Phong Lan Thao Tran

Stability of telomeric G-quadruplexes.

In most eukaryotes, telomeric DNA consists of repeats of a short motif that includes consecutive guanines and may hence fold into G-quadruplexes. Budding yeasts have telomeres composed of longer repeats and show variation in the degree of repeat homogeneity. Although telomeric sequences from several organisms have been shown to fold into G-quadruplexes in vitro, surprisingly, no study has been dedicated to the comparison of G-quadruplex folding and stability of known telomeric sequences. Furthermore, to our knowledge, folding of yeast telomeric sequences into intramolecular G-quadruplexes has never been investigated. Using biophysical and biochemical methods, we studied sequences mimicking about four repetitions of telomeric motifs from a variety of organisms, including yeasts, with the aim of comparing the G-quadruplex folding potential of telomeric sequences among eukaryotes. G-quadruplex folding did not appear to be a conserved feature among yeast telomeric sequences. By contrast, all known telomeric sequences from eukaryotes other than yeasts folded into G-quadruplexes. Nevertheless, while G(3)T(1-4)A repeats (found in a variety of organisms) and G(4)T(2,4) repeats (found in ciliates) folded into stable G-quadruplexes, G-quadruplexes formed by repetitions of G(2)T(2)A and G(2)CT(2)A motifs (found in many insects and in nematodes, respectively) appeared to be in equilibrium with non-G-quadruplex structures (likely hairpin-duplexes).

Tetramolecular Quadruplex Stability and Assembly

Guanine quadruplexes (G4) are unusual four-stranded nucleic acid structures formed by G-rich DNA/RNA. Beyond their likely biological relevance, the self-assembly, stability, and rigidity of these structures are also interesting for nanotechnology and biotechnology applications. Therefore, efforts are carried out to understand the rules that govern stability and folding of G-quadruplexes. We focus this chapter on tetramolecular conformations which are simple tractable models. We report here the experimental parameters, molecules, and modifications that affect thermal stability and/or association kinetics of these structures. Some chemical modifications which facilitate tetramolecular quadruplex formation and can be useful for nano- or biotechnology are also described.

Controlling the stoichiometry and strand polarity of a tetramolecular G-quadruplex structure by using a DNA origami frame

Guanine-rich oligonucleotides often show a strong tendency to form supramolecular architecture, the so-called G-quadruplex structure. Because of the biological significance, it is now considered to be one of the most important conformations of DNA. Here, we describe the direct visualization and single-molecule analysis of the formation of a tetramolecular G-quadruplex in KCl solution. The conformational changes were carried out by incorporating two duplex DNAs, with G–G mismatch repeats in the middle, inside a DNA origami frame and monitoring the topology change of the strands. In the absence of KCl, incorporated duplexes had no interaction and laid parallel to each other. Addition of KCl induced the formation of a G-quadruplex structure by stably binding the duplexes to each other in the middle. Such a quadruplex formation allowed the DNA synapsis without disturbing the duplex regions of the participating sequences, and resulted in an X-shaped structure that was monitored by atomic force microscopy. Further, the G-quadruplex formation in KCl solution and its disruption in KCl-free buffer were analyzed in real-time. The orientation of the G-quadruplex is often difficult to control and investigate using traditional biochemical methods. However, our method using DNA origami could successfully control the strand orientations, topology and stoichiometry of the G-quadruplex.

Guided Assembly of Tetramolecular G-Quadruplexes

Nucleic acids are finding applications in nanotechnology as nanomaterials, mechanical devices, templates, and biosensors. G-quadruplex DNA, formed by π-π stacking of guanine (G) quartets, is an attractive alternative to regular B-DNA because of the kinetic and thermodynamic stability of quadruplexes. However, they suffer from a fatal flaw: the rules of recognition, i.e., the formation of a G-quartet in which four identical bases are paired, prevent the controlled assembly between different strands, leading to complex mixtures. In this report, we present the solution to this recognition problem. The proposed design combines two DNA elements: parallel-stranded duplexes and a quadruplex core. Parallel-stranded duplexes direct controlled assembly of the quadruplex core, and their strands present convenient points of attachments for potential modifiers. The exceptional stability of the quadruplex core provides integrity to the entire structure, which could be used as a building block for nucleic acid-based nanomaterials. As a proof of principle for the designs versatility, we assembled quadruplex-based 1D structures and visualized them using atomic force and transmission electron microscopy. Our findings pave the way to broader utilization of G-quadruplex DNA in structural DNA nanomaterials.

