Interactions between diploid embryonal carcinoma cells and early embryonic cells

Two diploid embryonal carcinoma (EC) cell lines, P10 and P19, differ in their response to the embryonic environment. P10 produces mostly normal chimeras following injection into blastocysts, whereas P19 produces mostly abnormal chimeras. In this study, P10 cells were aggregated with morulae, and all resulting fetuses were chimeric with very large contributions from the EC cells. However, all embryos were abnormal. Following aggregation of P19 cells with morulae, very few embryos were recovered and they were all non-chimeric. Both P10 and P19 were capable of forming functional gap junctions with morula cells and with the ICM of the blastocyst but not with trophoblast, showing that differences in the ability to make junctional contact with the embryo cannot explain the differences between the two cell lines.     

Comparison of aggregation and injection techniques in producing chimeras with embryonic stem cells in mice

We analyzed embryonic stem cell lines for their capacity to produce aggregation chimeras with diploid or developmentally compromised tetraploid embryos. Descendants of embryonic stem cells which contributed to midgestation fetuses at high levels were capable of supporting fetal development also with tetraploid partners. Different numbers of embryonic stem cells were introduced into diploid and tetraploid morulae as well as into blastocysts by microinjection. There were no differences in the frequency of embryonic stem cell-containing fetuses when comparing aggregation or injection into morulae versus blastocysts. However, the distribution pattern of embryonic stem cell derivatives in chimeric fetuses suggested that pre-compaction embryos are more suitable for generating fetuses with high embryonic stem cell contribution. Injection of embryonic stem cells into tetraploid embryos showed that completely embryonic stem cell-derived fetuses can also be produced by this technique. Totally embryonic stem cell derived fetuses were observed in each group, when embryonic stem cells were injected into diploid embryos. However, the rate of chimeras and chimerism was lower when 1 or 3 embryonic stem cells were used versus 8 or 15 cells. This suggests that the number of embryonic stem cells introduced might play a role in the colonization ability.     

Pluripotency of cultured rabbit inner cell mass cells detected by isozyme analysis and eye pigmentation of fetuses following injection into blastocysts or morulae

Pluripotency of isolated rabbit inner cell masses (ICMs) and cultured (3 days) inner cell mass (ICM) cells was tested by injecting these donor cells into day 3.5 blastocysts (experiment 1) or day 3 morulae (experiment 2) to produce chimeric embryos. Injected (n = 107) and noninjected (n = 103) embryos were transferred to the opposite uterine horns of the same recipient females. Chimerism was determined by adenosine deaminase (ADA) isozyme analysis on fetal tissue and by eye pigmentation at midgestation. In experiment 1, 53% and 64%, respectively, of blastocysts injected with ICMs or cultured ICM cells developed to midgestation, compared with 52% and 48% for controls. Of these fetuses, four (31%) and one (6%), respectively, had ADA chimerism. In experiment 2,38% and 62%, respectively, of the morulae injected with ICMs or cultured ICM cells developed to midgestation, compared with 46% and 56% for control morulae. Six (43%) chimeric fetuses from morulae injected with ICMs were detected by ADA analysis, but 12 (86%) chimeric fetuses were detected by eye pigmentation, indicating that eye pigmentation was a more sensitive marker for chimerism than our ADA assay. None of the 14 fetuses recovered after injecting morulae with cultured ICM cells were chimeric with either marker. No chimeras developed from control embryos. These studies demonstrate (1) that pregnancy rates are not compromised by injection of blastocysts or morulae with ICMs or cultured ICM cells, (2) that chimeric rabbit fetuses can be produced by injecting ICMs into either blastocysts or morulae, and (3) that cultured ICM cells can contribute to embryonic development when injected into blastocysts. © 1993 Wiley-Liss, Inc.     

