Experimental induction of two inner cell masses in mouse embryos by vinblastine treatment in vitro

Induction of artificial fission of the inner cell mass in an in vitro embryonal culture system was attempted. Mouse blastocysts were collected from uteri on day 3 of gestation and exposed to vinblastine sulfate after removal of zona pellucida. Embryos in the control group had a single inner cell mass on the trophectoderm and developed to the postblastocyst stage. On the other hand, the inner cell masses of the embryos in experimental groups subdivided into two or more. The present results, therefore, revealed that the vinblastine treatment at the blastocyst stage induced fission of the inner cell mass in mouse embryos. Further studies are planned in improved culture conditions to determine whether each inner cell mass subdivision develops into independent embryos.     

A method for obtaining a pure population of t6/t6 mouse embryos prior to developmental arrest.

Developmental delay, as the result of ovariectomy, causes mouse blastocyst embryos obtained from +/t6 inter se matings to separate into two distinct populations when placed into outgrowth medium. One population remains as free floating embryos for a significantly longer period of time than the other population. Based upon their phenotypic expression following attachment and outgrowth, the former population was considered to be composed entirely of t6/t6 embryos and the latter, to be composed of +/+ and +/t6 embryos (Nadijcka et al., '81). In the present study, two-dimensional gel electrophoresis identified the embryos which were delayed in attachment as t6/t6 embryos since they synthesize only p63/6.9a, a product of the Tcp-1a locus which is unique to t-haplotypes. The early attaching embryos, assumed to be +/+ and +/t6, synthesize both p63/6.9a and b. The p63/6.9b protein is coded for by Tcp-1b on the wild-type homologous chromosome. Control +/+ blastocyst embryos synthesize only p63/6.9b. The data show that t6/t6 embryos can be identified prior to their lethal period and, thus, subjected to comparative studies to determine the cause of their lethality. Developmental delay is the first method established to enable one to unambiguously identify t6/t6 embryos prior to developmental arrest.     

Post-implantation development of demi-embryos and induction of decidual cell reaction in mice

Mouse demi-embryos that developed from bisected morulae were transferred to recipients. The eu-blastocysts (distinct inner cell mass and well-developed trophectoderm) contained cells equal to 51% of the controls that developed from zona-free morulae. The rate of decidual cell reaction induced by the eu-blastocysts was not significantly different from that of the controls, but the size of the deciduum containing the egg cylinder was significantly smaller on Day 5.5 of pregnancy (P < 0.001). A significant increase in embryonic loss was observed from Day 7.5 to Day 9.5 in the eu-blastocysts (P < 0.05), while the controls exhibited no significant difference. Although the embryos from the eu-blastocysts showed retardation of developmental stages and decreased size, they attained normal stages and size regulation up to 90% of that of the control on Day 10.5. The pseudo-blastocysts (poorly developed inner cell mass enclosed by trophectoderm) contained cells equal to 25% of those of the controls and showed less than a 10% developmental rate to the egg cylinder stage. The trophectodermal vesicles (no enclosed cells) and nonintegrated forms (disorganized clusters of cells) contained cells less than 18% of those of the controls. They showed lower rates of decidual cell reaction than those in the controls (P < 0.05), and no egg cylinder was found in the deciduum. The results indicate that a severe decrease in the number of embryonic cells affects the regulation of embryonic development and decidual cell reaction in the uterus.     

Differentiation in vitro of mouse embryos to the stage of early somite

Mouse blastocysts continuously differentiate in vitro to the early somite stage with reconstituted rat tail collagen as the substrate for the attachment. In order for this to occur, it appears that two differentiation barriers must be overcome. The first, the formation of egg cylinders from the inner cell mass, can be overcome by incubating embryos in heat-inactivated fetal calf serum. The second, the formation of the early somite from the presomite stage, can be overcome by replacing fetal calf serum with human cord serum.Mouse blastocysts were initially incubated with calf serum in Eagle's minimum essential medium. After shedding the zona pellucida, the denuded blastocysts lay flat on the surface of the collagen. Soon thereafter, trophoblastic cells invaded the underlying collagen leaving the rounded inner cell mass protruding from the surface of the collagen. By replacing calf serum in the medium with fetal calf serum the inner cell mass differentiated into endoderm and ectoderm to form an egg cylinder.The egg cylinder rapidly became elongated and formed extraembryonic and embryonic regions. However, the embryonic region shrank from this point on in the fetal calf serum, and the resulting yolk sac formation did not contain the embryo proper. When fetal calf serum was replaced with human cord serum at the end of the egg cylinder stage (equivalent to embryos of about 7.5 days gestation) neural tissue, cardiac chambers, and somites were formed.     

