Ultrastructural study on pronuclear development in fertilized eggs from goldfish, Carassius auratus

The formation of male and female pronuclei in physiologically monospermic fertilized eggs of the goldfish, Carassius auratus , has been investigated with transmission electron microscopy. Ultrastructural observations show that at 26°C the transformation of the sperm nucleus takes place very quickly. The sperm nuclear envelope degenerates and is replaced by a large number of smooth surface vesicles 1 min post-insemination. Concomitantly, most of the condensed sperm chromatin is dispersed and is surrounded by vesicles. Dispersion of the chromatin is followed by the fusion of vesicles and the formation of a new bilaminar pronuclear envelope. Within 5–10 min post-insemination, a spheroid male pronucleus with intranuclear annulate lamellae is produced. The formation of a female pronucleus is slightly different to that of the male pronucleus. The dispersing chromatin of the egg is divided into many groups, most of which are surrounded by multilaminar envelopes 5 min post-insemination. An ellipsoid female pronucleus with a continuous bilaminar pronuclear envelope and intranuclear annulate lamellae is formed 15 min post-insemination. Subsequently, the two pronuclei migrate towards one another. When the fully developed male and female pronuclei are located in the center of the blastodisc, each changes itself into a saccular complex 25 min post-insemination.     

The Drosophila maternal gene sésame is required for sperm chromatin remodeling at fertilization

The spermatozoon features an extremely condensed and inactive nucleus. The unique sperm chromatin organization is acquired during the late stages of spermatid differentiation by the replacement of somatic histones with sperm-specific chromosomal proteins. At fertilization, the inactive sperm nucleus must be rapidly transformed into a DNA replication competent male pronucleus before the formation of the zygote. The sequential events of this crucial process are well conserved among animals and are controlled by molecules present in the egg. We have previously identified a Drosophila maternal effect mutation called sésame, which specifically arrests male pronucleus formation at a late stage of chromatin decondensation. In this study, we show that sésame affects maternal histone incorporation in the male pronucleus, a situation that is expected to prevent nucleosomal organization of the paternal chromatin. As an apparent consequence, the male pronucleus is arrested before the first S-phase and does not condense mitotic chromosomes. However, centromeric heterochromatin is present on paternal centromeres, which occasionally interact with microtubules. The abnormal chromatin organization of the male pronucleus does not prevent the formation of a male pronuclear envelope, which breaks down and reassembles in synchrony with maternally derived nuclei present in the same cytoplasm.     

The maternal effect mutation sésame affects the formation of the male pronucleus in Drosophila melanogaster

After entering the oocyte and before the formation of the diploid zygote, the sperm nucleus is transformed into a male pronucleus, a process that involves a series of conserved steps in sexually reproducing animals. Notably, a major modification of the male gamete lies in the decondensation of the highly compact sperm chromatin. We present here the phenotype of sésame (ssm), a maternal effect mutation which affects the formation of the male pronucleus in Drosophila melanogaster. Homozygous ssm(185b) females produce haploid embryos which develop with only the maternally derived chromosomes. These haploid embryos die at the end of embryogenesis. Cytological analyses of the fertilization in eggs laid by ssm(185b) mutant females showed that both pronuclear migration and pronuclear apposition occurred normally. However, a dramatic alteration of the male pronucleus by which its chromatin failed to fully decondense was systematically observed. Consequently, the affected male pronucleus does not enter the first mitotic spindle, which is organized around only the maternally derived chromosomes. Immunodetection of lamina antigens indicates that a male pronuclear envelope is able to form around the partially decondensed paternal chromatin. This suggests that the maternally provided sésame(+) function is required for a late stage of sperm chromatin remodeling.     

