Expression and function of cell surface extracellular matrix receptors in mouse blastocyst attachment and outgrowth

Mouse-hatched blastocysts cultured in vitro will attach and form outgrowths of trophoblast cells on appropriate substrates, providing a model for implantation. Immediately after hatching, the surfaces of blastocysts are quiescent and are not adhesive. Over the period 24-36 h post-hatching, blastocysts cultured in serum-free medium become adhesive and attach and spread on the extracellular matrix components fibronectin, laminin, and collagen type IV in a ligand specific manner. Attachment and trophoblast outgrowth on these substrates can be inhibited by addition to the culture medium of an antibody, anti-ECMr (anti-extracellular matrix receptor), that recognizes a group of 140-kD glycoproteins similar to those of the 140-kD extracellular matrix receptor complex (integrin) recognized in avian cells by CSAT and JG22 monoclonal antibodies. Addition to the culture medium of a synthetic peptide containing the Arg-Gly-Asp tripeptide cell recognition sequence of fibronectin inhibits trophoblast outgrowth on both laminin and fibronectin. However, the presence of the peptide does not affect attachment of the blastocysts to either ligand. Immunoprecipitation of 125I surface-labeled embryos using anti-ECMr reveals that antigens recognized by this antibody are exposed on the surfaces of embryos at a time when they are spreading on the substrate, but are not detectable immediately after hatching. Immunofluorescence experiments show that both the ECMr antigens and the cytoskeletal proteins vinculin and talin are enriched on the cell processes and ventral surfaces of trophectoderm cells in embryo outgrowths, in patterns similar to those seen in fibroblasts, and consistent with their role in adhesion of the trophoblast cells to the substratum.     

Role of the extracellular matrix protein thrombospondin in the early development of the mouse embryo

The distribution of the extracellular matrix protein thrombospondin (TSP) in cleavage to egg cylinder staged mouse embryos and its role in trophoblast outgrowth from cultured blastocysts were examined. TSP was present within the cytoplasm of unfertilized eggs; in fertilized one- to four-cell embryos; by the eight-cell stage, TSP was also densely deposited at cell-cell borders. In the blastocyst, although TSP was present in all three cell types; trophectoderm, endoderm, and inner cell mass (ICM), it was enriched in the ICM and at the surface of trophectoderm cells. Hatched blastocysts grown on matrix-coated coverslips formed extensive trophoblast outgrowths on TSP, grew slightly less avidly on laminin, or on a 140-kD fragment of TSP containing its COOH terminus and putative cell binding domains. There was little outgrowth on the NH2 terminus heparin-binding domain. Addition of anti-TSP antibodies (but not GRGDS) to blastocysts growing on TSP strikingly inhibited outgrowth. Consistent with its early appearance and presence in trophoblast cells during implantation, TSP may play an important role in the early events involved in mammalian embryogenesis.     

Trophoblast-specific DNA methylation occurs after the segregation of the trophectoderm and inner cell mass in the mouse periimplantation embryo

The first cell differentiation in the mammalian development separates the trophoblast and embryonic cell lineages, resulting in the formation of the trophectoderm (TE) and inner cell mass (ICM) in blastocysts. Although a lower level of global DNA methylation in the genome of the TE compared with ICM has been suggested, the dynamics of the DNA methylation profile during TE/ICM differentiation has not been elucidated. To address this issue, first we identified tissue-dependent and differentially methylated regions (T-DMRs) between trophoblast stem (TS) and embryonic stem (ES) cells. Most of these TS–ES T-DMRs were also methylated differentially between trophoblast and embryonic tissues of embryonic day (E) 6.5 mouse embryos. Furthermore, we found that the human genomic regions homologous to mouse TS–ES T-DMRs were methylated differentially between human placental tissues and ES cells. Collectively, we defined them as cell-lineage-based T-DMRs between trophoblast and embryonic cell lineages (T–E T-DMRs). Then, we examined TE and ICM cells isolated from mouse E3.5 blastocysts. Interestingly, all T-DMRs examined, including the Elf5, Pou5f1 and Nanog loci, were in the nearly unmethylated status in both TE and ICM and exhibited no differences. The present results suggest that the establishment of DNA methylation profiles specific to each cell lineage follows the first morphological specification. Together with previous reports on asymmetry of histone modifications between TE and ICM, the results of the current study imply that histone modifications function as landmarks for setting up cell-lineage-specific differential DNA methylation profiles.     