Teratoid Tumors Derived from Mouse Embryos Grown in an Immunologically Privileged Site

Mouse early embryos and embryo fragments were transplanted into an immunologically privileged site, consisting of a glass cylinder previously implanted under the skin of adult mice in order to test their tumor producing potential, in allogeneic adult recipients. The highest yield of tumors was obtained upon transplantation of 6 1/2 day old embryos in toto. i.e., including the embryonic and extraembryonic areas. Histological examination showed teratomas composed of differentiated tissues derived from the three germ layers containing isolated foci of undifferentiated cells and nodules of trophoblast giant cells. Areas exhibiting the histological appearance of yolk sac carcinoma were also observed. Transplantation of the whole 6 1/2 day old egg cylinder, including the ectoplacental cone, and the isolated embryonic area produced a lower incidence of teratomas with a reduced variety of differentiated tissues. No yolk sac carcinoma was found in these grafts. The ectoplacental cone of 6 1/2 day embryos produced no tumors. Grafts of genital ridges from 12 1/2 day embryos gave rise to teratomas with well differentiated tissues of embryonic and extraembryonic origin. Areas ressembling yolk sac carcinoma were also observed. The life span of trophoblastic giant cells within the glass cylinder was significantly longer than in other experimental systems.     

Expression of a glucose-regulated cell surface protein in early mouse embryos

A 100,000-Da glucose-regulated surface protein (100K-GRP) has previously been isolated from the cell surface and culture medium of human fibroblasts. A rabbit antiserum directed against this protein reacts with the cell surface of both human and murine cultured cells and with a broad spectrum of mammalian tissues. It is shown, via indirect immunofluorescence, that this protein is also present on cells of the developing mouse embryo and can be detected as early as the 4-cell stage. The 8-cell embryo and morula show positive surface labeling; the inner cell masses of both the pre- and postimplantation blastocysts are also positive but the trophectoderm is not. At the 6-day egg cylinder stage, the embryonic and extra-embryonic ectoderm label intensely with the antiserum and visceral endoderm shows faint labeling. No labeling can be detected on parietal endoderm or on the trophoblastic giant cells invading the uterine decidua. However, the internal cells of the ectoplacental cone exhibit bright fluorescence. The same pattern is observed on 7- to 8.5-day embryos, except that at this stage no label is associated with the visceral endoderm. In addition, mesodermal cells emerging from the primitive streak are also labeled.     

The extended survival of tw5/tw5 mouse embryo cells in vitro

The tw5 haplotype is a recessive mutation which is lethal when homozygous in mouse embryos following implantation. This series of studies was undertaken to determine the effect of the tw5/tw5 genotype on embryos developing in vitro. Blastocyst embryos from +/tw5 inter se matings were compared with control blastocysts obtained from matings between T/+ and +/+ females and +/tw5 males for their abilities to continue development in vitro in two culture media. The data show that there are no significant differences between the percentages of experimental and control blastocyst embryos which attach and outgrow or which contain inner cell masses on any day of culture up to equivalent gestation day 21 in either media. These findings show that the life span of cells from tw5/tw5 embryos can be extended significantly by in vitro culture.     

Development of bovine and porcine embryonic teratomas in athymic mice

Inner cell masses (ICM) and embryonic discs from bovine and porcine blastocysts of various ages were transplanted under the kidney capsule of athymic (nude) mice to evaluate growth of teratocarcinomas containing both differentiated tissues and undifferentiated stem cells. Inner cell masses were isolated immunosurgically from Day 8, Day 9 and Day 10 porcine blastocysts and from Day 8, Day 10 and Day 12 bovine blastocysts. Embryonic discs were mechanically dissected from Day 11 and Day 12 porcine embryos and from Day 14 bovine embryos. Day 6 egg cylinders were dissected from embryos and from hybrid embryos of a cross between BALB/C and an outbred strain of mouse. Two to four ICM, embryonic discs or egg cylinders were transplanted under the kidney capsule of each athymic host. After 8 weeks, graft hosts were killed and their tumors removed, fixed and prepared for histological and immunohistochemical examination. Embryonic teratomas developed at high frequency from murine egg cylinders and from Day 11 and Day 12 porcine and Day 14 bovine embryos. Tumors were observed only infrequently from younger bovine and porcine blastocysts. Murine embryonic tumors were composed of numerous differentiated cell types of ectodermal, mesodermal and endodermal origins, but representation of the three embryonic germ layers was somewhat more restricted in bovine and porcine embryonic tumors. No undifferentiated stem cells were detected in tumors of any of the three species. These results demonstrate that teratomas will develop from bovine and porcine embryos when grafted to an immunocompromised host, but the presence of undifferentiated teratocarcinoma stem cells from these species has yet to be achieved.     

