Effect of loop orientation on quadruplex-TMPyP4 interaction

G-quadruplexes are believed to be potential targets for therapeutic intervention and this has resulted in designing of various quadruplex interacting ligands. Moreover, reports about existence of quadruplex forming sequences across the genome have propelled greater interest in understanding their interaction with small molecules. An intramolecular quadruplex sequence can adopt different conformations, owing to different orientation of loops in the structure. The differences in the loop orientation can affect their molecular recognition. Herein, we have studied the interaction of 5,10,15,20-tetrakis(1-methyl-4-pyridyl)-21H, 23H-porphine (TMPyP4), a well-known G quadruplex binding ligand with three DNA quadruplexes differing in loop orientations. Results obtained from UV, ITC, and SPR studies have coherently revealed that the TMPyP4 molecule shows preferential binding to parallel G-quadruplex ( c-myc and c-kit) over its antiparallel counterpart (human telomeric). The binding affinity for parallel quadruplex was (10(7)) 1 order of magnitude higher than that for antiparallel DNA quadruplex (10 ). The study shows two binding modes, stronger binding (10(7)) of TMPyP4 involving end stacking and a weaker external binding (10 ), while TMPyP4 shows only one binding mode with duplex with a binding affinity of the order of 10(6). Overall, the study emphasizes that differences in the loop orientation give rise to different conformations of quadruplex, which in turn govern its binding to small molecules, and thereby play a pivotal role in molecular recognition.     

Interaction of Metal Complexes with G‐Quadruplex DNA

Guanine‐rich sequences of DNA can assemble into tetrastranded structures known as G‐quadruplexes. It has been suggested that these secondary DNA structures could be involved in the regulation of several key biological processes. In the human genome, guanine‐rich sequences with the potential to form G‐quadruplexes exist in the telomere as well as in promoter regions of certain oncogenes. The identification of these sequences as novel targets for the development of anticancer drugs has sparked great interest in the design of molecules that can interact with quadruplex DNA. While most reported quadruplex DNA binders are based on purely organic templates, numerous metal complexes have more recently been shown to interact effectively with this DNA secondary structure. This Review provides an overview of the important roles that metal complexes can play as quadruplex DNA binding molecules, highlighting the unique properties metals can confer to these molecules.     

Stability and cations coordination of DNA and RNA 14-mer G-quadruplexes: a multiscale computational approach

Molecular dynamics simulations have been used to study the differences between two DNA and RNA 14-mer quadruplexes of analogous sequences. Their structures present a completely different fold: DNA forms a bimolecular quadruplex containing antiparallel strands and diagonal loops; RNA forms an intrastrand parallel quadruplex containing a G-tetrad and an hexad, which dimerizes by hexad stacking. We used a multiscale computational approach combining classical Molecular dynamics simulations and density functional theory calculations to elucidate the difference in stability of the 2-folds and their ability in coordinating cations. The presence of 2'-OH groups in the RNA promotes the formation of a large number of intramolecular hydrogen bonds that account for the difference in fold and stability of the two 14-mers. We observe that the adenines in the RNA quadruplex play a key role in conserving the geometry of the hexad. We predict the cation coordination mode of the two quadruplexes, not yet observed experimentally, and we offer a rationale for the corresponding binding energies involved.     

Topology variation and loop structural homology in crystal and simulated structures of a bimolecular DNA quadruplex

The topology of DNA quadruplexes depends on the nature and number of the nucleotides linking G-quartet motifs. To assess the effects of a three-nucleotide TTT linker, the crystal structure of the DNA sequence d(G(4)T(3)G(4)) has been determined at 1.5 A resolution, together with that of the brominated analogue d(G(4)(Br)UTTG(4)) at 2.4 A resolution. Both sequences form bimolecular intermolecular G-quadruplexes with lateral loops. d(G(4)(Br)UTTG(4)) crystallized in the monoclinic space group P2(1) with three quadruplex molecules in the asymmetric unit, two associating together as a head-to-head stacked dimer, and the third as a single head-to-tail dimer. The head-to-head dimers have two lateral loops on the same G-quadruplex face and form an eight-G-quartet stack, with a linear array of seven K(+) ions between the quartets. d(G(4)T(3)G(4)) crystallized in the orthorhombic space group C222 and has a structure very similar to the head-to-tail dimer in the P2(1) unit cell. The sequence studied here is able to form several different folds; however, all four quadruplexes in the two structures have lateral loops, in contrast to the diagonal loops reported for the analogous quadruplex with T(4) loops. A total of seven independent T(3) loops were observed in the two structures. These can be classified into two discrete conformational classes, suggesting that these represent preferred loop conformations that are independent of crystal-packing forces.     

