INDUCTION OF THE FROG HATCHING GLAND CELL FROM EXPLANTED PRESUMPTIVE ECTODERMAL TISSUE BY LICL

When cells of the superficial layer explanted from the presumptive ectoderm of a Rana japonica early gastrula embryo at stage 10 were cultured in standard salt solution for 4–7 days, they differentiated into cement gland cells (CGCs), cilia cells (CCs) and common epidermal cells (CECs). When, however, these explants were treated with LiCl and transferred to Barth's solution, hatching gland cells (HGCs) and pigment cells were induced.
The optimum condition for inducing differentiation of HGC was treatment with 70 mM LiCl for 6–8 hr at 18°C. The best ability to react to the HGC-inducing stimuli resided in the superficial layer of the dorsal presumptive epidermis of the embryo at stage 10. Upon repeated stimulation, explants from stage 8 embryos underwent differentiation into nerve and pigment cells, whereas those from stage 11 embryos differentiated into CCs and CECs. Under optimum conditions, the total volume of HGCs induced amounted to about 70% of the explanted tissue. The culture media from LiCl-induced HGCs showed an apparent jelly-digesting activity, strongly indicating that the cells were functionally identical with those differentiated in situ .     

Experimental analysis of the in vivo chondrogenic potential of the interdigital mesenchyme of the chick leg bud subjected to local ectodermal removal

Current in vitro investigations suggest that ectoderm plays a major role in limb morphogenesis by producing a diffusible factor which inhibits the chondrogenesis of the underlying mesenchyme. In the present work we report evidence supporting such an ectodermal role in vivo. Surgical removal of the marginal ectoderm from the third interdigit of chick leg buds at stages 27 to 30 induces the formation of PNA-positive prechondrogenic mesenchymal condensations 15 hr after the operation. The incidence of prechondrogenic condensations achieved 47, 95.2, and 92.8 of the experimental embryos of stages 27, 28, and 29, respectively. This high rate of prechondrogenic aggregate formation contrasted with a lower incidence of ectopic cartilage formation detectable by Alcian blue staining 40 hr after the operation. The sequential analysis of the experimental interdigits by means of peanut lectin labeling suggests that a number of prechondrogenic condensations undergo disaggregation 20 and 30 hr after the operation failing to form fully differentiated cartilages. When ectoderm removal was accompanied by the elimination of a variable amount of interdigital mesenchyme the incidence of prechondrogenic aggregates showed little differences but the formation of fully differentiated cartilages was reduced at a rate proportional to the amount of interdigital mesenchyme removed. From this study it can be concluded that the ectoderm in vivo appears to inhibit the process of aggregation of the mesenchymal cells to form prechondrogenic condensations. Furthermore our results suggest that as observed in vitro (C. P. Cotrill, C. Archer, and L. Wolpert, 1987, Dev. Biol. 122, 503-515) the transformation of prechondrogenic aggregates into fully differentiated cartilage requires the involvement of a critical amount of mesenchymal cells.     

Induction of the Eye Lens

In general terms embryonic induction involves the association of embryonic tissues and leads to tissue differentiation. It is one of the known essential processes leading to the normal development of embryos. However, despite its importance, very little is known about the mechanisms of inductive interactions. For example, what is the nature of communication between tissues, how does this communication effect the synthetic activity of the cells, and once a new pattern of synthesis has been established how is the sequence of events leading to tissue differentiation co-ordinated? The answers to these questions will come only from the intensive study of inductive interactions and tissue differentiation at all levels from the morphological to the molecular.
One of the best known examples of induction, at least superficially, is the differentiation of lens from head ectoderm after its interaction with optic vesicle. The popularity of this tissue with embryologists may be attributed to its accessibility of manipulation because of its position on the outside of the embryo. In addition, its distinct morphology and specific biochemical composition make it relatively easy to determine whether the lens differentiates after experimental treatment. About the turn of this century lens differentiation was thought to depend on the specific interaction of just two embryonic tissues, head ectoderm and neuro-ectoderm (optic vesicle). However, experimental analysis since then has revealed that this oversimplified view of lens induction is incorrect. In fact there is evidence that a large number of other tissues besides embryonic head ectoderm can differentiate into lens and that other conditions besides the presence of optic vesicle can induce lens differentiation. The purpose of this work is to review the evidence on lens induction and based on this, to determine what we know about the mechanism(s) controlling this process.     