Breakdown of the sperm nuclear envelope is a prerequisite for male pronucleus formation: direct evidence from the gynogenetic crucian carp Carassius auratus langsdorfii

The gynogenetic fish, Carassius auratus langsdorfii (the ginbuna, a crucian carp), provides an interesting model for the study of the mechanisms controlling male pronucleus formation. When the sperm nucleus of a different subspecies (C. a. cuvieri) is incorporated into the gynogenetic egg, the nuclear envelope of the spermatozoon is not broken down, and the pronucleus fails to develop, although dispersion of the sperm chromatin occurs to some extent within the space limited by the nuclear envelope. When spermatozoa without plasma membranes and nuclear envelopes were microinjected into mature activated eggs, the sperm nuclei underwent chromatin dispersion, nuclear envelope formation, DNA synthesis, and transformation into male pronuclei. These results indicate that the failure of the male pronucleus to form in ginbuna is primarily due to the failure of sperm nuclear envelope breakdown. We conclude that sperm nuclear envelope breakdown is an indispensable step for the development of the male pronucleus.     

Nascent protein requirement for completion of meiotic maturation and pronuclear development: examination of fertilized and A-23187-activated surf clam (Spisula solidissima) eggs

The involvement of newly synthesized proteins and calcium in meiotic processes, sperm nuclear transformations, and pronuclear development was examined in emetine-treated, fertilized, and A-23187-activated Spisula eggs by observing changes in the morphogenesis of the maternal and paternal chromatin. Emetine treatment (50 micrograms/ml) initiated 30 min before fertilization or A-23187 activation inhibited incorporation of [3H]leucine into TCA-precipitable material and blocked second polar body formation. Sperm incorporation and the initial enlargement of the sperm nucleus were unaffected; however, the dramatic enlargement and transformation of the sperm nucleus into a male pronucleus, which normally follow polar body formation, were delayed 10 to 20 min. Unlike the situation in untreated, control eggs, male pronuclear development took place while the maternally derived chromosomes remained condensed. It was not until approximately 20 min after the normal period of pronuclear development that the maternal chromosomes dispersed and formed a female pronucleus in emetine-treated, fertilized eggs. Formation of pronuclei, however, was unaffected in both emetine-treated, A-23187-activated eggs and fertilized eggs incubated with A-23187. These observations indicate that germinal vesicle breakdown, first polar body formation, and initial transformations of the sperm nucleus are independent of newly synthesized proteins. Inhibition of second polar body formation and the delay in pronuclear development brought about by emetine, as well as the appearance of silver grains over pronuclei in autoradiographs of control eggs incubated with [3H]leucine demonstrate that nascent proteins are involved with the completion of meiotic maturation and the development of male and female pronuclei. The ability of A-23187 to override the inhibitory effects of emetine on pronuclear development suggests that both nascent protein and calcium signals are involved in regulating the status of the maternal and paternal chromatin during pronuclear development.     

Ultrastructural aspects of in vivo fertilization in the cow

In vivo fertilization of cow eggs has been studied by electron microscopy. Eggs were recovered from intracervically inseminated heifers 30 to 42 hr after the onset of oestrus. The corona cells remained attached to 4 out of the 15 eggs studied, but no sign of sperm phagocytosis was noted. Spermatozoa close to the zona pellucida, but not in contact with it, were not acrosome reacted. In contrast, all sperm penetrating the zona pellucida had completed the acrosome reaction. Vesiculated products of the reaction were present at the zona surface of every penetrated egg, indicating that in this species, the acrosome reaction occurs at the surface of the zona pellucida. During sperm passage through the zona pellucida, the equatorial segment overlaid by its plasma membrane remained intact. Soon after penetration into the ooplasm, the sperm nucleus decondensed; at the same time, the female chromosomes resulting from the second meiotic division aggregated in a few masses of condensed chromatin. A nuclear envelope started to form around the condensed female chromatin, while it was not yet present around the decondensing male nucleus. After swelling, the two pronuclei presented similar ultrastructural morphology; they contained small, compact, agranular nucleoli with a large fibrillar center and unevenly distributed chromatin. The pronuclear envelope contained pores and presented characteristic blebbing. The endoplasmic reticulum was closely apposed to the nuclear envelope and large Golgi structures were proximal to the pronuclei.     

