Ascidian neural crest-like cells: phylogenetic distribution, relationship to larval complexity, and pigment cell fate

Migratory neural crest-like cells, which express the cell surface antigen HNK-1 and develop into pigment cells, have recently been identified in the ascidian Ecteinascidia turbinata. Here we use HNK-1 expression as a marker to determine whether neural crest-like cells are responsible for pigment development in diverse ascidian species. We surveyed HNK-1 expression and tyrosinase activity in 12 ascidian species, including those with different adult organizations, developmental modes, and larval sizes and complexities. We observed HNK-1 positive cells in every species, although the timing of HNK-1 expression varied according to the extent of larval complexity. HNK-1 expression was initiated during the late tailbud stage in species in which adult features are formed precociously in large complex larvae. In contrast, HNK-1 positive cells did not appear until the swimming tadpole or juvenile stage in species with small simple larvae in which most adult features appear after metamorphosis. Double labeling experiments indicated that HNK-1 and tyrosinase are expressed in the same subset of pigment-forming mesenchymal cells in species with complex or simple larvae. In addition, the absence of HNK-1 and tyrosinase expression in albino morphs of the colonial ascidian Botryllus schlosseri suggested that the major fate of neural crest-like cells is to become pigment cells. The results suggest that ascidian neural crest-like cells and vertebrate neural crest cells had a common origin during chordate evolution and that their primitive function was to generate body pigmentation.     

Larval Tunic and the Function of the Test Cells in Ascidians

Abstract In normal ascidian development, cuticular fins begin to form at the late tailbud stage and are fully formed at hatching. When one or several neurulae were manually demembranated (follicle cells, vitelline coat and test cells removed) and cultured in seawater they failed to form caudal fins. Fins were normal when the follicle cells alone were removed. The shape of the fins was normal when demembranation was delayed to the late tailbud stage. Does demembranation cause the loss of an essential factor produced by the embryos themselves or do the test cells provide a factor for fin morphogenesis? Demembranated neurulae of Ascidia callosa were cultured in groups ranging in size from 2 to 80 in 1 ml volumes of seawater. The mean lengths of the caudal fins increased with group size. In larger groups, some embryos developed fins that were normal in shape and as long as undemembranated controls. Results were similar with Corella inflata. These experiments suggest that a diffusible substance from the embryos facilitates fin morphogenesis and that test cells are not required. Test cells deposit ‘ornaments’ on the tunic in some species. In other species no ornaments are produced. Ten families are compared. It is proposed that the test cells make the tunic hydrophilic.     

Primordial germ cells originate from the endodermal strand cells in the ascidian Ciona intestinalis

The origin of germ cells in the ascidian is still unknown. Previously, we cloned a vasa homologue (CiVH) of Ciona intestinalis from the cDNA library of ovarian tissue by polymerase chain reaction and showed that its expression was specific to germ cells in adult and juvenile gonads. In the present study, we prepared a monoclonal antibody against CiVH protein and traced the staining for this antibody from the middle tailbud stage to young adulthood. Results showed that positive cells are present in the endodermal strand in middle tailbud embryos and larvae. When the larval tail was absorbed into the trunk during metamorphosis, the CiVH-positive cells migrated from the debris of the tail into the developing gonad rudiment, and appeared to give rise to a primordial germ cell (PGC) in the young juvenile. The testis rudiment separated from the gonad rudiment, the remainder of which differentiated into the ovary. PGCs of the testis rudiment and the ovary rudiment differentiated into spermatogenic and oogenic cells, respectively. When the larval tail containing the antibody-positive cells was removed, the juveniles did not contain any CiVH-positive cells after metamorphosis, indicating that the PGCs in the juvenile originated from part of the larval tail. However, even in such juveniles, positive cells newly appeared in the gonad rudiment at a later stage. This observation suggests that a compensatory mechanism regulates germline formation in C. intestinalis.     

