Phospholipid transfer protein (PLTP) mRNA expression is stimulated by developing embryos in the oviduct

In mammal, fertilization and early preimplantation embryo development occurs in the oviduct. Evidence is accumulating that the oviductal epithelia secrete various biomolecules to the lumen during the secretory phase of the estrus cycle to enhance embryo development. This secretory activity of the oviduct is under the regulation of steroid hormones. Observations also suggested that the gametes and embryos modulate the physiology and gene-expressing pattern of the oviduct. However, the underlying molecular changes remain elusive. We hypothesize that the developing embryos interact with the surrounding environment and affect the gene expression patterns of the oviduct, thereby modulating the oviductal secretory activity conducive to the preimplantation embryo development. To test this hypothesis, suppression subtractive hybridization (SSH) was used to compare the gene expressions in mouse oviduct containing transferred in vitro cultured preimplantation embryos with that of oviduct containing oocytes during the preimplantation period. We reported here the identification and characterization of phospholipids transfer protein (PLTP), which is highly expressed in the embryo-containing oviduct and localized at the oviductal epithelium by in situ hybridization. PLTP contains signal peptide putative for secretory function. More importantly, PLTP mRNA increases in the oviductal epithelia of pregnant, but not pseudo-pregnant mice when assayed by real-time PCR. Taken together, our data suggested that PLTP may play important role(s) during in vivo preimplantation embryo development. This molecule would be a target to delineate the mechanisms and the roles of oviductal secretory proteins on early embryonic development.     

Staging mouse preimplantation development in vivo using optical coherence microscopy

In mammals, preimplantation development primarily occurs in the oviduct (or fallopian tube) where fertilized oocytes migrate through, develop and divide as they prepare for implantation in the uterus. Studies of preimplantation development currently rely on ex vivo experiments with the embryos cultured outside of the oviduct, neglecting the native environment for embryonic growth. This prevents the understanding of the natural process of preimplantation development and the roles of the oviduct in early embryonic health. Here, we report an in vivo optical imaging approach enabling high‐resolution visualizations of developing embryos in the mouse oviduct. By combining optical coherence microscopy (OCM) and a dorsal imaging window, the subcellular structures and morphologies of unfertilized oocytes, zygotes and preimplantation embryos can be well resolved in vivo, allowing for the staging of development. We present the results together with bright‐field microscopy images to show the comparable imaging quality. As the mouse is a well‐established model with a variety of genetic engineering strategies available, the in vivo imaging approach opens great opportunities to investigate how the oviduct and early embryos interact to prepare for successful implantation. This knowledge could have beneficial impact on understanding infertility and improving in vitro fertilization. OCM through a dorsal imaging window enables high‐resolution imaging and staging of mouse preimplantation embryos in vivo in the oviduct.      

In vivo culture of embryos in the immature mouse oviduct

In-vitro culture of mammalian preimplantation embryos is associated with subsequent decreased viability. This phenomenon is more pronounced with the domestic species embryos as culture conditions are at present unable to sustain cleavage of early preimplantation embryos for more than one or two cell divisions. In this study, the immature mouse oviduct is shown to be capable of supporting cleavage and morphological development of rabbit and porcine embryos. The immature mouse oviduct was shown to be comparable to in vitro culture as 76% and 60% of the transferred zygotes developed to the morula stage after 2 and 3 d respectively. The porcine zygotes, however, failed to develop beyond the 4-cell stage in either the immature mouse oviduct or in vitro. Porcine morula showed better tolerance of the oviduct environment and when recovered after 2 d contained an average of 64 cells, which was significantly more than in in vitro cultured morulae (40 cells). Early porcine blastocysts transferred to the mouse oviduct had over a two-fold increase in cell division (104 cells) over comparable blastocysts grown in vitro (57 cells). The immature mouse oviduct is, therefore, a potential surrogate environment for short-term storage of embryos of other species.     

Possible expansion of "Window of Implantation" in pseudopregnant mice: time of implantation of embryos at different stages of development transferred into the same recipient

Blastocyst implantation and successful establishment of pregnancy require delicate interactions between the embryo and maternal environment. It is believed that the growth of transferred embryos of different ages is synchronized during preimplantation development and that such embryos are implanted in the uterus at the same time. To define the time of synchronization for developing embryos of different ages, embryos at two different stages of development were transferred separately into the oviducts of the same recipient. We then examined the subsequent development of the embryos at various time intervals after transfer. Pronucleus (PN) stage eggs were transferred separately to the right or left oviduct of recipients on Day 0, while eight-cell embryos (8C) were transferred to the other oviduct. For 8C, 5%, 63%, and 74% of transferred embryos were implanted in the uterus at 42, 66, and 90 h posttransfer, respectively. In contrast, none of the transferred PN was implanted until 90 h posttransfer. At 90 h posttransfer, 59% of the PN had successfully implanted. Histological examination revealed that developmental stage of the embryos in both groups synchronized around 162 h posttransfer, even though the implantation was accelerated in 8C compared with PN. Our results indicate that embryos of advanced stage transferred to the oviduct implant in the uterus in advance of younger embryos and that the uterine development is synchronized at the neural plate, presomite stage. Our results strongly suggest that uterine receptivity for implantation is expandable in pseudopregnant mice.     

