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

Sperm incorporation and pronuclear development during fertilization in the freshwater bivalveDreissena polymorpha

The invasive zebra mussel, Dreissena polymorpha (D. polymorpha), is proving to be a valuable model for understanding general mechanisms of fertilization, particularly regarding sperm incorporation. In the present study, we tracked the various components of the fertilizing sperm of D. polymorpha during sperm incorporation. During fertilization the sperm membrane remains associated with the egg surface as a distinct patch that disperses over time. This patch marked the site of sperm entry that occurs predominately on the CD blastomere. Taking advantage of the relatively unpigmented cytoplasm, real-time observations were made of the incorporated sperm nucleus as it decondensed and reformed as a developing pronucleus. Pronuclear enlargement occurred progressively and at rates comparable with previously reported fixed-time point observations. Sperm mitochondria were incorporated and separated from the sperm along the leading edge of the decondensing nucleus. Sperm mitochondria labeled with Mitotracker Green remained predominately associated with the CD blastomere following first cleavage and could be tracked to the 16-cell stage before the fluorescence was too faint to detect. Additionally, the demembranated sperm axoneme was incorporated, separated during nuclear decondensation, and remained visible in the egg cytoplasm up to 30 min postinsemination (PI). The present study provides one of the most complete descriptions of incorporation on multiple sperm components into the egg and coordinates fixed-time point observations with real-time observations of sperm within the remarkably transparent egg cytoplasm of zebra mussels.

Heteroplasmic conjugates formed by the fusion of starfish oocyte pairs with a 12 minute time difference in the maturation phase

Two starfish oocytes with a 12 min time difference in the maturation phase were fused together with electric pulses to make a heteroplasmic conjugate. The starfish used were Asterina pectinifera. The emergence of the first meiotic spindle and the extrusion of the polar bodies in the conjugate were timed. Under polarization microscopy two meiotic spindles emerged with a time difference of 10-11 min, which is close to the time difference in the maturation phase between the original oocytes before fusion. In contrast, subsequent formation of the first two polar bodies occurred successively with a short time lag of 1-3 min between them. Times for the formation of both polar bodies were midway between the anticipated times for polar body formation in respective non-fused control oocytes. Thus, in one nucleus the meiotic division was delayed, while in another nucleus it was accelerated, in a single heteroplasmic conjugate. These two sets of observations indicate the presence of a certain control system that regulates progression of the cell cycle at a point during the period from the entry into metaphase through to late anaphase of meiosis I in starfish oocytes. This type of cell cycle control in starfish oocytes is obviously distinct from the currently accepted view of the cell cycle control by the spindle assembly checkpoint that monitors unattached kinetochores of mitotic chromosomes.

Sperm nuclear activation during fertilization

The delivery of the paternal genome to the egg is a primary goal of fertilization. In preparation for this step, the nucleus of the developing spermatozoon undergoes extensive morphological and biochemical transformations during spermatogenesis to yield a tightly compacted sperm nucleus. These modifications are essentially reversed during fertilization. As a result, the incorporated sperm nucleus undergoes many steps in the egg cytoplasm as it develops into a male pronucleus. The sperm nucleus (1) loses its nuclear envelope, (2) undergoes nucleoprotein remodeling, (3) decondenses and increases in size, (4) becomes more spherical, (5) acquires a new nuclear envelope, and (6) becomes functionally competent to synthesize DNA and RNA. These changes are coordinate with meiotic processing of the maternal chromatin, and often result in behaviors asynchronous with the maternal chromatin. For example, in eggs fertilized during meiosis, the sperm nucleus decondenses while the maternal chromatin remains condensed. A model is presented that suggests some reasons why this puzzling behavior exists. Defects in any of the processes attending male pronuclear development often result in infertility. New assisted reproductive technologies have been developed that ensure delivery of the sperm nucleus to the egg cytoplasm so that a healthy embryo is produced. An emerging challenge is to further characterize the molecular mechanisms that control sperm nuclear transformations and link these to causes of human infertility. Further understanding of this basic process promises to revolutionize our understanding of the mystery of the beginning of new life.