Test cell migration and tunic formation during posthatching development of the larva of the ascidian, Ciona intestinalis

Morphological changes in the tunic layers and migration of the test cells during swimming period in the larva of the ascidian, Ciona intestinalis , were observed by light and electron microscopy. The swimming period was divided into three stages. In stage 1, further formation of juvenile tunic layer started only in the larval trunk and neck region. In stage 2, the layer became swollen in the ventral and dorsal sides of the neck region and in stage 3, the swelling expanded backward. Concomitantly with these changes, the outermost larval tunic layer (outer cuticular layer), which had been formed before hatching, also swelled in the neck region in stage 2 and formed two humps in stage 3, although the layer did not change in the tail region during the swimming period. Test cells that were present over the entire larval tunic layer in stage 1 began to move from the surface of the fin toward that of the side of the body in stage 2, and finally gathered to form six bands running radially from the anterior end to the posterior end of the trunk region and aligned along the lateral sides of body in the tail region in stage 3. In electron microscopic observations, pseudopodia protruding from the test cells invaded the larval tunic, following which they extended proximate to the juvenile tunic in the trunk region. In the tail region, which had no juvenile tunic layer as that described, the pseudopodia invaded and remained adjacent to the surface of the epidermis or the sensory cilia protruded from the epidermis. Metamorphosis of the larvae, further tunic formation, degradation of adhesive papilla, attachment of larva to the substratum and tail resorption commenced after these morphological changes occurred. The possible role of the test cells in metamorphosis is discussed.     

Statocyte and Ocellar Pigment Cell in Embryos and Larvae of the Ascidian, Styela plicata (Lesueur)

The processes of formation of two pigmented cells, the statocyte and the ocellar pigment cell, in the cerebral vesicle of larvae of the ascidian Styela plicata were investigated in whole mount specimens and serial paraffin sections by light microscopy. The pigmentations of the two cells became visible simultaneously in embryos at the stage of tail elongation, 5–6 hr after fertilization. The pigmented cells were at first located side by side in the dorsal wall of the neurocoel. Growth of the pigment mass in the ocellus ceased at about 6.5 hr, while that in the statocyte continued through the hatching period (9–10 hr) up to the swimming stage. The pigment mass in the statocyte consisted of two blocks which joined together during their growth. The statocyte migrated from the dorsal to the ventral wall of the cerebral vesicle by the swimming stage. In swimming larvae, the more ventral of the two pigment blocks of the statocyte formed an inverted pigment cup and a cluster of protuberances projected into it from the ventral wall of the cerebral vesicle. Phylogenetically, the sensory organs in the cerebral vesicle of Styela plicata seem intermediate between those in Pyuridae and Botryllinae with respect of their structure and process of differentiation.     

Structure of ocellus photoreceptors in the ascidian Ciona intestinalis larva as revealed by an anti‐arrestin antibody

Although there have been several studies on the structure of the ocellus photoreceptors in ascidian tadpole larvae using electron microscopy, the overall structure of these photoreceptor cells, especially the projection sites of the axons, has not been revealed completely. The number of photoreceptor cells is also controversial. Here, the whole structure of the ocellus photoreceptors in the larvae of the ascidian Ciona intestinalis was revealed by using an anti‐arrestin (anti–Ci‐Arr) antibody. The cell bodies of 30 photoreceptor cells covered the right side of the ocellus pigment cell and their outer segments extended through the pigment cell into the pigment cup. The axons of the photoreceptor cells were bundled together ventro‐posteriorly in a single tract extending towards the midline. The nerve terminals diverged antero‐posteriorly at the midline of the posterior sensory vesicle (SV). The Ci‐arr gene was expressed throughout the SV at the embryonic mid‐tailbud stage and it became restricted to the neighborhood of the ocellus pigment when ocellus pigmentation occurred. At the same time, the Ci‐Arr protein was first detected, suggesting that the photoreceptor cells began to differentiate. The development of photoreceptor cells after hatching was also investigated using the anti–Ci‐Arr antibody. Three hours after hatching, the photoreceptor terminals began to ramify and then expanded. Previous behavioral analysis showed that the larvae did not respond to the step‐down of light until 2 h after hatching and then the photoresponse became robust. Accordingly, our results suggest that growth of the photoreceptor terminal is critical for the larvae to become photoresponsive. © 2005 Wiley Periodicals, Inc. J Neurobiol, 2005     

