A simple "neural induction" model with two interacting cleavage-arrested ascidian blastomeres

Nervous system regulated by POZ domain Krüppel-like zinc finger (POK) family transcription repressor RP58

The POZ domain Krüppel-like zinc finger transcription repressor (POK family) contains many important molecules, including RP58, Bcl6 and PLZF. They function as transcription repressors via chromatin remodelling and histone deacetylation and are known to be involved in the development and tumourigenesis of various organs. Furthermore, they are important in the formation and function of the nervous system. This review summarizes the role of the POK family transcription repressors in the nervous system. We particularly targeted Rp58 (also known as Znf238, Znp238 and Zbtb18), a sequence-specific transcriptional repressor that is strongly expressed in developing glutamatergic projection neurons in the cerebral cortex. It regulates various physiological processes, including neuronal production, neuronal migration and neuronal maturation. Human studies suggest that reduced RP58 levels are involved in cognitive function impairment and brain tumour formation. This review particularly focuses on the mechanisms underlying RP58-mediated neuronal development and function. LINKED ARTICLES: This article is part of a themed issue on Neurochemistry in Japan. To view the other articles in this section visit http://onlinelibrary.wiley.com/doi/10.1111/bph.v178.4/issuetoc.

Tunicate gastrulation

Tunicates are a diverse group of invertebrate marine chordates that includes the larvaceans, thaliaceans, and ascidians. Because of their unique evolutionary position as the sister group of the vertebrates, tunicates are invaluable as a comparative model and hold the promise of revealing both conserved and derived features of chordate gastrulation. Descriptive studies in a broad range of tunicates have revealed several important unifying traits that make them unique among the chordates, including invariant cell lineages through gastrula stages and an overall morphological simplicity. Gastrulation has only been studied in detail in ascidians such as Ciona and Phallusia, where it involves a simple cup-shaped gastrula driven primarily by endoderm invagination. This appears to differ significantly from vertebrate models, such as Xenopus, in which mesoderm convergent extension and epidermal epiboly are major contributors to involution. These differences may reflect the cellular simplicity of the ascidian embryo.

Developmental Roles and Evolutionary Significance of AMPA-Type Glutamate Receptors

Organogenesis and metamorphosis require the intricate orchestration of multiple types of cellular interactions and signaling pathways. Glutamate (Glu) is an excitatory extracellular signaling molecule in the nervous system, while Ca²⁺ is a major intracellular signaling molecule. The first Glu receptors to be cloned are Ca²⁺ -permeable receptors in mammalian brains. Although recent studies have focused on Glu signaling in synaptic mechanisms of the mammalian central nervous system, it is unclear how this signaling functions in development. Our recent article demonstrated that Ca²⁺ -permeable AMPA-type Glu receptors (GluAs) are essential for formation of a photosensitive organ, development of some neurons, and metamorphosis, including tail absorption and body axis rotation, in ascidian embryos. Based on findings in these embryos and mammalian brains, we formed several hypotheses regarding the evolution of GluAs, the non-synaptic function of Glu, the origin of GluA-positive neurons, and the neuronal network that controls metamorphosis in ascidians.

Evolutionary History of Voltage-Gated Sodium Channels

Every cell within living organisms actively maintains an intracellular Na⁺ concentration that is 10-12 times lower than the extracellular concentration. The cells then utilize this transmembrane Na⁺ concentration gradient as a driving force to produce electrical signals, sometimes in the form of action potentials. The protein family comprising voltage-gated sodium channels (Na_Vs) is essential for such signaling and enables cells to change their status in a regenerative manner and to rapidly communicate with one another. Na_Vs were first predicted in squid and were later identified through molecular biology in the electric eel. Since then, these proteins have been discovered in organisms ranging from bacteria to humans. Recent research has succeeded in decoding the amino acid sequences of a wide variety of Na_V family members, as well as the three-dimensional structures of some. These studies and others have uncovered several of the major steps in the functional and structural transition of Na_V proteins that has occurred along the course of the evolutionary history of organisms. Here we present an overview of the molecular evolutionary innovations that established present-day Na_V α subunits and discuss their contribution to the evolutionary changes in animal bodies.

Morphology and Physiology of the Ascidian Nervous Systems and the Effectors

Neurobiology in ascidians has made many advances. Ascidians have offered natural advantages to researchers, including fecundity, structural simplicity, invariant morphology, and fast and stereotyped developmental processes. The researchers have also accumulated on this animal a great deal of knowledge, genomic resources, and modern genetic techniques. A recent connectomic analysis has shown an ultimately resolved image of the larval nervous system, whereas recent applications of live imaging and optogenetics have clarified the functional organization of the juvenile nervous system. Progress in resources and techniques have provided convincing ways to deepen what we have wanted to know about the nervous systems of ascidians. Here, the research history and the current views regarding ascidian nervous systems are summarized.

Cell-cell interaction modulates neuroectodermal specification of embryonic stem cells

The controlled differentiation of embryonic stem (ES) cells is of utmost interest to their clinical, biotechnological, and basic science use. Many investigators have combinatorially assessed the role of specific soluble factors and extracellular matrices in guiding ES cell fate, yet the interaction between neighboring cells in these heterogeneous cultures has been poorly defined due to a lack of conventional tools to specifically uncouple these variables. Herein, we explored the role of cell-cell interactions during neuroectodermal specification of ES cells using a microfabricated cell pair array. We tracked differentiation events in situ, using an ES cell line expressing green fluorescent protein (GFP) under the regulation of the Sox1 gene promoter, an early marker of neuroectodermal germ cell commitment in the adult forebrain. We observed that a previously specified Sox1-GFP+ cell could induce the specification of an undifferentiated ES cell. This induction was modulated by the two cells being in contact and was dependent on the age of previously specified cell prior to coculture. A screen of candidate cell adhesion molecules revealed that the expression of connexin (Cx)-43 correlated with the age-dependent effect of cell contact in cell pair experiments. ES cells deficient in Cx-43 showed aberrant neuroectodermal specification and lineage commitment, highlighting the importance of gap junctional signaling in the development of this germ layer. Moreover, this study demonstrates the integration of microscale culture techniques to explore the biology of ES cells and gain insight into relevant developmental processes otherwise undefined due to bulk culture methods.

