Cytoplasmic modification of the nuclear lamina during pronuclear-like transformation of mouse blastomere nuclei.

During the successive interphases of cleaving mouse embryos the nuclear periphery diminishes its reactivity to anti-lamin A and C antibodies. This developmentally regulated characteristic can be modified by exposure of the blastomere nuclei to metaphase II (M II) oocyte cytoplasm followed by activation. In the current study we define the cytoplasmic conditions necessary for this modification of 8-cell and 16-cell stage nuclei in hybrids obtained by fusion with metaphase II arrested oocytes, oocytes at various time points after parthenogenetic activation, naturally fertilized eggs (zygotes) and interphase 2-cell embryo blastomeres. The intensity of fluorescence obtained with anti-lamins A/C in the blastomere nuclei increases as a result of fusion with freshly activated oocytes or early zygotes (first 3.0-5.5 h in the case of parthenogenetic activation), and not when eggs or 2-cell blastomeres advanced in interphase are used as partners for fusion. This transformation of the A/C lamin pattern is correlated with the ability to promote pronucleus-like growth of blastomere nuclei in hybrids. Blastomere nuclei introduced into M II-arrested oocytes undergo premature chromatin condensation and dissolution of the nuclear lamina. The results are discussed with regard to certain particularities of the first embryonic interphase of the mouse and the potential involvement of nuclear lamins in pronuclear growth.     

In vivo aging of oocytes influences the behavior of nuclei transferred to enucleated rabbit oocytes

The present study examined nuclear remodeling in rabbit nuclear transfer (NT) embryos formed from metaphase II (MII) oocytes aged in vivo until 19 hr postcoitum (hpc), enucleated, and fused at 22–26 hpc with 32-cell morula blastomeres by means of electric fields, which also induced recipient oocyte activation. Post-activation events observed during the first hour following the fusion/activation pulse were studied in terms of chromatin, lamins, and micro-tubules, and revealed that transferred nuclei underwent premature chromosomes condensation (PCC) in only one-third of NT embryos and remained in interphase in others. Recipient oocytes were mostly not activated by manipulations performed before the fusion/activation pulse. The persistance of transferred nuclei in interphase resulted from the rapid progression of recipient oocytes to interphase after activation, suggesting that the cytoplasmic state of MII oocytes aged in vivo was poised for the approach to interphase. Studying micro-tubular organization in MII oocytes before nuclear transfer manipulations, we found that 19 hpc MII oocytes aged in vivo differed from 14 hpc MII oocytes (freshly ovulated) and from 19-hpc MII oocytes aged in vitro (collected at 14 hpc and cultured for 5 hr), notably by the presence of microtubule asters and tubulin foci or only tubulin foci dispersed throughout the cytoplasm. When PCC was avoided, remodeling of the transferred nucleus was well advanced 1 hr after nuclear transfer, and NT embryos developed better to the blastocyst stage. Mol. Reprod. Dev. 46:325–336, 1997. © 1997 Wiley-Liss, Inc.     

The expression of nuclear lamin A and C epitopes is regulated by the developmental stage of the cytoplasm in mouse oocytes or embryos.

The cytoplasmic regulation of changes of nuclear lamin antigens was examined by transferring 16-cell stage blastomeres into mouse oocytes. Sixteen-cell stage blastomeres were transferred to either pronuclear eggs, enucleated pronuclear eggs or metaphase II oocytes, which were subsequently activated. Pronuclei react with a monoclonal antibody to A/C lamins (J9), whereas nuclei from 16-cell stage blastomeres do not react with J9. However, after transfer of 16-cell stage nuclei to activated metaphase II oocytes, the transferred nuclei acquire the antigen. This is in contrast to 16-cell nuclei that were transferred to intact or enucleated pronuclear eggs; i.e., the nuclei only faintly acquired the A/C epitope. These results suggest that the developmental stage of the cytoplasm regulates the exposure of nuclear lamina epitopes, perhaps by limiting the supply of lamin A/C in the oocyte or because nuclear lamina assembly can only occur at the telophase transition. Furthermore, it appears that there is some exchange of the A/C epitope between (pro)nuclei within the same cell but that the majority of the A/C lamin epitope can be removed from a cell with (pro)nuclear removal.     