Functional analysis of trophoblast giant cells in parthenogenetic mouse embryos

Diploid mouse embryos containing only maternal DNA (parthenotes) fail, in part, because the inner cell mass does not induce the trophoblast to grow. In this study, we asked whether any of the defects in parthenotes may arise from alterations in trophoblast function. We examined the expression of genes important for normal trophoblast function and found several trophoblast genes that were expressed at normal levels in the primary trophoblast cells of parthenotes: E-cadherin, a cell adhesion molecule, was expressed normally in both the ICM and trophectoderm of parthenogenetic blastocysts and blastocyst outgrowths; the gene for Hxt, a basic helix-loop-helix factor that regulates trophoblast development, was expressed in both zygotic and parthenogenetic giant cells; placental lactogen-1, a hormone that is normally secreted by trophoblast giant cells, was expressed in most of both parthenogenetic and normal trophoblast cells; and the 92 kDa matrix metalloproteinase, gelatinase B, also known as MMP-9, was secreted at equivalent levels by both zygotic and parthenogenetic blastocyst outgrowths. However, once the outgrowths had developed, a subpopulation of trophoblast cells in parthenogenetic embryos had decreased DNA replication and significantly fewer nucleoli per nucleus than did zygotic embryos. Moreover, the parthenogenetic trophoblast cells growing out from blastocysts had a decreased viability in culture. These data suggest that, although parthenogenetic embryos are able to initiate primary trophoblast differentiation, the stability and continued differentiation of trophoblast giant cells may be abnormal. Our data support the hypothesis that the deficiency of secondary trophoblast giant cells may contribute to the decline of parthenogenetic embryos and suggest that the factors controlling this subset of trophoblast are distinct from those for primary trophoblast. Dev Genet 20:1–10, 1997. © 1997 Wiley-Liss, Inc.     

Production of mice derived entirely from embryonic stem cells after injecting the cells into heat treated blastocysts

The sensitivity of the inner cell mass (ICM) and trophectoderm (TE) of mouse blastocysts to high temperatures was examined. When blastocysts with a diameter of 100 to 120 microm treated for 15 to 20 min at 45 degrees C were cultured in vitro, the cell number in the ICM did not increase, although that in the TE did increase. After transfer of treated blastocysts to recipients, implantation was not drastically inhibited but no live fetuses were obtained. These results demonstrated that the ICM at the blastocyst stage was more sensitive to high temperature than the TE. ICM clumps or ES cells were injected into blastocysts treated for 20 min at 45 degrees C. After transfer of injected blastocysts to recipients, we obtained mice derived completely from ICM or ES cells as judged by GPI analysis. Since 4 of 7 ES-cell derived mice, but none of the 6 mice derived from the ICM died after birth, an as yet unidentified epigenetic alteration might have occurred during the establishment and/or culture of ES cells.     

Analysis of DNA fragmentation of in vitro cultured bovine blastocysts using TUNEL

