Pierre Adenot

Cloned rabbits produced by nuclear transfer from adult somatic cells.

We have developed a method to produce live somatic clones in the rabbit, one of the mammalian species considered up to now as difficult to clone. To do so, we have modified current cloning protocols proven successful in other species by taking into account both the rapid kinetics of the cell cycle of rabbit embryos and the narrow window of time for their implantation after transfer into foster recipients. Although our method still has a low level of efficiency, it has produced several clones now proven to be fertile. Our work indicates that cloning can probably be carried out successfully in any mammalian species by taking into account physiological features of their oocytes and embryos. Our results will contribute to extending the use of rabbit models for biomedical research.

Developmental Potential of Mouse Embryos Reconstructed from Metaphase Embryonic Stem Cell Nuclei

Abstract Mice have recently been successfully cloned from embryonic stem (ES) cells. However, these fast dividing cells provide a heterogenous population of donor nuclei, in terms of cell cycle stage. Here we used metaphases as a source of donor nuclei because they offer the advantage of being both unambiguously recognizable and synchronous with the recipient metaphase II oocyte. We showed that metaphases from ES cells can provide a significantly higher development rate to the morula or blastocyst stage (56–70%) than interphasic nuclei (up to 28%) following injection into a recipient oocyte. Selective detachment of mitotic cells after a demecolcin treatment greatly facilitates and accelerates the reconstruction of embryos by providing a nearly pure population of cells in metaphase and did not markedly affect the developmental rate. Most of the blastocysts obtained by this procedure were normal in terms of both morphology and ratio of inner cell mass and total cell number. After transfer into pseudopregnant recipients at the one- or two-cell stage, the ability of metaphase to be fully reprogrammed was demonstrated by the birth of two pups (1.5% of activated oocytes). Although the implantation rate was quite high (up to 32.9% of activated oocytes), the postimplantation development was characterized by a high and rapid mortality. Our data provide a clear situation to explore the long-lasting effects that can be induced by early reprogramming events.

Nuclear translocation and carboxyl-terminal domain phosphorylation of RNA polymerase II delineate the two phases of zygotic gene activation in mammalian embryos

In mammalian embryos, zygotic gene transcription initiates after a limited number of cell divisions through a two‐step process termed the zygotic gene activation (ZGA). Here we report that RNA polymerase II undergoes major changes in mouse and rabbit preimplantation embryos during the ZGA. In transcriptionally inactive unfertilized oocytes, the RNA polymerase II largest subunit is predominantly hyperphosphorylated on its carboxy‐terminal domain (CTD). The CTD is markedly dephosphorylated several hours after fertilization, before the onset of a period characterized by a weak transcriptional activity. The largest subunit of RNA polymerase II then lacks immunological and drug‐sensitivity characteristics related to its phosphorylation by the TFIIH‐associated kinase and gradually translocates into the nuclei independently of DNA replication and mitosis. A phosphorylation pattern of the largest subunit, close to that observed in somatic cells, is established in both mouse and rabbit embryos at the stage when transcription becomes a requirement for further development (respectively at the 2‐ and 8/16‐cell stage). As these events occurred in the presence of actinomycin D, the nuclear translocation of RNA polymerase II and the phosphorylation of the CTD might be major determinants of ZGA.

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.

3D-FISH analysis of embryonic nuclei in mouse highlights several abrupt changes of nuclear organization during preimplantation development

BackgroundEmbryonic development proceeds through finely tuned reprogramming of the parental genomes to form a totipotent embryo. Cells within this embryo will then differentiate and give rise to all the tissues of a new individual. Early embryonic development thus offers a particularly interesting system in which to analyze functional nuclear organization. When the organization of higher-order chromatin structures, such as pericentromeric heterochromatin, was first analyzed in mouse embryos, specific nuclear rearrangements were observed that correlated with embryonic genome activation at the 2-cell stage. However, most existing analyses have been conducted by visual observation of fluorescent images, in two dimensions or on z-stack sections/projections, but only rarely in three dimensions (3D).ResultsIn the present study, we used DNA fluorescent in situ hybridization (FISH) to localize centromeric (minor satellites), pericentromeric (major satellites), and telomeric genomic sequences throughout the preimplantation period in naturally fertilized mouse embryos (from the 1-cell to blastocyst stage). Their distribution was then analyzed in 3D on confocal image stacks, focusing on the nucleolar precursor bodies and nucleoli known to evolve rapidly throughout the first developmental stages. We used computational imaging to quantify various nuclear parameters in the 3D-FISH images, to analyze the organization of compartments of interest, and to measure physical distances between these compartments.ConclusionsThe results highlight differences in nuclear organization between the two parental inherited genomes at the 1-cell stage, i.e. just after fertilization. We also found that the reprogramming of the embryonic genome, which starts at the 2-cell stage, undergoes other remarkable changes during preimplantation development, particularly at the 4-cell stage.

