Comparative study of sequential expression of the organizer-related genes in normal Cynops pyrrhogaster embryos and mesodermalized ectoderm

An artificially mesodermalized ectoderm (mE) of early Cynops pyrrhogaster gastrula acquires the organizer property; the mE is able to induce the secondary axis. The expression of organizer-related genes was investigated during the mesodermalizing process of the mE. The expression of C. pyrrhogaster organizer-related genes, such as bra, gsc, lim-1, chd and noggin, were analyzed. Cynops pyrrhogaster shh expression was also investigated. The organizer-related genes were activated by 12 h after the mesoderm-inducing stimulus. It was noted that there was a temporal gap in the expression of each gene. The expression of bra and gsc seemed to be more quickly activated during the mesodermalizing process. While expression of lim-1 and noggin was activated later than that of bra and gsc, lim-1 expression was earlier than chd and noggin expression. Shh expression was activated later than lim-1/noggin. The present study suggests the possibility that the bra/gsc, lim-1, chd, noggin and shh genes are expressed one by one in that order during the mesodermalizing of the presumptive ectoderm. It also indicates that the sequence is not always consistent with that of the whole embryo during normal embryogenesis. The meaning of the discrepancy will be discussed in connection with the cascade of certain genes expressed during the mesodermalizing process.     

Movement of an Epithelial Layer Isolated from Early Embryos of the Newt, Cynops pyrrhogaster I. Development of Folding Movement of the Blastocoelic Wall Isolated from Embryos before and during Gastrulation

The blastocoelic wall (BW) was isolated from embryos of the newt, Cynops pyrrhogaster , before and during gastrulation. The mechanism responsible for the folding movement of the isolated BW toward the basal side was investigated. The BW isolated from the early gastrula was induced to fold toward the basal side by treatment with serum. The folding movement of the isolated BW took place from the late blastula to early gastrula stage. Electron microscopy, rhodamine-phalloidin staining and experiments with inhibitors show that the development of the folding movement was correlated with the appearance of a submembranous microfilaments layer (SML) which was formed beneath the cell membrane on the basal side of the BW and suggest that the contraction of actin filaments in the SML is involved in the folding movement of the isolated BW toward the basal side.     

Protein Synthesis during Neural and Epidermal Differentiation in Cynops Embryo

Two-dimensional gel electrophoresis was used to analyze protein synthesis in relation to neural and epidermal differentiation in Cynops pyrrhogaster embryo. Various regions of embryos at different developmental stages, from late morula to early neurula stages, were excised, radiolabelled with ³⁵S-methionine, and the pattern of protein synthesis were compared. The following four types of protein spots were observed: (1) six proteins synthesized characteristically in the epidermal region of the embryo after gastrulation, (2) two proteins synthesized in both epidermal and endodermal regions, but not in other regions, after gastrulation, (3) a protein first detected at early blastula stage, of which expression was nearly constant in presumptive epidermis region but declined in the other regions, (4) the candidate for neural plate specific protein synthesized at a very high level in ectoderm explants treated with concanavalin A, a substance which evokes neural induction.     

Ultrastructural Study of Changes in Cell Morphology and Extracellular Matrix in Prospective Endodermal Cells of Newt Embryos (Cynops pyrrhogaster) before and during Gastrulation

The cell morphology, cell-to-cell contact behavior and extracellular matrix (ECM) of inner cells (prospective endodermal cells) of newt ( Cynops pyrrhogaster ) embryos were examined from the morula to gastrula stage by light and electron microscopy. The inner cells showed increased cell-to-cell contact from the early blastula to early gastrula stage. The cells formed blebs (5–15 μm in diameter) during the blastula stage, and started to form filopodia and lamellipodia before gastrulation. Alcian blue and lanthanum nitrate treatment revealed ECM components on the cell surface in the early blastula stage and these components increased in amount from the late blastula to early gastrula stage. It is suggested that the increase in ECM components on the cell surface may have some relation with changes in cell-to-cell contact and formation of processes on the cell surface. Besides the cell surface ECM components, glycogen-like granules were observed in intercellular spaces. From the distribution of granules in gastrulae, it is suggested that these may be important in maintaining intercellular spaces for migration of invaginating cells.     

Epibolic extension of the presumptive ectodermal layer of embryos of the newt Cynops pyrrhogaster before and during gastrulation.

