Database for exchangeable gene trap clones: Pathway and gene ontology analysis of exchangeable gene trap clone mouse lines

Gene trapping in embryonic stem (ES) cells is a proven method for large‐scale random insertional mutagenesis in the mouse genome. We have established an exchangeable gene trap system, in which a reporter gene can be exchanged for any other DNA of interest through Cre/mutant lox‐mediated recombination. We isolated trap clones, analyzed trapped genes, and constructed the database for Exchangeable Gene Trap Clones (EGTC) [ http://egtc.jp ]. The number of registered ES cell lines was 1162 on 31 August 2013. We also established 454 mouse lines from trap ES clones and deposited them in the mouse embryo bank at the Center for Animal Resources and Development, Kumamoto University, Japan. The EGTC database is the most extensive academic resource for gene‐trap mouse lines. Because we used a promoter‐trap strategy, all trapped genes were expressed in ES cells. To understand the general characteristics of the trapped genes in the EGTC library, we used Kyoto Encyclopedia of Genes and Genomes (KEGG) for pathway analysis and found that the EGTC ES clones covered a broad range of pathways. We also used Gene Ontology (GO) classification data provided by Mouse Genome Informatics (MGI) to compare the functional distribution of genes in each GO term between trapped genes in the EGTC mouse lines and total genes annotated in MGI. We found the functional distributions for the trapped genes in the EGTC mouse lines and for the RefSeq genes for the whole mouse genome were similar, indicating that the EGTC mouse lines had trapped a wide range of mouse genes.     

High-throughput trapping of secretory pathway genes in mouse embryonic stem cells

High-throughput gene trapping is a random approach for inducing insertional mutations across the mouse genome. This approach uses gene trap vectors that simultaneously inactivate and report the expression of the trapped gene at the insertion site, and provide a DNA tag for the rapid identification of the disrupted gene. Gene trapping has been used by both public and private institutions to produce libraries of embryonic stem (ES) cells harboring mutations in single genes. Presently, approximately 66% of the protein coding genes in the mouse genome have been disrupted by gene trap insertions. Among these, however, genes encoding signal peptides or transmembrane domains (secretory genes) are underrepresented because they are not susceptible to conventional trapping methods. Here, we describe a high-throughput gene trapping strategy that effectively targets secretory genes. We used this strategy to assemble a library of ES cells harboring mutations in 716 unique secretory genes, of which 61% were not trapped by conventional trapping, indicating that the two strategies are complementary. The trapped ES cell lines, which can be ordered from the International Gene Trap Consortium (http://www.genetrap.org), are freely available to the scientific community.     

A review of current large‐scale mouse knockout efforts

After the successful completion of the human genome project (HGP), biological research in the postgenome era urgently needs an efficient approach for functional analysis of genes. Utilization of knockout mouse models has been powerful for elucidating the function of genes as well as finding new therapeutic interventions for human diseases. Gene trapping and gene targeting are two independent techniques for making knockout mice from embryonic stem (ES) cells. Gene trapping is high‐throughput, random, and sequence‐tagged while gene targeting enables the knockout of specific genes. It has been about 20 years since the first gene targeting and gene trapping mice were generated. In recent years, new tools have emerged for both gene targeting and gene trapping, and organizations have been formed to knock out genes in the mouse genome using either of the two methods. The knockout mouse project (KOMP) and the international gene trap consortium (IGTC) were initiated to create convenient resources for scientific research worldwide and knock out all the mouse genes. Organizers of KOMP regard it as important as the HGP. Gene targeting methods have changed from conventional gene targeting to high‐throughput conditional gene targeting. The combined advantages of trapping and targeting elements are improving the gene trapping spectrum and gene targeting efficiency. As a newly‐developed insertional mutation system, transposons have some advantages over retrovirus in trapping genes. Emergence of the international knockout mouse consortium (IKMP) is the beginning of a global collaboration to systematically knock out all the genes in the mouse genome for functional genomic research. genesis 48:73–85, 2010. © 2010 Wiley‐Liss, Inc.     

Gene Transfer and Genome-Wide Insertional Mutagenesis by Retroviral Transduction in Fish Stem Cells

