Project description:CD95 was found to be important for both the formation of CSCs and their maintenance. Using a stable isotope labeling by amino acids in cell culture (SILAC) analysis we have now identified STAT1 as a critical gene that mediates the CSC-driving activity of CD95. We report that chronic stimulation of CD95 by either agonist antibodies, soluble CD95L or stably expressed membrane CD95L causes both serine and tyrosine phosphorylation of STAT1 and activation of STAT1 regulated genes. The genes most significantly induced were part of an interferon (IFN)-related DNA damage resistance signature (IRDS) recently identified in a radiation resistant squamous cell carcinoma cell line Nu61 when compared to parental SCC61 cells. The IRDS was found to strongly correlate with therapy resistance (chemotherapy and radiation) in multiple cancer cells as well as in 5 human primary cancers. We now report that CD95 stimulation of breast cancer cell lines or the SCC61 cells induces the upregulation of Type I IFNs that bind to both Type I receptors IFNAR1 and IFNR2 resulting in activation of JAK kinases, activation of STAT1 and induction of a number of STAT1-regulated genes. This process can be inhibited by active caspases. Consequently, we identified Type I IFNs as drivers of cancer stemness. Knockdown of STAT1 using either siRNAs or shRNAs, or deleting two independent sites in the STAT1 gene in MCF-7 cells using the CRIPSR/Cas9 gene editing system resulted in a loss of the ability of CD95 to increase stemness. This identifies STAT1 as a critical mediator of the CSCs-inducing activity of CD95. androgen receptor (AR) activation independently of androgen. We have previously reported that AR can directly repress the expression of many target genes, one of which is NOV/CCN3. Here we show that NOV, primarily localized in the cytoplasm, physically interacts with AR at its Nterminus and sequesters AR and AR variants in the cytoplasm, thereby reducing AR chromatintargeting. This negative feedback loop, however, is disrupted in CRPC due to epigenetic silencing of NOV by the Polycomb group protein EZH2, rendering AR transcriptional activities and drug-resistant prostate cancer progression. Our findings thus suggest a working model wherein AR-repressed genes critically prevent CRPC through negative feedback loops inhibiting AR signaling.

Project description:Nu61, a radiation-resistant human tumor xenograft, was selected from a parental radiosensitive tumor SCC-61 by eight serial cycles of passage in athymic nude mice and in vivo irradiation. Obtained tumors xenografts were profiled in two independent experiments using Affymetrix U133A arrays. Most abundant gene pattern associated with radioresistant phenotype was presented by IFN-inducible, Stat1-dependent pathway. In these experiments we detected genes responding to IFN alpha, beta and gamma in nu61 and SCC61 Experiment Overall Design: Cell lines derived from nu61 and SCC61 were grown in vitro and treated by the mixture of IFNalpha, IFNbeta and IFN gamma (100,100 and 5ng/ml respectively). 5 hours after administration of IFNs cells were lysed, RNA collected and used for hybridization with U133A chips to detect genes responding to IFN treatment in nu61 and SCC61

Project description:CD95 is a member of the TNF receptor superfamily that is ubiquitously expressed in healthy and pathological tissues. Stimulation of CD95 by its physiological ligand CD95L induces its oligomerization leading in turn to the transduction of either apoptotic or non-apoptotic signals. CD95L can exist as both membrane-anchored and soluble forms (sCD95L), the latter resulting from the proteolytic cleavage of the former. Candidate proteases able to achieve CD95L cleavage were identified as matrix metalloproteases (MMP) due to their demonstrated ability to cleave other TNF superfamily ligands. The main goal of this study was to systematically identify the MMP family members capable of cleaving CD95L and subsequently determine the corresponding cleavage sites. By using different orthogonal biochemical approaches and combining them with molecular modeling, we confirmed data from the literature regarding CD95L cleavage by MMP-3 and MMP-7. Moreover, we found that MMP-2 and MMP-12 can cleave CD95L and characterized their resulting cleavage sites. This study provides a systematic approach to analyze the cleavage of CD95L, which until now had only been poorly described.

