De novo discovery of a tissue-specific gene regulatory module in a chordate.

We engage the experimental and computational challenges of de novo regulatory module discovery in a complex and largely unstudied metazoan genome. Our analysis is based on the comprehensive characterization of regulatory elements of 20 muscle genes in the chordate, Ciona savignyi. Three independent types of data we generate contribute to the characterization of a muscle-specific regulatory module: (1) Positive elements (PEs), short sequences sufficient for strong muscle expression that are identified in a high-resolution in vivo analysis; (2) CisModules (CMs), candidate regulatory modules defined by clusters of overrepresented motifs predicted de novo; and (3) Conserved elements (CEs), short noncoding sequences of strong conservation between C. savignyi and C. intestinalis. We estimate the accuracy of the computational predictions by an analysis of the intersection of these data. As final biological validation of the discovered muscle regulatory module, we implement a novel algorithm to search the genome for instances of the module and identify seven novel enhancers.

Ci-Tbx6b and Ci-Tbx6c are key mediators of the maternal effect gene Ci-macho1 in muscle cell differentiation in Ciona intestinalis embryos.

Maternally deposited mRNA encoding the Zic family zinc-finger protein Ci-macho1 is a determinant responsible for muscle cell differentiation in Ciona intestinalis embryos. In a previous study, we identified possible Ci-macho1 downstream genes, which include seven transcription factor genes and seven signaling molecule genes (Yagi, K., Satoh, N., Satou, Y., 2004. Identification of downstream genes of the ascidian muscle determinant gene Ci-macho1. Dev. Biol. 274, 478-489), suggesting complex Ci-macho1 downstream cascades. Here, we show that of the Ci-macho1 downstream genes, only Ci-Tbx6b and Ci-Tbx6c promote ectopic differentiation of muscle cells when misexpressed in non-muscle blastomeres. Overexpression of Ci-Tbx6b or Ci-Tbx6c in Ci-macho1 knockdown embryos is able to compensate for the functional loss of Ci-macho1 and promote differentiation of muscle cells. In addition, we show that knockdown of each of Ci-Tbx6b or Ci-Tbx6c suppresses the initiation of muscle protein gene expression, and both gene products appear to recognize a similar binding sequence. However, later expression of muscle protein genes at the tailbud stage is only reduced in Ci-Tbx6b knockdown embryos and undisturbed in Ci-Tbx6c knockdown embryos. Although ectopic expression or knockdown of Ci-ZicL alone does not affect muscle cell differentiation, simultaneous knockdown of Ci-Tbx6b, Ci-Tbx6c, and Ci-ZicL completely abolishes muscle cell differentiation, as in the case of knockdown of Ci-macho1 and Ci-ZicL. These results strongly suggest that muscle cell differentiation in Ciona embryos is controlled by four key factors: maternal macho1 and zygotic Tbx6b, Tbx6c, and ZicL. The two T-box genes are primary mediators of macho1 function, and cooperation between the zygotically expressed transcription factors is indispensable for muscle cell differentiation in Ciona embryos.

Identification of downstream genes of the ascidian muscle determinant gene Ci-macho1.

Autonomous differentiation of primary muscle cells in ascidian embryos is triggered by a maternal determinant recently identified as the macho-1 gene. macho-1 encodes a transcription factor of the Zic family with five C2H2 zinc-finger motifs. In the present study, we firstly performed a screen, using a quantitative PCR method, of genes encoding transcription factors and components in major signaling pathways to identify those regulated downstream of Ci-macho1 in early embryos of Ciona intestinalis. The amount of transcripts for a total of 64 genes was altered at the 32-cell stage depending on the Ci-macho1 activity level. Whole-mount in situ hybridization assays revealed that the alteration of expression for at least 13 of them was adequately visualized to confirm the results of quantitative PCR. Second, we determined a possible binding sequence of Ciona macho1. macho1 recombinant proteins of both C. intestinalis and Ciona savignyi recognized a sequence, 5'-GCCCCCCGCTG-3', that resembles the mammalian Zic binding site. In addition, most of the genes identified as potential Ci-macho1 downstream genes, in particular Ci-Tbx6b and Ci-snail, possessed plausible Ci-macho1-binding sequences in their 5' upstream region, suggesting their direct activation by Ci-macho1. Furthermore, some of the genes including three Wnt genes noted in the quantitative analyses implied that Ci-macho1 is involved in the differentiation of endoderm and mesenchyme via intracellular communications.

