Mouse zygotes with one diploid pronucleus formed as a result of ICSI can develop normally beyond birth

A mouse spermatozoon was injected into mouse secondary oocytes (ICSI) in the vicinity of the metaphase spindle. In 22% of oocytes injected successfully, the maternal chromatin (the haploid chromatids formed after the second meiotic division) and paternal chromatin (from the sperm nucleus) were surrounded by a common nuclear envelope to form one diploid bi-parental pronucleus. However, the use of spermatozoa in which BrdU had been incorporated into DNA during spermatogenesis revealed, that maternal and paternal chromatin occupied two separate compartments within the one pronucleus. In the living state, the diploid pronucleus could be distinguished from a haploid one by its distinctly larger size and by a greater number of "nucleolus-like bodies"-criteria confirmed karylogically at the 1st cleavage division. Such zygotes with one diploid pronucleus were able to develop in vitro into blastocysts as often as those with two haploid pronuclei [11/29 (38%) vs. 14/35 (40%)]. Seventy nine 2-cell embryos developing in vitro from zygotes with one diploid pronucleus were transplanted to the oviducts of pseudopregnant recipients: two females had six foetuses when killed on the 17th day, and two females gave birth to nine young, eight of which survived and developed into normal fertile animals.     

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.     

Ooplasmic influence on nuclear function during the metaphase II-interphase transition in mouse oocytes.

Nuclear and pronuclear transfer procedures were used to assess the functional competence of the nucleus and cytoplasm of mouse germinal vesicle-stage oocytes denuded of granulosa cells and matured in vitro or in vivo before artificial activation using a sequential treatment of A23187 + cycloheximide. Following activation, in vitro-matured oocytes were "fertilized" by inserting a male pronucleus (PN), cultured to the 2-cell stage, and then transferred to the oviducts of foster mothers. No live births were noted, whereas a 17% live birth rate was observed when in vivo-matured oocytes were used. The developmental competency of other zygotes was similarly assessed following the exchange of haploid PN of matured and activated eggs with the female PN of fertilized zygotes. When PN of oocytes subjected to maturation and activation in vitro were transferred, only 1 of 79 reconstructed zygotes developed to term. In contrast, the live birth rate was 21% (11 of 53) for zygotes reconstructed with PN from in vivo-matured oocytes. Moreover, a live birth rate of 23% (8 of 35) was observed for reconstructed zygotes with female PN from "hybrid" oocytes created by transferring the metaphase II nuclei of in vitro-matured oocytes into enucleated, in vivo-matured oocytes before activation. Such results suggest that the nucleus of an in vitro-matured oocyte can support embryonic development, but only when it is activated in the proper ooplasmic milieu. The cellular factors creating this ooplasmic milieu appear to develop normally in vivo during follicle maturation to metaphase II, but they fail to do so when the oocytes are denuded of granulosa cells and cultured in vitro before the final stages of maturation. In parallel studies, male and female PN of in vivo-fertilized zygotes were inserted into oocytes that were activated and enucleated following either in vitro or in vivo maturation. Live birth rates were comparable at 19% (5 of 27) and 18% (9 of 49), respectively, suggesting that, regardless of the environment of the final stages of oocyte maturation, the resultant ooplasm is competent to support all aspects of embryonic development once activation and PN formation has been completed. Such findings only point further toward the importance of the condition of the ooplasmic milieu at the time of chemical activation. Whether a similar situation exists when eggs are activated following sperm penetration remains to be determined.     

Spontaneous and sperm-induced activation of oocytes in LT/Sv strain mice

The oocytes of LT/Sv strain mice are unique in that a high proportion of them (∼40% in this study) are ovulated before reaching metaphase of the second meiotic division (metaphase II). The remaining oocytes of LT/Sv mice are ovulated at metaphase II, as in other strains of mice. When recently ovulated oocytes were cultured in vitro for 11–12 h, those ovulated at metaphase II remained at this stage, whereas those ovulated at metaphase of the first meiotic division (metaphase I) commonly resumed meiosis during in vitro aging. These oocytes extrude the polar body and form a diploid pronucleus. This oocyte activation is not coupled with cortical granule exocytosis. The oocytes ovulated at metaphase II are fully capable of normal fertilization, whereas those ovulated at metaphase I are not. Approximately 50% of metaphase I oocytes penetrated by spermatozoa remain at this stage, and sperm nuclei frequently undergo premature chromosome condensation. Only 13% of spermpenetrated metaphase I oocytes formed a diploid female pronucleus and a haploid male pronucleus by 4 h after insemination. These results demonstrate that the two types of ovulated LT/Sv oocytes have different potentials to undergo either spontaneous or sperm-induced activation.     

