Project description:K-ras is one of the most frequently mutated human oncogenes. Activation of K-ras can lead to either senescence or proliferation in primary cells. The precise mechanism governing these distinct outcomes remains unclear. Here we utilized a loss-of-function screen to assess the role of specific genes identified as potential key regulators of K-ras driven oncogenesis. Using this approach, we identify the transcription factor Wt1 as an inhibitor of senescence in primary cells expressing oncogenic K-ras. Deletion or suppression of Wt1 expression leads to senescence of primary cells expressing oncogenic K-ras under the control of the native promotor at physiological levels, but has no effect on cells expressing wild-type K-ras. Wt1 contributes to K-ras driven lung tumorigenesis in vivo and loss of Wt1 is specifically deleterious to human lung cancer cell lines that are dependent on oncogenic K-ras. Taken together, these observations reveal a novel role for Wt1 as a key regulator of the complex genetic network required for the oncogenic effect of the small GTPase K-ras. We compare the expression profiles of Wild type, K-ras mutant, Wt1-null, and double K-ras mutant/Wt1-null mouse embryonic fibroblasts (MEFs). The study provides insights into the transcriptional role of Wt1 in the context of oncogenic K-ras. MEFs were infected with adenoviral Cre to activate K-ras (6 samples), knockout Wt1 (5 samples), both activate K-ras and knockout Wt1 (7 samples). As a control, MEFs were infected with adenoviral GFP (5 samples). RNA was isolated using Trizol 7 days after infection. RNA was further prepared by passage over an RNeasy column. cDNA synthesis, biotinylation of cRNA and hybridization to mouse Genechip 430A v2 containing 39,000 probes was performed according to the manufacturer's instructions (Affymetrix, Santa Clara). Microarray data was normalized with Expression Console software (Affymetrix, Santa Clara) using RMA algorithms.

Project description:K-ras is one of the most frequently mutated human oncogenes. However, activation of K-ras can lead to either senescence or proliferation in primary cells. The precise mechanism governing these distinct outcomes remains unclear. Here we describe a novel loss-of-function screen to assess the role of specific genes identified as potential key regulators of K-ras driven oncogenesis. Using this approach, we identify the transcription factor Wt1 as an inhibitor of senescence in primary cells expressing oncogenic K-ras. Deletion or suppression of Wt1 expression leads to senescence of primary cells expressing oncogenic K-ras under the control of the native promotor and at physiological levels, but had no effect on cells expressing wild-type K-ras. Furthermore, loss of Wt1 in lung cancer cell lines that harbor mutant K-ras leads to apoptosis. Taken together, these observations reveal a novel role for Wt1 as a key regulator of the complex genetic network required for the oncogenic effect of the small GTPase K-ras. We compare the expression profiles of K-ras mutant mouse cell line (LKR13) upon shRNA knockdown of K-ras itself or Wt1. The study provides insights into the transcriptional role of Wt1 in the context of oncogenic K-ras.

Project description:K-ras is one of the most frequently mutated human oncogenes. However, activation of K-ras can lead to either senescence or proliferation in primary cells. The precise mechanism governing these distinct outcomes remains unclear. Here we describe a novel loss-of-function screen to assess the role of specific genes identified as potential key regulators of K-ras driven oncogenesis. Using this approach, we identify the transcription factor Wt1 as an inhibitor of senescence in primary cells expressing oncogenic K-ras. Deletion or suppression of Wt1 expression leads to senescence of primary cells expressing oncogenic K-ras under the control of the native promotor and at physiological levels, but had no effect on cells expressing wild-type K-ras. Furthermore, loss of Wt1 in lung cancer cell lines that harbor mutant K-ras leads to apoptosis. Taken together, these observations reveal a novel role for Wt1 as a key regulator of the complex genetic network required for the oncogenic effect of the small GTPase K-ras. We compare the expression profiles of K-ras mutant mouse cell line (LKR13) upon shRNA knockdown of K-ras itself or Wt1. The study provides insights into the transcriptional role of Wt1 in the context of oncogenic K-ras. LKR13 cells were infected with plko.1s vectors carrying one of two shRNAs against K-ras or Wt1. Control cells were infected with an shRNA against GFP. 48 hours after infection, cells were selected with puromycin for 3 days. RNA was isolated using Trizol 7 days after infection. RNA was further prepared by passage over an RNeasy column. cDNA synthesis, biotinylation of cRNA and hybridization to mouse Genechip 430A v2 containing 39,000 probes was performed according to the manufacturerâ??s instructions (Affymetrix, Santa Clara). Microarray data was normalized with Expression Console software (Affymetrix, Santa Clara), using RMA algorithms.

