Regulation and Function of SF/HGF during Migration of Limb Muscle Precursor Cells in Chicken

Limb muscles of vertebrates are derived from migratory dermomyotomal cells which emanate from a limited number of somites located adjacent to the developing limb buds. We have generated additional limb buds in chicken embryos by implantation of FGF-beads into the interlimb region in order to analyze whether these somites can be programmed to supply ectopic limbs with myogenic precursor cells. We show that migrating myogenic precursor cells are released from somites at the level of the newly formed limb, even when cell migration into the natural limb has been completed. The implantation of FGF beads in the lateral plate mesoderm rapidly induces SF/HGF expression. FGF beads implanted between HH stages 10 and 12 inhibit limb bud formation or shift the normal limb position. When an additional FGF bead was implanted at the original limb position at HH stage 15, SF/HGF expression was transiently induced to low levels without inducing a new limb. This demonstrates that the initial induction of SF/HGF by FGF does not require limb formation. Expression of SF/HGF during early limb bud stages was found in the entire developing bud and the adjacent lateral plate mesoderm with direct contacts to the lateral edge of the dermomyotome. Later, the SF/HGF expression domain retracts to a distal region below the apical ectodermal ridge. To investigate the role of SF/HGF in the migratory process, we implanted beads soaked in SF/HGF-alone or together with FGF into different locations of the developing chick embryo. In the experiments SF/HGF caused delamination of migratory cells from the dermomyotomal epithelium but no chemotactic attraction of migrating cells toward the SF/HGF source.     

Interspecies somatic cell nuclear transfer is dependent on compatible mitochondrial DNA and reprogramming factors

Interspecies somatic cell nuclear transfer (iSCNT) involves the transfer of a nucleus or cell from one species into the cytoplasm of an enucleated oocyte from another. Once activated, reconstructed oocytes can be cultured in vitro to blastocyst, the final stage of preimplantation development. However, they often arrest during the early stages of preimplantation development; fail to reprogramme the somatic nucleus; and eliminate the accompanying donor cell's mitochondrial DNA (mtDNA) in favour of the recipient oocyte's genetically more divergent population. This last point has consequences for the production of ATP by the electron transfer chain, which is encoded by nuclear and mtDNA. Using a murine-porcine interspecies model, we investigated the importance of nuclear-cytoplasmic compatibility on successful development. Initially, we transferred murine fetal fibroblasts into enucleated porcine oocytes, which resulted in extremely low blastocyst rates (0.48%); and failure to replicate nuclear DNA and express Oct-4, the key marker of reprogramming. Using allele specific-PCR, we detected peak levels of murine mtDNA at 0.14±0.055% of total mtDNA at the 2-cell embryo stage and then at ever-decreasing levels to the blastocyst stage (<0.001%). Furthermore, these embryos had an overall mtDNA profile similar to porcine embryos. We then depleted porcine oocytes of their mtDNA using 10 μM 2',3'-dideoxycytidine and transferred murine somatic cells along with murine embryonic stem cell extract, which expressed key pluripotent genes associated with reprogramming and contained mitochondria, into these oocytes. Blastocyst rates increased significantly (3.38%) compared to embryos generated from non-supplemented oocytes (P<0.01). They also had significantly more murine mtDNA at the 2-cell stage than the non-supplemented embryos, which was maintained throughout early preimplantation development. At later stages, these embryos possessed 49.99±2.97% murine mtDNA. They also exhibited an mtDNA profile similar to murine preimplantation embryos. Overall, these data demonstrate that the addition of species compatible mtDNA and reprogramming factors improves developmental outcomes for iSCNT embryos.     