Cell fate in the polar trophectoderm of mouse blastocysts as studied by microinjection of cell lineage tracers

Horseradish peroxidase (HRP), together with Fast Green or rhodamine-conjugated dextran (RDX), was used as an intracellular lineage tracer to determine cell fate in the polar trophectoderm of 3.5-day-old mouse embryos. In HRP-injected midstage (approximately 39-cell) and expanded (approximately 65-cell) blastocysts incubated for 24 hr, the central polar trophectoderm cell was displaced from the embryonic pole an average of 20 micron (5% of blastocyst circumference) and 29 micron (6% of blastocyst circumference), respectively. Expanded blastocysts injected with HRP + Fast Green and incubated for 24 hr or with HRP + RDX and incubated for 48 hr showed a displacement of 24 micron (4% of blastocyst circumference) and 88 micron (14% of blastocyst circumference), respectively. Up to 10 HRP-positive trophectoderm cells were observed among embryos incubated for 48 hr, indicating that in those cases, the labeled progenitor cells had divided at least three times. Our observations show that the central polar trophectoderm cell divides in the plane of the trophectoderm in expanded blastocysts and, along with its descendants, is displaced toward the mural trophectoderm. The systematic tandem displacement of labeled cells and their descendants toward the abembryonic pole suggests the presence of a proliferative area at the embryonic pole of the blastocyst. Large shifts in inner cell mass (ICM) position in relation to the trophectoderm do not occur during blastocyst expansion. Furthermore, random movements within the polar trophectoderm population do not account for the replacement of labeled cells by unlabeled polar trophectoderm cells. Rather, we propose the hypothesis that the ICM contributes these replacement cells to the polar trophectoderm during blastocyst expansion.     

Fate of embryonal carcinoma cells injected into postimplantation mouse embryos

Embryonal carcinoma (EC) cells, stem cells of teratocarcinoma, represent an excellent model to study the developmental mechanisms that, inappropriately reactivated, can drive tumorigenesis. EC cells are very aggressive, and grow rapidly when injected into adult syngeneic mice. However, when injected into blastocysts, they revert to normality, giving rise to chimeric animals. In order to study the ability of postimplantation embryonic environment to "normalize" tumorigenic cells, and to study their homing, we transplanted F9, Nulli-SCC1, and P19 EC cells into 8 to 15-day allogenic CD1 mouse embryos, into allogenic CD1 newborns, and into syngeneic adult mice, and evaluated tumor formation, spreading, and homing. We found that, although at all embryonic stages successful transplantation occurred, the chances of developing tumors after birth increased with the time of injection of EC cells into the embryo. In addition, using enhanced green fluorescent protein-expressing F9 cells, we demonstrated that the cells not giving rise to tumors remained latent and could be tracked down in tissues during adulthood. Our data indicate that the embryonic environment retains a certain ability to "normalize" tumor cells also during post-implantation development. This could occur through yet unknown epigenetic signals triggering EC cells' differentiation.     

Organization of non-muscle myosin during early murine embryonic differentiation

A monoclonal antibody (3D10) recognizing myosin heavy chain was isolated following immunization with a synthetic peptide sequence of eight amino acids. The antibody reacted with purified rabbit skeletal myosin and light mero-myosin in enzyme-linked immunosorbent assays and Western immunoblotting. A band of approximately 200 kDa was detected in cell extracts of an embryonal carcinoma (EC) cell line (P19EC) and one of its cloned differentiated derivatives, suggesting reactivity against non-muscle myosin. By indirect immunofluorescence, typical myosin banding patterns were observed in cryostat sections of human skeletal and cardiac muscle tissue. In undifferentiated P19EC cells, speckled immunofluorescent staining was observed in the cytoplasm that became organized in cortical rings where the cells made direct contact with each other. These rings consisted of circular bundles of F-actin decorated by myosin. Undifferentiated embryonic stem (ES) cells derived directly from mouse embryos shared the same features, although the pattern was less pronounced. Human testicular primary germ cell tumours showed cortical staining in the embryonal carcinoma component reminiscent of the staining of EC cells in vitro while cytoplasmic staining was observed in tumour cells with a differentiated morphology. In preimplantation embryos, the immunofluorescent staining was observed at cell apices of blastomeres of morula stage embryos. In blastocysts, staining of inner cell mass cells was not detectable. By contrast, various differentiated derivatives of P19EC contained extensive F-actin microfilament bundles throughout the cytoplasm decorated with myosin. Thick stress fibers in filopodious extensions of cells were particularly highly decorated by myosin. Over the nucleus, linear arrays of myosin containing speckled patterns of immunofluorescence were observed that were not associated with F-actin. The same pattern of staining could be observed in trophectoderm cells of the blastocyst. We conclude that embryonic non-muscle myosin is organized in specific patterns depending on the state of differentiation. As the myosin is primarily associated with F-actin we suspect that it forms part of a contractile apparatus that may have significance during embryonic development.     

