Project description:G-quadruplex (G4) structures exist in single-stranded DNA of chromatins and regulate genome function. However, the native chromatin G4 landscape in living cells has yet to be fully characterized. Herein, we fused BG4 antibody and GFP-tag to construct a live-cell G4 identifier (LiveG4ID). We first displayed its function as a high-specificity chromatin G4 probe in living cells by Dox-induced expression LiveG4ID in HEK293T cells and detecting its cellular localization, biocompatibility and G4-binding specificity. By coupling LiveG4ID with CUT&Tag technology, we established LiveG4ID-seq, a method for mapping native chromatin G4 landscape in living cells. LiveG4ID-seq can identify more chromatin G4 motifs than traditional CUT&Tag and ChIP-seq methods. Using LiveG4ID-seq, we profiled the dynamic landscape of chromatin G4 structures during the cell cycle. These data demonstrate the capacity of LiveG4ID-seq to profile a more accurate G4 landscape in living cells and promote future study on chromatin G4 structures.

Project description:DNA secondary structures are important for fundamental genome functions such as transcription and replication1. The G-quadruplex (G4) structural motif has been linked to gene regulation2,3 and genome instability4,5 and may be important to cancer development and other diseases6-8. Recently, ~700,000 discrete G4s have been observed in naked human single-stranded genomic DNA using G4-seq, a high-throughput sequencing technique that detects structural features in vitro.9 It is of vital importance to investigate G4 structures within an endogenous chromatin context, which until now remained elusive10,11. Herein, we address this via the development of G4 ChIP-seq, an antibody-based G4 chromatin immunoprecipitation and high-throughput sequencing approach. We identified ~10,000 endogenous G4 structures and show that G4s are predominantly seen in regulatory, nucleosome-depleted, chromatin regions. G4s were enriched in the promoters and 5’UTR regions of highly transcribed genes, particularly in genes related to cancer and in somatic copy number amplifications, such as MYC. Reorganization of the chromatin landscape using a histone deacetylase inhibitor, resulted in de novo G4 formation in new and more prominent regulatory, nucleosome-depleted regions associated with increased transcriptional output. Our findings suggest a striking relationship between promoter nucleosome-depleted regions, G4 formation and elevated transcriptional activity. Comparison between normal human epidermal keratinocytes and their immortalized counterparts revealed a 7-fold greater G4 abundance in immortalized cells, of which 80 % were found in regulatory, nucleosome-depleted regions common to both cell types. Consequently, cells exhibiting more G4s displayed significantly increased transcriptional output and were more sensitive to growth inhibition by a small molecule G4 ligand. Overall, our results provide new mechanistic insights into where and when DNA adopts G4 structure in vivo. Our findings show for the first time that regulatory, nucleosome-depleted chromatin and transcriptional states predominantly shape the endogenous G4 DNA landscape. Two cell lines, treated with entinostat or untreated, analyzed to detect gene expression differences, presence of G-Qudruplexes and chromatin state. Each combination of conditions replicated in duplicates or triplicates.

Project description:G-quadruplexes (G4s) and R-loops are non-canonical DNA structures that can play regulatory functions of basic nuclear processes and can trigger DNA damage and genome instability. We here show that specific G4 ligands can stabilize G4s and simultaneously increase R-loop levels in human cancer cells likely by spreading DNA:RNA heteroduplexes to adjacent regions containing G4 structures. DNA cleavage and DNA damage response induced by G4 ligands were rescued by overexpression of exogenous RNaseH1 in cancer cells independently of BRCA2 status. The data thus show that R-loops are involved in the induction of DNA damage by chemical G4 stabilization. In addition, G4 ligands trigger the formation of micronuclei, particularly in BRCA2-silenced cancer cells, in an R-loop dependent manner. Our results uncover the mechanism of genome instability caused by G4 ligands and can open to the development of unexpected anticancer strategies using G4-targeted agents.

Project description:R-loops and guanine quadruplexes (G4s) are secondary structures of nucleic acids that are ubiquitously present in cells, and are enriched in promoter regions of genes. By employing a bioinformatic approach based on overlap analysis of transcription factor ChIP-seq datasets, we found that many splicing factors, including U2AF1 whose recognition of 3¢ splicing site is crucial for pre-mRNA splicing, exhibit pronounced enrichment at endogenous R-loop- and DNA G4-structure loci in promoter regions of human genes. We revealed that U2AF1 can bind directly to R-loops and DNA G4 structures at low nM binding affinity. Additionally, we showed the ability of U2AF1 to undergo phase separation, which could be stimulated by binding with R-loops, but not duplex DNA, RNA/DNA hybrid, DNA G4, or single-stranded RNA. We also demonstrated that U2AF1 binds to promoter R-loops in human cells, and this binding competes with U2AF1’s interaction with 3¢-splicing site, thereby modulating pre-mRNA splicing. Together, we uncovered a group of candidate proteins that can bind to both R-loops and DNA G4s, revealed the direct and strong interaction of U2AF1 with these nucleic acid structures, and unveiled new functions of this interaction, i.e., promotion of phase separation of U2AF1 and modulation of mRNA splicing. Our work also established, for the first time, a biochemical basis for U2AF1’s occupancy in gene promoters.