Chromatin and microtubule organisation in maturing and pre-activated porcine oocytes following intracytoplasmic sperm injection

Chromatin and microtubule organisation was determined in maturing and activated porcine oocytes following intracytoplasmic sperm injection in order to obtain insights into the nature of sperm chromatin decondensation and microtubule nucleation activity. Sperm chromatin was slightly decondensed at 8 h following injection into germinal vesicle stage oocytes. Sperm-derived microtubules were not seen in these oocytes. Following injection into metaphase I (MI)-stage oocytes, sperm chromatin went to metaphase in most cases. A meiotic-like spindle was seen in the sperm metaphase chromatin. In a few MI-stage oocytes, sperm chromatin decondensed at 8 h after injection, and a small sperm aster was seen. Sperm injection into oocytes at 5 h following activation failed to yield pronuclear formation. Maternally derived microtubules were organised near the female chromatin in these oocytes, and seemed to move condensed male chromatin closer to the female pronucleus. At 18 h after sperm injection into pre-activated oocytes, a condensed sperm nucleus was located in close proximity to the female pronucleus. These results suggest that the sperm nuclear decondensing activity and microtubule nucleation abilities of the male centrosome are cell cycle dependent. In the absence of a functional male centrosome, microtubules of female origin take over the role of microtubule nucleation for nuclear movement.     

Ultraviolet irradiation of tilapia spermatozoa and the Hertwig effect: electron microscopic analysis

Electron microscopic analysis of U V-irradiated tilapia sperm showed that with irradiation dose of 1800 J m⁻² min⁻¹, an irradiation duration of 0.5 min caused decondensation of sperm chromatin. This phenomenon of chromatin decondensation reached a peak after l.5min of irradiation, where ∼ 15% of the sperm showed total decondensation, and was less apparent after 3 min of irradiation or more. Damage to the cytoplasmic membrane and nuclear envelope could be seen in cells that underwent total decondensation. As the duration of irradiation increased, cytoplasmic membrane and nuclear envelope defects appeared more severe, the mitochondria were affected and appeared as empty capsules, and sperm cells tended to lose their tails. Based on these results and others reported in the literature, we propose an explanation for the 'Hertwig curve' obtained in tilapia using UV irradiation. Sperm cells with decondensed chromatin and damaged cytoplasmic membrane and nuclear envelope, activate the 'developmental switch' when they penetrate the egg, but their pronuclei are subjected to cytoplasmic nuclease digestion. Consequently, the maternal pronucleus is the only functional pronucleus in the zygote, and therefore, only haploid embryos with the exclusive maternal genome are formed. If the paternal pronucleus is not digested, these embryos will die due to improper expression of the paternal genes.     

Pronuclear formation in starfish eggs inseminated at different stages of meiotic maturation: correlation of sperm nuclear transformations and activity of the maternal chromatin

Changes in sperm nuclei incorporated into starfish, Asterina miniata, eggs inseminated at different stages of meiosis have been correlated with the progression of meiotic maturation. A single, uniform rate of sperm expansion characterized eggs inseminated at the completion of meiosis. In oocytes inseminated at metaphase I and II the sperm nucleus underwent an initial expansion at a rate comparable to that seen in eggs inseminated at the pronuclear stage. However, in oocytes inseminated at metaphase I, the sperm nucleus ceased expanding by meiosis II and condensed into chromosomes which persisted until the completion of meiotic maturation. Concomitant with the formation and expansion of the female pronucleus, sperm chromatin of oocytes inseminated at metaphase I enlarged and developed into male pronuclei. Condensation of the initially expanded sperm nucleus in oocytes inseminated at metaphase II was not observed. Instead, the enlarged sperm nucleus underwent a dramatic increase in expansion commensurate with that taking place with the maternal chromatin to form a female pronucleus. Fusion of the relatively large female pronucleus and a much smaller male pronucleus was observed in eggs fertilized at the completion of meiotic maturation. In oocytes inseminated at metaphase I and II, the male and female pronuclei, which were similar in size, migrated into juxtaposition, and as separate structures underwent prophase. The chromosomes in each pronucleus condensed, intermixed, and became aligned on the metaphase palate of the mitotic spindle in preparation for the first cleavage division. These observations demonstrate that the time of insemination with respect to the stage of meiotic maturation has a significant effect on sperm nuclear transformations and pronuclear morphogenesis.     