Binding of a Telomestatin Derivative Changes the Mechanical Anisotropy of a Human Telomeric G‐Quadruplex

Mechanical anisotropy is an essential property for biomolecules to assume structural and functional roles in mechanobiology. However, there is insufficient information on the mechanical anisotropy of ligand–biomolecule complexes. Herein, we investigated the mechanical property of individual human telomeric G‐quadruplexes bound to telomestatin, using optical tweezers. Stacking of the ligand to the G‐tetrad planes changes the conformation of the G‐quadruplex, which resembles a balloon squeezed in certain directions. Such a squeezed balloon effect strengthens the G‐tetrad planes, but dislocates and weakens the loops in the G‐quadruplex upon ligand binding. These dynamic interactions indicate that the binding between the ligand and G‐quadruplex follows the induced‐fit model. We anticipate that the altered mechanical anisotropy of the ligand–G‐quadruplex complex can add additional level of regulations on the motor enzymes that process DNA or RNA molecules.     

Dual Binding of an Antibody and a Small Molecule Increases the Stability of TERRA G‐Quadruplex

In investigating the binding interactions between the human telomeric RNA (TERRA) G‐quadruplex (GQ) and its ligands, it was found that the small molecule carboxypyridostatin (cPDS) and the GQ‐selective antibody BG4 simultaneously bind the TERRA GQ. We previously showed that the overall binding affinity of BG4 for RNA GQs is not significantly affected in the presence of cPDS. However, single‐molecule mechanical unfolding experiments revealed a population (48 %) with substantially increased mechanical and thermodynamic stability. Force‐jump kinetic investigations suggested competitive binding of cPDS and BG4 to the TERRA GQ. Following this, the two bound ligands slowly rearrange, thereby leading to the minor population with increased stability. Given the relevance of G‐quadruplexes in the regulation of biological processes, we anticipate that the unprecedented conformational rearrangement observed in the TERRA‐GQ–ligand complex may inspire new strategies for the selective stabilization of G‐quadruplexes in cells.     

Quadruplex formation by a guanine-rich PNA oligomer

A guanine-rich PNA dodecamer having the sequence H-G4T4G4-Lys-NH2 (G-PNA) hybridizes with a DNA dodecamer of homologous sequence to form a four-stranded quadruplex (Datta, B.; Schmitt, C.; Armitage, B. A. J. Am. Chem. Soc. 2003, 125, 4111-4118). This report describes quadruplex formation by the PNA alone. UV melting curves and fluorescence resonance energy transfer experiments reveal formation of a multistranded structure stabilized by guanine tetrads. The ion dependency of these structures is analogous to that reported for DNA quadruplexes. Electrospray ionization mass spectrometry indicates that both dimeric and tetrameric quadruplexes are formed by G4-PNA, with the dimeric form being preferred. These results have implications for the use of G-rich PNA for homologous hybridization to G-rich targets in chromosomal DNA and suggest additional applications in assembling quadruplex structures within lipid bilayer environments.     

Binding Behaviors for Different Types of DNA G‐Quadruplexes: Enantiomers of [Ru(bpy)2(L)]2+ (L=dppz,dppz‐idzo)