Retrovirus (RV) is efficient for gene transfer and integration in dividing cells of diverse organisms. RV provides a powerful tool for insertional mutagenesis (IM) to identify and functionally analyze genes essential for normal and pathological processes. Here we report RV-mediated gene transfer and genome-wide IM in fish stem cells from medaka and zebrafish. Three RVs were produced for fish cell transduction: rvLegfp and rvLcherry produce green fluorescent protein (GFP) and mCherry fluorescent protein respectively under control of human cytomegalovirus immediate early promoter upon any chromosomal integration, whereas rvGTgfp contains a splicing acceptor and expresses GFP only upon gene trapping (GT) via intronic in-frame integration and spliced to endogenous active genes. We show that rvLegfp and rvLcherry produce a transduction efficiency of 11~23% in medaka and zebrafish stem cell lines, which is as 30~67% efficient as the positive control in NIH/3T3. Upon co-infection with rvGTgfp and rvLcherry, GFP-positive cells were much fewer than Cherry-positive cells, consistent with rareness of productive gene trapping events versus random integration. Importantly, rvGTgfp infection in the medaka haploid embryonic stem (ES) cell line HX1 generated GTgfp insertion on all 24 chromosomes of the haploid genome. Similar to the mammalian haploid cells, these insertion events were presented predominantly in intergenic regions and introns but rarely in exons. RV-transduced HX1 retained the ES cell properties such as stable growth, embryoid body formation and pluripotency gene expression. Therefore, RV is proficient for gene transfer and IM in fish stem cells. Our results open new avenue for genome-wide IM in medaka haploid ES cells in culture.     

Using embryonic stem cells to introduce mutations into the mouse germ line

It is now possible, through the use of a number of experimental technologies, to transfer genetic information into mouse embryos to stably alter the genetic constitution of mice. This experimental approach, namely the generation of so-termed "transgenic" animals, is affording new insights into a wide variety of biological problems. This review focuses on one system for the generation of transgenic mice, which utilizes tissue culture cell lines of embryonic stem cells, termed ES cells. The remarkable property of ES cells is that they retain the potential to reform an embryo; when they are replaced inside a carrier embryo, they resume normal development and contribute to all the tissues of the live-born chimeric animal. Recent experiments, using a repertoire of gene transfer techniques, have shown that ES cells are amenable to a variety of experimental manipulations in tissue culture. Moreover, it has been demonstrated that these genetically altered cells can be transferred into the germ line of chimeric mice, thus allowing the production of unique strains of animals for study. The applications of the ES cell system are reviewed, with particular emphasis on their use for the generation of random insertional mutations using a retrovirally mediated mutagenesis approach. Finally, the use of ES cells in conjunction with the recently described technique of homologous recombination, or "gene targeting," is discussed. This technology allows the generation of animals carrying extremely precise genetic modifications of endogenous genes.     

Gene-trap mutagenesis using Mol/MSM-1 embryonic stem cells from MSM/Ms mice

The MSM/Ms strain is derived from the Japanese wild mouse Mus musculus molossinus and displays characteristics not observed in common laboratory strains. Functional genomic analyses using genetically engineered MSM/Ms mice will reveal novel phenotypes and gene functions/interactions. We previously reported the establishment of a germline-competent embryonic stem (ES) cell line, Mol/MSM-1, from the MSM/Ms strain. To analyze its usefulness for insertional mutagenesis, we performed gene-trapping using these cells. In the present study, we compared the gene-trap events between Mol/MSM-1 and a conventional ES cell line, KTPU8, derived from the F1 progeny of a C57BL/6 × CBA cross. We introduced a promoter-trap vector carrying the promoterless β-galactosidase/neomycin-resistance fusion gene into Mol/MSM-1 and KTPU8 cells, isolated clones, and identified the trapped genes by rapid amplification of cDNA 5′-ends (5′-RACE), inverse PCR, or plasmid rescue. Unexpectedly, the success rate of 5′-RACE in Mol/MSM trap clones was 47 %, lower than the 87 % observed in KTPU8 clones. Genomic analysis of the 5′-RACE-failed clones revealed that most had trapped ribosomal RNA gene regions. The percentage of ribosomal RNA region trap clones was 41 % in Mol/MSM-1 cells, but less than 10 % in KTPU8 cells. However, within the Mol/MSM-1 5′-RACE-successful clones, the trapping frequency of annotated genes, the chromosomal distribution of vector insertions, the frequency of integration into an intron around the start codon-containing exon, and the functional spectrum of trapped genes were comparable to those in KTPU8 cells. By selecting 5′-RACE-successful clones, it is possible to perform gene-trapping efficiently using Mol/MSM-1 ES cells and promoter-trap vectors.     

High throughput gene trapping and postinsertional modifications of gene trap alleles

Gene trapping is a high-throughput insertional mutagenesis approach that has been primarily used in mouse embryonic stem cells (ESCs). As a high throughput technology, gene trapping helped to generate tenth of thousands of ESC lines harboring mutations in single genes that can be used for making knock-out mice. Ongoing international efforts operating under the umbrella of the International Knockout Mouse Consortium (IKMC; www.knockoutmouse.org) aim to generate conditional alleles for every protein coding gene in the mouse genome by high throughput conditional gene targeting and trapping. Here, we provide protocols for gene trapping in ESCs that can be easily adapted to any other mammalian cell. We further provide protocols for handling and verifying conditional gene trap alleles in ESC lines obtained from the IKMC repositories and describe a highly efficient method for the postinsertional modification of gene trap alleles. More specifically, we describe a protein tagging strategy based on recombinase mediated cassette exchange (RMCE) that enables protein localization and protein-protein interaction studies under physiological conditions.     

