Minos transposon causes germline transgenesis of the ascidian Ciona savignyi

An ascidian, Ciona savignyi, is regarded as a good experimental animal for genetics because of its small and compact genome for which a draft sequence is available, its short generation time and its interesting phylogenic position. ENU-based mutagenesis has been carried out using this animal. However, insertional mutagenesis using transposable elements (transposons) has not yet been introduced. Recently, one of the Tc1/mariner superfamily transposons, Minos, was demonstrated to cause germline transgenesis in the related species Ciona intestinalis. In this report, we show that Minos has the ability to transpose from DNA to DNA in Ciona savignyi in transposition assays. Although the activity was slightly weaker than in Ciona intestinalis, Minos still caused germline transgenesis in Ciona savignyi. In addition, one insertion seemed to have caused an enhancer trapping. These results indicate that Minos provides a potential tool for transgenic techniques such as insertional mutagenesis in Ciona savignyi.     

An enhancer trap in the ascidian Ciona intestinalis identifies enhancers of its Musashi orthologous gene

The enhancer trap technique, established in Drosophila melanogaster, is a very sophisticated tool. Despite its usefulness, however, there have been very few reports on enhancer traps in other animals. The ascidian Ciona intestinalis, a splendid experimental system for developmental biology, provides good material for developmental genetics. Recently, germline transgenesis of C. intestinalis has been achieved using the Tc1/mariner superfamily transposon Minos. During the course of that study, one Minos insertion line that showed a different GFP expression pattern from other lines was isolated. One fascinating possibility is that an enhancer trap event occurred in this line. Here we show that a Minos insertion in the Ci-Musashi gene was responsible for the altered GFP expression. Ci-Musashi showed a similar expression pattern to GFP. In addition, introns of Ci-Musashi have enhancer activity that can alter the expression pattern of nearby genes to resemble that of GFP in this line. These results clearly demonstrate that an enhancer trap event that entrapped enhancers of Ci-Musashi occurred in C. intestinalis.     

Tail morphogenesis in the ascidian, Ciona intestinalis, requires cooperation between notochord and muscle

We present evidence that notochord and muscle differentiation are crucial for morphogenesis of the ascidian tail. We developed a novel approach for embryological manipulation of the developing larval tissues using a simple method to introduce DNA into Ciona intestinalis and the several available tissue-specific promoters. With such promoters, we misexpressed the Xenopus homeobox gene bix in notochord or muscle of Ciona embryos as a means of interfering with development of these tissues. Ciona embryos expressing bix in the notochord from the 64-cell stage develop into larvae with very short tails, in which the notochord precursors fail to intercalate and differentiate. Larvae with mosaic expression of bix have intermediate phenotypes, in which a partial notochord is formed by the precursor cells that did not receive the transgene while the precursors that express the transgene cluster together and fail to undergo any of the cell-shape changes associated with notochord differentiation. Muscle cells adjacent to differentiated notochord cells are properly patterned, while those next to the notochord precursor cells transformed by bix exhibit various patterning defects. In these embryos, the neural tube extends in the tail to form a nerve cord, while the endodermal strand fails to enter the tail region. Similarly, expression of bix in muscle progenitors impairs differentiation of muscle cells, and as a result, notochord cells fail to undergo normal extension movements. Hence, these larvae have a shorter tail, due to a block in the elongation of the notochord. Taken together, these observations suggest that tail formation in ascidian larvae requires not only signaling from notochord to muscle cells, but also a "retrograde" signal from muscle cells to notochord.     

Identification of cis elements which direct the localization of maternal mRNAs to the posterior pole of ascidian embryos

During ascidian embryogenesis, some mRNAs show clear localization at the posterior-most region. These postplasmic mRNAs are divided into two groups (type I and type II) according to their pattern of localization. To elucidate how these localization patterns are achieved, we attempted to identify the localization elements of these mRNAs. When in vitro synthesized postplasmic mRNAs were introduced into eggs, these mRNAs showed posterior localization similar to the endogenous mRNAs. The posterior localization of these mRNAs was mediated by their 3' untranslated regions (3' UTRs), as is the case for several localized Drosophila and Xenopus mRNAs. We identified smaller fragments of the 3' UTRs of HrWnt-5 and HrPOPK-1 mRNAs (type I) and HrPet-3 mRNA (type II) that were sufficient to direct green fluorescent protein mRNA to the posterior pole. For the localization of HrWnt-5 mRNA, two UG dinucleotide repetitive elements were essential. Motifs similar to these small elements also exist within the HrPOPK-1 mRNA localization element and 3' UTR of HrZF-1 mRNA, suggesting the conservation of localization elements among type I mRNAs. In contrast, the smallest sequence that suffices for the posterior localization of HrPet-3 (a type II mRNA) has different features from those of type I mRNAs; indeed, it does not have an identifiable critical element. This difference may distinguish type II mRNAs from type I mRNAs. These findings, especially the identification of the small localization element of HrWnt-5 mRNA, provide new insights into the localization of mRNAs during ascidian embryogenesis.     