Cell contact induces multiple types of electrical excitability from ascidian two-cell embryos that are cleavage arrested and contain all cell fate determinants

Ascidian early embryonic cells undergo cell differentiation without cell cleavage, thus enabling mixture of cell fate determinants in single cells, which will not be possible in mammalian systems. Either cell in a two-cell embryo (2C cell) has multiple fates and develops into any cell types in a tadpole. To find the condition for controlled induction of a specific cell type, cleavage-arrested cell triplets were prepared in various combinations. They were 2C cells in contact with a pair of anterior neuroectoderm cells from eight-cell embryos (2C-aa triplet), with a pair of presumptive notochordal neural cells (2C-AA triplet), with a pair of presumptive posterior epidermal cells (2C-bb triplet), and with a pair of presumptive muscle cells (2C-BB triplet). The fate of the 2C cell was electrophysiologically identified. When two-cell embryos had been fertilized 3 h later than eight-cell embryos and triplets were formed, the 2C cells became either anterior-neuronal, posterior-neuronal or muscle cells, depending on the cell type of the contacting cell pair. When two-cell embryos had been fertilized earlier than eight-cell embryos, most 2C cells became epidermal. When two- and eight-cell embryos had been simultaneously fertilized, the 2C cells became any one of three cell types described above or the epidermal cell type. Differentiation of the ascidian 2C cell into major cell types was reproducibly induced by selecting the type of contacting cell pair and the developmental time difference between the contacting cell pair and 2C cell. We discuss similarities between cleavage-arrested 2C cells and vertebrate embryonic stem cells and propose the ascidian 2C cell as a simple model for toti-potent stem cells.

Ca2+ and Na+ current patterns during oocyte maturation, fertilization, and early developmental stages ofCiona intestinalis

Using the whole-cell voltage clamp technique, the electrical changes in oocyte and embryo plasma membrane were followed during different meiotic and developmental stages in Ciona intestinalis. We show, for the first time, an electrophysiological characterization of the plasma membrane in oocytes at the germinal vesicle (GV) stage with high L-type calcium (Ca2+) current activity that decreased through meiosis. Moreover, the absence of Ca2+ reduced germinal vesicle breakdown (GVBD), which is consistent with a role of Ca2+ currents in the prophase/metaphase transition. In mature oocytes at the metaphase I (MI) stage, Ca2+ currents decreased and then disappeared and sodium (Na+) currents first appeared remaining high up to the zygote stage. Intracellular Ca2+ release was higher in MI than in GV, indicating that Ca2+ currents in GV may contribute to fill the stores which are essential for oocyte contraction at fertilization. The fertilization current generated in Na+ free sea water was significantly lower than the control; furthermore, oocytes fertilized in the absence of Na+ showed high development of anomalous "rosette" embryos. Current amplitudes became negligible in embryos at the 2- and 4-cell stage, suggesting that signaling pathways that mediate first cleavage do not rely on ion current activities. At the 8-cell stage embryo, a resumption of Na+ current activity and conductance occurred, without a correlation with specific blastomeres. Taken together, these results imply: (i) an involvement of L-type Ca2+ currents in meiotic progression from the GV to MI stage; (ii) a role of Na+ currents during electrical events at fertilization and subsequent development; (iii) a major role of plasma membrane permeability and a minor function of specific currents during initial cell line segregation events.

Ion Channel Development, Spontaneous Activity, and Activity-Dependent Development in Nerve and Muscle Cells

At specific stages of development, nerve and muscle cells generate spontaneous electrical activity that is required for normal maturation of intrinsic excitability and synaptic connectivity. The patterns of this spontaneous activity are not simply immature versions of the mature activity, but rather are highly specialized to initiate and control many aspects of neuronal development. The configuration of voltage- and ligand-gated ion channels that are expressed early in development regulate the timing and waveform of this activity. They also regulate Ca2+influx during spontaneous activity, which is the first step in triggering activity-dependent developmental programs. For these reasons, the properties of voltage- and ligand-gated ion channels expressed by developing neurons and muscle cells often differ markedly from those of adult cells. When viewed from this perspective, the reasons for complex patterns of ion channel emergence and regression during development become much clearer.

Roles of Hroth, the ascidian otx gene, in the differentiation of the brain (sensory vesicle) and anterior trunk epidermis in the larval development of Halocynthia roretzi

Otx genes are expressed in the anterior neural tube and endoderm in all of the chordates so far examined. In mouse embryos, important roles of otx genes in the brain development have been well documented. However, roles of otx genes in other chordate species have been less characterized. To advance our understanding about roles of otx genes in chordates, we have studied Hroth, otx of the ascidian, Halocynthia roretzi. Hroth is expressed in the anterior part of the neural tube (the sensory vesicle), the endoderm and anterior epidermis in the development. In this study, we investigated roles of Hroth in the larval development through an antisense morpholino oligonucleotides (MOs) approach. Embryos injected with Hroth-targeting MO (Hroth knockdown embryos) developed into larvae without the adhesive organ, sensory pigment cells and cavity of the sensory vesicle. The tissues, in which defects were observed, are derived from anterior-animal cells of the embryo in early cleavage stages. During cleavage stages, Hroth is also expressed in the endoderm precursors of the vegetal hemisphere. However, Hroth expression in the anterior endoderm precursors do not seem to be essential for the above defects, since MO injection into the anterior-animal but not anterior-vegetal pair cells at the 8-cell stage gave the defects. Analysis of marker gene expression demonstrated that the fate choice of the sensory vesicle precursors and the specification of the sensory vesicle territory occurred normally, but the subsequent differentiation of the sensory vesicle was severely affected in Hroth knockdown embryos. The anterior trunk epidermis including the adhesive organ-forming region was also affected, indicating that anterior epidermal patterning requires Hroth function. Based on these findings, similarities and differences in the roles of otx genes between ascidians and mice are discussed.