Relationship between nuclear remodeling and development in nuclear transplant rabbit embryos.

The present study characterized the profile of nuclear remodeling in nuclear transplant rabbit embryos and investigated the relationship between chromatin behavior after transfer and embryo development. The developmental potential and pattern of remodeling of donor nuclei from cleavage-, morula-, and blastocyst- (inner cell mass ICM, and trophectoderm, TE) stage donors were evaluated. In addition, we determined whether a modification in the synchrony between blastomere fusion and oocyte activation altered the profile of nuclear remodeling and affected development of reconstituted embryos. Development to blastocysts was similar with 8- and 32-cell-stage donor nuclei (42% and 33%, respectively, p greater than 0.1). However, it was reduced with ICM transplants (17%, p less than 0.05), and development of TE transplants did not progress beyond the 8-cell stage. Upon blastomere fusion into nonactivated oocyte cytoplasm, nuclear remodeling was characterized by premature chromosome condensation (PCC), followed by pronuclear (PN) formation and swelling. PCC occurred synchronously within 1.2-1.5 h post-fusion with all stages of donor nuclei (p greater than 0.1). PN formation in 8- and 32-cell transplants occurred approximately 4 h after fusion, and was synchronous to that of female pronuclei in activated oocytes; however, it was delayed in ICM and TE transplants (p less than 0.01). With all stages of donor nuclei, final nuclear diameter was similar to, or larger than, that of female pronuclei. Fusion to activated oocyte cytoplasm, as opposed to nonactivated cytoplasm, prevented PCC and extensive nuclear swelling (16.0 +/- 0.7 vs. 30 +/- 0.7 microns, respectively, p less than 0.01). Nuclear diameter in early embryos was smaller (p less than 0.01), and development to blastocysts was reduced (p less than 0.05). The results indicate that remodeling of the donor nucleus is not essential for development to blastocysts; however, it is beneficial. Furthermore, complete reprogramming seems possible only after remodeling of the donor nucleus, i.e., PCC in nonactivated cytoplasm, followed by nuclear swelling upon activation of the oocyte.     

Nuclear transplantation in early pig embryos

Nuclear transfer was evaluated in early porcine embryos. Pronuclear stage embryos were centrifuged, treated with cytoskeletal inhibitors, and subsequently enucleated. Pronuclei containing karyoplasts were placed in the perivitelline space of the enucleated zygote and fused to the enucleated zygote with electrofusion. The resulting pronuclear exchange embryos were either monitored for cleavage in vitro (9/13 cleaved and contained 2 nuclei after 24 h, 69%) or for in vivo development. In vivo development after 3 days resulted in 14/15 (93%) of the embryos transferred cleaving to the greater than or equal to 4-cell stage and after 7 days 6/16 (38%) reaching the expanded blastocyst stage. A total of 56 pronuclear exchange embryos were allowed to go to term, and 7 piglets were born. A similar manipulation procedure was used to transfer 2-, 4- or 8-cell nuclei to enucleated, activated meiotic metaphase II oocytes. Enucleation was effective in 74% (36/49) of the contemporary oocytes. Activation was successful in 81% (37/46) of nonmanipulated but pulsed oocytes versus 13% (4/31) of control oocytes (p less than 0.01). After 6 days in vivo, 9% (1/11) of the 2-cell nuclei, 8% (7/83) of the 4-cell nuclei, and 19% (11/57) of the 8-cell nuclei transferred to enucleated, activated meiotic metaphase II oocytes resulted in development to the compact morula or blastocyst stage (p less than 0.01). A total of 88 nuclear transfer embryos were transferred to recipient gilts for continued development. A single piglet was born after the transfer of a 4-cell nucleus to an enucleated, activated metaphase II oocyte and subsequent in vivo development.(ABSTRACT TRUNCATED AT 250 WORDS)     