Unraveling the relationship between structure and stabilization of triarylpyridines as G-quadruplex binding ligands

A series of novel 2,4,6-triarylpyridines have been synthesized and their interactions with intramolecular G-quadruplexes have been measured by Förster Resonance Energy Transfer (FRET) melting and Fluorescent Intercalator Displacement (FID) assays. A few of these compounds exhibit stabilization of G4-DNA that is comparable to other benchmark G4-DNA ligands with fair to excellent G4-DNA vs. duplex selectivity and significant cytotoxicity towards HeLa cells. The nature of the 4-aryl substituents along with side chain length governs the G4-DNA stabilization ability of the compounds. In addition, we demonstrate that there is a strong correlation between the ability of the compounds to stabilize the same G4-DNA sequence in K(+) and Na(+) conditions and a strong correlation between the ability of the compounds to stabilize different G4-DNA sequences in K(+) or Na(+) buffer.

Telomere Targeting with a New G4 Ligand Enhances Radiation-Induced Killing of Human Glioblastoma Cells

The aim of this study was to test in vitro the efficacy of TAC, an original G-quadruplex ligand, as a potential radiosensitizing agent for glioblastoma multiforme (GBM). Two human radioresistant telomerase-positive GBM cell lines (SF763 and SF767) were analyzed, with and without TAC treatment, for telomere length, cell proliferation, apoptosis, cell-cycle distribution, gene expression, cytogenetic aberrations, clonogenic survival assay, 53BP1 immunofluorescence staining, and γH2AX phosphorylation. We found that low concentrations of TAC (0.5 and 1 μmol/L) inhibited the proliferation of GBM cells in a concentration-dependent manner after only 1 week of treatment, with minimal effects on cell cycle and apoptosis. TAC treatment had no visible effect on average telomere length but modified expression levels of telomere-related genes (hTERT, TRF1, and TRF2) and induced concentration-dependent DNA damage response and dicentric chromosomes. Survival curves analysis showed that exposure to nontoxic, subapoptotic concentrations of TAC enhanced radiation-induced killing of GBM cells. Analysis of DNA repair after irradiation revealed delayed repair kinetics in GBM cells treated with TAC. Furthermore, the combined treatment (TAC and radiation) significantly increased the frequency of chromosomal aberrations as compared with radiation alone. These findings provide the first evidence that exposure to a G4 ligand radiosensitizes human glioblastoma cells and suggest the prospect of future therapeutic applications. Mol Cancer Ther; 10(10); 1784–95. ©2011 AACR.

HIV-1 Nucleocapsid Proteins as Molecular Chaperones for Tetramolecular Antiparallel G-Quadruplex Formation

HIV-1 nucleocapsid proteins (NCps) facilitate remodeling of nucleic acids to fold thermodynamically stable conformations, and thus called nucleic acid chaperones. To date only little is known on the stoichiometry, NCp-NCp interactions, chaperone activity on G-quadruplex formation, and so on. We report here the direct and real-time analysis on such properties of proteolytic intermediate NCp15 and mature NCp7 using DNA origami. The protein particles were found to predominantly exist in monomeric form, while dimeric and multimeric forms were also observed both in free solution and bound to the quadruplex structure. The formation and the dissociation events of the G-quadruplexes were well documented in real-time and the intermediate-like states were also visualized. We anticipate that this pioneering study will strengthen our understanding on the chaperone activity of HIV-1 proteins which in turn will be helpful for the drug design based on G-quadruplex and also for the development of drugs against AIDS.

G-quadruplex-binding ligand-induced DNA synapsis inside a DNA origami frame

Among the approaches for DNA-based drug targeting, G-quadruplex-binding ligands are of particular interest because of the high abundance of G-rich sequences in regions such as human chromosomal telomeres and promoters of several proto-oncogenes. A number of quadruplex-ligands have been reported, but their functions at single-molecule level have not been explored using direct and real-time methods. Here, we report on the direct observation of the formation of a four-stranded G-quadruplex induced by bisquinolinium pyridine dicarboxamide with a linker containing biotin at one end. We fabricated a DNA origami frame with incorporated duplex DNAs that contained 3–6 G–G mismatches in the middle. In the absence of ligand, the duplex DNAs of interest had no interaction, as visualized by their parallel-shape in high-speed atomic force microscopy (HS-AFM) images. Presence of ligand induced the formation of G-quadruplex structure, which was characterized by an X-shape. Addition of streptavidin to the ligand-induced quadruplex caused the protein to localize in the middle of the X-shape, indicating that the ligand is bound to the quadruplex. A sequence of real-time images of the ligand-induced formation of a quadruplex and its reverse conformational switching by removing the ligand was captured by HS-AFM. Unprecedented intermediate-like states were recorded in our real-time analysis.