Dorthe Viuff

Effects of in vivo prematuration and in vivo final maturation on developmental capacity and quality of pre-implantation embryos

In current in vitro production (IVP) systems, oocytes lack in vivo dominant and preovulatory follicular development, which may compromise pregnancy and viability of calves born. When an oocyte sets off in vivo on the road toward fertilization, it contains numerous transcripts and proteins necessary to survive the first few cell cycles of embryonic development. It is not yet known during which period of development the oocyte builds up the store, possibly primarily during the major growth phase of the oocyte, which is completed at the time a follicle reaches the size of 3 mm. Here, we investigated to what extent the later phases of follicular development, such as prematuration in the dominant follicle before the LH surge and ensuing final maturation in the preovulatory follicle, contribute to oocyte competence and development into viable biastocysts. Recent studies on in vivo vs in vitro oocyte maturation employed oocytes from an identical preovulatory development by applying ovum pick-up (OPU) twice (before and 24 h after the LH surge) in each cow treated for superovulation with a controlled LH surge. The embryo recovery rates at Day 7 of IVC after IVF were similar: 44% (97/219) for in vivo- vs 41% (87/213) for in vitro-matured oocytes, which shows that the natural environment during final maturation is not essential for the mere in vitro development of the prematured oocyte beyond the 8- to 16-cell stage. However, in vivo maturation appeared to contribute to the oocytes quality in a more subtle way, as indicated by a significant increase in the proportion of expanded blastocysts and a more physiological degree of chromosome aberrations of the embryos. In blastocysts derived from in vivo-matured oocytes, 21% of the embryos were mixoploid vs 50% from in vitro-matured oocytes, concomitant with a higher number of cells (96 vs 54 per normal blastocyst). The expression pattern of a set of six developmentally important genes was, however, not significantly altered in blastocysts derived from in vivo-matured oocytes. Certain deviations were observed compared with the levels of entirely in vivo-developed control blastocysts, which suggests that the beneficial effects of in vivo maturation are possibly exerted at initial stages of embryonic development. Prematuration in vivo, occurring in a dominant follicle developing from about 8 mm into the preovulatory follicle, is accompanied by changes in protein synthesis of the cumulus oocyte complex (COC). Presumably, the differentially expressed proteins are involved in equipping the oocyte with further developmental competence. Although we have unraveled some important biochemical and cellular biological features of the oocyte, further research on in vivo processes is essential to improve in vitro embryo production in practice.

Transcriptional activity in in vitro produced bovine two- and four-cell embryos

The objectives of this study on in vitro produced bovine two‐ and four‐cell embryos were (1) to investigate the uptake of 3H‐uridine through the plasma membrane, (2) to characterize the pattern of RNA synthesis during the second cell cycle, and (3) to measure the incorporation of 3H‐uridine into de novo synthesized RNA. A total of 200 embryos were incubated with 3H‐uridine for 15, 30, 60 (two‐ and four‐cell embryos), 120 (four‐cell embryos), 180 (two‐cell embryos), and 240 min (two‐ and four‐cell embryos), respectively. 3H‐uridine uptake reached a maximum by 30 min in two‐cell embryos, whereas four‐cell embryos reached a maximum at 120 min. A total of 440 two‐cell embryos were isolated 27–33 hr postinsemination (hpi), and 90 of these were incubated for 10 hr with 3H‐uridine (200 μCi/ml). The remainder were incubated with 3H‐uridine for 3 hr starting at 0–3 (n = 54), 3–6 (n = 75), 6–9 (n = 77), or 9–12 (n = 77) hr after cleavage to the two‐cell stage. Control two‐cell embryos (n = 67) were incubated with 3H‐uridine supplemented with 5 mg/ml of unlabelled uridine for 10 hr (inhibition control), or they were incubated with 3H‐uridine for 10 hr and RNase treated (100 μg/ml post fixation (RNase control). Subsequently, the embryos were processed for autoradiography. The long‐term incubation revealed transcription (autoradiographically labelled nuclei) in a total of 77% of the two‐ and four‐cell embryos. No transcription was observed in any of the 3 hr incubation groups. The RNase control embryos lacked labelling of the nuclei, whereas the inhibition control embryos only showed markedly reduced labelling. Finally, total RNA extraction was performed on a total of 336 two‐cell embryos that were incubated with 3H‐uridine or 3H‐uridine supplemented with unlabelled uridine for 2, 5, or 10 hr. It was possible to detect an increasing amount of labelled RNA after the 2, 5, and 10 hr incubation periods, and it was possible to inhibit this incorporation competitively. Together the data demonstrate a low level of transcription during the second cell cycle without a well‐defined transcriptional peak.