Establishment of porcine transgenic embryonic germ cell lines expressing enhanced green fluorescent protein

The purpose of this study was to isolate porcine embryonic germ (EG) cells and establish transgenic EG cell lines. Plasmid DNA was the enhanced green fluorescent protein (EGFP) vector. Porcine EG cells in rapid proliferation (4th to 9th passage) were transfected with LipofecTamine 2000 and TransFast reagents. Porcine EG cells transfected with a complex of 1 microg of DNA and 2 microL of LipofecTamine 2000 reagent yielded four EG-EGFP cell lines, which emitted bright green fluorescence. EG-EGFP cells cultured for more than 2 weeks without passage gave rise to various differentiated phenotypes. In addition, to determine the degree to which EG cells become integrated into the inner cell mass of host embryos, 135 embryos were injected with porcine EG-EGFP cells; 110 embryos survived and developed into blastocysts (81.5%). Eighty-four chimeric embryos contained fluorescent cells after culture; 49 blastocysts contained EG-EGFP cells in the inner cell mass. Our results suggested that the chimeric rate would not be improved via using different stages of embryos for injection.     

At most three ES cells contribute to the somatic lineages of chimeric mice and of mice produced by ES-tetraploid complementation

Chimeric or entirely embryonic stem (ES) cell-derived mice ("ES mice") can be produced by injecting ES cells into diploid (2n) or tetraploid (4n) host blastocysts, respectively. Usually, between 10 and 15 ES cells are injected into the host blastocyst, but it is not clear how many of the injected cells contribute to the somatic lineages, thus serve as "founder cells" of the embryo proper. We have used genetically labeled ES cells to retrospectively determine the number of founder ES cells that generate the somatic lineages of chimeric and of ES mice. ES cell clones individually labeled with provirus were mixed in equal numbers and injected into 2n or 4n blastocysts to generate chimeric or ES mice. Southern analysis of DNA from the resulting animals indicated that the somatic lineages were most often derived from one or two and sometimes from up to three founder ES cells. The number of founder cells was independent of the total number of cells injected into the host blastocysts. Our results are consistent with the notion that constraints of the host embryo restrict the number of ES cells that can contribute to a chimeric or an ES mouse.     

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.     

Sex differentiation and germ cell production in chimeric pigs produced by inner cell mass injection into blastocysts

This study aimed at collecting background knowledge for chimeric pig production. We analyzed the genetic sex of the chimeric pigs in relation to phenotypic sex as well as to functional germ cell formation. Chimeric pigs were produced by injecting Day 6 or Day 7 inner cell mass (ICM) cells into Day 6 blastocysts. Approximately 20% of the piglets born from the injected blastocysts showed overt coat color chimerism regardless of the embryonic stage of donor cells. The male:female sex ratio was 7:2 and 6:1 in the chimeras derived from Day 6 and Day 7 ICM cells, respectively, showing an obvious bias toward males. When XX donor cells were injected into XY blastocysts at the same embryonic stage, the phenotypic sex of the resulting chimera was male with no germ-line cells formed from the donor cell lineage. On the other hand, when the donor was XY and the recipient blastocyst was XX, the phenotypic sex of the chimera was male, and germ-line cells were derived only from the donor cells. The combination of XY donor cells and XY blastocysts produced some chimeras in which the donor cell lineage did not contribute to germ-line formation even when it appeared in coat color. When the embryonic stage of the donor was advanced by 1 day in the XY-XY combination, 100% of the germ-line cells of the chimeras were derived from the donor cell lineage. These data showed that characteristics of sex differentiation and germ cell formation in chimeric pigs are similar to those in chimeric mice.     