Gene expression profiles of transcription factors and signaling molecules in the ascidian embryo: towards a comprehensive understanding of gene networks.

Achieving a real understanding of animal development obviously requires a comprehensive rather than partial identification of the genes working in each developmental process. Recent decoding of genome sequences will enable us to perform such studies. An ascidian, Ciona intestinalis, one of the animals whose genome has been sequenced, is a chordate sharing a basic body plan with vertebrates, although its genome contains less paralogs than are usually seen in vertebrates. In the present study, we discuss the genomewide approach to networks of developmental genes in Ciona embryos. We focus on transcription factor genes and some major groups of signal transduction genes. These genes are comprehensively listed and examined with regard to their embryonic expression by in situ hybridization (http://ghost.zool.kyoto-u.ac.jp/tfst.html). The results revealed that 74% of the transcription factor genes are expressed maternally and that 56% of the genes are zygotically expressed during embryogenesis. Of these, 34% of the transcription factor genes are expressed both maternally and zygotically. The number of zygotically expressed transcription factor genes increases gradually during embryogenesis. As an example, and taking advantage of this comprehensive description of gene expression profiles, we identified transcription factor genes and signal transduction genes that are expressed at the early gastrula stage and that work downstream of beta-catenin, FoxD and/or Fgf9/16/20. Because these three genes are essential for ascidian endomesoderm specification, transcription factor genes and signal transduction genes involved in each of the downstream processes can be deduced comprehensively using the present approach.

A zinc finger transcription factor, ZicL, is a direct activator of Brachyury in the notochord specification of Ciona intestinalis.

In ascidian embryos, Brachyury is expressed exclusively in blastomeres of the notochord lineage and play an essential role in the notochord cell differentiation. The genetic cascade leading to the transcriptional activation of Brachyury in A-line notochord cells of Ciona embryos begins with maternally provided beta-catenin, which is essential for endodermal cell specification. beta-catenin directly activates zygotic expression of a forkhead transcription factor gene, FoxD, at the 16-cell stage, which in turn somehow activates a zinc finger transcription factor gene, ZicL, at the 32-cell stage, and then Brachyury at the 64-cell stage. One of the key questions to be answered is whether ZicL functions as a direct activator of Brachyury transcription, and this was addressed in the present study. A fusion protein was constructed in which a zinc finger domain of Ciona ZicL was connected to the C-terminus of GST. Extensive series of PCR-assisted binding site selection assays and electrophoretic mobility shift assays demonstrated that the most plausible recognition sequence of Ciona ZicL was CCCGCTGTG. We found the elements CACAGCTGG (complementary sequence: CCAGCTGTG) at -123 and CCAGCTGTG at -168 bp upstream of the putative transcription start site of Ci-Bra in a previously identified basal enhancer of this gene. In vitro binding assays indicated that the ZicL fusion protein binds to these elements efficiently. A fusion gene construct in which lacZ was fused with the upstream sequence of Ci-Bra showed the reporter gene expression exclusively in notochord cells when the construct was introduced into fertilized eggs. In contrast, fusion constructs with mutated ZicL-binding-elements failed to show the reporter expression. In addition, suppression of Ci-ZicL abolished the reporter gene expression, while ectopic and/or overexpression of Ci-ZicL resulted in ectopic reporter expression in non-notochord cells. These results provide evidence that ZicL directly activates Brachyury, leading to specification and subsequent differentiation of notochord cells.

Neural expression of the Huntington's disease gene as a chordate evolutionary novelty.

