The pINDUCER lentiviral toolkit for inducible RNA interference in vitro and in vivo
The discovery of RNAi has revolutionized loss-of-function genetic studies in mammalian systems. However, significant challenges still remain to fully exploit RNAi for mammalian genetics. For instance, genetic screens and in vivo studies could be broadly improved by methods that allow inducible and uniform gene expression control. To achieve this, we built the lentiviral pINDUCER series of expression vehicles for inducible RNAi in vivo. Using a multicistronic design, pINDUCER vehicles enable tracking of viral transduction and shRNA or cDNA induction in a broad spectrum of mammalian cell types in vivo. They achieve this uniform temporal, dose-dependent, and reversible control of gene expression across heterogenous cell populations via fluorescence-based quantification of reverse tettransactivator expression. This feature allows isolation of cell populations that exhibit a potent, inducible target knockdown in vitro and in vivo that can be used in human xenotransplantation models to examine cancer drug targets.lentivirus | vector L oss-of-function studies represent a powerful means by which to gain insight into the molecular mechanisms behind complex biological processes. Until recently, these studies were practical for only a small set of genetically tractable model organisms (1, 2). The discovery of gene silencing through RNAi has made it possible to carry out loss-of-function studies in mammals. RNAi has transformed the way in which gene function can be investigated and has quickly become a versatile tool for a wide range of applications, including reverse genetics, highthroughput screens, and therapeutics (3). The application of RNAi technology both in vitro and in vivo has tremendous potential to further our knowledge of the molecular mechanisms that underpin both normal biology and human disease.To achieve efficient and long-term gene silencing, we have previously generated the retroviral-encoded microRNA-based shRNA PRIME (potent RNA interference using microRNA expression) vectors that are effective in suppressing expression of their intended gene targets from single proviral integrations (4). These vectors use the miR30 backbone and are expressed from RNA polymerase II promoters, which allows for exquisite regulation of shRNA expression. We have further generated genomewide shRNA libraries in these vectors that cover large numbers of mammalian transcripts for systematic study of gene function (5, 6). These shRNA libraries, as well as shRNA libraries generated by other laboratories (7,8), have been used to perform genetic screens in mammalian cell culture models for a variety of phenotypes, including cell transformation, synthetic lethal interactions, and resistance to chemotherapeutic treatments (9-15).Despite the success demonstrated by the above constitutive shRNA vectors, an inducible shRNA system would have obvious advantages in many experimental settings. First, the inducible shRNA system allows for the study of essential genes. Because constitutively expressed shRNAs targeting essential genes will be ...
Transforming growth factor- (TGF-) plays an essential role in growth and patterning of the mammary gland, and alterations in its signaling have been shown to illicit biphasic effects on tumor progression and metastasis. We demonstrate in mice that TGF- (Tgf) regulates the expression of a non-canonical signaling member of the wingless-related protein family, Wnt5a. Loss of Wnt5a expression has been associated with poor prognosis in breast cancer patients; however, data are lacking with regard to a functional role for Wnt5a in mammary gland development. We show that Wnt5a is capable of inhibiting ductal extension and lateral branching in the mammary gland. Furthermore, Wnt5a-/-mammary tissue exhibits an accelerated developmental capacity compared with wild-type tissue, marked by larger terminal end buds, rapid ductal elongation, increased lateral branching and increased proliferation. Additionally, dominant-negative interference of TGF- signaling impacts not only the expression of Wnt5a, but also the phosphorylation of discoidin domain receptor 1 (Ddr1), a receptor for collagen and downstream target of Wnt5a implicated in cell adhesion/migration. Lastly, we show that Wnt5a is required for TGF--mediated inhibition of ductal extension in vivo and branching in culture. This study is the first to show a requirement for Wnt5a in normal mammary development and its functional connection to TGF-.
