Quadruplex DNA: sequence, topology and structure

G-quadruplexes are higher-order DNA and RNA structures formed from G-rich sequences that are built around tetrads of hydrogen-bonded guanine bases. Potential quadruplex sequences have been identified in G-rich eukaryotic telomeres, and more recently in non-telomeric genomic DNA, e.g. in nuclease-hypersensitive promoter regions. The natural role and biological validation of these structures is starting to be explored, and there is particular interest in them as targets for therapeutic intervention. This survey focuses on the folding and structural features on quadruplexes formed from telomeric and non-telomeric DNA sequences, and examines fundamental aspects of topology and the emerging relationships with sequence. Emphasis is placed on information from the high-resolution methods of X-ray crystallography and NMR, and their scope and current limitations are discussed. Such information, together with biological insights, will be important for the discovery of drugs targeting quadruplexes from particular genes.     

Homologous recombination-mediated irreversible genome damage underlies telomere-induced senescence

Loss of telomeric DNA leads to telomere uncapping, which triggers a persistent, p53-centric DNA damage response that sustains a stable senescence-associated proliferation arrest. Here, we show that in normal cells telomere uncapping triggers a focal telomeric DNA damage response accompanied by a transient cell cycle arrest. Subsequent cell division with dysfunctional telomeres resulted in sporadic telomeric sister chromatid fusions that gave rise to next-mitosis genome instability, including non-telomeric DNA lesions responsible for a stable, p53-mediated, senescence-associated proliferation arrest. Unexpectedly, the blocking of Rad51/RPA-mediated homologous recombination, but not non-homologous end joining (NHEJ), prevented senescence despite multiple dysfunctional telomeres. When cells approached natural replicative senescence, interphase senescent cells displayed genome instability, whereas near-senescent cells that underwent mitosis despite the presence of uncapped telomeres did not. This suggests that these near-senescent cells had not yet acquired irreversible telomeric fusions. We propose a new model for telomere-initiated senescence where tolerance of telomere uncapping eventually results in irreversible non-telomeric DNA lesions leading to stable senescence. Paradoxically, our work reveals that senescence-associated tumor suppression from telomere shortening requires irreversible genome instability at the single-cell level, which suggests that interventions to repair telomeres in the pre-senescent state could prevent senescence and genome instability.     

Targeted DNA damage at individual telomeres disrupts their integrity and triggers cell death

Cellular DNA is organized into chromosomes and capped by a unique nucleoprotein structure, the telomere. Both oxidative stress and telomere shortening/dysfunction cause aging-related degenerative pathologies and increase cancer risk. However, a direct connection between oxidative damage to telomeric DNA, comprising <1% of the genome, and telomere dysfunction has not been established. By fusing the KillerRed chromophore with the telomere repeat binding factor 1, TRF1, we developed a novel approach to generate localized damage to telomere DNA and to monitor the real time damage response at the single telomere level. We found that DNA damage at long telomeres in U2OS cells is not repaired efficiently compared to DNA damage in non-telomeric regions of the same length in heterochromatin. Telomeric DNA damage shortens the average length of telomeres and leads to cell senescence in HeLa cells and cell death in HeLa, U2OS and IMR90 cells, when DNA damage at non-telomeric regions is undetectable. Telomere-specific damage induces chromosomal aberrations, including chromatid telomere loss and telomere associations, distinct from the damage induced by ionizing irradiation. Taken together, our results demonstrate that oxidative damage induces telomere dysfunction and underline the importance of maintaining telomere integrity upon oxidative damage.     

Selective recognition of a DNA G-quadruplex by an engineered antibody

Particular guanine rich nucleic acid sequences can fold into stable secondary structures called G-quadruplexes. These structures have been identified in various regions of the genome that include the telomeres, gene promoters and UTR regions, raising the possibility that they may be associated with biological function(s). Computational analysis has predicted that intramolecular G-quadruplex forming sequences are prevalent in the human genome, thus raising the desire to differentially recognize genomic G-quadruplexes. We have employed antibody phage display and competitive selection techniques to generate a single-chain antibody that shows >1000-fold discrimination between G-quadruplex and duplex DNA, and furthermore >100-fold discrimination between two related intramolecular parallel DNA G-quadruplexes. The amino acid sequence composition at the antigen binding site shows conservation within the light and heavy chains of the selected scFvs, suggesting sequence requirements for G-quadruplex recognition. Circular dichroism (CD) spectroscopic data showed that the scFv binds to the prefolded G-quadruplex and does not induce G-quadruplex structure formation. This study demonstrates the strongest discrimination that we are aware of between two intramolecular genomic G-quadruplexes.     