Chemical defense in the egg masses of benthic invertebrates: an assessment of antibacterial activity in 39 mollusks and 4 polychaetes.

Many marine invertebrates deposit benthic egg masses that are potentially vulnerable to microbial infection. To help counter this threat these species may have evolved some form of chemical protection for their encapsulated embryos. In this study the egg masses from 7 marine mollusks were tested for antibacterial activity against 4 marine pathogens: Enterococcus sericolicida, Vibrio anguillarum, Vibrio alginolyticus, and Vibrio harveyi. Extracts from all of these egg masses were found to inhibit the growth of at least 1 marine bacterium at concentrations that approximate the natural concentration of extract in the egg masses. The egg masses of 39 mollusks and 4 polychaetes were then tested for antibacterial activity against 3 human pathogenic bacteria; Escherichia coli, Staphylococcus aureus, and Pseudomonas aeruginosa. Activity was detected in the egg masses from 34 species, including 2 polychaetes and mollusks from two classes and 18 families. Antibacterial activity in molluskan egg masses was found to extend across the marine, estuarine, freshwater, and terrestrial environments. Both gelatinous egg masses and tough egg capsules were found to inhibit microbial growth, suggesting that physical protection alone may not be sufficient to protect the eggs. Antimicrobial activity was observed in the fresh egg masses but not in the well-developed egg masses of a subset of species. The results of this study indicate that a wide range of invertebrates use chemical defense to protect their early stage embryos against bacterial infection.     

Effects of Lysozyme and Inorganic Anions on the Morphology of Streptococcus mutans BHT: Electron Microscopic Examination

The effects of hen egg white lysozyme and the inorganic salt sodium thiocyanate on the integrity of Streptococcus mutans BHT were studied by transmission electron microscopy. Both control cells and cells exposed to NaSCN possessed thick outer cell walls and densely staining inner cell walls juxtaposed to the plasma membranes. In the presence of NaSCN, however, the S. mutans BHT nucleoid was coagulated into thick electron-dense filaments. Exposure of S. mutans BHT to 150 μg of hen egg white lysozyme per ml resulted in the progressive destruction of both the cell walls and the plasma membranes. The enzyme appeared to affect the region of the cell wall septum, and exposure to 150 μg of hen egg white lysozyme per ml for as short a time as 10 min resulted in visible morphological cell wall alterations. At 30 min, ultrastructural observations revealed that the majority of the cells were in the process of expelling a portion of their cytoplasmic contents from the septal and other regions of the cells at the time of fixation. After 3 h of incubation in the presence of this high lysozyme concentration, gelled protoplasmic masses, which were free from the cells, were evident. In addition, extensive damage to the outer and inner cell walls and to the plasma membranes was apparent, although the cells maintained their shape. On some areas of the cell surface, the outer cell wall and plasma membrane were completely absent, whereas at other locations the outer cell wall was either split away from the inner cell wall and plasma membrane or distended from an area free of inner cell wall and plasma membrane. Upon addition of NaSCN to the hen egg white lysozyme-treated cells, both the gelled protoplasmic masses and the damaged cells exhibited an exploded appearance and existed as membrane ghosts, cell wall fragments, or dense aggregates of cytoplasmic components. The effects of a low lysozyme concentration (22.5 μg/ml) on S. mutans morphology were less pronounced at short incubation times (i.e., 10 and 30 min) than those that were observed with a high enzyme concentration; however, breaks in the cell walls and dissolution of the plasma membranes with resulting cell lysis were visible after a prolonged (3-h) incubation and after subsequent addition of NaSCN.     