Chromosome Aberrations in In Vitro-Produced Bovine Embryos at Days 2–5 Post-Insemination

Abstract Availability of embryos of high quality is required to obtain satisfactory embryonic developmental rates and normal calves following transfer of in vitro-produced (IVP) bovine embryos. One relevant quality parameter is the frequency of chromosome aberrations, which can be evaluated using multicolor fluorescent in situ hybridization (FISH) with chromosome 6- and chromosome 7-specific probes in cattle. In this study, interphase nuclei (n = 3805) were analyzed from 426 bovine IVP embryos. We found that 73%, 72%, 81%, and 58% of the embryos from Days 2, 3, 4, and 5 post-insemination (pi), respectively, displayed a normal diploid chromosome number in all cells. When looking at the types of chromosome aberrations, the percentages of mixoploidy at Days 2, 3, 4, and 5 pi were 22%, 15%, 16%, and 42%, respectively, whereas the percentages of polyploidy (i.e., all nuclei in an embryo were analyzed and were polyploid) were 5%, 13%, 3%, and 0%, respectively. In conclusion, numerical chromosome aberrations were detected as early as Day 2 pi. The development of polyploid embryos is slow and is apparently arrested during the third cell cycle, whereas the mixoploid embryos seem to continue development.

Investigation of the effect of kaolin and tissue factor–activated citrated whole blood, on clot forming variables, as evaluated by thromboelastography

BACKGROUND: The Thrombelastograph (TEG; Haemoscope Corp.) analyzes clot formation in whole blood (WB) and treatment based on this analysis has been shown to reduce transfusion requirements in liver and cardiac surgery when compared to conventional coagulation analysis. Implementing TEG as a routine laboratory‐based analysis, however, requires validation of the activators employed and the effect of storage of the WB sample in citrate before analysis.

Numerical Chromosome Errors in Day 7 Somatic Nuclear Transfer Bovine Blastocysts

Abstract Day 7 bovine somatic nuclear transfer (NT) embryos reconstructed from granulosa cells were examined for numerical chromosome aberrations as a potential cause of the high embryonic and fetal loss observed in such embryos after transfer. The NT embryos were reconstructed using a zona-free manipulation method: half-cytoplasts were made from zona-free oocytes by bisection, after which two half-oocytes and one granulosa cell (serum-starved primary culture) were fused together and activated. The NT embryos were cultured in modified synthetic oviductal fluid containing essential and nonessential amino acids, myoinositol, sodium citrate, and 5% cattle serum in microwells for 7 days, at which time nuclei from all blastocysts were extracted and chromosome aberrations were evaluated using dual-color fluorescent in situ hybridization with bovine chromosome 6- and 7-specific probes. Five embryo clone families, consisting of 112 blastocysts reconstructed from five different primary granulosa cell cultures, were examined. Overall, the mean chromosome complement within embryos was 86.9 ± 3.7% (mean ± SEM) diploid, 2.6 ± 0.5% triploid, 10.0 ± 3.1% tetraploid, and 0.5 ± 0.2% pentaploid or greater; the vast majority (>75%) of the abnormal nuclei were tetraploid. Completely diploid and mixoploid embryos represented 22.1 ± 4.5% and 73.7 ± 5.5%, respectively, of all clones. Six totally polyploid blastocysts, containing ≤91 nuclei, were recorded. The ploidy distributions (classified as 2N, 3N, 4N, and ≥5N chromosome complements, respectively) between two clone families were different (P < 0.01), as were blastocyst yields between other clone families (P < 0.01). Blastocyst yield was not correlated to % total ploidy error between clone families, but an inverse relationship (P < 0.01) between blastocyst total cell number and total % chromosome abnormality was observed within embryos. Categorization of the blastocysts into three quality grades (good, medium, and poor) and comparison of the distribution of ploidies when classified into 0%, 0.1–5.0%, 5.1–10.0%, 10.1–15.0%, and 15.1–100% errors within embryos indicated that medium- and poor-grade embryos were different (P < 0.05) from good-quality, in vitro-produced embryos. In a separate study, 11 different granulosa cell cultures (that did not correspond to those used for NT) were evaluated and found to possess only 0.23 ± 0.12% ploidy errors. These results demonstrate that 1) the percentage of ploidy errors in bovine NT blastocysts is inversely related to total blastocyst cell number, 2) the mixoploid condition is representative of the majority of embryos, 3) 100% polyploid NT blastocysts can exist, and 4) the ploidy errors seem not to be derived from the donor cells.