The ascidian homolog of the vertebrate homeobox gene Rx is essential for ocellus development and function

The tadpole larvae prosencephalon of the ascidian Ciona intestinalis contains a single large ventricle, along the inner walls of which lie two sensory organs: the otolith (a gravity-sensing organ) and the ocellus (a photo-sensing organ composed of a single cup-shaped pigment cell, about 20 photoreceptor cells, and three lens cells). Comparison has been drawn between the morphology and physiology of photoreceptor cells in the ascidian ocellus and the vertebrate eye. The development of vertebrate and invertebrate eyes requires the activity of several conserved genes and it is regulated by precise expression patterns and cell fate decisions common to several species. We have isolated a Ciona homeobox gene (Ci-Rx) that belongs to the paired-like class of homeobox genes. Rx genes have been identified from a variety of organisms and have been demonstrated to have a role in vertebrate eye formation. Ci-Rx is expressed in the anterior neural plate in the middle tailbud stage and subsequently in the larval stage in the sensory vesicle around the ocellus. Loss of Ci-Rx function leads to an ocellus-less phenotype that shows a loss of photosensitive swimming behavior, suggesting the important role played by Ci-Rx in basal chordate photoreceptor cell differentiation and ocellus formation. Furthermore, studies on Ci-Rx regulatory elements electroporated into Ciona embryos using LacZ or GFP as reporter genes indicate the presence of Ci-Rx in pigment cells, photoreceptors, and neurons surrounding the sensory vesicle. In Ci-Rx knocked-down larvae, neither basal swimming activity nor shadow responses develop. Thus, Rx has a role not only in pigment cells and photoreceptor formation but also in the correct development of the neuronal circuit that controls larval photosensitivity and swimming behavior. The results suggest that a Ci-Rx "retinal" territory exists, which consists of pigment cells, photoreceptors, and neurons involved in transducing the photoreceptor signals.     

The fate of cells in the tailbud of Xenopus laevis

The vertebrate tailbud and trunk form very similar tissues. It has been a controversial question for decades whether cell determination in the developing tail proceeds as part of early axial development or whether it proceeds by a different mechanism. To examine this question more closely, we have used photoactivation of fluorescence to mark small neighborhoods of cells in the developing tailbud of Xenopus laevis. We show that, in one region of the tailbud, very small groups of adjacent cells can contribute progeny to the neural tube, notochord and somitic muscle, as well as other identified cell types within a single embryo. Groups averaging three adjacent cells at a later stage can contribute progeny with a similar distribution. Our data suggest that the tailbud contains multipotent cells that make very late germ-layer decisions.     

Analysis of ascidian <Emphasis Type="Italic">Not</Emphasis> genes highlights their evolutionarily conserved and derived features of structure and expression in development

The ascidian larva is often regarded as an organism close to the ancestral form of chordates, while it is generally accepted that the Spemanns organizer is absent from ascidian embryos. Not is one of the genes expressed in the organizer to execute functions in vertebrate embryos. To address the extent of conservation of Not gene expression among ascidians and vertebrates, we examined the structure and developmental expression of Not of the two distantly related ascidian species, Halocynthia and Ciona. Putative ascidian Not proteins were noted by the absence of one of the two motifs conserved among Not proteins of sea urchin and vertebrates. Analysis by in situ hybridization revealed that Not gene expression of ascidians could be categorized into three types: expression likely to be conserved between ascidians and vertebrates, that probably unique to ascidians, and that specific to ascidian species. Expression of ascidian Not in the posterior end of the tail as well as the notochord and a small part of the anterior neural tube at the tailbud stage is reminiscent of the expression of the vertebrate counterparts in the tailbud, which is regarded as a continuation of the organizer and the pineal gland, respectively. The expression of Not in the epidermis precursors during cleavage stage may be unique to ascidians. In the light of the present findings, evolutionary aspects of Not genes are discussed.Electronic Supplementary Material Supplementary material is available for this article at Edited by N. Satoh     

