Maternal-to-embryonic Transition Research Articles

Comparing mRNA and sncRNA profiles during the maternal-to-embryonic transition in bovine IVF and scNT embryos†.

Production of embryos with high developmental competence by somatic cell nuclear transfer (scNT) is far less efficient than for in vitro fertilized (IVF) embryos, likely due to an accumulation of errors in genome reprogramming that results in aberrant expression of RNA transcripts, including messenger RNAs (mRNA) and, possibly, microRNAs (miRNA). Thus, our objectives were to use RNAseq to determine the dynamics of mRNA expression in early developing scNT and IVF embryos in the context of the maternal-to-embryonic transition (MET) and to correlate apparent transcriptional dysregulation in cloned embryos with miRNA expression profiles. Comparisons between scNT and IVF embryos indicated large scale transcriptome differences, which were most evident at the 8-cell and morula stages for genes associated with biological functions critical for the MET. For two miRNAs previously identified as differentially expressed in scNT morulae, miR-34a and miR-345, negative correlations with some predicted mRNA targets were apparent, though not widespread among the majority of predicted targets. Moreover, although large-scale aberrations in expression of mRNAs were evident during the MET in cattle scNT embryos, these changes were not consistently correlated with aberrations in miRNA expression at the same developmental stage, suggesting that other mechanisms controlling gene expression may be involved.

Dynamics of small non-coding RNAs in bovine scNT embryos through the maternal-to-embryonic transition†.

The efficiency of somatic cell nuclear transfer (scNT) for production of viable offspring is relatively low as compared to in vitro fertilization (IVF), presumably due to deficiencies in epigenetic reprogramming of the donor cell genome. Such defects may also involve the population of small non-coding RNAs (sncRNAs), which are important during early embryonic development. The objective of this study was to examine dynamic changes in relative abundance of sncRNAs during the maternal-to-embryonic transition (MET) in bovine embryos produced by scNT as compared to IVF by using RNA sequencing. When comparing populations of miRNA in scNT versus IVF embryos, only miR-2340, miR-345, and miR34a were differentially expressed in morulae, though many more miRNAs were differentially expressed when comparing across developmental stages. Also of interest, distinct populations of piwi-interacting like RNAs (pilRNAs) were identified in bovine embryos prior to and during embryonic genome activation (EGA) as compared bovine embryos post-EGA and differentiated cells. Overall, sncRNA sequencing analysis of preimplantation embryos revealed largely similar profiles of sncRNAs for IVF and scNT embryos at the 2-cell, 8-cell, morula, and blastocyst stages of development. However, these sncRNA profiles, including miRNA, piRNA, and tRNA fragments, were notably distinct prior to and after completion of the MET.

Cloning of Porcine Pituitary Tumor Transforming Gene 1 and Its Expression in Porcine Oocytes and Embryos.

The maternal-to-embryonic transition (MET) is a complex process that occurs during early mammalian embryogenesis and is characterized by activation of the zygotic genome, initiation of embryonic transcription, and replacement of maternal mRNA with embryonic mRNA. The objective of this study was to reveal the temporal expression and localization patterns of PTTG1 during early porcine embryonic development and to establish a relationship between PTTG1 and the MET. To achieve this goal, reverse transcription-polymerase chain reaction (RT-PCR) was performed to clone porcine PTTG1. Subsequently, germinal vesicle (GV)- and metaphase II (MII)-stage oocytes, zygotes, 2-, 4-, and 8-cell-stage embryos, morulas, and blastocysts were produced in vitro and their gene expression was analyzed. The results revealed that the coding sequence of porcine PTTG1 is 609-bp in length and that it encodes a 202-aa polypeptide. Using qRT-PCR, PTTG1 mRNA expression was observed to be maintained at high levels in GV- and MII-stage oocytes. The transcript levels in oocytes were also significantly higher than those in embryos from the zygote to blastocyst stages. Immunohistochemical analyses revealed that porcine PTTG1 was primarily localized to the cytoplasm and partially localized to the nucleus. Furthermore, the PTTG1 protein levels in MII-stage oocytes and zygotes were significantly higher than those in embryos from the 2-cell to blastocyst stage. After fertilization, the level of this protein began to decrease gradually until the blastocyst stage. The results of our study suggest that porcine PTTG1 is a new candidate maternal effect gene (MEG) that may participate in the processes of oocyte maturation and zygotic genome activation during porcine embryogenesis.

