An embryonic story: Analysis of the gene regulative network controlling Xist expression in mouse embryonic stem cells

In mice, dosage compensation of X‐linked gene expression is achieved through the inactivation of one of the two X‐chromosomes in XX female cells. The complex epigenetic process leading to X‐inactivation is largely controlled by Xist and Tsix, two non‐coding genes of opposing function. Xist RNA triggers X‐inactivation by coating the inactive X, while Tsix is critical for the designation of the active X‐chromosome through cis‐repression of Xist RNA accumulation. Recently, a plethora of trans‐acting factors and cis‐regulating elements have been suggested to act as key regulators of either Xist, Tsix or both; these include ubiquitous factors such as Yy1 and Ctcf, developmental proteins such as Nanog, Oct4 and Sox2, and X‐linked regulators such as Rnf12. In this paper we summarise recent advances in our knowledge of the regulation of Xist and Tsix in embryonic stem (ES) and differentiating ES cells.     

X chromosome reactivation and regulation in cloned embryos

Somatic cell nuclear transfer embryos exhibit extensive epigenetic abnormalities, including aberrant methylation and abnormal imprinted gene expression. In this study, a thorough analysis of X chromosome inactivation (XCI) was performed in both preimplantation and postimplantation nuclear transfer embryos. Cloned blastocysts reactivated the inactive somatic X chromosome, possibly in a gradient fashion. Analysis of XCI by Xist RNA and Eed protein localization revealed heterogeneity within cloned embryos, with some cells successfully inactivating an X chromosome and others failing to do so. Additionally, a significant proportion of cells contained more than two X chromosomes, which correlated with an increased incidence of tetraploidy. Imprinted XCI, normally found in preimplantation embryos and extraembryonic tissues, was not observed in blastocysts or placentae from later stage clones, although fetuses recapitulated the Xce effect. We conclude that, although SCNT embryos can reactivate, count, and inactivate X chromosomes, they are not able to regulate XCI consistently. These results illustrate the heterogeneity of epigenetic changes found in cloned embryos.     

Successful cryopreservation of expanded equine blastocysts

Effective cryopreservation of expanded equine blastocysts (> 300 μm in diameter) has been difficult, perhaps due to the volume of blastocoele fluid or the presence of the equine embryonic capsule. Recently, we reported normal viability of equine embryos after trophoblast biopsy, which resulted in blastocyst collapse. The present study addressed the effect of biopsy and resultant breach of the capsule and blastocyst collapse on survival of expanded equine blastocysts after vitrification. First, non-biopsied, small embryos (< 300 μm) were vitrified in fine-diameter microloader pipette tips using dimethylsulfoxide-containing medium (DM) or ethylene glycol-containing medium (EG). A third group was vitrified with EG, but was warmed using sucrose (EG/s). Embryos in the DM and EG/s treatments grew in culture after vitrification, and established pregnancies after transfer (3 of 12 and 3 of 6, respectively). Expanded blastocysts 300-730 μm in diameter were then biopsied and vitrified; rates of normal pregnancy (detection of embryonic heartbeat) after warming and transfer were 2 of 16 (13%) and 6 of 13 (46%) for DM and EG/s treatments, respectively (P = 0.05). Within the EG/s treatment, it appeared that greater loss of blastocoele fluid after biopsy was associated with higher survival. Therefore, an altered (“Central”) biopsy technique was used to aspirate blastocoele fluid, followed by vitrification in EG/s. Pregnancy rates were 1 of 8 (13%) for embryos cultured after warming and 4 of 7 (57%) for embryos transferred immediately after warming (P = 0.1). Finally, expanded blastocysts 407 to 565 μm in diameter were biopsied from the periphery, and blastocoele fluid was removed with gentle suction. After vitrification with EG/s, this resulted in a rate of normal pregnancy of 5 of 7 (71%). These findings demonstrated that blastocoele collapse and vitrification in fine-diameter pipettes allowed successful cryopreservation of expanded equine blastocysts.     

X-inactivation is stably maintained in mouse embryos deficient for histone methyl transferase G9a

One of the two X chromosomes becomes inactivated during early development of female mammals. Recent studies demonstrate that the inactive X chromosome is rich in histone H3 methylated at Lys-9 and Lys-27, suggesting an important role for these modifications in X-inactivation. It has been shown that in the mouse Eed is required for maintenance of X-inactivation in the extraembryonic lineages. Interestingly, Eed associates with Ezh2 to form a complex possessing histone methyltransferase activity predominantly for H3 Lys-27. We previously showed that G9a is one of the histone methyltransferases specific for H3 Lys-9 and is essential for embryonic development. Here we examined X-inactivation in mouse embryos deficient for G9a. Expression of Xist, which is crucial for the initiation of X-inactivation, was properly regulated and the inactivated X chromosome was stably maintained even in the absence of G9a. These results demonstrate that G9a is not essential for X-inactivation.     

