Andrzej K. Tarkowski

Electrofusion of mouse blastomeres

Fusion of blastomeres of 2-cell mouse embryos with an intact zona pellucida can be induced with electric pulses. Fusion was most frequent with the field strength of 1 kV/cm and direct current pulses of 100-250 microsec duration. An electrolyte solution (PBS) can be used instead of a non-electrolyte solution (0.3 M mannitol). The viability of blastomeres fused in these two types of solution is similar. Fused 2-cell blastomeres develop into tetraploid blastocysts but die after implantation. Embryos in which blastomeres failed to fuse despite the treatment (diploid controls) can develop till term. The technique can also be applied to 3- and 4-cell embryos and to zona-free oocytes and blastomeres.

Blastomeres of the mouse embryo lose totipotency after the fifth cleavage division: expression of Cdx2 and Oct4 and developmental potential of inner and outer blastomeres of 16- and 32-cell embryos.

Sixteen inner or outer blastomeres from 16-cell embryos and 32 inner or outer blastomeres from 32-cell embryos (nascent blastocysts) were reaggregated and cultured in vitro. In 24 h old blastocysts developed from blastomeres derived from 16-cell embryos the expression of Cdx2 protein was upregulated in outer cells (new trophectoderm) of the inner cells-derived aggregates and downregulated in inner cells (new inner cell mass) of the external cells-derived aggregates. After transfer to pseudopregnant recipients blastocysts originating from both inner and outer blastomeres of 16-cell embryo developed into normal, fertile mice, but the implantation rate of embryos formed from inner cell aggregates was lower. The aggregates of external blastomeres derived from 32 cell embryo usually formed trophoblastic vesicles accompanied by vacuolated cells. In contrast, the aggregates of inner blastomeres quickly compacted but cavitation was delayed. Although in the latter embryos the Cdx2 protein appeared in the new trophectoderm within 24 h of in vitro culture, these embryos formed only very small outgrowths of Troma1-positive giant trophoblastic cells and none of these embryos was able to implant in recipient females. In separate experiment we have produced normal and fertile mice from 16- and 32-cell embryos that were first disaggregated, and then the sister outer and inner blastomeres were reaggregated at random. In blastocysts developed from aggregates, within 24 h of in vitro culture, the majority of inner and outer blastomeres located themselves in their original position (internally and externally), which implies that in these embryos development was regulated mainly by cell sorting.

The role of germinal vesicle karyoplasm in the development of male pronucleus in the mouse

Abstract Zona-free mouse ovarian oocytes from Swiss albino females were bisected into nucleate and anucleate halves at the germinal vesicle stage (1), shortly after germinal vesicle breakdown (GVBD) (2) and in metaphase I (3). Sister halves were cultured for 15–17 h (ser. 1, 2) or 6.5–7.5 h (ser. 3) and those in which the nucleate fragment extruded the first polar body, were fertilized with F1(C57BL/10 × CBA/H) spermatozoa. After an additional period of culture lasting for 6–7 1 2 (1, 2) or 16–17 h (3) the cells were fixed and examined in whole-mount preparations. Intact oocytes recovered from follicles at the same stages as those used for bisection, and ovulated oocytes (both zona-free) served as controls. Nucleate fragments and intact ovarian oocytes were fertilized in 65% and in the majority of them sperm heads were transformed into pronuclei; no differences were observed between the three series in the rate of fertilization and development of pronuclei. In anucleate oocyte fragments development of male pronuclei took place only if the dissolution of germinal vesicle had occurred prior to bisection. It is concluded that in the mouse, the germinal vesicle material is essential for transformation of sperm nucleus into the functional male pronucleus.

Individual blastomeres of 16- and 32-cell mouse embryos are able to develop into foetuses and mice.