Effects of current velocity on development and survival of lingcod,Ophiodon elongatus,embryos

Synopsis The influence of current velocity on the survival and development of lingcod embryos was investigated in the field and laboratory. Examination of egg masses at five lingcod spawning sites indicated that embryo mortalities were high (up to 95%) at low-current sites because of inadequate ventilation and resulting hypoxia. Development of embryos near the center of poorly ventilated egg masses was retarded relative to development of embryos near the periphery. Hatching of embryos from poorly ventilated eggs was protracted; embryos from the interior of egg masses hatched later and were significantly smaller than embryos from eggs near the periphery. Oxygen levels measured in egg masses at low-current velocity sites during tidal flow average 16% air saturation, corresponding to a Median Tolerance Limit (LT₅₀) of about 73 h. Oxygen levels measured in egg masses at high-current velocity sites during slack water average 69% air saturation, a level that did not adversely affect the embryos. Current velocities of 10–15 cm s^–1 were needed to maintain interstitial oxygen levels in egg masses near that of the ambient water. Water movement may be an important stimulus for spawning site selection by lingcod. In areas where tidal currents were weak, spawn deposition occurred in shallow water where waves and vertical tide motion created water movement. In areas where tidal currents were strong, spawns were consistently deposited in deeper water.     

Form, function, and embryonic migration in large gelatinous egg masses of arenicolid worms

Abstract. Attachment and gas exchange are design problems for the spheroidal egg masses that annelids and molluscs tether in sediments. At an intertidal site in Bodega Harbor, a high proportion of masses of arenicolid worms became detached, but they were not stranded higher than attached masses, and the embryos developed to advanced stages. The large masses, weighing 100–200 g, challenge predictions on limiting size for oxygen supply by diffusion. The estimated concentrations of embryos and thickness of the embryo layer exceed the limits predicted by a simple model for oxygen supply by diffusion from the surrounding water, but several features may enhance oxygen supply to embryos. (1) There is an internal cavity. Distal tears in the gel layer admit pulses of water into the center, thus adding an inner surface for gas exchange. (2) The motile embryos aggregate near the outer and sometimes inner surfaces of the gel layer. Embryos migrate in the gel toward regions of greater oxygen concentration. (3) Pennate diatoms colonize the masses, coating the surfaces and penetrating into the gelatinous matrix. Photosynthesis can exceed respiration when a mass is in the light. The pH in gel changes diurnally from a low of ∼7 to as much as 9.5, indicating an excess of respiration over photosynthesis at night and at least sometimes an excess of photosynthesis over respiration by day.     

Embryonic exposure to 2,3,7,8-tetrachlorodibenzo-p-dioxin in chickens: effects of dose and embryonic stage on hatchability and growth

Chicken embryos (Gallus domesticus) were injected with 0, 8, 20 or 50 ng tetrachlorodibenzo-p-dioxin (TCDD) per egg at embryonic day (ED) 4, 8 or 12 to investigate the effects of differential periods of sensitivity to TCDD exposure. At hatch, all chicks were weighed, sexed and examined macroscopically to identify possible malformations. Liver, bursa, heart and spleen masses were recorded from a number of chicks. The remaining chicks were raised until 6 weeks of age and body and organ masses, plasma concentrations of thyroid hormones, triglycerides and glucose were measured. Dose and stage during embryonic development at which injection was performed affected hatchability. Fifty nanogram of TCDD was highly toxic for 4-day-old chicken embryos. TCDD was less toxic for chicken embryos of 8- and especially 12-days old. One-day-old chick and organ weights were not different between TCDD doses at all injection days. However, injection performed at ED4 or ED8 with 20 and 50 ng, respectively, significantly depressed post-hatch body mass gain. Moreover, body mass gain in males was more depressed than in females. The delayed growth in TCDD treated chickens was accompanied by changes in T(3)/T(4) ratio that at some ages were significantly higher compared to control animals. No pronounced changes in plasma triglycerides or glucose concentrations during postnatal life were observed. Absolute and relative organ masses of 6-week-old chickens showed no remarkable changes.     