Ets-mediated brain induction in embryos of the ascidian Halocynthia roretzi

The larval ascidian brain (sensory vesicle) is located on the dorsal side of the trunk region and forms part of the anterior central nervous system. Sensory organs such as the otolith, ocellus, and hydrostatic-pressure organ reside in the brain. The brain coordinates the core roles of the larval nervous system. The brain is derived from anterior animal a-line blastomeres. The default fate of these blastomeres is epidermis, and the inductive signals from anterior vegetal blastomeres convert the fate into brain. It remains unclear, however, when these inductive interactions take place. To determine when, we examined whether partial embryos derived from brain-lineage blastomeres isolated at various stages express neural and epidermal marker genes. Partial embryos derived from brain-lineage blastomeres isolated after the 32-cell stage expressed all the neural marker genes examined. The expression of the epidermal marker gene was first reduced in partial embryos when blastomeres were isolated at the 64-cell stage. Moreover, the process for brain specification seemed to continue after the 110-cell stage. We also investigated the function of HrEts, an ascidian homolog of Ets transcription factors, to elucidate the molecular mechanism of brain induction. HrEts functions were inhibited by the use of antisense morpholino oligonucleotides. Loss of Ets functions resulted in loss of the expression of some of the neural marker genes and the ectopic expression of the epidermal marker gene in brain precursor cells. These results suggest that HrEts is an essential transcription factor that mediates ascidian brain induction.

Early steps in the formation of neural tissue in ascidian embryos

Ascidians are simple invertebrate chordates whose lineage diverged from that of vertebrates at the base of the chordate tree. Their larvae display a typical chordate body plan, but are composed of a remarkably small number of cells. Ascidians develop with an invariant cell lineage, and their embryos can be easily experimentally manipulated during the cleavage stages. Their larval nervous system is organised in a similar way as in vertebrates but is composed of less than 130 neurones and around 230 glial cells. This remarkable simplicity offers an opportunity to understand, at the cellular and molecular levels, the ontogeny and function of each neural cell. Here, we first review the organisation of the ascidian nervous system and its lineage. We then focus on the current understanding of the processes of neural specification and patterning before and during gastrulation. We discuss these advances in the context of what is currently known in vertebrates.

Ciona intestinalis cDNA projects: expressed sequence tag analyses and gene expression profiles during embryogenesis

Ascidians are primitive chordates. Their fertilized egg develops quickly into a tadpole-type larva, which consists of a small number but distinct types of cells, including those of epidermis, central nervous system with two sensory organs, endoderm and mesenchyme in the trunk, and notochord and muscle in the tail. This configuration of the ascidian tadpole is thought to represent the most simplified and primitive chordate body plan. In addition, the free-swimming and non-feeding larvae metamorphose into sessile and filter-feeding adults. The genome size of Ciona intestinalis is estimated to be about 160 Mb, and the number of genes approximately 15,500. The present Ciona cDNA projects focused on gene expression profiles of fertilized eggs, 32-110-cell stage embryos, tailbud embryos, larvae, and young adults. Expressed sequence tags (ESTs) of the 5'-most end and 3'-most end of more than 3000 clones were determined at each developmental stage, and the clones were categorized into independent clusters using the 3'-end sequences. Nearly 1000 clusters of them were then analyzed in detail of their sequences against a BLASTX search. This analysis demonstrates that, on average, half of the clusters showed proteins with sequence similarities to known proteins and the other half did not show sequence similarities to known proteins. Genes with sequence similarities were further categorized into three major subclasses, depending on their functions. Furthermore, the expression profiles of all of the clusters were analyzed by whole-mount in situ hybridization. This analysis highlights gene expression patterns characteristic to each developmental stage. As a result, the present study provides many new molecular markers for each of the tissues and/or organs that constitutes the Ciona tailbud embryo. This sequence information will be used for further comparative genome studies to explore molecular mechanisms involved in the formation of one of the most primitive chordate body plans. All of the data fully characterized may be viewed at the web site http://ghost.zool.kyoto-u.ac.jp.

Gene expression profiles in tadpole larvae of Ciona intestinalis

A set of 12,779 expressed sequence tags (ESTs), both the 5'-most and 3'-most ends, derived from Ciona intestinalis tadpole larvae was categorized into 3521 independent clusters, from which 1013 clusters corresponding to 9424 clones were randomly selected to analyze genetic information and gene expression profiles. When compared with sequences in databases, 545 of the clusters showed significant matches (P < E-15) with reported proteins, while 153 showed matches with putative proteins for which there is not enough information to categorize their function, and 315 had no significant sequence similarities to known proteins. Sequence-similarity analyses of the 545 clusters in relation to the biological functions demonstrated that 407 of them have functions that many kinds of cells use, 104 are associated with cell-cell communication, and 34 are transcription factors or other gene-regulatory proteins. Sequence prevalence distribution analysis demonstrated that more than one-half of the mRNAs are rare mRNAs. All of the 1013 clusters were subjected to whole-mount in situ hybridization to analyze the gene expression profile in the tadpole larva. A total of 361 clusters showed expression specific to a certain tissue or organ: 96 showed epidermis-specific expression, 60 were specific to the nervous system, 108 to endoderm, 34 to mesenchyme, 5 to trunk lateral cells, 4 to trunk ventral cells, 23 to notochord, 28 to muscle, and 3 to siphon rudiments. In addition, 190 clusters showed expression in multiple tissues. Moreover, nervous system-specific genes showed intriguing expression patterns dependent on the cluster. The present study highlights a broad spectrum of genes that are used in the formation of one of the most primitive chordate body plans as well as for the function of various types of tissue and organ and also provides molecular markers for individual tissues and organs constituting the Ciona larva.

Induction of ascidian peripheral neuron by vegetal blastomeres

Ascidian tadpole larvae have a similar dorsal tubular nervous system as vertebrates. The induction of brain formation from a4.2-derived (a-line) cells requires signals from the A4.1-derived (A-line) cells. However, little is known about the mechanism underlying the development of the larval peripheral nervous system due to the lack of a suitable molecular marker. Gelsolin, an actin-binding protein, is specifically expressed in epidermal sensory neurons (ESNs) that mainly constitute the entire peripheral nervous system of the ascidian young tadpoles. Here, we address the role of cell interactions in the specification of ESNs using immunostaining with an anti-gelsolin antibody. Animal half (a4.2- and b4.2-derived) embryos did not give rise to any gelsolin-positive neurons, indicating that differentiation of ESNs requires signals from vegetal cells. Cell isolation experiments showed that A4.1 blastomeres induce gelsolin-positive neurons from a-line cells but not from b4.2-derived (b-line) cells. On the other hand, B4.1 blastomeres induce gelsolin-positive neurons both from b-line cells and a-line cells. This is in sharp contrast to the specification of brain cells which is not affected by the ablation of B4.1-derived (B-line) cells. Furthermore, basic fibroblast growth factor (bFGF) induced ESNs from the a-line cells and b-line cells in the absence of vegetal cells. Their competence to form ESNs was lost between the 110-cell stage and the neurula stage. Our results suggested that the specification of the a-line cells and b-line cells into ESNs is controlled by distinct inducing signals from the anterior and posterior vegetal blastomeres. ESNs in the trunk appear to be derived from the a8.26 blastomeres aligning on the edge of presumptive neural region where ascidian homologue of Pax3 is expressed. These findings highlight the close similarity of ascidian ESNs development with that of vertebrate placode and neural crest.

