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.     

Enhanced gene trapping in mouse embryonic stem cells

Gene trapping is used to introduce insertional mutations into genes of mouse embryonic stem cells (ESCs). It is performed with gene trap vectors that simultaneously mutate and report the expression of the endogenous gene at the site of insertion and provide a DNA tag for rapid identification of the disrupted gene. Gene traps have been employed worldwide to assemble libraries of mouse ESC lines harboring mutations in single genes, which can be used to make mutant mice. However, most of the employed gene trap vectors require gene expression for reporting a gene trap event and therefore genes that are poorly expressed may be under-represented in the existing libraries. To address this problem, we have developed a novel class of gene trap vectors that can induce gene expression at insertion sites, thereby bypassing the problem of intrinsic poor expression. We show here that the insertion of the osteopontin enhancer into several conventional gene trap vectors significantly increases the gene trapping efficiency in high-throughput screens and facilitates the recovery of poorly expressed genes.     

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 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.     

A gene trap approach to identify genes that control development

One methodology called gene trap represents a versatile strategy by which murine genes that control developmental events can be captured and identified with corresponding mutants produced at the same time. Gene trap methodology has been developed and several genes and their mutants have been analyzed, but almost all of the genes reported are those already known or murine homologs of other species. In this study, the efficiency of the gene trap methodology was improved and a novel mutant mouse strain named jumonji established which displayed an intriguing defect. Homozygous fetal mice died in utero and a significant proportion of the homozygotes showed abnormal groove formation on the neural plate and a defect in neural tube closure with a mixed genetic background of 129/Ola and BALB/c. The trapped gene believed to be responsible for these phenotypes encodes a novel nuclear protein. The results reveal that the gene trap approach can identify unknown interesting genes in murine development. The gene trap strategy, however, has several problems, the greatest of which is the difficulty in prescreening embryonic stem (ES) cells for interesting trapped genes. Recent studies are solving this problem and show that the prescreening of ES cells for genes with several characteristics is possible.     

Sequence and expression of a novel mouse gene PRDC (protein related to DAN and cerberus) identified by a gene trap approach

Gene trapping in embryonic stem (ES) cells was used to identify a novel gene involved in mouse development. In order to screen trapped ES cell lines for the presence of developmentally regulated genes, an in vitro differentiation test was used. One of the G418 resistant cell lines, in conjunction with the lacZ reporter gene, showed differential expression patterns under differentiated and undifferentiated conditions. The gene trap insertion in this cell line was germ-line transmitted and X-gal staining was used to assess the expression pattern of lacZ in embryos heterozygous for the trapped allele. The reporter gene's expression was detected in commissural neurons in the developing spinal cord, suggesting functions for the trapped gene in mouse neural development. Structural analysis of the cDNA revealed that this trapped gene, named PRDC (protein related to DAN and cerberus), is a novel gene that encodes a putative secretory protein consisting of 168 amino acid residues. PRDC gene product shows limited similarities to the products of DAN (differential screening-selected gene aberrative in neuroblastoma) and cerberus . (DAN is a possible tumor-suppressor for neuroblastoma in human. Cerberus can induce an ectopic head in Xenopus embryos when ectopically expressed.) These three gene products may form a novel family of signaling molecules.     

A novel triple fusion reporter system for use in gene trap mutagenesis

Gene trapping is an insertional mutagenesis strategy that allows for simultaneous gene identification and mutation in embryonic stem (ES) cells. Gene trap vectors both disrupt coding sequence and report on the genes' endogenous expression. The most popular gene trap reporter to date combines beta-galactosidase expression with neomycin resistance in a fusion protein known as beta-geo. Here we describe a refinement to this reporter that also incorporates real time fluorescent readouts. We have constructed a series of gene trap vectors incorporating a novel tripartite fusion protein consisting of EGFP, beta-galactosidase, and the neomycin or hygromycin resistance activities. Our results indicate that these triple fusions can function efficiently as reporters of endogenous trapped gene expression and subcellular localization. We show that these fusion proteins constitute versatile gene trap reporters whose activity can be detected in real time by fluorescence and in fixed tissue with a sensitive enzymatic activity.     

Inducible gene trapping with drug-selectable markers and Cre/loxP to identify developmentally regulated genes

Gene trapping in mouse embryonic stem cells is an important genetic approach that allows simultaneous mutation of genes and generation of corresponding mutant mice. We designed a selection scheme with drug selection markers and Cre/loxP technology which allows screening of gene trap events that responded to a signaling molecule in a 96-well format. Nine hundred twenty gene trap clones were assayed, and 258 were classified as gene traps induced by in vitro differentiation. Sixty-five of the in vitro differentiation-inducible gene traps were also responsive to retinoic acid treatment. In vivo analysis revealed that 85% of the retinoic acid-inducible gene traps trapped developmentally regulated genes, consistent with the observation that genes induced by retinoic acid treatment are likely to be developmentally regulated. Our results demonstrate that the inducible gene trapping system described here can be used to enrich in vitro for traps in genes of interest. Furthermore, we demonstrate that the cre reporter is extremely sensitive and can be used to explore chromosomal regions that are not detectable with neo as a selection cassette.     