Project description:G-quadruplexes (G4s) are noncanonical DNA secondary structures formed through the self-association of guanines, and they are distributed widely across the genome. G4 participates in multiple biological processes including gene transcription, and G4-targeted ligands serve as potential therapeutic agents for DNA-targeted therapies. However, genome-wide studies of the exact roles of G4s in transcriptional regulation are still lacking. We found that drug-induced promoter-proximal RNA polymerase II pausing promotes nearby G4 formation, and oppositely, G4 stabilization by G4-targeted ligands globally reduces RNA polymerase II occupancy at gene promoters as well as nascent RNA synthesis. To study the underlying mechanisms by which native G4 affects transcriptional regulation, we annealed the biotin-labeled core promoter DNA to form G4s and performed pull-down assays with nuclear extraction proteins in the presence or absence of TMPyP4. Mass spectrometry analysis was performed to identify the interacting proteins with G4-forming core promoter DNA.

Project description:DNA G-quadruplex (G4) is a non-canonical four-stranded nucleic acid structure functioning in various biological processes in mammals. G4 ChIP-seq assay, In this study, we developed a robust BG4-DNA ChIP-seq for global identification of DNA G4 in rice..We found that G4s harbored some functional motifs for binding of certain trans-factors, were co-localized with R-loops and DHSs in the rice genome. Importantly, G4s exhibited differential effects on DNA methylation between TE and non-TE genes in rice. Especially, G4 intensity-dependent enrichment occurred between DNA 5mC and 6mA.These DNA-related features suggest potential regulatory roles of G4 in rice. Thus, our study will pave the way for prompting intensive characterization towards identifying novel functions of G4 in plants, especially for agronomic important crops.

Project description:G-quadruplexes (G4s) are four-stranded nucleic acid structures abundant at gene promoters. They can adopt several distinctive conformations. G4s have been shown to form in the herpes simplex virus-1 (HSV-1) genome during its viral cycle. Here by cross-linking/pull-down assay we identified ICP4, the major HSV-1 transcription factor, as the protein that most efficiently interacts with viral G4s during infection. ICP4 specific and direct binding and unfolding of parallel G4s, including those present in HSV-1 immediate early gene promoters, induced transcription in vitro and in infected cells. This mechanism was also exploited by ICP4 to promote its own transcription. Proximity ligation assay allowed visualization of G4-protein interaction at the single selected G4 in cells. G4 ligands inhibited ICP4 binding to G4s. Our results indicate the existence of a well-defined G4-viral protein network that regulates the productive HSV-1 cycle. They also point to G4s as elements that recruit transcription factors to activate transcription in cells.

Project description:i-Motifs (iMs) are four-stranded DNA structures that form at cytosine (C)-rich sequences and in acidic conditions in vitro. However, their formation and distribution in cells is still under debate. Here we performed CUT&Tag sequencing using the anti-iM antibody iMab and showed that iMs form within the human genome in live cells. We mapped native iMs in two different human cell lines and recovered C-rich sequences that were confirmed to fold into iMs in vitro. We found that iMs in cells are mainly present at actively transcribing gene promoters and that their abundance and distribution are specific to each cell type. iMs with both long and short C-tracts were recovered, further extending the relevance of iMs throughout the genome. By simultaneously mapping G-quadruplexes (G4s), four-stranded structures that form at guanine-rich regions, and comparing the results with iMs, we proved that the two structures can form in independent genomic regions; however, when both iMs and G4s are present in the same genomic tract, their formation is favored. Our findings support the in vivo formation of iM structures and provide new insights into their interplay with G4s as new regulatory elements in the human genome.

Project description:i-Motifs (iMs) are four-stranded DNA structures that form at cytosine (C)-rich sequences and in acidic conditions in vitro. However, their formation and distribution in cells is still under debate. Here we performed CUT&Tag sequencing using the anti-iM antibody iMab and showed that iMs form within the human genome in live cells. We mapped native iMs in two different human cell lines and recovered C-rich sequences that were confirmed to fold into iMs in vitro. We found that iMs in cells are mainly present at actively transcribing gene promoters and that their abundance and distribution are specific to each cell type. iMs with both long and short C-tracts were recovered, further extending the relevance of iMs throughout the genome. By simultaneously mapping G-quadruplexes (G4s), four-stranded structures that form at guanine-rich regions, and comparing the results with iMs, we proved that the two structures can form in independent genomic regions; however, when both iMs and G4s are present in the same genomic tract, their formation is favored. Our findings support the in vivo formation of iM structures and provide new insights into their interplay with G4s as new regulatory elements in the human genome.

Project description:Single-stranded DNA (ssDNA) containing guanine repeats can form G-quadruplex (G4) structures. While cellular proteins and small molecules can bind G4s, it has been difficult to broadly assess their sequence specificity. Here, we use custom DNA microarrays to examine the binding specificities of proteins, small molecules, and antibodies across ~15,000 G4 structures. Molecules used include fluorescently labeled pyridostatin (Cy5-PDS, a small molecule), BG4 (Cy5-BG4, a G4-specific antibody), and eight proteins (GST-tagged nucleolin, IGF2, CNBP, FANCJ, PIF1, BLM, DHX36, and WRN). Cy5-PDS and Cy5-BG4 selectively bind sequences known to form G4s, confirming their formation on the microarrays. Cy5-PDS binding decreased when G4 formation was inhibited using lithium or when ssDNA features on the microarray were made double-stranded. Similar conditions inhibited the binding of all other molecules except for CNBP and PIF1. We report that proteins have different G4 binding preferences suggesting unique cellular functions. Finally, competition experiments are used to assess the binding of an unlabeled small molecule, revealing the structural features in the G4 required to achieve selectivity. These data demonstrate that the microarray platform can be used to assess the binding preferences of molecules to G4s on a broad scale, helping to understand the properties that govern molecular recognition.