Prolactin affects bovine oocytes through direct and cumulus-mediated pathways.

The available evidence points to participation of PRL in regulation of mammalian oocyte maturation. The aim of the present study was to characterize pathways of PRL action on bovine oocytes. We analyzed (1) the presence of the PRL receptor and its mRNA isoforms in oocytes and cumulus cells; (2) the effect of PRL on meiosis resumption and the role of cumulus cells, the NO/NO synthase system, protein kinase C, and tyrosine kinases in this effect; and (3) PRL effects in the presence of gonadotropins on the developmental capacity of cumulus-free and cumulus-enclosed oocytes. The transcript and protein expression of the PRL receptor in the cells were detected by reverse transcription polymerase chain reaction and immunocytochemistry, respectively. The nuclear status of oocytes was assessed after culture of cumulus-oocyte complexes (COCs) and denuded oocytes (DOs) with or without PRL (5-500 ng/mL) for 7, 14, or 24 hours. Besides, DOs were incubated for 7 hours in the absence or the presence of PRL (50 ng/mL) and/or L-NAME (an inhibitor of NO synthase), genistein (an inhibitor of tyrosine kinases), or calpostin C (a protein kinase C inhibitor). After IVM in 2 different systems containing PRL (50 ng/mL) and/or gonadotropic hormones, a part of oocytes underwent IVF and IVC and the embryo development was tracked until the blastocyst stage. Messenger RNA of long and short isoforms of the PRL receptor was revealed in both oocytes and cumulus cells. Immunocytochemistry confirmed the presence of the PRL receptor in oocytes and the cumulus investment. In the absence of gonadotropins (system 1), PRL retarded meiosis resumption in DOs but not in cumulus-enclosed oocytes, with this effect being short term, dose dependent, suppressed by L-NAME and genistein, and unaffected by calpostin. In systems containing gonadotropins, PRL did not affect nuclear maturation and the cleavage rate of cumulus-free and cumulus-enclosed oocytes. However, in the case of COCs, it raised the blastocyst yield both in system 2 (from 20.5%-40.9%, P < 0.01) and in system 3 (from 21.7%-33.9%, P < 0.05). The findings show for the first time the functioning of the direct pathway of PRL signaling into bovine oocytes, as confirmed by the expression of receptors of PRL and its direct meiosis-retarding effect involving activation of tyrosine kinases and NO synthase. Furthermore, this is the first demonstration that the beneficial effect of PRL on the oocyte developmental capacity is achieved via cumulus cells containing PRL receptors.

Early aberrations in chromatin dynamics in embryos produced under in vitro conditions.

In vitro production of porcine embryos by means of in vitro fertilization (IVF) or somatic cell nuclear transfer (SCNT) is limited by great inefficienciy. The present study investigated chromatin and nucleolar dynamics in porcine embryos developed in vivo (IV) and compared this physiological standard to that of embryos produced by IVF, parthenogenetic activation (PA), or SCNT. In contrast to IV embryos, chromatin spatial and temporal dynamics in PA, IVF, and SCNT embryos were altered; starting with aberrant chromatin-nuclear envelope interactions at the two-cell stage, delayed chromatin decondensation and nucleolar development at the four-cell stage, and ultimately culminating in failure of proper first lineage segregation at the blastocyst stage, demonstrated by poorly defined inner cell mass. Interestingly, in vitro produced (IVP) embryos also lacked a heterochromatin halo around nucleolar precursors, indicating imperfections in global chromatin remodeling after fertilization/activation. Porcine IV-produced zygotes and embryos display a well-synchronized pattern of chromatin dynamics compatible with genome activation and regular nucleolar formation at the four-cell stage. Production of porcine embryos under in vitro conditions by IVF, PA, or SCNT is associated with altered chromatin remodeling, delayed nucleolar formation, and poorly defined lineage segregation at the blastocyst stage, which in turn may impair their developmental capacity.

Changes of DNA methylation level and spatial arrangement of primordial germ cells in embryonic day 15 to embryonic day 28 pig embryos.

The mammalian germline is generally assumed to undergo extensive epigenetic reprogramming during embryonic development, including a nearly complete erasure of DNA methylation. This assumption does, however, to large degree rely on data from mouse, and despite a well-grounded picture the general nature of these data needs to be validated by investigations of other mammalian species. This study represents such a contribution in the examination of the germline in the domestic pig (Sus scrofa). Semiquantitative immunohistochemistry was used to investigate the level of DNA methylation in the POU5F1-positive primordial germ cells (PGCs) compared with neighboring somatic cells in porcine embryos at Embryonic Day 15 (E15), E17, E20, E21, and E28. We show that, in agreement with the mouse model, a significantly lower level of DNA methylation was observed in the early migrating PGCs. This level was decreasing until a stage coinciding with the entrance of the PGCs to the genital ridge. After this, the methylation level increased. Using whole-mount immunostaining, we determined the spatial arrangement of the porcine PGCs in the period between E15 and E28, allowing some comparison with the migration of the murine germline. The overall conclusion from the obtained data is that the DNA methylation changes in porcine PGCs, as well as the migration of these cells, parallels the picture reported for the mouse.