Cell and developmental studies have clarified how, by the time of implantation, the mouse embryo forms three primary cell lineages: epiblast (EPI), primitive endoderm (PE), and trophectoderm (TE). However, it still remains unknown when cells allocated to these three lineages become determined in their developmental fate. To address this question, we studied the developmental potential of single blastomeres derived from 16- and 32-cell stage embryos and supported by carrier, tetraploid blastomeres. We were able to generate singletons, identical twins, triplets, and quadruplets from individual inner and outer cells of 16-cell embryos and, sporadically, foetuses from single cells of 32-cell embryos. The use of embryos constitutively expressing GFP as the donors of single diploid blastomeres enabled us to identify their cell progeny in the constructed 2n↔4n blastocysts. We showed that the descendants of donor blastomeres were able to locate themselves in all three first cell lineages, i.e., epiblast, primitive endoderm, and trophectoderm. In addition, the application of Cdx2 and Gata4 markers for trophectoderm and primitive endoderm, respectively, showed that the expression of these two genes in the descendants of donor blastomeres was either down- or up-regulated, depending on the cell lineage they happened to occupy. Thus, our results demonstrate that up to the early blastocysts stage, the destiny of at least some blastomeres, although they have begun to express markers of different lineage, is still labile.

Sperm penetration into immature mouse oocytes and nuclear changes during maturation: an EM study.

The ultrastructure of oocyte and sperm nuclei was studied in mouse ovarian oocytes inseminated in vitro and cultured for 1 1/2 and 3 h in a medium containing dbcAMP or lacking the maturation inhibitor. In oocytes blocked at the germinal vesicle (GV) stage, certains maturation‐linked changes were noted. Sperm apposition and sperm‐oocyte fusion were similar to that during fertilization of ovulated oocytes. The sperm nucleus and its nuclear envelope remained intact after penetrating into the ovarian oocyte. One and a half h after removal of the drug (time 0 of maturation) the germinal vesicle (GV) and sperm nucleus remained intact. In oocytes maturing for 3 h, the nuclear envelopes of the GV and sperm nucleus had fragmented. The NE of the oocyte formed quadruple membranes while the NE of the sperm remained as flat vesicles. Oocyte chromatin condensed to form chromosomes, whereas at the same time the sperm chromatin was in the process of decondensation and was surrouded by fragments of the sperm NE. The sperm chromatin, composed of DNA complexed with protamines, consisted of thin fibrils; the individual fibrils measured 3.8 nm in diameter. Near the penetrated spermatozoa only occasional Mts were detected which were not related to the proximal centriole which was recognizable in the neck‐piece of the flagellum. Thus in mouse oocytes the introduced sperm centriole is not capable of behaving as a centrosome and organizing microtubules in the form of an aster.

Delayed sperm incorporation into parthenogenetic mouse eggs : Sperm nucleus transformation and development of resulting embryos

In this study we examined the effect of experimentally induced asynchrony between male and female pronuclei on male pronucleus formation and developmental potential of the resulting mouse embryos. We demonstrate that when the interval between oocyte activation and sperm incorporation is up to 1.5–2 hr, the spermatozoa transform into normal pronuclei. These male pronuclei can replicate their chromosomes during the first embryonic cell cycle and are transcriptionally competent. During the first cleavage these “delayed” male pronuclei condense into discrete mitotic chromosomes and when resulting embryos are transplanted into oviducts of pregnant females at least some of them can develop to term. In contrast, when sperm nuclei are introduced into parthenogenetic eggs 3 hr or more after activation, their transformation into pronuclei is significantly impaired, and they neither replicate nor transcribe. During the first mitosis they form a group of condensed chromatin, which is displaced into one of the resulting blastomeres leading to formation of haploid/diploid mosaic embryos. These mosaic embryos have poor developmental potential: only a few can reach blastocyst stage in vitro and no full‐term development of such embryos was observed after transfer into pregnant females. We conclude that the cytoplasmic factors that make possible the transformation of a sperm nucleus into a functional male pronucleus exhaust within 1.5–2 hr after fertilization and that the male genome which had skipped the first cell cycle cannot become a functional partner in the embryonic genome. Mol. Reprod. Dev. 54:303–310, 1999.

