Project description:G4 are noncanonical secondary structures consist in stacked tetrads of Hoogsteen hydrogen-bonded guanines bases. An essential feature of G-quadruplexes is their intrinsic polymorphic nature. Indeed, depending on the length and the composition of the sequence, as well as the environmental conditions (including the nature and concentration of metal cations, and local molecular crowding), a G-quadruplex-forming sequence can adopt different topologies in which the strands are in parallel or antiparallel conformations, with the co-existence of different types of loops (lateral, diagonal or propeller) with variable lengths. The impact of G4 on cellular metabolism is associated with protein or enzymatic factors that promote, inhibits or resolve these structures. Thus, the major impact of G4 on the human cell metabolism is associated with genetic defects affecting proteins that counteract their formation. Although a large number of proteins able to bind and/or "to resolve" G-quadruplex structures have been identified in vitro, less is known about their mode of interaction with G-quadruplex, their specificity versus the topology and finally their specificity for G4 structures relatively to G-rich single-stranded sequences. In this study we aimed to identify and characterize human proteins interacting with locked G4 structures.

Project description:Background G-quadruplexes (G4s) are stable non-canonical DNA secondary structures consisting of stacked arrays of four guanines, each held together by Hoogsteen hydrogen bonds. Sequences with the ability to form these structures in vitro, G4 motifs, are found throughout bacterial and eukaryotic genomes. The budding yeast Pif1 DNA helicase, as well as several bacterial Pif1 family helicases, unwind G4 structures robustly in vitro and suppress G4-induced DNA damage in S. cerevisiae in vivo. Results We determined the genomic distribution and evolutionary conservation of G4 motifs in four fission yeast species and investigated the relationship between G4 motifs and Pfh1, the sole S. pombe Pif1 family helicase. Using chromatin immunoprecipitation combined with deep sequencing, we found that many G4 motifs in the S. pombe genome were associated with Pfh1. Cells depleted of Pfh1 had increased fork pausing and DNA damage near G4 motifs, as indicated by high DNA polymerase occupancy and phosphorylated histone H2A, respectively. In general, G4 motifs were underrepresented in genes. However, Pfh1-associated G4 motifs were located on the transcribed strand of highly transcribed genes significantly more often than expected, suggesting that Pfh1 has a function in replication or transcription at these sites. Conclusions In the absence of functional Pfh1, unresolved G4 structures cause fork pausing and DNA damage of the sort associated with human tumors.

Project description:G-quadruplex (G4) structure is an alternative conformation of the double helical structure of B-form DNA arisen in guanine-rich sequences . The formation of G4 structures can influence chromatin architecture and many fundamental biology processes, such as DNA replication and gene regulation . We present G4-miner, a genome-wide approach to directly identify G4 structures from ordinary sequencing data. G4-miner inspects sequencing quality in whole genome, seizes unexpected fluctuations in local, and ascribes some of the quality fluctuations to the unstable formation of G4. We identified 736,689 G4 structures within human genome, in which 44.9% of all predicted canonical G4-froming sequences were contained.

Project description:In the presence of monovalent alkali metal ions, G-rich DNA sequences containing four runs of contiguous guanines can fold into G-quadruplex (G4) structures. Recent studies showed that these structures are located in critical regions of the human genome and assume important functions in many essential DNA metabolic processes, including replication, transcription and repair. However, not all potential G4-forming sequences are actually folded into G4 structures in cells, where G4 structures are known to be dynamic and modulated by G4-binding proteins as well as helicases. It remains unclear whether there are other factors influencing the formation and stability of G4 structures in cells. Herein, we showed that DNA G4s can undergo phase separation in vitro. In addition, immunofluorescence microscopy and ChIP-Seq experiments with the use of BG4, a G4 structure-specific antibody, revealed that disruption of phase separation in cells could result in global destabilization of G4 structures. Together, our work revealed phase separation as a new determinant in regulating the formation and stability of G4 structures in human cells.

