Delayed development in Fischer's pygmy fruit bat, Haplonycteris fischeri, in the Philippines

A long delay in post-implantation embryonic development was detected in Fischer's pygmy fruit bats (palaeotropical fruit bats of the suborder Megachiroptera), the first time such a delay has been demonstrated outside the bat suborder Microchiroptera. Samples of bats were obtained from the Philippines over 5 years, and reproductive tracts were preserved and examined using standard histological techniques. Most parous female pygmy bats were impregnated in June, within a few weeks of parturition, and the embryos underwent superficial implantation at the anterior end of the uterus contralateral to the previously gravid uterus. Shortly thereafter, the rate of embryonic growth slowed tremendously for up to 8 months. During the period of delay, the mean length of the embryoblast increased only from 280 microns to 520 microns. In March of the following year, the developmental rate increased, and the embryos completed development in the next 3 months. The 8-month delay gives these bats a gestation period of 11.5 months, the longest known in bats. Most nulliparous females become pregnant at an age of 3-5 months, and their embryos entered a similar delay that terminated in March or April, after 2-6 months of delay. Males showed signs of fertility throughout the entire year, but testis volume was highest during May, June and July, at about the time when most females become receptive.     

Apoptosis at the time of embryo implantation in mouse and rat.

The aim of this review is to summarize the information currently available regarding the occurrence of apoptosis in the developing embryo and in the receptive uterus during the peri-implantation period of gestation. Cell death is detected in the inner cell mass of late pre-implantation embryos as the result of an eliminative process that helps trim the embryonic cell lineages of surplus or dysfunctional stem cells. Cell death is also detected in the epiblastic core of early post-implantation embryos, where the process is implicated in the formation of the pro-amniotic cavity. On the maternal side, uterine epithelial cells situated around the attachment site undergo cell death during the initial phase of implantation in order to facilitate embryo anchorage and access to maternal blood supply. Uterine stromal cells closest to the implantation chamber first transform into decidual cells and then commit suicide to make room for the rapidly growing embryo. Although apoptosis is well recognized as a crucial determinant of successful peri-implantation development, our understanding of the cellular and molecular mechanisms regulating this process clearly lags behind the comprehension of cell death control in other systems.     

Position of the embryos of American mink in the fetal chamber at different stages of development]

The spacial position of American mink embryos is characterized by regular changes and is associated with the development and formation of provisory embryonic organs and the uterus. After the implantation the longitudinal axis of the embryo's body lies perpendicularly towards the long axis of the uterus horn. From the end of the 22nd day till birth the embryo moves along the antimesometral side of the fetal chamber by rotation counter clockwise relative to the point of attachment of the alantois stalk. On the 20th day prior to delivery the embryo's body bent as a coil takes a vertical position its fore-part is disposed in the yolk sac cavity, and the hinder part is in the exocoelom. During 17 days before birth the embryo "rolls out" from the yolk sac cavity and occupies the low position in the longitudinal posture of the body. During the following 6 days the prefetus moves towards the opposite side wall of the fetal chamber, takes the upper position and keeps a longitudinal position till the end of the embryonic life.     

人胚胎干细胞向滋养层分化的研究进展

哺乳动物胚胎发育产生的第一个细胞系的分离是内细胞团和滋养层的分离,不同哺乳动物之间胚胎干细胞向滋养层细胞分化不同,滋养层细胞对胚胎的植入、促进胚胎在子宫内的生存和生长至关重要.人胚胎干细胞为研究人类胚胎发育及向滋养层分化提供了一个独特的模型.人胚胎干细胞可以在实验室条件下保持无限期稳定的培养,用于最初胚胎和滋养外胚层发生的机制研究.目前人胚胎干细胞分化为滋养层细胞在体外可以通过自发分化、基因敲除、分离EB小体和BMP4诱导等几种途径实现.不同哺乳动物之间胚胎干细胞向滋养层分化机制,主要通过信号通路如BMP4,LIF等以及某些标志基因如OCT4,CDX2,Eomes等的变化调节.人胚胎干细胞向滋养层分化的研究为临床应用提供了一定的基础.     