Polymorphic DNA G‐quadruplex recognition has attracted great interest in recent years. The strong binding affinity and potential enantioselectivity of chiral [Ru(bpy)₂(L)]²⁺ (L=dipyrido[3,2‐a:2′,3′‐c]phenazine, dppz‐10,11‐imidazolone; bpy=2,2′‐bipyridine) prompted this investigation as to whether the two enantiomers, Δ and Λ, can show different effects on diverse structures with a range of parallel, antiparallel and mixed parallel/antiparallel G‐quadruplexes. These studies provide a striking example of chiral‐selective recognition of DNA G‐quadruplexes. As for antiparallel (tel‐Na⁺) basket G‐quadruplex, the Λ enantiomers bind stronger than the Δ enantiomers. Moreover, the behavior reported here for both enantiomers stands in sharp contrast to B‐DNA binding. The chiral selectivity toward mixed parallel/antiparallel (tel‐K⁺) G‐quadruplex of both compounds is weak. Different loop arrangements can change chiral complex selectivity for both antiparallel and mixed parallel/antiparallel G‐quadruplex. Whereas both Δ and Λ isomers bind to parallel G‐quadruplexes with comparable affinity, no appreciable stereoselective G‐quadruplex binding of the isomers was observed. In addition, different binding stoichiometries and binding modes for Δ and Λ enantiomers were confirmed. The results presented here indicate that chiral selective G‐quadruplex binding is not only related to G‐quadruplex topology, but also to the sequence and the loop constitution.     

A Chimeric DNA/RNA Antiparallel Quadruplex with Improved Stability

Nucleic acid quadruplexes are proposed to play a role in the regulation of gene expression, are often present in aptamers selected for specific binding functions and have potential applications in medicine and biotechnology. Therefore, understanding their structure and thermodynamic properties and designing highly stable quadruplexes is desirable for a variety of applications. Here, we evaluate DNA→RNA substitutions in the context of a monomolecular, antiparallel quadruplex, the thrombin-binding aptamer (TBA, GGTTGGTGTGGTTGG) in the presence of either K⁺ or Sr²⁺. TBA predominantly folds into a chair-type configuration containing two G-tetrads, with G residues in both syn and anti conformation. All chimeras with DNA→RNA substitutions (G→g) at G residues requiring the syn conformation demonstrated strong destabilization. In contrast, G→g substitutions at Gs with anti conformation increased stability without affecting the monomolecular chair-type topology. None of the DNA→RNA substitutions in loop positions affected the quadruplex topology; however, these substitutions varied widely in their stabilizing or destabilizing effects in an unpredictable manner. This analysis allowed us to design a chimeric DNA/RNA TBA construct that demonstrated substantially improved stability relative to the all-DNA construct. These results have implications for a variety of quadruplex-based applications including for the design of dynamic nanomachines.     

An Aggregating Amphiphilic Squaraine: A Light‐up Probe That Discriminates Parallel G‐Quadruplexes

G‐quadruplexes (G4s) are peculiar DNA or RNA tertiary structures that are involved in the regulation of many biological events within mammalian cells, bacteria, and viruses. Although their role as versatile therapeutic targets has been emphasized for 35 years, G4 selectivity over ubiquitous double‐stranded DNA/RNA, as well as G4 differentiation by small molecules, still remains challenging. Here, a new amphiphilic dicyanovinyl‐substituted squaraine, SQgl , is reported to act as an NIR fluorescent light‐up probe discriminating an extensive panel of parallel G4s while it is non‐fluorescent in the aggregated state. The squaraine can form an unconventional sandwich π‐complex binding two quadruplexes, which leads to a strongly fluorescent (Φ _F=0.61) supramolecular architecture. SQgl is highly selective against non‐quadruplex and non‐parallel G4 sequences without altering their topology, as desired for applications in selective in vivo high‐resolution imaging and theranostics.     

Selective and Cooperative Ligand Binding to Antiparallel Human Telomeric DNA G‐Quadruplexes

The quest for ligands that specifically bind to particular G‐quadruplex nucleic acid structures is particularly important to conceive molecules with specific effects on gene expression or telomere maintenance, or conceive structure‐specific molecular probes. Using electrospray mass spectrometry in native conditions, we reveal a highly cooperative and selective 2:1 binding of Cu^II‐tolylterpyridine complexes to human telomeric G‐quadruplexes. Circular dichroism and comparisons of affinities for different sequences reveal a marked preference for antiparallel structures with diagonal loops and/or wide‐medium–narrow‐medium groove‐width order. The cooperativity is attributed to conformational changes in the polymorphic telomeric G‐quadruplex sequences, which convert preferably into an antiparallel three‐quartet topology upon binding of two ligands.     