Programmed cell death (apoptosis) characteristically affects the single cells of blastocysts whereas necrosis affects cluster of cells in both the inner cell mass (ICM) and the trophectoderm (TE). This study uses the trophectodermrminal deoxynucleotidyl transferase (TdT) mediated dUTP nick-end labeling (TUNEL) assay as a way of evaluating the proportion of apoptotic cells and, thus, bovine blastocyst quality during in vitro culture at Days 6,7, and 8. Furthermore, parthenogenetic blastocysts were compared to in vitro fertilized blastocysts at Day 7. Confocal microscopy was used to generate three-dimensional reconstructions of the blastocysts. Apoptosis was observed in both early (Day 6) and late (Day 8) developing blastocysts. The dead cell index (DCI, total number of apoptotic nuclei/total number of nuclei) tend to increase as the in vitro culture time increases, and apoptosis is proportionately higher in the ICM than in the TE. The ratio of ICM to TE cells remains relatively constant even as the blastocysts cell number increases (Day 6 = 11.9 +/- 2.2, Day 7 = 11.2 +/- 0.5, Day 8 = 11.7 +/- 0.4). The overall cell number is significantly reduced in parthenogenetic blastocysts compared to Day 7 in vitro produced blastocysts (P = 0.037). The parthenogenetic blastocysts also show an increase of apoptosis over Day 7 controls. The decrease in cell number in the parthenogenetic blastocysts may be due to the increase of apoptotic nuclei observed. Based on these results we found the TUNEL assay to be a useful method for evaluating in vitro culture conditions of pre-implantation bovine embryos.     

A rapid procedure for visualising the inner cell mass and trophectoderm nuclei of mouse blastocysts in situ using polynucleotide-specific fluorochromes

A rapid procedure has been devised to count the numbers of outer trophectoderm (TE) and inner cell mass (ICM) cells of mouse blastocysts by differentially labelling their nuclei in situ with polynucleotide-specific fluorochromes. The TE nuclei were labelled with propidium iodide (PI) by permeabilising the cells using selective antibody-mediated complement lysis (Solter and Knowles, '75). The blastocysts were then fixed in ethanol and the ICM nuclei labelled with bisbenzimide. These two fluorochromes have widely different fluorescent spectra. Thus, by using fluorescence microscopy with appropriate filter combinations, the PI-labelled TE nuclei appeared pink or red; the bisbenzimide-labelled ICM nuclei, blue or unlabelled. The total numbers of blastocyst nuclei and the numbers of ICM nuclei counted by differential labelling were similar to the numbers detected after spreading the nuclei of intact blastocysts or immunosurgically isolated ICMs by air-drying (Tarkowski '66). Differential labelling of TE and ICM nuclei in situ has two important advantages--that the numbers of both these cell types can be determined for individual blastocysts and that spatial relationships are partially preserved so that regional interactions can be studied.     

Effects of metabolic inhibitors on mouse preimplantation embryo development and the energy metabolism of isolated inner cell masses

The effects of two metabolic inhibitors, methyl palmoxirate (MP) and amino-oxyacetate (AOA), on mouse preimplantation embryo development and cell number, and inner cell mass (ICM) cell metabolism have been examined. Two-cell embryos were cultured in media supplemented with either MP, which inhibits fatty acid oxidation, or AOA, which inhibits the transamination of glutamate into α-ketoglutarate. Embryos were scored for development daily. On day 5, expanded blastocysts were differentially labeled with fluorochromes to visualize TE and ICM cell nuclei, or the ICMs isolated by immunosurgery and their energy metabolism determined using microfluorometric methods. Embryos exposed to the two inhibitors developed into fully expanded blastocysts, although cell numbers of both the TE and ICM cells were significantly reduced compared to controls. The uptake of glucose in the presence of 1 mM MP or AOA did not differ from the controls, but less glucose was accountable for by lactate production. MP significantly reduced lactate production. In the presence of 4 mM AOA, the amount of glucose oxidized and the amount of lactate formed by ICMs were significantly reduced. The results indicate that the fuels used by isolated mouse ICMs vary in response to substrate availability and that fatty acids may be a potential energy source. © 1996 Wiley-Liss, Inc.     