Expression of nebulette during early cardiac development

Nebulette, a cardiac homologue of nebulin, colocalizes with alpha-actinin in the pre-myofibrils of spreading cardiomyocytes and has been hypothesized to play a critical role in the formation of the thin-filament-Z-line complex early during myofibrillogenesis. Data from mesodermal explants or whole tissue mounts of developing hearts suggest that the pattern of myofibrillogenesis in situ may differ from observations of spreading cardiomyocytes. To evaluate the role of nebulette in myofibrillogenesis, we have analyzed the expression of nebulette in chicken heart rudiments by immunoblots and immunofluorescence. We detect the 110 kDa nebulette in heart rudiments derived from stage 9-10 using the anti-nebulin mAb, N114, or polyclonal anti-nebulette Abs by immunoblotting. Immunofluorescence analysis of explants stained with anti-nebulette and anti-alpha-actinin Abs demonstrates that both proteins localize along actin filaments in punctate to continuous manner at early stages of cardiac development and later give rise to striations. In both cases, the punctate staining had a periodicity of approximately 1.0 microm indicating a pre-myofibrils distribution at the earliest time points examined. We demonstrate that nebulette is indeed associated with premyofibrils in very early stages of myofibrillogenesis and suggest that nebulette may play an important role in the formation of these structures.     

Differential participation of ventral and dorsolateral mesoderms in the hemopoiesis of Xenopus, as revealed in diploid-triploid or interspecific chimeras

The thymocytes in the early larvae of Xenopus laevis have been shown to be derived from precursor cells immigrating interstitially through the mesenchyme into the organ rudiments at 3-4 days of age (Nieuwkoop and Faber stages 42-45). Orthotopic grafting of diploid tissues onto triploid stage 22 embryos followed by ploidy analyses of their hemopoietic cells revealed that both thymocytes and erythrocytes in early larvae are derived from the ventral blood islands (VBI), whereas those in late larvae and adults come mainly from the dorsolateral plate (DLP). To study how the VBI cells of embryos at stage 22 participate in hemopoiesis, a number of interspecific chimeras were produced in X. laevis and X. borealis embryos. Sections of the chimeras at various developmental stages were examined by employing the unique stainability of X. borealis nuclei to quinacrine as a marker; the results show that the VBI-derived cells enter into the circulation around stage 35/36, and that some of them leave the blood vessels to migrate interstitially through the mesenchyme toward the thymic rudiment during stages 43-45. A minor population of the VBI-derived cells was also found extravascularly in the mesonephric primordia. In contrast to the VBI, the DLP-derived cells contributed to the hemopoietic cell population not in early larvae, but in late ones as a major constituent in the mesonephros, thymus, liver, and peripheral blood.     

C-type virus-lymphocyte interactions in developing mouse thymus.

The appearance of C-type virus particles in thymus cells of Swiss mouse embryos, 11.5 to 15.5 days post-conception age (PCA), was studied with the electron microscope. In thymic rudiments of all specimens examined, virus particles were seen in epithelial cytoplasm, budding from epithelial cell surfaces and in extracellular spaces. Lymphoid cells were first seen in thymic rudiments of 13.5 days PCA, and did not display virus particles at this stage. At 14.5 days PCA, thymic lymphocytes had localized plasmalemmal thickenings of high electron-density which were adjacent to extracellular virus particles. Viruses appeared to be penetrating thymic lymphocytes by viropexis in embryos of 15.5 days PCA. At this stage, many lymphocytes also had cytoplasmic virus-containing vesicles and viral buds at their surfaces. These observations suggest the possibility that, in embryos, C-type viruses are transmitted horizontally from thymic epithelium to early populations of thymic lymphocytes.     