Dynamics of DNA methylation levels in maternal and paternal rabbit genomes after fertilization.

The reprogramming of DNA methylation in early embryos has been considered to be essential for the reprogramming of differentiated parental genomes to totipotency, the transcription of embryonic genome activation (EGA) and subsequent development. However, its degree appears to differ as a function of species and it may be altered by the in vitro environment. While the rabbit is a pertinent model for species with a delayed EGA because both in vivo and in vitro developed embryos are easily available, the status of DNA methylation levels in both parental genomes after fertilization remains controversial. In order to generate precise data on the DNA methylation status in rabbit zygotes, we first of all defined five pronuclear (PN) stages during the first cell cycle and then classified in vivo and in vitro developed rabbit zygotes according to these PN stages. Using this classification we precisely quantified both methylated DNA and the total DNA content during the one cell stage. The quantification of methylated DNA, normalized for the total DNA content, showed that both pronuclei displayed distinct patterns of DNA methylation reprogramming. In the maternal pronucleus (MP) the methylation level remained constant throughout the one cell stage, thanks to maintenance methylation during the S phase. Conversely, in the paternal pronucleus (PP) partial demethylation occurred before replication, probably as a result of active DNA demethylation, while maintenance methylation subsequently occurred during the S phase. Interestingly, we showed that PP DNA methylation reprogramming was partially altered by the in vitro environment. Taken together, our approach evidenced that rabbit is one of the species displaying partial DNA demethylation in the PP, and for the first time demonstrated maintenance methylation activity in both pronuclei during the first S phase.

Dynamics of constitutive heterochromatin: two contrasted kinetics of genome restructuring in early cloned bovine embryos

Efficient reprograming of the donor cell genome in nuclear transfer (NT) embryos is linked to the ability of the embryos to sustain full-term development. As the nuclear architecture has recently emerged as a key factor in the regulation of gene expression, we questioned whether early bovine embryos obtained from transfer of cultured fibroblasts into enucleated oocytes would adopt an embryo-like nuclear organization. We studied the dynamics of constitutive heterochromatin in the stages prior to embryonic genome activation by distribution analysis of heterochromatin protein CBX1 (HP1), centromeric proteins CENPA and CENPB, and histone H3 three-methylated at lysine 9. Then we applied descriptive, quantitative, and co-localization analyses. A dramatic reorganization of heterochromatic blocks of somatic donor cells was first observed in the late one-cell stage NT embryos. Then at two- and four-cell stages, we found two types of NT embryos: one displaying noncondensed heterochromatin patches similar to IVF embryos, whereas the second type displayed condensed heterochromatin blocks, normally observed in IVF embryos only after the eight-cell stage. These analyses discriminate for the first time two contrasted types of nuclear organization in NT embryos, which may correspond to different functional states of the nuclei. The relationship with the somatic nucleus reprograming efficiency is discussed.

PTGS2-Related PGE2 Affects Oocyte MAPK Phosphorylation and Meiosis Progression in Cattle: Late Effects on Early Embryonic Development