Cloning of leukemia inhibitory factor (LIF) and its expression in the uterus during embryonic diapause and implantation in the mink (Mustela vison)

Leukemia inhibitory factor (LIF) is essential for embryo implantation in mice. Whether LIF plays a role in termination of embryonic diapause and initiation of implantation in carnivores, especially in species with obligate delayed implantation such as the mink, is not known. The objectives of this study were to clone the LIF coding sequence in the mink and determine its mRNA abundance in the uterus through embryonic diapause, implantation, and early postimplantation. We show that the mink LIF cDNA contains 609 nt encoding a deduced protein of 203 amino acids. The homologies are 80.6, 90, 88.2, 87.6, and 86.8% in coding sequence and 79.2, 90.1, 91, 90.1 and 85.4% in amino acid sequence with mouse, human, pig, cow, and sheep respectively. Glycosylation sites and disulfide bonds present in other species are generally conserved in the mink LIF sequence. Quantitation by polymerase chain reaction amplification indicates that LIF mRNA is expressed in mink uterus just prior to implantation and during the first two days after implantation, but not during diapause or later after implantation pregnancy. The abundance of LIF mRNA was significantly higher in the uterus at the embryo expansion stage (P < 0.05) than at days 1–2 of postimplantation. By immunohistochemical localization it was shown that LIF is expressed in the uterine epithelial glands at time of embryonic expansion and in early postimplantation. The coincidence of LIF expression with implantation in this species suggests that LIF is involved in the implantation process, and may be a maternal signal which terminates obligate embryonic diapause. Mol. Reprod. Dev. 51:13–21, 1998. © 1998 Wiley-Liss, Inc.     

Early implantation stages in the marmoset monkey (Callithrix jacchus)

The morphology of the initial stages of implantation in the marmoset monkey (Callithrix jacchus) was studied by obtaining embryos and associated endometrium at timed intervals after ovulation. Estrus cycles were detected by measuring daily levels of plasma progesterone. Following a short follicular phase, circulating levels of progesterone above 20 ng/ml were taken as representing day 1 after ovulation. On this basis, single, twin, and triplet embryos were recovered from six perfused-fixed females on days 13, 16, 19, 23, and 29 after ovulation and prepared in resin for light microscopy. Early implantation stages, 13 and 16 days after ovulation, were characterized by the intrusion of syncytial trophoblast between epithelial cells of the endometrium with minimal cellular damage. Some hyperplasia of epithelium at the margin of the implantation site was evident. The consolidation of the initial attachment was achieved by an increase in syncytial trophoblast underlying the inner cell mass of the embryo which rapidly surrounded and breached maternal capillaries. Although initially separate, the chorions of twin or triplet embryos started to fuse by day 19 after ovulation. This process was complete by day 29 such that embryos shared a common uterine exocoelom surrounded by continuous trophoblast. It was concluded that implantation in the marmoset monkey commenced on days 11-12.5 after ovulation and involved an intrusive mechanism. Although trophoblast penetration of endometrium was superficial, maternal capillaries were tapped at an early stage of implantation. The fusion of chorions of twins and triplets first occurred around day 19 after ovulation.     

Uterine-embryonic interaction in pig: activin, follistatin, and activin receptor II in uterus and embryo during early gestation

The mRNA expression patterns of activin beta(A) and follistatin in the uterus and embryo, the mRNA expression of the activin receptor II in the embryo, and the localization in the uterus of the immunoreactive activin beta(A) and the receptor II proteins in the uterus were examined at gestation days 7-12 after ovulation in pig. Activin was located predominantly at the mesometrial side of the uterus during all stages of pregnancy studied. Follistatin mRNA was absent in the uterus during these stages, suggesting that activin of uterine origin is not inhibited by intra-uterine follistatin. The receptor was localized throughout the glandular and luminal epithelium of the uterus. In the embryo, activin was expressed predominantly in the epiblast before unfolding, but after unfolding of the epiblast activin expression shifted to the trophoblast. The expression pattern of follistatin mRNA was contrarily to that of activin, i.e., before unfolding predominantly in the trophoblast (days 8-9), and shifted to the epiblast at day 10. During streak stages, follistatin was detected in the node and primitive streak. Activin receptor II mRNA was first detected at day 8 in the embryoblast. At day 11, it was expressed in trophoblast cells near the epiblast, and in the first ingressing mesoderm cells. During the streak stages, it was expressed predominantly in the trophoblast. The presence of activin and its receptor in uterine epithelium and early embryonic tissues indicate that both embryonic and uterine activin are involved in intra-uterine processes, such as attachment and early embryonic development. Mol. Reprod. Dev. 59: 390-399, 2001.     

