Shonan Amemiya

HPETS, AN ETS-RELATED TRANSCRIPTION FACTOR IMPLICATED IN PRIMARY MESENCHYME CELL DIFFERENTIATION IN THE SEA URCHIN EMBRYO

The mechanism of micromere specification is one of the central issues in sea urchin development. In this study we have identified a sea urchin homologue of ets 1 + 2. HpEts, which is maternally expressed ubiquitously during the cleavage stage and which expression becomes restricted to the skeletogenic primary mesenchyme cells (PMC) after the hatching blastula stage. The overexpression of HpEts by mRNA injection into fertilized eggs alters the cell fate of non-PMC to migratory PMC. HpEts induces the expression of a PMC-specific spicule matrix protein, SM50, but suppresses of aboral ectoderm-specific arylsulfatase and endoderm-specific HpEndo16. The overexpression of dominant negative delta HpEts which lacks the N terminal domain, in contrast, specifically represses SM50 expression and development of the spicule. In the upstream region of the SM50 gene there exists an ets binding site that functions as a positive cis-regulatory element. The results suggest that HpEts plays a key role in the differentiation of PMCs in sea urchin embryogenesis.

Larval stages of a living sea lily (stalked crinoid echinoderm).

The embryos and larvae of stalked crinoids, which are considered the most basal group of extant echinoderms, have not previously been described. In contrast, much is known about the development of the more accessible stalkless crinoids (feather stars), which are phylogenetically derived from stalked forms. Here we describe the development of a sea lily from fertilization to larval settlement. There are two successive larval stages: the first is a non-feeding auricularia stage with partly longitudinal ciliary bands (similar to the auricularia and bipinnaria larvae of holothurian and asteroid echinoderms, respectively); the second is a doliolaria larva with circumferential ciliary bands (similar to the earliest larval stage of stalkless crinoids). We suggest that a dipleurula-type larva is primitive for echinoderms and is the starting point for the evolution of additional larval forms within the phylum. From a wider evolutionary viewpoint, the demonstration that the most basal kind of echinoderm larva is a dipleurula is consistent with Garstangs auricularia theory for the phylogenetic origin of the chordate neural tube.

Early inductive interactions are involved in restricting cell fates of mesomeres in sea urchin embryos.

Isolated intact caps of animal blastomeres, obtained from either 8- or 16-cell embryos, differentiate as swollen ectodermal vesicles. These findings agree with earlier studies demonstrating that mesomeres contribute only to larval ectoderm during normal development. In contrast, we find that pairs of mesomeres isolated from 16-cell embryos can differentiate endodermal and mesenchymal cells in a substantial number of cases (23%). Thus, mesomeres have a greater developmental potential than is realized during normal development. Further results support hypotheses that graded distributions of morphogenetic determinants exist within these embryos, since the extent of differentiation of isolated mesomeres is related to the relative position of the third cleavage plane along the animal-vegetal axis. When the third cleavage plane is subequatorial and the resulting animal blastomeres inherit a fraction of the vegetal hemisphere, more cases (39%) differentiate endodermal and mesenchymal cell types. A significant number of mesomere pairs (9-14%), however, can still differentiate endodermal and mesenchymal cells when the mesomeres are formed within the animal hemisphere. Thus, putative vegetal morphogenetic determinants may extend into the animal hemisphere in some cases. Further results indicate a temporal restriction in the developmental potential of mesomeres or mesomere progenitor cells since their differentiative capability is greater if they are isolated earlier during development. Aggregates of isolated mesomere pairs also display a decreased developmental potential when compared to isolated mesomere pairs. These results suggest that associations with adjacent cells (vegetal cells as well as adjacent mesomeres) restrict the development of mesomeres between third and sixth cleavages.

Expression patterns of Hox genes in larvae of the sea lily Metacrinus rotundus

We cloned eight Hox genes (MrHox1, MrHox2, MrHox4, MrHox5, MrHox7, MrHox8, MrHox9/10, and MrHox11/13c) from the sea lily Metacrinus rotundus, a member of the most basal group of the extant echinoderms. At the auricularia stage, before the formation of the pentaradial rudiment, four MrHox genes were expressed sequentially along the anteroposterior (AP) axis in the straightened mesodermal somatocoels in the order MrHox5, MrHox7, MrHox8, and MrHox9/10. The expression of MrHox7 and MrHox8 was detected as early as the hatching stage in the presumptive somatocoel region of the archenteral sac. MrHox5 was expressed in the anteriormost region of the somatocoels, where a stalk-related structure (the chambered organ) forms later. In addition to the mesodermal somatocoels, MrHox7 was expressed in the oral hood ectoderm, which gives rise to the adhesive pit. The expression of four other MrHox genes (MrHox1, MrHox2, MrHox4, and MrHox11/13c) was not detected in any of the larval stages we examined. In comparison with the mesodermal sea urchin Hox genes, the MrHox genes are expressed more posteriorly along the AP (oral–anal) axis than the sea urchin orthologs, implying that the evolution of the eleutherozoans was accompanied by a posteriorization of the larval body. Our study illuminates the possible body plan and Hox expression patterns of the ancestral echinoderm and sheds light on the larval body plan of the last common ancestor of the echinoderms and chordates.

