LiCl inhibits the establishment of left-right asymmetry in larvae of the direct-developing echinoid Peronella japonica

The effect of LiCl on the establishment of left-right (LR) asymmetry in larvae of the direct-developing echinoid Peronella japonica was investigated with special attention to the location of the amniotic opening and ciliary band pattern. The larvae of echinoids are LR symmetric, but shortly before metamorphosis the larval LR symmetry is lost as a result of the formation of an amniotic cavity (vestibule), part of the adult rudiment, on the left side of the body. P. japonica has been considered to be the only exception among the echinoids, because the amniotic cavity forms at the midline of the larval body. In the present study we discovered the following two different LR asymmetric traits in larvae of P. japonica: the opening of the amniotic cavity initially forms at the midline of the larval body but shifts to the left dorsal side, and a looped ciliary band that initially forms with LR symmetry becomes LR asymmetric as a result of the formation of a bulge on left dorsal side. The establishment of LR asymmetry in both the location of the amniotic opening and the change in the shape of the ciliary band was influenced by exposing embryos to LiCl. Quantitative analysis of the shift in amniotic opening showed that exposure of embryos to LiCl causes repression of leftward shifting of the amniotic opening in earlier stage larvae, and leftward or rightward shifting in later stage larvae. These findings suggest that LiCl is an effective means of impairing the establishment of LR asymmetry in sea urchin embryos.     

Variation of cleavage pattern permitting normal development in a sand dollar,Peronella japonica: comparison with other sand dollars

 Peronella japonica, a sand dollar, forms an abbreviated pluteus larva and metamorphoses within 3 days without feeding. In the present study, the cleavage pattern of Peronella embryos was found to be quite irregular in the vegetal blastomeres at the fourth cleavage. Less than half of the embryos examined formed four typical micromeres. The majority formed zero, one, two or three typical micromeres of regular size, and the blastomere(s) remaining in the vegetal-most region was atypical in size and/or its direction of division. Most embryos were able to form pluteus larvae and a considerable proportion of these metamorphosed into juvenile sea urchins, regardless of whether or not they had formed four typical micromeres of regular size, although embryos which formed no typical micromeres developed into pluteus larvae less frequently. The micromere progeny in Peronella embryos form skeletogenic mesenchyme cells. The average numbers of skeletogenic mesenchyme cells in the three sand dollar species, Clypeaster japonicus, Astriclypeus manni and P. japonica were 62, 122 and 219, respectively. In these species, the skeletogenic mesenchyme cell-specific glycoprotein (msp130) was first detected immediately after ingression of the primary mesenchyme cells, spicules appeared at the early gastrula stage and triradiate spicules were found in late gastrulae. Appearance of these characteristics was markedly accelerated in the embryos of A. manni and P. japonica in comparison with those of C. japonicus. Each step in the formation of larval spicules was equally accelerated in A. manni and P. japonica, although the appearance of the adult skeleton was further accelerated in P. japonica in comparison with A. manni, possibly because of omission of the four- to eight-armed pluteus stages. Received: 1 September 1995 / Accepted in revised form: 21 May 1995     

Exogastrulation induced by heavy water in sea urchin larvae.

Replacement of H2O with D2O in seawater causes exogastrulation in larvae of the sea urchins, Hemicentrotus pulcherrimus, Strongylocentrotus intermedius and S. nudus. When larvae at any stages before mesenchymal blastula stage are transferred to 40% D2O-seawater all of them develop gradually to exogastrulae and finally up to plutei with evaginated archenterons. Effects of D2O are partly reversible at limited steps of the way to exogastrulation. Fertilisation and cleavage are not affected appreciably by D2O (50% or less) except for the delay of cleavage.     