DNA methylation in porcine preimplantation embryos developed in vivo and produced by in vitro fertilization, parthenogenetic activation and somatic cell nuclear transfer.

DNA demethylation and remethylation are crucial for reprogramming of the differentiated parental/somatic genome in the recipient ooplasm upon somatic cell nuclear transfer. Here, we analyzed the DNA methylation dynamics during porcine preimplantation development. Porcine in vivo developed (IV), in vitro fertilized (IVF), somatic cell nuclear transfer (SCNT) and parthenogenetically activated (PA) embryos were evaluated for DNA methylation quantification at different developmental stages. Fertilized (IV and IVF) one-cell stages lacked a substantial active demethylation of the paternal genome. Embryos produced under in vitro conditions had higher levels of DNA methylation than IV. A lineage-specific DNA methylation (hypermethylation of the inner cell mass and hypomethylation of the trophectoderm) was observed in porcine IV late blastocysts, but was absent in PA- and SCNT-derived blastocysts despite the occurrence of de novo methylation in early blastocysts. Comparable levels of DNA methylation were found in IV embryos and in 50% and 14% of SCNT early and late blastocysts, respectively. In conclusion, DNA methylation patterns were adversely affected by in vitro embryo production.

Reelin expression during embryonic development of the pig brain.

BACKGROUND: Reelin is an extracellular glycoprotein of crucial importance in the developmental organisation of neurons in the mammalian cerebral cortex and other laminated brain regions. The pig possesses a gyrencephalic brain that bears resemblance to the human brain. In order to establish an animal model for neuronal migration disorders in the pig, we have studied the expression pattern and structure of Reelin during pig brain development. RESULTS: We determined the sequence of pig Reelin mRNA and protein and identified a high degree of homology to human Reelin. A peak in Reelin mRNA and protein expression is present during the period of major neurogenesis and neuronal migration. This resembles observations for human brain development. Immunohistochemical analysis showed the highest expression of Reelin in the Cajal-Reztius cells of the marginal zone, in resemblance with observations for the developing brain in humans and other mammalian species. CONCLUSIONS: We conclude that the pig might serve as an alternative animal model to study Reelin functions and that manipulation of the pig Reelin could allow the establishment of an animal model for human neuronal migration disorders.

Confinement and clearance of OCT4 in the porcine embryo at stereomicroscopically defined stages around gastrulation.

In the areas of developmental biology and embryonic stem cell research, reliable molecular markers of pluripotency and early lineage commitment are sparse in large animal species. In this study, we present morphological and immunohistochemical findings on the porcine embryo in the period around gastrulation, days 8-17 postinsemination, introducing a stereomicroscopical staging system in this species. In embryos at the expanding hatched blastocyst stage, OCT4 is confined to the inner cell mass. Following detachment of the hypoblast, and formation of the embryonic disk, this marker of pluripotency was selectively observed in the epiblast. A prominent crescent-shaped thickening at the posterior region of the embryonic disk marked the first polarization within this structure reflecting incipient cell ingression. Following differentiation of the epiblast, clearance of OCT4 from the three germ layers was observed at defined stages, suggesting correlations to lineage specification. In the endoderm, clearance of OCT4 was apparent from early during its formation at the primitive streak stage. The endoderm harbored progenitors of the "fourth germ layer," the primordial germ cells (PGCs), the only cells maintaining expression of OCT4 at the end of gastrulation. In the ectodermal and mesodermal cell lineages, OCT4 became undetectable at the neural groove and somite stage, respectively. As in the mouse, PGCs showed onset of c-kit expression when located in extraembryonal compartments. They appeared to follow the endoderm during extraembryonal allocation and the mesoderm on return to the genital ridge.

Post-hatching development of the porcine and bovine embryo--defining criteria for expected development in vivo and in vitro.