Complete regulation of development throughout metamorphosis of sea urchin embryos devoid of macromeres

The developmental potential of the animal cap (consisting of eight mesomeres) recombined with micromeres or of micromere progeny was examined in sea urchin embryos. The embryos derived from the animal cap recombined with a quartet of micromeres or their descendants developed into four-armed plutei. After feeding, the larvae developed into eight-armed plutei. The left-right polarity of the larvae, recognized by the location of the echinus rudiment, was essentially normal, regardless of the orientation of animal-vegetal polarity in micromeres combining with the animal cap. The larvae had sufficient potential to metamorphose into complete juvenile sea urchins with five-fold radial symmetry. Cell lineage tracing experiments showed that: (i) macromere progeny were not required for formation of the typical pattern of primary mesenchyme cells derived exclusively from large micromeres; (ii) the progeny of large micromeres did not contribute to cells in the endodermal gut with three compartments of normal function; (iii) the presumptive ectoderm had the potential to differentiate into endodermal gut and mesodermal secondary mesenchyme cells, from which pigment cells likely differentiated; and (iv) behavior of the progeny of small micromeres was the same as that in normal embryos through the gastrula stage. These results indicate that the mesomeres respecify their fate under the inductive influence of micromeres so perfectly that complete juvenile sea urchins are produced.     

Coelomic pouch formation in reconstructing embryos of the starfish Asterina pectinifera

The morphogenetic processes of coelomic pouch (CP) formation in starfish embryos that were experimentally dissociated and induced to undergo reconstruction were studied. An analysis of these embryos randomly chosen from several cultures showed that CP always form on either side of the esophagus, even though the CP formation can differ in timing of initiation and duration, and can vary in number and size from embryo to embryo. Successive observations of CP formation in living embryos revealed two distinct sequences of CP development that were accompanied by different appearances of the blastocoele. These processes were named 'enterocoelic-like' and 'schizocoelic-like' CP formation. The former resembled normal development and occurred in embryos with a transparent blastocoele. The latter was characterized by the aggregation and epithelialization of mesenchyme-like cells on either side of the esophagus and was observed in embryos possessing a cloudy blastocoele. In a few embryos, both types of CP formation were seen in the same individual ('mosaic type' CP formation). Thick sections of embryos possessing a cloudy blastocoele revealed that aggregates of mesenchyme-like cells undergoing CP formation directly contact the developing esophagus. Together, these data demonstrate flexibility in the morphogenetic processes that regulate CP formation, and suggest that positional cues in the esophagus regulate the placement of CP.     

Production of chimeric hamsters by aggregation of eight-cell embryos.

Chimeric animals were produced by aggregation of 8-cell-stage embryos from two strains of hamsters (LVG and Bio 1.5). Two series of experiments were performed. In the first series, embryo pairs in contact with each other were classified as aggregates even if 2 distinct embryos could still be distinguished. Of 88 aggregates transferred, 2 chimeras were obtained. Pregnancy rate was 25%, and embryo survival was 35%. In the second set of experiments, only embryo pairs that had coalesced to form a single giant blastocyst were classified as aggregates. Of 56 aggregates transferred, 6 chimeras were obtained. Pregnancy rate was 83%, and embryo survival was 30%. Of the 8 chimeras, 6 were phenotypic males, and 2 were phenotypic females. Both females were germ line chimeras. Of the 6 males, 4 reproduced normally, 1 had abnormal external genitalia but normal spermatogenesis, and 1 was sterile and had atrophic testes. Each of the fertile males transmitted only a single component, either the LVG or the Bio 1.5. Examination of the testes from the sterile chimera revealed that in excess of 80% of the seminiferous cords were devoid of germ cells. These results demonstrate that hamster chimeras can be obtained by aggregation of 8-cell-stage embryos.     