The role of Irf6 in tooth epithelial invagination

Thickening and the subsequent invagination of the epithelium are an important initial step in ectodermal organ development. Ikkα has been shown to play a critical role in controlling epithelial growth, since Ikkα mutant mice show protrusions (evaginations) of incisor tooth, whisker and hair follicle epithelium rather than invagination. We show here that mutation of the Interferon regulatory factor (Irf) family, Irf6 also results in evagination of incisor epithelium. In common with Ikkα mutants, Irf6 mutant evagination occurs in a NF-κB-independent manner and shows the same molecular changes as those in Ikkα mutants. Irf6 thus also plays a critical role in regulating epithelial invagination. In addition, we also found that canonical Wnt signaling is upregulated in evaginated incisor epithelium of both Ikkα and Irf6 mutant embryos.     

Induction of metamorphosis in the sand dollar Peronella japonica by thyroid hormones

The larva of the sand dollar Peronella japonica lacks a mouth and gut, and undergoes metamorphosis into a juvenile sand dollar without feeding. In the present study, it was found that thyroid hormones accelerate the metamorphosis of P. japonica larvae. The contents of thyroid hormones in larvae increased gradually during development. Thiourea and potassium perchlorate, inhibitors of thyroid hormone synthesis, delayed larval metamorphosis and simultaneously repressed an increase in the content of thyroxine in the larval body. These results suggest that the P. japonica larva has a system for synthesis of thyroid hormones that act as factors for inducing metamorphosis.     

Micromere-derived signal regulates larval left-right polarity during sea urchin development

The micromeres (Mics) lineage functions as a morphogenetic signaling center in early embryos of sea urchins. The Mics lineage releases signals that regulate the specification of cell fates along the animal-vegetal and oral-aboral axes. We tested whether the Mics lineage might also be responsible for differentiation of the left-right (LR) axis by observing of the placement of the adult rudiment, which normally forms only on the left side of the larvae, after removal of the Mics lineage. When all of the Mics lineage were removed from embryos of the regular sea urchin Hemicentrotus pulcherrimus between the 16- and 64-cell stages, the LR placement of the rudiment became randomized. However, the immediate retransplantation of the Mics rescued the normal LR placement of the rudiment, indicating that the Mics lineage releases a signal that specifies LR polarity. Additionally, we investigated whether the specification of LR polarity of whole embryos in the indirect-developing sea urchin H. pulcherrimus is affected by LiCl exposure, which disturbs the establishment of LR asymmetry in a direct-developing sea urchin. Larvae derived from normal animal caps combined with LiCl-exposed Mics descendants were defective in normal LR placement of the rudiment, suggesting that LiCl interferes with the Mics-derived signal. In contrast, embryos of two sand dollar species (Scaphechinus mirabilis and Astriclypeus manni) were resistant to alteration of LR placement of the rudiment by either removal of the Mics lineage or LiCl exposure. These results indicate that the Mics lineage is involved in specification of LR polarity in the regular sea urchin H. pulcherrimus, and suggest that LiCl impairs the normal LR patterning by affecting Mics-derived signaling.     

Potentiation by the lithium ion of morphogenetic responses to a Xenopus inducing factor

We have cultured explants of Xenopus blastular animal cap tissue from embryos that had received an earlier treatment with LiCl and from their untreated siblings, in various concentrations of XTC-cell-derived mesoderm-inducing factor (XTC-MIF, Smith, 1987; Smith et al. 1988). The pretreatment with lithium that we used transforms later morphogenesis in the whole embryo to give radialized body forms with anterior/dorsal levels of structure grossly over-represented. In addition, animal caps from 'Li+' embryos were allowed to develop without exposure to in vitro MIF (Li+ controls) and compared with normal uninduced control explants, and explants were made from normal early blastulae but given various initial treatments with LiCl in culture. The results confirm that the lithium ion itself will not induce mesoderm in competent, animal cap tissue of Xenopus. It does, however, enhance the responsiveness of this tissue to XTC-MIF, in a way that parallels its recently reported effect in the case of another mesoderm inducer of different character, bFGF (Slack et al. 1988). The effects observed are sufficient to imply that the altered body pattern that follows lithium treatment, in whole embryos, could be caused by modulation of the responses to an unaltered pattern of in situ inductive stimuli. We also observe evidence that appreciable inductive signals reach animal pole tissue beyond the limits of mesoderm formation in normal development. Relatively low concentrations of MIF prevent the development of an epidermis-specific marker in dissociated blastular animal cap cells (Symes et al. 1988). When such experiments are repeated in relation to the lithium pretreatment of embryos, such treatment is seen to have sensitized the cell population, so that the MIF concentration range that assures complete suppression of the marker is reduced. The results are discussed in relation to induction considered as pattern formation.     