Maternal control of early embryogenesis in mammals.

Oocyte quality is a critical factor limiting the efficiency of assisted reproductive technologies (ART) and pregnancy success in farm animals and humans. ART success is diminished with increased maternal age, suggesting a close link between poor oocyte quality and ovarian aging. However, the regulation of oocyte quality remains poorly understood. Oocyte quality is functionally linked to ART success because the maternal-to-embryonic transition (MET) is dependent on stored maternal factors, which are accumulated in oocytes during oocyte development and growth. The MET consists of critical developmental processes, including maternal RNA depletion and embryonic genome activation. In recent years, key maternal proteins encoded by maternal-effect genes have been determined, primarily using genetically modified mouse models. These proteins are implicated in various aspects of early embryonic development, including maternal mRNA degradation, epigenetic reprogramming, signal transduction, protein translation and initiation of embryonic genome activation. Species differences exist in the number of cell divisions encompassing the MET and maternal-effect genes controlling this developmental window. Perturbations of maternal control, some of which are associated with ovarian aging, result in decreased oocyte quality.

Genome activation in bovine embryos: Review of the literature and new insights from RNA sequencing experiments

Maternal-to-embryonic transition (MET) is the period in early embryonic development when maternal RNAs and proteins stored in the oocyte are gradually degraded and transcription of the embryonic genome is activated. First insights into the timing of embryonic genome activation (EGA) came from autoradiographic analyses of embryos following incorporation of [3H]uridine. These studies identified the eight- to 16-cell stage of bovine embryos as the period of major EGA, but detected first transcriptional activity already in one-cell embryos. Subsequent studies compared the transcriptome profiles of untreated embryos and of embryos incubated with the transcription inhibitor α-amanitin to reveal transcripts of embryonic origin. In addition, candidate gene-based and global gene expression studies over several stages of early development were performed and characteristic profiles were revealed. However, the onset of embryonic transcription was obscured by the presence of maternal transcripts and could only be determined for genes which are not expressed in oocytes. Using RNA sequencing of bovine germinal vesicle and metaphase II oocytes, and of four-cell, eight-cell, 16-cell and blastocyst stage embryos, we established the most comprehensive transcriptome data set of bovine oocyte maturation and early development. EGA was analyzed by (i) detection of embryonic transcripts which are not present in oocytes; (ii) detection of transcripts from the paternal allele; and (iii) detection of primary transcripts with intronic sequences. Using these three approaches we were able to map the onset of embryonic transcription for almost 7400 genes. Genes activated at the four-cell stage or before were functionally related to RNA processing, translation, and transport, preparing the embryo for major EGA at the eight-cell stage, when genes from a broad range of functional categories were found to be activated. These included transcriptional and translational functions as well as protein ubiquitination. The functions of the genes activated at the 16-cell stage were consistent with ongoing transcription and translation, while the genes activated in blastocysts included regulators of early lineage specification. Fine mapping of EGA provides a new layer of information for detecting disturbances of early development due to genetic, epigenetic, and environmental factors.