Huntington's disease is a progressive neuro-degenerative disorder in humans, which is scharacterized by onset of dementia, muscular ataxia, and death. Huntington's disease is caused by the expansion of the polyglutamine (polyQ) tract in the N-terminus of the HD protein (Huntingtin). CAG expansion is a dominant gain of function mutation that affects striated neurons in the brain (Cattaneo, 2003, News Physiol Sci 18:34). The evolutionary origins of the vertebrate Hd gene are not well understood. In order to address the evolutionary history of the Hd gene, we have cloned and characterized the expression of the Hd gene in two invertebrate deuterostomes, an echinoderm and an ascidian, and have examined the expression patterns in a phylogenetic context. Echinoderms are basal deuterostomes and ascidians are basal chordates; both are useful for understanding the origins of and evolutionary trends in genes important in vertebrates such as the Huntigton's disease gene. Expression of Hd RNA is detected at all stages of development in both the echinoderm and ascidian studied. In the echinoderm Heliocidaris erythrogramma, Hd is expressed in coelomic mesodermal tissue derivatives, but not in the central nervous system. In the ascidian Halocynthia roretzi expression is located in both mesoderm and nervous tissue. We suggest that the primitive deuterostome expression pattern is not neural. Thus, neural expression of the Hd gene in deuterostomes may be a novel feature of the chordate lineage, and the original role(s) of HD in deuterostomes may have been non-neural.

A genomewide survey of developmentally relevant genes in Ciona intestinalis. III. Genes for Fox, ETS, nuclear receptors and NFkappaB.

A survey against the draft genome sequence and the cDNA/EST database of Ciona intestinalis identified a number of genes encoding transcription factors regulating a variety of processes including development. In the present study, we describe almost complete sets of genes for Fox, ETS-domain transcription factors, nuclear receptors, and NFkappaB as well as other factors regulating NFkappaB activity, with their phylogenetic nature. Vertebrate Fox transcription factors are currently delineated into 17 subfamilies: FoxA to FoxQ. The present survey yielded 29 genes of this family in the Ciona genome, 24 of which were Ciona orthologues of known Fox genes. In addition, we found 15 ETS genes, 17 nuclear receptor genes, and several NFkappaB signaling pathway genes in the Ciona genome. The number of Ciona genes in each family is much smaller than that of vertebrates, which represents a simplified feature of the ascidian genome. For example, humans have two NFkappaB genes, three Rel genes, and five NFAT genes, while Ciona has one gene for each family. The Ciona genome also contains smaller numbers of genes for the NFkappaB regulatory system, i.e. after the split of ascidians/vertebrates, vertebrates evolved a more complex NFkappaB system. The present results therefore provide molecular information for the investigation of complex developmental processes, and an insight into chordate evolution.

A genomewide survey of developmentally relevant genes in Ciona intestinalis. VI. Genes for Wnt, TGFbeta, Hedgehog and JAK/STAT signaling pathways.

Cell-cell interactions play important roles in a variety of developmental processes, and therefore molecules involved in the signaling pathways have been studied extensively. Recently, the draft genome sequence of the basal chordate, Ciona intestinalis, was determined. Here we annotated genes for the signaling pathways of Wnt, transforming growth factor beta (TGFbeta), Hedgehog, and JAK/STAT in the genome of Ciona intestinalis. The Ciona genome contains ten wnt genes, six frizzled genes, four sFRP genes, ten TGFbeta family member genes, five TGFbeta-receptor genes, and five Smad genes; most of the genes were found with less redundancy than in vertebrate genomes. The other genes in the signaling pathways are present as a single copy in the Ciona genome. In addition, all of the identified genes for the signaling pathway, except for a few genes, have EST evidence, and their cDNAs are available from the Ciona intestinalis gene collection. Therefore, Ciona intestinalis may provide an experimental system for exploring the basic genetic cascade associated with the signaling pathways in chordates.

A cDNA resource from the basal chordate Ciona intestinalis.

The genome of the basal choradate Ciona intestinalis contains a basic set of genes with less redundancy compared to the vertebrate genome. Extensive EST analyses, cDNA sequencing, and clustering yielded "Ciona intestinalis Gene Collection Release 1," which contains cDNA clones for 13,464 genes, covering nearly 85% of the Ciona mRNA species. This release is ready for use in cDNA cloning, micro/macroarray analysis, and other comprehensive genome-wide analyses for further molecular studies of basal chordates.

Neural marker genes differently expressed in subsets of embryonic neural cells of the ascidian Halocynthia roretzi.