Ascidian embryos as a model system to analyze expression and function of developmental genes

Ascidians have served as an appropriate experimental system in developmental biology for more than a century. The fertilized egg develops quickly into a tadpole larva, which consists of a small number of organs including epidermis, central nervous system with two sensory organs, endoderm and mesenchyme in the trunk, and notochord and muscle in the tail. This configuration of the ascidian tadpole is thought to represent the most simplified and primitive chordate body plan. Their embryogenesis is simple, and lineage of embryonic cells is well documented. The ascidian genome contains a basic set of genes with less redundancy compared to the vertebrate genome. Cloning and characterization of developmental genes indicate that each gene is expressed under discrete spatio-temporal pattern within their lineage. In addition, the use of various molecular techniques in the ascidian embryo system highlights its advantages as a future experimental system to explore the molecular mechanisms underlying the expression and function of developmental genes as well as genetic circuitry responsible for the establishment of the basic chordate body plan. This review is aimed to highlight the recent advances in ascidian embryology.

Characterization of heteromultimeric G protein-coupled inwardly rectifying potassium channels of the tunicate tadpole with a unique pore property

Two cDNAs that encode the G protein-coupled inwardly rectifying K(+) channel (GIRK, Kir3) of tunicate tadpoles (tunicate G protein-coupled inwardly rectifying K(+) channel-A and -B; TuGIRK-A and -B) have been isolated. The deduced amino acid sequences showed approximately 60% identity with the mammalian Kir3 family. Detected by whole mount in situ hybridization, both TuGIRK-A and -B were expressed similarly in the neural cells of the head and neck region from the tail bud stage to the young tadpole stage. By co-injecting cRNAs of TuGIRK-A and G protein beta(1)/gamma(2) subunits (Gbetagamma) in Xenopus oocytes, an inwardly rectifying K(+) current was expressed. In contrast, coinjection of TuGIRK-B with Gbetagamma did not express any current. When both TuGIRK-A and -B were coexpressed together with Gbetagamma, an inwardly rectifying K(+) current was also detected. The properties of this current clearly differed from those of TuGIRK-A current, since it displayed a characteristic decline of the macroscopic conductance at strongly hyperpolarized potentials. TuGIRK-A/B current also differed from TuGIRK-A current in terms of the lower sensitivity to the Ba(2+) block, the higher sensitivity to the Cs(+) block, and the smaller single channel conductance. Taken together, we concluded that TuGIRK-A and -B form functional heteromultimeric G protein-coupled inwardly rectifying K(+) channels in the neural cells of the tunicate tadpole. By introducing a mutation of Lys(161) to Thr in TuGIRK-B, TuGIRK-A/B channels acquired a higher sensitivity to the Ba(2+) block and a slightly lower sensitivity to the Cs(+) block, and the decrease in the macroscopic conductance at hyperpolarized potentials was no longer observed. Thus, the differences in the electrophysiological properties between TuGIRK-A and TuGIRK-A/B channels were shown to be, at least partly, due to the presence of Lys(161) at the external mouth of the pore of the TuGIRK-B subunit.

Anteroposterior patterning of the epidermis by inductive influences from the vegetal hemisphere cells in the ascidian embryo

Patterning along the anteroposterior axis is a critical step during animal embryogenesis. Although mechanisms of anteroposterior patterning in the neural tube have been studied in various chordates, little is known about those of the epidermis. To approach this issue, we investigated patterning mechanisms of the epidermis in the ascidian embryo. First we examined expression of homeobox genes (Hrdll-1, Hroth, HrHox-1 and Hrcad) in the epidermis. Hrdll-1 is expressed in the anterior tip of the epidermis that later forms the adhesive papillae, while Hroth is expressed in the anterior part of the trunk epidermis. HrHox-1 and Hrcad are expressed in middle and posterior parts of the epidermis, respectively. These data suggested that the epidermis of the ascidian embryo is patterned anteroposteriorly. In ascidian embryogenesis, the epidermis is exclusively derived from animal hemisphere cells. To investigate regulation of expression of the four homeobox genes in the epidermis by vegetal hemisphere cells, we next performed hemisphere isolation and cell ablation experiments. We showed that removal of the vegetal cells before the late 16-cell stage results in loss of expression of these homeobox genes in the animal hemisphere cells. Expression of Hrdll-1 and Hroth depends on contact with the anterior-vegetal (the A-line) cells, while expression of HrHox-1 and Hrcad requires contact with the posterior-vegetal (the B-line) cells. We also demonstrated that contact with the vegetal cells until the late 32-cell stage is sufficient for animal cells to express Hrdll-1, Hroth and Hrcad, while longer contact is necessary for HrHox-1 expression. Contact with the A-line cells until the late 32-cell stage is also sufficient for formation of the adhesive papillae. Our data indicate that the epidermis of the ascidian embryo is patterned along the anteroposterior axis by multiple inductive influences from the vegetal hemisphere cells and provide the first insight into mechanisms of epidermis patterning in the chordate embryos.

Vegetal cell fate specification and anterior neuroectoderm formation by Hroth, the ascidian homologue of orthodenticle/otx

To obtain insights into the mechanisms of gastrulation and neural tube formation, we studied the function and regulation of expression of Hroth, the ascidian homologue of orthodenticle/otx, during embryogenesis. Microinjection of synthetic Hroth mRNA into fertilized eggs led to embryos with an expanded trunk and a reduced tail. In these embryos, development of notochord and muscle was effected. Also, Hroth overexpression caused ectopic formation of anterior neuroectoderm, along with suppression of epidermis development, even in the absence of cell-cell interaction. Furthermore, we demonstrated that ectodermal expression of Hroth requires an inductive influence from the vegetal hemisphere cells. These data suggest roles of Hroth in both specification of mesoendodermal cells and anterior neuroectoderm formation.