Coordinate accumulation of five transcripts in the primary mesenchyme during skeletogenesis in the sea urchin embryo

The sea urchin larval skeleton is produced by the primary mesenchyme (PM), a group of 32 cells descended from the four micromeres of the 16-cell embryo. The development of this lineage proceeds normally in isolated cultures of micromeres. A complementary DNA (cDNA) library was generated from cytoplasmic polyadenylated RNA isolated from differentiated micromere cultures of Strongylocentrotus purpuratus. Five clones were selected on the basis of their enrichment in differentiated PM cell RNA as compared to the polyribosomal RNAs of other embryonic cell types and other developmental stages. Each cloned cDNA hybridized to a distinct RNA that was abundant in the polyribosomes of differentiated PM cells, but absent from larval ectoderm and from 16-cell embryos. These RNAs were encoded by single or low copy genes. In situ hybridization analysis of the most abundant of these RNAs (SpLM 18) demonstrated that it was specifically limited to the skeletogenic PM of intact embryos. During the development of the PM, all five RNAs exhibited the same schedule of accumulation, appearing de novo, or increasing abruptly just before PM ingression, and remaining at relatively high levels thereafter. This pattern of RNA accumulation closely paralleled the pattern of synthesis of PM-specific proteins in general (Harkey and Whiteley, 1983) and of the SpLM 18-encoded protein specifically (Leaf et al., 1987). These results indicate that at least five distinct genes in the sea urchin, each of which encodes a PM-enriched or PM-specific mRNA, are expressed with tight coordination during development of the larval skeleton. They also demonstrate that expression of these genes in the PM is regulated primarily at the level of RNA abundance rather than RNA utilization.     

Changes in states of commitment of single animal pole blastomeres of Xenopus laevis

The experiments described in this paper were designed to compare the normal fates of animal pole blastomeres of Xenopus laevis with their state of commitment. Single animal pole blastomeres were labeled with a lineage marker and transplanted into the blastocoels of host embryos of different stages. The distribution of labeled daughter cells in the tadpole reflects the state of commitment of the parent cell at the time of transplantation. It is known that cells from the animal pole of the early blastula normally contribute predominantly to ectoderm with a small, but significant, contribution to the mesoderm. We show that on transplantation to the blastocoels of late blastula host embryos these blastomeres are pluripotent, contributing to all three germ layers. At later stages the normal fate of these cells becomes restricted solely to ectoderm and concomitantly the proportion of pluripotent cells is reduced, although the results depend upon the stage of the host embryo. Blastomeres from late blastula donors transplanted to mid gastrulae contribute solely to ectoderm in 34% of cases; however, in earlier hosts, when the vegetal hemisphere cells have "mesoderm inducing" or "vegetalizing" activity, late blastula animal pole blastomeres contribute to mesoderm and endoderm rather than ectoderm. Thus during the blastula stage animal pole cells pass from pluripotency to a labile state of commitment to ectoderm.     

Developmental potential of fused Caenorhabditis elegans oocytes: generation of giant and twin embryos

With their first cleavage blastomeres in Caenorhabditis elegans are fixed to very different developmental programs going along with differential segregation of maternal gene products. To investigate whether indications for a prelocalization of cytoplasmic components can already be found in unfertilized egg cells, we fused mature C. elegans oocytes with the help of a laser microbeam. Fertilization of two fused oocytes resulting in triploid zygotes showed an essentially normal early cleavage pattern with the establishment of five somatic cell lineages and a germline and also a normal spatial arrangement of blastomeres. A considerable fraction of such embryos hatched and developed into fertile giant nematodes. The numbers of cell nuclei in freshly hatched and adult giant animals were found to be essentially the same as in untreated controls. When three fused oocytes were fertilized, two alternative patterns of early embryogenesis were observed. Half of the embryos followed the normal cleavage mode. The other half, however, developed in a twin-like fashion with all cells present in two copies, apparently due to fertilization by two sperm. In such embryos, two areas of gastrulation were established, resulting in the generation of two separate gut primordia. In summary, our results suggest that (1) in contrast to the uncleaved zygote in the mature oocyte of C. elegans no cytoplasmic regionalization exists, (2) the invariable cell numbers typical for the C. elegans embryo are not controlled via cell size, and (3) the entry of a second sperm can induce a cascade of events in the egg leading to the formation of two complete embryo anlagen.     