Timing of the potential of micromere-descendants in echinoid embryos to induce endoderm differentiation of mesomere-descendants.

It has been reported that the micromeres of echinoid embryos have the potential to induce an archenteron in animal cap mesomeres recombined at the 16‐ or 32‐cell stage. In the present study, experiments were performed to determine the exact period when the micromeres transmit their inductive signal to respecify the cell fate of mesomeres as endo‐mesoderm. An animal cap was recombined with a quartet of micromeres, or micromere‐descendants cultured in isolation, to form a recombinant embryo. The micromere‐descendants were completely removed at various developmental stages, resulting in an embryo composed only of mesomere‐descendants that had been under the inductive influence of micromeres for a limited period. The resulting embryos were cultured and examined for their potential to differentiate endoderm. The results indicated that the signal effective for inducing an archenteron in mesomere‐descendants emanated from the micromere‐descendants at the early blastula stage around hatching onward. Before this stage, the micromeres and micromere‐descendants showed this potential slightly or not at all. The inductive signal emanated from the micromere‐descendants almost on time even when the cells were cultured in isolation. The micromere‐descendants completed transmission of the signal for inducing the archenteron in the animal cap within 2 h of recombination. The animal cap at between the 28‐cell stage and 2 h after the 32‐cell stage could react with the inductive signal from the micromere‐descendants. Embryos composed of only animal cap mesomeres that had received the inductive signal from micromere‐descendants for a limited period had the potential to develop into 8‐armed plutei. Each pluteus formed an adult rudiment essentially on the left side of the larval body, and metamorphosed into a juvenile with pentaradiate symmetry.

Comparative biochemical studies of carotenoids in sea urchins—III. Relationship between developmental mode and carotenoids in the Australian echinoids Heliocidaris erythrogramma and H. tuberculata and a comparison with Japanese species

Abstract The sea urchin Heliocidaris tuberculata is typical of most echinoids in having a small egg and a feeding larva, while H. erythrogramma has a large egg and modified development through a non-feeding larvae. The carotenoids in the gonads of these two species were investigated from the comparative biochemical points of view. The carotenoid content of the buoyant eggs of H. erythrogramma was approximately 60 times that of the negatively-buoyant eggs of H. tuberculata . With respect to cytoplasmic volume, however, the carotenoid concentration in the eggs of H. tuberculata was approximately twice that in the eggs of H. erythrogramma . In both species β-echinenone was the principal carotenoid found and their carotenoid patterns were similar. It is very interesting from a functional point of view that carotenoid levels per cytoplasmic volume are conserved across most of the species we have examined irrespective of phylogeny and egg size. In light of this result we suggest that carotenoids may play an important role in developing stage in all echinoids including indirect and direct developers.

Phylogenetic correspondence of the body axes in bilaterians is revealed by the right‐sided expression of Pitx genes in echinoderm larvae

Chordates and echinoderms are two of the three major deuterostome phyla and show conspicuous left‐right (LR) asymmetry. The establishment of LR asymmetry has been explored in vertebrates, but is largely unknown in echinoderms. Here, we report the expression pattern of genes that are orthologous to the chordate left‐side specific gene Pitx, cloned from the sea urchin Hemicentrotus pulcherrimus (HpPitx) and the starfish Asterina pectinifera (ApPitx). HpPitx transcripts were first detected bilaterally in one cell of the ventrolateral primary mesenchyme‐cell aggregate of early prism larvae. New expression was detected asymmetrically in the right counterpart of a bilateral pair of mesodermal coelomic pouches and in the right ectoderm. In starfish bipinnaria larvae, the ApPitx signal was detected in the right coelomic pouch and in the right half of the ectoderm along the ciliary bands. These results suggest that the function of Pitx in establishing LR asymmetry was introduced in the last common ancestor of echinoderms and chordates. However, the right‐side specific expression in echinoderm larvae is inverted compared to chordate embryos. This indicates that the LR axis is inversely represented between echinoderms and chordates, which supports the scenario that dorsoventral axis inversion was introduced into the chordate lineage by turning upside down.

