Project description:Oncogenic levels of Myc expression sensitize cells to multiple apoptotic stimuli and this protects long-lived organisms from cancer development. How cells discriminate physiological from supra-physiological levels of Myc is largely unknown. Here we show that induction of apoptosis by Myc in breast epithelial cells requires association of Myc with Miz1. Gene expression and ChIP-sequencing experiments show that oncogenic levels of Myc, but not of MycV394D, a point mutant that does not bind Miz1, recruit Miz1 to core promoters and enable binding of Myc/Miz1 complexes to low-affinity target sites, correlating with repression of a specific set of target genes. Repressed genes encode proteins involved in cell adhesion, migration and wound healing; their promoters are enriched for binding sites of the serum response (SRF) factor. Restoring SRF activity attenuates Myc-induced apoptosis in response to glutamine starvation, exposure to Trail and to DNA damage. We propose that supra-physiological levels of Myc engage Miz1 in repressive DNA binding complexes and suppress transcriptional progress. MIZ1, MYC-ER and MYC-ERVD ChIP-Seq with 10E2 and HC20 anti-ERalpha antibodies in MCF10A cells, performed on an Illumina IIx Genome Analyzer. Input sample is accessioned as GSM1423726.

Project description:Oncogenic levels of Myc expression sensitize cells to multiple apoptotic stimuli and this protects long-lived organisms from cancer development. How cells discriminate physiological from supra-physiological levels of Myc is largely unknown. Here we show that induction of apoptosis by Myc in breast epithelial cells requires association of Myc with Miz1. Gene expression and ChIP-sequencing experiments show that oncogenic levels of Myc, but not of MycV394D, a point mutant that does not bind Miz1, recruit Miz1 to core promoters and enable binding of Myc/Miz1 complexes to low-affinity target sites, correlating with repression of a specific set of target genes. Repressed genes encode proteins involved in cell adhesion, migration and wound healing; their promoters are enriched for binding sites of the serum response (SRF) factor. Restoring SRF activity attenuates Myc-induced apoptosis in response to glutamine starvation, exposure to Trail and to DNA damage. We propose that supra-physiological levels of Myc engage Miz1 in repressive DNA binding complexes and suppress transcriptional progr

Project description:Oncogenic levels of Myc expression sensitize cells to multiple apoptotic stimuli and this protects long-lived organisms from cancer development. How cells discriminate physiological from supra-physiological levels of Myc is largely unknown. Here we show that induction of apoptosis by Myc in breast epithelial cells requires association of Myc with Miz1. Gene expression and ChIP-sequencing experiments show that oncogenic levels of Myc, but not of MycV394D, a point mutant that does not bind Miz1, recruit Miz1 to core promoters and enable binding of Myc/Miz1 complexes to low-affinity target sites, correlating with repression of a specific set of target genes. Repressed genes encode proteins involved in cell adhesion, migration and wound healing; their promoters are enriched for binding sites of the serum response (SRF) factor. Restoring SRF activity attenuates Myc-induced apoptosis in response to glutamine starvation, exposure to Trail and to DNA damage. We propose that supra-physiological levels of Myc engage Miz1 in repressive DNA binding complexes and suppress transcriptional progress.

Project description:The mouse promyelocyte (MPRO) granulocyte cell model expressing the MYC-ER fusion protein encoding transgene was used as a system to perform gene expression profiling in a granulocytic cell setting of low endogenous MYC expression (differentiated MYC-ER MPROs, D4) where we then activated the MYC-ER protein for 24 h with 4-OHT (D5T) as compared to a EtOH vehicle treated control (D5E).

Project description:We profiled the transcriptome of HOMycER12 rat fibroblasts whose c-Myc activity was induced to supra-physiological levels with 4-hydroxytamoxifen (OHT). In this dataset, we included the expression data hourly for the first 6 h, then every 2 or 4 hours over a total of 24 h for 4-hydoxytamoxifen activated cells, and expression data from control samples (no 4-hydroxytamoxifen activation) at 8, 16 and 24 h.

Project description:We profiled gene expression and splicing changes in MCF-10A human mammary epithelial cells expressing MYC fused to a portion of estrogen receptor (MYC-ER) (Eilers et al., 1989; Littlewood et al., 1995). We performed RNA-seq, in triplicate, on 3D-grown MCF-10A MYC-ER cells at 0, 8, and 24 hours (h) after 4-OHT-induced MYC activation. As a control for 4-OHT-induced effects, 3D-grown parental MCF-10A cells lacking the MYC-ER fusion protein were treated with 4-OHT at the same timepoints.