mRNAs encoding aquaporins are present during murine preimplantation development.

The present study was conducted to investigate the mechanisms underlying fluid movement across the trophectoderm during blastocyst formation by determining whether aquaporins (AQPs) are expressed during early mammalian development. AQPs belong to a family of major intrinsic membrane proteins and function as molecular water channels that allow water to flow rapidly across plasma membranes in the direction of osmotic gradients. Ten different AQPs have been identified to date. Murine preimplantation stage embryos were flushed from the oviducts and uteri of superovulated CD1 mice. Reverse transcription–polymerase chain reaction (RT‐PCR) methods employing primer sets designed to amplify conserved sequences of AQPs (1–9) were applied to murine embryo cDNA samples. PCR reactions were conducted for up to 40 cycles involving denaturation of DNA hybrids at 95°C, primer annealing at 52–60°C and extension at 72°C. PCR products were separated on 2% agarose gels and were stained with ethidium bromide. AQP PCR product identity was confirmed by sequence analysis. mRNAs encoding AQPs 1, 3, 5, 6, 7, and 9 were detected in murine embryos from the one‐cell stage up to the blastocyst stage. AQP 8 mRNAs were not detected in early cleavage stages but were present in morula and blastocyst stage embryos. The results were confirmed in experimental replicates applied to separate embryo pools of each embryo stage. These results demonstrate that transcripts encoding seven AQP gene products are detectable during murine preimplantation development. These findings predict that AQPs may function as conduits for trophectoderm fluid transport during blastocyst formation. Mol. Reprod. Dev. 57:323–330, 2000.

Chromosomal Abnormalities and Developmental Kinetics in In Vivo-Developed Cattle Embryos at Days 2 to 5 after Ovulation

Abstract The frequency of chromosome abnormalities was investigated in cattle embryos (n = 256) derived from superovulated heifers (n = 35) on Days 2, 3, 4, and 5 postovulation (PO). Interphase nuclei (n = 4358) were analyzed for chromosome abnormalities using fluorescent in situ hybridization with chromosome 6- and chromosome 7-specific probes and the developmental rate was described by scoring cell numbers. We found that 93%, 85%, 84%, and 69% of the embryos from Days 2, 3, 4, and 5 PO, respectively, displayed a normal diploid chromosome number in all cells. Of the embryos containing abnormal cells, mixoploidy was significantly more frequent than polyploidy. The percentage of mixoploidy at Days 2, 3, 4, and 5 PO was 5%, 13%, 16%, and 31%, respectively, whereas the percentages of polyploidy were 2%, 2%, 0%, and 0%, respectively. The mean number of cells per embryo was 4.7, 8, 11.5, and 48.3, respectively, at Days 2, 3, 4, and 5 PO. Thus, in vivo-developed embryos were significantly more advanced than the in vitro-produced (IVP) embryos except for Day 2. In conclusion, a significantly lower frequency of chromosomally abnormal embryos, in particular displaying polyploidy early after fertilization, was seen in in vivo versus IVP embryos, and these chromosomal abnormalities may be inherent to the process of IVP in cattle.

Evaluation of thromboelastography for monitoring recombinant activated factor VII ex vivo in haemophilia A and B patients with inhibitors: a multicentre trial.

