Project description:In vivo protein-DNA interactions connect each transcription factor with its direct targets to form a gene network scaffold. To map these protein-DNA interactions comprehensively across entire mammalian genomes, we developed a large-scale chromatin immunoprecipitation assay (ChIPSeq) based on direct ultrahigh-throughput DNA sequencing. This sequence census method was then used to map in vivo binding of the neuron-restrictive silencer factor (NRSF; also known as REST, for repressor element–1 silencing transcription factor) to 1946 locations in the human genome. The data display sharp resolution of binding position [±50 base pairs (bp)], which facilitated our finding motifs and allowed us to identify noncanonical NRSF-binding motifs. These ChIPSeq data also have high sensitivity and specificity [ROC (receiver operator characteristic) area ≥ 0.96] and statistical confidence (P < 10−4), properties that were important for inferring new candidate interactions. These include key transcription factors in the gene network that regulates pancreatic islet cell development.

Project description:Repressor element-1 silencing transcription factor (REST) or neuron-restrictive silencer factor (NRSF) is a zinc-finger (ZF) containing transcriptional repressor that recognizes thousands of neuron-restrictive silencer elements (NRSEs) in mammalian genomes. How REST/NRSF regulates gene expression remains incompletely understood. Here, we investigate the binding pattern and regulation mechanism of REST/NRSF in the clustered protocadherin (PCDH) genes. We find that REST/NRSF directionally forms base-specific interactions with NRSEs via tandem ZFs in an anti-parallel manner but with striking conformational changes. In addition, REST/NRSF recruitment to the HS5-1 enhancer leads to the decrease of long-range enhancer-promoter interactions and downregulation of the clustered PCDH alpha genes. Thus, REST/NRSF represses PCDH alpha gene expression through directional binding to a repertoire of NRSEs within the distal enhancer and variable target genes.

Project description:The goal of this study was discover the transcription binding synthax for the key differentiation TFs in mouse embryonic stem cells. Genes are regulated through enhancer sequences, in which transcription factor binding motifs and their specific arrangements (syntax) form a cis-regulatory code. To understand the relationship between motif syntax and transcription factor binding, we train a deep learning model that uses DNA sequence to predict base-resolution binding profiles of four pluripotency transcription factors Oct4, Sox2, Nanog, and Klf4. We interpret the model to accurately map hundreds of thousands of motifs in the genome, learn novel motif representations and identify rules by which motifs and syntax influence transcription factor binding. We find that instances of strict motif spacing are largely due to retrotransposons, but that soft motif syntax influences motif interactions at protein and nucleosome range. Most strikingly, Nanog binding is driven by motifs with a strong preference for ~10.5 bp spacings corresponding to helical periodicity. Interpreting deep learning models applied to high-resolution binding data is a powerful and versatile approach to uncover the motifs and syntax of cis-regulatory sequences.

Project description:The transcription factor NRSF/REST represses many vertebrate neuronal genes in non-neuronal cells by binding to 3 distinct motif classes, which are the canonical 21bp NRSEs, longer non-canonical sites and solo half-sites. We used ChIP-seq in four mammalian species to determine the evolution of the NRSF binding repertoire. We show that while some NRSEs are deeply conserved, genes with several NRSEs show evidence of compensatory site turnover, suggesting that the association of the transcription factor to its target gene is more important than the specific binding site. We also found that many newborn sites in human are associated with primate specific indels and transposable elements. Our analysis of sites with conserved ChIP-binding in all 4 species demonstrates that both the non-canonical and solo half-sites convert preferentially to canonical motifs. These findings support a model of dynamic conversion between different motif types that account for the preferential accumulation of the canonical NRSE during evolution.

Project description:Transcription Factor Binding Sites by Motifs Scan

Project description:The goal of this study was to identify genomic binding sites of the NRSF/REST transcription factor under conditions of basal and increased SF-1 dosage in the H295R human adrenocortical tumor cell line. 4 samples: input DNA (2 replicates) - NRSF/REST ChIP basal SF-1 dosage - NRSF/REST ChIP increased SF-1 dosage

Project description:Analysis of HeLa cell with overexpression of an EGFP-tagged dominant-negative truncation (73- 563 a.a.) of human REST/NRSF. RNA polymerase II and DNA damage repair factor γ-H2AX binding data provide insight into the molecular bases of how REST/NRSF perturbation impairs genome stability.

Project description:The vertebrate-specific transcription factor RE-1 silencing transcription factor or neuron-restrictive silencer factor (REST/NRSF) was first described as a negative regulator restricting expression of neuronal genes to neurons in a variety of genetic contexts. However, REST/NRSF has a more general role in the regulation of gene expression that involves chromatin remodelling via a SWI/SNF complex. We identified a 677 gene repertoire of potential REST/NRSF-dependent genes taking advantage of Rest/Nrsf gene silencing in a mouse cell line. Using Ka/Ks analysis, we found that REST/NRSF protein, REST/NRSF interactors and the products of REST/NRSF-dependent genes display significantly higher rates of protein evolution in primates than in rodents. The McDonald-Kreitman test indicated positive selection for human REST/NRSF and nuclear RNA-binding proteins encoded by REST/NRSFdependent genes. In these proteins, we demonstrated sites under positive selection within the primate’s clade. Importantly, the REST/NRSF-dependent gene repertoire is statistically enriched in genes disrupted in neuropsychiatric diseases such as schizophrenia. In addition, we found that Smarca2 (Brm), Smarcd3 (Baf60c), Smarce1 (Baf57), Hdac1, RcoR1, and Mecp2, which are part of the REST/NRSFSWI/SNF chromatin remodelling complex, are transcriptionally regulated by REST/NRSF. Changing their gene dosage in vitro induced abnormal dendritic and dendritic spine phenotypes that were previously observed in rodent models of neuropsychiatric diseases. Altogether, these results suggest that genes encoding proteins of the REST/NRSF-SWI/SNF pathway display primate-specific accelerated evolution. It may be hypothesized that the subset of genes involved in this pathway, which display a primate evolutionary signature in specific sites, may represent a novel gene candidate repertoire for neuropsychiatric diseases.

Project description:ChIPseq data for 31 CLL samples (12 controls, 19 tumor) of the CancerEpiSys-PRECiSe project; containing histone H3, histone modifications and transcription factor binding sites (CTCF, EBF1).

Project description:Chromatin endogenous cleavage (ChEC) uses fusion of a protein of interest to micrococcal nuclease (MNase) to target calcium-dependent cleavage to specific genomic loci in vivo. Here we report the combination of ChEC with high-throughput sequencing (ChEC-seq) to map budding yeast transcription factor (TF) binding. Temporal analysis of ChEC-seq data reveals two classes of sites for TFs, one displaying rapid cleavage at sites with robust consensus motifs and the second showing slow cleavage at largely unique sites with low-scoring motifs. Sites with high-scoring motifs also display asymmetric cleavage, indicating that ChEC-seq provides information on the directionality of TF-DNA interactions. Strikingly, similar DNA shape patterns are observed regardless of motif strength, indicating that the kinetics of ChEC-seq discriminates DNA recognition through sequence and/or shape. We propose that time-resolved ChEC-seq detects both high-affinity interactions of TFs with consensus motifs and sites preferentially sampled by TFs during diffusion and sliding.