Project description:The DNA Guanine quadruplexes (G4) plays important roles in multiple cellular processes, including regulation of DNA replication, transcription and genome stability. Here, we show that Yin Yang-1 (YY1), a ubiquitously expressed and multifunctional transcription factor, can bind with G4 structures directly. Fluorescence anisotropy experiments shows that YY1 binds towards G4 structures with Kd in low nanomolar range (<100 nM) through the C terminal zinc finger domains. ChIP-seq results show that 81% of the YY1 ChIP-seq peaks contain G4 forming sequences, which is highly overlapped with the G4 ChIP-seq peaks. YY1 facilitate the DNA-DNA interaction through its binding with G4 structures in vivo and in vitro, which can be disturbed by G4 stabilizer treatment. In all, our studies identify a novel G4 structure binding protein-YY1, and reveal that G4 structure functions in DNA-DNA interaction.

Project description:The genome consists of non-B-DNA structures such as G-quadruplexes (G4) that are involved in the regulation of genome stability and transcription. Telomeric-repeat containing RNA (TERRA) is capable of folding into G-quadruplex and interacting with chromatin remodeler ATRX. Here we show that TERRA modulates ATRX occupancy on repetitive sequences and over genes, and maintains DNA G-quadruplex structures at TERRA target and non-target sites in mouse embryonic stem cells. TERRA prevents ATRX from binding to subtelomeric regions and represses H3K9me3 formation. G4 ChIP-seq reveals that G4 abundance decreases at accessible chromatin regions, particularly at transcription start sites (TSS) after TERRA depletion; such G4 reduction at TSS is associated with elevated ATRX occupancy and differentially expressed genes. Loss of ATRX alleviates the effect of gene repression caused by TERRA depletion. Immunostaining analyses demonstrate that knockdown of TERRA diminishes DNA G4 signals, whereas silencing ATRX elevates G4 formation. Our results uncover an epigenetic regulation by TERRA that sequesters ATRX and preserves DNA G4 structures.

Project description:Single-stranded DNA or RNA sequences rich in guanine (G) can adopt non-canonical structures known as G-quadruplexes (G4). G4 in the mitochondrial genome are heavy-strand enriched and have been associated with the formation of deletion breakpoints that cause mitochondrial diseases. However, the functional role of G4 structures in mitochondria remains unclear. Here, we have identified RHPS4 as a G4-specific ligand that localizes to mitochondria and causes replication pausing, with mitochondrial DNA (mtDNA) depletion occurring at higher dosage. We further show that RHPS4 interferes with mitochondrial transcript elongation at low doses, leading to respiratory complex depletion. These unprecedented observations suggest that G4 motifs modulate mitochondrial transcription and replication efficiency. Using the differential effects of high vs low RHPS4 dosing, we characterized gene expression pathway responses to mitochondrial transcription inhibition or mitochondrial genome depletion. Importantly, a human mtDNA mutation that increases G4 formation potential strongly enhanced the RHPS4-mediated mitochondrial respiratory defect. We propose that abnormal G4 dynamics may contribute to mtDNA instability and gene expression defects, particularly in the presence of mitochondrial mutations that enhance the G4 formation.

Project description:G-quadruplex (or G4) structures are non-canonical DNA structures that form in guanine-rich sequences and threaten genome stability when not properly resolved. G4 unwinding occurs during S phase via an unknown mechanism. Using Xenopus egg extracts, we define a three-step G4 unwinding mechanism that acts during DNA replication. First, the replicative helicase (CMG) stalls at a leading strand G4 structure. Second, the DHX36 helicase mediates the bypass of the CMG past the intact G4 structure, which allows approach of the leading strand to the G4. Third, G4 structure unwinding by the FANCJ helicase enables the DNA polymerase to synthesize past the G4 motif. A G4 on the lagging strand template does not stall CMG, but still requires active DNA replication for unwinding. DHX36 and FANCJ have partially redundant roles, conferring robustness to this pathway. Our data reveal a novel genome maintenance pathway that promotes faithful G4 replication thereby avoiding genome instability.

Project description:G-rich DNA sequences can form four-stranded G-quadruplex (G4) secondary structures and are linked to fundamental biological processes such as transcription, replication and telomere maintenance. G4s are also implicated in promoting genome instability, cancer and other diseases. Here, we describe a detailed G4 ChIP-seq method that robustly enables the determination of G4 structure formation genome-wide in chromatin. This protocol adapts traditional ChIP-seq for the detection of DNA secondary structures through the use of a G4-structure-specific phage display antibody with refinements in chromatin immunoprecipitation followed by high-throughput sequencing. Beginning with chromatin isolation and antibody preparation the entire protocol can be completed in less than 1 week including computational analysis.

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.