In vitro induction systems for analyses of amphibian organogenesis and body patterning

The discovery that some well-known growth factors have inducing activity in embryogenesis has accelerated our understanding of embryonic induction. Relevant receptors, signal transduction pathways and patterns of gene expression have been characterized over the past decade. Amphibian embryos have provided an excellent model for analysis of embryonic induction because they are easily surgically manipulated and cultured in vitro, and with the addition of treatment with various inducing factors we have been able to control organogenesis and body patterning during early development in vitro. Activin A, a TGF-beta family protein, has a potent mesoderm-inducing activity on the isolated ectoderm called the animal cap. Activin induces animal caps to differentiate into various mesodermal and endodermal tissues, including beating hearts, in a dose-dependent fashion. Activin, in combination with retinoic acid, also induces the formation of the pronephros, a primitive embryonic kidney. The in vitro induced kidney was confirmed to function in vivo in a transplantation experiment. Furthermore, the activin-induced animal caps organize heads or trunk-and-tails in exactly the same manner as the organizer. The potential use of in vitro induction systems to further our understanding of vertebrate organogenesis and body patterning will be discussed.     

A Protein That Binds an Exogastrula-Inducing Peptide, EGIP-D, in the Hyaline Layer of Sea Urchin Embryos

Exogastrula-inducing peptides are present in eggs and embryos of the sea urchin Anthocidaris crassispina . They induce exogastrulation when added exogenously to the embryos. In the present study, we investigated an EGIP-D-binding protein in the embryos. EGIP-D was incubated with homogenates of embryos. EGIP-D was then cross-linked to the binding protein by use of disuccinimidyl suberate (DSS) and the complex was analyzed by western blotting with an EGIP-D-specific antibody. A 30-kDa protein was detected in both eggs and embryos. To examine the localization of this protein, EGIP-D was added to intact embryos, cross-linked to proteins by use of DSS, and the complexes were again analyzed by western blotting. The EGIP-D-binding protein was detected in intact embryos but not in embryos treated with Ca²⁺- and Mg²⁺-free seawater (CMF-SW) that removes the hyaline layer (HL). It appeared, therefore, that this protein was present on the outer surface of the embryo, being a constituent of the HL. The CMF-SW extract that contained EGIP-D-binding protein, inhibited the induction of exogastrulation by EGIP-D. Furthermore, the treatment of embryos with CMF-SW prevented EGIP-D from inducing exogastrulation. Our observations indicate that the interaction between EGIP-D and the binding protein is a prerequisite for induction of exogastrulation by EGIP-D.     

Induction of tooth and eye by transplantation of activin A-treated, undifferentiated presumptive ectodermal Xenopus cells into the abdomen

Activin A can induce the Xenopus presumptive ectoderm (animal cap) to form different types of mesoderm and endoderm at different concentrations and the animal cap treated with activin can function as an organizer during early development. The dissociated Xenopus animal cap cells treated with activin form an aggregate and it develops into various tissues in vitro. In this study, to induce jaw cartilage from undifferentiated cells effectively, we developed a culture method to manipulate body patterning in vitro, using activin A and dissociated animal cap cells. An aggregate consisting only of activin A-treated dissociated cells developed into endodermal tissues. However, when activin A-treated cells were mixed with untreated cells at a ratio of 1:5, the aggregate developed cartilage with the maxillofacial regional marker genes, goosecoid, Xenopus Distal-less 4 and X-Hoxa2. When this aggregate was transplanted into the abdominal region of host embryos, maxillofacial structures containing cartilage and eye developed. We raised these embryos to adulthood and found that tooth germ had developed in the transplanted tissue. Here, we show the induction of jaw cartilage, tooth germ and eye structures from animal caps using activin A in the aggregation culture method. This differentiation system will help to promote a better understanding of the regulating mechanisms of body patterning and tooth induction in vertebrates.     