Fertilization of nucleate and anucleate egg fragments in the mouse

Abstract Ovulated mouse eggs were bisected into one anucleate and one nucleate half which carried the spindle of metaphase II. Both types of fragment can be fertilized and can develop at least to the 2-cell stage. The number of spermatozoa penetrating into the fragments varied both within and between experimental subgroups, but on average the anucleate and nucleate fragments were penetrated by a similar number of sperm. Anucleate egg halves tended to complete the first cleavage division faster than their nucleate counterparts. Since the latter have had an average of one more pronucleus (female), it is concluded that the duration of the first cell cycle is inversely correlated with ploidy. Dispermic anucleate fragments represent a potential source of diploid embryos (animals?) with a genome of exclusively paternal origin.

Transcription and DNA replication of sperm nuclei introduced into blastomeres of 2-cell mouse embryos.

The aim of this study was to investigate the behaviour of sperm nuclei in the cytoplasm of the 2-cell mouse embryo. To this end, we produced hybrids between anucleate fertilised oocyte fragments and blastomeres of the 2-cell embryos. When sperm nuclei at the stage of decondensation or recondensation were introduced into blastomeres the development of male pronuclei was usually retarded and they never reached the size of the blastomere nuclei. These abortive male pronuclei were unable to initiate transcription but they were capable of synthesising DNA. The majority of sperm nuclei introduced into blastomeres as early male pronuclei developed normally and reached the size of the blastomere nuclei. They synthesised DNA simultaneously with blastomere nuclei and were transcriptionally active. In addition they participated in the cleavage division of hybrid cells. This shows that the very early male pronucleus when transmitted from the oocyte cytoplasm to the blastomere cytoplasm can respond positively to the new cytoplasmic factors, i.e. it undertakes both DNA replication and transcription according to the time schedule characteristic of the second cell cycle.

Haploid maternal genome derived from early diplotene oocytes can substitute for the female pronucleus in preimplantation mouse development

We describe the preimplantation development of mouse embryos that have received the haploid maternal genome derived from early diplotene nuclei of primordial oocytes (PO). Two generations of recipient egg‐cells were used. Induction of two meiotic divisions of the PO nucleus and the reduction of the number of chromosomes to the haploid level were achieved in preovulatory oocytes (primary recipients). The developmental potential of the obtained haploid genome was examined in zygotes (secondary recipients).

Pluripotency of bank vole embryonic cells depends on FGF2 and activin A signaling pathways.

The objective of this study was to investigate the capability of bank vole (Myodes glareolus) embryonic cells to sustain their pluripotent character during in vitro culture, and to determine the optimal conditions for derivation of embryonic stem (ES) cells. We compared the presence of specific pluripotency (Oct4, Ssea1) and differentiation markers (Gata4 - primitive endoderm marker; Cdx2 - trophectoderm marker) in blastocysts and inner cell mass (ICM) outgrowths obtained from blastocysts of bank vole, and two mouse hybrids F1(C57Bl/6xCBA/H) and F1(C57Bl/6x129/Sv), which differ in the permissiveness of giving rise to ES cells. We found that, in contrast to mouse, the expression of pluripotency markers in the cells of bank vole ICM outgrowths is progressively downregulated and rapidly lost by the 4th day of culture. This correlates with the appearance of cells expressing Gata4 and Cdx2, indicating differentiation towards primitive endoderm and derivatives of trophectoderm, respectively. We have also shown that heterologous cytokine leukaemia inhibitory factor (LIF) in conjunction with either homologous or heterologous feeder layer is unable to delay differentiation and preserve pluripotency of bank vole embryonic cells. Thus, the conditions optimised for mouse do not support the maintenance of bank vole embryonic cells in the undifferentiated state and do not allow for the isolation of the ES cells. Instead, combination of fibroblast growth factor 2 and activin A allows retention of Oct4 expression in bank vole blastocyst outgrowths during 4-day culture, indicating that signaling pathways operating in human, rather than mouse ES cells, might be involved in the process of self-renewal of bank vole embryonic cells.