Wolfgang Tomek

Molecular and subcellular characterisation of oocytes screened for their developmental competence based on glucose-6-phosphate dehydrogenase activity

Oocyte selection based on glucose-6-phosphate dehydrogenase (G6PDH) activity has been successfully used to differentiate between competent and incompetent bovine oocytes. However, the intrinsic molecular and subcellular characteristics of these oocytes have not yet been investigated. Here, we aim to identify molecular and functional markers associated with oocyte developmental potential when selected based on G6PDH activity. Immature compact cumulus-oocyte complexes were stained with brilliant cresyl blue (BCB) for 90 min. Based on their colouration, oocytes were divided into BCB(-) (colourless cytoplasm, high G6PDH activity) and BCB(+) (coloured cytoplasm, low G6PDH activity). The chromatin configuration of the nucleus and the mitochondrial activity of oocytes were determined by fluorescence labelling and photometric measurement. The abundance and phosphorylation pattern of protein kinases Akt and MAP were estimated by Western blot analysis. A bovine cDNA microarray was used to analyse the gene expression profiles of BCB(+) and BCB(-) oocytes. Consequently, marked differences were found in blastocyst rate at day 8 between BCB(+) (33.1+/-3.1%) and BCB(-) (12.1+/-1.5%) oocytes. Moreover, BCB(+) oocytes were found to show higher phosphorylation levels of Akt and MAP kinases and are enriched with genes regulating transcription (SMARCA5), cell cycle (nuclear autoantigenic sperm protein, NASP) and protein biosynthesis (RPS274A and mRNA for elongation factor 1alpha, EF1A). BCB(-) oocytes, which revealed higher mitochondrial activity and still nucleoli in their germinal vesicles, were enriched with genes involved in ATP synthesis (ATP5A1), mitochondrial electron transport (FL405), calcium ion binding (S100A10) and growth factor activity (bone morphogenetic protein 15, BMP15). This study has evidenced molecular and subcellular organisational differences of oocytes with different G6PDH activity.

Dynamics of meiosis and protein kinase activities in bovine oocytes correlated to prolactin treatment and follicle size.

Oocyte developmental competence depends on the size of the original follicle and is affected by compounds like prolactin. We wished to investigate nuclear and cytoplasmic maturation of bovine oocytes correlated to their origin and response to prolactin treatment, by monitoring at frequent intervals meiotic configuration of chromosomes and activity of histone H1 and MAP-kinase. Bovine ovaries were obtained from a slaughterhouse and oocytes were recovered by follicle isolation. Oocytes (n = 1,397) with a compact cumulus were selected from small (2 to 3 mm) and large (4 to 5 mm in diameter) follicles and cultured up to 28 h in TCM 199+20% bull serum with or without 50 ng/mL bovine prolactin. Four groups of oocytes were formed: originating from small or large follicles, and treated or not treated with prolactin. At the scheduled time intervals for in vitro maturation, cumulus oocyte complexes from the 4 groups were randomly selected and the oocytes were analyzed for histone H1 and MAP-kinase, and for chromatin configuration. The first meiotic division took longer to complete in oocytes from large follicles (P < 0.01). Under the influence of prolactin the meiosis was prolonged in oocytes both from small and large follicles (P < 0.05). Histone H1 and MAP-kinases started to be activated at approximately the same time, around 6 h after beginning maturation. But after this time, significantly lower levels of both kinase activities were found in oocytes treated with prolactin, especially those treated during Meiosis I (P < 0.05). Our results indicate a correlation of chromatin configuration and histone H1/MAP-kinase activities.

Incidence of apoptosis and transcript abundance in bovine follicular cells is associated with the quality of the enclosed oocyte

