Project description:A genome-wide survey of transcriptional targets responding to chronic KRAS/MAPK (mitogen-activated protein kinase) pathway activation in rat ovarian surface epithelial cells (ROSE 199) has identified multiple differentially expressed transcriptional regulators including the architectural transcription factor high mobility group AT hook 2 (HMGA2). To elucidate the role of HMGA2 in the transcriptional network affected by oncogenic signaling, we used an integrated approach combining RNAi-mediated silencing, microarray-based expression profiling, computational prediction of transcription factor binding sites in target gene promoters and phenotypic analysis. Knocking-down HMGA2 resulted in the reversion of epithelial-mesenchymal transition, loss of anchorage independence and in a substantial restoration of the gene expression pattern characteristic of non-transformed ROSE cells. Computational prediction of transcription factor binding sites in the promoters of HMGA2-regulated genes and expression profiling revealed a preferential role of activator complex-1 (AP-1) components Fra-1 and JunB in target gene regulation. Forced expression of HMGA2 did not transform normal ovarian epithelial cells, suggesting that HMGA2 up-regulation is not sufficient for inducing the transformed phenotype, but mediates cancer-specific phenotypic traits in cells expressing mutated KRAS and, hence, oncogene addiction. The Ras signaling target array was designed and produced as described (Tchernitsa et al., 2005). Briefly, we selected 121 genes recovered from subtracted cDNA libraries representing sequences differentially expressed in parental and KRAStransformed ROSE 199 cells (Tchernitsa et al., 2004). In addition, we selected genes from subtracted libraries representing sequences differentially expressed in normal 208F fibroblasts and the HRAS-transformed derivative FE-8 (Zuber et al., 2000). Previously described Ras pathway targets and 13 different genes described as housekeeping genes in many different tissues and cell lines were included to permit normalization of hybridization intensities on microarrays. The total number of gene probes is 325 on the array. Unmodified 70-mer DNA oligonucleotides were chosen as probe sets for the array. The oligonucleotide design was performed with software available on the web (http://oligo.lnatools.com/expression/) using the following parameters: option for LNA frequency=0, melting temperature between 74°C and 76°C, GC content between 45- 55%, absence of strong secondary structures and proximity to 3’ end of coding sequence. Oligonucleotides were synthesized at Illumina, Inc (San-Diego, USA) at the 50 nmol scale. Each of the 325 oligonucleotides was spotted four times at a different location on the slides. Thus, the array contains 1,300 features. Overall the study contains six samples. We studied for conditions: First condition is influence of empty plasmid on ROSE199 cells. No additional hybridization replica. Sample 199_199emptyvector Second condition is influence of siEGFP (used as a scramble duplex) on ROSEA25 cell line. As there was no influence of siEGFP on A25cell line and genes differentially expressed between ROSE199 and ROSEA25 were previously described in our several publication here we also used only one hybridization replica. Sample ROSE199_ROSEA25siEGFP. Third condition is influence of HMGA2 expression vector on ROSE199 cells. One dye swap replica was done. Samples: ROSE199_ROSE199HMGA2 and 199HMGA2_199. Forth condition is influence of siHMGA2 duplex on ROSEA25 cell line compared to ROSE199 cell line. One replica with dye swap. Samples ROSE199_ROSEA25siGMGA2 and ROSEA25siHMGA2_ROSE199.

Project description:RAS mutations are highly relevant for progression and therapy response of human tumours, but the genetic network that ultimately executes the oncogenic effects is poorly understood. Here we used a reverse-engineering approach in an ovarian cancer model to reconstruct KRAS oncogene-dependent cytoplasmic and transcriptional networks from perturbation experiments based on gene silencing and pathway inhibitor treatments. We measured mRNA and protein levels in manipulated cells by microarray, RT-PCR and Western Blot analysis, respectively. The reconstructed model revealed complex interactions among the transcriptional and cytoplasmic components, some of which were confirmed by double pertubation experiments. Interestingly, the transcription factors decomposed into two hierarchically arranged groups. To validate the model predictions we analysed growth parameters and transcriptional deregulation in the KRAS-transformed epithelial cells. As predicted by the model, we found two functional groups among the selected transcription factors. The experiments thus confirmed the predicted hierarchical transcription factor regulation and showed that the hierarchy manifests itself in downstream gene expression patterns and phenotype. RAS-ROSE cells and ROSE cells treated with Scrambled siRNA

Project description:RAS mutations are highly relevant for progression and therapy response of human tumours, but the genetic network that ultimately executes the oncogenic effects is poorly understood. Here we used a reverse-engineering approach in an ovarian cancer model to reconstruct KRAS oncogene-dependent cytoplasmic and transcriptional networks from perturbation experiments based on gene silencing and pathway inhibitor treatments. We measured mRNA and protein levels in manipulated cells by microarray, RT-PCR and Western Blot analysis, respectively. The reconstructed model revealed complex interactions among the transcriptional and cytoplasmic components, some of which were confirmed by double pertubation experiments. Interestingly, the transcription factors decomposed into two hierarchically arranged groups. To validate the model predictions we analysed growth parameters and transcriptional deregulation in the KRAS-transformed epithelial cells. As predicted by the model, we found two functional groups among the selected transcription factors. The experiments thus confirmed the predicted hierarchical transcription factor regulation and showed that the hierarchy manifests itself in downstream gene expression patterns and phenotype. RAS-ROSE cells were treated with siRNA against 7 transcription factors or controls,

Project description:To identify HMGA2-regulated downstream target microRNAs, we compared the difference of microRNA profiles between ovarian surface epithelial cells without HMGA2 (T29) and cells with HMGA2 (T29A2). Immortalized ovarian surface epithelial cells (named T29) were transfected with HMGA2 retrovirus vector pBabe-HMGA2 (named T29A2). Then cells were harvested for RNA isolation for microRNA expression analysis.