Analysis of microRNAs and their precursors in bovine early embryonic development

In animals, the maternal-to-embryonic transition (MET) occurs in the first days of early development and involves the degradation of maternal transcripts that have been stored during oogenesis. Moreover, precise and specific control mechanisms govern the adequate synchronization of the MET events to promote the activation of the embryonic genome. These mechanisms are not well understood, but it is believed that microRNAs (miRNAs) could be one of the mechanisms involved. After a microarray screening study, we analysed the expression of specific miRNA during oocyte maturation and early embryo development until preimplantation stages. Two differentially expressed candidates were selected for further analysis. Mature and precursor forms of miR-21 and miR-130a were quantified by qRT-PCR in pools of 20 oocytes at GV (germinal vesicle), GV breakdown and metaphase II stages as well as in pools of embryos at the 2-cell, 4-cell, 8-cell and blastocyst stages. The results showed a linear increase during the 1-8 cell stage for the mature forms of miR-130a and miR-21 (P < 0.05 and P < 0.003, respectively) and for the precursor form of miR-130a (P < 0.002). To see if this increase was due to minor transcriptional activity, 2-cell embryos were exposed to α-amanitin for 30-34 h. Results showed a significant decrease in miR-21, pre-miR-21, miR-130a and SRFS3 in α-amanitin-treated embryos (P < 0.05). Considering the potential regulatory role of these miRNA, the bovine genome was screened to identify putative targets with a 3'UTR exact seed match. This study suggests that miRNAs could be important players in the MET, as expression profiles suggest a potential regulation role during early development steps.

35 DYNAMICS OF PERICENTRIC REPETITIVE SEQUENCES IN PREIMPLANTATION RABBIT EMBRYOS UNDERLINES INADEQUATE SPATIO-TEMPORAL REORGANIZATION AFTER NUCLEAR TRANSFER

Nowadays, a critical question in the epigenetic field is how chromatin is organised within the cell nucleus and how it affects gene expression. In this study we hypothesise that nuclear structure could be involved in the control of gene expression during early rabbit embryonic development. We focused on pericentric/centric heterochromatin, a peculiar region within nuclei known to form higher-order chromatin structures. We therefore performed immunostaining of associated proteins (HP1 and CENP) as well as FISH (fluorescent in situ hybridization) with probes corresponding to these genomic regions. Fertilized embryos were collected from New Zealand white rabbit female, cultured in vitro and fixed at different developmental stages up to 16-cell. Nuclear transfer of rabbit fetal skin fibroblasts was performed by electrofusion and electroactivation (Chesne et al., 2002). Immunostaining experiments were performed as previously described (Martin et al., 2006) and FISH experiments were performed using DNA probes specific to Rsat I and Rsat II sequences (Ekes et al., 2004) according to our published protocol (Maalouf et al., 2010). Three-dimensional images were acquired by confocal laser microscopy (each group included 20 to 40 embryos) and then analysed through automated 3D image processes (according to Ballester et al., 2008; Pichugin et al., 2010). Briefly, after segmentation of the nuclei, immunostaining signals were analysed using an automatic threshold segmentation procedure and FISH spots distributions were analysed with the eroded volume fraction (EVF) method. In in vivo fertilized rabbit embryos, we observed that during the 1- and 2-cell cycles pericentric heterochromatin was dispersed throughout the embryonic nuclei. Large foci of pericentric heterochromatin then progressively appeared at the 4-cell stage and increased in frequency and size by the 8/16-cell stage [∼75% of the embryos, n = 40; i.e. the stage of major transcriptional activation also called MET (maternal to embryonic-transition)]. This suggested that dramatic aggregation of pericentric heterochromatin is associated to the onset of transcription. Interestingly, after nuclear transfer, the donor nuclear organisation was quickly reverted into an early embryonic dispersed form in most 1-cell embryos (80%, n = 35). Subsequently, a somatic-like nuclear reorganization with large heterochromatin foci was re-established in 86% of the 4-cell stage cloned embryos (n = 35). This pattern was similar to the one observed in fertilized embryos at MET; it also appeared one stage earlier (4-cell vs 8-cell). Coincidently, most cloned embryos stopped developing at that stage (85% of cleavage until the 4-cell but only 38% at morula, n = 173). Together, the results suggested that inadequate spatio-temporal reorganization of the donor nucleus could be deleterious during early development in rabbit clones. The present work was supported by INRA « Jeune Equipe » funding, the European CLONET (MRTN-CT-2006-035468) grant and the Ambassade de France en Chine.