Role of germinal vesicle on protein synthesis in rat oocyte during in vitro maturation

To investigate the role of the germinal vesicle (GV) on in vitro maturation (IVM) of rat oocytes, we examined protein synthesis during IVM by comparing polypeptide patterns in control and enucleated oocytes using one and two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Separation of polypeptides extracted from the cytoplasm of GV by one-dimensional SDS-PAGE revealed that a 55 kDa polypeptide was present only in the GVs of rat oocytes. At 0, 12, 24, 36, and 44 hr after PMSG injection, prior to the initiation of maturation, enucleated oocytes synthesized the same major polypeptides as cumulus intact (CI) oocytes. During meiotic maturation, no major changes were detected in protein synthesis from prophase (GV stage) to prometaphase I (0–6 hr IVM). However, after entry into prometaphase I (7 hr IVM), striking changes were seen; a 24 kDa polypeptide disappeared and expression of a 34 kDa polypeptide became stronger. This pattern lasted until metaphase II. We detected no major differences in the pattern of protein synthesis between CI and enucleated oocytes using two-dimensional PAGE. These results indicate that protein synthesis in the maturing rat oocyte is controlled by cytoplasmic regulators rather than intrinsic nuclear components. © 1996 Wiley-Liss, Inc.     

Nuclear transplantation in mouse embryos: assessment of recipient cell stage

Enucleated zygotes were compared with enucleated two-cell embryos as recipients for donor nuclei from eight-cell embryos. Only one or two cleavage divisions were observed when eight-cell nuclei were transplanted to enucleated zygotes. Development of enucleated two-cell embryos containing a transplanted eight-cell nucleus was appreciably better with 51% (45/89) of the embryos forming blastocysts in vitro and 42% (25/60) initiating implantation. Of these, eleven implantation sites on Day 10 of gestation were examined histologically and two contained normally developing embryos. No development was observed beyond Day 12 of gestation. These observations indicate that a major transition occurs between the zygote and two-cell stage that results in the two-cell recipient being more compatible with the eight-cell nucleus than with the zygote.     

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)     

Behavior of sperm nuclei in intact and bisected metaphase II mouse oocytes fertilized in the presence of colcemid

Our objective was to examine the developmental fate of sperm nuclei in oocytes fertilized under conditions of meiotic arrest. Therefore zona-free metaphase II oocytes and oocyte fragments (nucleate and anucleate) were fertilized in the presence of colcemid. In anucleate oocyte fragments, normal male pronuclei develop. In contrast, in intact oocytes and nucleate fragments sperm nuclei after initial decondensation undergo secondary condensation. This state is maintained as long as the oocytes are treated with colcemid. When the drug is removed 3 h after insemination, the meiotic spindle(s) is reconstructed, the second polar body(ies) is extruded, and a female pronucleus (or micronuclei) forms. At the same time the sperm nucleus decondenses again and transforms into a male pronucleus. In addition oocytes fertilized in the presence of colcemid could not be refertilized. These observations suggest that oocytes and oocyte fragments fertilized in the presence of colcemid undergo activation despite the failure of pronucleus formation. The inhibitory effect of colcemid on the formation of pronuclei is expressed only in the presence of oocyte chromosomes. We suggest that colcemid stabilizes factors responsible for chromosome condensation that are associated with oocyte chromosomes but not factors (whether the same or different) present in the cytoplasm.     

Reconstruction of enucleated mouse germinal vesicle oocytes with blastomere nuclei

We have investigated the possibility that mitotic nuclei originating from preimplantation stage embryos and placed in the oocyte cytoplasm can undergo remodelling that allows them to undergo meiosis in the mouse. To address this question, we have used enucleated germinal vesicle (GV) ooplasts as recipients and blastomeres from the 2-, 4- or 8-cell stage as nuclear donors. We employed two methods to obtain ooplasts from GV oocytes: cutting and enucleation. Although efficiency of the reconstruction process was higher after enucleation than after cutting (90% and 70% respectively), the developmental potential of the oocytes was independent of how they had been produced. Nuclei from the 2-, 4-, or 8-cell stage embryos supported maturation in about 35%, 55% and 60% of cases, respectively. The time between nuclear envelope breakdown and the first meiotic division was shortened by up to 5 h in reconstructed oocytes, a period equivalent to the mitotic division of control blastomeres. About one-third of oocytes reconstituted with blastomere nuclei divided symmetrically instead of extruding a polar body; however, in the majority of them metaphase plates were found, suggesting that reconstructed oocytes (cybrids) underwent a meiotic rather than mitotic division. The highest percentage of asymmetric divisions accompanied by metaphase plates was found in cybrids with 8-cell-stage blastomere nuclei, suggesting that the nuclei from this stage appear to conform best to the cytoplasmic environment of GV ooplasts. Our results indicate that the oocyte cytoplasm is capable of remodelling blastomere nuclei, allowing them to follow the path of the meiotic cell cycle.     