Changes in global histone acetylation pattern in somatic cell nuclei after their transfer into oocytes at different stages of maturation

In our study, we have examined the pattern of global histone modification changes in somatic cell nuclei after their transfer into mouse oocytes at different stages of maturation or after their parthenogenetic activation. While germinal vesicle (GV) staged immature oocytes are strongly labeled with anti-acetylated histone H3 and H4 antibodies, the signal is absent in both metaphase I and metaphase II oocytes (MI, MII). In contrast, the oocytes of all maturation stages show a presence of trimethylated H3/K4 in their chromatin. When somatic cells were fused to intact or enucleated GV oocytes, both the GV and the somatic cell nucleus showed a very strong signal for all the antibodies used. On the other hand, when somatic cells nuclei that are AcH3 and AcH4 positive before fusion are introduced into either intact or enucleated MI or MII oocytes, their acetylation signal decreased rapidly and was totally absent after a prolonged culture. This was not the case when anti-trimethyl H3/K4 antibody was used. The somatic cell chromatin showed only a slight decrease in the intensity of labeling after its transfer into MI or MII oocytes. This decrease was, however, evident only after a prolonged culture. These results suggest not only a relatively higher stability of the methylation modification but also some difference between the oocyte and somatic chromatin. The ability to deacetylate the chromatin of transferred somatic nuclei disappears rapidly after the oocyte activation. Our results indicate that at least some reprogramming activity appears in the oocyte cytoplasm almost immediately after GV breakdown (GVBD), and that this activity rapidly disappears after the oocyte activation.     

Cell cycle-dependent behavior of microtubules in hybrids of mouse oocytes and blastomeres.

The behavior of microtubules was studied in hybrids formed between mouse oocytes arrested in metaphase II or activated parthenogenetically and mouse embryo interphase blastomeres. In all cases the interphase blastomere's network of microtubules disassembles rapidly after fusion with oocytes. Introduction of interphase cytoplasm and nuclei to metaphase oocytes during fusion induces the polymerization of new microtubules in the cytoplasm and in the meiotic spindle. The degree and the duration of this facilitated polymerization of microtubules was positively correlated with the volume of blastomeres used for fusion. The blastomere nuclei induce the formation of microtubular frames, which become more evident when the chromatin undergoes premature condensation. Finally, spindle-like structures are formed around the prematurely condensed chromosomes. In hybrids activated around the time of fusion, the blastomere nuclei undergo pronuclear-like transformation. These hybrids develop an interphase network of microtubules typical for activated oocytes. These results are discussed with regards to the cell cycle control of microtubule behavior.     

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.     

Factors controlling the loss of immunoreactive somatic histone H1 from blastomere nuclei in oocyte cytoplasm: a potential marker of nuclear reprogramming

Nuclei of differentiated cells can acquire totipotency following transfer into the cytoplasm of oocytes. While the molecular basis of this nuclear reprogramming remains unknown, the developmental potential of nuclear-transfer embryos is influenced by the cell-cycle stage of both donor and recipient. As somatic H1 becomes immunologically undetectable on bovine embryonic nuclei following transfer into ooplasm and reappears during development of the reconstructed embryo, suggesting that it may act as a marker of nuclear reprogramming, we investigated the link between cell-cycle state and depletion of immunoreactive H1 following nuclear transplantation. Blastomere nuclei at M-, G1-, or G2-phase were introduced into ooplasts at metaphase II, telophase II, or interphase, and the reconstructed embryos were processed for immunofluorescent detection of somatic histone H1. Immunoreactivity was lost more quickly from donor nuclei at metaphase than at G1 or G2. Regardless of the stage of the donor nucleus, immunoreactivity was lost most rapidly when the recipient cytoplast was at metaphase and most slowly when the recipient was at interphase. When the recipient oocyte was not enucleated, however, immunoreactive H1 remained in the donor nucleus. The phosphorylation inhibitors 6-DMAP, roscovitine, and H89 inhibited the depletion of immunoreactive H1 from G2, but not G1, donor nuclei. In addition, immunoreactive H1 was depleted from mouse blastomere nuclei following transfer into bovine oocytes. Finally, expression of the developmentally regulated gene, eIF-1A, but not of Gapdh, was extinguished in metaphase recipients but not in interphase recipients. These results indicate that evolutionarily conserved cell-cycle-regulated activities, nuclear elements, and phosphorylation-linked events participate in the depletion of immunoreactive histone H1 from blastomere nuclei transferred in oocyte cytoplasm and that this is linked to changes in gene expression in the transferred nucleus.     