MicroRNA-196a regulates bovine newborn ovary homeobox gene (NOBOX) expression during early embryogenesis

BackgroundOocyte-derived maternal RNAs drive early embryogenesis when the newly formed embryo is transcriptionally inactive. Recent studies in zebrafish have identified the role of microRNAs during the maternal-to-embryonic transition (MET). MicroRNAs are short RNAs that bind to the 3' UTR of target mRNAs to repress their translation and accelerate their decay. Newborn ovary homeobox gene (NOBOX) is a transcription factor that is preferentially expressed in oocytes and essential for folliculogenesis in mice. NOBOX knockout mice are infertile and lack of NOBOX disrupts expression of many germ-cell specific genes and microRNAs. We recently reported the cloning and expression of bovine NOBOX during early embryonic development and our gene knockdown studies indicate that NOBOX is a maternal effect gene essential for early embryonic development. As NOBOX is a maternal transcript critical for development and NOBOX is depleted during early embryogenesis, we hypothesized that NOBOX is targeted by microRNAs for silencing and/or degradation.ResultsUsing an algorithm "MicroInspector", a potential microRNA recognition element (MRE) for miR-196a was identified in the 3' UTR of the bovine NOBOX mRNA. Expression analysis of miR-196a in bovine oocytes and during early embryonic development indicated that it is expressed both in oocytes and embryos and tends to increase at the four-cell and eight-cell stages. Ectopic expression of NOBOX and miR-196a in HeLa cells inhibited the expression of NOBOX protein compared to the control cells without miR-196a. Similarly, the activity of a luciferase construct containing the entire 3' UTR of bovine NOBOX was suppressed, and the regulation was abolished by mutations in the miR-196a binding site indicating that the predicted MRE is critical for the direct and specific binding of miR-196a to the NOBOX mRNA. Furthermore, ectopic expression of miR-196a mimic in bovine early embryos significantly reduced the NOBOX expression at the both mRNA and protein levels.ConclusionCollectively, our results demonstrate that miR-196a is a bona fide negative regulator of NOBOX during bovine early embryogenesis.

Lineage-specific expression of heterochromatin protein 1γ in post-compaction, in vitro-produced bovine embryos

Heterochromatin protein 1gamma (HP1gamma) is a highly conserved regulator of euchromatic and heterochromatic gene expression. Mammalian HP1gamma is essential for both successful preimplantation embryo development and maintenance of pluripotency in embryonic stem cells in vitro. Here, we describe HP1gamma protein localisation in matured (MII) bovine oocytes and IVF preimplantation embryos at defined developmental stages. HP1gamma is expressed in post-compaction embryos in a highly lineage-specific pattern. In embryonic stages preceding the maternal to embryonic transition (MET), HP1gamma protein was primarily cytoplasmic, whereas in 8-16-cell embryos (post MET), HP1gamma was primarily nuclear. Lineage-specific patterns of HP1gamma protein localisation become evident from compaction, being restricted to peripheral, extraembryonic cells at the morula and blastocyst stages (Days 7-9). Surprisingly, we detected HP1gamma mRNA in both embryonic and extraembryonic cells in blastocysts by fluorescence in situ hybridisation. In trophectoderm cells, HP1gamma protein was localised in specific patterns at the mitotic and interphase stages of the cell cycle. These results demonstrate lineage- and cell cycle-specific patterns of HP1gamma protein localisation in the post-compaction, preimplantation bovine embryo and raise interesting questions about the role of HP1gamma in early embryo development.