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.     

Oocyte nucleus controls progression through meiotic maturation

We analyzed progression through the meiotic maturation in oocytes manipulated to replace the prophase oocyte nucleus with the nucleus from a cumulus cell, a pachytene spermatocyte or the pronucleus from a fertilized egg. Removal of the oocyte nucleus led to a significant reduction in histone H1 kinase activity. Replacement of the oocyte nucleus by a pronucleus followed by culture resulted in premature pseudomeiotic division and occasional abnormal cytokinesis; however, histone H1 kinase activity was rescued, microtubules formed a bipolar spindle, and chromosomes were condensed. In addition to the anomalies observed after pronuclear transfer, those after transfer of the nucleus from a cumulus cell or spermatocyte included a dramatically impaired ability to form the bipolar spindle or to condense chromosomes, and histone H1 kinase activity was not rescued. Expression of a cyclin B-YFP in enucleated oocytes receiving the cumulus cell nucleus rescued histone H1 kinase activity, but spindle formation and chromosome condensation remained impaired, indicating a pleiotropic effect of oocyte nucleus removal. However, when the cumulus cell nucleus was first transformed into pronuclei (transfer into a metaphase II oocyte followed by activation), such pronuclei supported maturation after transfer into the oocyte in a manner similar to that of normal pronuclei. These results show that the oocyte nucleus contains specific components required for the control of progression through the meiotic maturation and that some of these components are also present in pronuclei.     

卵母细胞的生发泡移植

生发泡(germinal vesicle,GV)移植到去核的GV期卵母细胞后,获得重构卵,重构卵在体外能成熟,受精和进行胚胎发育。GV移植到去核的第二次减数分裂中期(metaphase Ⅱ,MII)卵母细胞后,重构卵能发生GV破裂,但难以排出第一极体。GV移植后,通过连续核移植,重构合子具有发育到终期的能力。GV移植为研究卵母细胞的发育提供了一种重要工具。     

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.     

Changes in histone acetylation during mouse oocyte meiosis

We examined global changes in the acetylation of histones in mouse oocytes during meiosis. Immunocytochemistry with specific antibodies against various acetylated lysine residues on histones H3 and H4 showed that acetylation of all the lysines decreased to undetectable or negligible levels in the oocytes during meiosis, whereas most of these lysines were acetylated during mitosis in preimplantation embryos and somatic cells. When the somatic cell nuclei were transferred into enucleated oocytes, the acetylation of lysines decreased markedly. This type of deacetylation was inhibited by trichostatin A, a specific inhibitor of histone deacetylase (HDAC), thereby indicating that HDAC is able to deacetylate histones during meiosis but not during mitosis. Meiosis-specific deacetylation may be a consequence of the accessibility of HDAC1 to the chromosome, because HDAC1 colocalized with the chromosome during meiosis but not during mitosis. As histone acetylation is thought to play a role in propagating the gene expression pattern to the descendent generation during mitosis, and the gene expression pattern of differentiated oocytes is reprogrammed during meiosis to allow the initiation of a new program by totipotent zygotes of the next generation, our results suggest that the oocyte cytoplasm initializes a program of gene expression by deacetylating histones.     

Injection of frozen-thawed porcine first polar bodies into enucleated oocytes results in fertilization and embryonic development

The objective was to determine whether enucleated oocytes injected with frozen porcine first polar bodies (pPB1s) could be fertilized and developed into viable embryos in vitro. Metaphase II (MII) oocytes with pPB1s were frozen (vitrified) and stored for 2 mo. The pPB1s were isolated from thawed MII oocytes and injected into enucleated recipient oocytes by micromanipulation. All recipients injected with thawed pPB1s were fertilized by intracytoplasmic sperm injection (ICSI), and the resulting recombinant zygotes were incubated to assess their developmental competence in vitro. Furthermore, double-antibody immunohistochemistry was used to verify that the nucleus of the pPB1 participated in fertilization and supported embryonic development. Porcine embryos (2- to 8-cell stage) were obtained from the recombinants. The average in vitro cleavage rate of 2-, 4-, and 8-cell stage recombinant embryos was 25.3, 17.7, and 9.3% (P < 0.05), respectively. Chromosomes in the labeled pPB1 participated in the formation of the two blastomere nuclei of 2-cell stage embryos derived from recombinant oocytes. In conclusion, nuclear materials of frozen-thawed pPB1 supported oocyte fertilization and subsequent embryonic development, thereby providing a new way to use frozen PB1s for preservation and reproduction of mammals.     