Delineating metamorphic pathways in the ascidian Ciona intestinalis

In most ascidians, metamorphosis of tadpole-like swimming larvae is accompanied by dynamic changes in their shape to form sessile adults. The mechanisms underlying ascidian metamorphosis have been debated for a long time. Although recent molecular studies have revealed the presence of various molecules involving in this process, the basic mechanism of the metamorphic events is still unclear. For example, it has not been solved whether all metamorphic events are organized by the same single pathway or by multiple, independent pathways. In the present study, we approached this question using the ascidian Ciona intestinalis. When the papillae and preoral lobes of the larvae were cut off, the papillae-cut larvae initiated certain trunk metamorphic events such as the formation of an ampulla, body axis rotation and adult organ growth without other metamorphic events. This observation indicates that metamorphic events can be divided into at least two groups, events initiated in the papillae-cut larva and events not initiated in this larva. In addition to this observation, we have isolated a novel mutant, tail regression failed (trf), which shows similar phenotypes to those of papillae-cut larvae. The phenotypes of trf mutants are basically different from those of swimming juvenile mutants (Sasakura, Y., Nakashima, K., Awazu, S., Matsuoka, T., Nakayama, A., Azuma, J., Satoh, N., 2005. Transposon-mediated insertional mutagenesis revealed the functions of animal cellulose synthase in the ascidian Ciona intestinalis. Proc. Natl. Acad. Sci. U. S. A. 102, 15134-15139.), which also show abnormal metamorphosis. These findings suggest a model by which ascidian metamorphic events can be classified into four groups initiated by different pathways.     

Developmental expression of tryptophan hydroxylase gene in <Emphasis Type="Italic">Ciona intestinalis</Emphasis>

To describe the serotonergic system in a tunicate larva, we cloned a gene encoding for tryptophan hydroxylase (TPH), the rate-limiting enzyme in serotonin synthesis, in the ascidian Ciona intestinalis and studied its expression pattern during development. Ci-TPH expression was found from tailbud stage in the precursor cells of the visceral ganglion and in the tail. In the larva, TPH-expressing neurons formed two clusters in the anterior central nervous system at the level of the visceral ganglion. Moreover, we found Ci-TPH expression at the level of the muscle cells of the tail and suggested that this localisation might be at the level of neuro-muscolar junctions. Moreover, we discussed the involvement of serotonin in the control of larval locomotory activity.     

CHANGES IN THE ACTIVITY OF ACID PHOSPHATASE AND THE APPEARANCE OF METAMORPHOSING POTENCIES OF THE LARVAE OF THE ASCIDIAN, HALOCYNTHIA RORETZI

In the swimming phase of the larvae of the ascidian, Halocynthia roretzi , changes in the activity of acid phosphatase (AcP-ase) were studied cytochemically with respect to the appearance of metamorphosing potencies. The AcP-ase activity in the larvae before and soon after hatching is weakly visible only in and around the nuclei of the epithelial, muscular and notochordal cells. 6 hr after hatching the enzyme activity begins t o appear weakly in the microblasts around the proximal end of the notochordal sheath, whereas the activities which were found in the previous stages disappear. In the larvae which passed for 12 hr after hatching, the activity of AcP-ase is distinctly shown in the microblasts and also in the other 2 mesodermal cells, meso- and macro- blasts. The microblasts of this stage are closely attached to the notochordal sheath at the proximal end. At the same time, many large granules which appear similar to lysosomes are found in the microblast by an electron microscopy. The 6th hour's larvae after hatching can be induced slowly to resorb its tail by the treatment with a nile blue solution, but the time which it takes for tail resorption is gradually shortened depending on the age of the larva up until 12 hr after hatching.
From these results, i t was concluded that the appearance of the AcP-ase activity in the microblasts was parallel with the appearance of the potency of metamorphosis of the larvae after hatching. Possible roles of the microblasts at onset of meta- morphosis would seem to play a role in the rupture of the notochordal sheath and in the succeeding regression of the tail tissues.     