Xist nucleates local protein gradients to propagate silencing across the X chromosome

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Effect of dehydration prior to cryopreservation of large equine embryos

Cryopreservation of equine embryos > 300 μm in diameter results in low survival rates using protocols that work well for smaller equine embryos. These experiments tested the potential benefit of incorporating a dehydration step prior to standard cryopreservation procedures. Forty-six, day 7–8, grade 1, equine embryos 300–1350 μm in diameter were subjected to one of the following treatments: (A) 2 min in 0.6 M galactose, 10 min in 1.5 M glycerol, slow freeze (n = 21); (B) 10 min in 1.5 M glycerol, slow freeze (n = 15); (C) 2 min in 0.6 M galactose, 10 min in 1.5 M glycerol, followed by exposure to thaw solutions, then culture medium (n = 5); (D) transferred directly to culture medium (n = 5). Frozen embryos were thawed and subjected to a three-step cryoprotectant removal. Five embryos from each treatment were evaluated morphologically after 24 and 48 h culture (1 = excellent, 5 = degenerate/dead). All treatments had at least 4/5 embryos with a quality score  3 at these time points except treatment B (2/5 at 24 h, 1/5 at 48 h). Subsequent embryos from treatment A (n = 16) or B (n = 10) were matched in sets of two for size and treatment, thawed, and immediately transferred in pairs to 13 recipients. Only two recipient mares were pregnant; one received two 400 μm embryos from treatment A, and the other one 400 and one 415 μm embryo from treatment B. There was no advantage of incorporating a 2 min dehydration step into the cryopreservation protocol for large equine embryos.     

RNAi in X inactivation: contrasting findings on the role of interference

X inactivation is the process that brings about the dosage equivalence of X‐linked genes in females to that of males. This complex process initiated at a very early stage of female embryonic development is orchestrated by long non‐coding RNAs transcribed in both sense and antisense orientation. Recent studies present contradicting evidence for the role of small RNAs and RNase III enzyme Dicer in the X inactivation process. In this review, I discuss these results in the overall perspective of X inactivation and gene silencing.     

Initiation of transcription and nucleologenesis in equine embryos

The time of activation of the embryonic genome (maternal-embryonic transition) in equine embryos was investigated by assessing incorporation of ³H-uridine and nucleolar development. In Experiment 1, embryos were recovered from the oviduct (n = 15) and the uterus (n = 3). Recovered embryos were assessed for morphologic development and quality score. Recovered embryos with less than 8 cells (two cells, n = 4; four cells, n = 5; five cells, n = 2) were incubated with ³H-uridine (560 μCi/ml) for 10 hr, while eight-cell embryos (n = 2), morulae (n = 2), and blastocysts (n = 3) were incubated with 280 μCi/ml for 0.5–1 hr. At the end of incubation, embryos were washed twice in PBS with 10% FBS and incubated for 30 min with 2.5 mg/ml of unlabelled uridine. Embryos were spread onto glass slides, dipped into emulsion, and exposed for 8 d, then developed and counter-stained with Giemsa and propidium iodide. Embryos at the blastocyst, morula, eight-cell, and five-cell stages incorporated ³H-uridine into their cell nuclei as detected by autoradiography. In a second experiment, nucleologenesis in equine embryos was examined by transmission electron microscopy. Nucleoli or nucleolar precursors were found in 12 of 23 embryos examined. Most embryos in the four- to six-cell stage (n = 7) had nucleolar precursor bodies (npb) consisting of homogeneous fibrillar structures. Two five- to six-cell embryos also possessed reticulated nucleoli with both fibrillar and granular components as did all eight-cell embryos (n = 3). Nucleoli in one morula and one blastocyst were reticulated with prominent granular components, fibrillar components, and apparent fibrillar centers. These results indicate that incorporation of ³H-uridine and the formation of functional nucleoli with typical fibrillar and granular components occurs between the four- to eight-cell stage in equine embryos. © 1995 wiley-Liss, Inc.     

A new procedure for the cryopreservation of equine embryos

Early equine blastocysts and blastocysts were collected nonsurgically at six days post-ovulation. Thirty-two embryos were randomly assigned to a 2x2 factorial design. Factors were: 1) 0.5-ml straws or 1-ml glass ampules; and 2) plunging into liquid nitrogen (IN(2)) at -33 C or -38 C. Cryoprotectant, 10% glycerol in PBS plus 5% fetal calf serum (FCS) was added in two steps, 5% then 10%. Embryos were cooled at 4 C/min to -6 C and then seeded, 0.3 C/min to -30 or -35 C and 0.1 C/min to -33 or -38 C. Samples were thawed in 37 C water and glycerol removed in six steps, 10 min per step. Embryo quality and stage of development were evaluated prior to freezing, immediately post-thaw and after 24 h culture in Ham's F10 with 5% FCS. The mean post-thaw quality of embryos plunged at -33 C was superior (P<0.05) to that of embryos plunged at -38 C (2.0 vs 2.9). Embryos frozen in ampules and plunged at -38 C were of poorer quality (P<0.05) than those frozen in ampules and plunged at -33 C or frozen in straws and plunged at -33 C. After 24 h of culture, more embryos developed if frozen in straws compared to ampules, and plunging at -33 C resulted in higher quality embryos than plunging at -38 C. In Experiment 2, 23 embryos were packaged in straws and plunged at -33 C as described in Experiment 1. Six of the 23 surgically transferred frozen embryos were degenerate at thawing and the remaining 17 surgically transferred were via flank incision. Pregnancy rate at 50 days post-ovulation was 53% (nine of 17). Early blastocysts resulted in a higher (P<0.05) pregnancy rate (8 10 , 80%) than expanded blastocysts (1 7 , 14%).