Experimental hybridization among Oryzias species. II. Karyogamy and abnormality of chromosome separation in the cleavage of interspecific hybrids between Oryzias latipes and O. javanicus

In interspecific hybridization between Oryzias latipes and O. javanicus, all hybrid embryos failed to develop and died before hatching. Cytological examination of fertilization and early development was performed to discover the cause of lethal development. When O. latipes eggs were inseminated by sperm of O. javanicus, the cortical reaction was induced normally. Chromosomal material in the fertilized eggs was visualized using the DNA-specific fluorochrome Hoechst. The spermatozoon was capable of penetrating into the egg cytoplasm through the micropyle, and the sperm nucleus transformed to the male pronucleus. The female pronucleus that formed after extrusion of the second polar body migrated towards the male pronucleus. The female and the male pronuclei underwent DNA synthesis and encountered each other in the center of the blastodisc, fused with one another and formed a zygote nucleus before breakdown of the nuclear envelope. Metaphase chromosomes with electron dense chromatin regions were abnormally divided into each blastomere in cleavage. The abnormally separating chromatin masses were also labeled by BrdU. The abnormal separation resulting in partial loss of fragmented chromatin might be a cause of abortive development in the interspecific hybrids between O. latipes and O. javanicus.     

Transmission of modified nucleosomes from the mouse male germline to the zygote and subsequent remodeling of paternal chromatin

Rapidly after gamete fusion, the sperm nucleus loses its specific chromatin conformation and the DNA is repopulated with maternally derived nucleosomes. We evaluated the nature of paternally derived nucleosomes and the dynamics of sperm chromatin remodeling in the zygote directly after gamete fusion. We observed histone H4 acetylated at K8 or K12 already prior to full decondensation of the sperm nucleus, suggesting that these marks are transmitted by the spermatozoon. Tracking down the origin of H4K8ac and H4K12ac during spermiogenesis revealed the retention of nucleosomes with these modifications in the chromocenter of elongating spermatids. We show that sperm constitutive heterochromatin is enriched for nucleosomes carrying specific histone modifications which are transmitted to the zygote. Our results suggest an epigenetic mechanism for inheritance of chromosomal architecture. Furthermore, up to pronucleus formation, histone acetylation and phosphorylation build up in a cascade-like fashion in the paternal chromatin. After formation of the pronucleus, a subset of these marks is removed from the heterochromatin, which suggests a reestablishment of the euchromatin-heterochromatin partition.     