The close contact and interaction between the oocyte and the follicular environment influence the establishment of oocyte developmental competence. Moreover, it is assumed that apoptosis in the follicular cells has a beneficial influence on the developmental competence of oocytes. The aim of this study was to investigate whether bovine oocytes with varied developmental competence show differences in the degree of apoptosis and gene expression pattern in their surrounding follicular cells (cumulus and granulosa cells). Oocytes and follicular cells from follicles of 3 to 5 mm in diameter were grouped as brilliant cresyl blue (BCB)+ and BCB- based on glucose-6-phosphate dehydrogenase (G6PDH) activity in the ooplasm by BCB staining. In the follicular cells initial, early and late apoptotic events were assessed by analyzing caspase-3 activity, annexin-V and TUNEL, respectively. Global gene expression was investigated in immature oocytes and corresponding follicular cells. BCB+ oocytes resulted in a higher blastocyst rate (19.3%) compared to the BCB- group (7.4%, P < 0.05). Moreover, the analysis of apoptosis showed a higher caspase-3 activity in the follicular cells and an increased degree of late apoptotic events in granulosa cells in the BCB+ compared with the BCB- group. Additionally, the global gene expression profile revealed a total of 34 and 37 differentially expressed genes between BCB+ and BCB- cumulus cells and granulosa cells, respectively, whereas 207 genes showed an altered transcript abundance between BCB+ and BCB- oocytes. Among these, EIF3F, RARRES2, RNF34, ACTA1, GSTA1, EIF3A, VIM and CS gene transcripts were most highly enriched in the BCB+ oocytes, whereas OLFM1, LINGO1, ALDH1A3, PTHLH, BTN3A3, MRPS2 and PPM1K were most significantly reduced in these cells. Therefore, the follicular cells enclosing developmentally competent oocytes show a higher level of apoptosis and a different pattern of gene expression compared to follicular cells enclosing non-competent bovine oocytes.

Analysis of mRNA associated factors during bovine oocyte maturation and early embryonic development

Regulation of gene expression at the translational level is particularly essential during developmental periods, when transcription is impaired. According to the closed‐loop model of translational initiation, we have analyzed components of the 5´‐mRNA cap‐binding complex eIF4F (eIF4E, eIF4G, eIF4A), the eIF4E repressor 4E‐BP1, and 3´‐mRNA poly‐(A) tail‐associated proteins (PABP1 and 3, PAIP1 and 2, CPEB1, Maskin) during in vitro maturation of bovine oocytes and early embryonic development up to the 16‐cell stage. Furthermore, we have elucidated the activity of distinct kinases which are potentially involved in their phosphorylation. Major phosphorylation of specific target sequences of PKA, PKB, PKC, CDKs, ATM/ATR, and MAPK were observed in M II stage oocytes. Furthermore, main changes in the abundance and/or phosphorylation of distinct mRNA‐binding factors occur at the transition from M II stage oocytes to 2‐cell embryos. In conclusion, the results indicate that, at the transition from oocyte to embryonic development, translational initiation is regulated by striking differences in the abundance and/or phosphorylation of 5´‐end and 3´‐end mRNA associated factors, mainly the poly‐(A) bindings proteins PABP1 and 3, their repressor PAIP2 and a Maskin‐like protein with distinct eIF4E‐binding properties which prevents eIF4E/cap binding and eIF4F formation in vitro. Nevertheless, from the M II stage to 16‐cell embryos a substantial amount of eIF4E and, to a lesser extent, of eIF4G was precipitated by 7m‐GTP‐Separose indicating eIF4F complex formation. Therefore, it is likely that in general the reduction in PABP1 and 3 abundance represses overall translation during early embryonic development. Mol. Reprod. Dev. 76: 1208–1219, 2009.

Regulation of cap-dependent translation initiation in the early stage porcine parthenotes.

The binding of mRNAs to ribosomes is mediated by the protein complex eIF4F in conjunction with eIF4B (eukaryotic initiation factor 4F and 4B). EIF4F is a three subunit complex consisting of eIF4A (RNA helicase), eIF4E (mRNA cap binding protein), and eIF4G (bridging protein). The crucial role is played by eIF4E, which directly binds the 5′‐cap structure of the mRNA and facilitates the recruitment to the mRNA of other translation factors and the 40S ribosomal subunit. EIF4E binding to mRNA and to other initiation factors is regulated on several levels, including its phosphorylation on Ser‐209, and association with its regulatory protein 4E‐binding protein (4E‐BP1). In this study we document that both the translation initiation factor eIF4E and its regulator 4E‐BP1 become dephosphorylated in the early stage porcine zygotes already 8 hr post‐activation. Similarly, the activities of ERK1/2 MAP and Mnk1 kinases, which are both involved in eIF4E phosphorylation, gradually decrease during this period with the timing similar to that of eIF4E dephosphorylation. The formation of an active eIF4F complex is also diminished after 9–15 hr post‐activation, although substantial amounts of this complex have been detected also 24 hr post‐activation (2‐cell stage). The overall protein synthesis in the parthenotes decreases gradually from 12 hr post‐activation reaching a minimum after 48 hr (4‐cell stage). Although the translation is gradually decreasing during early preimplantation development, the eIF4F complex, which is temporarily formed, might be a premise for the translation of a small subset of mRNAs at this period of development. Mol. Reprod. Dev. 75: 1716–1725, 2008.