A whole lotta jumpin' goin' on: new transposon tools for vertebrate functional genomics

Genome sequences of vertebrate model organisms are becoming available, fuelling the next challenging phase of research: annotating all of the genes with functional information. The functional annotation of all of the approximately 35 000 genes in mammals will undoubtedly require complementing the technologies of forward and reverse genetics in mutagenesis screens. Two recent articles report on the construction of retrotransposable elements that efficiently 'jump' in mammalian cells. These new elements hold great promise as useful vectors for insertional mutagenesis screens in the mouse.     

A system for rapid generation of coat color-tagged knockouts and defined chromosomal rearrangements in mice.

Gene targeting in mouse embryonic stem (ES) cells can be used to generate single gene mutations or defined multi-megabase chromosomal rearrangements when applied with the Cre- loxP recombination system. While single knockouts are essential for uncovering functions of cloned genes, chromosomal rearrangements are great genetic tools for mapping, mutagenesis screens and functional genomics. The conventional approach to generate mice with targeted alterations of the genome requires extensive molecular cloning to build targeting vectors and DNA-based genotyping for stock maintenance. Here we describe the design and construction of a two-library system to facilitate high throughput gene targeting and chromo-somal engineering. The unique feature of these libraries is that once a clone is isolated, it is essentially ready to be used for insertional targeting in ES cells. The two libraries each bear a complementary set of genetic markers tailored so that the vector can be used for Cre- loxP -based chromosome engineering as well as single knockouts. By incorporating mouse coat color markers into the vectors, we illustrate a widely applicable method for stock maintenance of ES cell-derived mice with single gene knockouts or more extensive chromosomal rearrangements.     

Insertional mutagenesis in mice: new perspectives and tools

Insertional mutagenesis has been at the core of functional genomics in many species. In the mouse, improved vectors and methodologies allow easier genome-wide and phenotype-driven insertional mutagenesis screens. The ability to generate homozygous diploid mutations in mouse embryonic stem cells allows prescreening for specific null phenotypes prior to in vivo analysis. In addition, the discovery of active transposable elements in vertebrates, and their development as genetic tools, has led to in vivo forward insertional mutagenesis screens in the mouse. These new technologies will greatly contribute to the speed and ease with which we achieve complete functional annotation of the mouse genome.     

Chromosomal mobilization and reintegration of Sleeping Beauty and PiggyBac transposons

The Sleeping Beauty and PiggyBac DNA transposon systems have recently been developed as tools for insertional mutagenesis. We have compared the chromosomal mobilization efficiency and insertion site preference of the two transposons mobilized from the same donor site in mouse embryonic stem (ES) cells under conditions in which there were no selective constraints on the transposons' insertion sites. Compared with Sleeping Beauty, PiggyBac exhibits higher transposition efficiencies, no evidence for local hopping and a significant bias toward reintegration in intragenic regions, which demonstrate its utility for insertional mutagenesis. Although Sleeping Beauty had no detectable genomic bias with respect to insertions in genes or intergenic regions, both Sleeping Beauty and PiggyBac transposons displayed preferential integration into actively transcribed loci. genesis 47:404–408, 2009. © 2009 Wiley‐Liss, Inc.     

Chemical mutagenesis of the mouse genome: an overview

The careful comparison of the phenotypic variations generated by different alleles at a given locus, including of course, those alleles with a deleterious effect, is often an important source of information for the understanding of gene functions. In fact, every time it is possible to match a specific alteration observed at the genomic level with a particular pathology, it is possible to establish a relationship between a gene and its function. When considered from this point of view, the production of new mutations by experimental mutagenesis appears as an alternative to the strategy of in vitro gene invalidation by homologous recombination in embryonic stem (ES) cells, with the advantage that experimental mutagenesis does not require any previous knowledge of the gene structure at the molecular level. Homologous recombination in ES cells is a gene driven approach, in which mutant alleles are produced for those genes that we already know. Experimental mutagenesis, on the contrary, is a phenotype driven approach, in which unknown genes are identified based on phenotypic changes. Also, while homologous recombination in ES cells requires a rather sophisticated technology, mutagenesis is simple to achieve but relies greatly on the efficiency of the mutagenic treatment as well as on the use of an accurate protocol for phenotyping. In this review, we will address a few comments about the different techniques that can be used for the induction of point mutations in the mouse germ line with special emphasis on chemical mutagenesis. We will also discuss the limitations of experimental mutagenesis and the necessity to look for alternative ways for the discovery of new genes and gene functions in the mouse.