Spatial and temporal changes of decorin, type I collagen and fibronectin expression in normal and clone bovine placenta.

INTRODUCTION: Alteration of expression of various genes including extracellular matrix components, have been suggested to play major role in the placental pathologies after somatic cloning in mammals. The objectives of the present study were to analyze pattern of expression (mRNA and protein) of the small leucine-rich proteoglycan, Decorin in association with Type I Collagen and Fibronectin in bovine placental tissues from normal and clone pregnancies. METHODS: Genotyping and allelic expression of Decorin were determined by Sanger sequencing. The expression patterns of Decorin, Type I collagen and Fibronectin 1 were analyzed by quantitative RT-qPCR and combined in situ hybydization (ISH) and immunohistochemistry (IHC) in endometrial and placental tissues from D18 to term from artificially inseminated and somatic cloning pregnancies. RESULTS: The expression levels of DCN increased in the AI endometrial stroma and chorionic mesenchyme during implantation and declined during placentome growth until term. Combined ISH and IHC revealed an unexpected discrepancy mRNA and protein tissue distribution. Moreover, Decorin was maintained in the placentome tissues from SCNT pregnancies while both mRNA and protein were absent in AI derived placenta. DISCUSSION: In bovine, the pattern of expression of Decorin exhibits significant changes during placental formation. Downregulation of Decorin is associated with proliferation, remodeling and vascularization of placental tissues. These observations reinforces the putative role of Decorin in these processes. CONCLUSIONS: These observations suggest that Decorin is involved in placental growth and that dysregulation of its expression is associated with placental abnormalities in SCNT derived pregnancy.

Reproductive technologies and genomic selection in dairy cattle.

Genomic tools are now available for most livestock species and are used routinely for genomic selection (GS) in cattle. One of the most important developments resulting from the introduction of genomic testing for dairy cattle is the application of reasonably priced low-density single nucleotide polymorphism technology in the selection of females. In this context, combining genome testing and reproductive biotechnologies in young heifers enables new strategies to generate replacement and elite females in a given period of time. Moreover, multiple markers have been detected in biopsies of preimplantation stage embryos, thus paving the way to develop new strategies based on preimplantation diagnosis and the genetic screening of embryos. Based on recent advances in GS, the present review focuses on new possibilities inherent in reproductive technologies used for commercial purposes and in genetic schemes, possible side effects and beneficial impacts on reproductive efficiency. A particular focus is on the different steps allowing embryo genotyping, including embryo micromanipulation, DNA production and quality assessment.

Retrotransposon expression as a defining event of genome reprogramming in fertilized and cloned bovine embryos.

Genome reprogramming is the ability of a nucleus to modify its epigenetic characteristics and gene expression pattern when placed in a new environment. Low efficiency of mammalian cloning is attributed to the incomplete and aberrant nature of genome reprogramming after somatic cell nuclear transfer (SCNT) in oocytes. To date, the aspects of genome reprogramming critical for full-term development after SCNT remain poorly understood. To identify the key elements of this process, changes in gene expression during maternal-to-embryonic transition in normal bovine embryos and changes in gene expression between donor cells and SCNT embryos were compared using a new cDNA array dedicated to embryonic genome transcriptional activation in the bovine. Three groups of transcripts were mostly affected during somatic reprogramming: endogenous terminal repeat (LTR) retrotransposons and mitochondrial transcripts were up-regulated, while genes encoding ribosomal proteins were downregulated. These unexpected data demonstrate specific categories of transcripts most sensitive to somatic reprogramming and likely affecting viability of SCNT embryos. Importantly, massive transcriptional activation of LTR retrotransposons resulted in similar levels of their transcripts in SCNT and fertilized embryos. Taken together, these results open a new avenue in the quest to understand nuclear reprogramming driven by oocyte cytoplasm.

Delayed and incomplete reprogramming of chromosome methylation patterns in bovine cloned embryos.

Full-term development has now been achieved in several mammalian species by transfer of somatic nuclei into enucleated oocytes [1, 2]. Although a high proportion of such reconstructed embryos can evolve until the blastocyst stage, only a few percent develop into live offspring, which often exhibit developmental abnormalities [3, 4]. Regulatory epigenetic markers such as DNA methylation are imposed on embryonic cells as normal development proceeds, creating differentiated cell states. Cloned embryos require the erasure of their somatic epigenetic markers so as to regain a totipotent state [5]. Here we report on differences in the dynamics of chromosome methylation between cloned and normal bovine embryos before implantation. We show that cloned embryos fail to reproduce distinguishable parental-chromosome methylation patterns after fusion and maintain their somatic pattern during subsequent stages, mainly by a highly reduced efficiency of the passive demethylation process. Surprisingly, chromosomes appear constantly undermethylated on euchromatin in morulae and blastocysts, while centromeric heterochromatin remains more methylated than that of normal embryos. We propose that the abnormal time-dependent methylation events spanning the preimplantation development of clones may significantly interfere with the epigenetic reprogramming, contributing to the high incidence of physiological anomalies occurring later during pregnancy or after clone birth.

Delipidating in vitro-produced bovine zygotes: effect on further development and consequences for freezability.

