A genomewide survey of developmentally relevant genes in Ciona intestinalis. V. Genes for receptor tyrosine kinase pathway and Notch signaling pathway

In the present survey, we identified most of the genes involved in the receptor tyrosine kinase (RTK), mitogen activated protein kinase (MAPK) and Notch signaling pathways in the draft genome sequence of Ciona intestinalis, a basal chordate. Compared to vertebrates, most of the genes found in the Ciona genome had fewer paralogues, although several genes including ephrin, Eph and fringe appeared to have multiplied or duplicated independently in the ascidian genome. In contrast, some genes including kit/flt, PDGF and Trk receptor tyrosine kinases were not found in the present survey, suggesting that these genes are innovations in the vertebrate lineage or lost in the ascidian lineage. The gene set identified in the present analysis provides an insight into genes for the RTK, MAPK and Notch signaling pathways in the ancient chordate genome and thereby how chordates evolved these signaling pathway.     

A genomewide survey of developmentally relevant genes in Ciona intestinalis. VII. Molecules involved in the regulation of cell polarity and actin dynamics

In the present study, genes involved in the pathways that establish cell polarity and cascades regulating actin dynamics were identified in the completely sequenced genome of Ciona intestinalis, a basal chordate. It was revealed that the Ciona genome contains orthologous genes of each component of aPKC-Par and PCP pathways and WASP/WAVE/SCAR and ADF/cofilin cascades, with less redundancy than the vertebrate genomes, suggesting that the conserved pathways/cascades function in Ciona development. In addition, the present study found that the orthologous proteins of five gene groups (Tc10, WRCH, RhoD, PLC-L, and PSKH) are conserved in humans and Ciona but not in Drosophila melanogaster, suggesting a similarity in the gene composition of Ciona to that of vertebrates. Ciona intestinalis, therefore, may provide refined clues for the study of vertebrate development and evolution.     

A genome-wide survey of genes for enzymes involved in pigment synthesis in an ascidian, Ciona intestinalis

The draft genome sequence and a large quantity of EST and cDNA information are now available for the ascidian Ciona intestinalis. In the present study, genes involved in pigment synthesis pathways were identified in the decoded genome of Ciona, and information about these genes was obtained from available EST and cDNA sequences. It was found that the Ciona genome contains orthologous genes for each enzyme of the melanin, pteridine, ommochrome, papiliochrome, and heme synthesis pathways. Several appear as independent duplications in the Ciona genome. Because cDNA clones for all but two of these genes have already been isolated by the cDNA project, C. intestinalis will provide an experimental system to explore molecular mechanisms underlying color patterns, through future genome-wide studies.     

A comprehensive survey of cadherin superfamily gene expression patterns in Ciona intestinalis

We have carried out a comprehensive survey of the spatiotemporal expression of cadherin superfamily genes in the basal chordate Ciona intestinalis, as an example of a genome-wide expression study of a gene family directly regulating cellular processes in morphogenesis. We found 15 definitely expressed cadherin superfamily genes in the Ciona intestinalis genome. Up to the late gastrula stage, all identified delta-protocadherins and the type II classical cadherin, but not other subfamily members, were zygotically expressed. At later stages, however, all cadherin superfamily genes were expressed in the nervous system. These data are useful for understanding the role of these genes in Ciona development and the evolution of chordates.     

A genomewide survey of developmentally relevant genes in Ciona intestinalis. VIII. Genes for PI3K signaling and cell cycle