A functional overlap of plasminogen and MMPs regulates vascularization during placental development

Both plasminogen activators and matrix metalloproteinases (MMPs) have been implicated in a variety of developmental processes in the mouse during embryo implantation and placentation. We show here that pharmacological treatment of plasminogen-deficient mice with the broad spectrum MMP inhibitor galardin leads to a high rate of embryonic lethality. Implantation sites from plasminogen-deficient galardin-treated mice at 7.5 days post coitus (dpc) showed delay in both decidualization and invasion of maternal vessels into the decidua. At 8.5 dpc, half of the embryos were runted and still at the developmental stage of a 7.5 dpc embryo. Most embryos that escaped these initial defects eventually died, probably from defective vascularization and development of the labyrinth layer of the placenta, although a direct role on embryo development cannot be ruled out. These results demonstrate that the combination of MMPs and plasminogen is essential for the proper development of the placenta. Plasminogen deficiency alone and galardin treatment alone had much less effect and there was a pronounced synergism on both placental vascularization and embryonic lethality, indicating a functional overlap between plasminogen and MMPs.     

Factors affecting the survival of whole and half-embryos transferred in cattle

We estimated that embryonic loss in cattle was about 30% after direct blastocyst transfer. This loss occurred mostly before and during implantation and was augmented by handling the embryo during deep-freezing or culture $\text{in vitro}$. Pregnancy rate increased with the number of embryos transferred. The establishment of a “dialogue” between the embryo and uterus thus depended on the number and quality of the embryonic cells transferred. The trophoblastic cells gave the signal maintaining the corpus luteum of the recipient cow, but the survival of the transferred embryo depended on the good viability of the cells of the embryonic disc.To limit early embryonic loss, the embryonic signal could be amplified by transferring a trophoblastic vesicle $\text{in utero}$ at the same time as the embryo.     

The absence of mitochondrial thioredoxin 2 causes massive apoptosis,exencephaly, and early embryonic lethality in homozygous mice

Thioredoxin 2 (Trx-2) is a small redox protein containing the thioredoxin active site Trp-Cys-Gly-Pro-Cys that is localized to the mitochondria by a mitochondrial leader sequence and encoded by a nuclear gene (Trx-2). Trx-2 plays an important role in cell viability and the regulation of apoptosis in vitro. To investigate the role of Trx-2 in mouse development, we studied the phenotype of mice that have the Trx-2 gene silenced by mutational insertion. Homozygous mutant embryos do not survive to birth and die after implantation at Theiler stage 15/16. The homozygous mutant embryos display an open anterior neural tube and show massively increased apoptosis at 10.5 days postcoitus and are not present by 12.5 days postcoitus. The timing of the embryonic lethality coincides with the maturation of the mitochondria, since they begin oxidative phosphorylation during this stage of embryogenesis. In addition, embryonic fibroblasts cultured from homozygous Trx-2-null embryos were not viable. Heterozygous mice are fertile and have no discernible phenotype visible by external observation, despite having decreased Trx-2 mRNA and protein. These results show that the mitochondrial redox protein Trx-2 is required for normal development of the mouse embryo and for actively respiring cells.     

Spatiotemporal expression of cyclooxygenase 1 and cyclooxygenase 2 during delayed implantation and the periimplantation period in the Western spotted skunk

Embryonic development in the western spotted skunk is arrested after blastocyst formation for about 200 days. This developmental arrest is believed to be due to insufficiency of uterine conditions to support continuous development. Implantation and decidualization are defective in cyclooxygenase 2 (Cox2)-, but not Cox1-, deficient mice. We therefore used Northern and in situ hybridization to investigate changes in uterine expression of Cox1 and Cox2 genes during various stages of pregnancy in the spotted skunk. Cox1 was constitutively expressed at all stages of pregnancy examined, but it did exhibit localized up-regulation in the trophoblast and necks of uterine glands at early implantation sites. Cox2 expression was highly regulated with little or no expression during delayed implantation. Cox2 expression was first detected in the uterus and trophoblast prior to blastocyst attachment and remained detectable for 5-6 days after blastocyst attachment. Cox2 expression was also localized in the luminal and glandular epithelia of uterine segments located between implantation chambers. Changes in Cox expression were not correlated with the abrupt increase in uterine weight that occurs simultaneously with renewed embryonic development but was correlated with an influx of serum proteins into the uterus observed in a previous study.     