Epibolic extension of the presumptive ectodermal layer (PEL) was investigated in embryos of the newt Cynops pyrrhogaster before and during gastrulation. The PEL was composed of only one layer of columnar cells at all stages examined. The cells of the PEL became elongated from the blastula to the early gastrula stage. They were most elongated at the early gastrula stage and then shortened during gastrulation. Present observations suggest that changes in cell shape of the PEL play an important role in the control of the epibolic extension of the newt embryos. The morphology and movement of the isolated cells from the PEL were examined in an attempt to elucidate the role of cell movement in epibolic extension of the PEL. Blebbing and vermiform cells which showed active cell movement appeared at the early blastula stage. The blebbing cells, which formed large hyaline blebs that moved around the circumference of each cell, appeared in large numbers at the early blastula stage. The frequency of the blebbing cells decreased from the early blastula to the early gastrula stage and increased again during gastrulation. The vermiform cells, which had an elongated cell body and moved in a worm-like manner, increased in frequency from the early blastula to the early gastrula stage. The relative number of such vermiform cells was maximal at the early gastrula stage and decreased abruptly during gastrulation. These results suggest that the elongation of the cells of the PEL is controlled by the active cell movement which resembles that of a worm.     

STAGING OF NEWT BLASTULA EMBRYOS AND FIRST APPEARANCE OF PRIMARY MESODERMAL COMPETENCE

Using the swimbladder of the crusian carp ( Carrasius auratus ) as an inductor, the first appearance of mesodermal competence in the presumptive ectoderm of the newt ( Triturus pyrrhogaster ) blastula was investigated. The time course of embryonic development before the gastrula stage was determined by counting the number of surface cells on a 0.25 mm line at the animal pole. Pregastrula embryos with 2–3, 4–5, 6–7 and 7–8 cells roughly correspond to those at 14, 14–12, 8–6 and 4–0 hr before the beginning of gastrulation. Using presumptive ectoderm of the early gastrula stage, 15 min was found to be the minimum time of contact necessary for the realization of induction. The reactivity of the presumptive ectoderm from pregastrula embryos was tested by 30 min contact. Presumptive ectoderm up to the 4–5 cell stage did not react to the inductor. It may become competent within the next 4–8 hr, since the ectoderm from embryos in the 6–7 cell stage was reactive.     

Timing and mechanisms of mesodermal and neural determination revealed by secondary embryo formation in Cynops and Xenopus

We examined the timing and mechanisms of mesodermal and neural determination in Cynops , using the secondary embryo induced by transplantation of the prechordal endomesoderm. Two unique approaches were used: one was to observe gastrulation movements induced by the graft, and the other to measure the volumes of formed tissues. Transplanted graft pulled host animal cap cells inside to form a new notochord and other mesoderm of the secondary embryo, showing determination of mesoderm during gastrulation. The graft attained a certain width beneath the host ectoderm and moved near to the animal pole of the host by late gastrula, and a neural plate, which had a similar width to the graft, was formed covering the graft. The volume of neural tissues of the secondary embryo at tail-bud stages was about half that of the normal embryo, while the volumes of notochord were comparable in each case. These data suggest that prechordal endomesoderm, rather than notochord, determines the limit of neural plate in the overlying ectoderm. Similar dorsal grafts were transplanted at early gastrula in Xenopus but did not form well developed secondary embryos, demonstrating that the timing and mechanisms of mesoderm formation in Xenopus are different from those in Cynops .     

Establishment of the organizing activity of the lower endodermal half of the dorsal marginal zone is a primary and necessary event for dorsal axis formation in Cynops pyrrhogaster

The formation of the head and trunk-tail organizers in the dorsal marginal zone (DMZ) of an amphibian embryo is thought to require spatial and temporal interactions between the Nieuwkoop center and the DMZ. Recent studies of the Xenopus embryo suggested that intra-DMZ interaction is also needed to establish the regional specificity of the DMZ. However, it is not yet clarified when and how the final pattern of the head and trunk-tail organizers is established. To analyze the intra-DMZ interactions, we injected suramin into the blastocoel of the mid-blastula of the urodele, Cynops pyrrhogaster, at 6 h prior to the onset of gastrulation. The pigmented blastopore formed normally, but the convergent extension and involution of the DMZ and dorsal axis formation of the embryo were completely inhibited. Expression of gsc, chd and Lim-1 were not maintained, but noggin was unaffected in the suramin-treated embryos. Dorsal axis formation and the expression of these genes of the suramin-treated embryos were rescued by replacing the lower endodermal half of the DMZ (LDMZ) with normal LDMZ. The present results of embryological and molecular examinations indicate that organizing activity of the early Cynops gastrula DMZ is restricted to the LDMZ, and that the organizing activity of the LDMZ is established during the late blastula stages. The results also indicate that LDMZ triggers the sequential interaction within the DMZ that establishes the final pattern of the regional specificity of the DMZ, and that the formation of the LDMZ is a primary and necessary event for dorsal axis formation.     