Cell growth and cell divisions are two fundamental biological processes for cells in multi-cellular organisms. The molecules involved in these biological processes are highly conserved within eukaryotes, including plants and unicellular organisms such as yeast. However, some regulatory molecules seem to be innovated during animal evolution. Therefore, to understand how the ubiquitous systems have evolved or have been conserved, we examined genes for the phosphoinositide 3-kinase (PI3K) pathway that is important for cell growth, and genes for cell cycle regulation in the genome of Ciona intestinalis. It was found that the Ciona intestinalis genome contains all the essential constituents of the PI3K pathway. In addition, the class IB PI3K catalytic and regulatory subunits, which had not previously been known in animals other than mammals, were found in the Ciona genome. Similarly, all essential cyclins and CDKs were found in the Ciona genome, while cyclin G and cyclin L were likely to be independently lost in the ascidian lineage, which may be dispensable for the cell cycle. Cyclin F, which was previously known only in vertebrates, was not found in the Ciona genome. Therefore, this gene was probably innovated during the evolution of vertebrates to be involved in vertebrate-specific cell cycle regulation. Since Ciona is regarded as one of the most primitive extant chordates, the present analysis gives us an insight into how these fundamental biological genes are evolved or are conserved during chordate evolution.     

A genomewide survey of developmentally relevant genes in Ciona intestinalis. X. Genes for cell junctions and extracellular matrix

Cell junctions and the extracellular matrix (ECM) are crucial components in intercellular communication. These systems are thought to have become highly diversified during the course of vertebrate evolution. In the present study, we have examined whether the ancestral chordate already had such vertebrate systems for intercellular communication, for which we have searched the genome of the ascidian Ciona intestinalis. From this molecular perspective, the Ciona genome contains genes that encode protein components of tight junctions, hemidesmosomes and connexin-based gap junctions, as well as of adherens junctions and focal adhesions, but it does not have those for desmosomes. The latter omission is curious, and the ascidian type-I cadherins may represent an ancestral form of the vertebrate type-I cadherins and desmosomal cadherins, while Ci-Plakin may represent an ancestral protein of the vertebrate desmoplakins and plectins. If this is the case, then ascidians may have retained ancestral desmosome-like structures, as suggested by previous electron-microscopic observations. In addition, ECM genes that have been regarded as vertebrate-specific were also found in the Ciona genome. These results suggest that the last common ancestor shared by ascidians and vertebrates, the ancestor of the entire chordate clade, had essentially the same systems of cell junctions as those in extant vertebrates. However, the number of such genes for each family in the Ciona genome is far smaller than that in vertebrate genomes. In vertebrates these ancestral cell junctions appear to have evolved into more diverse, and possibly more complex, forms, compared with those in their urochordate siblings.     

Large-scale characterization of genes specific to the larval nervous system in the ascidian Ciona intestinalis

The central and peripheral nervous systems (CNS and PNS) of the ascidian tadpole larva are comparatively simple, consisting of only about 350 cells. However, studies of the expression of neural patterning genes have demonstrated overall similarity between the ascidian CNS and the vertebrate CNS, suggesting that the ascidian CNS is sufficiently complex to be relevant to those of vertebrates. Recent progress in the Ciona intestinalis genome project and cDNA project together with considerable EST information has made Ciona an ideal model for investigating molecular mechanisms underlying the formation and function of the chordate nervous system. Here, we characterized 56 genes specific to the nervous system by determining their full-length cDNA sequences and confirming their spatial expression patterns. These genes included those that function in the nervous systems of other animals, especially those involved in photoreceptor-mediated signaling and neurotransmitter release. Thus, the nervous system-specific genes in Ciona larvae will provide not only probes for determining their function but also clues for exploring the complex network of nervous system-specific genes.     

Fluorescent in situ hybridization to ascidian chromosomes

The draft genome of the ascidian Ciona intestinalis has been sequenced. Mapping of the genome sequence to the Ciona 14 haploid chromosomes is essential for future studies of the genome-wide control of gene expression in this basal chordate. Here we describe an efficient protocol for fluorescent in situ hybridization for mapping genes to the Ciona chromosomes. We demonstrate how the locations of two BAC clones can be mapped relative to each other. We also show that this method is efficient for coupling two so-far independent scaffolds into one longer scaffold when two BAC clones represent sequences located at either end of the two scaffolds.     