A Monoclonal Antibody Specific to Embryonic Trunk-Lateral Cells of the Ascidian Halocynthia roretzi Stains Coelomic Cells of Juvenile and Adult Basophilic Blood Cells

In spite of extensive knowledge on the structure and function of ascidian blood cells, little is known about their embryological origin. In the present investigation, the developmental fate of trunk lateral cells (TLCs) was explored using a specific monoclonal antibody. TLCs comprise a group of undefined embryonic cells of the ascidian Halocynthia roretzi , which arise from the A7.6 blastomeres of a 64-cell embryo. The antigenicity first appeared at the middle tailbud stage in a pair of TLC-clusters situated lateral to the brain stem of the bilaterally symmetrical embryo. The position and number of stained cells did not change during later embryogenesis until hatching. After hatching, the stained cells were found in the entire trunk region of the swimming larva. After metamorphosis, cells that expressed the antigen were present within the coelom and within the tunic layer of the juvenile. In addition, the antibody stained adult basophilic blood cells. These observations suggest a relationship of this group of embryonic cells with the prospective blood forming mesenchymal cells.     

Regionalization of the tail-tip epidermis requires inductive influence from vegetal cells and FGF signaling in the development of an ascidian, Halocynthia roretzi

The epidermis of an ascidian larva derived from animal-hemisphere cells is regionalized along the anterior-posterior (AP) axis through inductive signals emanating from vegetal-hemisphere cells in early stages of the development. Previously, we showed by blastomere isolation and ablation experiments that the contact between the animal and vegetal hemispheres until the 32-cell stage is necessary for the proper AP patterning of the epidermis in the tailbud-stage embryo. We here addressed the patterning mechanism of the posteriormost epidermis using a tail-tip epidermis marker, HrTT-1. Employing blastomere isolation and ablation experiments along with knockdown of a master regulator gene for posterior mesoderm, we have demonstrated that presence of the posterior vegetal cells after the 32-cell stage is necessary for the expression of HrTT-1. To explore the timing and nature of the influence of the posterior vegetal cells, we treated the embryos with FGF signaling inhibitors at various developmental stages and found that HrTT-1 expression was lost from embryos treated with the inhibitors from stages earlier than the late neurula stage, just prior to the onset of HrTT-1 expression but not after the initial tailbud stage, at which the expression of HrTT-1 had started. In embryos lacking HrTT-1 expression, the expression domain of Hrcad, which would otherwise be localized anterior to that of HrTT-1, expanded to the tail-tip. These results suggest that FGF signaling from the neurula to initial tailbud stages is necessary for the initiation but not maintenance of HrTT-1 expression in the tail-tip epidermis. The contact with posterior vegetal cells until and after the 32-cell stage may be required for FGF signaling to occur in the posterior tail, which in turn regionalizes the tail-tip epidermal territory.     

Tissue-specific profile of DNA replication in the swimming larvae of Ciona intestinalis

The cell cycle is strictly regulated during development and its regulation is essential for organ formation and developmental timing. Here we observed the pattern of DNA replication in swimming larvae of an ascidian, Ciona intestinalis. Usually, Ciona swimming larvae obtain competence for metamorphosis at about 4-5 h after hatching, and these competent larvae initiate metamorphosis soon after they adhere to substrate with their papillae. In these larvae, three major tissues (epidermis, endoderm and mesenchyme) showed extensive DNA replication with distinct pattern and timing, suggesting tissue-specific cell cycle regulation. However, DNA replication did not continue in aged larvae which kept swimming for several days, suggesting that the cell cycle is arrested in these larvae at a certain time to prevent further growth of adult organ rudiments until the initiation of metamorphosis. Inhibition of the cell cycle by aphidicolin during the larval stage affects only the speed of metamorphosis, and not the formation of adult organ rudiments or the timing of the initiation of metamorphosis. However, after the completion of tail resorption, DNA replication is necessary for further metamorphic events. Our data showed that DNA synthesis in the larval trunk is not directly associated with the organization of adult organs, but it contributes to the speed of metamorphosis after settlement.     