远交系小鼠胚胎干细胞系的建立及嵌合鼠的获得

ＥＳ细胞（ＥｍｂｒｙｏｎｉｃＳｔｅｍＣｅｌｌｓ）是来源于小鼠早期胚胎的多潜能干细胞,它可以在体外大量培养。并以单细胞的形式注射到早期胚胎里,发育为嵌合体。到目前为止,通常使用的１２９小鼠品系是来源于近交系（ｉｎｂｒｅｄ）小鼠的胚胎．与之相比,远交系小鼠应当具有较强的生命力和抗病能力。曾有人报道过建成了远交系小鼠胚胎干细胞系,但是尚没有见到获得嵌合鼠的报道。有人甚至认为：由于不同品系小鼠所具有的遗传背景不同,有的小鼠不能建成ＥＳ细胞系。最近,本实验室在这方面做了有益的探索,成功地建成了远交系小鼠胚胎干细胞系,并在这里报导首例用远交系小鼠胚胎干细胞系培育成功嵌合体小鼠。采用源于Ｓｗｉｓｓ小鼠远交群的昆明（ＫＭ）品系小鼠囊胚建成了三个小鼠胚胎干细胞系（ＫＥ１．ＫＥ２．ＫＥ５）。核型正常率均达到７０％以上。自第八代起分批冻存,复苏后,培养至第１２代,消化成单细胞,通过囊胚显微注射,将其注射到６１５品系小鼠胚胎。在幸存的幼鼠中获得了一只来源于ＫＥ１细胞的嵌合鼠（Ｔａｂｌｅ１）．其毛色表现为受体鼠（６１５）的白色中嵌合有供体鼠（ＫＭ）的黑褐色（ＰｌａｔｅＩ－Ａ）．嵌合鼠与受体鼠的杂交后代鼠中仍然出现了受体鼠的毛色类型（     

The Activin A-Dependent Proliferation of PCC3/A/1 Embryonal Carcinoma Cells in Serum-Free Medium

Examination of the growth requirements of murine embryonal carcinoma cells (EC cells) or embryonic stem cells (ES cells) in serum-free medium revealed that PCC3 EC cells required activin A to grow and/or survive in such medium. In the absence of activin A, PCC3 cells began to disintegrate within 3 days under any serum-free conditions examined. P19 and AT805 EC cells grew even in serum-free medium without activin A but their growth rates were slightly facilitated by its addition. F9 EC cells also grew in the medium without activin A and its addition somewhat inhibited their growth rate. Three independently isolated ES cell lines and feeder-dependent PSA-1 EC cells also grew in serum-free medium without activin A if leukemia inhibitory factor (LIF) was supplemented. The addition of activin A had little effect on their growth rates. These findings suggest that PCC3 EC cells are a sort of nutritional mutant requiring activin A, thus making them useful in stidies on the growth regulatory mechanisms of EC/ES cells and/or the action of activin on EC/ES cells.     

Chimeric pigs following blastocyst injection of transgenic porcine primordial germ cells.

Porcine primordial germ cell (PGC) derived cell lines of WAPhGH-transgenic pigs have been established that were able to contribute to chimeras. PGCs were isolated from day 25 to 28 genital ridges of more than 30 individual transgenic fetuses in order to have an easy to follow marker gene. To support undifferentiated growth, cell lines were derived and stable maintained on STO no. 8 feeder cells, a murine embryonic fibroblast cell line expressing recombinant, membrane-bound porcine stem cell factor (SCF). Fifteen lines proliferated in an undifferentiated state up to passage 13; two lines were maintained for more than 23 passages. Cell staining experiments for differentiation markers in several cell lines, indicated the presence of pluripotent cells in prolonged cultures. Further characterization using karyotyping revealed a normal, euploid set of chromosomes in cells of passages 15 and higher. Pluripotency of freshly isolated, short-term (up to 24 hr before injection) and long-term cultured, frozen/thawed cells was tested by injection into day 6 recipient blastocysts to give rise to chimeric piglets. The injected embryos (n = 209) were endoscopically transferred into the uterine horns of 11 recipient gilts. Tissue analysis from 49 fetuses and eighteen liveborn piglets for PGC contribution in chimeras was carried out using PCR analysis for the presence of the marker transgene. Thirty-two fetuses showed detectable chimerism in up to five out of 12 tissues analyzed. Skin samples from eight piglets were positive for the transgene, four of them displayed coat colour chimerism.     

The developmental potential of the inner cell mass of blastocysts that were derived from mouse ES cells using nuclear transfer technology

The present study examined the causes of the low developmental potential of enucleated oocytes that have received ES cells and consequent postnatal death of the young. The inner cell masses (ICM) of nuclear-transferred blastocysts or diploid blastocysts were injected into tetraploid blastocysts (group B) or nuclear-transferred tetraploid blastocysts (group C), respectively. The developmental potential of these groups was compared with tetraploid blastocysts injected with ICM of diploid blastocysts (group A). The potential of reconstituted blastocysts to develop into live young in group B increased slightly (5%) but was significantly lower than that in group A (45%). The rate of postnatal death of young in group B did not decrease. The implantation rate of reconstituted blastocysts in group C was very low and no live fetuses were obtained. The results of the present study indicate that the inferior potential of both ICM and trophectoderm cells of nuclear-transferred blastocysts underlies the low developmental rate of nuclear-transferred oocytes receiving ES cells and the higher rate of postnatal death of ES cell-derived young.     