Pre-implantation embryo development in BALB/C ByJ mice.

Problem of failure of ovum implantation in BALB/C ByJ strain in comparison to Swiss inbred mouse was studied. The results were compared with those of BALB outbred mice thereafter. BALB/C ByJ strain showed a poor responsiveness to superovulatory stimuli and their embryo development was not uniform. The embryo were delayed in attaining blastocyst stage on day 4. The delay was not significant in Swiss inbred embryos and was prevented by in vitro cultures. By direct embryo transfer it was shown that the uterus was not receptive for successful implantation. However, when these blastocysts were transferred to F1 hybrid (CBA x BALB outbred) recipients demonstrated normal acceptances. This may be a manifestation of inbreeding depression.     

Dissection of 6.5 dpc mouse embryos

Analysis of gene expression patterns during early stages of mammalian embryonic development can provide important clues about gene function, cell-cell interaction and signaling mechanisms that guide embryonic patterning. However, dissection of the mouse embryo from the decidua shortly after implantation can be a challenging procedure, and detailed step-by-step documentation of this process is lacking. Here we demonstrate how post-implantation (6.5 dpc) embryos are isolated by first dissecting the uterus of a pregnant mouse (detection of the vaginal plug was designated day 0.5 poist coitum) and subsequently dissecting the embryo from maternal decidua. The dissection of Reichert's membrane is described as well as the removal of the ectoplacental cone.     

Transforming growth factor alpha (TGFalpha) modulates the effect of genomic imprinting and prolongs the development of parthenogenetic murine embryos]

The effect of transforming growth factor alpha (TGF alpha) on the development of diploid parthenogenetic mouse embryos (CBA x C57BL/6)F1 was studied. The embryos were in vitro treated with the TGF alpha at the stage of morula. Upon reaching the blastocyst stage, each embryo was implanted into uterus of a pseudopregnant female. At a dose of 5 ng/ml, the TGF alpha was found to improve development of parthenogenetic embryos before implantation, increase significantly the number of developing blastocysts, and promote embryo implantation into uterus. After treatment with TGF alpha at a dose of 10 ng/ml, 4% of parthenogenetic embryos reached the stage of 30-45 somites and had forelimb and hindlimb buds; the embryo size from vertex to sacrum was 2.0 to 3.8 mm. A well-developed placenta was observed in 6% of TGF alpha-treated parthenogenetic embryos that reached the somite stages. In the parthenogenetic embryos with the most prominent development (42-45 somites) treated with 10 ng/ml of TGF alpha, the placental diameter was 4.0 to 4.2 mm on day 12 of gestation, which is close to the placental size of the normal (fertilized) 11-day-old mouse embryos. Our results suggest that endogenous TGF alpha can modulate the effects of genomic imprinting significantly improving formation of trophoblast derivatives and promoting longer postimplantation development of parthenogenetic embryos.     

Increased appearance of inducible nitric oxide synthase in the uterus and embryo at implantation.

The aim of this study was to investigate the presence of iNOS in the murine uterus and embryo at implantation. Western blot analysis showed the presence of a 130-kDa band with strong reactivity to anti-iNOS antibody in the pre- and peri-implantation stage uteri. This band was faint in the postimplantation uteri. Immunocytochemical studies showed a heavy localization of iNOS specifically on the apical cells of the uterine endometrium in the pre- and peri-implantation stages. But the postimplantation uteri showed resorbed endometrium showing weaker expression of iNOS. The iNOS was induced by estrogen and the induction was intensified when progesterone was given along with estrogen. This truly mimics the in vivo situation since implantation in mice occurs when an estrogen surge occurs on a background of progesterone. The embryos too express iNOS at the peri-implantation stage. We suggest that iNOS expressed at peri-implantation would lead to enhanced NO production, which could act as a vasodilator and an angiogenic mediator. These effects could promote the attachment of the blastocyst to the uterus.