High-throughput enhancer trap by remobilization of transposon Minos in Ciona intestinalis

The enhancer trap approach utilizing transposons yields us information about gene functions and gene expression patterns. In the ascidian Ciona intestinalis, transposon-based transgenesis and insertional mutagenesis were achieved with a Tc1/mariner transposon Minos. We report development of a novel technique for enhancer trap in C. intestinalis. This technique uses remobilization of Minos in the Ciona genome. A Minos vector for enhancer trap was constructed and a tandem array insertion of the vector was introduced into the Ciona genome to create a mutator line. Minos was remobilized in Ciona chromosomes to create new insertions by providing transposases. These transposase-introduced animals were crossed with wild-type animals. Nearly 80% of F1 families showed novel GFP expression patterns. This high-throughput enhancer trap screen will be useful to create new marker transgenic lines showing reporter gene expression in specific tissues and to identify novel patterns of gene expression.     

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.     

Transposon mediated transgenesis in a marine invertebrate chordate: <Emphasis Type="Italic">Ciona intestinalis</Emphasis>

Achievement of transposon mediated germline transgenesis in a basal chordate, Ciona intestinalis, is discussed. A Tc1/mariner superfamily transposon, Minos, has excision and transposition activities in Ciona. Minos enables the creation of stable transgenic lines, enhancer detection, and insertional mutagenesis.     

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.     

Generation of Ci-Brachyury-GFP stable transgenic lines in the ascidian Ciona savignyi

We report generation of stable transgenic lines of the ascidian Ciona savignyi carrying a Ciona intestinalis-Brachyury-promoter/Green Fluorescent Protein-reporter (Ci-Bra-GFP) construct. The transgenic lines were made using a technique in which the endonuclease I-SceI was coinjected into fertilized eggs with a transgene construct containing flanking recognition sites for I-SceI. Two founder animals, out of 12 F(0) adults tested, were found to transmit the transgene to their offspring (F(1)s) at frequencies of 42% and 23%. The transgene was further inherited by the F(2) in a Mendelian fashion and displayed nonmosaic expression, indicating integration into the genome. The Mendelian inheritance and the absence of mosaicism persisted through the F(3) and F(4) generations. Southern blot analyses showed that the transgene was organized in tandem arrays of no more than 10 copies. Using these Ci-Bra-GFP transgenics, we describe cellular movements and shape changes involved in notochord morphogenesis in both wildtype and mutant embryos.     

A Rapid Protocol for Integrating Extrachromosomal Arrays With High Transmission Rate into the C. elegans Genome

Microinjecting DNA into the cytoplasm of the syncytial gonad of Caenorhabditis elegans is the main technique used to establish transgenic lines that exhibit partial and variable transmission rates of extrachromosomal arrays to the next generation. In addition, transgenic animals are mosaic and express the transgene in a variable number of cells. Extrachromosomal arrays can be integrated into the C. elegans genome using UV irradiation to establish nonmosaic transgenic strains with 100% transmission rate of the transgene. To that extent, F1 progenies of UV irradiated transgenic animals are screened for animals carrying a heterozygous integration of the transgene, which leads to a 75% Mendelian transmission rate to the F2 progeny. One of the challenges of this method is to distinguish between the percentage of transgene transmission in a population before (X% transgenic animals) and after integration (≥75% transgenic F2 animals). Thus, this method requires choosing a nonintegrated transgenic line with a percentage of transgenic animals that is significantly lower than the Mendelian segregation of 75%. Consequently, nonintegrated transgenic lines with an extrachromosomal array transmission rate to the next generation ≤60% are usually preferred for integration, and transgene integration in highly transmitting strains is difficult. Here we show that the efficiency of extrachromosomal arrays integration into the genome is increased when using highly transmitting transgenic lines (≥80%). The described protocol allows for easy selection of several independent lines with homozygous transgene integration into the genome after UV irradiation of transgenic worms exhibiting a high rate of extrachromosomal array transmission. Furthermore, this method is quite fast and low material consuming. The possibility of rapidly generating different lines that express a particular integrated transgene is of great interest for studies focusing on gene expression pattern and regulation, protein localization, and overexpression, as well as for the development of subcellular markers.     

Optimized conditions for transgenesis of the ascidian Ciona using square wave electroporation

The protochordate Ciona has recently become an important model organism for the study of developmental gene regulation, in part because transient transgenic embryos can be produced rapidly and reliably using electroporation. Published methods are currently for the use of electroporation devices delivering exponentially decaying pulses. However, some workers have advocated the use of square wave electroporation devices for eukaryotic transgenics. This paper presents results of experiments to find optimal conditions for the use of square-wave electroporation in the ascidian Ciona. In the present analysis, a single pulse of 90 msec duration at 63–75 V/cm was found to give an optimal balance of a high proportion of cells transformed with the transgene, and a low level of abnormal development. Forty micrograms of DNA per electroporation is sufficient for effective visualization of reporter gene expression, although doses up to 100 μg provide higher proportions of transformed cells. In side-by-side comparison with exponential pulse electroporation, square wave pulses give similar penetrance of transgene expression, along with lower proportions of embryos with abnormal development at higher amounts of input DNA.     