Vertical development of the secondary palate in hamster embryos following exposure to 6-mercaptopurine

Cellular aspects of vertical development of the secondary palate were examined in control and 6-mercaptopurine (6MP)-treated hamster embryos. Cross-sectional area of the palatal shelf was measured and the numbers of both epithelial and mesenchymal cells counted. Also, in 6MP-treated palates the damaged mesenchymal cells, characterized by the presence of dense bodies, were counted. DNA synthesis in both control and treated fetuses was measured by 3H-thymidine incorporation. The results indicated that both the shelf area and cell numbers increased with age in control and 6MP-treated palates. However, in controls the mesenchymal cell density and DNA synthesis showed two peaks that were absent following 6MP treatment. Unlike controls, in treated embryos the damage to mesenchymal cells became increasingly pronounced between days 10:00 and 10:12 but subsided by day 11:00 of gestation. It is suggested that a major force in the development of the initial primordia and early vertical development of the palatal shelf may be provided by a spurt of DNA synthesis in the mesenchymal cells resulting in their increased number. After 6MP treatment, depression of DNA synthesis and consequent reduction in the mesenchymal cell number and density followed by cell damage lead to retardation in the vertical development of the palatal shelves.     

Mouse zinc transporter 1 gene provides an essential function during early embryonic development

The SLC30 family of cation diffusion transporters includes at least nine members in mammals, most of which have been documented to play a role in zinc transport. The founding member of this family, Znt1, was discovered by virtue of its ability to efflux zinc from cells and to protect them from zinc toxicity. However, its physiological functions remain unknown. To address this issue, mice with targeted knockout of the Znt1 gene were generated by homologous recombination in embryonic stem cells. Heterozygous Znt1 mice were viable. In contrast, homozygous Znt1 mice died in utero soon after implantation due to a catastrophic failure of embryonic development. Although extraembryonic membranes formed around these embryos, the embryo proper failed to undergo morphogenesis past the egg cylinder stage and was amorphous by d9 of pregnancy. Expression of the Znt1 gene was detected predominantly in trophoblasts and in the maternal deciduum during the postimplantation period (d5 to d8). The failure of homozygous Znt1 embryos to develop could not be rescued by manipulating maternal dietary zinc (either excess or deficiency) during pregnancy. However, embryos in Znt1 heterozygous females were approximately 3 times more likely to develop abnormally when exposed to maternal dietary zinc deficiency during later pregnancy than were those in wildtype females. These studies suggest that Znt1 serves an essential function of transporting maternal zinc into the embryonic environment during the egg cylinder stage of development, and further suggest that Znt1 plays a role in zinc homeostasis in adult mice.     

Marine algal symbionts benefit benthic invertebrate embryos deposited in gelatinous egg masses

Algae colonize the gelatinous egg masses of marine invertebrates. This study demonstrates a symbiotic relationship between marine algae and the invertebrate embryos in gelatinous egg masses found in Indian River Lagoon, FL, USA. The benefits to the embryos in this association differ among host species investigated. The embryos of the polychaete Axiothella mucosa graze on the diatom assemblage in their egg masses and the fitness of the crawl-away juveniles is improved by this food source. The tenuous egg masses of the polychaete Arenicola cristata and the mollusk Haminoea succinea are negatively buoyant when spawned and become buoyant when symbiotic algae are present. In addition to increased dispersal of their lecithotrophic larvae, the potential of the egg masses of A. cristata and H. succinea to float may reduce predation on the embryos by benthic predators such as the gastropod Nassarius vibex. Photosynthetically derived oxygen from the algae may benefit the embryos of the opisthobranch Haminoea elegans by increasing oxygen supply when crawl-away juveniles emerge from the egg mass. However, when mostly earlier stage larvae are hatched from egg masses of H. elegans, the additional oxygen supplied by the algae does not provide a substantial advantage. Algae were absent in the gelatinous egg mass core of only one of the five species examined, Haminoea antillarum. H. antillarum has both a short embryonic development time and denser egg mass gel than the other four species tested. What is not understood is whether invertebrate egg masses are an opportunistic space for algae to colonize or whether only a few microalgal species can exploit the gelatinous substrate.     

Influence of copper on the early post-implantation mouse embryo: An in vivo and in vitro study

Summary Female mice were injected intravenously with copper sulphate on either the 7th day (early egg cylinder stage of development), the 8th day (late egg cylinder stage), or the 9th day (early somite stage of development), and examined on the 10th day of gestation. Injection on the 7th day was found to be embryo-lethal; when females were injected on the 8th day, the majority of the surviving embryos exhibited anomalies of the neural tube and/or the heart, while injection on the 9th day resulted in a very low incidence of anomalies. The most common malformations seen on the 10th day involved failure of closure of the neural tube in the head region of the embryo, and various types of anomalies of cardiac rotation and shape. When additional females injected on the 8th day were examined on the 12th day, a high proportion of the fetuses examined had developed exencephaly.A further group of embryos from untreated females were explanted on the 9th day and cultured in vitro in various concentrations of copper sulphate. The lowest levels tested had little obvious effect on neural tube closure. Intermediate doses resulted in, retarded and anomalous embryonic development, while the highest levels employed resulted in neural tube and cardiac anomalies similar to those produced in vivo.The results demonstrate both the direct toxic effect of copper on embryonic development and that the stage of embryonic development at the time of exposure determines both the nature and the extent of the effect.     