用基因诱捕法制作Ayu17-449基因敲除小鼠模型

为了探明Ayu17-449基因在小鼠生长发育过程中的功能, 用特殊的诱捕载体（Gene trapping vector）导入小鼠ES细胞中,5′RACE、Southern blot方法鉴定成功地单一捕获Ayu17-449基因后,由这种ES制作了Ayu17-449 敲除小鼠并用Northern blot方法该基因在突变小鼠体内的表达。结果在Ayu17-449 敲除小鼠体内,诱捕载体位于Ayu17-449基因的翻译起始密码上游,Ayu17-449基因的转录被抑制。表明Ayu17-449敲除小鼠为分析Ayu17-449基因的功能提供了可靠的实验材料。      

Mouse gene trap approach: identification of novel genes and characterization of their biological functions.

The mouse gene trap strategy is an insertional mutagenesis involving an exogenous DNA, termed the trap vector, as a mutagen that produces a mutation in the mouse genome and a sequence tag to facilitate the isolation of the mutated genes. The trap vector consists of a reporter gene whose expression mimics that of the endogenous genes mutated and a selection marker that sorts cells bearing the inserted vector. Gene trap is a powerful method for identifying genes important in biological phenomena. Moreover, the method produces mutant organisms whose phenotypes provide invaluable information about the biological functions of the genes responsible for these phenotypes. Indeed, a number of genes essential for mouse embryogenesis have been identified by the gene trap method. Here, we describe the principle, results, and perspectives for applications of gene trap approach to the study of cell differentiation and lineage commitment.     

Exchangeable gene trap using the Cre/mutated lox system.

The gene trap technique is a powerful approach for characterizing and mutating genes involved in mouse development. However, one shortcoming of gene trapping is the relative inability to induce subtle mutations. This problem can be overcome by introducing a knock-in system into the gene trap strategy. Here, we have constructed a new gene trap vector, pU-Hachi, employing the Cre-mutated lox system (Araki et al., 1997), in which a pair of mutant lox, lox71 and lox66, was used to promote targeted integrative reaction by Cre recombinase. The pU-Hachi carries splicing acceptor (SA)-lox71-internal ribosomal entry site (IRES)-beta-geo-pA-loxP-pA-pUC. By using this vector, we can carry out random insertional mutagenesis as the first step, and then we can replace the beta-geo gene with any gene of interest through Cre-mediated integration. We have isolated 109 trap clones electroporated with pU-Hachi, and analyzed their integration patterns by Southern blotting to select those carrying a single copy of the trap vector. By use of some of these clones, we have succeeded in exchanging the reporter gene at high efficiency, ranging between 20-80%. This integration system is also quite useful for plasmid rescue to recover flanking genomic sequences, because a plasmid vector sequence can be introduced even when the pUC sequence of the trap vector is lost through integration into the genome. Thus, this method, termed exchangeable gene trapping, has many advantages as the trapped clones can be utilized to express genes with any type of mutation.     

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.     

Mouse splice mutant generation from ENU-treated ES cells--a gene-driven approach

Mutant mice are important for elucidating mammalian gene functions and for modeling human disease phenotypes. In recent years, chemical mutagenesis has become an increasingly popular method to disrupt gene functions due to its high efficiency of inducing mutations throughout the genome. Mutagenesis of embryonic stem (ES) cells offers the possibility of gene-driven approaches, which, however, require efficient mutation detection procedures to screen archives of mutated samples for lesions in particular genes. We have developed an approach that focuses on the detection of splice mutations in highly pooled cDNA samples using exon-skipping PCR primers. As a proof of concept, splice mutants for the Kit gene were isolated from a library comprising approximately 40,000 ES cell clones treated with N-ethyl-N-nitrosourea followed by transmission through the mouse germ-line. The approach will be useful for the production of mouse models for human disease-related splice mutations and as a general gene disruption strategy.     

RET: a poly A-trap retrovirus vector for reversible disruption and expression monitoring of genes in living cells

Gene trapping is a form of insertional mutagenesis that causes disruption of gene function. Here we report the construction and extensive examination of a versatile retrovirus vector, RET (removable exon trap). The RET vector uses an improved poly A-trap strategy for the efficient identification of functional genes regardless of their expression status in target cells. A combination of a potentially very strong splice acceptor and an effective polyadenylation signal assures the complete disruption of the function of trapped genes. Inclusion of a promoterless GFP cDNA in the RET vector allows the expression pattern of the trapped gene to be easily monitored in living cells. Finally, because of loxP-containing LTRs at both ends, the integrated proviruses can be removed from the genome of infected cells by Cre-mediated homologous recombination. Hence, it is possible to attribute the mutant phenotype of gene-trapped cells directly to RET integration by inducing phenotypic reversion after provirus excision. The RET system can be used in conjunction with cell lines with functional heterozygosity, embryonic stem cells, lineage-committed cell lines that differentiate in response to specific inducing factors and other responsive cell lines that can be selected by virtue of their induced green fluorescence protein expression.     

分泌蛋白特异性基因陷阱的设计与验证

蛋白质分子向细胞外分泌的过程有赖于信号肽的介导.基因陷阱是功能性基因克隆的一种有效方法,经典的基因陷阱以geo作为报告基因,对所克隆的基因类型没有选择性.将绿脓杆菌外毒素、2A序列、IL-2受体穿膜区以及新霉素磷酸转移酶的基因依次融合构建新型报告基因——peo,该报告基因能够特异性地甄别具有信号肽编码序列的基因.为验证peo对信号肽编码序列的特异性甄别作用,以peo为报告基因,构建了3种质粒载体,分别模拟用基因陷阱载体进行筛选时可能出现的3种情况,通过转染HeLa细胞、G418筛选以及碱性磷酸酶检测,证明peo能够有效地区分信号肽和非信号肽编码序列,以peo为报告基因改造的基因陷阱载体可以用于分泌蛋白基因的筛选.