Rapid validation of cancer genes in chimeras derived from established genetically engineered mouse models

Recent technological advances have opened the door for the fast and cost-effective generation of genetically engineered mouse models (GEMMs) to study cancer. We describe here a conceptually novel approach for the generation of chimeric GEMMs based on the controlled introduction of various genetic elements in embryonic stem cells (ESCs) that are derived from existing mouse strains with a predisposition for cancer. The isolation of GEMM-derived ESC lines is greatly facilitated by the availability of the newly defined culture media containing inhibitors that effectively preserve ESC pluripotency. The feasibility of the GEMM-ESC approach is discussed in light of current literature and placed into the context of existing models. This approach will allow for fast and flexible validation of candidate cancer genes and drug targets and will result in a repository of GEMM-ESC lines and corresponding vector collections that enable easy distribution and use of preclinical models to the wider scientific community.     

Cre recombinase‐mediated site‐specific modification of a cellular genome using an integrase‐defective retroviral vector

Retroviral integrase is an enzyme responsible for the integration of retroviruses. A single mutation in the integrase core domain can severely compromise its integration ability, leading to the accumulation of circular retroviral cDNA in the nuclei of infected cells. We therefore attempted to use those cDNA as substrates for Cre recombinase to perform a recombinase‐mediated cassette exchange (RMCE), thereby targeting retroviral vectors to a predetermined site. An expression unit containing a promoter, an ATG codon and marker genes (hygromycin resistance gene and red fluorescent protein gene) flanked by wild‐type and mutant loxP sites was first introduced into cellular chromosome to build founder cell lines. We then constructed another plasmid for the production of integrase‐defective retroviral vectors (IDRV), which contains an ATG‐deficient neomycin resistance gene and green fluorescent protein gene, flanked by a compatible pair of loxPs. After providing founder cells with Cre and infecting with IDRV later, effective RMCE occurred, resulting in the appearance of G418‐resistant colonies and a change in the color of fluorescence from red to green. Southern blot and PCR analyses on selected clones further confirmed site‐specific recombination. The successful substitution of the original viral integration machinery with a non‐viral mechanism could expand the application of retroviral vectors. Biotechnol. Bioeng. 2010;107:717–729. © 2010 Wiley Periodicals, Inc.     

An accumulative site‐specific gene integration system using cre recombinase‐mediated cassette exchange

The Cre‐loxP system is frequently used for site‐specific recombination in animal cells. The equilibrium and specificity of the recombination reaction can be controlled using mutated loxPs. In the present study, we designed an accumulative site‐specific gene integration system using Cre recombinase and mutated loxPs in which the Cre‐mediated cassette exchange reaction is infinitely repeatable for target gene integration into loxP target sites. To evaluate the feasibility and usefulness of this system, a series of integration reactions were repeated and confirmed in vitro using Cre recombinase protein and plasmids. Accumulative gene integration was also performed on the genome of Chinese hamster ovary (CHO) cells. The results indicated that the system was applicable for repeated gene integration of multiple genes to the target sites on both plasmids and CHO cell genomes. This gene integration system provides a novel strategy for gene amplification and for biological analyses of gene function through the genetic modification of cells and organisms. Biotechnol. Bioeng. 2010;105: 1106–1114. © 2009 Wiley Periodicals, Inc.     

ROSA26Flpo deleter mice promote efficient inversion of conditional gene traps in vivo

Gene trap mutagenesis in embryonic stem cells is an important tool to help elucidate gene function in current mouse mutagenesis efforts. Vector systems based on inversion of the gene trap module have recently been devised to allow for conditional mutagenesis. However, additional efforts are needed to improve this technology including improving the efficiency of site‐specific recombinases required to manipulate these conditional vectors in vivo. Here we describe a mouse line carrying the codon‐optimized FLP recombinase Flpo at the ROSA26 locus that functions at higher efficiency than a similar Flpe line in mediating the DNA inversion of a conditional gene trap cassette in vivo. genesis 48:603–606, 2010. © 2010 Wiley‐Liss, Inc.     