The dynamics of gene products fluctuation during bovine pre‐hatching development

Early embryonic development, spanning fertilization to blastocyst hatching, is a very dynamic developmental window that is characterized, especially in large mammals, by a period of transcriptional incompetence that ends during the maternal to embryonic transition (MET). Prior to the MET, the first cell cycles are supported by stored RNA and proteins pools accumulated during oogenesis. Therefore, RNA and protein content are different between developmental stages. It is also known that the stability of the stored mRNA and the mechanisms for translation recruitment are partly controlled by the length of the poly(A) tail. To date, little is known about RNA and protein content fluctuations during the pre-hatching period. In this report we present measurements of total RNA, mRNA, poly(A) bearing mRNA and protein contents, as well as estimations of the proportions of both mRNA fractions to total RNA contents within these developmental stages. We found that while the ontogenic profiles of the different transcript contents were expected, their amounts were considerably lower than the reported values. Additionally, low 28S rRNA abundance and a tendency for diminishing protein content prior to the MET, suggest a limited potential for ribosomal turnover and translation. We consider the overall fluctuations in RNA and protein contents to be reference points that are essential for downstream interpretation of gene expression data across stages whether it be through candidates or high throughput approaches.

Maternal enzyme masks the phenotype of mouse embryos lacking dihydrolipoamide dehydrogenase

During early embryogenesis, the phenotype reflecting the embryonic genotype emerges only as maternal proteins are replaced by embryonically encoded forms, a process known as the maternal-to-embryonic transition (MET). Little is understood about MET for most proteins. This study investigates how complete deficiency of the murine dihydrolipoamide dehydrogenase gene (Dld), a gene that encodes an enzyme of mitochondrial energy metabolism, affects the phenotype of the early embryo and how the MET of the DLD protein affects the phenotype. Dld-deficient (-/-) embryos were found to develop similarly to wild-type (+/+) or heterozygous (+/-) embryos throughout the preimplantation period. These three genotypic classes also have comparable rates of glucose uptake (4.9-5.0 pmoles/embryo/h) and lactate production (0.97-1.0 pmoles/embryo/h). Dld-deficient embryos at the end of the preimplantation stage have 44% of DLD enzyme present in oocytes, a proportion similar to that found in +/+ or +/- embryos. This study demonstrates that Dld-deficient preimplantation embryos are phenotypically normal, as the MET for the DLD enzyme is only partially complete by the end of the preimplantation period. These findings have implications for phenotype- or enzyme-based approaches to identify mutations in Dld and other genes that encode proteins with similar MET kinetic profiles.

Genomic RNA profiling and the programme controlling preimplantation mammalian development.

Preimplantation development shifts from a maternal to embryonic programme rapidly after fertilization. Although the majority of oogenetic products are lost during the maternal to embryonic transition (MET), several do survive this interval to contribute directly to supporting preimplantation development. Embryonic genome activation (EGA) is characterized by the transient expression of several genes that are necessary for MET, and while EGA represents the first major wave of gene expression, a second mid-preimplantation wave of transcription that supports development to the blastocyst stage has been discovered. The application of genomic approaches has greatly assisted in the discovery of stage specific gene expression patterns and the challenge now is to largely define gene function and regulation during preimplantation development. The basic mechanisms controlling compaction, lineage specification and blastocyst formation are defined. The requirement for embryo culture has revealed plasticity in the developmental programme that may exceed the adaptive capacity of the embryo and has fostered important research directions aimed at alleviating culture-induced changes in embryonic programming. New levels of regulation are emerging and greater insight into the roles played by RNA-binding proteins and miRNAs is required. All of this research is relevant due to the necessity to produce healthy preimplantation embryos for embryo transfer, to ensure that assisted reproductive technologies are applied in the most efficient and safest way possible.