Cell division and death in the mouse blastocyst before implantation

Summary The numbers of cells in the trophectoderm (TE) and inner cell mass (ICM) of mouse blastocysts were counted by differentially labelling their nuclei with two polynucleotide-specific fluorochromes. Blastocysts recovered from the uterus at intervals between their formation early on Day 4 to the initial stages of implantation on day 5 were analysed. TE cell number increase was initially rapid, indicating some synchronisation of the sixth division, but slowed down progressively and plateaued on Day 5, possibly due to the onset of primary giant cell formation. ICM cell number increase was slower than the corresponding TE cells. As a result, TE cell number more than quadrupled, whereas ICM cell number only doubled over this period. Although the mitotic index of both populations of cells fell steadily, there was no significant difference between them. The decline in the proportion of ICM cells, therefore, is likely to be due to cell death, first detected in early blastocysts and predominantly located in the ICM. In addition, however, a contribution of ICM cells to the overlying polar TE cannot be excluded.     

Protein secretion by the mouse trophoblast during attachment and outgrowth in vitro

Protein secretion from mouse blastocysts undergoing attachment and trophoblast outgrowth in vitro was assessed. When Day 5 blastocysts were cultured in serum-containing medium, secretion of several 'attachment-associated' proteins (PAS) was initiated within 24 h, coincident with attachment and outgrowth. Those proteins characteristic of the pre-attachment blastocyst disappeared or made-up only a small portion of the secretions once attachment began. The major secreted protein from attached embryos, PA1, is a 35,000-45,000 Mr acidic glycoprotein with multiple isoelectric forms. PA2, a group of basic 40,000 Mr proteins and PA3 a group of 72,000 Mr proteins were also produced during outgrowth. PAS were secreted during outgrowth on fibronectin-coated plastic in serum-free medium, but not by blastocysts held in a non-attachment state during culture in serum-free medium on uncoated plastic. In pre-attachment blastocysts, secreted proteins were produced by trophoblast vesicles, but not by isolated inner cell masses. Both trophoblast vesicles growing out in vitro and surgically isolated trophoblast from spreading blastocysts had secreted protein patterns qualitatively similar to those of intact blastocyst outgrowths. The results indicate that development of trophoblast protein secretion continues through the period of outgrowth and giant cell transformation. These changes are apparently dependent on attachment of the blastocyst to a suitable substrate, but not dependent on any other serum influence.     

Effects of fructose supplementation in chemically defined protein-free medium on development of bovine in vitro fertilized embryos

The present study evaluated the possible embryotrophic role of fructose supplementation in potassium simplex optimization medium (KSOM) on preimplantation development of bovine in vitro matured and fertilized (IVF) embryos under chemically defined conditions. In Experiment 1, the rates of cleavage (74.0-75.5%) and blastocyst formation (21.0-24.5%) were not affected by the supplementation of fructose in KSOM in absence or presence of glucose. In Experiment 2, the rates of cleavage (71.7-77.3%) and blastocyst formation (19.9-26.3%) did not differ significantly among the concentrations (0.0, 0.2, 1.5, 3.0, 5.6mM) of fructose supplementations in KSOM in presence of glucose. Moreover, the number of total ICM and TE cells, and percentage of ICM to total cell in blastocysts did not differ significantly among the concentrations of fructose supplementations in presence of glucose. In Experiment 3, the rates of cleavage (67.3-74.7%) and blastocyst formation (14.4-19.3%) did not differ significantly among the concentrations (0.0, 0.2, 1.5, 3.0, 5.6mM) of fructose supplementations in KSOM in absence of glucose. Although the number of total and ICM cells, and percentage of ICM to total cells in blastocysts did not differ significantly among the concentrations of fructose supplementations, 1.5mM fructose supplementation in absence of glucose had significantly (P<0.05) higher number of TE cells (106.2) than that of 5.6mM (84.0) supplementation. The study indicates that, fructose up to 5.6mM concentration can be used as an alternative for energy substrate in culture media without any detrimental effect on pre-implantation development in bovine IVF embryos.     

