Biological validation that SF3b is a target of the antitumor macrolide pladienolide.

Pladienolide is a naturally occurring macrolide that binds to the SF3b complex to inhibit mRNA splicing. It has not been fully validated whether the splicing impairment is a relevant mechanism for the potent antitumor activity of pladienolide. We established pladienolide-resistant clones from WiDr and DLD1 colorectal cancer cells that were insensitive to the inhibitory action of pladienolide on cell proliferation and splicing. An mRNA-Seq differential analysis revealed that these two cell lines have an identical mutation at Arg1074 in the gene for SF3B1, which encodes a subunit of the SF3b complex. Reverse expression of the mutant protein transferred pladienolide resistance to WiDr cells. Furthermore, immunoprecipitation analysis using a radiolabeled probe showed that the mutation impaired the binding affinity of paldienolide to its target. These results clearly demonstrate that pladienolide exerts its potent activity by targeting SF3b and also suggest that inhibition of SF3b is a promising drug target for anticancer therapy.

Early zygotic expression of transcription factors and signal molecules in fully dissociated embryonic cells of Ciona intestinalis: A microarray analysis.

Specification of early embryonic cells of animals is established by maternally provided factors and interactions of neighboring cells. The present study addressed a question of autonomous versus non-autonomous specification of embryonic cells by using the Ciona intestinalis embryo, in particular the genetic cascade of zygotic expression of transcription factor genes responsible for notochord specification. To examine this issue, we combined the classic experiment of continuous dissociation of embryonic cells with the modern technique of oligonucleotide-based microarrays. We measured early zygotic expression of 389 core transcription factors genes and 118 major signal molecule genes in embryonic cells that were fully dissociated from the first cleavage. Our results indicated that even if cells are free from contact with neighbors, the major transcription factor genes that have primary roles in embryonic cell specification commence their zygotic expression at the same time as in normal embryos. Dissociation of embryonic cells did not affect extracellular signal-regulated kinases (ERK) activity. Although normal embryos treated with U0126 failed to express Bra and Twist-like-1, dissociated embryonic cells treated with U0126 expressed the genes. These results are discussed in relation to the grade of autonomous versus non-autonomous genetic cascades that are responsible for the specification of early Ciona embryonic cells.

Genome-wide network of regulatory genes for construction of a chordate embryo.

Animal development is controlled by gene regulation networks that are composed of sequence-specific transcription factors (TF) and cell signaling molecules (ST). Although housekeeping genes have been reported to show clustering in the animal genomes, whether the genes comprising a given regulatory network are physically clustered on a chromosome is uncertain. We examined this question in the present study. Ascidians are the closest living relatives of vertebrates, and their tadpole-type larva represents the basic body plan of chordates. The Ciona intestinalis genome contains 390 core TF genes and 119 major ST genes. Previous gene disruption assays led to the formulation of a basic chordate embryonic blueprint, based on over 3000 genetic interactions among 79 zygotic regulatory genes. Here, we mapped the regulatory genes, including all 79 regulatory genes, on the 14 pairs of Ciona chromosomes by fluorescent in situ hybridization (FISH). Chromosomal localization of upstream and downstream regulatory genes demonstrates that the components of coherent developmental gene networks are evenly distributed over the 14 chromosomes. Thus, this study provides the first comprehensive evidence that the physical clustering of regulatory genes, or their target genes, is not relevant for the genome-wide control of gene expression during development.

Microarray analysis of zygotic expression of transcription factor genes and cell signaling molecule genes in early Ciona intestinalis embryos.

In ascidians, specification of embryonic cells takes place very early at the 16-, 32- and 64-cell stages, and this developmental event involves zygotic expression of various genes, some encoding transcription factors and some encoding cell signaling molecules. Previous studies have demonstrated that approximately 50 transcription factor genes and 25 signaling molecule genes commence their zygotic expression by the 64-cell stage of Ciona intestinalis embryos. With the aid of oligonucleotide-based microarray, we examined the zygotic expression profiles of developmental genes in early Ciona embryos. Although the microarray method had a tendency to barely detect zygotic expression of genes that are expressed maternally, the present results confirmed the results of previous studies. In addition, the present analysis demonstrated the zygotic expression of four genes that were not identified in previous studies, and this result was confirmed by whole-mount in situ hybridization. Our results therefore provide further information on the developmental genes that are zygotically expressed in early Ciona embryos, and demonstrate that the microarray is a powerful tool for future studies of the gene regulatory network in Ciona, a basal chordate with a body plan similar to that of vertebrates.

Genomic overview of mRNA 5'-leader trans-splicing in the ascidian Ciona intestinalis.

Although spliced leader (SL) trans-splicing in the chordates was discovered in the tunicate Ciona intestinalis there has been no genomic overview analysis of the extent of trans-splicing or the make-up of the trans-spliced and non-trans-spliced gene populations of this model organism. Here we report such an analysis for Ciona based on the oligo-capping full-length cDNA approach. We randomly sampled 2078 5'-full-length ESTs representing 668 genes, or 4.2% of the entire genome. Our results indicate that Ciona contains a single major SL, which is efficiently trans-spliced to mRNAs transcribed from a specific set of genes representing approximately 50% of the total number of expressed genes, and that individual trans-spliced mRNA species are, on average, 2-3-fold less abundant than non-trans-spliced mRNA species. Our results also identify a relationship between trans-splicing status and gene functional classification; ribosomal protein genes fall predominantly into the non-trans-spliced category. In addition, our data provide the first evidence for the occurrence of polycistronic transcription in Ciona. An interesting feature of the Ciona polycistronic transcription units is that the great majority entirely lack intercistronic sequences.

Chromosomal mapping of 170 BAC clones in the ascidian Ciona intestinalis.

The draft genome ( approximately 160 Mb) of the urochordate ascidian Ciona intestinalis has been sequenced by the whole-genome shotgun method and should provide important insights into the origin and evolution of chordates as well as vertebrates. However, because this genomic data has not yet been mapped onto chromosomes, important biological questions including regulation of gene expression at the genome-wide level cannot yet be addressed. Here, we report the molecular cytogenetic characterization of all 14 pairs of C. intestinalis chromosomes, as well as initial large-scale mapping of genomic sequences onto chromosomes by fluorescent in situ hybridization (FISH). Two-color FISH using 170 bacterial artificial chromosome (BAC) clones and construction of joined scaffolds using paired BAC end sequences allowed for mapping of up to 65% of the deduced 117-Mb nonrepetitive sequence onto chromosomes. This map lays the foundation for future studies of the protochordate C. intestinalis genome at the chromosomal level.

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.