Tandem mass spectrometry of platinated quadruplex DNA

Quadruplexes are higher-order structures formed by G-rich DNA strands that are involved in various processes of cell cycle regulation, such as control of telomere length and participation in gene regulation. Because of these central biological functions, quadruplex DNA represents a promising target for cancer therapy, e.g. by applying organometallic drugs, such as cisplatin. High-resolution electrospray tandem mass spectrometry is evaluated as a technique for exploring structural features of unplatinated and platinated quadruplexes. Results of experiments on tetramolecular, bimolecular and monomolecular quadruplexes provide information about the extent of platination and the binding sites of the drug. The dissociation behavior of the different types of quadruplexes is compared. Tetramolecular quadruplexes were found to weave out a strand end in order to provide a platination site, and their fragmentation is characterized by the release of an unplatinated strand and the formation of a platinated triplex. Partial opening of the structure in combination with the loss of small fragments leads to truncated quadruplex ions. For the bimolecular quadruplexes studied, strand separation is the predominant dissociation pathway. Depending on the loop sequence, cross-linking of the loops by cisplatin is demonstrated. Distinct differences in the product ion spectra of unannealed and annealed monomolecular sequences provide proof of quadruplex formation and show that platination preferentially occurs at the terminal regions.     

Monomer–Dimer Equilibrium for the 5′–5′ Stacking of Propeller‐Type Parallel‐Stranded G‐Quadruplexes: NMR Structural Study

Guanine‐rich sequence motifs, which contain tracts of three consecutive guanines connected by single non‐guanine nucleotides, are abundant in the human genome and can form a robust G‐quadruplex structure with high stability. Herein, by using NMR spectroscopy, we investigate the equilibrium between monomeric and 5′–5′ stacked dimeric propeller‐type G‐quadruplexes that are formed by DNA sequences containing GGGT motifs. We show that the monomer–dimer equilibrium depends on a number of parameters, including the DNA concentration, DNA flanking sequences, the concentration and type of cations, and the temperature. We report on the high‐definition structure of a simple monomeric G‐quadruplex containing three single‐residue loops, which could serve as a reference for propeller‐type G‐quadruplex structures in solution.     

Loop-length-dependent folding of G-quadruplexes

Guanine-rich DNA sequences can form a large number of structurally diverse quadruplexes. These vary in terms of strand polarity, loop composition, and conformation. We have derived guidelines for understanding the influence of loop length on the structure adopted by intramolecular quadruplex-forming sequences, using a combination of experimental (using CD and UV melting data) and molecular modeling and simulation techniques. We find that a parallel-stranded intramolecular quadruplex structure is the only possible fold when three single residue loops are present. When single thymine loops are present in combination with longer length loops, or when all loops are longer than two residues, both parallel- and antiparallel-folded structures are able to form. Multiple conformations of each structure are likely to coexist in solution, as they were calculated to have very similar free energies.     

Photocrosslinking of G‐Quadruplex‐Forming Sequences found in Human Promoters

While is it well known that human telomeric DNA sequences can adopt G‐quadruplex structures, some promoters sequences have also been found to form G‐quadruplexes, and over 40% of promoters contain putative G‐quadruplex‐forming sequences. Because UV light has been shown to crosslink human telomeric G‐quadruplexes by cyclobutane pyrimidine dimer (CPD) formation between T's on adjacent loops, UV light might also be able to photocrosslink G‐quadruplexes in promoters. To investigate this possibility, 15 potentially UV‐crosslinkable G‐quadruplex‐forming sequences found in a search of human DNA promoters were UVB irradiated in vitro, and three were confirmed to have formed nonadjacent CPDs by mass spectrometry. In addition to nonadjacent T=T CPDs found in human telomeric DNA, a nonadjacent T=U CPD was discovered that presumably arose from deamination of a nonadjacent T=C CPD. Analysis of the three sequences by circular dichroism, melting temperature analysis and chemical footprinting confirmed the presence of G‐quadruplexes that could explain the formation of the nonadjacent CPDs. The formation of nonadjacent CPDs from the sequences in vitro suggests that they might be useful probes for the presence of non‐B DNA structures, such as G‐quadruplexes, in vivo, and if they were to form in vivo, might also have significant biological consequences.     