Specification of ectoderm restricts the size of the animal plate and patterns neurogenesis in sea urchin embryos

The animal plate of the sea urchin embryo becomes the apical organ, a sensory structure of the larva. In the absence of vegetal signaling, an expanded and unpatterned apical organ forms. To investigate the signaling that restricts the size of the animal plate and patterns neurogenesis, we have expressed molecules that regulate specification of ectoderm in embryos and chimeras. Enhancing oral ectoderm suppresses serotonergic neuron differentiation, whereas enhancing aboral or ciliary band ectoderm increases differentiation of serotonergic neurons. In embryos in which vegetal signaling is blocked, Nodal expression does not reduce the size of the thickened animal plate; however, almost no neurons form. Expression of BMP in the absence of vegetal signaling also does not restrict the size of the animal plate, but abundant serotonergic neurons form. In chimeras in which vegetal signaling is blocked in the entire embryo, and one half of the embryo expresses Nodal, serotonergic neuron formation is suppressed in both halves. In similar chimeras in which vegetal signaling is blocked and one half of the embryo expresses Goosecoid (Gsc), serotonergic neurons form only in the half of the embryo not expressing Gsc. We propose that neurogenesis is specified by a maternal program that is restricted to the animal pole by signaling that is dependent on nuclearization of beta-catenin and specifies ciliary band ectoderm. Subsequently, neurogenesis in the animal plate is patterned by suppression of serotonergic neuron formation by Nodal. Like other metazoans, echinoderms appear to have a phase of neural development during which the specification of ectoderm restricts and patterns neurogenesis.     

Identification of a biological activity that supports maintenance and proliferation of pluripotent cells from the primitive ectoderm of the mouse

Pluripotent cell development in the mammalian embryo results in the sequential formation of several developmentally distinct populations, inner cell mass, primitive ectoderm, and the primordial germ lineage. Factors within medium conditioned by HepG2 cells (MEDII) have been implicated in the formation and maintenance of primitive ectoderm from inner cell mass cells both in vitro and in vivo. Here we demonstrate that MEDII, but not LIF, is able to support the maintenance and proliferation in culture of pluripotent cells derived from primitive ectoderm formed in vitro or during embryonic development. This distinguishes primitive ectoderm and inner cell mass (ICM) on the basis of cytokine responsiveness and validates the biological activity proposed for factors within MEDII in primitive ectoderm establishment and maintenance. Further, it potentially provides an alternative technology for the isolation of pluripotent cells from the mammalian embryo.     

mRNA localization studies suggest that murine FGF-5 plays a role in gastrulation.

During gastrulation in the mouse, the pluripotent embryonic ectoderm cells form the three primary germ layers, ectoderm, mesoderm and endoderm. Little is known about the mechanisms responsible for these processes, but evidence from previous studies in amphibians, as well as expression studies in mammals, suggest that signalling molecules of the Fibroblast Growth Factor (FGF) family may play a role in gastrulation. To determine whether this might be the case for FGF-5 in the mouse embryo, we carried out RNA in situ hybridization studies to determine when and where in the early postimplantation embryo the Fgf-5 gene is expressed. We chose to study this particular member of the FGF gene family because we had previously observed that its pattern of expression in cultures of teratocarcinoma cell aggregates is consistent with the proposal that Fgf-5 plays a role in gastrulation in vivo. The results reported here show that Fgf-5 expression increases dramatically in the pluripotent embryonic ectoderm just prior to gastrulation, is restricted to the cells forming the three primary germ layers during gastrulation, and is not detectable in any cells in the embryo once formation of the primary germ layers is virtually complete. Based on this provocative expression pattern and in light of what is known about the functions in vitro of other members of the FGF family, we hypothesize that in the mouse embryo Fgf-5 functions in an autocrine manner to stimulate the mobility of the cells that contribute to the embryonic germ layers or to render them competent to respond to other inductive or positional signals.