Effects of an 8-bromodeoxyguanosine incorporation on the parallel quadruplex structure [d(TGGGT)]4

NMR, molecular dynamics and mechanics calculations, and CD spectroscopy were used to characterise three tetramolecular quadruplex complexes: [d(TG(Br)GGT)](4), [d(TGG(Br)GT)](4) and [d(TGGG(Br)T)](4), where G(Br) indicates an 8-bromoguanine residue. All three quadruplexes are characterised by a 4-fold symmetry with all strands parallel to each other and, differently to what has been observed for other parallel quadruplex structures, with a tetrad (formed by 8-Br-dGs) in a syn conformation. The whole of the data demonstrates that the replacement in turn of different dG residues with 8-Br-dG in the sequence 5[prime or minute]-TGGGT-3[prime or minute] affects the resulting structures in different ways, leading to different CD profiles and thermal stabilities. Particularly, [d(TG(Br)GGT)](4) and [d(TGG(Br)GT)](4) are more stable than the unmodified sequence, whereas [d(TGGG(Br)T)](4) is much less stable than the natural counterpart. The conformational features found in the three quadruplexes might, in principle, amplify the range of applicability of synthetic oligonucleotides as aptamers or catalysts, by providing novel structural motifs with different molecular recognition capabilities from those of native DNA sequences.     

Effect of O6-methylguanine on the stability of G-quadruplex DNA

The effects of substitution of O6-methylguanine on the structure and stability of a human telomere quadruplex was studied by circular dichroism, thermal denaturation, analytical ultracentrifugation, and molecular dynamics simulations. The results show that, while quadruplex structures can form containing the modified base, they are much less stable than the normal unmodified structure. The extent of destabilization is critically dependent on the exact position of the modified base within the quadruplex structure.     

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.     

Formation of Human Telomeric G-quadruplex Structures Induced by the Quaternary Benzophenanthridine Alkaloids:Sanguinarine,Nitidine,and Chelerythrine

The ligands which can facilitate the formation and stabilize G‐quadruplex structures have attracted enormous attention due to their potential ability of inhibiting the telomerase activity and halting tumor cell proliferation. It is noteworthy that the abilities of the quaternary benzophenanthridine alkaloids (QBAs), the very important G‐quadruplex binders, in inducing the formation of human telomeric DNA G‐quadruplex structures, have not been reported. Herein, the interaction between single‐strand human telomeric DNA and three QBAs: Sanguinarine (San), Nitidine (Nit) and Chelerythrine (Che), has been investigated. Although these molecules are very similar in structure, they exhibit significantly different abilities in inducing oligonucleotide d(TTAGGG)₄ (HT4) to specific G‐quadruplex structures. Our experimental results indicated that the best ligand San could convert HT4 into antiparallel G‐quadruplex structure completely, followed by Nit, which could transform to mixed‐type or hybrid G‐quadruplex structure partially, whereas Che could only transform to antiparallel G‐quadruplex structure in small quantities. The relative QBAs' inducing abilities as indicated by the CD data are in the order of San>Nit>Che. Further investigation revealed that the G‐quadruplex structures from HT4 induced by QBAs are of intramolecular motif. And only sequences with certain length could be induced by QBAs because of their positive charges which could not attract short chain DNA molecules to close to each other and form intermolecular G‐quadruplex. In addition, the factors that affect the interaction between HT4 and QBAs were discussed. It is proposed that the thickness of the molecular frame and the steric hindrance are the primary reasons why the subtle differences in QBAs' structure lead to their remarkable differences in inducing the formation of the G‐quadruplex structures.     

Structural and thermodynamic studies of the interaction of distamycin A with the parallel quadruplex structure [d(TGGGGT)]4

The complex between distamycin A and the parallel DNA quadruplex [d(TGGGGT)]4 has been studied by 1H NMR spectroscopy and isothermal titration calorimetry (ITC). To unambiguously assert that distamycin A interacts with the grooves of the quadruplex [d(TGGGGT)]4, we have analyzed the NMR titration profile of a modified quadruplex, namely [d(TGGMeGGT)]4, and we have applied the recently developed differential frequency-saturation transfer difference (DF-STD) method, for assessing the ligand-DNA binding mode. The three-dimensional structure of the 4:1 distamycin A/[d(TGGGGT)]4 complex has been determined by an in-depth NMR study followed by dynamics and mechanics calculations. All results unequivocally indicate that distamycin molecules interact with [d(TGGGGT)]4 in a 4:1 binding mode, with two antiparallel distamycin dimers that bind simultaneously two opposite grooves of the quadruplex. The affinity between distamycin A and [d(TGGGGT)]4 enhances ( approximately 10-fold) when the ratio of distamycin A to the quadruplex is increased. In this paper we report the first three-dimensional structure of a groove-binder molecule complexed to a DNA quadruplex structure.     