Project description:During oncogenic transformation, cells acquire genetic mutations that override the normal mechanisms regulating cellular proliferation. Excessive expression of activating transcription factor 4 (ATF4) is often observed in mammalian malignant tumors. However, little is known about the role of ATF4 in the malignant transformation of normal cells. Here, we show that ATF4 promotes oncogene-induced malignant transformation of murine fibroblasts by suppressing the expression of cellular senescence-associated genes. Ectopic expression of oncogenes, H-rasV12 and simian virus 40 large T-antigen, elicited malignant transformation of embryonic fibroblasts from wild-type mice, but not from Atf4-null (Atf4-/-) mice. The oncogenic stresses induced the expression of both Atf4 and cyclin-dependent kinase inhibitor 2a (Cdkn2a), in wild-type cells. Elevated levels of ATF4 successively suppressed the expression of cdkn2a encoding the cellular senescence-associated proteins, p16INK4a and p19ARF, thereby promoting oncogenic transformation. Conversely, the loss of ATF4 caused cellular senescence resulting from the consistent expression of p16INK4a and p19ARF. These findings reveal a novel function of ATF4: that of promoting oncogenic transformation by suppressing cellular senescence. Total 2 samples were derived from [1] H-Ras and SV40T expressing vector-transfected wild-type mouse embryonic fibroblasts (MEFs) and [2] H-Ras and SV40T expressing vector-transfected Atf4-/- MEFs

Project description:Oncogenic ras activates several signaling pathways that cooperate in cell transformation. They include the ERK/MAP kinase pathway, the PI3K pathway and the Ral pathway among others. Surprisingly, in primary human fibroblasts, oncogenic ras expression induces senescence not transformation, but upon knockdown of ERK2 senescence is bypassed and transformation is stimulated. We used microarrays to characterize the gene expression programme of cells transformed by oncogenic ras, telomerase and knockdown of the ERK2 kinase. Primary human fibroblasts were co-infected with a retroviral vector that expresses oncogenic ras and either a control shRNA or an shRNA against ERK2. Cells with oncogenic ras and shRNA control entered senescence while cells with oncogenic ras and shRNA ERK2 bypassed senescence and underwent malignant transformation. Triplicates of these populations were used to purify total RNA, which we sent to Genome Quebec service for hybridization with Affymetrix microarrays.

Project description:EWS fusion oncoproteins underlie the pathogenesis of several human malignancies including Desmoplastic Small Round Cell Tumor (DSRCT), an aggressive mesenchymal tumor driven by fusions between the disordered domain of EWS and the developmental transcription factor WT1. Here we combined chromatin occupancy and long-range interaction profiles to identify EWS-WT1-dependent gene regulation networks and directly controlled target genes. We show that EWS-WT1 operates primarily as a powerful activator of distal regulatory elements and controls an oncogenic gene expression program that characterize primary DSRCTs. Moreover, EWS-WT1 has two isoforms that differ by three amino acids in their DNA binding domain (+/- KTS), as observed for wild type WT1, and we show that each fusion isoform has a specific DNA binding profile that is distinct from its wild type counterparts and requires a functional EWSR1 prion like domain. Remarkably, xenograft experiments using human mesothelial cells, candidate cells of origin of DSRCT, reveal that both isoforms are required to generate viable tumors that resemble DSRCT. Finally, we identify new candidate EWS-WT1 target genes with potential therapeutic implications, including CCND1, whose inhibition by the clinically-approved drug Palbociclib leads to marked tumor burden decrease in DSRCT PDXs in vivo. Taken together, our studies identify gene regulation programs and therapeutic vulnerabilities in DSRCT and provide a mechanistic understanding of the complex isoform-dependent oncogenic activity of EWS-WT1.

Project description:EWS fusion oncoproteins underlie the pathogenesis of several human malignancies including Desmoplastic Small Round Cell Tumor (DSRCT), an aggressive mesenchymal tumor driven by fusions between the disordered domain of EWS and the developmental transcription factor WT1. Here we combined chromatin occupancy and long-range interaction profiles to identify EWS-WT1-dependent gene regulation networks and directly controlled target genes. We show that EWS-WT1 operates primarily as a powerful activator of distal regulatory elements and controls an oncogenic gene expression program that characterize primary DSRCTs. Moreover, EWS-WT1 has two isoforms that differ by three amino acids in their DNA binding domain (+/- KTS), as observed for wild type WT1, and we show that each fusion isoform has a specific DNA binding profile that is distinct from its wild type counterparts and requires a functional EWSR1 prion like domain. Remarkably, xenograft experiments using human mesothelial cells, candidate cells of origin of DSRCT, reveal that both isoforms are required to generate viable tumors that resemble DSRCT. Finally, we identify new candidate EWS-WT1 target genes with potential therapeutic implications, including CCND1, whose inhibition by the clinically-approved drug Palbociclib leads to marked tumor burden decrease in DSRCT PDXs in vivo. Taken together, our studies identify gene regulation programs and therapeutic vulnerabilities in DSRCT and provide a mechanistic understanding of the complex isoform-dependent oncogenic activity of EWS-WT1.