Hypothermia: teratogenic and protective effects on the development of mouse embryos in vitro

Hypothermia often occurs in association with clinical conditions involving severe hypoglycemia, but its effect on embryonic development has not been well evaluated. Thus, the whole embryo culture method was used to expose day 9 (neurulating) and day 10 (early limb bud stage) mouse embryos to physiologic levels of hypothermia (35 degrees C and 32 degrees C) for 4 and 24 hr. Embryos were evaluated after 24 hours for growth and malformations and compared with controls grown at 37 degrees C. Lactate production was measured in embryos cultured for 4 hr at 32 degrees C and compared with those cultured at 37 degrees C. A 4-hr exposure to hypothermia produced little effect morphologically but reduced the rate of lactate production at both embryonic stages. A 24-hr exposure to hypothermia at 35 degrees C or 32 degrees C produced growth retardation and dysmorphogenesis in embryos undergoing neurulation. Early limb bud stage embryos were less sensitive to this treatment, with growth retardation produced only at the lower temperature. Since hypothermia is commonly associated with severe hypoglycemia in cases of diabetic insulin overdose, day 9 (neurulating) mouse embryos were exposed concurrently to short periods of hypothermia and hypoglycemia and compared with embryos cultured in hypoglycemic medium at normal temperature. The results demonstrate that hypothermia partially protects embryos against the dysmorphogenic effects of hypoglycemia. A balance of metabolic rate and available substrate is discussed as a possible mechanism for this protective effect.     

FGF-2-induced imbalance in early embryonic heart cell proliferation: a potential cause of late cardiovascular anomalies

BACKGROUND: This laboratory previously demonstrated that placement of fibroblast growth factor-2 (FGF-2)-soaked beads adjacent to the developing ventricle at stage 24 caused cardiovascular anomalies by embryonic day 15. We sought to characterize early cellular changes that may suggest mechanisms for the abnormalities observed at day 15. Because levels of both myocyte proliferation and immunohistochemically detectable endogenous FGF-2 begin to decline before stage 24 in untreated embryos, it was of interest to determine whether exogenous FGF-2 might maintain cardiac myocyte proliferation at or near peak levels. METHODS: Chick embryos were incubated to stage 18 (2.8 days), at which time beads soaked in phosphate-buffered saline (PBS) or 100 microg/ml FGF-2 were placed adjacent to the developing ventricle and development was allowed to continue. After 3 days (stage 29), bromodeoxyuridine (BrdU) was applied to mark dividing cells, followed by double fluorescent assessments to detect relative numbers of dividing and nondividing cells. RESULTS: Quantitative image analysis, using Metamorph software, showed that exogenous FGF-2 caused a 62% increase in the overall number of dividing cells (P < 0.01), concomitant with a 25% increase in total cell number (cell density: P < 0.05). Expressed in relative terms, these changes corresponded to a 25% increase in the proliferation labeling index: 30% of all cells were proliferating in FGF-treated hearts, in contrast with only 24% in control hearts. CONCLUSIONS: Taken together, these data suggest that an FGF-induced imbalance in myocardial cell proliferation at early developmental stages of heart development causes cardiovascular anomalies during late embryogenesis.     

"Chemical surgery" as an approach to study morphogenetic events in embryonic mouse limb

Cytosine arabinoside (Ara-C) or retinoic acid (RA) was injected into pregnant mice in doses which induce a high incidence of limb defects. Within 4 hr of the treatment, extensive cell death was observed in the embryonic limb buds. However, the location of necrotic cells and the eventual limb defects were different for the two chemicals. Ara-C killed cells in those regions of the limb which were undergoing active proliferation. RA, on the other hand, had no effect on actively dividing cells but was lethal to cells of chondrogenic lineage at stages when their proliferation rate had fallen 7- to 10-fold below the original rate. In all cases, an excellent correlation between the location of dead cells (as seen 4 hr after drug treatment) and the eventual bony defects (as seen in the term fetuses) was observed. The unique properties of Ara-C and RA have been exploited in determining the relative levels of cytodifferentiation in the embryonic mouse limb buds. It is concluded that in the limbs of early 11th day mouse embryos (comparable to chick stage 19–20), differentiation of future skeletal elements has not yet begun. However, by the 12th day (comparable to chick stage 23), cell populations destined to form most of the future cartilages (except for digits) have already been established.     

Interactions between retinoids and TGF beta s in mouse morphogenesis.