Cytogenetic study of silver-staining NOR in 8-cell-stage mouse blastomeres fused to 1-cell-stage embryos

Isolated blastomeres from 8- to 16-cell-stage embryos were fused by standard micromanipulatory means with either unfertilized eggs or fertilized or haploid parthenogenetically activated pronuclear-stage embryos. The hybrid eggs/embryos were incubated overnight in the presence of Colcemid until they had entered the first cleavage division. Air-dried chromosome preparations were then stained with silver nitrate in order to detect active nucleolar organizing regions (NOR). While control unfertilized eggs and 1-cell-stage fertilized and parthenogenetically activated embryos showed no evidence of silver-staining NOR-positive regions, the metaphase plates from 8- to 16-cell embryos showed characteristic NOR-positive regions, while their interphase nuclei also showed a characteristic reticular staining appearance. When hybrids between blastomere nuclei and unfertilized eggs were examined, none of the blastomere nuclei entered mitosis. However, when hybrids between blastomere nuclei and fertilized embryos were examined, in two thirds of the embryos, a single blastomere-derived diploid metaphase plate was present in association with two pronuclear-derived haploid metaphase plates. In most instances, the blastomere-derived chromosomes did not display silver-nitrate-staining NOR. Similar findings were observed when the blastomere-derived chromosomes in hybrids between blastomere nuclei and haploid parthenogenetic embryos were analysed. In the majority of cases, when blastomere nuclei remained in interphase, the characteristic silver-nitrate-staining fine reticular material either was not seen, or the nuclear contents were dispersed into clumps of chromatin-like material. Occasionally, the diploid chromosomes in the hybrids displayed morphological abnormalities. Our findings suggest that the cytoplasm of activated (but not nonactivated) 1-cell embryos is capable of influencing the nucleolar activity of the introduced 8- to 16-cell nuclei, effectively erasing from their chromosomes the memory of at least three previous rounds of rRNA synthesis.     

Development of mouse enucleated oocytes receiving a nucleus from different stages of the second cell cycle.

The influence of the stage of the cell cycle of donor nuclei on the development of mouse oocytes enucleated at telophase I was examined. After nuclear transplantation and activation, a high proportion of the oocytes remodelled a nucleus, emitted a polar body and formed a pronuclear-like nucleus. Most of the reconstituted embryos that received an interphase nucleus 30-32 h or 34-36 h after treatment with human chorionic gonadotrophin (hCG) arrested at the 2-cell stage. The reconstituted embryos were able to develop to blastocysts when nuclei from late 2-cell embryos (44-46 and 48-50 h after hCG) were transferred to the oocytes. The resulting blastocysts were transferred to recipients and ten live young were obtained from the embryos that formed a pronuclear-like nucleus after extrusion of a polar body. Thus, the developmental ability of the reconstituted embryos was critically influenced by the stage of the cell cycle of the donor nuclei.     

