Teruo Kaneda

Studies on the formation and state of determination of the trunk organizer in the newt,Cynops pyrrhogaster

SummaryThe exact localization of the presumptive trunk organizer was determined by means of vital staining at the initiation of gastrulation (0 h embryo) and subsequently in 6, 9, 12 and 24 h embryos.The progressive changes in the self-differentiation and inductive capacity of the trunk organizer were studied in isolation cultures (sitting drop) and in sandwich cultures with competent gastrula ectoderm. In the 0 and 6 h embryo cultures the excised trunk organizer predominantly formed atypical ectoderm. A dramatic change in differentiation and inductive capacity occurred in the 9 h embryo. The positive cases — 83% of the isolation and 50% of the sandwich cultures — mainly formed notochord and somites, accompanied by spinal cord and hindbrain in the sandwich cultures. Although no further change in self-differentiation occurred from that time onwards, a gradual increase in inductive capacity was recognized.

Germ Layer Interactions in Pattern Formation of Amphibian Mesoderm during Primary Embryonic Induction

Mesodermal differentiation of dorsal marginal zone (DMZ) before and after invagination was analyzed by a series of combination experiments with different kinds of ectoderm.

Studies on the formation and state of determination of the trunk organizer in the newt Cynops pyrrhogaster. II. Inductive effect from the underlying cranial archenteron roof

Mesoderm formation in the presumptive trunk organizer was analyzed in gastrulae of Cynops pyrrhogaster. The presumptive trunk organizer showed little or no mesodermal differentiation in the beginning gastrula (0 h embryo). But as soon as the presumptive trunk organizer came into contact with the newly invaginated cranial archenteron roof, it rapidly formed mesoderm. This suggests that this differentiation was brought about by an inductive effect of the underlying cranial archenteron roof. For investigation of this possibility, the presumptive trunk organizer of 0 h embryos (Tr‐0) and the newly invaginated cranial archenteron roof (presumptive pharyngeal endoderm and prechordal plate) of successive stages were cultured in isolation and by the sandwich technique. The newly invaginated presumptive pharyngeal endoderm and prechordal plate had no effect on mesoderm formation of the presumptive trunk organizer, and mesodermal differentiation of the combinations was similar to that of the Tr‐0 alone. On the other hand, results showed that the prechordal plate, which came into contact with the still uninvaginated presumptive trunk organizer, stimulated dorsalisation of the weakly mesodermized trunk organizer. Based on these results, the stepwise process of mesoderm formation in the trunk organizer is discussed.

Gastrulation and pre-gastrulation morphogenesis, inductions, and gene expression: similarities and dissimilarities between urodelean and anuran embryos.

Studies of meso-endoderm and neural induction and subsequent body plan formation have been analyzed using mainly amphibians as the experimental model. Xenopus is currently the predominant model, because it best enables molecular analysis of these induction processes. However, much of the embryological information on these inductions (e.g., those of the Spemann-Mangold organizer), and on the morphogenetic movements of inductively interacting tissues, derives from research on non-model amphibians, especially urodeles. Although the final body pattern is strongly conserved in vertebrates, and although many of the same developmental genes are expressed, it has become evident that there are individually diverse modes of morphogenesis and timing of developmental events. Whether or not this diversity represents essential differences in the early induction processes remains unclear. The aim of this review is to compare the gastrulation process, induction processes, and gene expressions between a urodele, mainly Cynops pyrrhogaster, and an anura, Xenopus laevis, thereby to clarify conserved and diversified aspects. Cynops gastrulation differs significantly from that of Xenopus in that specification of the regions of the Xenopus dorsal marginal zone (DMZ) are specified before the onset of gastrulation, as marked by blastopore formation, whereas the equivalent state of specification does not occur in Cynops until the middle of gastrulation. Detailed comparison of the germ layer structure and morphogenetic movements during the pre-gastrula and gastrula stages shows that the entire gastrulation process should be divided into two phases of notochord induction and neural induction. Cynops undergoes these processes sequentially after the onset of gastrulation, whereas Xenopus undergoes notochord induction during a series of pre-gastrulation movements, and its traditionally defined period of gastrulation only includes the neural induction phase. Comparing the structure, fate, function and state of commitment of each domain of the DMZ of Xenopus and Cynops has revealed that the true form of the Spemann-Mangold organizer is suprablastoporal gsc-expressing endoderm that has notochord-inducing activity. Gsc-expressing deep endoderm and/or superficial endoderm in Xenopus is involved in inducing notochord during pre-gastrulation morphogenesis, rather than both gsc- and bra-expressing tissues being induced at the same time.