Generation of a reporter mouse line expressing Akt and EGFP upon Cre-mediated recombination

The serine-threonine kinase Akt regulates multiple biological processes. An important strategy to study Akt signaling in different tissues is targeted activation of this pathway in vivo. The current studies describe the generation of a mouse model that combines a double reporter system with activation of a constitutively active form of Akt1 (caAkt) in a Cre-dependent manner. Before Cre recombination, these mice express LacZ during development as well as in most adult tissues. After Cre-mediated excision of the LacZ reporter, functionality of the transgene was demonstrated by expression of the caAkt mutant along with the second reporter, EGFP in different pancreatic compartments and in the nervous system. This animal model provides a critical reagent for assessing the effects of Akt activation in specific tissues. The lineage-tracing properties provide a useful tool to study the role of Akt signaling in regulation of differentiation programs during development and plasticity of mature tissues.     

基于Cre重组酶体系的鸡卵清蛋白基因打靶载体的构建

利用胚胎干细胞基因打靶技术制备转基因鸡是研制鸡输卵管反应器的最佳技术路线。为建立基于Cre/loxp系统的鸡卵清蛋白基因(Ovalbumingene,OV)位点的双交换打靶载体系统,本研究克隆了鸡的OV基因7.8kb片段,并与克隆的内部核糖体进入位点(IRES)、人工合成的含有Cre重组酶识别位点变异体交换盒m2/loxp71EGFPloxp66,一起构建了含有Hsvtk负筛选标记的针对鸡卵清蛋白基因位点的敲入型共表达基因打靶载体pSSCm2/71EGFP66IRESOV7.8;以猪β干扰素基因(βInterferon,IFNβ)为目的基因构建了穿梭载体pMDm2/66MCSIFNMCSLoxp71,经过限制酶酶切及部分测序鉴定,所构建载体结构正确。进一步将它们共转化组成性表达Cre的细菌BM25.8,验证了loxp突变位点对重组反应的有效性     

Novel pan-neuronal Cre-transgenic line for conditional ablation of genes in the nervous system

Tissue-specific gene ablation is accomplished by combining conventional gene targeting approaches with site-specific recombinases such as the Cre/loxP system. Despite the use of a cardiac-specific rat myosin light chain II promoter, our transgenic line (CRE3) had little or no Cre expression in the heart; however, strong Cre activity was detected in the brain as early as gestation day E11.5. This was determined by several methods including crossing our mouse line with a lacZ indicator line (ROSA26). Transgenic Cre, in this mouse line, mediated DNA recombination of loxP-flanked genes selectively in neurons throughout the gray matter of the brain, cerebellum, spinal cord, as well as retina, dorsal, and sympathetic ganglia. Cre protein was also detected by immunohistochemistry exclusively in neurons, but not in other types of cells or tissues. Thus, our transgenic CRE3 mice provide pan-neuronal expression of CRE for carrying out conditional deletion of genes in neurons and their progenitors.     

Thyrocyte-specific expression of Cre recombinase in transgenic mice

A transgenic mouse line that expresses Cre recombinase under control of the human thyroid peroxidase (TPO) gene promoter was established. The activity and specificity of the TPO-driven Cre recombinase were examined by using Northern blotting and by crossing with the ROSA26 reporter transgenic mouse line. In the latter mice, Cre-mediated recombination occurred only in the thyrocytes, and recombination commenced around embryonic day 14.5, at the time during thyroid organogenesis when TPO expression begins. This study demonstrates that the TPO-Cre transgenic mouse is a powerful tool to specifically delete loxP-inserted (floxed) genes in thyrocytes and will be of great value in the study of thyrocyte-specific genes during development and/or in adult thyroids.     