Unveiling the bovine embryo transcriptome during the maternal-to-embryonic transition

Bovine early embryos are transcriptionally inactive and subsist through the initial developmental stages by the consumption of the maternal supplies provided by the oocyte until its own genome activation. In bovine, the activation of transcription occurs during the 8- to 16-cell stages and is associated with a phase called the maternal-to-embryonic transition (MET) where maternal mRNA are replaced by embryonic ones. Although the importance of the MET is well accepted, since its inhibition blocks embryonic development, very little is known about the transcripts expressed at this crucial step in embryogenesis. In this study, we generated and characterized a cDNA library enriched in embryonic transcripts expressed at the MET in bovine. Suppression subtractive hybridization followed by microarray hybridization was used to isolate more than 300 different transcripts overexpressed in untreated late eight-cell embryos compared with those treated with the transcriptional inhibitor, alpha-amanitin. Validation by quantitative RT-PCR of 15 genes from this library revealed that they had remarkable consistency with the microarray data. The transcripts isolated in this cDNA library have an interesting composition in terms of molecular functions; the majority is involved in gene transcription, RNA processing, or protein biosynthesis, and some are potentially involved in the maintenance of pluripotency observed in embryos. This collection of genes associated with the MET is a novel and potent tool that will be helpful in the understanding of particular events such as the reprogramming of somatic cells by nuclear transfer or for the improvement of embryonic culture conditions.

Dynamic changes in localization of chromobox (CBX) family members during the maternal to embryonic transition

The Chromobox domain (Cbx) gene family, consisting of Polycomb and Heterochromatin Protein 1 genes, is involved in transcriptional repression, cell cycle regulation and chromatin remodeling. We report the first study of gene expression and protein localization of the Cbx genes in in vitro produced bovine embryos. All but one gene (Cbx6) were expressed. This was confirmed by immunolocalization for HP1alpha, beta, gamma, and Pc2, 3. HP1beta was found in the nuclei of embryos from the two-cell stage onwards, whereas HP1gamma showed diffuse cytoplasmic/nuclear localization at the two- and eight-cell stages, and predominantly nuclear localization at the four-cell stage and the 16-cell stage onwards. Leptomycin B (LMB), a specific inhibitor of the nuclear export protein CRM-1 (chromosomal regional maintenance-1), was found to increase nuclear localization of HP1gamma at the eight-cell stage, and to prevent progression past this stage of embryogenesis. This indicates that HP1gamma possesses a CRM-1-dependent nuclear export pathway which may represent part of the basis of HP1gamma's ability to shuttle between the nucleus and the cytoplasm in dynamic fashion. HP1alpha was expressed in embryonic nuclei at all stages, but was found to relocalise from euchromatin to heterochromatin during the maternal to embryonic transition (MET). In contrast, Pc2 and Pc3 were evenly distributed between cytoplasm and nucleus until the eight- and sixteen-cell stages or the morula stage, respectively, before relocating preferentially to the cytoplasm. Collectively, the results suggest that dynamic changes of the nuclear-cytoplasmic and subnuclear distribution of members of the Cbx family may be central to the MET.