Porcine nuclei in early growing stage do not possess meiotic competence in matured oocytes

To determine whether the nuclei of early growing stage porcine oocytes can mature to the MII stage, we examined meiotic competence of nuclei that had been fused with enucleated GV oocytes using the nuclear transfer method. In vitro matured oocytes were enucleated and then fused with early growing oocytes (30-40 μm in diameter) from 5 to 7-wk-old piglets using the hemagglutinating virus of Japan (HVJ). Reconstructed oocytes were cultured for 24 h to the MII stage. Although these oocytes extruded the first polar body, they did not contain normal haploid chromosomes, and the spindles were misaligned or absent at the metaphase II (MII) stage. Furthermore, maturation promoting factor (MPF) activity levels were low in oocytes reconstructed with early growing oocytes at metaphase I (MI) and MII. In contrast, mitogen-activated protein kinase (MAPK) activity was detected between the MI and MII stages, although at slightly lower levels. In conclusion, the nuclei of early growing oocytes did not accomplish normal meiotic division in matured oocytes due to misaligned or absent spindle formation.     

Nuclear transplantation in the mouse: heritable differences between parental genomes after activation of the embryonic genome

Paternal and maternal genomes apparently have complementary roles during embryogenesis in the mouse, and both are essential for development to term. However, there is no direct evidence to show that functional differences between parental genomes remain intact after activation of the embryonic genome at the 2-cell stage. In this study we demonstrate that transfer of paternal or maternal nuclei from early haploid preimplantation embryos back to fertilized eggs from which one pronucleus was removed resulted in development to term, but only if the remaining pronucleus was of the parental type opposite to the donor nucleus. Hence, functional differences between parental chromosomes are heritable and they survive activation of the embryonic genome and probable reprogramming of donor embryonic nuclei by epigenetic factors in the egg cytoplasm.     

Full-term development of rat after transfer of nuclei from two-cell stage embryos

Cloning technology would allow targeted genetic alterations in the rat, a species which is yet unaccessible for such studies due to the lack of germline-competent embryonic stem cells. The present study was performed to examine the developmental ability of reconstructed rat embryos after transfer of nuclei from early preimplantation stages. We observed that single blastomeres from two-cell embryos and zygotes reconstructed by pronuclei exchange can develop in vitro until morula/blastocyst stage. When karyoplasts from blastomeres were used for the reconstruction of embryos, highest in vitro cleavage rates were obtained with nuclei in an early phase of the cell cycle transferred into enucleated preactivated oocytes or zygotes. However, further in vitro development of reconstructed embryos produced from blastomere nuclei was arrested at early cleavage stages under all conditions tested in this study. In contrast, immediate transfer to foster mothers of reconstructed embryos with nuclei from two-cell embryos at an early stage of the cell cycle in preactivated enucleated oocytes resulted in live newborn rats, with a general efficiency of 0.4%-2.2%. The genetic origin of the cloned offspring was verified by using donor nuclei from embryos of Black Hooded Wistar rats and transgenic rats carrying an ubiquitously expressed green fluorescent protein transgene. Thus, we report for the first time the production of live cloned rats using nuclei from two-cell embryos.     

Checkpoint for DNA integrity at the first mitosis after oocyte activation

Activation of oocytes, arrested at the meiosis II (MII) in mammals, initiates meiotic release, mitotic divisions, and development. Unlike most somatic cell types, MII arrested female germ cells lack an efficient DNA integrity checkpoint control. Here we present evidence showing a unique checkpoint for DNA integrity at first mitosis after oocyte activation. Mouse oocytes carrying intact DNA cleaved normally after meiotic release, whereas 50% of oocytes harboring damaged DNA manifested cytofragmentation, a morphological hallmark of apoptosis. If not activated, DNA-damaged MII oocytes did not show apoptotic fragmentation. Further, activated, enucleated oocytes or enucleated fertilized oocytes also underwent cytofragmentation, implicating cytoplasmic coordination of the fragmentation process, independent of the nucleus. Depolymerization of either actin filaments or microtubules induced no cytofragmentation, but inhibited fragmentation upon oocyte activation. During the process of fragmentation, microtubule networks formed, then microtubule asters congregated at discrete locations, around which fragmented cellular bodies formed. Mitotic spindles, however, were not formed inactivated oocytes with damaged or absent DNA; in contrast, normal mitotic spindles were formed in activated oocytes with intact DNA. These results demonstrate that damaged DNA or absence of DNA leads to cytofragmentation after oocyte activation. Further, we found a mechanism of cytoskeletal involvement in the process of cytofragmentation. In addition, possible implication of the present findings in somatic cell cloning and human clinical embryology is discussed.