Ku-deficient yeast strains exhibit alternative states of silencing competence

In Saccharomyces cerevisiae, efficient silencer function requires telomere proximity, i.e. compartments of the nucleoplasm enriched in silencing factors. Accordingly, silencers located far from telomeres function inefficiently. We show here that cells lacking yKu balance between two mitotically stable states of silencing competence. In one, a partial delocalization of telomeres and silencing factors throughout the nucleoplasm correlates with enhanced silencing at a non-telomeric locus, while in the other, telomeres retain their focal pattern of distribution and there is no repression at the non-telomeric locus, as observed in wild-type cells. The two states also differ in their level of residual telomeric silencing. These findings indicate the existence of a yKu-independent pathway of telomere clustering and Sir localization. Interestingly, this pathway appears to be under epigenetic control.     

Distribution of non-telomeric sites of the (TTAGGG)n telomeric sequence in vertebrate chromosomes

The intrachromosomal distribution of non-telomeric sites of the (TTAGGG)_n telomeric repeat was determined for 100 vertebrate species. The most common non-telomeric location of this sequence was in the pericentric regions of chromosomes. A variety of species showed relatively large amounts of this sequence present within regions of constitutive heterochromatin. We discuss possible relationships between the non-telomeric distribution of the (TTAGGG)_n sequence and the process of karyotype evolution, during which these sites may provide potential new telomeres.     

Recognition of internal (TTAGGG)n repeats by telomeric protein TRF1 and its role in maintenance of chromosomal stability in Chinese hamster cells

Mammalian telomeres contain long tandem (TTAGGG)n repeats, which are protected by a complex of different proteins. Telomeric repeat-binding factors TRF1 and TRF2 play the key role in protection of telomeres through the formation of terminal loops (called T-loop). A T-loop isolates the 3' strand telomeric end and with this mechanism protects telomeres from the influence of enzymes of DNA reparation and telomere fusions and also interferes with the interaction of telomerase with telomeres. Many vertebrate species also contain large blocks of (TTAGGG)n sequences in pericentric and interstitial chromosome bands. The Chinese hamster genome contains a total of 18 arrays of these non-telomeric internal (TTAGGG)n sequences (ITs). Chromosome bands containing these arrays are unstable and should be protected with the help of another mechanism, rather than that using telomeres. In this study we analysed association of Green Fluorescent Protein (GFP)-tagged TRF1 in Chinese hamster V79 cells with ITs. We found that in these cells GFP-TRF1 associates with ITs in the interphase nucleus. We detected a little overlap between IT-associated GFP-TRF1 and random DSB sites visualized after the treatment of V79 cells with ionizing radiation. We found that the treatment of V79 cells with WM significantly increases the frequency of spontaneous chromosome aberrations. These WM effects are possible due to inhibiting phosphorylation of TRF1 by ATM. TRF1 is known to be eliminated from telomeres by overexpression of TANK1, which induces TRF1 poly(ADP-ribosyl)ation. We transfected V79 cells by plasmid encoding TANK1 and found that the frequency of chromosome rearrangements increased in these cells independently of their treatment by IR. Taken together, our results suggest that TRF1 may be involved in the sequence-specific protection of internal non-telomeric (TTAGGG)n repeats.     

Why to target G-quadruplexes using peptides: Next-generation G4-interacting ligands

Guanine-rich oligonucleotides existing in both DNA and RNA are able to fold into four-stranded DNA secondary structures via Hoogsteen type hydrogen-bonding, where four guanines self-assemble into a square planar arrangement, which, when stacked upon each other, results in the formation of higher-order structures called G-quadruplexes. Their distribution is not random; they are more frequently present at telomeres, proto-oncogenic promoters, introns, 5′- and 3′-untranslated regions, stem cell markers, ribosome binding sites and so forth and are associated with various biological functions, all of which play a pivotal role in various incurable diseases like cancer and cellular ageing. Several studies have suggested that G-quadruplexes could not regulate biological processes by themselves; instead, various proteins take part in this regulation and can be important therapeutic targets. There are certain limitations in using whole G4-protein for therapeutics purpose because of its high manufacturing cost, laborious structure prediction, dynamic nature, unavailability for oral administration due to its degradation in the gut and inefficient penetration to reach the target site because of the large size. Hence, biologically active peptides can be the potential candidates for therapeutic intervention instead of the whole G4-protein complex. In this review, we aimed to clarify the biological roles of G4s, how we can identify them throughout the genome via bioinformatics, the proteins interacting with G4s and how G4-interacting peptide molecules may be the potential next-generation ligands for targeting the G4 motifs located in biologically important regions.     