Ascidian Wnt-7 gene is expressed exclusively in the tail neural tube of tailbud embryos

In vertebrate embryogenesis, many Wnt genes are expressed in the neural tube and play important roles in regional specifications. There are many subfamilies of Wnt, and each subfamily shows distinct expression patterns in the neural tube. Ascidian larvae have a dorsal hollow neural tube similar to that of vertebrates. To date, the degree of correspondence between regionality of the neural tubes of ascidians and vertebrates remains unclear. To compare cellular differences in neural tubes, Wnt genes can be used as molecular probes. We report here that a new member of the ascidian Wnt gene family, HrWnt-7, was expressed in the tail neural tube at the early tailbud stage. Moreover, in cross-section, HrWnt-7 was expressed in the dorsal and ventral ependymal cells. Received: 14 July 2000 / Accepted: 1 August 2000     

The evolution of larval morphology and swimming performance in ascidians

The complexity of organismal function challenges our ability to understand the evolution of animal locomotion. To meet this challenge, we used a combination of biomechanics, phylogenetic comparative analyses, and theoretical morphology to examine evolutionary changes in body shape and how those changes affected swimming performance in ascidian larvae. Results of phylogenetic comparative analyses suggest that coloniality evolved at least three times among ascidians and that colonial species have a convergent larval morphology characterized by a large trunk volume and shorter tail length in proportion to the trunk. To explore the functional significance of this evolutionary change, we first verified the accuracy of a mathematical model of swimming biomechanics in a solitary (C. intestinalis) and a colonial (D. occidentalis) species and then ran numerous simulations of the model that varied in tail length and trunk volume. The results of these simulations were used to construct landscapes of speed and cost of transport predictions within a trunk volume/tail length morphospace. Our results suggest that the reduction of proportionate tail length in colonial species resulted in improved energetic economy of swimming. The increase in the size of larvae with the origin of coloniality facilitated faster swimming with negligible energetic cost, but may have required a reduction in adult fecundity. Therefore, the evolution of ascidians appears to be influenced by a trade-off between the fecundity of the adult stage and the swimming performance of larvae.     

Spatio-temporal regulation of Rx and mitotic patterns shape the eye-cup of the photoreceptor cells in Ciona

The ascidian larva has a pigmented ocellus comprised of a cup-shaped array of approximately 30 photoreceptor cells, a pigment cell, and three lens cells. Morphological, physiological and molecular evidence has suggested evolutionary kinship between the ascidian larval photoreceptors and vertebrate retinal and/or pineal photoreceptors. Rx, an essential factor for vertebrate photoreceptor development, has also been suggested to be involved in the development of the ascidian photoreceptor cells, but a recent revision of the photoreceptor cell lineage raised a crucial discrepancy between the reported expression patterns of Rx and the cell lineage. Here, we report spatio-temporal expression patterns of Rx at single-cell resolution along with mitotic patterns up to the final division of the photoreceptor-lineage cells in Ciona. The expression of Rx commences in non-photoreceptor a-lineage cells on the right side of the anterior sensory vesicle at the early tailbud stage. At the mid tailbud stage, Rx begins to be expressed in the A-lineage photoreceptor cell progenitors located on the right side of the posterior sensory vesicle. Thus, Rx is specifically but not exclusively expressed in the photoreceptor-lineage cells in the ascidian embryo. Two cis-regulatory modules are shown to be important for the photoreceptor-lineage expression of Rx. The cell division patterns of the photoreceptor-lineage cells rationally explain the generation of the cup-shaped structure of the pigmented ocellus. The present findings demonstrate the complete cell lineage of the ocellus photoreceptor cells and provide a framework elucidating the molecular and cellular mechanisms of photoreceptor development in Ciona.