Who came first--larvae or adults? origins of bilaterian metazoan larvae

There is a classic controversy in zoology over whether the common ancestor of living bilaterian phyla was a benthic animal with a bilaterian body plan, or was a pelagic larva-like animal similar to what we see today in the primary larvae of indirect-developing bilaterians. We examine the current larva-like adult hypothesis, and present an alternate model for the evolution of complex life histories by intercalation of larval features into the ontogeny of an ancestral direct-developing bilaterian. This gradual accumulation of larval features results in a developmental regulatory program that produces a larva distinct in body plan from the adult. The evolution of a rapid and complete metamorphosis is made possible by the convergent evolution of set aside cells in the final stages of the emergence of indirect developing larval forms. Although convergences abound either hypothesis for the evolution of developmental pathways and life histories, the bilaterian first hypothesis is consistent with all stages of evolution of a complex life history being selectively advantageous, with the rapid evolution of larval forms, and with the frequent co-option of genes from the adult phase of the life cycle prevalent in the evolution of embryos and larvae.     

Evagination of imaginal discs in the fleshflySarcophaga crassipalpis: Hormonal control in vivo

Summary The hormonal control of evagination of the imaginal leg discs of the fleshflySarcophaga crassipalpis was studied by means of ectopic transplantation of discs from mature larvae or prepupae onto prepupal hosts. Evagination was influenced by the age of the donor and the developmental commitment of the host. Discs from non-diapuse as well as diapause-committed donors did not differ in their capacity to evaginate and differentiate. Mature larval discs from either type of donor could evaginate only when transplanted onto non-diapause hosts; they failed to evaginate on diapause-committed hosts even though host discs evaginated in situ about 40 h after transplantation. Discs from white prepupae evaginated whether transplanted onto non-diapause or onto diapause-committed hosts.     

Dorsalization of mesoderm induction by lithium

Lithium dorsalizes the body plan of Xenopus embryos when administered at the 32-cell stage (K.R. Kao and R.P. Elinson, 1988, Dev. Biol. 127, 64-77). In this paper, we have attempted to determine the effects of lithium on mesoderm induction, in order to localize the target of action of lithium. In the 32-cell embryo, the vegetal-most tier 4 cells are able to induce dorsal development in the overlying, equatorial tier 3 cells (R.L. Gimlich and J.C. Gerhart, 1984, Dev. Biol. 104, 117-130). Our experiments show that microinjection of lithium into either tier 3 or tier 4 cells of ultraviolet-irradiated, dorsoanterior-deficient embryos rescues normal development. Lineage tracer studies show that only tier 3-injected cells contribute progeny to dorsal axial structures while tier 4-injected cells contribute progeny to endoderm. Sandwich explants between animal caps and ventral vegetal cells cause induction of large amounts of muscle in the explants if either caps or vegetal cells are pretreated with lithium. Similarly, fibroblast growth factor-mediated mesoderm induction is also modified by lithium so that muscle is induced instead of ventral mesoderm. We conclude that lithium dorsalizes the response of animal cells to mesoderm induction signals, while not acting directly as a mesoderm inducer itself. The target of action of lithium is likely the third tier of cells of the 32-cell embryo.     

Brefeldin A and monensin inhibit the D quadrant organizer in the polychaete annelids Arctonoe vittata and Serpula columbiana