Remodeling the sperm nucleus into a male pronucleus at fertilization

After fertilization, the dormant sperm nucleus undergoes morphological and biochemical transformations leading to the development of a functional nucleus, the male pronucleus. We have investigated the formation of the male pronucleus in a cell-free system consisting of permeabilized sea urchin sperm nuclei incubated in fertilized sea urchin egg extract containing membrane vesicles. The first sperm nuclear alteration in vitro is the disassembly of the sperm nuclear lamina as a result of lamin phosphorylation mediated by egg protein kinase C. The conical sperm nucleus decondenses into a spherical pronucleus in an ATP-dependent manner. The new nuclear envelope (NE) forms by ATP-dependent binding of vesicles to chromatin and GTP-dependent fusion of vesicles to each other. Three cytoplasmic membrane vesicle fractions with distinct biochemical, chromatin-binding and fusion properties, are required for pronuclear envelope assembly. Binding of each fraction to chromatin requires two detergent-resistant lipophilic structures at each pole of the sperm nucleus, which are incorporated into the NE by membrane fusion. Targeting of the bulk of NE vesicles to chromatin is mediated by a lamin B receptor (LBR)-like integral membrane protein. The last step of male pronuclear formation involves nuclear swelling. Nuclear swelling is associated with import of soluble lamin B into the nucleus and growth of the nuclear envelope by fusion of additional vesicles. In the nucleus, lamin B associates with LBR, which apparently tethers the NE to the lamina. Thus male pronuclear envelope assembly in vitro involves a highly ordered series of events. These events are similar to those characterizing the remodeling of somatic and embryonic nuclei transplanted into oocytes. The relationship between sperm nuclear remodeling at fertilization and nuclear remodeling after nuclear transplantation is discussed.     

Dynamics of paternal chromatin changes in live one-cell mouse embryo after natural fertilization

Using video-enhanced fluorescence microscopy, we describe in live mouse zygotes the paternal chromatin changes undergone after fertilization. We focus on the sperm recondensation process and the formation of the paternal pronucleus, in relationship with the progression of maternal chromatin. Chromatin is labeled with the vital fluorophore Hoechst 33342. Our conditions of dye concentration and irradiation allow a continuous following of the dynamics of changes without major perturbation. We combine these observations with ultrastructural analysis performed by electron microscopy of the same eggs fixed at chosen stages. We show that the highly recondensed state corresponds to the appearance of the nuclear envelope and therefore the beginning of the pronuclear stage.     

Derivation of the membrane comprising the male pronuclear envelope in inseminated sea urchin eggs

Investigations were conducted in an effort to determine the origin of the membrane comprising the male pronuclear envelope of inseminated sea urchin eggs. The events of fertilization in zygotes treated with 200 μg/ml of puromycin are not impaired even though incorporation of [³H]leucine is inhibited up to 80% when compared to control specimens. Developing male pronuclei in zygotes treated with puromycin form nuclear envelopes structurally similar to and within the same period as controls. In puromycin-treated and untreated zygotes morphologically recognizable portions of the sperm nuclear envelope are incorporated into the structure of the male pronuclear envelope. Pronuclear development was also examined in inseminated ova where most of the endoplasmic reticulum (ER) was confined to a specific area of the zygote. Eggs were centrifuged in order to stratify their organelles into specific layers (stratified eggs); with further centrifugation stratified eggs are bisected to form nucleate (rich in ER) and nonnucleate halves (containing little ER). Observations of inseminated stratified eggs and nucleate and nonnucleate halves demonstrate an inverse relation between the amount of ER present in the vicinity of a reorganizing sperm nucleus and the time it takes to form the male pronuclear envelope. Computation of the maximum quantity of membrane in the male pronucleus that may be derived from the sperm nuclear envelope is approximately 15%. These investigations suggest that a major portion of the male pronuclear envelope is derived from endoplasmic reticulum within the egg and only a small portion (up to 15%) originates from the sperm nuclear envelope.     

THE FINE STRUCTURE OF PRONUCLEAR DEVELOPMENT AND FUSION IN THE SEA URCHIN, ARBACIA PUNCTULATA

Fertilization events following coalescence of the gamete plasma membranes and culminating in the formation of the zygote nucleus were investigated by light and electron microscopy in the sea urchin, Arbacia punctulata. Shortly after the spermatozoon passes through the fertilization cone, it rotates approximately 180° and comes to rest lateral to its point of entrance. Concomitantly, the nonperforated nuclear envelope of the sperm nucleus undergoes degeneration followed by dispersal of the sperm chromatin and development of the pronuclear envelope. During this reorganization of the sperm nucleus, the sperm aster is formed. The latter is composed of ooplasmic lamellar structures and fasciles of microtubules. The male pronucleus, sperm mitochondrion, and flagellum accompany the sperm aster during its migration. As the pronuclei encounter one another, the surface of the female pronucleus proximal to the advancing male pronucleus becomes highly convoluted. Subsequently, the formation of the zygote nucleus commences with the fusion of the outer and the inner membranes of the pronuclear envelopes, thereby producing a small internuclear bridge and one continuous, perforated zygote nuclear envelope.     

