Genomic- and protein-based approaches for connectin (titin) identification in the ascidian Ciona intestinalis

Determining the complete primary structure of large proteins is difficult because of the large sequence size and low sequence homology among animals, as is the case with connectin (titin)-like proteins in invertebrate muscles. Conventionally, large proteins have been investigated using immuno-screenings and plaque hybridization screenings that require significant time and labor. Recently, however, the genomic sequences of various invertebrates have been determined, leading to changes in the strategies used to elucidate the complete primary structures of large proteins. In this paper, we describe our methods for determining the sequences of large proteins by elucidating the primary structure of connectin from the ascidian Ciona intestinalis as an example. We searched for genes that encode connectin-like proteins in the C. intestinalis genome using the BLAST search program. Subsequently, we identified some domains present in connectin and connectin-like proteins, such as immunoglobulin (Ig), fibronectin type 3 (Fn) and kinase domains in C. intestinalis using the SMART program and manual estimation. The existence of these domains and the unique sequences between each domain were confirmed using RT-PCR. We also examined the localization of mRNA using whole-mount in situ hybridization (WISH) and protein expression using SDS-PAGE. These analyses indicate that the domain structure and molecular weight of ascidian connectin are similar to those of vertebrate connectin and that ascidian connectin is also expressed in heart muscle, similarly to vertebrate connectin. The methods described in this study can be used to determine the primary structures of large proteins, such as novel connectin-like proteins in invertebrates.     

Gene expression profile during the life cycle of the urochordate Ciona intestinalis

Recent whole-genome studies and in-depth expressed sequence tag (EST) analyses have identified most of the developmentally relevant genes in the urochordate, Ciona intestinalis. In this study, we made use of a large-scale oligo-DNA microarray to further investigate and identify genes with specific or correlated expression profiles, and we report global gene expression profiles for about 66% of all the C. intestinalis genes that are expressed during its life cycle. We succeeded in categorizing the data set into 5 large clusters and 49 sub-clusters based on the expression profile of each gene. This revealed the higher order of gene expression profiles during the developmental and aging stages. Furthermore, a combined analysis of microarray data with the EST database revealed the gene groups that were expressed at a specific stage or in a specific organ of the adult. This study provides insights into the complex structure of ascidian gene expression, identifies co-expressed gene groups and marker genes and makes predictions for the biological roles of many uncharacterized genes. This large-scale oligo-DNA microarray for C. intestinalis should facilitate the understanding of global gene expression and gene networks during the development and aging of a basal chordate.     

cDNA microarray analyses reveal candidate marker genes for the detection of ascidian disease in Korea

A serious disease of the ascidian Halocynthia roretzi has been spread extensively among Korean aquaculture sites. To reveal the cause of the disease and establish a monitoring system for it, we constructed a cDNA microarray spotted with 2,688 cDNAs derived from H. roretzi hemocyte cDNA libraries to detect genes differentially expressed in hemocytes between diseased and non-diseased ascidians. We detected 21 genes showing increased expression and 16 genes showing decreased expression in hemocytes from diseased ascidians compared with those from non-diseased ascidians. RT-PCR analyses confirmed that the expression levels of genes encoding astacin, lysozyme, ribosomal protein PO, and ubiquitin-ribosomal protein L40e fusion protein were increased in hemocytes from diseased ascidians, while those of genes encoding HSP40, HSP70, fibronectin, carboxypeptidase and lactate dehydrogenase were decreased. These genes were expressed not only in hemocytes but also in various other tissues in ascidians. Furthermore, the expression of glutathione-S transferase omega, which is known to be up-regulated in H. roretzi hemocytes during inflammatory responses, was strongly increased in hemocytes from diseased ascidians. These gene expression profiles suggest that immune and inflammatory reactions occur in the hemocytes of diseased ascidians. These genes will be good markers for detecting and monitoring this disease of ascidians in Korean aquaculture sites.     

Expression cloning in ascidians: isolation of a novel member of the asctacin protease family

The small genome size and gene number of ascidians makes them an ideal model system in which to screen for conserved genes that regulate the development of chordates. Expression cloning has proven to be an effective strategy for isolating genes that play a role in embryogenesis. We have taken advantage of the large size and ease of manipulation of Xenopus embryos for use as an assay system to screen for developmental regulatory genes from the ascidian Ciona intestinalis. Many invertebrate genes have been shown to function in vertebrates, providing us with precedent for our cross-species analysis. The first clone isolated from this screen is an astacin class metalloprotease. This ascidian astacin, named no va, causes a gastrulation defect in Xenopus. In C. intestinalis, no va is expressed both maternally and zygotically. The zygotic expression is seen in the mesenchyme of gastrula and neurula staged embryos.     

Characterization of Brachyury-downstream notochord genes in the Ciona intestinalis embryo

The notochord has two major roles during chordate embryogenesis, as a source of inductive signals for the patterning of neural tube and paraxial mesoderm and as a supportive organ of the larval tail. Despite the recent identification of mutations that affect the notochord development in vertebrate embryos, little is known about genes that are expressed in the differentiating notochord itself. In the urochordate ascidian Ciona intestinalis, Brachyury (Ci-Bra) plays a key role in notochord differentiation. In a previous study, we isolated cDNA clones for nearly 40 potential Ci-Bra target genes that are expressed in notochord cells (H. Takahashi et al., 1999, Genes Dev. 13, 1519-1523). Here we characterized 20 of them by determining the complete nucleotide sequences of the cDNAs. These genes encode a broad spectrum of divergent proteins associated with notochord formation and function. Two genes encode ascidian homologs of the Drosophila Prickle LIM domain proteins and another encodes the ERM protein, all 3 of which appear to be involved in the control of cytoskeletal architecture. In addition, genes for netrin, leprecan, cdc45, ATP:citrate lyase, ATP sulfurylase/APS kinase, protein tyrosine phosphatase, beta4-galactosyltransferase, fibrinogen-like protein, divergent tropomyosin-like proteins, and Drosophila Pellino-like protein were identified. The observation of the netrin gene expression in the notochord may provide the first molecular evidence that the ascidian notochord is a source of signals as in vertebrates. In addition, the present information should be used to identify nonchordate deuterostome tissues homologous to the notochord as well as genes which are expressed in the notochord cells of vertebrate embryos.