Studies on the Formation and State of Determination of the Trunk Organizer in the Newt, Cynops Pyrrhogaster III. Tangential Induction in the Dorsal Marginal Zone

Analysis of the course of differentiation of combinants between the presumptive prechordal plate (PcP) and presumptive ectoderm (PE) by time-lapse filming showed that the PcP of early gastrulae has the capacity to induce mesoderm (notochord, muscle cells and migrating cells) in the PE. The mesoderm-inducing capacity of the PcP decreases sharply during gastrulation. Following invagination in the mid-gastrula, the PcP completely loses its mesoderm-inducing capacity. This change also occurred when the PcP of the earliest gastrula was aged in vitro for 18 hr. This shows that the mesoderm-inducing capacity of the PcP decreases autonomously with aging.
PE transplanted into the presumptive trunk organizer region of the dorsal marginal zone of the earlist gastrula, became mesodermized within 12 hr. It is clear that this mesodermization of the transplanted PE is due to "tangential induction" from the PcP. The stepwise formation of the trunk organizer in Cynops pyrrhogaster is discussed in consideration of these results.     

NEURAL COMPETENCE AND CELL LINEAGE OF GASTRULA ECTODERM OF NEWT EMBRYO

The change in the capacity to form neural structures was quantitatively analyzed in both intact and isolated ectoderms of Cynops pyrrhogaster gastrula. The frequency of explants with induced neural structures abruptly decreases between stage 12c and stage 13b in intact ectoderm, and between 12 hr and 18 hr preculture in isolated ectoderm. The quantitative analysis also made clear that the size of the cell population of induced neural structures was gradually reduced with the aging of the ectoderm. The authors simultaneously examined the cell proliferation of early gastrula ectoderm and confirmed that all ectodermal cells divided at least once within 18 hr at 23°C, after which the neural competence of the ectoderm completely disappeared.
The relationships between neural competence and cell lineage (cell generation) of the ectoderm are discussed in the light of these findings.     

Development of Ca²(+) signaling mechanisms and cell motility in presumptive ectodermal cells during amphibian gastrulation

This study investigated the development of Ca2(+) signaling mechanisms and their role in initiating morphogenetic cell movement in the presumptive ectoderm of Japanese newt (Cynops pyrrhogaster) during gastrulation. Histochemical staining using fluorescently labeled ryanodine and dihydropyridine probes revealed that dihydropyridine receptor (L-type Ca2(+) channels) appeared in stage 12b embryos, while ryanodine receptors were expressed in both stage 11 and 12b embryos. Transmission electron microscopy of stage 12b embryos showed abundant peripheral couplings, which are couplings of the endoplasmic reticulum and cell membrane with an approximate 12 nm gap. Caffeine increased the intracellular free Ca2(+) concentration ([Ca2(+)](i)) in presumptive ectodermal cells isolated from both stage 11 and 12b embryos, while (±)-Bay K 8644 ((±)-BayK) increased [Ca2(+)](i) in cells isolated from stage 12b embryos, but not in cells isolated from stage 11 embryos. Dantrolene and nifedipine completely inhibited increases in [Ca2(+)](i) after treatment with caffeine and (±)-BayK, respectively. Caffeine activated the motility of cells isolated from both stage 11 and 12b embryos, but (±)-BayK only activated the motility of cells isolated from stage 12b embryos. These findings suggested that formation of the Ca2(+) -induced Ca2(+) release system in presumptive ectodermal cells during gastrulation plays an important role in the initiation and execution of epibolic extension.     

Regional specification of the head and trunk-tail organizers of a urodele (Cynops pyrrhogaster) embryo is patterned during gastrulation

The dorsal marginal zone (DMZ) of an amphibian early gastrula is thought to consist of at least two distinct domains: the future head and trunk-tail organizers. We studied the mechanism by which the organizing activities of the lower half of the DMZ (LDMZ) of the urodelean (Cynops pyrrhogaster) embryo are changed. The uninvoluted LDMZ induces the notochord and then organizes the trunk-tail structures, whereas after cultivation in vitro or suramin treatment, the same LDMZ loses the notochord-inducing ability and organizes the head structures. A cell-lineage experiment indicated that the change in the organizing activity of the LDMZ was reflected in the transformation of the inductive ability: from notochord-inducing to neural-inducing activity. Using RT-PCR, we showed that the LDMZ expressed gsc, lim-1, chordin, and noggin, but not the mesoderm marker bra. In the sandwich assay, the LDMZ induced bra expression in the animal cap ectoderm, but the inductive activity was inhibited by cultivation or suramin treatment. The present study indicates that the change in the organizing activity of the LDMZ from trunk-tail to head is coupled with the loss of notochord-inducing activity. Based on these results, we suggest that this change is essential for the specification of the head and trunk-tail organizers during gastrulation.     