Ascidians are lower chordates that possess a possible prototype of the vertebrate nervous system. The central and peripheral nervous systems of ascidian larvae are composed of only a few hundred cells (Nicol and Meinertzhagen, 1991). To investigate how these ascidian nervous systems develop, dissection at the molecular level using subset-specific markers is essential. Here we describe four new genes zygotically expressed in subsets of the ascidian neural cells. The spatial expression domains of these genes overlap in some parts but not in other parts of the nervous systems. Our results suggest that there are functionally different regions in the nervous systems owing to the gene expression differences. Further analyses of these genes will enable us to determine the molecular neuro-developmental characteristics of various clusters of neural cells.

Retinoic acid differently affects the formation of palps and surrounding neurons in the ascidian tadpole.

The anterior-most surface of the ascidian tadpole larvae is composed of specialized complex structures, including adhesive organs (palps) and the surrounding sensory neurons (RTENs) connected to neurons inside the palps. These are derived from a-line blastomeres by inductive effects from A-line blastomeres. The induction is reported to coordinate the expression of homeobox genes in the anterior epidermis, which can be affected by all- trans retinoic acid (RA). RA treatment also results in failure of the morphological formation of palps. Here we first isolated a gene intensely expressed in the cells of the anterior structure from the time of their lineage restriction, and then found that the RA treatment did not affect the specific gene expression in the presumptive palp cells but did affect that in the RTENs. These results suggest that the palp formation involves at least two different processes, a RA-insensitive cell-type specification process and a RA-sensitive morphogenetic process. RA treatment also affects the morphogenetic process of the palp formation and also disturbs the precise patterning of the surrounding epidermis, which may contribute to the regulation of RTEN development.

macho-1-Related genes in Ciona embryos.

In ascidians, maternal factor(s) localized in the myoplasm of the egg are essential for specification and subsequent differentiation of larval muscle cells. The macho-1 gene of Halocynthia roretzi encodes a zinc-finger protein: the gene is only expressed maternally, the resultant maternal mRNA is localized to the myoplasm, and the gene function is essential for muscle cell differentiation. Here we have characterized macho-1 homologues, Ci-macho1 of Ciona intestinalis and Cs-macho1 of Ciona savignyi. Interestingly, we found that the Ciona macho-1 genes are expressed both maternally and zygotically: their maternal transcript is localized to the myoplasm while their zygotic expression is seen after neurulation in cells of the central nervous system. Functional suppression of Cs-macho1 with morpholino antisense oligonucleotide resulted in inhibition of the initiation of zygotic expression of a muscle-specific actin gene. We propose a possible evolutionary scenario in which an ancestral Zic-related gene gave rise to both the macho-1-like muscle determinant gene as well as neuronal Zic genes.

Radiosensitization by overexpression of the nonphosphorylation form of IkappaB-alpha in human glioma cells.

To assess the role of NF-kappaB in cellular radiosensitivity, we constructed mutated IkappaB expression plasmids for SY-IkappaB (with mutations at residues of 32, 36 and 42) expression in human malignant glioma cells (radiosensitive MO54 and radioresistant T98 cells), giving respective cell types referred to as MO54-SY4 and T98-SY14. Both of the clones expressing SY-IkappaB became radiosensitive, compared with the parental MO54 and T98 cells. A treatment with herbimycin A or genistein did not change the radiosensitivity of cells expressing SY-IkappaB, but made both the MO54 and T98 parental cells more sensitive to ionizing radiation. A treatment with TNF-alpha induced DNA fragmentation and apoptosis in cells expressing SY-IkappaB, but not in MO54 and T98 cells. The survival after X-ray exposure of the parental MO54 cells was slightly increased by a TNF-alpha treatment, but that of the parental T98 cells did not change. The change in sensitivity to ultra-violet (UV) radiation and adriamycin in MO54-SY4 cells was very similar to that for X-ray sensitivity, but no change was observed in T98-SY14 cells. Significant sublethal damage repair was observed in T98 cells, whereas MO54 cells showed little repair activity. The expression of p53 was enhanced in the parental MO54 cells, while the p53 levels in the MO54-SY4, and in the parent and clonal T98 cells, did not change. Our data suggest that the serine and tyrosine phosphorylation of IkappaB-alpha may play a role in determining the radiosensitivity of malignant glioma cells.