Purpose Signal Transducers and Activators of Transcription (STATs) activate transcription in response to numerous cytokines, controlling proliferation, gene expression and apoptosis. Aberrant activation of STAT proteins, particularly STAT-3, is implicated in the pathogenesis of many cancers, including Globlastoma Multiforme (GBM), by promoting cell cycle progression, stimulating angiogenesis, and impairing tumor immune surveillance. Little is known about the endogenous STAT inhibitors, the Protein Inhibitors of Activated STATs (PIAS) proteins, in human malignancies. The objective of this study was to examine the expression of STAT-3 and its negative regulator, PIAS3, in human tissue samples from control and GBM brains. Experimental Design Control and GBM human tissues were analyzed by immunoblotting and immunohistochemistry to determine the activation status of STAT-3 and expression of the PIAS3 protein. The functional consequence of PIAS3 inhibition by siRNA or PIAS3 over-expression in GBM cells was determined by examining cell proliferation, STAT-3 transcriptional activity and STAT-3 target gene expression. This was accomplished using 3H-TdR incorporation, STAT-3 dominant-negative constructs, RT-PCR and immunoblotting. Results and Conclusions STAT-3 activation, as assessed by tyrosine and serine phosphorylation, was elevated in GBM tissue compared to control tissue. Interestingly, we observed expression of PIAS3 in control tissue, while PIAS3 protein expression in GBM tissue was greatly reduced. Inhibition of PIAS3 resulted in enhanced glioblastoma cellular proliferation. Conversely, PIAS3 over-expression inhibited STAT-3 transcriptional activity, expression of STAT-3 regulated genes, and cell proliferation. We propose that the loss of PIAS3 in GBM contributes to enhanced STAT-3 transcriptional activity and subsequent cell proliferation.
TGF-β, together with IL-6 and IL-21, promotes Th17 cell development. IL-6 and IL-21 induce activation of STAT3, which is crucial for Th17 cell differentiation, as well as the expression of suppressor of cytokine signaling (SOCS)3, a major negative feedback regulator of STAT3-activating cytokines that negatively regulates Th17 cells. However, it is still largely unclear how TGF-β regulates Th17 cell development and which TGF-β signaling pathway is involved in Th17 cell development. In this report, we demonstrate that TGF-β inhibits IL-6- and IL-21-induced SOCS3 expression, thus enhancing as well as prolonging STAT3 activation in naive CD4+CD25− T cells. TGF-β inhibits IL-6-induced SOCS3 promoter activity in T cells. Also, SOCS3 small interfering RNA knockdown partially compensates for the action of TGF-β on Th17 cell development. In mice with a dominant-negative form of TGF-β receptor II and impaired TGF-β signaling, IL-6-induced CD4+ T cell expression of SOCS3 is higher whereas STAT3 activation is lower compared with wild-type B6 CD4+ T cells. The addition of a TGF-β receptor I kinase inhibitor that blocks Smad-dependent TGF-β signaling greatly, but not completely, abrogates the effect of TGF-β on Th17 cell differentiation. Our data indicate that inhibition of SOCS3 and, thus, enhancement of STAT3 activation is at least one of the mechanisms of TGF-β promotion of Th17 cell development.
Fibroblast growth factor (FGF) signaling plays an important role in embryonic stem cells and adult tissue homeostasis, but the function of FGFs in mammary gland stem cells is less well defined. Both FGFR1 and FGFR2 are expressed in basal and luminal mammary epithelial cells (MECs), suggesting that together they might play a role in mammary gland development and stem cell dynamics. Previous studies have demonstrated that the deletion of FGFR2 resulted only in transient developmental defects in branching morphogenesis. Using a conditional deletion strategy, we investigated the consequences of FGFR1 deletion alone and then the simultaneous deletion of both FGFR1 and FGFR2 in the mammary epithelium. FGFR1 deletion using a keratin 14 promoter-driven Cre-recombinase resulted in an early, yet transient delay in development. However, no reduction in functional outgrowth potential was observed following limiting dilution transplantation analysis. In contrast, a significant reduction in outgrowth potential was observed upon the deletion of both FGFR1 and FGFR2 in MECs using adenovirus-Cre. Additionally, using a fluorescent reporter mouse model to monitor Cre-mediated recombination, we observed a competitive disadvantage following transplantation of both FGFR1/R2-null MECs, most prominently in the basal epithelial cells. This correlated with the complete loss of the mammary stem cell repopulating population in the FGFR1/R2-attenuated epithelium. FGFR1/R2-null MECs were partially rescued in chimeric outgrowths containing wild-type MECs, suggesting the potential importance of paracrine mechanisms involved in the maintenance of the basal epithelial stem cells. These studies document the requirement for functional FGFR signaling in mammary stem cells during development.
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