Using immunocytochemical methods we describe the distribution of different TGF beta isoforms and the effects of excess retinoic acid on their expression during early mouse embryogenesis (8 1/2 - 10 1/2 days of development). In normal embryos at 9 days, intracellular TGF beta 1 is expressed most intensely in neuroepithelium and cardiac myocardium whereas extracellular TGF beta 1 is expressed in mesenchymal cells and in the endocardium of the heart. At later stages, intracellular TGF beta 1 becomes very restricted to the myocardium and to a limited number of head mesenchymal cells; extracellular TGF beta 1 continues to be expressed widely in cells of mesenchymal origin, particularly in head and trunk mesenchyme, and also in endocardium. TGF beta 2 is widely expressed at all stages investigated while TGF beta 3 is not expressed strongly in any tissue at the stages examined. Exposure of early neural plate stage embryos to retinoic acid caused reduced expression of TGF beta 1 and TGF beta 2 proteins but had no effect on TGF beta 3. Intracellular TGF beta 1 expression was reduced in all tissues except in the myocardium, while extracellular TGF beta 1 was specifically reduced in neuroepithelium and cranial neural crest cells at early stages. TGF beta 2 was reduced in all embryonic tissues. The down-regulation of intracellular TGF beta 1 was observed up to 48 hours after initial exposure to retinoic acid while some down-regulation of TGF beta 2 was still seen up to 60 hours after initial exposure.(ABSTRACT TRUNCATED AT 250 WORDS)     

The development of hormonal responses of cultured embryonic chick limb mesenchymal cells

Cells obtained from stage 24 chick limb buds were cultured and assayed for their ability to respond to exogenously supplied parathyroid hormone (PTH) as monitored by analysis of cellular cyclic AMP (cAMP). After 3–4 days in culture, these cells developed a striking responsiveness to the hormone; 20 -to 50-fold elevations in cAMP were routinely observed upon exposure to 10^?8, M hormone for 2 min. This response was greatest in cells initially plated at low densities (1 × 10⁶ cells/35-mm dish) and was inversely correlated to the amount of cartilage which developed in such cultures. Cells obtained from limbs of stages 23–26 embryos developed a similar responsiveness to PTH after 3–4 days in culture, but cells obtained from limbs of stage 22 embryos showed no such responsiveness even after 6 days in culture. A response to calcitonin also was noted in cultures of stage 24 limb mesenchymal cells after 4–5 days in culture, but this was of much smaller magnitude than the PTH response. Of 12 other hormones tested, only β agonists elicited any cAMP response in the cultered stage 24 limb mesenchymal cells. Although cells initially plated at a high density and grown for 8 days in culture show no response to PTH, the presence of PTH-responsive cells in such cultures could be demonstrated by sequential digestion with collagenase and replating the extracellular matrix-free cells released by this treatment. Such replated cells then exhibited a responsiveness to PTH. Thus, the responsiveness of cultured limb mesenchymal cells depends on the developmental stage of the starting limb mesenchyme, the phenotypes which develop, and physical factors such as accessibility to exogenously supplied hormone.     

Temporospatial patterns of apoptosis in chick embryos during the morphogenetic period of development

We examined the temporospatial pattern of naturally occurring apoptosis in chick embryos to five days of incubation (H.H. stages 1-25; Hamburger and Hamilton, 1951) using TUNEL labeling. The initial TUNEL-positive structure was the embryonic shield at stage 1. Apoptotic cells became ubiquitously present within embryos by stage 3, which is early in gastrulation. Until stage 6, TUNEL-positive cells were restricted to the headfold region. In embryos of stages 7-8, most cell death was localized at the most anterior neural plate. TUNEL-positive neural plate, notochord and somites appeared at stage 9. Otic and optic regions became TUNEL-positive at stage 11. The aggregation of cells from which the tail bud arises contains apoptotic cells from stage 11 onwards. At stage 16, scattered TUNEL-positive cells appeared in the branchial arches. Three streams of apoptotic neural crest cells in the cranial region became most clearly visible at stage 18. The secondary neural tube from which caudal structures develop contains apoptotic cells at stage 14. Apoptotic cells are present in the branchial arches and lateral body wall for extended periods, stages 16-25 and 25 respectively. At stages 24-25, intense positive regions of cell death were confined to the caudal regions of the arches, to limb and tail buds and to the lateral body wall, the latter in relation to body wall closure. The new findings in this study are discussed along with past studies to provide the temporospatial pattern of cell death during early chick development.     