Orienting Tetramolecular G‐Quadruplex Formation: The Quest for the Elusive RNA Antiparallel Quadruplex

DNA and RNA G‐quadruplexes (G4) are unusual nucleic acid structures involved in a number of key biological processes. RNA G‐quadruplexes are less studied although recent evidence demonstrates that they are biologically relevant. Compared to DNA quadruplexes, RNA G4 are generally more stable and less polymorphic. Duplexes and quadruplexes may be combined to obtain pure tetrameric species. Here, we investigated whether classical antiparallel duplexes can drive the formation of antiparallel tetramolecular quadruplexes. This concept was first successfully applied to DNA G4. In contrast, RNA G4 were found to be much more unwilling to adopt the forced antiparallel orientation, highlighting that the reason RNA adopts a different structure must not be sought in the loops but in the G‐stem structure itself. RNA antiparallel G4 formation is likely to be restricted to a very small set of peculiar sequences, in which other structural features overcome the formidable intrinsic barrier preventing its formation.     

Enhanced stability of G-quadruplexes from conformationally constrained aep-PNA backbone

Nucleic (DNA) acids having contiguous stretch of G sequence form quadruplex structure, which is very critical to control cell division. Recently the existence of G-quadruplex in RNA is also reported in presence of monovalent metal ion. PNA is a promising DNA analogue which binds strongly to DNA to form PNA:DNA duplex or PNA(2):DNA triplex. PNA also forms quadruplexes such G-quadruplex and i-motif in G and C-rich sequences respectively. aep-PNA containing a prolyl ring is one of several PNA analogues that provide rigidity and chirality in backbone and has binding affinity to natural DNA which is higher than that of PNA. Here we examine the ability of aep-PNA-G to form a quadruplex by UV, CD and mass spectroscopic techniques.     

Formation of a Ligand‐Assisted Complex of Two RNA Hairpin Loops

The hairpin structure is one of the most common secondary structures in RNA and holds a central position in the stream of RNA folding from a non‐structured RNA to structurally complex and functional ribonucleoproteins. Since the RNA secondary structure is strongly correlated to the function and can be modulated by the binding of small molecules, we have investigated the modulation of RNA folding by a ligand‐assisted formation of loop–loop complexes of two RNA hairpin loops. With a ligand (NCT6), designed based on the ligand binding to the G–G mismatches in double‐stranded DNA, we successfully demonstrated the formation of both inter‐ and intra‐molecular NCT6‐assisted complex of two RNA hairpin loops. NCT6 selectively bound to the two hairpin loops containing (CGG)₃ in the loop region. Native polyacrylamide gel electrophoresis analysis of two doubly‐labeled RNA hairpin loops clearly showed the formation of intermolecular NCT6‐assisted loop–loop complex. Förster resonance energy‐transfer studies of RNA constructs containing two hairpin loops, in which each hairpin was labeled with Alexa488 and Cy3 fluorophores, showed the conformational change of the RNA constructs upon binding of NCT6. These experimental data showed that NCT6 simultaneously bound to two hairpin RNAs at the loop region, and can induce the conformational change of the RNA molecule. These data strongly support that NCT6 functions as molecular glue for two hairpin RNAs.     

Solution NMR Structure of a Ligand/Hybrid‐2‐G‐Quadruplex Complex Reveals Rearrangements that Affect Ligand Binding

Telomeric G‐quadruplexes have recently emerged as drug targets in cancer research. Herein, we present the first NMR structure of a telomeric DNA G‐quadruplex that adopts the biologically relevant hybrid‐2 conformation in a ligand‐bound state. We solved the complex with a metalorganic gold(III) ligand that stabilizes G‐quadruplexes. Analysis of the free and bound structures reveals structural changes in the capping region of the G‐quadruplex. The ligand is sandwiched between one terminal G‐tetrad and a flanking nucleotide. This complex structure involves a major structural rearrangement compared to the free G‐quadruplex structure as observed for other G‐quadruplexes in different conformations, invalidating simple docking approaches to ligand–G‐quadruplex structure determination.