Project description:The transcription factor E2F4 is a member of the E2F family of regulators which has critical roles in cell cycle control and differentiation. We investigated the genome-wide binding profile of E2F4 using a newly developed peak calling program based on a kernel density estimation and identified approximately 16 thousands E2F4 binding sites at a 1% FDR threshold, which potentially modulate 7,346 downstream target genes. Gene Ontology (GO) functional analysis of E2F4 target genes revealed several novel functions of E2F4 including I-kappaB kinase/NF-kappaB cascade, protein transport and targeting, protein folding, and sterol biosynthetic process. In addition to mRNA target genes, E2F4 also binds and regulates some miRNA targets such as let-7a, mir-17 and mir-22. Interestingly, we found that about 20% of E2F4 sites are in intergenic regions, which suggests that E2F4 may function at enhancer sites. De novo motif discovery revealed 5 novel, significantly enriched motifs within E2F4 sites. Only 5% of binding sites contain a canonical motif, indicating that E2F4 can use diverse motifs to bind DNA and regulate transcription. Overexpression of E2F4 and its cofactors such as RBL2 and DP-1, followed by microarray analysis, revealed that E2F4 functions as an activator and a repressor. Taken together, our genome-wide E2F4 ChIP sequencing data provided evidences of versatile physiological roles of E2F4 and insights into its functions. This SuperSeries is composed of the SubSeries listed below.

Project description:The transcription factor E2F4 is a member of the E2F family of regulators which has critical roles in cell cycle control and differentiation. We investigated the genome-wide binding profile of E2F4 using a newly developed peak calling program based on a kernel density estimation and identified approximately 16 thousands E2F4 binding sites at a 1% FDR threshold, which potentially modulate 7,346 downstream target genes. Gene Ontology (GO) functional analysis of E2F4 target genes revealed several novel functions of E2F4 including I-kappaB kinase/NF-kappaB cascade, protein transport and targeting, protein folding, and sterol biosynthetic process. In addition to mRNA target genes, E2F4 also binds and regulates some miRNA targets such as let-7a, mir-17 and mir-22. Interestingly, we found that about 20% of E2F4 sites are in intergenic regions, which suggests that E2F4 may function at enhancer sites. De novo motif discovery revealed 5 novel, significantly enriched motifs within E2F4 sites. Only 5% of binding sites contain a canonical motif, indicating that E2F4 can use diverse motifs to bind DNA and regulate transcription. Overexpression of E2F4 and its cofactors such as RBL2 and DP-1, followed by microarray analysis, revealed that E2F4 functions as an activator and a repressor. Taken together, our genome-wide E2F4 ChIP sequencing data provided evidences of versatile physiological roles of E2F4 and insights into its functions. This SuperSeries is composed of the SubSeries listed below. Refer to individual Series

Project description:In the developing vertebrate nervous system, bHLH proneural factors such as Ascl1 are known to play important regulatory roles at different stages of the neurogenic differentiation process. In spite of the wealth of information gathered on the cellular functions of proneural factors, little was known of the molecular basis for their activities, and in particular of the identity of their target genes. The development of genomic approaches is making possible the characterization of transcriptional programs at an unprecedented scale. Recently, we have used a combination of genomic location analysis by ChIP-on-chip and expression profiling in order to characterize the proneural transcription program regulated by Ascl1 in the ventral telencephalon of the mouse embryonic brain. Our results demonstrate that Ascl1 directly controls successive steps of neurogenesis and provide a molecular frame for previously described Ascl1 functions. In addition, we uncovered an important but previously unrecognized role for Ascl1 in promoting the proliferation of neural progenitors. Here we discuss our recent findings and review them in light of efforts from other laboratories to characterize the transcriptional programs downstream various proneural factors.

Project description:The transcription factor GATA-1 is required for terminal erythroid maturation and functions as an activator or repressor depending on gene context. Yet its in vivo site selectivity and ability to distinguish between activated versus repressed genes remain incompletely understood. In this study, we performed GATA-1 ChIP-seq in erythroid cells and compared it to GATA-1-induced gene expression changes. Bound and differentially expressed genes contain a greater number of GATA-binding motifs, a higher frequency of palindromic GATA sites, and closer occupancy to the transcriptional start site versus nondifferentially expressed genes. Moreover, we show that the transcription factor Zbtb7a occupies GATA-1-bound regions of some direct GATA-1 target genes, that the presence of SCL/TAL1 helps distinguish transcriptional activation versus repression, and that polycomb repressive complex 2 (PRC2) is involved in epigenetic silencing of a subset of GATA-1-repressed genes. These data provide insights into GATA-1-mediated gene regulation in vivo.

Project description:Candida albicans, the major human fungal pathogen, undergoes a reversible morphological transition from blastospores (round budding cells) to filaments (elongated cells attached end-to-end). This transition, which is induced upon exposure of C. albicans cells to a number of host conditions, including serum and body temperature (37 degrees C), is required for virulence. Using whole-genome DNA microarray analysis, we describe 61 genes that are significantly induced (> or =2-fold) during the blastospore to filament transition that takes place in response to exposure to serum and 37 degrees C. We next show that approximately half of these genes are transcriptionally repressed in the blastospore state by three transcriptional repressors, Rfg1, Nrg1, and Tup1. We conclude that the relief of this transcriptional repression plays a key role in bringing the C. albicans filamentous growth program into play, and we describe the framework of this transcriptional circuit.