25 MATERNAL-TO-EMBRYONIC TRANSITION FOLLOWING NUCLEAR TRANSFER OR PARTHENOGENETIC ACTIVATION

The successful development of embryos generated by somatic cell nuclear transfer (SCNT) requires the ooplasm to reprogram the nucleus. This establishes the gene expression pattern necessary for full development by mechanisms that are currently being clarified. The ooplasm action on somatic nuclei shows many common aspects to the process that leads to the creation of a functional embryonic genome from the differentiated sperm and egg genomes. In order to investigate this aspect we studied a critical phase of early embryonic development: the maternal to embryonic transition (MET). We compared the pattern and level of gene expression between bovine embryos derived from in vitro fertilization (IVF), from nuclear transfer of adult fibroblasts (NT), or from parthenogenetic activation (PG). The study was performed in cattle because MET, in this species, occurs over four cell cycles, making it easier to detect even small deviations. Oocytes, matured for 22 h and fertilized in vitro or after cumulus removal, were enucleated and fused to fibroblast cells. Nuclear transfer and Met II oocytes were activated at 24-26 h of maturation with ionomycin (5 �M) for 5 min and 6DMAP (2 mM) for 4 h and then cultured in mSOFaa. Embryos were harvested at the required time for analysis at the 2-, 4-, 8-, and 16-cell; morula; and blastocyst stages and stored snap-frozen in a minimal volume of medium in groups of 5-10 embryos. Semiquantitative RT-PCR was used to study the expression of Nanog, Oct-4, Zar-1, and Par-3, because these genes are directly involved in early embryo development and have a specific expression pattern during MET. Data were analyzed with one-way ANOVA followed by Student-Newman-Keuls All Pairwise Multiple Comparison. No difference in pre-implantation development was observed among the three groups. The Nanog expression pattern was unchanged in all three groups, becoming detectable from the 8-16-cell stage onward. Oct-4 mRNA was detected at all stages in every group, but only in NT embryos did a significant increase occur at the 16-cell stage, suggesting the onset of an anticipated embryonic transcription. the Zar-1 expression pattern, with the characteristic de-novo transcription peak at the 4-cell stage, was observed in both IVF and NT embryos but not in PG embryos. In this group, Zar-1 mRNA levels were significantly higher at the 2- and 4-cell stage than in all of the following stages. The Par-3 gene showed the biggest differences among groups: IVF embryos expressed this gene from the 8-cell stage onward, whereas NT embryos showed high levels of Par-3 mRNA already at the 2-cell stage. Surprisingly, PG embryos showed no detectable Par-3 levels at any stages. The results indicate that, although in vitro development was not affected, gene-specific expression differences during MET occurred among groups. Relating the specific functions exerted by each of these genes in early development to the changes observed following the different manipulations provides useful data toward a better understanding of the role of these genes and of the mechanisms of nuclear reprogramming. This work was supported by FIRB RBNE01HPMX, FIRST 2004, and ESF-EuroStells.

246 EXPRESSION PATTERN OF NANOG AND Par3 GENES IN IN VITRO-DERIVED BOVINE EMBRYOS

Homeobox genes have been demonstrated to be important in patterning and lineage specification during early embryogenesis. Nanog belongs to the family of DNA-binding transcription factors and has been shown to maintain pluripotency of embryonic stem cells, both in murine and human. Par3 plays an essential role in determining cell fate of the early mouse embryo, leading to the generation of the inner cell mass and the trophectoderm. No information is available on these genes in the bovine; therefore, the aim of the present study was to identify and characterize Nanog and Par3 expression in bovine embryos. Oocytes recovered from slaughterhouse ovaries were matured for 22 h, fertilized in vitro and then cultured in mSOFaa medium. RNA was extracted from pools of five oocytes and embryos at different stages of development (2-, 4-, 8-, 16-cell, morula and blastocyst). It was then reverse transcribed, and PCR runs were carried out with primers specifically designed for Nanog and Par3, based on the sequence data bank available. The amplified products were separated on a 2% TAE agarose gel, purified, sequenced and aligned using Clustal W. Comparison of the bovine Nanog cDNA sequence (EMBL AM039957) with databases revealed a 84% degree of homology with the human, 97% with the mouse, and 82% with the goat genes. IVF bovine embryos express Nanog only upon genome activation, becoming detectable from the 8-cell stage onward indicating that Nanog is zygotically expressed in the bovine similar to what happens in mouse, pig and goat. Bovine Par3 cDNA sequence (EMBL AM039956) shows a high degree of homology with human (83%), mouse (81%), and rat (79%). Also Par3 is expressed only upon the maternal to embryonic transition (MET) at the 8-cell stage. As opposed to the expression patterns of other early embryo genes, like Oct-4 and Zar-1, Nanog and Par3 expression patterns in bovine embryos closely resemble those described in the mouse. Since both are absent in the ooplasm and before MET, they represent useful markers for genome activation. This work was supported by FIRB RBNE01HPMX, FIRST 2004 and ESF-EuroStells.