Evidence for histogenic interactions during in vitro limb chondrogenesis

The requirement for homotypic cell interaction was studied by making chimeric micromass cultures containing various proportions of chick and quail limb mesenchyme. Cultures made from limb mesenchyme from embryos of Hamburger and Hamilton stages 23–24 produce large clumps of cartilage cells, identified by the accumulation of an extracellular matrix which stains with alcian blue at pH 1 and by the ability of cells to take up ³⁵SO₄ rapidly, as demonstrated autoradiographically. Dissociated mesenchyme from stage 19 embryos did not produce cartilage in micromass cultures, but only precartilage cell aggregates. Micromass cultures prepared from mixtures of mesenchyme cells obtained from stage 19 and stages 23–24 embryos contained decreasing numbers of cartilage nodules as the proportion of stage 19-derived mesenchyme increased. At the same time the number of aggregates was not affected. When the ratio of stage 19- to stage 24-derived cells was 3:1 or greater, no nodules were detected. The actual number of cells from each stage was verified by using mixtures of quail and chick cells, which are microscopically distinguishable. Additional evidence suggests that the stage 19-derived mesenchyme inhibits chondrogenesis by passively preventing stage 24-derived cells from interacting. The results presented are consistent with the suggestions that (1) homotypic cell interaction plays a role in limb chondrogenesis and (2) the capacity to interact in the required manner is acquired after the embryos have reached stage 19. These phenomena might be involved in the normal histogenesis of cartilage tissue.     

A quantitative analysis of the effect of all-trans-retinoic acid on the pattern of chick wing development

Small, positively charged beads that slowly release known amounts of all-trans-retinoic acid have been implanted below the apical ectodermal ridge at the anterior margin (opposite somite 16) of wing buds of 3 1/2 day-old chick embryos. The continuous release of retinoic acid is shown to create an anteroposterior concentration gradient of retinoic acid in the limb field that is stable with time, despite the fact that this compound is metabolized by the limb tissue. With beads that release increasing amounts of retinoic acid, the normal 234 digit pattern is progressively altered to a 2234, to a 32234, and then to a 432234 pattern. The tissue concentrations of all-trans-retinoic acid required to change the digit pattern in this way range between 1 and 25 nM. When the same amounts of retinoic acid are released from posteriorly implanted beads (placed below the apical ectodermal ridge opposite somite border 19/20 or somite 20), the normal digit pattern is unaffected. Implantations of beads that release all-trans-retinoic acid are thus identical in their effect to grafts of cells from the limb polarizing region, which cause similar dose-dependent changes in the digit pattern when grafted to the anterior margin of the bud (but not when grafted opposite somites 19 or 20). Because of the low concentrations of retinoic acid required for its biological effect, the graded response observed, and the fact that a concentration gradient is established across the limb field, all-trans-retinoic acid closely mimics the putative morphogen that has been postulated to be emitted by polarizing region cells during normal development.     