Preimplantation development of rabbit embryos after transfer of embryonic nuclei into different cytoplasmic environment

The development of nuclear-transfer oocytes and zygotes was tested in the rabbit. Metaphase II oocytes and zygotes in the early pronuclear stage were treated with a cytoskeletal inhibitor (cytochalasin D), enucleated, and subsequently fused either with single blastomeres from eight- and 16-cell stages (oocytes and zygotes) or with pronuclei-containing karyoplasts (zygotes only). Also, nonenucleated zygotes were fused with 1/8 blastomeres. Fusion was performed by means of an electric field. Development of reconstituted embryos was monitored mainly in vitro, but a certain number of embryos developed from oocytes and zygotes receiving nuclei from eight-cell stages were also transferred into pseudopregnant does. Development of nuclear-transfer oocytes was distinctly better than that of nuclear-transfer zygotes, since 16.9% and 9.5% oocytes vs. 8.1% and 3.7% zygotes carrying eight- and 16-cell nuclei, respectively, developed to the blastocyst stage. Two advanced but already dead fetuses were found after transfer of 27 four-cell embryos obtained after fusion of oocytes with 1/8 blastomeres. No implantations were observed after transfer of 25 four-cell embryos developed from enucleated zygotes receiving eight-cell nuclei. These findings indicate that, in the rabbit, some nuclei from 16-cell embryos are still capable of promoting at least preimplantation development. Comparison between the developmental abilities of oocyte- and zygote-derived nuclear-transfer embryos also suggests that the cytoplasmic environment of recipient cell is more crucial for the development of reconstituted embryos than the stage of introduced nuclei (at least up to the 16-cell stage). The majority of pronuclear exchange embryos (69.9%) and 40% of nonenucleated zygotes receiving eight-cell nuclei were able to develop to the blastocyst stage. This latter observation indicates, similarly as with mouse, a supporting role of residual pronuclei for participation of an eight-cell nucleus in the development of reconstituted zygotes.     

Remodelling of thymocyte nuclei in activated mouse oocytes: an ultrastructural study

Oocyte-thymocyte mouse cell hybrids were produced using polyethylene glycol (PEG) and examined at the ultrastructural level. Fusion was accomplished either before or after activation of metaphase II oocytes. In both experimental variants thymocyte nuclei undergo remodelling which comprises the following sequence of events: nuclear envelope breakdown, initial chromatin condensation, and subsequent decondensation, nuclear envelope reformation and formation of nucleoli. In hybrids produced before oocyte activation but activated within a short time and cultured for several hours the thymocyte nuclei become identical to the female pronucleus. In the second variant (fusion with activated oocytes) the degree of remodeling of thymocyte nuclei is variable. Our observations demonstrate that between metaphase II, telophase of meiosis and early female pronuclear stages the mouse oocyte contains all "factors" necessary for remodelling of differentiated somatic nuclei and their development as if they were pronuclei.     

Developmental regulation of an snRNP core protein epitope during pig embryogenesis and after nuclear transfer for cloning.

The appearance and stabilization of a core protein epitope of the snRNP is developmentally regulated during pig embryogenesis. The epitope recognized by the monoclonal antibody Y12 is present in the germinal vesicle of mature oocytes and interphase nuclei of late 4-cell stage (24 to 30 hours post cleavage to the 4-cell stage) to blastocyst stage embryos. There was no antibody localization within pronuclei, or nuclei of 2-cell or early 4-cell stage embryos. Zygotes or 2-cell stage embryos cultured in the presence of alpha-amanitin to the late 4-cell stage showed no immunoreactivity, whereas control embryos had immunoreactivity. Thus antibody localization was correlated with RNA synthesis and RNA processing that begins by 24 hours post cleavage to the 4-cell stage. A final experiment showed no detectable immunoreactivity in 16-cell stage nuclei that had been transferred to enucleated activated meiotic metaphase II oocytes. Since immunoreactivity is associated with active RNA synthesis and RNA processing, it suggests that the 16-cell stage nucleus, which is RNA synthetically active, does not process RNA after nuclear transfer to an enucleated activated meiotic metaphase II oocyte.     