Project description:EWS fusion oncoproteins underlie the pathogenesis of several human malignancies including Desmoplastic Small Round Cell Tumor (DSRCT), an aggressive mesenchymal tumor driven by fusions between the disordered domain of EWS and the developmental transcription factor WT1. Here we combined chromatin occupancy and long-range interaction profiles to identify EWS-WT1-dependent gene regulation networks and directly controlled target genes. We show that EWS-WT1 operates primarily as a powerful activator of distal regulatory elements and controls an oncogenic gene expression program that characterize primary DSRCTs. Moreover, EWS-WT1 has two isoforms that differ by three amino acids in their DNA binding domain (+/- KTS), as observed for wild type WT1, and we show that each fusion isoform has a specific DNA binding profile that is distinct from its wild type counterparts and requires a functional EWSR1 prion like domain. Remarkably, xenograft experiments using human mesothelial cells, candidate cells of origin of DSRCT, reveal that both isoforms are required to generate viable tumors that resemble DSRCT. Finally, we identify new candidate EWS-WT1 target genes with potential therapeutic implications, including CCND1, whose inhibition by the clinically-approved drug Palbociclib leads to marked tumor burden decrease in DSRCT PDXs in vivo. Taken together, our studies identify gene regulation programs and therapeutic vulnerabilities in DSRCT and provide a mechanistic understanding of the complex isoform-dependent oncogenic activity of EWS-WT1.

Project description:EWS fusion oncoproteins underlie the pathogenesis of several human malignancies including Desmoplastic Small Round Cell Tumor (DSRCT), an aggressive mesenchymal tumor driven by fusions between the disordered domain of EWS and the developmental transcription factor WT1. Here we combined chromatin occupancy and long-range interaction profiles to identify EWS-WT1-dependent gene regulation networks and directly controlled target genes. We show that EWS-WT1 operates primarily as a powerful activator of distal regulatory elements and controls an oncogenic gene expression program that characterize primary DSRCTs. Moreover, EWS-WT1 has two isoforms that differ by three amino acids in their DNA binding domain (+/- KTS), as observed for wild type WT1, and we show that each fusion isoform has a specific DNA binding profile that is distinct from its wild type counterparts and requires a functional EWSR1 prion like domain. Remarkably, xenograft experiments using human mesothelial cells, candidate cells of origin of DSRCT, reveal that both isoforms are required to generate viable tumors that resemble DSRCT. Finally, we identify new candidate EWS-WT1 target genes with potential therapeutic implications, including CCND1, whose inhibition by the clinically-approved drug Palbociclib leads to marked tumor burden decrease in DSRCT PDXs in vivo. Taken together, our studies identify gene regulation programs and therapeutic vulnerabilities in DSRCT and provide a mechanistic understanding of the complex isoform-dependent oncogenic activity of EWS-WT1.

Project description:EWS fusion oncoproteins underlie the pathogenesis of several human malignancies including Desmoplastic Small Round Cell Tumor (DSRCT), an aggressive mesenchymal tumor driven by fusions between the disordered domain of EWS and the developmental transcription factor WT1. Here we combined chromatin occupancy and long-range interaction profiles to identify EWS-WT1-dependent gene regulation networks and directly controlled target genes. We show that EWS-WT1 operates primarily as a powerful activator of distal regulatory elements and controls an oncogenic gene expression program that characterize primary DSRCTs. Moreover, EWS-WT1 has two isoforms that differ by three amino acids in their DNA binding domain (+/- KTS), as observed for wild type WT1, and we show that each fusion isoform has a specific DNA binding profile that is distinct from its wild type counterparts and requires a functional EWSR1 prion like domain. Remarkably, xenograft experiments using human mesothelial cells, candidate cells of origin of DSRCT, reveal that both isoforms are required to generate viable tumors that resemble DSRCT. Finally, we identify new candidate EWS-WT1 target genes with potential therapeutic implications, including CCND1, whose inhibition by the clinically-approved drug Palbociclib leads to marked tumor burden decrease in DSRCT PDXs in vivo. Taken together, our studies identify gene regulation programs and therapeutic vulnerabilities in DSRCT and provide a mechanistic understanding of the complex isoform-dependent oncogenic activity of EWS-WT1.