RIKEN BioResource Center Research Articles

The Transcription Factor Runx3 Represses the Neurotrophin Receptor TrkB during Lineage Commitment of Dorsal Root Ganglion Neurons

Runx3, a Runt domain transcription factor, determines neurotrophin receptor phenotype in dorsal root ganglion (DRG) neurons. Molecular mechanisms by which Runx3 controls distinct neurotrophin receptors are largely unknown. Here, we show that RUNX3 abolished mRNA induction of TRKB expression, and concomitantly altered the neurotrophin response in a differentiating neuroblastoma cell line. In contrast, RUNX3 did not play a significant role in TRKC regulation even under the relevant BMP signaling pathway. We identified putative regulatory elements of Ntrk2/NTRK2 (a gene that codes for TrkB) using an unbiased computational approach. One of these elements was a highly conserved intronic sequence that contains a cluster of Runx binding sites. In a primary culture of DRG neurons, endogenous Runx3 bound to the consensus cluster, which had repressor activity against the Ntrk2 promoter under the control of NT-3 signaling. Consistent with these findings, Runx3-deficient embryos showed an increased number of trkB+ DRG neurons and failed to maintain trkC expression. Taken together, Runx3 determines TrkC positive sensory neuron identities through the transcriptional repression of TrkB when Trk-BTrkC double positive neurons differentiate into TrkC single positive neurons.

Essential role for gene profiling analysis in the authentication of human cell lines

Cross-contamination between cultured cell lines can result in the generation of erroneous scientific data. Hence, it is very important to eliminate cell lines that are of an origin different from that being claimed. Inter-species contamination can be detected by various established methods, such as karyotype and isozyme analyses. However, it has been impossible to detect intraspecies cross-contamination prior to the development of technology to detect differences between cell lines at the molecular level. Recently, profiling of short tandem repeat (STR) polymorphisms has been established as a method for the analyses of gene polymorphism. Gene profiling by STR polymorphism (STR profiling) is a simple and reliable method to identify individual cell lines. Each human cell line currently provided by the Cell Engineering Division of the RIKEN BioResource Center was analyzed by STR profiling to authenticate its identity. We found that more than 10 human cell lines out of approximately 400 were in fact identical to a different cell line deposited in the collection, and therefore had been misidentified. We conclude that STR profiling is a useful and powerful method for eliminating cell lines that have been misidentified by cross-contamination or by other causes. Hence, STR profiling of human cell lines used in published research will likely be a prerequisite for publication in the future, so that the problem of misidentification of cell lines can be eliminated.

A Resource of 5,814 Dissociation Transposon-tagged and Sequence-indexed Lines of Arabidopsis Transposed from Start Loci on Chromosome 5

We report here the generation of an additional collection of Dissociation (Ds) transposon-tagged, sequence-indexed lines of Arabidopsis thaliana. Our RIKEN Ds insertion collection now totals 17,668 lines. Our collection has preferential insertions in chromosomes 1 and 5, because Ds was transposed from start loci on those chromosomes (11,854 and 5,814 lines, respectively). We describe here features of the latter 5,814 lines. The former 11,854 lines have been described previously. We have created a searchable database of the insertion sites and mutated genes (http://rarge.gsc.riken.jp/), and are depositing these lines in the RIKEN BioResource Center (http://www.brc.riken.go.jp/lab/epd/Eng/). Our collection of these mutants will contribute to progress in functional genomics of plants.

A database of recombinant viruses and recombinant viral vectors available from the RIKEN DNA bank

Viral vectors are required as gene-delivery systems for gene therapy and basic research. Recombinant adenoviruses (rAds) expressing genes of interest are being developed as research tools and many studies in vitro and in vivo have already been performed with such rAds. Shuttle vectors for rAds were constructed with full-length cDNAs and rAds were generated in HEK293 cells by the COS-TPC method. The rAds and shuttle vectors were developed by the Japanese research community and deposited in the RIKEN DNA Bank (RDB; http://www.brc.riken.jp/lab/dna/en/) for distribution to the scientific community. The Recombinant Virus Database (RVD; http://www.brc.riken.jp/lab/dna/rvd/) was established at the RIKEN BioResource Center (BRC) in Japan as the source of information about and distribution of the various resources. The RIKEN BRC is releasing more than 300 recombinant viruses (RVs) and 500 shuttle vectors, as well as all related information, which is included in a newly established database, the RVD. The RVD consists of (i) information about the RVs, the inserted cDNAs and the shuttle vectors; (ii) data about sequence-tagged sites (STSs) that are markers of viral DNAs; and (iii) experimental protocols for the use of RVs. The new database and available resources should be very useful to scientists who are studying human gene therapy and performing related basic research. It is a web-interfaced flat-file database that can be accessed through the internet. Moreover, all of the resources deposited in the RDB, which is a public facility in Japan, are available to researchers around the world.

RARGE: a large-scale database of RIKEN Arabidopsis resources ranging from transcriptome to phenome

The RIKEN Arabidopsis Genome Encyclopedia (RARGE) database houses information on biological resources ranging from transcriptome to phenome, including RIKEN Arabidopsis full-length (RAFL) complementary DNAs (cDNAs), their promoter regions, Dissociation (Ds) transposon-tagged lines and expression data from microarray experiments. RARGE provides tools for searching by resource code, sequence homology or keyword, and rapid access to detailed information on the resources. We have isolated 245 946 RAFL cDNA clones and collected 11 933 transposon-tagged lines, which are available from the RIKEN Bioresource Center and are stored in RARGE. The RARGE web interface can be accessed at http://rarge.gsc.riken.jp/. Additionally, we report 90 000 new RAFL cDNA clones here.

A collection of 11 800 single-copy Ds transposon insertion lines in Arabidopsis.

More than 10 000 transposon-tagged lines were constructed by using the Activator (Ac)/Dissociation (Ds) system in order to collect insertional mutants as a useful resource for functional genomics of Arabidopsis. The flanking sequences of the Ds element in the 11 800 independent lines were determined by high-throughput analysis using a semi-automated method. The sequence data allowed us to map the unique insertion site on the Arabidopsis genome in each line. The Ds element of 7566 lines is inserted in or close to coding regions, potentially affecting the function of 5031 of 25 000 Arabidopsis genes. Half of the lines have Ds insertions on chromosome 1 (Chr. 1), in which donor lines have a donor site. In the other half, the Ds insertions are distributed throughout the other four chromosomes. The intrachromosomal distribution of Ds insertions varies with the donor lines. We found that there are hot spots for Ds transposition near the ends of every chromosome, and we found some statistical preference for Ds insertion targets at the nucleotide level. On the basis of systematic analysis of the Ds insertion sites in the 11 800 lines, we propose the use of Ds-tagged lines with a single insertion in annotated genes for systematic analysis of phenotypes (phenome analysis) in functional genomics. We have opened a searchable database of the insertion-site sequences and mutated genes (http://rarge.gsc.riken.go.jp/) and are depositing these lines in the RIKEN BioResource Center as available resources (http://www.brc.riken.go.jp/Eng/).