A maternal store of macroH2A is removed from pronuclei prior to onset of somatic macroH2A expression in preimplantation embryos

MacroH2A histones are variants of canonical histone H2A that are conserved among vertebrates. Previous studies have implicated macroH2As in epigenetic gene-silencing events including X chromosome inactivation. Here we show that macroH2A is present in developing and mature mouse oocytes. MacroH2A is localized to chromatin of germinal vesicles (GV) in both late growth stage (lg-GV) and fully grown (fg-GV) stage oocytes. In addition, macroH2A is associated with the chromosomes of mature oocytes, and abundant macroH2A is present in the first polar body. However, maternal macroH2A is lost from zygotes generated by normal fertilization by the late 2 pronuclei (2PN) stage. Normal embryos at 2-, 4-, and 8-cell stages lack macroH2A except in residual polar bodies. MacroH2A protein expression reappears in embryos after the 8-cell stage and persists in morulae and blastocysts, where nuclear macroH2A is present in both the trophectodermal and inner cell mass cells. We followed the loss of macroH2A from pronuclei in parthenogenetic embryos generated by oocyte activation. Abundant macroH2A is present upon the metaphase II plate and persists through parthenogenetic anaphase, but macroH2A is progressively lost during pronuclear decondensation prior to synkaryogamy. Examination of embryos generated by intracytoplasmic sperm injection (ICSI) revealed that macroH2A is associated exclusively with female pronuclei prior to loss in late pronucleus stage embryos. These results outline a surprising finding that a maternal store of macroH2A is removed from the maternal genome prior to synkaryogamy, resulting in embryos that execute three to four mitotic divisions in the absence of macroH2A prior to the onset of embryonic macroH2A expression.     

Factors influencing chromosome condensation and development of cloned rat embryos

Factors influencing premature chromosome condensation (PCC) in transferred rat nuclei have been examined. Chromosome condensation of rat cumulus cell nuclei did not occur when the cell nuclei were injected into enucleated rat oocytes. By contrast, chromosome condensation did occur after transfer to enucleated mouse oocytes or intact rat oocytes. In the first serial NT experiment, rat somatic cell nuclei were injected into enucleated mouse oocytes, and the reconstructed oocytes were activated by strontium chloride. From these reconstructed embryos, karyoplasts containing pronucleus-like vesicles were transferred into pronuclear zygote-derived cytoplasts by a DC pulse. Transfer of a total of 340 serial NT zygotes into recipient females, including 206 two-cell embryos, resulted in only seven implantation sites. In the second serial NT experiment, rat somatic cell nuclei were injected into intact rat oocytes; the recipient metaphase-plate was then aspirated under UV light from the NT oocytes in which PCC of injected nuclei was observed. After activation of the NT oocytes, karyoplasts were introduced into zygote-derived cytoplasts. Transfer of a total of 115 serial NT zygotes, including 37 two-cell embryos, resulted in four implantation sites but no live offspring. These results establish a mean of inducing chromosome condensation in rat oocytes and demonstrate that reconstructed rat zygotes can be prepared by serial NT procedures. Developmental competence of these embryos remains to be clarified.     

Mouse oocytes gradually develop the capacity for activation during the metaphase II arrest

Metaphase II (M II) mouse oocytes were subjected to a parthenogenetic stimulus (8% ethanol) or fertilized in vitro at various times following the extrusion of the first polar body. The oocytes progressively develop the ability for full activation. Their responsiveness to activation stimuli not only increases, but also changes qualitatively with time. Newly arrested oocytes do not respond at all; then, when the ability to undergo meiotic anaphase II first develops, the response is defective: following extrusion of the second polar body (II PB), the oocyte does not enter interphase but arrests again at metaphase (M III-arrest). Finally, oocytes gain the ability for full activation including the entry to interphase. Depending on the type of activating stimulus, oocytes exhibit the capacity for full activation at different ages. The oocyte arrest in M III is similar to M II and can be released by subsequent activation. Such oocytes undergo anaphase III, extrude a third polar body (III PB), and form an aneuploid female pronuclei.