Configuration of maternal and paternal chromatin and pertaining microtubules in human oocytes failing to fertilize after intracytoplasmic sperm injection

The microtubules and chromosomes of 180 human oocytes failing to fertilize after intracytoplasmic sperm injection were observed in order to establish how sperm chromatin and sperm astral microtubule configuration is related to the phases of oocyte cell cycle, and to find the defects in those structures causing fertilization arrest. As many as 125 (69%) oocytes were arrested at metaphase II. In one-fourth of them, damages of the second meiotic spindle were noted. In their cytoplasm intact sperm were found in 38 (30%) cases, a swollen sperm head in 36 (29%) and prematurely condensed sperm chromosomes (G1-PCC)-a result of active mitosis promoting factor (MPF)-in 51 (41%) cases. G1-PCC were mostly (73%) surrounded by the bipolar paternal spindle instead of astral microtubules. A male pronucleus was never presented in metaphase II oocytes. In 19 (11%) oocytes, arrested at anaphase II, no intact sperm were found. As many as 9 (47%) oocytes contained sperm in G1-PCC form, which proves that anaphase II oocytes mostly retain active MPF, despite oocyte activation. As many as 78% of 36 monopronucleate oocytes contained sperm, with delay in the process of sperm nucleus decondensation. Sperm in G1-PCC form and a bipolar paternal spindle were never found in monopronucleate oocytes. From this we conclude that sperm that does not activate the oocyte may continue decondensing the chromatin, but the oocyte prevents male pronucleus formation before the female one, mostly by causing PCC in the sperm and by duplicating the sperm centrosome. Mol. Reprod. Dev. 55:197-204, 2000.     

Transformation of sperm nuclei to metaphase chromosomes in the cytoplasm of maturing oocytes of the mouse

Zona-free oocytes of the mouse were inseminated at prometaphase I or metaphase I of meiotic maturation in vitro, and the behavior of the sperm nuclei within the oocyte cytoplasm was examined. If the oocytes were penetrated by up to three sperm, maturation continued during subsequent incubation and became arrested at metaphase II. Meanwhile, each sperm nucleus underwent the following changes. First, the chromatin became slightly dispersed. By 6 h after insemination, this dispersed chromatin had become coalesced into a small mass, from which short chromosomal arms later became projected. Between 12 and 18 h after insemination, each mass of chromatin became resolved into 20 discrete metaphase chromosomes. In contrast, if oocytes were penetrated by four to six sperm, oocyte meiosis was arrested at metaphase I, and each sperm nucleus was transformed into a small mass of chromatin rather than into metaphase chromosomes. If oocytes were penetrated by more than six sperm, the maternal chromosomes became either decondensed or pycnotic, and the sperm nuclei were transformed into larger masses of chromatin. As control experiments, immature and fully mature metaphase II oocytes were inseminated. In the immature oocytes, which were kept immature by exposure to dibutyryl cyclic AMP, no morphological changes in the sperm nucleus were observed. On the other hand, in the fully mature oocytes, which were activated by sperm penetration, the sperm nucleus was transformed into the male pronucleus. Therefore, the cytoplasm of the maturing oocyte develops an activity that can transform the highly condensed chromatin of the sperm into metaphase chromosomes. However, the capacity of an oocyte is limited, such that it can transform a maximum of three sperm nuclei into metaphase chromosomes. Furthermore, the presence of more than six sperm causes a loss of the ability of the oocyte to maintain the maternal chromosomes in a metaphase state.     