Project description:Failure to cure ovarian cancer relates to the persistence of dormant, drug-resistant cancer cells following surgery and chemotherapy. "Second look" surgery can detect small, poorly vascularized nodules of persistent ovarian cancer in ~50% of patients, where >80% are undergoing autophagy and express DIRAS3. Autophagy is one mechanism by which dormant cancer cells survive in nutrient poor environments. DIRAS3 is a tumor suppressor gene downregulated in >60% of primary ovarian cancers by genetic, epigenetic, transcriptional and post-transcriptional mechanisms, that upon re-expression can induce autophagy and dormancy in a xenograft model of ovarian cancer. We examined the expression of DIRAS3 and autophagy in ovarian cancer cells following nutrient deprivation and the mechanism by which they are upregulated. We have found that DIRAS3 mediates autophagy induced by amino acid starvation, where nutrient sensing by mTOR plays a central role. Withdrawal of amino acids downregulates mTOR, decreases binding of E2F1/4 to the DIRAS3 promoter, upregulates DIRAS3 and induces autophagy. By contrast, acute amino acid deprivation did not affect epigenetic regulation of DIRAS3 or expression of miRNAs that regulate DIRAS3. Under nutrient poor conditions DIRAS3 can be transcriptionally upregulated, inducing autophagy that could sustain dormant ovarian cancer cells.

Project description:Breast and ovarian cancer susceptibility genes BRCA1 and PALB2 have enigmatic roles in cellular growth and mammalian development. While these genes are essential for growth during early developmental programs, inactivation later in adulthood results in increased growth and formation of tumors, leading to their designation as tumor suppressors. We performed genome-wide analysis assessing their chromatin residence and gene expression responsiveness using high-throughput sequencing in breast epithelial cells. We found an intimate association between BRCA1 and PALB2 chromatin residence and genes displaying high transcriptional activity. Moreover, our experiments revealed a critical role for BRCA1 and, to a smaller degree, PALB2 in transcriptional responsiveness to NF-κB, a crucial mediator of growth and inflammatory response during development and cancer. Importantly, we also uncovered a vital role for BRCA1 and PALB2 in response to retinoic acid (RA), a growth inhibitory signal in breast cancer cells, which may constitute the basis for their tumor suppressor activity. Taken together, our results highlight an important role for these breast cancer proteins in the regulation of diverse growth regulatory pathways.

Project description:E2F transcription factors are central regulators of cell cycle progression and cell fate decisions in mammalian cells. E2F4 is a transcriptional repressor implicated in cell cycle arrest and whose repressive activity depends on its interaction with members of the RB family. E2F4 often represents the predominant E2F activity in cells. Here we show that E2F4 is important for the proliferation and the survival of mouse embryonic stem cells. In these cells, E2F4 acts in part as a transcriptional activator that promotes the expression of cell cycle genes. Importantly, this role for E2F4 is completely independent of the RB family. Accordingly, an unbiased analysis of the E2F4 interactome shows that E2F4 functionally interacts with chromatin regulators associated with gene activation in RB family-mutant cells. Taken together, our findings uncover a non-canonical role for E2F4 that reveal novel insights into the biology of rapidly dividing cell types.

Project description:E2F transcription factors are central regulators of cell division and cell fate decisions. E2F4 often represents the predominant E2F activity in cells. E2F4 is a transcriptional repressor implicated in cell cycle arrest and whose repressive activity depends on its interaction with members of the RB family. Here we show that E2F4 is important for the proliferation and the survival of mouse embryonic stem cells. In these cells, E2F4 acts in part as a transcriptional activator that promotes the expression of cell cycle genes. This role for E2F4 is independent of the RB family. Furthermore, E2F4 functionally interacts with chromatin regulators associated with gene activation and we observed decreased histone acetylation at the promoters of cell cycle genes and E2F targets upon loss of E2F4 in RB family-mutant cells. Taken together, our findings uncover a non-canonical role for E2F4 that provide insights into the biology of rapidly dividing cells.

Project description:The p53 tumor suppressor protein is a major sensor of cellular stresses, and upon stabilization, activates or represses many genes that control cell fate decisions. While the mechanism of p53-mediated transactivation is well established, several mechanisms have been proposed for p53-mediated repression. Here, we demonstrate that the cyclin-dependent kinase inhibitor p21 is both necessary and sufficient for the downregulation of known p53-repression targets, including survivin, CDC25C, and CDC25B in response to p53 induction. These same targets are similarly repressed in response to p16 overexpression, implicating the involvement of the shared downstream retinoblastoma (RB)-E2F pathway. We further show that in response to either p53 or p21 induction, E2F4 complexes are specifically recruited onto the promoters of these p53-repression targets. Moreover, abrogation of E2F4 recruitment via the inactivation of RB pocket proteins, but not by RB loss of function alone, prevents the repression of these genes. Finally, our results indicate that E2F4 promoter occupancy is globally associated with p53-repression targets, but not with p53 activation targets, implicating E2F4 complexes as effectors of p21-dependent p53-mediated repression.