Development of 4-cell mouse embryos after re-vitrification

This paper reports studies on the effects of re-vitrification by the CPS (Closed Pulled Straw) method on the development of 4-cell stage mouse embryos. The procedure involved culturing 2-cell mouse embryos in G-1 medium until the 4-cell stage followed by the division of the normal 4-cell stage embryos into a control group (non-vitrified) and two experimental subgroups (vitrified and re-vitrified). Embryos in the vitrified subgroup were cryopreserved by the CPS vitrification method. In the second experimental subgroup (re-vitrified), embryos that were already vitrified were warmed and cryopreserved again by the same method. There was no significant reduction in the rate of blastocyst formation after vitrification and re-vitrification. However, re-vitrification reduced the total cell number, ICM (inner cell mass) percent and blastocyst diameter (P<0.05). These results showed that vitrification and re-vitrification by the CPS method did not negatively affect the development of vitrified-warmed 4-cell mouse embryos, whereas re-vitrification significantly reduced both the cell number and diameter of blastocysts.     

Development of a new rapid measurement technique for fish embryo membrane permeability studies using impedance spectroscopy

Information on fish embryo membrane permeability is vital in their cryopreservation. Whilst conventional volumetric measurement based assessment methods have been widely used in fish embryo membrane permeability studies, they are lengthy and reduce the capacity for multi-embryo measurement during an experimental run. A new rapid 'real-time' measurement technique is required to determine membrane permeability during cryoprotectant treatment. In this study, zebrafish (Danio rerio) embryo membrane permeability to cryoprotectants was investigated using impedance spectroscopy. An embryo holding cell, capable of holding up to 10 zebrafish embryos was built incorporating the original system electrods for measuring the impedance spectra. The holding cell was tested with deionised water and a series of KCl solutions with known conductance values to confirm the performance of the modified system. Untreated intact embryos were then tested to optimise the loading capacity and sensitivity of the system. To study the impedance changes of zebrafish embryos during cryoprotectant exposure, three, six or nine embryos at 50% epiboly stage were loaded into the holding cell in egg water, which was then removed and replaced by 0.5, 1.0, 2.0 or 3M methanol or dimethyl sulfoxide (DMSO). The impedance changes of the loaded embryos in different cryoprotectant solutions were monitored over 30 min at 22 degrees C, immediately following embryo exposure to cryoprotectants, at the frequency range of 10-10(6)Hz. The impedance changes of the embryos in egg water were used as controls. Results from this study showed that the optimum embryo loading level was six embryos per cell for each experimental run. The optimum frequency was identified at 10(3.14) or 1,380 Hz which provided good sensitivity and reproducibility. Significant impedance changes were detected after embryos were exposed to different concentrations of cryoprotectants. The results agreed well with those obtained from conventional volumetric based studies.     

A Brief Contact with Early Embryonic Cells Induces the Differentiation of Embryonal Carcinoma Cells

An assay system was developed to detect a switch of mouse embryonal carcinoma (EC) cells to the pathway for normal cell differentiation after a brief contact with normal embryonic cells. The system consisted of (1) the mixed aggregation of AT805 EC cells with 8-cell stage mouse embryos, (2) the stationary culture of the mixed aggregates into blastocysts and (3) the cell culture of inner cell masses isolated from chimeric blastocysts containing EC cells at 2, 3 and 4 days after the initiaion of chimeric aggregation. The number of foci of EC cells which appeared in the cultures of inner cell masses was decreased with a length of contact of EC cells with normal embryos as the mixed aggregates. After 4 days' contact, only fibroblastic and epithelial cells appeared in most cultures of inner cell masses. Examination of isozyme markers of GPI revealed that such cell cultures consisting of nonmalignant cells contained cells of tumor origin. Thus, it was concluded that a brief exposure to the environment of normal embryos can regulate the tumor cells to differentiate into non-malignant cells. This conclusion was substantiated by comparing the pattern of protein spots of the tumor cells with that of non-malignant cells of the tumor origin by two dimensional gel electrophoresis.