Construction of BAC libraries derived from the ascidian Ciona intestinalis

Large insert genomic bacterial artificial chromosome (BAC) libraries were constructed from a basal chordate, the ascidian Ciona intestinalis. Insert analyses of randomly selected clones indicated that in the first library the mean insert size was 135 kb and predicted a 15-fold coverage of the Ciona genome, and in the second library the mean insert size was 165 kb and predicted a 5-fold coverage of the genome. These first large insert genomic libraries of the ascidian should increase the speed of genomic analyses of basal chordates.     

FISH analysis of 142 EGFP transgene integration sites into the mouse genome

Production of transgenic animals is an important technique for studying various biological processes. However, whether the integration of a particular transgene occurs randomly in the mouse genome has not been determined. Analysis by fluorescence in situ hybridization of the integration sites of the 142 EGFP (a mutant of green fluorescent protein) transgenic lines that we produced showed that the transgenes had become incorporated into every mouse chromosome. A single integration site was observed in 82.4% of the lines. The concomitant integrations of transgene into two different loci were observed in 15 cases (10.6%). In 3 cases, the transgenic founder mice showed chimerism in integration sites (2.1%). Chromosomal translocation was observed in 7 cases (4.9%). Moreover, when we statistically analyzed the transgene integration sites of these mouse lines, they were shown to distribute unevenly throughout the genome. This is the first report to analyze the transgene integration sites by producing more than 100 transgenic mouse lines.     

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.     

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.     

Establishment of enhancer detection lines expressing GFP in the gut of the ascidian Ciona intestinalis

The gut is a tubular, endodermal organ for digesting food and absorbing nutrients. In this study, we characterized eight enhancer detection lines that express green fluorescent protein (GFP) in the whole or part of the digestive tube of the ascidian Ciona intestinalis. Three enhancer detection lines for the pyloric gland, a structure associated with the digestive tube, were also analyzed. These lines are valuable markers for analyzing the mechanisms of development of the gut. Based on the GFP expression of the enhancer detection lines together with morphological characteristics, the digestive tube of Ciona can be subdivided into at least 10 compartments in which different genetic cascades operate. Causal insertion sites of the enhancer detection lines were identified, and the expression pattern of the genes near the insertion sites were characterized by means of whole-mount in situ hybridization. We have characterized four and two genes that were specifically or strongly expressed in the digestive tube and pyloric gland, respectively. The present data provide the basic information and useful resources for studying gut formation in Ciona.     

High Efficiency Production of germ-line Transgenic Japanese Medaka (Oryzias latipes) by Electroporation with Direct Current-shifted Radio Frequency Pulses

Although there have been several studies showing the production of transgenic fish through electroporation techniques, success rates have been low and few studies show germ-line integration and expression. When electroporation has been successful, the device used is no longer commercially available. The goal of this experiment was to find an alternative efficient method of generating transgenic Japanese medaka (Oryzias latipes) using a commercially available electroporation device. The Gene Pulser II and RF module (Bio-Rad Laboratories, USA), along with two reporter gene constructs, were used. In contrast to other electroporation devices, which are based on a single pulse with exponential decay or square wave technology, the Gene Pulser II incorporates a direct current (DC)-shifted radio frequency (RF) signal. With this technique, over 1000 embryos can be electroporated in less than 30 min. The plasmid pCMV-SPORT--gal (Invitrogen, USA) was used in the supercoiled form to optimize parameters for gene transfer into single-celled embryos, and resulted in up to 100% somatic gene transfer. Similar conditions were used to generate fish transgenic for both the pCMV-EGFP plasmid (Clontech, USA) and a cytomegalovirus (CMV) driven phytase-EGFP construct. The conditions used were a voltage of 25 V, a percent modulation of 100%, a radio frequency of 35 kHz, a burst duration of 10 ms, 3 bursts, and a burst interval of 1.0 s. Seventy percent of the embryos electroporated with the pCMV-EGFP construct survived to sexual maturity, and of those, 85% were capable of passing the transgene on to their offspring. Transgenic second generation back-crossed (BC₂) fry were subjected to Southern blot analysis, which confirmed germ-line integration, and observation for green fluorescence protein, which confirmed protein expression. DC-shifted RF pulses are effective and efficient in the production of transgenic medaka, and germ-line integration and expression can be achieved without linearization of the transgene vector.     

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.     

Molecular cytogenetic characterization of Ciona intestinalis chromosomes

The compact genome of the ascidian Ciona intestinalis has been sequenced. Chromosome karyotype and mapping of the genome sequence information on each of the 14 pairs of chromosomes are essential for genome-wide studies of gene expression and function in this basal chordate. Although the small chromosome size (most pairs measuring less than 2 mum) complicates accurate chromosome pairing based on morphology alone, the present results suggest that 20 chromosomes are metacentric and 8 are submetacentric or subtelocentric, and two pairs of large chromosomes (#1 and #2) were defined. The characterization of chromosomes by FISH and staining with propidium iodide indicated that 18S/28S ribosomal gene repeats are present in the short arms of three pairs of chromosomes and that the short arms of these pairs show remarkable size polymorphism. In addition, each chromosome was characterized molecular cytogenetically by mapping representative BAC clones with FISH. The present study is therefore a first step in expanding the karyotype analysis and entire physical mapping of the genome sequence of Ciona intestinalis.