Development of the basal lamina and its role in migration and pattern formation of primary mesenchyme cells in sea urchin embryos

The development and substructure of the basal lamina and its role in migration and pattern formation of primary mesenchyme cells (PMCs) in normal as well as Li+‐ and Zn++‐treated embryos of sea urchins were investigated by electron microscopy. Major findings were as follows. 1) Network fibrils appear along the basal surface of the blastular wall by the hatching blastula stage. The area covered with fibrils is restricted to the vegetal hemisphere at earlier stages, but extends to the animal hemisphere as development proceeds. 2) Nonfibrous fuzzy material embeds the fibrils to form a basal lamina, but in places the fibrils project from the basal lamina into the blastocoel. The major components of the fuzzy material were digested by glycosidase, which failed to digest the fibrous components. 3) The fibrils can be classified into two types, one Ca++‐independent and the other Ca++‐dependent. PMCs apparently utilize the Ca++‐indepndent fibrils as a substratum for locomotion. 4) After migration, PMCs accumulate in a specific region to form the PMC pattern. This is formed in the area of greatest concentration of Ca++‐independent fibrils. 5) PMCs in embryos treated with LiCl, in contrast to normal embryos, accumulate in the animal pole region where the Ca++‐independent fibrils are markedly concentrated.

Electron microscopic studies on primary mesenchyme cell ingression and gastrulation in relation to vegetal pole cell behavior in sea urchin embryos

Early morphogenetic events of primary mesenchyme cell (PMC) ingression and gastrulation were examined by scanning and transmission electron microscopy, with special attention directed to changes in the shape of vegetal pole cells, the length of their microvilli, and interactions between microvilli and the hyaline layer (HL). Eight cells (vegetal pole cells) with elongated microvilli remained in the vegetal pole region while surrounding cells ingressed into the blastocoel to form the primary mesenchyme. These vegetal pole cells indented with the surrounding cells at the stage of gastrulation. The outer surface area with elongated microvilli of vegetal pole cells expanded at the stage of PMC ingression, but was considerably reduced at gastrulation. Microvilli on vegetal pole cells continued to adhere to the HL up to the stage of PMC ingression, but ceased to do so at the time of gastrulation. Thus, the area with separated HL, which is restricted to the region of the PMC released at the stage of PMC ingression, spreads almost entirely throughout the area of the indenting vegetal plate at gastrulation. The apical lamina, apparently consisting of fibrous material intertwinning the stalks of the microvilli, filled the space between the HL and ectodermal cells. The cells surrounding those of the vegetal pole and indenting with those at the stage of gastrulation appeared to behave in the same way as ingressing PMCs in both cell-shape and loss of adhesion of microvilli to HL. The role of vegetal pole cells in early morphogenetic events is discussed.

The micro1 gene is necessary and sufficient for micromere differentiation and mid/hindgut-inducing activity in the sea urchin embryo

In the sea urchin embryo, micromeres have two distinct functions: they differentiate cell autonomously into the skeletogenic mesenchyme cells and act as an organizing center that induces endomesoderm formation. We demonstrated that micro1 controls micromere specification as a transcriptional repressor. Because micro1 is a multicopy gene with at least six polymorphic loci, it has been difficult to consistently block micro1 function by morpholino-mediated knockdown. Here, to block micro1 function, we used an active activator of micro1 consisting of a fusion protein of the VP16 activation domain and the micro1 homeodomain. Embryos injected with mRNA encoding the fusion protein exhibited a phenotype similar to that of micromere-less embryos. To evaluate micro1 function in the micromere, we constructed chimeric embryos composed of animal cap mesomeres and a micromere quartet from embryos injected with the fusion protein mRNA. The chimeras developed into dauerblastulae with no vegetal structures, in which the micromere progeny constituted the blastula wall. We also analyzed the phenotype of chimeras composed of an animal cap and a mesomere expressing micro1. These chimeras developed into pluteus larvae, in which the mesomere descendants ingressed as primary mesenchyme cells and formed a complete set of skeletal rods. The hindgut and a part of the midgut were also generated from host mesomeres. However, the foregut and nonskeletogenic mesoderm were not formed in the larvae. From these observations, we conclude that micro1 is necessary and sufficient for both micromere differentiation and mid/hindgut-inducing activity, and we also suggest that micro1 may not fulfill all micromere functions.