Reproducible and inducible knockdown of gene expression in mice

RNA interference (RNAi) has emerged as an efficient approach for rapid analysis of gene function. In mammalian cells, vector-based expression of small hairpin RNAs (shRNA) produces potent and stable gene knockdown effects. An inducible RNAi system with reproducible levels of siRNA expression will extend the usefulness of this methodology to the identification of gene functions within the developing or adult mouse. We present evidence that an RNA polymerase III-driven U6 promoter with stuffer sequences flanked by loxP sites inserted at three different sites within the promoter drives shRNA expression in a Cre recombinase-dependent manner. We utilized this approach to develop a generic strategy for the reproducible knockdown of gene expression in mice. By placing the inducible shRNA cassette into the ROSA26 locus of the mouse, we were able to generate reproducible levels of controlled expression of shRNA to produce discernable phenotypes in vitro and in vivo. This approach circumvents the prescreening of random integration in embryonic stem cell clones and further enables conditional gene knockdown with temporal and/or tissue specificity. This methodology should expedite large-scale functional studies.     

Inducible suppression of Fgfr2 and Survivin in ES cells using a combination of the RNA interference (RNAi) and the Cre–LoxP system

RNA interference (RNAi) is a simple and powerful tool widely used for studying gene function in a number of species. Recently, inducible regulation of RNAi in mammalian cells using either tetracycline- or ecdysone-responsive systems has been developed to prevent potential lethality or non-physiological responses associated with persistent suppression of genes that are essential for cell survival or cell cycle progression. Here we show that the inducible regulation of RNAi also can be achieved by using a Cre–LoxP approach. We demonstrate that the insertion of a loxP-flanked neomycin cassette into RNA polymerase III promoter, which controls a vector-based RNAi unit, impairs the promoter activity. However, the expression of RNAi construct can be completely restored upon the removal of the neo cassette using a tamoxifen inducible Cre construct. We show that this system works with high efficiency in suppression of two endogenous genes, Fgfr2 and Survivin, in mouse embryonic stem (ES) cells, as evidenced by the decrease of levels of gene expression, reduced cell proliferation and colony formation. This system provides a potentially important yet simple approach to establish mutant mouse strains for functional study at defined stages upon turning on the inducible switches controlled by the Cre–LoxP system.     

Inducible suppression of Fgfr2 and Survivin in ES cells using a combination of the RNA interference (RNAi) and the Cre-LoxP system

RNA interference (RNAi) is a simple and powerful tool widely used for studying gene function in a number of species. Recently, inducible regulation of RNAi in mammalian cells using either tetracycline- or ecdysone-responsive systems has been developed to prevent potential lethality or non-physiological responses associated with persistent suppression of genes that are essential for cell survival or cell cycle progression. Here we show that the inducible regulation of RNAi also can be achieved by using a Cre-LoxP approach. We demonstrate that the insertion of a loxP-flanked neomycin cassette into RNA polymerase III promoter, which controls a vector-based RNAi unit, impairs the promoter activity. However, the expression of RNAi construct can be completely restored upon the removal of the neo cassette using a tamoxifen inducible Cre construct. We show that this system works with high efficiency in suppression of two endogenous genes, Fgfr2 and Survivin, in mouse embryonic stem (ES) cells, as evidenced by the decrease of levels of gene expression, reduced cell proliferation and colony formation. This system provides a potentially important yet simple approach to establish mutant mouse strains for functional study at defined stages upon turning on the inducible switches controlled by the Cre-LoxP system.     

Silencing of the Pink1 gene expression by conditional RNAi does not induce dopaminergic neuron death in mice

Transgenic RNAi, an alternative to the gene knockout approach, can induce hypomorphic phenotypes that resemble those of the gene knockout in mice. Conditional transgenic RNAi is an attractive choice of method for reverse genetics in vivo because it can achieve temporal and spatial silencing of targeted genes. Pol III promoters such as U6 are widely used to drive the expression of RNAi transgenes in animals. Tested in transgenic mice, a Cre-loxP inducible U6 promoter drove the broad expression of an shRNA against the Pink1 gene whose loss-of-functional mutations cause one form of familial Parkinson's disease. The expression of the shRNA was tightly regulated and, when induced, silenced the Pink1 gene product by more than 95% in mouse brain. However, these mice did not develop dopaminergic neurodegeneration, suggesting that silencing of the Pink1 gene expression from embryo in mice is insufficient to cause similar biochemical or morphological changes that are observed in Parkinson's disease. The results demonstrate that silencing of the PINK1 gene does not induce a reliable mouse model for Parkinson's disease, but that technically the inducible U6 promoter is useful for conditional RNAi in vivo.     

RUSH and CRUSH: A rapid and conditional RNA interference method in mice

RNA interference (RNAi) is a powerful approach to phenocopy mutations in many organisms. Gold standard conventional knock‐out mouse technology is labor‐ and time‐intensive; however, off‐target effects may confound transgenic RNAi approaches. Here, we describe a rapid method for conditional and reversible gene silencing in RNAi transgenic mouse models and embryonic stem (ES) cells. RUSH and CRUSH RNAi vectors were designed for reversible or conditional knockdown, respectively, demonstrated using targeted replacement in an engineered ROSA26^lacZ ES cell line and wildtype V6.5 ES cells. RUSH was validated by reversible knockdown of Dnmt1 in vitro. Conditional mouse model production using CRUSH was expedited by deriving ES cell lines from Cre transgenic mouse strains (nestin, cTnnT, and Isl1) and generating all‐ES G₀ transgenic founders by tetraploid complementation. A control CRUSH^GFP RNAi mouse strain showed quantitative knockdown of GFP fluorescence as observed in compound CRUSH^GFP, Ds‐Red Cre‐reporter transgenic mice, and confirmed by Western blotting. The capability to turn RUSH and CRUSH alleles off or on using Cre recombinase enables this method to rapidly address questions of tissue‐specificity and cell autonomy of gene function in development. genesis 52:39–48, 2014. © 2013 Wiley Periodicals, Inc.     

Postnatal male germ‐cell expression of cre recombinase in Tex101‐iCre transgenic mice

We have generated a transgenic mouse line that expresses improved Cre recombinase (iCre) under the control of the testis‐expressed gene 101 (Tex101) promoter. This transgenic mouse line was named Tex101‐iCre. Using the floxed ROSA reporter mice, we found that robust Cre recombinase activity was detected in postnatal testes with weak or no activity in other tissues. Within the testis, Cre recombinase was active in spermatogenic cells as early as the prospermatogonia stage at day 1 after birth. In 30‐ and 60‐day‐old mice, positive Cre recombinase activity was detected not only in prospermatogonia but also in spermatogenic cells at later stages of spermatogenesis. There was little or no Cre activity in interstitial cells. Breeding wild‐type females with homozygous floxed fibroblast growth factor receptor 2 (Fgfr2) males carrying the Tex101‐iCre transgene did not produce any progeny with the floxed Fgfr2 allele. All the progeny inherited a recombined Fgfr2 allele, indicating that complete deletion of the floxed Fgfr2 allele by Tex101‐iCre can be achieved in the male germline. Furthermore, FGFR2 protein was not detected in spermatocytes and spermatids of adult Fgfr2^fl/fl;Tex101‐iCre mice. Taken together, our results suggest that the Tex101‐iCre mouse line allows the inactivation of a floxed gene in spermatogenic cells in adult mice, which will facilitate the functional characterization of genes in normal spermatogenesis and male fertility. genesis 48:717–722, 2010. © 2010 Wiley‐Liss, Inc.