Project description:Epithelial-Mesenchymal Transition (EMT) is thought to contribute to cancer metastasis, but its underlying mechanisms are not well understood. To define early steps in this cellular transformation, we analyzed human mammary epithelial cells with tightly regulated expression of Snail-1, a master regulator of EMT. Following Snail-1 induction, epithelial markers were repressed within 6 hours and mesenchymal genes induced at 24 hours. Snail-1 binding to its target promoters was transient (6-48 hours) despite continued protein expression and it was followed by both transient and long-lasting chromatin changes. To generate a potent reversible EMT-inducing stimulus, we created a Snail-1 retroviral expression construct, using a fused estrogen receptor (ER) response element to mediate regulation by exogenous 4-hydroxy-tamoxifen (4-OHT). Since Snail-1 protein stability and nuclear localization are suppressed by GSK3-beta-mediated phosphorylation, we substituted the six targeted amino acids (ER-Snail-1(6SA)), thus conferring constitutive activity to the induced protein (Zhou et al., 2004, Pubmed ID 15448698). Infection of non-transformed, immortalized human mammary epithelial MCF10A cells with ER-Snail-1(6SA), followed by treatment with 4-OHT, triggered morphological and biomarker characteristics of EMT. At 3, 6, 12, 24, 72 and 120 hours after beginning exposure to 4-OHT in ethanol (or, for controls, ethanol only) we extracted RNA and did gene expression analysis using microarrays. We perfomed three replicates of each.

Project description:Epithelial-Mesenchymal Transition (EMT) is thought to contribute to cancer metastasis, but its underlying mechanisms are not well understood. To define early steps in this cellular transformation, we analyzed human mammary epithelial cells with tightly regulated expression of Snail-1, a master regulator of EMT. Following Snail-1 induction, epithelial markers were repressed within 6 hours and mesenchymal genes induced at 24 hours. Snail-1 binding to its target promoters was transient (6-48 hours) despite continued protein expression and it was followed by both transient and long-lasting chromatin changes. To generate a potent reversible EMT-inducing stimulus, we created a Snail-1 retroviral expression construct, using a fused estrogen receptor (ER) response element to mediate regulation by exogenous 4-hydroxy-tamoxifen (4-OHT). Since Snail-1 protein stability and nuclear localization are suppressed by GSK3-beta-mediated phosphorylation, we substituted the six targeted amino acids (ER-Snail-1(6SA)), thus conferring constitutive activity to the induced protein (Zhou et al., 2004, Pubmed ID 15448698). Infection of non-transformed, immortalized human mammary epithelial MCF10A cells with ER-Snail-1(6SA), followed by treatment with 4-OHT, triggered morphological and biomarker characteristics of EMT. At 0, 6, 48 and 120 hours after beginning exposure to 4-OHT in ethanol (or, for controls, ethanol only) we ChIPed Snail-1 and 6 histone marks. We perfomed two replicates of each, except we only had one replicate of H3K27Me3 at 6 hours.

Project description:Experiment description To identify FoxM1-regulated genes, we carried out gene expression profile analysis after inducible activation of a FoxM1-ER fusion protein using high-density human cDNA microarrays. We constructed a stable line of U2OS cells expressing full-length HA-FoxM1 fused at its C-terminus to the ligand-binding domain of the estrogen receptor (ER), mutated such that it specifically responds to 4-hydroxytamoxifen (4-OHT) but not to estrogen. In the absence of 4-OHT the activity of the ER fusion protein is turned off, but can be rapidly induced when cells are exposed to 4-OHT. We isolated total RNA from untreated cultures and cultures treated with 4-OHT for 6 or 16 hr. As activation of FoxM1 results in accumulation of cells in G2/M, we additionally analyzed the induction of gene expression by FoxM1 in G1/S-synchronized cells by a thymidine block. Total RNA derived from untreated or stimulated FoxM1-ER cells was amplified, reverse transcribed, labeled and hybridized to cDNA microarrays containing 18,000 cDNAs and expressed sequence tags (ESTs). Bound cDNA was detected using Cy3 or Cy5 dyes. In each independent experiment we included reverted color controls (Cy3 (4-OHT treated); Cy5 (untreated) or Cy3 (untreated); Cy5 (treated)) and the expression profile was expressed as a Cy5:Cy3 ratio.

Project description:Genomic copy numbers of various generations of Atm-/-TERT-ER mice treated with 4-OHT or vehicle were profiled. Genomic copy numbers of transplanted G3 Atm-/-TERT-ER T-cell lymphomas with telomerase or ALT T-cell lymphomas were developed in various generations of Atm-/-TERT-ER mice with 4-OHT or vehicle treatment. These tumors were profiled with aCGH. G3 Atm-/-TERT-ER tumors were transplanted into SCID mice treated with 4-OHT or vehicle. Cells maintained on vehicle eventually developed ALT-dependent resistance. We used aCGH to profile telomerase+ tumors vs. ALT+ tumors from the same parental lines.