Project description:>80% of a large number of tested siRNAs and shRNAs targeting CD95 or CD95 ligand (CD95L) induce a form of cell death that is characterized by the simultaneous activation of multiple death pathways and preferentially affects transformed and cancer stem cells. We now show that these si/shRNAs kill cancer cells through canonical RNAi by targeting the 3’UTR of critical survival genes in a unique form of off-target effect. We also provide evidence showing that the full length CD95L mRNA is also toxic and produces small Ago-associated RNAs.

Project description:>80% of a large number of tested siRNAs and shRNAs targeting CD95 or CD95 ligand (CD95L) induce a form of cell death that is characterized by the simultaneous activation of multiple death pathways and preferentially affects transformed and cancer stem cells. We now show that these si/shRNAs kill cancer cells through canonical RNAi by targeting the 3’UTR of critical survival genes in a unique form of off-target effect. We also provide evidence showing that the full length CD95L mRNA is also toxic and produces small Ago-associated RNAs.

Project description:>80% of a large number of tested siRNAs and shRNAs targeting CD95 or CD95 ligand (CD95L) induce a form of cell death that is characterized by the simultaneous activation of multiple death pathways and preferentially affects transformed and cancer stem cells. We now show that these si/shRNAs kill cancer cells through canonical RNAi by targeting the 3’UTR of critical survival genes in a unique form of off-target effect. We also provide evidence showing that the full length CD95L mRNA is also toxic and produces small Ago-associated RNAs.

Project description:>80% of a large number of tested siRNAs and shRNAs targeting CD95 or CD95 ligand (CD95L) induce a form of cell death that is characterized by the simultaneous activation of multiple death pathways and preferentially affects transformed and cancer stem cells. We now show that these si/shRNAs kill cancer cells through canonical RNAi by targeting the 3’UTR of critical survival genes in a unique form of off-target effect. We also provide evidence showing that the full length CD95L mRNA is also toxic and produces small Ago-associated RNAs.

Project description:>80% of a large number of tested siRNAs and shRNAs targeting CD95 or CD95 ligand (CD95L) induce a form of cell death that is characterized by the simultaneous activation of multiple death pathways and preferentially affects transformed and cancer stem cells. We now show that these si/shRNAs kill cancer cells through canonical RNAi by targeting the 3’UTR of critical survival genes in a unique form of off-target effect. We also provide evidence showing that the full length CD95L mRNA is also toxic and produces small Ago-associated RNAs.

Project description:>80% of a large number of tested siRNAs and shRNAs targeting CD95 or CD95 ligand (CD95L) induce a form of cell death that is characterized by the simultaneous activation of multiple death pathways and preferentially affects transformed and cancer stem cells. We now show that these si/shRNAs kill cancer cells through canonical RNAi by targeting the 3’UTR of critical survival genes in a unique form of off-target effect. We also provide evidence showing that the full length CD95L mRNA is also toxic and produces small Ago-associated RNAs.

Project description:The death receptor CD95/Fas can be activated by immune cells to kill cancer cells. However, most siRNAs or shRNAs targeting either CD95 or CD95L induce DICE (Death Induced by CD95/CD95L Elimination), a form of cell death in which a combination of different cell death pathways are activated, that is selective for transformed cells, and that preferentially affects cancer stem cells. We now provide evidence that both CD95 and CD95L are part of a network of genes that contain sequences that when expressed as either siRNAs or shRNAs are toxic to cancer cells. They act through canonical RNAi by targeting the 3'UTRs of critical survival genes. We propose that these embedded toxic sequences are part of a conserved mechanism that regulates cell death, and we predict the existence of endogenous siRNAs, that when produced, induce cell death to regulate genome fidelity. Our data have implications for cancer therapy and the use of RNAi.