端粒结合蛋白TRF2的研究进展

端粒DNA结合蛋白TRF2(TTAGGG repeat binding factor-2)以二聚体形式通过Myb结构域与端粒重复序列TTAGGG结合,并与TRF1、TIN2、Rap1、TINT1及POT1蛋白组成Shelterin蛋白复合物,协同在端粒动态平衡维持过程中起关键作用,进而影响整个基因组的稳定性。此外,TRF2在细胞DNA损伤应答过程中可能发挥重要作用。本文将对TRF2结构和功能研究的最新进展进行综述。     

48 NMR study of the interaction between G-quadruplexes and small molecules

Guanine-rich oligonucleotides are able to adopt secondary DNA structures, known as G-quadruplexes. Such G-rich sequences are found in human telomeres, promoter regions of oncogenes, 5′ untranslated regions (UTRs) of mRNAs and human intronic sequences. Studies have shown that small molecules can induce anti-cancer effect through stabilizing or promoting G-quadruplex formation. In order to design and develop a potent drug, structural details on the interaction between small molecules and G-quadruplexes are invaluable. In this study, we seek to understand the structural determinants involved in the interaction between G-quadruplexes and small molecules. NMR spectroscopy is employed to resolve the structures of two intramolecular G-quadruplexes bound to small molecules. These resolved complexes allow us to structurally design new potent drugs for their application in anti-cancer therapy.     

Clustering heterochromatin: Sir3 promotes telomere clustering independently of silencing in yeast

A general feature of the nucleus is the organization of repetitive deoxyribonucleic acid sequences in clusters concentrating silencing factors. In budding yeast, we investigated how telomeres cluster in perinuclear foci associated with the silencing complex Sir2-Sir3-Sir4 and found that Sir3 is limiting for telomere clustering. Sir3 overexpression triggers the grouping of telomeric foci into larger foci that relocalize to the nuclear interior and correlate with more stable silencing in subtelomeric regions. Furthermore, we show that Sir3's ability to mediate telomere clustering can be separated from its role in silencing. Indeed, nonacetylable Sir3, which is unable to spread into subtelomeric regions, can mediate telomere clustering independently of Sir2-Sir4 as long as it is targeted to telomeres by the Rap1 protein. Thus, arrays of Sir3 binding sites at telomeres appeared as the sole requirement to promote trans-interactions between telomeres. We propose that similar mechanisms involving proteins able to oligomerize account for long-range interactions that impact genomic functions in many organisms.     

Structural insight into the hTERT intron 6 sequence d(GGGGTGAAAGGGG) from 1H-NMR study

The interest in DNA quadruplex structures has been fueled by the recognition that telomeres, the 3' single stranded guanine-rich overhangs found at the termini of chromosomes, are likely to form G-tetrads type structures important in cell senescence and cancer. In addition to their presence in telomeres, where they may play a role in maintaining the stability and integrity of chromosomes, guanine-rich regions are found in other region of the genome, amongst these is intron 6 of hTERT a gene codifying for the enzyme telomerase. Interestingly, the formation of G-quadruplexes in this region is involved in the down-regulation of telomerase activity caused by an alteration of the hTERT splicing pattern. Therefore, we have analyzed several sequences of that intron by (1)H-NMR and CD spectroscopy, and we have found that the sequence d(GGGGTGAAAGGGG) is able to fold in a single well-defined antiparallel quadruplex structure consisting of four G-tetrads, possessing a twofold symmetry, and containing four Gs in a syn glycosidic conformation.     

Chromatin modifiers and recombination factors promote a telomere fold-back structure,that is lost during replicative senescence

Telomeres have the ability to adopt a lariat conformation and hence, engage in long and short distance intra-chromosome interactions. Budding yeast telomeres were proposed to fold back into subtelomeric regions, but a robust assay to quantitatively characterize this structure has been lacking. Therefore, it is not well understood how the interactions between telomeres and non-telomeric regions are established and regulated. We employ a telomere chromosome conformation capture (Telo-3C) approach to directly analyze telomere folding and its maintenance in S. cerevisiae. We identify the histone modifiers Sir2, Sin3 and Set2 as critical regulators for telomere folding, which suggests that a distinct telomeric chromatin environment is a major requirement for the folding of yeast telomeres. We demonstrate that telomeres are not folded when cells enter replicative senescence, which occurs independently of short telomere length. Indeed, Sir2, Sin3 and Set2 protein levels are decreased during senescence and their absence may thereby prevent telomere folding. Additionally, we show that the homologous recombination machinery, including the Rad51 and Rad52 proteins, as well as the checkpoint component Rad53 are essential for establishing the telomere fold-back structure. This study outlines a method to interrogate telomere-subtelomere interactions at a single unmodified yeast telomere. Using this method, we provide insights into how the spatial arrangement of the chromosome end structure is established and demonstrate that telomere folding is compromised throughout replicative senescence.