Monitoring early neuronal differentiation by ion channels in ascidian embryos

According to the evolutionary tree proposed by Garstang, the tunicate larva has a central role in directing the ancestral sessile animal derived from primitive echinoderms into the stem for vertebrates by evolution through neoteny. The close similarity of the tunicate larval body plan to those of vertebrates and the extraordinary simplicity indicated by an extremely small cell population make the ascidian embryo and larva an excellent model system for analysis of vertebrate embryonic development. Furthermore, isolated anterior animal blastomeres from the Halocynthia eight-cell cleavage-arrested embryo, which are known to include presumptive brain vesicle region, autonomously develop long-lasting Ca-dependent action potentials which are characteristic of epidermal differentiation. However, when blastometeres are cultured in contact with the anterior vegetal blastomere, which are known to include presumptive notochordal region, and raised in contacted two cell systems, the same anterior animal blastomeres now develop neuronal Na+ spikes characterized by expression of Na+ channels and triethylammonium sensitive delayed rectifier K+ channels. This unique two-cell system enables us to examine roles of cell contact in various aspects of inductive differentiation at the cellular level. In this review, we focus on this simple cellular preparation and in particular, attempt to show how to make the preparation.

Basic fibroblast growth factor induction of neuronal ion channel expression in ascidian ectodermal blastomeres

1. Cleavage-arrested anterior animal (a4-2) blastomeres isolated from eight-cell embryos of Halocynthia aurantium differentiated into neuronal type cells expressing neuron-specific ion channels when they were treated with basic fibroblast growth factor (bFGF). This induction process was very similar to that when a4-2 blastomeres were cultured in contact with anterior vegetal (A4-1) blastomeres from the same embryos or when treated with subtilisin, a serine protease. 2. Other growth factors, transforming growth factor (TGF) beta1, activin A, epidermal growth factor (EGF) and nerve growth factor (NGF), had no effect on the default epidermal differentiation of cleavage-arrested a4-2 blastomeres. 3. Messenger RNA of the ascidian neuronal Na+ channel, TuNa I, was detected using RT-PCR in a4-2-derived partial embryos of Halocynthia aurantium as well as in the cleavage-arrested a4-2 blastomeres treated with bFGF, confirming the neural inducer activity of bFGF during ascidian embryogenesis. 4. bFGF was effective at concentrations as low as 1 ng ml-1 in inducing neuronal ion channels in cleavage-arrested a4-2 blastomeres. EC50 for neuronal differentiation was estimated to be around 8 ng ml-1, and the maximum effect of 90 % neuronalization was obtained with above 100 ng ml-1. 5. For induction of neuronal differentiation, bFGF was required to be continuously present 8 to 14 h after fertilization. A similar time window was required for cell-contact induction, but it was considerably shorter for subtilisin induction. 6. We discuss whether activation of receptor tyrosine kinase is a common pathway for neural induction by bFGF, subtilisin, and cell-contact with A4-1 blastomeres.

Ion channels and early development of neural cells

In this review we underscore the merits of using voltage-dependent ion channels as markers for neuronal differentiation from the early stages of uncommitted embryonic blastomeres. Furthermore, a fairly large part of the review is devoted to the descriptions of the establishment of a simple model system for neural induction derived from the cleavage-arrested eight-cell ascidian embryo by pairing a single ectodermal with a single vegetal blastomere as a competent and an inducer cell, respectively. The descriptions are focused particularly on the early developmental processes of various ion channels in neuronal and other excitable membranes observed in this extraordinarily simple system, and we compare these results with those in other significant and definable systems for neural differentiation. It is stressed that this simple system, for which most of the electronic and optical methods and various injection experiments are applicable, may be useful for future molecular physiological studies on the intracellular process of differentiation of the early embryonic cells. We have also highlighted the importance of suppressive mechanisms for cellular differentiation from the experimental results, such as epidermal commitment of the cleavage-arrested one-cell Halocynthia embryos or suppression of epidermal-specific transcription of inward rectifier channels by neural induction signals. It was suggested that reciprocal suppressive mechanisms at the transcriptional level may be one of the key processes for cellular differentiation, by which exclusivity of cell types is maintained.

Cell fate specification by localized cytoplasmic determinants and cell interactions in ascidian embryos

Tadpole larvae of ascidians show the basic body plan of chordates. An ascidian larva consists of only a few types of cells and has a relatively small number of cells. Cell lineages are invariant among individuals and have been described in detail. These advantages facilitate the analysis of how the fate of each blastomere becomes specified during development. Over a century of research on ascidian embryogenesis has uncovered many interesting features concerning cellular mechanisms responsible for the fate specification. During embryogenesis, the developmental fate of a blastomere is specified by one of three different mechanisms: localized maternal cytoplasmic determinants, inductive interactions, or lateral inhibition in an equivalence cell group.

Ras is an essential component for notochord formation during ascidian embryogenesis

In ascidian embryos, inductive interactions are necessary for the fate specification of notochord cells. Previous studies have shown that notochord induction occurs at the 32-cell stage and that basic fibroblast growth factor (bFGF) has notochord-inducing activity in ascidian embryos. In vertebrate, it is known that bFGF receptors have tyrosine kinase domain and the signaling pathway is mediated by the small-GTP binding protein, Ras. To study the role of Ras in ascidian embryos, we injected dominant negative Ras (RasN17) into fertilized eggs. RasN17 inhibited the formation of notochord, suggesting that the Ras signaling pathway is involved in signal transduction in the induction of notochord cells. When the presumptive-notochord (A6.2) blastomere was co-isolated with the inducer (A6.1) blastomere and then RasN17 was injected into the A6.2 blastomere, notochord differentiation was suppressed. The presumptive-notochord blastomeres injected with RasN17 were treated with bFGF. Many of them failed to develop notochord-specific features. Next, we examined the effect of injecting constitutively active Ras (RasV12) into the A6.2 blastomeres. However, microinjection of RasV12 into these cells did not bypass notochord induction. These results suggest that the Ras signaling pathway is essential for the formation of notochord and that another signaling pathway also must be activated simultaneously in notochord formation during ascidian embryogenesis.