Direct examination of chromosomal clustering of organ-specific genes in the chordate Ciona intestinalis

One of challenges in the field of developmental biology is to understand how spatially and/or temporally coordinated expression of genes is controlled at the chromosomal level. It remains controversial whether genes expressed in a given tissue are randomly distributed throughout a given animal genome, or instead resolve into clusters. Here we used microarray analysis to identify more than 1,700 genes that are expressed preferentially in each of 11 organs of the chordate Ciona intestinalis adult, and determined the location of these genes on the 14 pairs of Ciona chromosomes. In spite of extensive mapped gene analysis, we only confirmed small clusters containing two or three genes. Our result indicates that organ-specific genes are distributed rather evenly all over chromosomes, suggesting that the notion of clustering of organ-specific genes in animal genomes is not generally applicable to this chordate.     

Ascidians as a vertebrate-like model organism for physiological studies of Rho GTPase signaling

GTPases of the Rho family are evolutionarily conserved proteins that control cell shape dynamics during physiological processes as diverse as cell migration and polarity, axon outgrowth and guidance, apoptosis and phagocytosis. In mammals, 18 Rho proteins are distributed in 7 subfamilies. Rho, Rac and Cdc42 are the best-characterized ones, benefiting from the use of worm and drosophila, which only express these 3 subfamilies. An additional model would therefore help understand the physiological role of other mammalian subfamilies. We identified in genome databases the complete Rho family of two ascidians, Ciona intestinalis and Ciona savignyi, and showed that these families contain single ancestors of most mammalian Rho subfamilies. In Ciona intestinalis, all Rho genes are expressed and display specific developmental variations of mRNA expression during tadpole formation. Although C. intestinalis expresses five additional Rac compared to the closely related Ciona savignyi, only two appeared fully active in functional assays. Last, we identified in Ciona intestinalis database more than 50 Rho regulators (RhoGEFs and RhoGAPs) and 20 effector targets, whose analysis further supports the notion that Rho signaling components are of comparable complexity in mammals and ascidians. Since the tadpole of ascidians combines vertebrate-like developmental features with reduced cell number, particularly adapted to evolutionary and developmental biology studies, our data advocate this model for physiological studies of Rho signaling pathways.     

Mitogenomics reveals two cryptic species in Ciona intestinalis

Individual mitochondrial genes or genomic features are commonly used as phylogenetic markers at many taxonomic levels. We used a mitogenomics approach to demonstrate the existence of two cryptic species in the ascidian Ciona intestinalis, a model chordate whose status as a single species has recently been questioned. Comprehensive comparative analysis of the mitochondrial genome of the two cryptic species revealed significant differences in gene order, size and number of noncoding regions, compositional features and divergence of protein-coding genes.     

Three insulin-relaxin-like genes in Ciona intestinalis

The Ciona intestinalis genome harbors three insulin-like genes: INS-L1, -L2 and -L3. Conserved synteny between the Ciona-human genomes predicts that Ciona INS-Ls are orthologous to the vertebrate insulin-relaxin family, but this relation cannot be inferred from molecular phylogeny. A conserved protein core with six cysteines; typical arrangement of B-, C- and A-protein domains; pro-protein maturation mode; and putative insulin receptor-binding sites were identified in Ciona INS-L proteins. ESTs used to assemble exonic sequences of INS-Ls combined with qRT-PCR analysis provided evidence that the predicted genes are expressed in the developing and adult Ciona. Our results support that Ciona INS-L1 is orthologous to the vertebrate insulin-like/relaxin genes, INS-L2 to insulin genes and INS-L3 to IGF genes. Our analysis also implies that the insulin-like/relaxin ancestor switched receptor type from tyrosine kinase- to GPCR-type, whereas insulin-IGF subfamily retained the tyrosine kinase-type of receptor. We propose that this receptor-switch occurred after the time when urochordates branched from the common chordate lineage, but before the two genome-duplications at the root of the vertebrates.