Successful development of viable blastocysts from enhanced green fluorescent protein transgene-microinjected mouse embryos: comparison of culture media

To improve efficiency of transgenesis, we compared M16 and CZB embryo culture media, supporting development to blastocysts of FVB/N mouse pronuclear-eggs, microinjected with enhanced green fluorescent protein (EGFP) transgene. When EGFP-injected-eggs were cultured (120 hr), blastocyst development was significantly (P < 0.03) higher in M16 medium (72.5 +/- 2.4%) than that in CZB (13.2 +/- 4.3%) or CZBG (CZB with 5.6 mM glucose at 48 hr culture) (62.1 +/- 3.7%) media. Blastocyst development of noninjected embryos was higher in M16 (92.0 +/- 2.6%) and CZBG (83.9 +/- 3.9%) media than in CZB (31.9 +/- 2.8%) medium (P < 0.0001). However, percentages of morulae at 72 hr were comparable in all treatments. Developed blastocysts were better in M16 than in CZB or CZBG media. Consistent with this, mean cell number per blastocyst, developed from injected embryos, was significantly (P < 0.002) higher in M16 medium (79.6), than those in CZB (31.3) or CZBG media (60.7); similar with noninjected embryos. Cell allocation to trophectoderm (TE) and inner cell mass (ICM), i.e., TE:ICM ratio, for injected blastocysts in M16 (3.0) was less than (P < 0.05) those in CZB (4.2) and CZBG (4.4) media; similar with noninjected blastocysts. Moreover, blastocysts, developed in M16 and CZBG media, hatched, attached, and exhibited trophoblast outgrowth; 18% of them showed EGFP-expression. Importantly, blastocysts from M16 medium produced live transgenic "green" pups (11%) following embryo transfer. Taken together, our results indicate that supplementation of glucose, at 48 hr of culture (CZBG), is required for morula to blastocyst transition; M16 medium, containing glucose from the beginning of culture, is superior to CZB or CZBG for supporting development of biologically viable blastocysts from EGFP-transgene-injected mouse embryos.     

Cell allocation in bovine embryos cultured in two media under two oxygen concentrations

Blastocyst development, total cell number and allocation to inner cell mass (ICM) and trophectoderm (TE) lineages was compared among day 9 hatched blastocysts from four culture treatments in a two-factor design. Two modified commercial media (KSOM and SOF) were used in atmospheres with two oxygen concentrations (5% and 20% O2). No significant effect of medium on development was found, but 20% O2 increased hatching (p < 0.05). There were more cells in hatched blastocysts cultured in KSOM than in SOF (181 vs 136, respectively; p < 0.0001); however, ICM/total cell ratio was not affected by medium. There was a trend suggesting that the proportion of cells allocated to ICM was lower in hatched blastocysts cultured under 5% O2 compared with 20% O2 (0.323 vs 0.380, respectively; p < 0.1). No significant interactions between medium type and oxygen concentration were found. These results indicate that culture components used in this study may affect cell proliferation without altering cell allocation, and that oxygen concentration may play a role in allocation of cells to ICM and TE lineages.     

A comparative investigation on the potency of cells from the inner cell mass and trophectoderm of mouse blastocysts to produce chimeras

The ability of trophectoderm (TE) cells to produce chimeric mice (pluripotency) was compared with that of inner cell mass (ICM) cells. TE and ICM cells of blastocysts and hatching or hatched blastocysts derived from albino mice (CD-1, Gpi-1a/a) were aggregated with zona cut 8- to 16-cell stage embryos or injected into the blastocoele from non-albino mice (C57BL/6 x C3H/He, Gpi-1b/b). After transfer to pseudopregnant female mice, the contribution of the donor cells was examined by glucose phosphate isomerase (GPI) analysis of embryos, membrane and placenta at mid-gestation (Day 10.5 and 12.5) or by the coat color of newborn mice. In contrast to ICM cells, there was no contribution of TE cells in the conceptuses and no coat color chimeric young were obtained. After pre-labeling of TE cells with fluorescent latex microparticles, they were aggregated with embryos and the allocation of TE cells at the compacted morula and blastocyst stages was observed under a fluorescent microscope. Although the TE cells were observed attached onto the surface of the embryos at morula and blastocyst stages, unlike the ICM cells, they were not positively incorporated into the embryos. Thus, the pluripotency of TE cells from mouse blastocysts was not induced by the aggregation and injection methods.