To study the effect of partial removal of intracytoplasmatic lipids from bovine zygotes on their in vitro and in vivo survival, presumptive zygotes were delipidated by micromanipulation and cocultured with Vero cells in B2+10% FCS. Blastocyst rates of delipidated (n=960), sham (centrifuged but not delipidated, n=830) and control embryos (n=950) were 42.1, 42.3 and 39.9% respectively (P > 0.05). Day 7 blastocysts derived from delipidated zygotes had a mean of 123.9 +/-45.6 nuclei compared to 137.5+/-32.9 for control blastocysts (P > 0.05). The full-term development of delipidated blastocysts after single transfer to recipients was similar to that of control IVF blastocysts (41.2% vs 45.4% respectively). To assess the effect of delipidation on the embryo tolerance to freezing/thawing, delipidated (n=73), control (n=67) and sham (n=50) Day 7 blastocysts were frozen in 1.36 M glycerol + 0.25 M sucrose in PBS. After thawing, embryos were cocultured for 72 h with Vero cells in B2+10% FCS. Survival rates at 24 h were not significantly different between groups. However, in the delipidated group, the survival rate after 48 h in culture was significantly higher than in the control group (56.2 vs 39.8, P < 0.02), resulting in a higher hatching rate after 3 days in culture (45.2 vs 22.4, P < 0.02). Pregnancy rates for delipidated and control frozen/thawed embryos were respectively 10.5 and 22.2% (P > 0.05). Electron microscopic observations showed much fewer lipid droplets (and smaller) in delipated blastocysts than in controls. Taken together, our data show that delipidation of one cell stage bovine embryos is compatible with their normal development to term and has a beneficial effect on their tolerance to freezing and thawing at the blastocyst stage. This procedure, however, alters the developmental potential of such blastocysts, suggesting that maternally inherited lipid stores interfere with metabolic recovery after thawing.

Nuclear transfer from sexed parent embryos in cattle: efficiency and birth of offspring.

The objectives of this study were to evaluate the efficiency and reliability of embryo sexing from isolated single blastomeres, and after nuclear transfer to examine the influence of the sex of donor embryos on development in vitro and in vivo up to calving. The sex of the donor embryo was determined by revealing a specific Y DNA sequence by PCR and electrophoresis after isolation of one, two, three, or more than five cells. The efficiency of sex determination was over 90% and reliability was 100% independent of the number of blastomeres used. In a second experiment, sex was determined from a single cell and the other cells were used for nuclear transfer. The effect of sex on in vitro development was studied in 386 male and 314 female reconstructed embryos derived from 19 male and 14 female parent embryos, respectively. Developmental competence in vitro of male and female constructs over 7 days was not statistically different (25.2 and 23.1% blastocysts on day 7, respectively; P > 0.05). After the transfer of predetermined male (n = 30) and female (n = 27) cloned embryos into recipient heifers, no effect of sex was observed on pregnancy rates at day 21, 35 and 90, or on calving rates (P > 0.05). These rates did not differ between single and twin transfer (P > 0.05). The sex of the calves born always corresponded to that determined from a single blastomere. These results show that sex can be determined accurately when using a single blastomere before nuclear transfer and that the sex of the parent embryo does not affect in vitro development or in vivo survival rates of cloned embryos.

Developmental potential of bovine embryos reconstructed from enucleated matured oocytes fused with cultured somatic cells.

Muscle and skin biopsies taken from bovine fetuses and young calves have been used as a source of donor nuclei for cloning experiments. After culture, cells were individually fused to enucleated matured oocytes and the resulting blastocysts obtained after 7 d of culture (3-8% depending on the cell type) were transferred to foster recipient heifers. Two calves, a female and a male, both originating from muscle cells were born, and four additional pregnancies have surpassed mild-term gestation. The pregnancies include one fetus established from a transgenic nucleus from a fetal skin cell, and another one resulting from a skin biopsy performed on a female calf. Our data demonstrate that nuclei from cultured bovine somatic cells obtained from differentiated tissues can be made multipotent.

Cloning in cattle: from embryo splitting to somatic nuclear transfer.

The ability to obtain genetically identical offspring in cattle (clones) is useful for research and for potential applications to breeding schemes. Experimental possibilities for generating such animals have evolved considerably in the last two decades. Embryo splitting has become a relatively simple technique but is limited to twinning. Embryonic nuclear transfer has improved and is associated with sexing to generate sets of clones despite a great variability of results between parent embryos. The factors of progress are reviewed here. Recently, somatic cells used as a source of nuclei in bovine nuclear transfer has been demonstrated. Here we present the results of the developmental potential of nuclei from skin and muscle cells.

Beneficial effects of Vero cells for developing IVF bovine eggs in two different coculture systems.

A Vero cell line was used for coculture of bovine in vitro fertilized eggs up to blastocyst stage in comparison with bovine oviductal epithelial cells (BOEC) in two culture systems: monolayers or microdrops. Inseminated oocytes cocultured for 7 days with Vero cells in microdrops resulted in a significantly higher blastocyst rate compared to BOEC (29.5% vs 21.1%, respectively; P < 0.01). This difference was not significant in the monolayer coculture system although the blastocyst rate tended to be higher with Vero than with BOEC monolayers (27% vs 22.3%, respectively). Interestingly, the coefficient of variation between replicates was lower in both Vero cell groups than in BOEC groups indicating that Vero cells may help reduce variability. Medium conditioned by Vero cells partly supported embryo development compared to coculture itself (14.6% vs 26.5%, respectively; P < 0.01). Blastocysts developed on Vero cells contained significantly more cells (142 +/- 39) than those developed on BOEC (88.8 +/- 32.8, P < 0.001). Viability of blastocysts developed on Vero cells was evaluated by single transfer to 26 recipient heifers. Confirmed pregnancy rate after 3 months was 58%, demonstrating their high viability.