Paternal effects in Drosophila: implications for mechanisms of early development

The study of paternal effects on development provides a means to identify sperm-supplied products required for fertilization and the initiation of embryogenesis. This review describes paternal effects on animal development and discusses their implications for the role of the sperm in egg activation, centrosome activity, and biparental inheritance in different animal species. Paternal effects observed in Caenorhabditis elegans and in mammals are briefly reviewed. Emphasis is placed on paternal effects in Drosophila melanogaster. Genetic and cytologic evidence for paternal imprinting on chromosome behavior and gene expression in Drosophila are summarized. These effects are compared to chromosome imprinting that leads to paternal chromosome loss in sciarid and coccid insects and mammalian gametic imprinting that results in differential expression of paternal and maternal loci. The phenotypes caused by several early-acting maternal effect mutations identify specific maternal factors that affect the behavior of paternal components during fertilization and the early embryonic mitotic divisions. In addition, maternal effect defects suggest that two types of regulatory mechanisms coordinate parental components and synchronize their progression through mitosis. Some activities are coordinated by independent responses of parental components to shared regulatory factors, while others require communication between paternal and maternal components. Analyses of the paternal effects mutations sneaky, K81, paternal loss, and Horka have identified paternal products that play a role in mediating the initial response of the sperm to the egg cytoplasm, participation of the male pronucleus in the first mitosis, and stable inheritance of the paternal chromosomes in the early embryo.

A metaphase pause: hormone-induced maturation progresses through a long pause at the first meiotic metaphase in oocytes of the starfish, Pisaster ochraceus

In several species of starfish, it has been reported that the meiotic divisions in fertilized oocytes occur precociously compared to those in unfertilized oocytes. The nature of the 'acceleration' of meiosis was studied using Pisaster ochraceus oocytes. The extent of the acceleration of first polar body formation was found to be completely dependent on the time of fertilization (or artificial activation); fertilization at about 100 min after 1-methyladenine application accelerated meiosis I the most, while earlier or later fertilization resulted in a smaller extent of accelerations of meiosis I. Observation of isolated meiotic spindles and fluorescent visualization of meiotic spindles in whole oocytes showed that progression of meiosis I in Pisasteroocytes pauses transiently at metaphase I for more than 40 min unless they are activated. The activation shortened the duration of metaphase I, which resulted in the acceleration of first polar body formation. A new term 'metaphase pause' is proposed to define this long duration of metaphase I in starfish oocytes.

Cyclopiazonic acid induces accelerated progress of meiosis in pig oocytes

In mammalian oocytes, calcium plays an important role in the regulation of meiotic maturation. In our study, we used the mycotoxin cyclopiazonic acid (CPA), an inhibitor of calcium-dependent ATPases, to mobilise intracellular calcium deposits during in vitro maturation of pig oocytes. The CPA treatment of maturing oocytes significantly accelerated the progress of their maturation. Oocytes entered the CPA-sensitive period after 21 h of in vitro culture. A very short (5 min) exposure to CPA (100 mM) is sufficient to accelerate maturation and it seems that accelerated maturation can be triggered by a transient elevation of intracellular calcium levels. The effect of CPA is not mediated through the cumulus cells, because maturation is accelerated by CPA treatment even in oocytes devoid of cumulus cells. Culture of oocytes with the calcium channel blocker verapamil (concentrations ranging from 0.01 to 0.04 mM) blocked the progress of oocyte maturation beyond the stage of metaphase I. This block can be overcome by the mobilisation of intracellular calcium deposits after CPA treatment (100 nM). The microinjection of heparin (20 pl, 0.1 mg/ml), the inhibitor of inositol triphosphate receptors, before CPA treatment prevented the acceleration of oocyte maturation. This indicates that CPA mobilises the release of calcium deposits through inositol trisphosphate receptors. On the other hand, the microinjection of procaine (20 pl, 200 nM) or the microinjection of ruthenium red (20 pl, 50 mM), both inhibitors of ryanodine receptors, did not prevent accelerated maturation in CPA-treated oocytes. If present in pig oocytes, ryanodine receptors evidently play no part in the liberation of calcium from intracellular stores after CPA treatment.