Predicting the clinical effect of bypassing agents such as recombinant activated factor VII in haemophilia patients with inhibitors is hampered by the limited availability of reliable laboratory monitoring tools. This multicentre, open-label trial aimed to explore the dose–response relationship between recombinant activated factor VII concentration and thromboelastography parameters in blood samples from patients with haemophilia A or B with inhibitors in a nonbleeding state. Citrated whole blood samples from 16 patients (≥16 years) with haemophilia A or B were spiked ex vivo with recombinant activated factor VII (1.2, 1.6, 2.0, 2.6, 3.0, 3.5 μg/ml), corresponding approximately to doses of 90–270 μg/kg. Samples were analysed by Thromboelastograph or Rotation Thromboelastography (three United States and three European centres, respectively) within 30 min (final lipidated recombinant tissue factor 1: 17 000; final CaCl2 15 mM). Thromboelastograph/Rotation Thromboelastography parameters showed large intersubject variation in the baseline profiles. There was a clear effect when recombinant activated factor VII was added; however, a clear concentration–response relationship was only detected for one patient. This is likely due to the fact that the curves were not sufficiently abnormal that led to reduced assay sensitivity. Our preliminary results suggest that thromboelastography may potentially be a clinically useful tool for monitoring changing concentrations of recombinant activated factor VII in haemophilia patients, but only when the baseline curve is significantly abnormal. Thus, test conditions may need to be optimized before Thromboelastograph/Rotation Thromboelastography can be utilized for all inhibitor patients.

Activation of ribosomal RNA genes in preimplantation cattle and swine embryos

Transcription of ribosomal RNA (rRNA) genes occurs in the nucleolus resulting in ribosome synthesis. In cattle and swine embryos, functional ribosome-synthesizing nucleoli become structurally recognizable towards the end of the fourth and third post-fertilization cell cycle, respectively. In cattle, a range of important nucleolar proteins become localized to the nucleolar anlage over several cell cycles and this localization is apparently completed towards the end of the fourth cell cycle. In swine, the localization of these proteins to the anlage is more synchronous and occurs towards the end of the third cell cycle and is apparently completed at the onset of the fourth. The rRNA gene activation and the associated nucleolus formation may be used as a marker for the activation of the embryonic genome in mammalian embryos and, thus, serve to evaluate the developmental potential of embryos originating from different embryo technological procedures. By this approach, we have demonstrated that in vitro produced porcine embryos display a lack of localization of nucleolar proteins to the nucleolar anlage as compared with in vivo developed counterparts. Similarly, bovine embryos produced by nuclear transfer from morulae display such deviations as compared with in vitro produced counterparts. Collectively, this information may help to explain the appearance of abnormalities seen in a certain proportion of offspring derived from in vitro produced embryos and after cloning.

Activation of the Ribosomal RNA Genes Late in the Third Cell Cycle of Porcine Embryos

Abstract In porcine embryos, nucleoli are first observed during the third postfertilization cell cycle, i.e., at the 4-cell stage. However, direct studies of the initiation of rRNA transcription have not been reported. This transcription was investigated in the present study by simultaneous visualization of the rRNA genes and the rRNA by fluorescent in situ hybridization using a porcine 28S rDNA probe and subsequent visualization of argyrophilic nucleolar proteins by silver staining of extracted and fixed nuclei from in vivo-derived porcine embryos (n = 229). Nucleologenesis was observed by transmission electron microscopy. In general, the 2-cell and 4-cell embryos fixed at 10 and 20 h postcleavage (hpc) showed no signs of rRNA transcription. Four small clusters of fluorescein isothiocyanate (FITC) labeling were visible in interphase nuclei, consistent with hybridization to the rRNA gene clusters only; there was no silver staining at the sites of the rRNA genes and nucleolus precursor bodies. From 30 hpc onwards, most 4-cell embryos had medium size to large clusters of FITC-labeled areas colocalized with silver staining of rRNA gene clusters and fibrillogranular nucleoli. These observations indicate that rRNA transcription had been initiated. These signs of rRNA synthesis could be blocked by actinomycin D, which is a strong inhibitor of RNA polymerase I. The rRNA transcription of porcine embryos is initiated between 20 and 30 hpc, corresponding to the end of the S-phase or the beginning of the G2 phase during the third cell cycle.