Nucleoprotein changes during male pronuclear development as determined by the ammoniacal silver reaction

Sperm nucleoprotein changes during male pronuclear development in fertilized sea urchin (Arbacia punctulata) eggs have been examined utilizing the ammoniacal silver reaction (ASR) at the light and electronic microscopic levels of observation. Previous studies and control preparations indicated that the ASR has an affinity for basic proteins, staining intensely those rich in arginine residues. Differences in the affinity of the paternally derived chromatin to the ASR prior to, during, and following pronuclear development were observed. Relative to the female pronucleus the unincorporated sperm nucleus was densely stained. Upon its entry into the egg the sperm nucleus showed a two-fold increase in staining, indicating an augmentation in the availability of reactive sites already present in the paternally derived chromatin or an accumulation of “new” reactive sites from the egg cytoplasm. With the dispersion of the sperm nucleus there was a progressive decrease in staining intensity of the paternally derived chromatin. Subsequent to pronuclear fusion the paternally derived chromatin, recognized by its relatively dense staining, was seen at one pole of the zygote nucleus. With time there was a gradual regression in the size and staining intensity of the paternally derived chromatin within the zygote nucleus. Changes in reactivity of sperm-derived chromatin are discussed in reference to previous studies of chromatin transitions at fertilization.     

PREMATURE CHROMOSOME CONDENSATION OF THE KARYOGAMY-BLOCKED SPERM PRONUCLEUS IN THE FERTILIZATION OF FUCUS DISTICHUS (FUCALES,PHAEOPHYCEAE)1

Mitosis of egg and sperm pronuclei of Fucus distichus subsp. evanescens (C. Agardh)Powell was examined by fluorescence and electron microscopy when migration of the sperm pronucleus and, as a result, karyogamy were blocked by colchicine treatment after plasmogamy. Chromosome condensation was obsewed in both pronuclei Microspectrophotometric studies after staining the nuclei with mithramycin A clearly showed that DNA synthesis ocurred in the egg pronucleus but not in the sperm pronucleus. This means that chromosomes condensed prematurely in the sperm pronucleus (premature chromosome condensation). In some cases, the egg chromosomes became arranged on a metaphase plate, whereas the sperm chromosomes lay scattered near the egg pronucleus. Immuno fluorescence microscopy using anti-β-tubulin antibody confirmed that a normal spindle was formed at the egg pronucleus. A pair of centrioles existed at the two poles of this spindle. The sperm nuclear membrane disappeared, and microtubules radiated to the sperm chromosomes from one pole of the egg spindle.     

Time-lapse and retrospective analysis of DNA methylation in mouse preimplantation embryos by live cell imaging

Genome-wide change of DNA methylation in preimplantation embryos is known to be important for the nuclear reprogramming process. A synthetic RNA encoding enhanced green fluorescence protein fused to the methyl-CpG-binding domain and nuclear localization signal of human MBD1 was microinjected into metaphase II-arrested or fertilized oocytes, and the localization of methylated DNA was monitored by live cell imaging. Both the central part of decondensing sperm nucleus and the rim region of the nucleolus in the male pronucleus were highly DNA-methylated during pronuclear formation. The methylated paternal genome undergoing active DNA demethylation in the enlarging pronucleus was dispersed, assembled, and then migrated to the nucleolar rim. The female pronucleus contained methylated DNA predominantly in the nucleoplasm. When the localization of methylated DNA in preimplantation embryos was examined, a configurational change of methylated chromatin dramatically occurred during the transition of 2-cell to 4-cell embryos. Moreover, retrospective analysis demonstrated that a noticeable number of the oocytes reconstructed by round spermatid injection (ROSI) possess small, bright dots of methylated chromatin in the nucleoplasm of male pronucleus. These ROSI oocytes showed a significantly low rate of 2-cell formation, thus suggesting that the poor embryonic development of the ROSI oocytes may result from the abnormal localization of methylated chromatin.