The D quadrant organizer is a developmental signaling center that is localized to the vegetal D quadrant in different spiral-cleaving lophotrochozoan embryos and may be homologous to axial organizing regions in other metazoans. Patterning by this organizing center creates a secondary developmental axis and is required for the transition from spiral to bilateral cleavage and later establishment of the adult body plan. Organizer specification in equal-cleaving embryos is thought to involve inductive interactions between opposing animal and vegetal blastomeres. To date, experimental demonstration of this interaction has been limited to molluscs and nemerteans. Here, we examine three families of equal-cleaving polychaete annelids for evidence of animal-vegetal contact. We find that contact is present in the polynoid, Arctonoe vittata, but is absent in the serpulid, Serpula columbiana, and in the oweniid, Oweniia fusiformis. To interfere with cell signaling during the period predicted for organizer specification and patterning in A. vittata and S. columbiana, we use two general inhibitors of protein processing and secretion: Brefeldin A (BFA) and monensin. In A. vittata, we detail subsequent embryonic and larval adult development and show that treatment with either chemical results in radialization of the embryo and subsequent body plan. Radialized larvae differentiate many larval and adult structures despite the loss of bilateral symmetry but do so in either a radially symmetric or four-fold radially symmetric fashion. Our results suggest that the D quadrant organizer is functionally conserved in equal-cleaving polychaetes, but that details of its specification, induction, and patterning have diverged relative to other spiral-cleaving phyla.     

Evolutionary modification of specification for the endomesoderm in the direct developing echinoid <Emphasis Type="Italic">Peronella japonica</Emphasis>: loss of the endomesoderm-inducing signal originating from micromeres

We investigated the inductive signals originating from the vegetal blastomeres of embryos of the sand dollar Peronella japonica, which is the only direct developing echinoid species that forms micromeres. To investigate the inductive signals, three different kinds of experimental embryos were produced: micromere-less embryos, in which all micromeres were removed at the 16-cell stage; chimeric embryos produced by an animal cap (eight mesomeres) recombined with a micromere quartet isolated from a 16-cell stage embryo; and chimeric embryos produced by an animal cap recombined with a macromere-derived layer, the veg1 or veg2 layer, isolated from a 64-cell stage embryo. Novel findings obtained from this study of the development of these embryos are as follows. Micromeres lack signals for endomesoderm specification, but are the origin of a signal establishing the oral–aboral (O–Ab) axis. Some non-micromere blastomeres, as well as micromeres, have the potential to form larval skeletons. Macromere descendants have endomesoderm-inducing potential. Based on these results, we propose the following scenario for the first step in the evolution of direct development in echinoids: micromeres lost the ability to send a signal endomesoderm induction so that the archenteron was formed autonomously by macromere descendants. The micromeres retained the ability to form larval spicules and to establish the O–Ab axis.     

Anatomy and ecology of the shell-less endoparasitic gastropod Asterophila japonica Randall and Heath, 1912 (Mollusca: Eulimidae)

The shell-less, endoparasitic gastropod, Asterophila japonica , was collected from two species of sea star, Leptychaster anomalus Fisher, 1906 and Ctenodiscus crispatus (Retzius, 1805) in Toyama Bay, Japan. All observed individuals were located on the aboral side of the host's disk (except one specimen parasitizing the arm) between the epidermis and the coelomic epithelium. More than one large individual frequently co-occur on a single host. The body plan of A. japonica is surprisingly modified from that of general gastropods; organs unrelated to digestion and reproduction are greatly reduced, simplified or completely lost. Dimorphism of body size is striking between males and females: males are much smaller than females and are attached to the surface of the pseudopallium of females. Females deposit and brood an egg mass(es) in the pseudopallial cavity until the eggs develop to veliger larvae. At the late developmental stage, brooded larvae reduce the velum and develop the foot for crawling, suggesting lecithotrophic development with or without a short planktonic stage. It is uncertain as to how the larvae can find and parasitize the next generation of the host. The systematic placement of Asterophila in the family Eulimidae is supported by three characters, viz. parasitism on echinoderms, smooth hydrophobic protoconch, and the enclosure of the visceral mass with the pseudopallium.     