Expression of potassium channels in gerbil outer hair cells during development does not require neural induction

Mammalian outer hair cells (OHCs) contain Ca and K channels in their synaptic pole. We questioned if the ontogeny of potassium currents of OHCs depends on the neural induction of early afferent contact. By recording whole-cell currents of OHCs grown in organotypic cultures deprived of afferent innervation, we show that a Ca-activated K channel is expressed in these cells, suggesting that the ontogeny of the K channel is an intrinsic process.

Neuronal expression in cleavage-arrested ascidian blastomeres requires gap junctional uncoupling from neighbouring cells

1. When anterior-animal (a4-2) blastomeres isolated from 8-cell ascidian embryos were cultured under cleavage-arrested conditions in contact with anterior-vegetal (A4-1) blastomeres (a-A blastomere pairs), the a4-2 blastomeres differentiated into neuronal cells that expressed Na+ and delayed K+ channels at a time when normal sister embryos became tadpole larvae (after 40 developmental hours at 9 degrees C). When a4-2 blastomeres were cultured in contact with posterior-animal (b4-2) blastomeres (a-b blastomere pairs), the a4-2 blastomeres differentiated into epidermal cells expressing Ca2+ channels and tunic on their exterior surface. In these blastomere pairs, we analysed changes in gap junctional communication during neural and epidermal differentiation by using both dye transfer and double voltage clamp. 2. In both types of blastomere pairs, gap junctional communication was detectable at 5 h by double voltage clamp and at 7 h by dye transfer. Gap junctional communication in both types gradually increased until 25 h (equivalent to the neurula stage). However, during 25-35 h (late neurula or tailbud) in the a-A pair it decreased and finally disappeared, while it increased steeply in the a-A pair. When blastomere pairs were treated with a transcription inhibitor, actinomycin D, gap junctional communication also appeared at around 7 h but remained at a plateau level, showing neither a steep increase in a-b pairs nor a disappearance in a-A pairs. 3. In blastomere triplets in which an epidermally committed a4-2 was in contact with both blastomeres of an a-A pair, the epidermally committed a4-2 blastomere did, but the neurally committed a4-2 blastomere did not, communicate through gap junctions with the A4-1 blastomere, indicating that gap junctional communication is restricted when a4-2 blastomeres are neurally committed. 4. When a kinase inhibitor, K252a (0.5-1.0 microM), was applied at 20 h (prior to the disappearance of gap junctional communication), gap junctional communication was maintained in the a-A pair for more than 40 h. The persistence of gap junctional communication delayed the expression of Na+ and K+ channels in the a4-2 blastomere. However, channel expression followed an almost normal time sequence in single neuronally committed a4-2 blastomeres separated from A-a pairs and treated with K252a. 5. We conclude that the persistence of gap junctions causes a delay in expression of neuronal characteristics, and suggest that one of the functional roles of embryonic gap junctions is to time the expression of neuron-specific ion channels and other markers in preneuronal cells.

Neural differentiation in cleavage-arrested ascidian blastomeres induced by a proteolytic enzyme

1. As previously reported, ectodermal a4-2 blastomeres isolated from 8-cell embryos of the ascidian, Halocynthia roretzi or aurantium, and cultured under conditions of cleavage arrest always differentiated into an epidermal phenotype, showing long-lasting Ca(2+)-dependent action potentials and/or tunic on the cell surface. a4-2 blastomeres contacted by a chordamesodermal blastomere, A4-1, differentiated into a neural phenotype, characterized by fast Na(+)-dependent spikes. Differentiation to a similar neural phenotype occurred when isolated a4-2 blastomeres from H. aurantium embryos were treated with > 0.003% subtilisin for 60 min at the 32-cell stage of the control embryo. Comparisons between induction by cell contact and induction by proteolytic enzymes were made and showed them to be similar in several respects. 2. When the serine protease, subtilisin, was used as the neural inducer, neural competence of a4-2 blastomeres, measured as the percentage frequency of the induction of Na+ spikes, increased after the 32-cell stage and decreased during the gastrula stage. The time course of the neural competence was the same as that for contact with the A4-1 blastomere. 3. The neural competence of four different ectodermal blastomeres isolated from the 16-cell embryo was also examined using subtilisin as a neural inducer, and by contact with the A4-1 blastomere from the 8-cell embryo. The competence was higher in anterior blastomeres than in posterior blastomeres for both types of induction. This regional difference in neural competence along the antero-posterior axis paralleled that expected from neural cell lineage during normal development, i.e. blastomeres with more cells of neural lineage among their derivatives showed higher competence. 4. Streptomyces subtilisin inhibitor, SSI (0.1%), a specific protease inhibitor for subtilisin-type serine proteases, significantly suppressed (50%) neural induction of the ectodermal blastomere, a4-2, by contact with the chordamesodermal blastomere, A4-1. 5. Monensin, brefeldin A and bafilomycin A1, all of which affect secretory processes, suppressed the neural inducing ability of the chordamesodermal blastomere, A4-1. 6. These results permit the hypothesis that a protease secreted from the chordamesoderm-generating blastomere induces the ectodermal blastomere to differentiate into neural cell type.

Neural induction suppresses early expression of the inward-rectifier K+ channel in the ascidian blastomere