Origin of the prechordal plate and patterning of the anteroposterior regional specificity of the involuting and extending archenteron roof of a urodele, Cynops pyrrhogaster

We analyzed the notochord formation, formation of the prechordal plate, and patterning of anteroposterior regional specificity of the involuting and extending archenteron roof of a urodele, Cynops pyrrhogaster. The lower (LDMZ) and upper (UDMZ) domains of the dorsal marginal zone (DMZ) of the early gastrula involuted and formed two distinct domains: the anterior fore-notochordal endodermal roof and the posterior domain containing the prospective notochord. Cygsc is expressed in the LDMZ from the onset of gastrulation, and the Cygsc-expressing LDMZ planarly induces the notochord in the UDMZ at the early to mid gastrula stages. At the mid to late gastrula stages, part of the Cygsc-expressing LDMZ is confined to the prechordal plate. On the other hand, Cybra expression only begins at mid gastrula stage, coincident with notochord induction at this stage. Anteroposterior regional specificity of the neural plate was patterned by the posterior domain of the involuting archenteron roof containing the prospective notochord at the mid to late gastrula stages. Cynops gastrulation thus differs significantly from Xenopus gastrulation in that the regions of the DMZ are specified from the onset of gastrulation, while the equivalent state of specification does not occur in Cynops until the middle of gastrulation. Thus we propose that Cynops gastrulation is divided into two phases: a notochord induction phase in the early to mid gastrula, and a neural induction phase in the mid to late gastrula.

Blastopore formation and dorsal mesoderm induction are independent events in early Cynops embryogenesis

The independent roles of blastopore formation and dorsal mesoderm induction in dorsal axis formation of the Cynops pyrrhogaster embryo were attempted to be clarified. The blastopore‐forming (bottle) cells originated mainly from the progeny of the mid‐dorsal C and/or D blastomeres of the 32‐cell embryo, but were not defined to a fixed blastomere. It was confirmed that the isolated dorsal C and D blastomeres autonomously formed a blastopore. Ultraviolet‐irradiated eggs formed an abnormal blastopore and then did not form a dorsal axis, although the lower dorsal marginal zone (LDMZ) still had dorsal mesoderm‐inducing activity. Involution of the dorsal marginal zone was disturbed by the abnormal blastopore. These embryos were rescued by artificially facilitating involution of the dorsal marginal zone. Suramin‐injected and nocodazole‐treated blastulae did not have involution of the dorsal marginal zone, although the blastopore was formed. Neither embryos formed the dorsal axis. The dorsal mesoderm‐inducing activity of the LDMZ in the nocodazole‐treated gastrulae was still active. In contrast, the LDMZ of the suramin‐injected embryos lost its dorsal mesoderm‐inducing activity. bra expression was activated in the nocodazole‐treated embryos but not in the suramin‐injected embryos. The present study suggested that (i) the dorsal determinants consist of blastopore‐forming and dorsal mesoderm‐inducing factors, which are not always mutually dependent; (ii) both factors are activated during the late blastula stage; (iii) the dorsal marginal zone cannot specify to an organized notochord and muscle without the involution that blastopore formation leads to; and (iv) the localization of both factors in the same place is prerequisite for dorsal axis formation.

pag gene-like protein (ABP-25) of the Cynops embryo: regional distribution and gene expression during early embryogenesis

A maternal protein showing a unique distribution during early Cynops embryogenesis was screened by monoclonal antibody. The antigen protein, designated as ABP-25 (animal blastomere protein, molecular weight 25,000), was distributed uniformly in the uncleaved egg and concentrated into blastomeres of the animal half during cleavage. At the blastula stage, ABP-25 was definitely localized in cells of the animal half and a polarized distribution was observed within the cytoplasm. During gastrulation, immunohistochemical analysis indicated that the reactivity of the marginal zone (presumptive mesoderm) to the monoclonal antibody ABP-25 decreased after involution. At the end of gastrulation, a polarized distribution was still clearly observed in the ventral epidermis, but not in the neuroectoderm. Both Western and Northern blots indicated that the amount of antigen protein and the intensity of gene expresion were almost constant until the neurula stage. The deduced amino acid sequence of the ABP-25 cDNA showed a strong homology (84%) with that of the pag gene associated with cell proliferation.

Neural-Inducing Activity of Newly-Mesodermalized Cells and Cellular Alterations of Induced Neurodermal Cells

In primary embryonic induction of amphibia, there are two main problems: neural-inducing activity of the organizer (chorda-mesoderm) and transformation of the presumptive ectoderm into neurodermal tissues. Many attempts to analyze the problems have been made from various points of view. It is still quite important to investigate the appearance of neural-inducing activity and cellular alterations of induced neurodermal cells. In the present paper, several results on the temporal relationship between mesodermalization and neural-inducing activity of actor cells, and on cellular alterations of induced neurodermal cells are presented.