Transformation of sperm nuclei into metaphase chromosomes in maturing pig oocytes penetrated in vitro

Cumulus-free pig oocytes at the germinal vesicle (GV) stage were incubated in modified Brackett & Oliphant's medium with 5% fetal calf serum and 5mM caffeine with or without cryopreserved, ejaculated spermatozoa. When oocytes were transferred into modified tissue culture medium (TCM-199B at pH 7.4) supplemented with 10 IU/ml eCG, 10 IU/ml hCG and 1 microg/ml oestradiol-17beta after 8 h of incubation with spermatozoa and cultured for 0-48 h, 86-99% of oocytes were penetrated. Most (95-100%) oocytes penetrated 0-16 h after transfer had decondensed sperm chromatin. However, 24 h after transfer 47% and 33% of penetrated oocytes contained recondensed sperm chromatin and sperm metaphase chromosomes, respectively. The proportion of penetrated oocytes containing sperm metaphase chromosomes increased after 36-48 h of transfer (51-65%). The transformation of sperm nuclei to metaphase chromosomes was obtained in 75% and 79% of anaphase I (AI) to telophase I (TI) and metaphase II (MII) oocytes, respectively, but only in 38% of metaphase I (MI) oocytes. Moreover, such transformation was observed only in 1 of 30 oocytes at the stages of GV breakdown to prometaphase I and none of 69 oocytes at the GV stage. The transformation of sperm nuclei into metaphase chromosomes was completely inhibited in oocytes penetrated by eight or more spermatozoa. Well-developed male and female pronuclei were observed in only 3 (4%) of 77 oocytes penetrated 48 h after transfer. The proportion of oocytes reaching MII was greatly inhibited by sperm penetration; only 18% of penetrated oocytes, but 87% of non-inseminated oocytes, reached MII by 48 h after transfer. None of the oocytes penetrated by seven or more spermatozoa reached MII. Most (75%) oocytes were inhibited from the transition from MI to MII even though they were cultured for 48 h. The present results indicate that: (1) the cytoplasm of maturing oocytes possesses an activity for transforming sperm nuclei into metaphase chromosomes, (2) immature pig oocytes penetrated by spermatozoa can undergo meiotic maturation to MI, and (3) the transition of such oocytes from MI to MII is inhibited, suggesting that an activity of mitogen-activated protein kinase may be retarded.

Activation of bovine oocytes penetrated after germinal vesicle breakdown

The present study was designed to examine the ability of bovine oocytes, after germinal vesicle breakdown (GVBD), to be activated by sperm penetration and the sequence of sperm nuclear transformation. Bovine oocytes cultured for 8 h in maturation medium (tissue culture medium TCM-199 containing 10% fetal calf serum) were inseminated in Brackett and Oliphant's medium supplemented with bovine serum albumin (10 mg/ml), caffeine (5 mM) and heparin (10 micrograms/ml). When oocytes were transferred to the maturation medium 8 h after insemination and additionally cultured for 5-40 h at 39 degrees C in 5% CO2 in air, 71-76% of oocytes were penetrated and polyspermy (67-75%) was common. The proportions of penetrated oocytes that were activated significantly increased with the lapse of the additional culture time, reaching 88% and 87% by 25 and 40 h after additional culture, respectively. When compared with unpenetrated oocytes, significantly higher proportions of penetrated oocytes reached metaphase II or beyond 15 and 25 h after additional culture. After penetration, sperm nuclei were transformed into metaphase chromosomes and then to telophase chromosomes before the formation of male pronuclei. These results provide evidence that bovine oocytes acquire the ability to respond to sperm-mediated activation soon after GVBD.

Completion of first meiosis by sperm penetration in vitro of bovine oocytes inhibited at metaphase-I with dimethylsulphoxide

The effects of dimethylsulphoxide (DMSO) on immature oocytes during maturation in culture and following penetration by spermatozoa were examined. Germinal vesicle breakdown (GVBD) was observed in all oocytes cultured in the maturation medium supplemented with 2, 4 and 8% DMSO. When the oocytes were cultured in medium with 8% DMSO, 95% (57 60 ) of them were inhibited at prometaphase-I. Cumulus cells were significantly (P<0.05) beneficial for resumption of oocyte nuclear maturation during further culture in the maturation medium for 4, 8 and 24 h after DMSO treatment. When the oocytes were additionally cultured for 4 and 8 h in the maturation medium after DMSO treatment, the proportions of oocytes reaching metaphase-II were significantly (P<0.05) higher in those cultured with spermatozoa than without (68 vs 49% and 84 vs 56%, respectively). These results indicate that 8% DMSO does not affect GVBD of oocytes, but conversely it inhibits oocytes at prometaphase-I, and that cumulus cells are important for recovery from DMSO inhibition and for the resumption of nuclear maturation of oocytes. Sperm penetration was also found to stimulate the completion of meiotic maturation of oocytes inhibited at metaphase-I with 8% DMSO.

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.