when less than 1% of the oocytes from treated and control were activated, activation was always higher in oocytes incubated in calcium-free medium (p less than 0.001). The omission of magnesium from the medium had no effect on the activation response of oocytes obtained approximately 3 h after ovulation but its absence did increase the activation rate of oocytes of later post ovulatory age (approximately 9 h after ovulation) although it was still lower than that obtained with media devoid of calcium. When the extracellular calcium was replaced by other divalent cations (strontium, barium and manganese) high rates of activation were obtained even at post ovulatory times which produced relatively low rates of activation in calcium-free medium alone. Similar results were obtained when hamster oocytes were exposed to all the aforementioned treatments. It is concluded that calcium plays an essential role in the activation of the mammalian oocyte but the mechanism of its action remains obscure. Further development of oocytes activated by calcium-free treatment was limited and was similar to that of oocytes activated in other ways.

Penetration of the zona-free or intact eggs by foreign spermatozoa and the fertilization of deer mouse eggs in vitro

Zona-free eggs were introduced to fresh or preincubated sperm suspensions and the penetration of eggs by foreign spermatozoa was examined, as evidenced by enlargement of the sperm head and formation of the male pronucleus. It was found that zona-free hamster eggs can be penetrated by guinea-pig, deer mouse and rabbit spermatozoa but zona-free rat, mouse and rabbit eggs cannot be penetrated by guinea-pig spermatozoa. Furthermore, zona-free rat and mouse eggs cannot be penetrated by spermatozoa from two species of deer mice and the Mongolian gerbil. The zona pellucida of a few intact rat eggs can be penetrated by mouse (6%) and by P. leucopus spermatozoa (14%) but enlargement of the sperm head and formation of pronuclei were observed in the former but not in the latter. It seems that (1) sperm capacitation is required for the penetration of zona-free eggs, (2) the attachment of foreign spermatozoa to eggs may indicate their potential ability of penetration in some cases, (3) there is a certain affinity between the vitellus of one species and spermatozoa from another species, (4) the block to the entry of foreign spermatozoa is not only in the zona pellucida but also in the vitelline membrane, (5) zona-free hamster eggs can be penetrated by spermatozoa of six species, (6) mouse spermatozoa can penetrate zona-free eggs of three species, and (7) fertilization of intact P. maniculatus eggs can be achieved in vitro.

The incidence and significance of polynuclear follicles

In the treatment of pelvic disorders, ovarian tissue was surgically removed from 165 patients (divided into four age groups) and examined microscopically. This article presents the incidence of polynuclear follicles and discusses potential signficance of these structures in the histogenesis of the ovarian teratoma.

Ultrastructural observations on rabbit, hamster and mouse eggs following electrical stimulation in vitro

The fine structural changes were studied in the plasma membrane, cortical granules (CGs) and meiotic spindle of rabbit, hamster and mouse eggs in response to electrical stimulation. Eggs were collected 16 to 18 hours after HCG injection, and freed from the cumulus oophorus. They were stimulated in vitro by delivering a single monophasic square wave pulse of 150 V for 1 msec. Stimulated and unstimulated eggs were fixed for fine structural observations 1, 30 and 60 minutes after stimulation. Within one minute of stimulation the microvilli of rabbit eggs were long, branching and had bulbous ends. Umbonate protrusions were also present on their surface. By 30 minutes after stimulation the rabbit eggs lacked microvilli and the perivitelline space with detached vesicles. Degenerating changes were readily noticeable in the microvilli of hamster eggs by 60 minutes. Changes were not noted in the microvilli of stimulated mouse eggs. There were markedly fewer CGs in the hamster and mouse, but not rabbit, eggs by 30 minutes after stimulation, and nearly all of them disappeared in the mouse and hamster eggs by 60 minutes. The density of the CGs in the rabbit was not altered. The meiotic spindle of hamster eggs dissipated within one minute of stimulation, however, the microtubules reappeared by 60 minutes after stimulation. Rotation of the meiotic spindle occurred in the mouse and hamster eggs by 30 minutes after stimulation. In some of the mouse eggs the spindle migrated to the center and the chromosomes were in telophase.

The fine structural development of preimplantation mouse parthenotes

The normality of the preimplantation development of 2-cell to expanded blastocyst stage mouse parthenotes, derived from oocytes activated in vivo, or in vitro, has been assessed at the fine structural level. Major changes in the organization of the cellular organelles, i.e., nucleoli, mitochondria, ribosomes, RER and junctional complexes, follow the same developmental sequences observed in embryos obtained from normally fertilized oocytes. One difference between parthenotes and controls is the scarcity of crystalloid bodies in parthenotes at the blastocyst stage. Because the embryos examined in this study had been cultured in vitro, in a simple salt and albumin medium in the absence of maternal influences, our observations on parthenotes indicate that developmental, preimplantation changes in the subcellular organization of the embryo do not require the continued presence of "maternal" factors or the participation of the paternal genome.

Ultrastructural analysis of artificially activated rabbit eggs

Ultrastructural investigations have been carried out on parthenogenetic rabbit eggs in an effort to elucidate events occurring during artificial activation and their similarity to processes of fertilization and embryogenesis. Rabbit eggs were artificially activated by culturing at 10 degrees C for 24 hours followed by incubation at 37 degrees C for 2 to 24 hours. Examination of eggs immediately after incubation at 10 degrees C for 24 hours indicates that activation is initiated when the chromosomes coalesce to form a reticulum which is either surrounded completely by two parallel membranes or incompletely by cisternae of smooth endoplasmic reticulum. Aggregation of the chromosomes occurs as a result of a reduction in the number of microtubules making up the meiotic spindle. When cold treated ova are subsequently incubated at 37 degrees C a nucleus is formed which moves central where it may participate in the cleavage of the egg. Formation of a second polar body and release of the contents of the cortical granules as reported for inseminated eggs was not found to be a part of activation of the egg by cold treatment. Approximately 95% of the ova cultured at 10 degrees C for 24 hours followed by 37 degrees C for 12 hours were activated, i.e., they possessed a nucleus or they had cleaved. Many of the activated eggs cultured for short periods at 37 degrees C were structurally similar to fertilized ova, with further incubation fragmented eggs and abnormal multicellular stages predominated.