Upstream Stimulating Factors 1 and 2 Enhance Transcription from the Placenta-Specific Promoter 1.1 of the Bovine Cyp19 Gene

BackgroundPlacenta-derived oestrogens have an impact on the growth and differentiation of the trophoblast, and are involved in processes initiating and facilitating birth. The enzyme that converts androgens into oestrogens, aromatase cytochrome P450 (P450arom), is encoded by the Cyp19 gene. In the placenta of the cow, expression of Cyp19 relies on promoter 1.1 (P1.1). Our recent studies of P1.1 in vitro and in a human trophoblast cell line (Jeg3) revealed that interactions of placental nuclear protein(s) with the E-box element at position -340 are required for full promoter activity. The aim of this work was to identify and characterise the placental E-box (-340)-binding protein(s) (E-BP) as a step towards understanding how the expression of Cyp19 is regulated in the bovine placenta.ResultsThe significance of the E-box was confirmed in cultured primary bovine trophoblasts. We enriched the E-BP from placental nuclear extracts using DNA-affinity Dynabeads and showed by Western blot analysis and supershift EMSA experiments that the E-BP is composed of the transcription factors upstream stimulating factor (USF) 1 and USF2. Depletion of the USFs by RNAi and expression of a dominant-negative USF mutant, were both associated with a significant decrease in P1.1-dependent reporter gene expression. Furthermore, scatter plot analysis of P1.1 activity vs. USF binding to the E-box revealed a strong positive correlation between the two parameters.ConclusionFrom these results we conclude that USF1 and USF2 are activators of the bovine placenta-specific promoter P1.1 and thus act in the opposite mode as in the case of the non-orthologous human placenta-specific promoter.

4E-BP1 degradation and eIF4E truncation occur spatially distinctly in the porcine uterine epithelia and are features of noninvasive implantation in the pig.

The implantation of the blastocyst into the endometrium is an indispensable premise for successful embryonic development. This process is regulated by maternal and embryonic signals that influence gene expression at the translational level, among other processes. Recently, we have shown that proteolytical cleavage of the prototypical 25‐kDa, mRNA cap‐binding protein eIF4E produces a stable variant with a molecular mass of approximately 23 kDa exclusively in the porcine endometrium during implantation. This is accompanied by dephosphorylation and reduction of the abundant repressor 4E‐BP1. Here, we investigate the distribution of the truncated eIF4E and of 4E‐BP1 in the porcine uterine tissue, their binding in native samples, and we analyzed eIF4E‐, eIF4G‐, and 4E‐BP1‐specific proteolytic activities. Our results show that in pigs, the truncated eIF4E is located in the endometrial luminal epithelium during implantation. Neither glandulary tissue nor stroma expressed any truncated eIF4E. The reduced abundance of 4E‐BP1 during implantation is mainly the result of decay in the glandular epithelia. Moreover, steroid replacements, in vitro protease assays, and cell lysate fractionation showed that eIF4E cleavage and 4E‐BP1 decay both depended on the ovarian steroid hormones estradiol and progestrone, but these effects are the result of different proteolytic activities. Although eIF4G cleavage also depends on calcium, stimulation by these steroids could not be established. We propose that the translation initiation process in the endometrium is differently regulated by the truncated eIF4E, utilizing different abundances of 4E‐BP1 and binding dynamic of eIF4E/4E‐BP1 in distinct forms of implantation. Mol. Reprod. Dev. 78:895–905, 2011.