Isolation and culture of embryonic stem-like cells from pig nuclear transfer blastocysts of different days

This study was conducted to establish pig embryonic stem (ES)-like cell lines from nuclear transfer blastocysts. A green fluorescent protein (GFP)-expressing cell line was used as the source of donor cells injected into the enucleated oocytes. Blastocysts were collected at D5 (the fifth day), D7 (the seventh day) and D9 (the ninth day). Differential staining was used to assay the viability and development of blastocysts from the 3 days. The number of inner cell mass (ICM) cells increased from 1.83 ± 0.8 (D5) to 5.37 ± 1.2 (D7) to 7.56 ± 1.5 (D9). The expression profiles of embryonic stem (ES) cell factors (OCT4, SOX2, KLF4 and c-MYC) correlated best with the undifferentiated ES state and were identified by qPCR. The expression of the four factors was increased from D5 to D7, whereas the expression decreased from D7 to D9. We tried to isolate ES-like cells from these embryos. However, ES-like cells from the D7 blastocysts grew slowly and expressed alkaline phosphatase. The cells from the D9 blastocysts grew rapidly but did not express alkaline phosphatase. ES-like cells were not isolated from the D5 blastocysts. These results show that the cells from the D7 embryos are pluripotent but grow slowly. The cells from the D9 embryos grow rapidly but start to lose pluripotency.     

H19/Igf2 Expression and Methylation of Histone 3 in Mice Chimeric Blastocysts

Background:Currently, the efficient production of chimeric mice and their survival are still challenging. Recent researches have indicated that preimplantation embryo culture media and manipulation lead to abnormal methylation of histone in the H19/Igf2 promotor region and consequently alter their gene expression pattern. This investigation was designed to evaluate the relationship between the methylation state of histone H3 and H19/Igf2 expression in mice chimeric blastocysts.Methods:Mouse 129/Sv embryonic stem cells (mESCs) expressing the green fluorescent protein (mESCs-GFP) were injected into the perivitelline space of 2.5 days post-coitis (dpc) embryos (C57BL/6) using a micromanipulator. H3K4 and H3K9 methylation, and H19 and Igf2 expression was measured by immunocytochemistry and q-PCR, respectively, in blastocysts. Results:Histone H3 trimethylation in H3K4 and H3K9 in chimeric blastocysts was significantly less and greater, respectively (p< 0.05), than in controls. H19 expression was significantly less (p< 0.05), while Igf2 expression was less, but not significantly so, in chimeric than in control blastocysts.Conclusion:Our results showed, that the alteration ofH3K4me3 and H3K9me3 methylation, change H19/Igf2 expression in chimeric blastocysts.Key Words: Chimeric blastocysts, H19/Igf2, Histone 3 (H3) methylation     

Fate of tetraploid cells in 4n<-->2n chimeric mouse blastocysts

Previous studies have shown that tetraploid (4n) cells rarely contribute to the derivatives of the epiblast lineage of mid-gestation 4n<-->2n mouse chimeras. The aim of the present study was to determine when and how 4n cells were excluded from the epiblast lineage of such chimeras. The contributions of GFP-positive cells to different tissues of 4n<-->2n chimeric blastocysts labelled with tauGFP were analysed at E3.5 and E4.5 using confocal microscopy. More advanced E5.5 and E7.5 chimeric blastocysts were analysed after a period of diapause to allow further growth without implantation. Tetraploid cells were not initially excluded from the epiblast in 4n<-->2n chimeric blastocysts and they contributed to all four blastocyst tissues at all of the blastocyst stages examined. Four steps affected the allocation and fate of 4n cells in chimeras, resulting in their exclusion from the epiblast lineage by mid-gestation. (1) Fewer 4n cells were allocated to the inner cell mass than trophectoderm. (2) The blastocyst cavity tended to form among the 4n cells, causing more 4n cells to be allocated to the hypoblast and mural trophectoderm than the epiblast and polar trophectoderm, respectively. (3) 4n cells were depleted from the hypoblast and mural trophectoderm, where initially they were relatively enriched. (4) After implantation 4n cells must be lost preferentially from the epiblast lineage. Relevance of these results to the aetiology of human confined placental mosaicism and possible implications for the interpretation of mouse tetraploid complementation studies of the site of gene action are discussed.     

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.