Gravitational effects on apoptosis of presumptive ectodermal cells of amphibian embryo

The effects of simulated microgravity (clinostat rotation at 6 rpm) on the presumptive ectodermal cells of amphibian embryos were examined. When morulae of Cynops pyrrhogaster developed under the influence of simulated microgravity, the thickness of the presumptive ectoderm was greater significantly. Embryonic cells isolated from the presumptive ectoderm of morulae were cultured for one day under the influence of simulated microgravity. The number of cells was greater after such clinostat rotation than in the control culture. TUNEL staining and electron microscopy revealed apoptotic cells both in embryos and among cultured cells, but the number of apoptotic cells was smaller in clinostat-treated embryos and cultured cells than in their controls. These results suggest that simulated microgravity suppresses apoptosis in the amphibian embryo, and as a result, affects the thickness of the presumptive ectoderm.     

CHANGES IN THE ELECTROPHORETIC MOBILITY OF PRESUMPTIVE ECTODERM CELLS TREATED WITH MESODERMAL INDUCING SUBSTANCES

Using gastrula ectoderm of Cynops pyrrhogaster , the electrophoretic mobility (EPM) of cells was measured. Before EPM measurement, the cells were treated with either LiCl or swimbladder tissue, which are known to possess endo- and mesodermal inducing activity. The EPM of the treated cells increased after 48 hr. A significant difference was observed between the control and experimental series. In addition to the measurements of EPM, histological sections of the explants were examined. Before obvious tissue differentiation occurred in the explants, definitive changes in the EPM values were recorded at 48 and 72 hr after treatment.     

Studies on the development of melanophores in in vitro cultured amphibian neural plates

Various parts of neural plates of Japanese newt (Cynops pyrrhogaster) neurula embryos were cultured alone in drops of culture media (Niu-Twitty's balanced salt solution or modified Leibovitz L-15 medium) with or without fetal calf serum (FCS). Although none of the parts gave rise to melanophores in a medium without FCS, some produced melanophores in a medium with FCS. The localization of melanophore-producing areas in the neural plates corresponded to that of Tada's (1944) findings. The assumption that FCS affects survival and development of melanophores is excluded, because neural fold cells do not require FCS to develop into melanophores. Therefore, there may be in FCS some factor which acts on the specialization of neural plate cells into melanophores. The results of this experiment suggest that this factor may be heat labile. The findings also indicate that FCS does not induce melanophores in gastrula ectoderm, but only affects neurula neural plate cells so as to give rise to melanophores.     

Expression of Na+, K+-ATPase α-Subunit in Animalized and Vegetalized Embryos of the Sea Urchin, Hemicentrotus pulcherrimus.

A marked increase in the Na⁺, K⁺-ATPase activity of sea urchin embryos occurred following an elevation of its mRNA level, revealed by Northern blotting analysis, in developmental period between the swimming blastula and the late gastrula stage. cDNA clone of Na⁺, K⁺-ATPase α-subunit, obtained from γgt10 cDNA library of sea urchin gastrulae, was digested with EcoRl ad Hindlll. The obtained 268 bp cDNA fragment, hybridized to a 4.6 Kb RNA, was used as probe for Northern blotting analysis. The level of Na⁺, K⁺-ATPase mRNA was higher in embryo-wall cell fraction isolated from late gastrulae (ectoderm cells) than the level in the bag fraction, containing mesenchyme cells (mesoderm cells) and archenteron (endoderm cells). The activity of Na⁺, K⁺-ATPase and the level of its mRNA were higher in animalized embryos obtained by pulse treatment with A23187 for 3 hr, starting at the 8–16 cell stage and were considerably lower in vegetalized embryos induced by 3 hr treatment with Li⁺ than that in normal embryos at the post gastrula corresponidng stage. Augmentation of Na⁺, K⁺-ATPase gene expression can be regarded as a marker for ectoderm cell differentiation at the post gastrula stage, which results from determination of cell fate in prehatching period.