Textpresso site‐specific recombinases: A text‐mining server for the recombinase literature including Cre mice and conditional alleles

Textpresso Site Specific Recombinases ( http://ssrc.genetics.uga.edu/ ) is a text‐mining web server for searching a database of more than 9,000 full‐text publications. The papers and abstracts in this database represent a wide range of topics related to site‐specific recombinase (SSR) research tools. Included in the database are most of the papers that report the characterization or use of mouse strains that express Cre recombinase as well as papers that describe or analyze mouse lines that carry conditional (floxed) alleles or SSR‐activated transgenes/knockins. The database also includes reports describing SSR‐based cloning methods such as the Gateway or the Creator systems, papers reporting the development or use of SSR‐based tools in systems such as Drosophila, bacteria, parasites, stem cells, yeast, plants, zebrafish, and Xenopus as well as publications that describe the biochemistry, genetics, or molecular structure of the SSRs themselves. Textpresso Site Specific Recombinases is the only comprehensive text‐mining resource available for the literature describing the biology and technical applications of SSRs. genesis 47:842–846, 2009. © 2009 Wiley‐Liss, Inc.     

Efficient DNA cassette exchange in mouse embryonic stem cells by staggered positive-negative selection

Recombinase-mediated cassette exchange (RMCE), when applied to mouse embryonic stem (ES) cells, promises to increase the ease with which genetic alterations can be introduced into targeted genomic loci in the mouse. However, existing selection strategies for identifying ES cells in which replacement DNA cassettes from a carrier plasmid have been exchanged correctly into a defined locus are suboptimal. Here, we report the generation in mouse ES cells of a loxed cassette acceptor (LCA) allele within the glucokinase (gk) gene locus. Using the gkLCA as a test allele, we developed a staggered positive-negative selection strategy that facilitates efficient identification of ES cell clones in which a DNA replacement cassette from a carrier plasmid has been exchanged correctly into the gkLCA allele. This selection strategy, by facilitating more efficient production of ES cell clones with various replacement DNA cassettes, should accelerate targeted repetitive introduction of gene modifications into the mouse.     

Generation of a floxed allele of Smad5 for cre-mediated conditional knockout in the mouse

Smad5 is a member of the Smad family of intracellular mediators of BMP signals and in endothelial cells of TGF-beta signals. We and others previously showed that loss of Smad5 in the mouse results in embryonic lethality (between E9.5-E11.5) due to multiple embryonic and extraembryonic defects. To circumvent the early embryonic lethality and to allow tissue- and time-specific Smad5 inactivation, we created a conditional Smad5 allele in the mouse. Floxed Smad5 (Smad5(flE2,Neo/flE2,Neo)) mice were generated in which both exon2 and the Neo-cassette were flanked by loxP sites. Here we demonstrate that embryos with ubiquitous Cre-mediated deletion of Smad5 (Smad5(flDeltaE2/flDeltaE2)) phenocopy the conventional Smad5 knockout mice. Smad5(flE2/flE2) mice are now available and will be a valuable tool to analyze the role of Smad5 beyond its crucial early embryonic function throughout development and postnatal life.     

Floxed allele for conditional inactivation of the GABAB(1) gene

GABA(B) receptors are the G-protein-coupled receptors for the neurotransmitter GABA. GABA(B) receptors are broadly expressed in the nervous system. Their complete absence in mice causes premature lethality or--when mice are viable--epilepsy, impaired memory, hyperalgesia, hypothermia, and hyperactivity. A spatially and temporally restricted loss of GABA(B) function would allow addressing how the absence of GABA(B) receptors leads to these diverse phenotypes. To permit a conditional gene inactivation, we flanked critical exons of the GABA(B(1)) gene with lox511 sites. GABA(B(1)) (lox511/lox511) mice exhibit normal levels of GABA(B(1)) protein, are fertile, and do not display any behavioral phenotype. We crossed GABA(B(1)) (lox511/lox511) with Cre-deleter mice to produce mice with an unrestricted GABA(B) receptor elimination. These GABA(B(1)) (-/-) mice no longer synthesize GABA(B(1)) protein and exhibit the expected behavioral abnormalities. The conditional GABA(B(1)) allele described here is therefore suitable for generating mice with a site- and time-specific loss of GABA(B) function.