During the periovulatory period, the induction of prostaglandin G/H synthase-2 (PTGS2) expression in cumulus cells and associated prostaglandin E2 (PGE2) production are implicated in the terminal differentiation of the cumulus-oocyte complex. During the present study, the effects of the PTGS2/PGE2 pathway on the developmental competence of bovine oocytes were investigated using an in vitro model of maturation, fertilization, and early embryonic development. The specific inhibition of PTGS2 activity with NS-398 during in vitro maturation (IVM) significantly restricted mitogen-activated protein kinase (MAPK) activation in oocytes at the germinal vesicle breakdown stage and reduced both cumulus expansion and the maturation rate after 22 h of culture. In addition, significantly higher rates of abnormal meiotic spindle organization were observed after 26 h of culture. Periconceptional PTGS2 inhibition did not affect fertilization but significantly reduced the speed of embryo development. Embryo output rates were significantly decreased on Day 6 postfertilization but not on Day 7. However, total blastomere number was significantly lower in embryos obtained after PTGS2 inhibition. The addition of PGE2 to IVM and in vitro fertilization cultures containing NS-398 overrode oocyte maturation and early embryonic developmental defects. Protein and mRNA expression for the prostaglandin E receptor PTGER2 were found in oocytes, whereas the PTGER2, PTGER3, and PTGER4 subtypes were expressed in cumulus cells. This study is the first to report the involvement of PGE2 in oocyte MAPK activation during the maturation process. Taken together, these results indicate that PGE2-mediated interactions between somatic and germ cells during the periconceptional period promote both in vitro oocyte maturation and preimplantation embryonic development in cattle.

The nuclear localization of WAP and CSN genes is modified by lactogenic hormones in HC11 cells

Whey acidic protein (WAP) and casein (CSN) genes are among the most highly expressed milk protein genes in the mammary gland of the lactating mouse. Their tissue‐specific regulation depends on the activation and recruitment of transcription factors, and chromatin modifications in response to hormonal stimulation. We have investigated if another mechanism, such as specific positioning of the genes in the nucleus, could be involved in their functional regulation. Fluorescent in situ hybridization was used to study the nuclear localization of WAP and CSN genes in mouse mammary epithelial cells (HC11) cultured in the absence and presence of lactogenic hormones. Automatic 3D image processing and analysis tools were developed to score gene positions. In the absence of lactogenic hormones, both genes are distributed non‐uniformly within the nucleus: the CSN locus was located close to the nuclear periphery and the WAP gene tended to be central. Stimulation by lactogenic hormones induced a statistically significant change to their distance from the periphery, which has been described as a repressive compartment. The detection of genes in combination with the corresponding chromosome‐specific probe revealed that the CSN locus is relocated outside its chromosome territory following hormonal stimulation, whereas the WAP gene, which is already sited more frequently outside its chromosome territory in the absence of hormones, is not affected. We conclude that milk protein genes are subject to nuclear repositioning when activated, in agreement with a role for nuclear architecture in gene regulation, but that they behave differently as a function of their chromosomal context. J. Cell. Biochem. 105: 262–270, 2008.

Nuclear dynamics of histone H3 trimethylated on lysine 9 and/or phosphorylated on serine 10 in mouse cloned embryos as new markers of reprogramming?

Somatic cell nuclear transfer (SCNT) is the injection of a donor nucleus into an enucleated egg. Despite the use of this technology for many years in research, it is still quite inefficient. One of the causes for this is thought to be incorrect or incomplete genome reprogramming. Embryos produced by nuclear transfer (cloned embryos) very often present abnormal epigenetic signatures and irregular chromatin reorganization. Of these two issues, the issue of chromatin rearrangements within the nuclei after transfer is the least studied. It is known that cloned embryos often present pericentromeric heterochromatin clumps very similar to the chromocenters structures present in the donor nuclei. Therefore, it is believed that the somatic nuclear configuration of donor nuclei, especially that of the chromocenters, is not completely lost after nuclear transfer, in other words, not well reprogrammed. To further investigate pericentromeric heterochromatin reorganization after nuclear transfer, we decided to study its rearrangements in cumulus-derived clones using several related epigenetic markers such as H3S10P, H3K9me3, and the double marker H3K9me3S10P. We observed that two of these markers, H3S10P and H3K9me3S10P, are the ones found on the part of the pericentromeric heterochromatin that is remodeled correctly, resembling exactly the embryonic heterochromatin configuration of naturally fertilized embryos. Conversely, H3K9me3 and heterochromatin protein 1 beta (HP1β)-associated protein were also detected in the perinuclear clumps of heterochromatin, making obvious the maintenance of the somatic epigenetic signature within these nuclear regions. Our results demonstrate that H3S10P and H3K9me3S10P could be good candidates for evaluating heterochromatin reorganization following nuclear reprogramming.