Project description:To identify HMGA2-regulated downstream target genes, we compared the difference of gene profiles between ovarian surface epithelial cells without HMGA2 (T29-1, T29-2, T80) and cells with HMGA2 (T29A2-8, T29A2-15, T80A2-11). Immortalized ovarian surface epithelial cells (named T29-1, T29-2, T80) were transfected with HMGA2 retrovirus vector pBabe-HMGA2 (named T29A2-8, T29A2-15, T80A2-11). Then cells were harvested for RNA isolation for gene expression analysis. Control group: T29-1, T29-2, T80. Testing group: T29A2-8, T29A2-15, T80A2-11.

Project description:To identify HMGA2-regulated downstream target microRNAs, we compared the difference of microRNA profiles between ovarian surface epithelial cells without HMGA2 (T29) and cells with HMGA2 (T29A2).

Project description:To identify HMGA2-regulated downstream target genes, we compared the difference of gene profiles between ovarian surface epithelial cells without HMGA2 (T29-1, T29-2, T80) and cells with HMGA2 (T29A2-8, T29A2-15, T80A2-11).

Project description:Mutations in RAS proteins occur in 30% of human tumours and have a high relevance in tumor progression. Despite the importance of the underlying genetic network that governs the effects of oncogenic RAS, it is still poorly understood. We developed and applied a reverse-engineering approach in order to reconstruct the network structure of the signaling and gene-regulatory network downstream of RAS from perturbation experiments. We performed microarray, RT-PCR and Western Blot analysis to detect mRNA and protein levels of cytoplasmatic and nuclear targets downstream of RAS after systematic perturbation of the signaling pathways and knock-down of selected transcription factors in KRAS-transformed ovarian surface epithelium cell lines. The reconstructed model shows that the investigated components are connected through a complex network. The transcription factors decomposed into two hierarchically arranged groups. While knock-down of all investigated transcription factors showed a partial reversion of the malignant phenotype, different growth assays show that these two groups of transcription factors control different functions in the malignant anchorage-independent growth and cell cycle regulation of the ROSE cells. Furthermore, the model showed strong regulatory interplay of inhibitory and activating interactions between the RAS-dependent trancriptional network and cytoplasmatic signaling components. Overall the study contains 32 samples. We studied the influence of seven transcription factors (Fosl1, Gfi1, Hmga2, Junb, Klf6, Otx1, Rela) being knocked down by means of RNA interference. Two independent siRNA duplexes (N1, N2) against the same gene were used. All experiments were done with Cy3/Cy5 dye-swaps. As a negative control, we used scrambled siRNAs. Off-target effect was estimated by comparison of the scrambled siRNA treatment and an unterated cell line ROSEA 25.

Project description:This SuperSeries is composed of the following subset Series: GSE38584: Hierarchical regulation in a KRAS pathway-dependent transcriptional network revealed by a reverse-engineering approach (7TF and control) GSE38585: Hierarchical regulation in a KRAS pathway-dependent transcriptional network revealed by a reverse-engineering approach (RAS-ROSE and ROSE with siRNA) Refer to individual Series

Project description:Loss of Pten in the KrasG12D;Amhr2-Cre mutant mice leads to the transformation of ovarian surface epithelial (OSE) cells and rapid development of low-grade, invasive serous adenocarcinomas. Tumors occur with 100% penetrance and express elevated expression of wild type tumor repressor protein 53 (TRP53). To test the functions of TRP53 in the Pten;Kras (Trp53+) mice, we disrupted the Trp53 gene yielding Pten;Kras(Trp53-) mice. By comparing morphology and gene expression profiles in the Trp53+ and Trp53- OSE cells, we document that wild-type TRP53 acts as a major promoter of OSE cell survival and differentiation: cells lacking Trp53 are transformed yet are less adherent, migratory and invasive and exhibit a gene expression profile more like normal OSE cells. These results provide a new paradigm: wild type TRP53 does not preferentially induce apoptotic or senescent related genes in the Pten;Kras(Trp53+) cancer cells but rather increases genes regulating DNA repair, cell cycle progression and proliferation and decreases putative tumor suppressor genes. However, if TRP53 activity is forced higher by exposure to nutlin-3a (an MDM2 antagonist), TRP53 suppresses DNA repair genes and induces the expression of genes that control cell cycle arrest and apoptosis. Thus, in the Pten;Kras(Trp53+) mutant mouse OSE cells and likely in human TP53+ low grade ovarian cancer cells, wild type TRP53 controls global molecular changes that are dependent on its activation status. These results suggest that activation of TP53 may provide a promising new therapy for managing type I ovarian cancer and other cancers in humans where wild-type TP53 is expressed. A direct comparison of ovarian surface epithelia cells from three different genotype mice