Cells from Rana pipiens gastrulae and arrested hybrid gastrulae show differences in adhesion to fibronectin-sepharose beads

Experiments were performed to examine adhesion of Rana pipiens gastrula cells and arrested hybrid gastrula cells to fibronectin-Sepharose beads (FN-beads). Blastula cells from both normal and hybrid embryos show poor adhesion to FN-beads. Beginning at the early gastrula stage, however, normal cells show a progressively increasing tendency to adhere to beads. In two different arrested hybrid embryos, cells from all developmental stages lack the ability to adhere to beads. A third hybrid shows an increase and then a decrease in cell-bead adhesion. A fourth hybrid shows a late increase in cell-bead adhesion in animal-half cells and no increase at all in vegetal-half cells. Blastula-stage cells have the ability to adhere to con A-beads and two kinds of Cytodex beads but will not adhere to FN-beads. Similarly, some cells from arrested hybrid embryos lack the ability to adhere to FN-beads but will adhere to con A-beads and cytodex beads. Observations in the light and scanning electron microscope show that normal cells form lamellipodia on FN-beads and move about actively on them, much like they do in vivo on surfaces coated by fibrils containing fibronectin. For adherent hybrid cells attached to beads, one kind does so by small pseudopodia but does not move on them and another kind forms active lamellipodia at the tips of fusiform cells and moves on beads.     

Embryonic vascular development: immunohistochemical identification of the origin and subsequent morphogenesis of the major vessel primordia in quail embryos

The development of the embryonic vasculature is examined here using a monoclonal antibody, QH-1, capable of labelling the presumptive endothelial cells of Japanese quail embryos. Antibody labelling is first seen within the embryo proper at the 1-somite stage. Scattered labelling of single cells appears ventral to the somites and at the lateral edges of the anterior intestinal portal. The dorsal aorta soon forms a continuous cord at the ventrolateral edge of the somites and continues into the head to fuse with the ventral aorta forming the first aortic arch by the 6-somite stage. The rudiments of the endocardium fuse at the midline above the anterior intestinal portal by the 3-somite stage and the ventral aorta extends craniad. Intersomitic arteries begin to sprout off of the dorsal aorta at the 7-somite stage. The posterior cardinal vein forms from single cells which segregate from somatic mesoderm at the 7-somite stage to form a loose plexus which moves mediad and wraps around the developing Wolffian duct in later stages. These studies suggest two modes of origin of embryonic blood vessels. The dorsal aortae and cardinal veins apparently arise in situ by the local segregation of presumptive endothelial cells from the mesoderm. The intersomitic arteries, vertebral arteries and cephalic vasculature arise by sprouts from these early vessel rudiments. There also seems to be some cell migration in the morphogenesis of endocardium, ventral aorta and aortic arches. The extent of presumptive endothelial migration in these cases, however, needs to be clarified by microsurgical intervention.     

Teratogenic effects of retinoic acid and dimethylsulfoxide on embryonic chick wing and somite

In order to document the stage(s) at which the embryonic chick wing bud is sensitive to vitamin A teratogenesis and the kinds of defects produced by vitamin A insult to the embryonic chick wing, 1-microgram doses of retinoic acid (1 microliter RA in 90% DMSO at a concentration of 1 microgram/microliter) were locally applied to the right wing bud of chick embryos at stages 17-23 (Hamburger and Hamilton: J. Morphol., 88:49-92, '51), and the resulting limb skeleton anatomy was observed at 10 days of incubation. Local application of RA at stages 17-20 resulted in distal wing skeleton defects. There were significantly more wing skeleton defects among embryos treated at these stages with RA solution than among solvent (DMSO)-treated control embryos and than among untreated control embryos. Wings of embryos treated with RA at stages 21-23 were always normal. Scapular and vertebral defects were seen at 10 days of incubation among embryos which had been treated prior to stage 21 with both the RA solution and the solvent control. Statistical analysis and histological data suggest that scapular and vertebral defects were caused by DMSO-induced damage to somites.     