The Akt/mTor signaling cascade is modified during placentation in the porcine uterine tissue

Recently we showed that essential components for the initiation of protein synthesis, namely the eukaryotic initiation factor 4E (eIF4E, mRNA-cap-binding protein) and its repressors 4E-BP1 as well as 4E-BP2, are proteolytically processed in the porcine endometrium during implantation. Here, the situation during placentation was compared with ovariectomized (OVX) animals and animals on pregnancy day 1 (PD1). Furthermore, the research was extended to factors which phosphorylate eIF4E and 4E-BPs and regulate their activities. These are the protein kinase B/mammalian target of rapamycin kinase (Akt/mTor) with the regulators Raptor and Rictor as well as the mitogen activated protein kinases (MAPKs): extra cellular-signal regulated kinase 1 and 2 (ERK1 and ERK2). Striking differences in the placentation site (PS) and the areas aside from PS (peri-PS) were observed. EIF4E and 4E-BP2 truncation as well as 4E-BP1 degradation took place in the endometrium of the peri-PS on PD24. Accompanied by a fragmentation of Akt/mTor, no expression of Rictor was observed, whereas the abundance of Raptor was not altered. On the contrary, MAPKs expression and phosphorylation remained almost stable in the peri-PS. In conclusion, the results indicated that on PD24 the translational regulation was shifted to 4E-BP2 control. Furthermore, the Akt/mTor signaling cascade seemed to be down regulated which suggest reduced phosphorylation of 4E-BP2. Whereas Akt was proteolyzed, the observed mTor fragments represented most likely splicing variants. The results indicate that translational control of gene expression is an important feature in the porcine endometrium during early pregnancy.

Truncation of the mRNA Cap‐Binding Protein eIF4E is Specific for the Non‐Invasive Implantation in Pigs

The mechanism of implantation is species specific (pig: epitheliochorial, bovine: synepitheliochorial, mouse: hemochorial). Recently, we have shown that proteolytical cleavage of the prototypical 25 kDa mRNA cap-binding protein eIF4E (eukaryotic initiation factor 4E) produces a stable variant with a molecular mass of approximately 23 kDa in porcine endometrium at the time of implantation. Here, we investigate if an eIF4E truncation also takes place in the endometrium of species with other implantation forms. Thus, eIF4E and its repressor protein 4E-BP1 were investigated in porcine, murine and bovine endometrium during the time of implantation. Our results show that eIF4E truncation is specific for the porcine implantation. In bovine and mouse uterine tissue, no cleavage of eIF4E was observed. Whereas no difference of bovine 4E-BP1 was found, in murine samples, increased phosphorylation during implantation was observed. However, porcine samples exhibit an opposite behaviour, the abundance and mainly the phosphorylation of 4E-BP1 decrease. We propose that the translation initiation in the endometrium is differently regulated by the two eIF4E forms with regard to different 4E-BP1 abundance and phosphorylation as well as different eIF4E/4E-BP1 binding dynamic depending on the type of implantation.

Estrogen-Specific Sulfotransferase (SULT1E1) in Bovine Placentomes: Inverse Levels of mRNA and Protein in Uninucleated Trophoblast Cells and Trophoblast Giant Cells

ABSTRACT The bovine trophoblast produces significant amounts of estrogens. In maternal and fetal blood, estrogens occur predominantly in sulfonated forms, which are unable to bind to estrogen receptors (ESRs). However, estrogens may act as local factors in ESR-positive trophoblast cells or in the adjacent caruncular epithelium, which in addition to ESR highly expresses steroid sulfatase. Estrogen sulfonation is catalyzed by the cytosolic enzyme SULT1E1. Previous studies clearly indicated the trophoblast as the primary site of estrogen sulfonation. However, investigations into the cellular localization of SULT1E1 yielded conflicting results. In situ hybridization studies detected SULT1E1 mRNA only in trophoblast giant cells (TGCs), whereas in immunohistochemical experiments the SULT1E1 protein was virtually restricted to uninucleated trophoblast cells (UTCs). The aim of this work was to resolve this conflict by analyzing SULT1E1 expression in isolated UTCs and TGCs. Highly enriched pools of UTCs and TGCs were obtained from four bovine placentas (Days 118–130 of gestation) using an optimized fluorescence-activated cell sorting procedure. UTC and TGC pools were analyzed by quantitative RT-PCR and Western blot experiments to measure the amounts of SULT1E1 transcript and protein, respectively. In contrast to previously published results, both SULT1E1 transcript and SULT1E1 protein were clearly present in the UTC and TGC pools. However, some evidence indicated a higher transcript concentration in TGCs and a higher amount of protein in UTCs. Thus, our results resolve the conflicting results on the localization of SULT1E1 from earlier studies and suggest that posttranscriptional mechanisms play an important role in the control of SULT1E1 expression during TGC differentiation.