Localization and expression pattern of type I postplasmic mRNAs in embryos of the ascidian Halocynthia roretzi

The posterior-vegetal cytoplasm (PVC) of fertilized ascidian eggs plays important roles in embryo development. It has been reported that some maternal RNAs are localized to the PVC. We identified four novel type I postplasmic mRNAs that are localized to the PVC through the use of data from a cDNA project of maternal mRNAs in the eggs of Halocynthia roretzi (MAGEST database). The mRNAs are HrGLUT, HrPEN-1, and HrPEM-3, which show similarity to a glucose transporter, a g1-related protein, and Ciona pem-3, respectively; and HrPEN-2, with no similarity. Maternal mRNAs of all four genes were identically localized to the PVC after ooplasmic segregation. During cleavage, they were concentrated in the centrosome-attracting body (CAB) and were then segregated into the small blastomeres located at the posterior pole. This localization pattern is common to all known type I postplasmic mRNAs found so far. HrGLUT, HrPEN-1, and HrPEM-3 were expressed zygotically in various tissues later in embryogenesis: HrGLUT and HrPEM-3 in the mesenchyme and nervous system, and HrPEN-1 in the ectodermal cells.     

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.     

Local database and the search program for proteomic analysis of sperm proteins in the ascidian Ciona intestinalis

Separation of proteins by two-dimensional electrophoresis and following mass spectrometry (MS) is now a conventional technique for proteomic analysis. For proteomic analysis of a certain tissue with a limited information of primary structures of proteins, we have developed an analytical system for peptide mass fingerprinting in gene products in the testis of the ascidian Ciona intestinalis. Ciona sperm proteins were separated by two-dimensional gel electrophoresis and the tryptic fragments were subjected to MALDI-TOF/MS. The mass pattern was searched against on-line databases but resulted in less identification of these proteins. We have constructed a MS database from Ciona testis ESTs and the genome draft sequence, along with a newly devised, perl-based search program PerMS for peptide mass fingerprinting. This system could identify more than 80% of Ciona sperm proteins, suggesting that it could be widely applied for proteomic analysis for a limited tissue with less genomic information.     

Isolation and characterization of beta-catenin downstream genes in early embryos of the ascidian Ciona savignyi

Nuclear localization of beta-catenin is most likely the first step of embryonic axis formation or embryonic cell specification in a wide variety of animal groups. Therefore, the elucidation of beta-catenin target genes is a key research subject in understanding the molecular mechanisms of the early embryogenesis of animals. In Ciona savignyi embryos, nuclear accumulation of beta-catenin is the first step of endodermal cell specification. Previous subtractive hybridization screens of mRNAs between beta-catenin-overexpressed embryos and nuclear beta-catenin-depleted embryos have resulted in the identification of beta-catenin downstream genes in Ciona embryos. In the present study, I characterize seven additional beta-catenin downstream genes, Cs-cadherinII, Cs-protocadherin, Cs-Eph, Cs-betaCD1, Cs-netrin, Cs-frizzled3/6, and Cs-lefty/antivin. All of these genes were expressed in vegetal blastomeres between the 16-cell and 110-cell stages, although their spatial and temporal expression patterns were different from one another. In situ hybridizations and real-time PCR revealed that the expression of all of these genes was up-regulated in beta-catenin-overexpressed embryos, and down-regulated in beta-catenin-suppressed embryos. Therefore, the accumulation of beta-catenin in the nuclei of vegetal blastomeres activates various vegetally expressed genes with potentially important functions in the specification of these cells.     

Characterization of a maternal T-Box gene in Ciona intestinalis

A new T-box gene, CiVegTR, was isolated in the ascidian Ciona intestinalis. CiVegTR maternal RNAs become localized to the vegetal cytoplasm of fertilized eggs and are incorporated into muscle lineages derived from the B4.1 blastomere. The CiVegTR protein binds to specific sequences within a minimal, 262-bp enhancer that mediates Ci-snail expression in the tail muscles. Mutations in these binding sites abolish expression from an otherwise normal lacZ reporter gene in electroporated embryos. In addition to the previously identified AC-core E-box sequences, T-box recognition sequences are conserved in the promoter regions of many genes expressed in B4.1 lineages in both Ciona and the distantly related ascidian Halocynthia. These results suggest that CiVegTR encodes a component of the classical muscle determinant that was first identified in ascidians nearly 100 years ago.