The spatial and temporal distribution of polarizing activity in the flank of the pre-limb-bud stages in the chick embryo

The presence of polarizing activity in the limb buds of developing avian embryos determines the pattern of the anteroposterior axis of the limbs in the adult. Maps of the spatial distribution and the strength of the signal within limb buds of different stages are well documented. Polarizing activity can also be found in Hensen's node in the early embryo. We have mapped the distribution of polarizing activity as it emerges from Hensen's node and spreads into the flank tissue of the embryo. There is a clear change in the local pattern of expression of polarizing activity between stage 8 and 18. Almost no activity is measured for stages 8 and 9. More or less uniform levels of around 10% are spread along the flank lateral to the unsegmented somitic mesoderm from somite position 12 to 22 in stage 10 embryos. Some 6 to 8 h later at stage 12, there is a distinct peak of activity at somite position 18, the middle of the wing field. This peak increases at stages 13 to 15 and its position traverses to the posterior edge of the wing field. Full strength of activity is reached shortly before the onset of limb bud formation at stage 16 to 17. Stages 16 to 18 were investigated for polarizing activity in the wing and the leg field. Low levels of polarizing activity are present in the anterior leg field at stages 16 and 17 but have disappeared by stage 18 and all activity is confined to the posterior part of the leg bud.     

The role of external tensions in differentiation of Xenopus laevis embryonic tissues

Explants extirpated from Xenopus laevis embryos at the early gastrula stage were placed on pieces of hydrophilized latex film which were then either stretched or remained intact. In explants cultivated on the intact films most cells emigrated out of the explants and remained undifferentiated, whereas the explants on the films stretched for 10 min or more developed a normal set of rudiments. In the explants of suprablastoporal zone stretched perpendicularly to the cranio-caudal direction, the axial organs were oriented in the direction of stretching. In the stretched explants, unlike the intact ones, a system of microfilament-associated intercellular contacts was formed within a few minutes.     

New method to deliver exogenous material into developing planarian embryos

The ability to report or modify the embryological processes in living embryos is pivotal for developmental biology research. Planarian embryology has experienced renewed interest as the genetic pathways that drive adult regeneration were found to be involved in the development of embryos. The major drawback to the study of planarian embryology is the absence of methods that give access to the embryos and enable their manipulation. Herein, we report on a novel method for delivering external material into developing embryos using nanosecond laser pulses. When focused on the eggshell surface under optimal parameters, laser pulses ablate the protective case and open a pathway throughout which foreign material can be delivered. In this study, we used egg capsules from Schmidtea polychroa (Schmidt, 1861) to microinject 1 microm fluorescein isothiocyanate fluorescent beads into the live embryos. We obtained viability values ranging from 15% in early egg capsules to 100% in late developmental stages. Moreover, we measured the delivery effectiveness as the number of hatchlings containing fluorescent beads per microinjected egg capsule, reaching 100% in early stages and almost 40% in late stages. This is the first time that planarian embryos have been modified without compromising normal development. We consider that this technique will be of extreme value to future work on planarian developmental biology and regeneration, enabling the application of modern functional tools to the study of this Lophotrochozoan.     

Effects of tunicamycin upon glycoprotein synthesis and development of early mouse embryos

Tunicamycin, an antimetabolite which inhibits the N-glycosylation of proteins, does not block the initial cleavages of mouse embryos, even at relatively high concentrations. However, it can interfere with compaction and blastocyst formation. Although tunicamycin treatment from the two-cell or eight-cell stage can cause developmental arrest prior to hatching from the zona pellucida, much higher (sublethal) concentrations of the antimetabolite added at the morula or blastocyst stage do not specifically affect hatching of blastocysts, their attachment to the substratum, or outgrowth of trophoblast cells. The consequence of continuous exposure of embryos to moderate amounts (0.05 to 0.1 μg/ml) of tunicamycin through peri-implantation stages is death of trophoblast cells with little effect upon the cells of the inner cell mass (ICM). The latter give rise to apparently normal early endoderm cells in the presence of the antimetabolite. The incorporation of leucine, mannose, and fucose into acid-insoluble material by ICM cells is only minimally inhibited by tunicamycin. On the other hand, the antimetabolite causes a severe inhibition of incorporation of not only mannose, but also leucine, into acid-insoluble material in trophoblast cells. Thus, trophoblast cells resemble transformed cells by their extreme sensitivity to tunicamycin.