1. Early expression of ion channels following neural induction was examined in isolated, cleavage-arrested blastomeres from the ascidian embryo using a two-electrode voltage clamp. Currents were recorded from the isolated, cleavage-arrested blastomere, a4-2, after treatment with serine protease, subtilisin, which induces neural differentiation as consistently as cell contact. 2. The inward-rectifier K+ current increased at the late gastrula stage shortly after the sensitive period for neural induction both in the induced (protease-treated) and uninduced cells. Ca2+ channels, characteristic of epidermal-type differentiation, and delayed-rectifier K+ channels and differentiated-type Na+ channels, characteristic of neural-type differentiation appeared much later than the inward-rectifier K+ channels, at a time corresponding to the tail bud stage of the intact embryo. 3. When cells were treated with subtilisin during the critical period for neural induction, the increase in the inward-rectifier K+ current from the late gastrula stage to the neurula stage was about three times smaller (3.67 +/- 1.74 nA, mean +/- S.D., n = 14) than in untreated cells (11.25 +/- 3.10 nA, n = 26). The same changes in the inward-rectifier K+ channel were also observed in a4 2 blastomeres which were induced by cell contact with an A4-1 blastomere. However, when cells were treated with subtilisin after the critical period for neural induction, the amplitude of the inward-rectifier K+ current was the same as in untreated cells. Thus the expressed level of the inward-rectifier K+ channel was linked to the determination of neural or epidermal cell types. 4. There was no significant difference in the input capacitance of induced and uninduced cells, indicating that the difference in the amplitude of the inward-rectifier K+ currents derived from a difference in the channel density rather than a difference in cell surface area. 5. The expression of the inward-rectifier K+ channel at the late gastrula stage was sensitive to alpha-amanitin, a highly specific transcription inhibitor. In both induced and uninduced cells, injection of alpha-amanitin at the 32-cell stage reduced the current density of the inward-rectifier K+ channel to about 2 nA/nF, corresponding to 13% of that recorded from uninjected cells. By contrast, the expression of the fast-inactivating-type Na+ current, which transiently increased along with the inward-rectifier K+ channel, was resistant to alpha-amanitin injection. 6. The dose of alpha-amanitin injected was controlled by monitoring co-injected fluorescent dye, fura-2.(ABSTRACT TRUNCATED AT 400 WORDS)

Developmental potential for tissue differentiation of fully dissociated cells of the ascidian embryo

Initially, each tissue-progenitor blastomere of embryos of the ascidian Halocynthia was identified and isolated manually at the 110-cell (late-blastula) stage, the time at which most of the blastomeres have assumed a particular fate, such that each gives rise to a single type of tissue. The isolates were allowed to develop as partial embryos, then tissue differentiation was examined by monitoring the expression of specific molecular markers for differentiation of epidermis, endoderm, muscle and notochord. Essentially, all of the precursor blastomeres of these four kinds of tissue expressed the appropriate features of tissue differentiation in isolation, indicating that determination is already complete in most of the blastomeres by the 110-cell stage. Next, in order to evaluate the absolute capacity of cells for autonomous development, embryos were maintained continuously in a dissociated state from the first cleavage to the 110-cell stage, then the cells were allowed to develop into partial embryos. Tissue differentiation in the partial embryos was examined. The results showed the striking autonomy of the processes of segregation of developmental potential, as well as the autonomy of the processes of expression of differentiated phenotypes, namely those of epidermis and endoderm. Autonomous muscle differentiation was also observed; however, excess formation of "muscle" partial embryos occurred. The hypothesis that fate determination is mediated by localized maternal information in the egg cytoplasm is supported by the evidence of development of these tissues. By contrast, no evidence of notochord differentiation was observed in the partial embryos.

Developmental changes in delayed rectifier K+ currents in the muscular- and neural-type blastomere of ascidian embryos

1. Developmental changes in the amplitude, kinetic properties, tetraethyl-ammonium (TEA) sensitivity, and ion selectivity of the delayed rectifier K+ currents were investigated in differentiating muscular-type (M) and neural-type (N) blastomeres isolated from the early cleavage-arrested ascidian embryos, using conventional two-microelectrode voltage clamp techniques. 2. No voltage-sensitive outward K+ currents were found in either type of blastomere during the first 35 h of development at 9 degrees C. Thereafter the delayed rectifier K+ current became apparent. The peak amplitude of the K+ current in the M-blastomere increased abruptly from 50 to 60 h and tended to plateau after 60 h, while in the N-blastomere it continued to increase after initial emergence at around 35 h. 3. The threshold potential level of the K+ current in the M-blastomere was initially about -10 mV in a standard external solution (1 mM-K+ solution), but shifted towards the hyperpolarized direction until it reached a steady level at 45 h after fertilization. At the fully differentiated stages, the threshold was around -32 mV and -26 mV in the M- and N-blastomeres, respectively. 4. Throughout development, the reversal potential of the tail current changed with the external K+ concentration in both M- and N-blastomeres as expected for a K(+)-electrode. There was no significant difference in the selectivity ratios for the K+ channel between the two types of blastomeres. The relative selectivities were K+ (1.000): Rb+ (0.774): NH4+ (0.122): Na+ (0.074) and K+ (1.000): Rb+ (0.724): NH4+ (0.155): Na+ (0.074) in the M- and N-blastomeres, respectively. 5. Modified Scatchard plots of TEA-sensitivity data indicated a one-to-one reaction between TEA and the K+ channel. These plots revealed the presence of TEA-resistant K+ channels in addition to TEA-sensitive K+ channels in the M-blastomere, but revealed only TEA-sensitive K+ channels in the N-blastomere. The dissociation constant (Ki) values of these three types of K+ channel did not change during development. In the M-blastomere, the Ki of the TEA-sensitive K+ channel was 1.29 +/- 0.05 mM (mean +/- S.E.M., n = 31) and that of the TEA-resistant K+ channel was 1.4 +/- 0.1 M (mean +/- S.E.M., n = 31) at a test potential of 45 mV. The Ki value of the neural-type K+ current was 1.38 +/- 0.03 mM (mean +/- S.E.M., n = 20) at 45 mV.(ABSTRACT TRUNCATED AT 400 WORDS)

Changes in sodium channels during neural differentiation in the isolated blastomere of the ascidian embryo

1. The current density and the kinetics of voltage-sensitive sodium channels during neural differentiation were examined in the isolated, cleavage-arrested blastomere of ascidian embryos which contains presumptive neural regions. The macroscopic sodium current were measured with the two-microelectrode voltage-clamp technique and the single sodium channel currents were recorded with the patch-clamp technique under the cell-attached configuration. 2. The entire time course of sodium channel development could be divided into three phases from the current density and channel gating properties. 3. In the first phase, from fertilization to about 40 h, the density of the sodium channel current was from 8 to 50 microA cm-2. The channel gating properties were similar to those of the sodium channel in the egg cell except for a negative shift in the voltage dependence of the peak inward current, the steady-state inactivation, and the decay time constant. The sodium channels in this phase were classified as 'type-I' channels. 4. In the second phase (40-60 h after fertilization), the density of the sodium channel current increased from 20 to 800 microA cm-2. The curves of the I-V relationship and of the steady-state inactivation shifted in the positive direction by 5-10 mV. 5. At 45-55 h, when the rate of increase in the sodium current was greatest, as much as 40 microA cm-2 h-1, the decay time course of the sodium current became slowest. The time for the current to decline from the peak to the one-tenth of the peak (t 1/10) increased to about five times that in the first phase. After 55 h t 1/10 gradually decreased. 6. In this phase, steady-state inactivation curves showed two inflexion points at different levels of membrane potential and were fitted with a sum of two Boltzmann distribution curves with distinct parameters. The relative contribution of the component with its voltage dependence shifted in the positive direction tended to decrease with development. 7. On examining single-channel recordings, two types of sodium channel were identified in this phase. One type (type-II) showed frequent repetitions of open-to-shut states throughout a voltage step. The ensemble current of the type-II channel showed a slow decay, suggesting that this type of channel may underlie the markedly slow decay of the macroscopic current in this phase. The second type (type-III) had more late openings than the type-I channel but fewer than the type-II channel.(ABSTRACT TRUNCATED AT 400 WORDS)