Identification of a specialized extracellular matrix component in Drosophila imaginal discs

We have generated a monoclonal antibody that recognizes a major component of a specialized extracellular matrix in Drosophila imaginal discs. In mature larvae, antibody binding is observed almost exclusively on imaginal discs. On the basal surface of the thoracic discs, the antigen is localized to particular regions of the epithelium, and ultrastructural studies indicate that the antigen is found in a fibrous network secreted between the cells and the basal lamina. The localized expression indicates that the matrix is not simply related to disc differentiation, as all regions of the columnar disc epithelium are determined to secrete adult cuticle. A correlation of the antigen distribution with known developmental events leads us to propose that the antigen-containing network provides an extensible matrix for the rapid elongation of the disc epithelium during evagination; consistent with this, the antigen is a component of the matrix between the dorsal and ventral surfaces of the evaginated wing pouch. The antigen is very large (greater than 5 X 10(5) Da), can be labeled metabolically with methionine and sulfate, and is digested by chondroitinase ABC; these biochemical characteristics indicate that the antigen is a proteoglycan.     

Marked Alteration at Midblastula Transition in the Effect of Lithium on Formation of the Larval Body Pattern of Xenopus laevis

Embryos of Xenopus laevis were exposed to 0.4 M LiCl for 5 min at various stages of development. The effect of lithium on the larval body pattern could be detected from the 2-cell to the late gastrula stage, but changed from reduction of posterior structures ("anteriorization") to reduction of anterior structures ("posteriorization") just after the 12th cleavage, the time of midblastula transition (MBT). Temporal coincidence of MBT with alteration of the effect of lithium was observed even with embryos derived from half-egg fragment, in which MBT occurs just after the 11th cleavage. These results suggest the existence of a mechanism for formation of the basic plan of the larval body whose function changes at MBT. Combinations of the pre- and post-MBT exposures to lithium induced marked posteriorization in most larvae, indicating that the basic plan is not irreversibly determined until MBT, but is fixed during post-MBT stages.     

In vitro control of organogenesis and body patterning by activin during early amphibian development

In the process of amphibian development, an embryonic body plan is established through cell division, sequential gene expression, morphogenesis and cell differentiation. The mechanism of body patterning is complex and includes multiple induction events. Activin, a TGF-beta family protein, can induce several kinds of mesodermal and endodermal tissues in animal cap explants in a dose-dependent manner. In a recent study of the role of activin in organogenesis, we succeeded in raising a beating heart by treating animal caps with a high concentration of activin. Activin also participates in kidney organogenesis in combination with retinoic acid. An embryonic kidney induced by activin and retinoic acid in vitro can function in vivo when it is transplanted into a larva in which pronephros rudiments have already been removed. Further, the activin-treated animal caps clearly show organizer actions that are closely related to body patterning along the anteroposterior axis. These experiments will help to serve as a model system for understanding organogenesis and body patterning at the cellular and molecular levels.     

Head size constrains forebrain development and evolution in ray-finned fishes

In ray-finned fishes, which comprise nearly half of all vertebrate species, the telencephalon does not evaginate, as it does in other vertebrates, but instead everts. No detailed explanation for this species difference has ever been offered. Here we propose that telencephalic eversion evolved because ray-finned fish embryos are so small that their telencephalon cannot evaginate but must, instead, squeeze into the space just dorsal to the developing nasal epithelia and rostral to the eyes-morphogenetic movements that amount to eversion. Evidence for this hypothesis derives from cladistic analyses, which show that early ray-finned fishes reduced their adult body size and adopted a novel reproductive strategy, based on the production of myriad minute young. Because body size tends to be inversely proportional to brain:body ratio, this phylogenetic reduction in body size implies that embryonic ray-finned fishes should have proportionately larger brains than embryos of species whose telencephalons evaginate. This prediction was confirmed by comparing serially sectioned heads of representative ray-finned and cartilaginous fish embryos at several stages of development. The brain, excluding its ventricles, occupies 36-46% of the cranial cavity in embryonic ray-finned fishes, but less than 20% in embryonic sharks. Moreover, three-dimensional reconstructions show that in embryonic ray-finned fishes the telencephalon has no room for a full-fledged evagination; instead, it spreads into the spaces just dorsal and caudal to the developing nasal epithelia. These morphogenetic movements, in conjunction with a thinning of the forebrain roof, generate telencephalic eversion.