Particular attention has been paid to the pre-hatching period of embryonic development although blastocyst development is a poor indicator of embryo viability. Post-hatching embryonic development in vitro would allow for establishment of more accurate tools for evaluating developmental potential without the need for transfer to recipient animals. Such a system would require (1) definition of milestones of expected post-hatching embryonic development in vivo; and (2) development of adequate culture systems. We propose a stereomicroscopical staging system for post-hatching embryos defining the following stages: (1) Expanded hatched blastocyst stage where the embryo presents an inner cell mass (ICM) covered by trophoblast. (2) Pre-streak stage 1 where the embryonic disc is formed. (3) Pre-streak stage 2 where a crescent-shaped thickening of the caudal portion of the embryonic disk appears. (4) Primitive streak stage where the primitive streak has developed as an axis of cell ingression of cells for meso- and endoderm formation. (5) Neural groove stage where the neural groove is developing from the rostral pole of the embryo along with a proportional shortening of the primitive streak; and (6) Somite stage(s) where paraxial mesoderm gradually condensates to form somites. Post-hatching development of bovine embryos in vitro is compromised and although hatching occurs and elongation can be physically provoked by culture in agarose tunnels, the embryonic disk characterizing the pre-streak stage 1 is never established. Thus, particular focus should be placed on establishing culture conditions that support at least some of the above-mentioned critical phases of development that in vivo occur within the initial two (pig) to three (cattle) weeks.

Effect of leukemia inhibitory factor (LIF) on in vitro produced bovine embryos and their outgrowth colonies.

In vitro produced (IVP) bovine embryos were subjected to in vitro culture with or without 1000 U/ml human recombinant leukemia inhibitory factor (LIF) added to the culture medium from Days 5 to 8 post insemination (p.i.). Resulting blastocysts were subsequently plated intact on mouse feeder cells in a medium with or without LIF. Significantly more embryos reached the hatched blastocyst stage, and the number of blastocysts with excellent morphology was significantly higher, when LIF was omitted. At Day 8 p.i., total cell count (TCC) and inner cell mass (ICM) cell count was significantly higher in embryos cultured without LIF. In embryos cultured with LIF, cytoplasmic vesicles and lipid droplets were abundant and a decreased expression of both Oct4 and laminin could be observed. Initial hypoblast formation was revealed in almost 1/3 of the LIF-cultured blastocysts whereas this feature was evident in 2/3 of the blastocysts cultured in the absence of LIF. Overall, almost 60% of the blastocysts cultured without LIF formed outgrowth colonies (OCs) when plated on feeders, whereas this phenomenon was only observed in 30% of the blastocysts cultured in the presence of LIF. A tendency for retaining a tightly packed central growth of putative ICM-derived cells was observed, when attachment to the feeder layer was initiated close to the embryonic pole of the blastocyst. At Day 8 of outgrowth culture, approximately 20% of the colonies contained a central core of putative ICM-derived cells appearing large enough for mechanical isolation and further subculture. Immunohistochemical labeling for Oct4 revealed staining of both trophectodermal and ICM-derived cells. The presence of LIF in the outgrowth culture medium did not have any apparent effect on the plating efficiency or colony type. In conclusion, LIF had an adverse effect on in vitro embryonic development when added to the culture medium in the period from Days 5 to 8 p.i., whereas it had no apparent effect on the OCs subsequently formed from such embryos.

Ultrastructural and immunohistochemical characterization of the bovine epiblast.

The epiblast represents the final embryonic founder cell population with the potential for giving rise to all cell types of the adult body. The pluripotency of the epiblast is lost during the process of gastrulation. Large animal species have a lack of specific markers for pluripotency. The aim of the present study was to characterize the bovine epiblast cell population and to provide such markers. Bovine Day 12 and Day 14 embryos were processed for transmission-electron microscopy or immunohistochemistry. In Day 12 embryos, two cell populations of the epiblast were identified: one constituting a distinctive basal layer apposing the hypoblast, and one arranged inside or above the former layer, including cells apposing the Rauber layer. Immunohistochemically, staining for the octamer-binding transcription factor 4 (OCT4, also known as POU5F1), revealed a specific and exclusive staining of nuclei of the complete epiblast. Colocalization of vimentin and OCT4 was demonstrated. Only trophectodermal cells stained for alkaline phosphatase. Staining for the proliferation marker Ki-67 was localized to most nuclei throughout the epiblast. A continuous staining for zonula occludens-1 protein was found between cells of the trophectoderm and hypoblast but was not evident in the epiblast. A basement membrane, detected by staining for laminin, formed a "cup-like" structure in which the epiblast was located. The ventrolateral sides of the cup appeared to be incomplete. In conclusion, the bovine epiblast includes at least two cell subpopulations, and OCT4 was shown, to our knowledge for the first time, to be localized exclusively to epiblast cells in this species.