Inactivation kinetics of the sodium channel in the egg and the isolated, neurally differentiated blastomere of the ascidian

1. Inactivation kinetics of the sodium channel was compared between the egg-type channel in the egg cell and the differentiated-type channel in the cleavage-arrested, neurally differentiated blastomere of the ascidian. The techniques of the two-microelectrode voltage clamp and the cell-attached patch clamp were used. 2. In both types of channel, the time course of inactivation development obtained with a two-pulse protocol at potentials from -40 to -60 mV could be fitted with two exponentials with distinctive parameters. 3. The time course of recovery from inactivation at potentials more negative than -70 mV was compared between the two types of channel. At -80 to -120 mV, a delay of recovery was evident in the egg-type channel, whereas no delay was observed in the differentiated type. 4. In both types of channel, the two time constants of the inactivation of the macroscopic current, derived from the measurements of inward current, inactivation development and recovery from inactivation, had a bell-shaped voltage dependency. The fast time constants had a peak at -55 mV in the differentiated type and -70 mV in the egg type. The slow time constants had a peak around -60 mV in both types. 5. At the single-channel level, the averaged current from the differentiated-type channel showed both fast and slow decays. The frequency of late openings was higher in the differentiated-type channel than in the egg type. 6. The voltage dependence of the decay time constant and the carried charge in the summed current of the single-channel events was found to be shifted in the negative direction by 10-30 mV, compared with that of the macroscopic current. 7. The possibility that the higher frequency of late openings in the differentiated-type channel might be derived from delayed activation was excluded, since first-latency histograms of the single channel were not significantly different between the two types of channel.

Induced neural-type differentiation in the cleavage-arrested blastomere isolated from early ascidian embryos

1. Isolated blastomeres and pairs of blastomeres from 8-cell embryos of Halocynthia roretzi and Halocynthia aurantium were cleavage-arrested with cytochalasin B and cultured. Their differentiation was examined in terms of membrane excitability, immunoreactivity to an epidermis-specific monoclonal antibody (2C5), and the presence of acetylcholinesterase. 2. The blastomeres that showed epidermal-type differentiation had Ca2(+)-dependent action potentials and membrane currents, and immunoreactivity to 2C5. The blastomeres that showed neural-type differentiation had Na(+)-, Ca2(+)- and TEA-sensitive delayed K+ channels, and lacked immunoreactivity to 2C5. 3. Cleavage-arrested anterior-animal blastomeres, a4-2, when cultured in isolation from an 8-cell embryo, differentiated exclusively into epidermal-type cells. However, when cultured in contact with anterior-vegetal blastomeres, A4-1, they mostly showed neural-type differentiation (seventeen out of twenty-four cells in H. roretzi). 4. Reduction of the cytochalasin B concentration enhanced neural-type development of a4-2 blastomeres in contact with A4-1 blastomeres in H. aurantium, possibly by tightening the physical contact between the blastomeres. 5. When a cleavage-arrested and isolated a4-2 blastomere was treated with 2% pronase at 10 degrees C for 15 min at the time when sister control embryos reached the 32-cell stage, the blastomere underwent neural-type differentiation in a manner identical to that of a4-2 blastomeres contacted by A4-1 cells. 6. The period during which neural-type differentiation of a4-2 blastomeres could be induced by treatment with pronase was from the 8-cell to the 110-cell stage. At the late gastrula stage neural-type differentiation of a4-2 blastomeres was not induced by pronase. The effective period for neural-type differentiation of a4-2 blastomeres in contact with A4-1 cells was between the 64-cell stage and late gastrula stage. Competence of the a4-2 blastomere to undergo neural-type differentiation decreased during gastrula stages, while the inducing ability of the A4-1 blastomere lasted longer. 7. In a few cases the posterior-animal blastomere, b4-2, could also be induced to undergo neural-type differentiation after contact with A4-1 cells or after pronase treatment. 8. The appearance of Na+ spikes in a4-2 blastomeres in contact with A4-1 cells was considered a manifestation of neural induction, similar in principle to the induction of ectoderm by the chorda-mesoderm in higher vertebrates.

Giant Drosophila neurons differentiated from cytokinesis-arrested embryonic neuroblasts

The relative contributions of the intrinsic and extrinsic factors in determining neuronal differentiation are not fully understood yet. We found that isolated neuroblasts from Drosophila gastrulae were able to differentiate neuron-specific properties in culture even when cell divisions were inhibited. The resultant giant multinucleated neurons displayed thickened neurites with a variety of distinct branching patterns. Neuronal antigens were expressed as in normal cultured neurons, and action potentials could be evoked by current injection within two days after plating. These results indicate that the factors for initiating specific differentiation programs for basic neuronal form and function are present in a neuroblast already. The cells of increased sizes in this culture system are more accessible to physiological and cell biological analyses and could facilitate future studies of the Drosophila nervous system.

A voltage-dependent chloride current linked to the cell cycle in ascidian embryos

A voltage-dependent chloride current has been found in early ascidian embryos that is a minor conductance in the oocyte and in interphase blastomeres but that increases transiently in amplitude by more than tenfold during each cell division. Repeated cycles in the density of this chloride current could be recorded for up to 6 hours (four cycles) in cleavage-arrested embryos, whether they were activated by sperm or calcium ionophore. These data suggest that there is a direct link between the cell cycle clock and the properties of this channel, a link that results in pronounced cyclical changes in the electrical properties of early blastomeres.