The roles of parathyroid hormone-like hormone during mouse preimplantation embryonic development

Parathyroid hormone-like hormone (PTHLH) was first identified as a parathyroid hormone (PTH)-like factor responsible for humoral hypercalcemia in malignancies in the 1980s. Previous studies demonstrated that PTHLH is expressed in multiple tissues and is an important regulator of cellular and organ growth, development, migration, differentiation, and survival. However, there is a lack of data on the expression and function of PTHLH during preimplantation embryonic development. In this study, we investigated the expression characteristics and functions of PTHLH during mouse preimplantation embryonic development. The results show that Pthlh is expressed in mouse oocytes and preimplantation embryos at all developmental stages, with the highest expression at the MII stage of the oocytes and the lowest expression at the blastocyst stage of the preimplantation embryos. The siRNA-mediated depletion of Pthlh at the MII stage oocytes or the 1-cell stage embryos significantly decreased the blastocyst formation rate, while this effect could be corrected by culturing the Pthlh depleted embryos in the medium containing PTHLH protein. Moreover, expression of the pluripotency-related genes Nanog and Pou5f1 was significantly reduced in Pthlh-depleted embryos at the morula stage. Additionally, histone acetylation patterns were altered by Pthlh depletion. These results suggest that PTHLH plays important roles during mouse preimplantation embryonic development.     

未经休眠处理的体细胞用于异种核移植

自“多莉”诞生以来,在全世界掀起了一场体细胞克隆的浪潮,许多体细胞克隆动物,如小鼠、山羊、牛、猪等纷纷问世。围绕体细胞克隆的供体细胞周期问题,学术界存在两种不同的观点,一是Wilmut等认为体细胞必须经过休眠处理,使细胞停滞在G0/G1期,或者采用以G0/G1期为主的活体细胞作为供体,这是克隆成功的关键,这一方面的报道已有很多。第二是Cibelli等认为不必对细胞作     

未经休眠处理的体细胞用于异种核移植（简报）

It is the point at issue in intraspecies nuclear transfer whether quiescence is necessary for development of nuclear transfer reconstructed embryos. In the interspecies nuclear transfer, some reports have proved that quiescent cell is able to support preimplantation development of the interspecies reconstructed embryos. Are non-quiescent cells able to support preimplantation development of the interspecies reconstructed embryos? We used non-quiescent somatic cells from C57BL/6 mice and giant pandas as donors to transfer into enucleated rabbit oocytes. After electrofusion (the electrofusion rates were 62.2% and 71.6%, respectively) and electrical activation, 5.1% of those mouse-rabbit reconstructed embryos developed to blastocyst in vitro, and 4.2% of panda-rabbit reconstructed embryos developed to blastocyst after transferring into ligated rabbit oviduct. These results indicate that non-quiescent cell from C57BL/6 mouse and giant panda could be dedifferentiated in enucleated rabbit oocytes and support early embryo development.     

雌核发育银鲫原肠期胚胎和尾芽期胚胎差异表达基因的呈现

构建了雌核发育银鲫原肠期胚胎和尾芽期胚胎间的抑制性差减杂交cDNA质粒文库。对原肠期’739个和尾芽期816个PCR阳性克隆进行斑点杂交,得到72个原肠期和98个尾芽期斑点杂交阳性克隆。测序和基因数据库比对结果表明：72个原肠期斑点杂交阳性克隆中,包括19个已知基因的cDNA片段和31个没有同源性的cDNA片段;98个尾芽期斑点杂交阳性克隆中,包括52个已知基因的cDNA片段和37个没有同源性的cDNA片段。采用虚拟Northern杂交和RT-PCR证实了部分基因在银鲫胚胎发育过程中的差异表达。这些差异表达基因的呈现为进一步研究银鲫胚胎发育的分子机制奠定了基础。     

兔单个植入前克隆胚胎cDNA文库的构建

人与小鼠和牛在正常胚胎植入前发育过程中基因活化的研究已经取得了长足的进展 ,但是还没有对同期克隆胚胎相关研究的报道 .利用单个家兔植入前移核重构胚胎成功地构建了MⅡ卵母细胞及发育至 4 、8 细胞期的胚胎和囊胚的特异性cDNA文库 .并用 β肌动蛋白和LAPTM4α证实这类文库是可靠的 .以 8 细胞期移核重构胚cDNA文库为例 ,随机挑取克隆进行测序分析 :其中 2 3的基因EST片段可以在GenBank或EST库中找到同源序列 ,约 1 3的EST片段属于未知的新片段 ,表明这是一类重要的新兴基因资源库 (期特异性EST库 ) .这种利用单胚胎构建cDNA文库的方法 ,解决了胚胎研究材料受限的问题 ,在时间上更加精确 ,更符合胚胎发育的规律 ,也能够更加准确地反映出一些克隆胚胎的异常表型 ,是研究早期胚胎发育基因表达以及克隆胚胎再程序化基因表达的一种有效手段 .     

De novo DNA methylation independent establishment of maternal imprint on X chromosome in mouse oocytes

In female mouse embryos, the paternal X chromosome (Xp) is preferentially inactivated during preimplantation development and trophoblast differentiation. This imprinted X-chromosome inactivation (XCI) is partly due to an activating imprint on the maternal X chromosome (Xm), which is set during oocyte growth. However, the nature of this imprint is unknown. DNA methylation is one candidate, and therefore we examined whether disruptions of the two de novo DNA methyltransferases in growing oocytes affect imprinted XCI. We found that accumulation of histone H3 lysine-27 trimethylation, a hallmark of XCI, occurs normally on the Xp, and not on the Xm, in female blastocysts developed from the mutant oocytes. Furthermore, the allelic expression patterns of X-linked genes including Xist and Tsix were unchanged in preimplantation embryos and also in the trophoblast. These results show that a maternal disruption of the DNA methyltransferases has no effect on imprinted XCI and argue that de novo DNA methylation is dispensable for Xm imprinting. This underscores the difference between imprinted XCI and autosomal imprinting.