Gas-phase stability of G-quadruplex DNA determined by electrospray ionization tandem mass spectrometry and molecular dynamics simulations

The relative gas-phase stabilities of seven quadruplex DNA structures, [d(TG(4)T)](4), [d(T(2)G(3)T)](4), [d(G(4)T(4)G(4))](2), [d(T(2)AG(3))(2)](2), d(T(2)AG(3))(4), d(T(2)G(4))(4), and d(G(2)T(4))(4), were investigated using molecular dynamics simulations and electrospray ionization mass spectrometry (ESI-MS). MD simulations revealed that the G-quadruplexes maintained their structures in the gas phase although the G-quartets were distorted to some degree and ammonium ions, retained by [d(TG(4)T)](4) and [d(T(2)G(3)T)](4), played a key role in stabilizing the tetrad structure. Energy-variable collisional activated dissociation was used to assess the relative stabilities of each quadruplex based on E(1/2) values, and the resulting order of relative stabilities was found to be [d(TG(4)T)](4) > d(T(2)AG(3))(4) approximately d(T(2)G(4))(4) > [d(T(2)G(3)T)](4) > [d(T(2)AG(3))(2)](2) approximately d(G(2)T(4))(4) approximately [d(G(4)T(4)G(4))](2.) The stabilities from the E(1/2) values generally paralleled the RMSD and relative free energies of the quadruplexes based on the MD energy analysis. One exception to the general agreement is [d(G(4)T(4)G(4))](2), which had the lowest E(1/2) value, but was determined to be the most stable quadruplex according to the free-energy analysis and ranked fourth based on the RMSD comparison. This discrepancy is attributed to differences in the fragmentation pathway of the quadruplex.     

Spectroscopic detection of DNA quadruplexes by vibrational circular dichroism

The four-stranded G-quadruplex motif is a conformation frequently adopted by guanine-rich nucleic acids that plays an important role in biology, medicine, and nanotechnology. Although vibrational spectroscopy has been widely used to investigate nucleic acid structure, association of particular spectral features with the quadruplex structure has to date been ambiguous. In this work, experimental IR absorption and vibrational circular dichroism (VCD) spectra of the model quadruplex systems d(G)(8) and deoxyguanosine-5'-monophosphate (5'-dGMP) were analyzed using molecular dynamics (MD) and quantum-chemical modeling. The experimental spectra were unambiguously assigned to the quadruplex DNA arrangement, and several IR and VCD bands related to this structural motif were determined. Involvement of MD in the modeling was essential for realistic simulation of the spectra. The VCD signal was found to be more sensitive to dynamical structural variations than the IR signal. The combination of the spectroscopic techniques with multiscale simulations provides extended information about nucleic acid conformations and their dynamics.     

Carbohydrate–DNA Interactions at G‐Quadruplexes: Folding and Stability Changes by Attaching Sugars at the 5′‐End

Quadruplex DNA structures are attracting an enormous interest in many areas of chemistry, ranging from chemical biology, supramolecular chemistry to nanoscience. We have prepared carbohydrate–DNA conjugates containing the oligonucleotide sequences of G‐quadruplexes (thrombin binding aptamer (TBA) and human telomere (TEL)), measured their thermal stability and studied their structure in solution by using NMR and molecular dynamics. The solution structure of a fucose–TBA conjugate shows stacking interactions between the carbohydrate and the DNA G‐tetrad in addition to hydrogen bonding and hydrophobic contacts. We have also shown that attaching carbohydrates at the 5′‐end of a quadruplex telomeric sequence can alter its folding topology. These results suggest the possibility of modulating the folding of the G‐quadruplex by linking carbohydrates and have clear implications in molecular recognition and the design of new G‐quadruplex ligands.     

Structural characterization of G-quadruplexes in deoxyguanosine clusters using ion mobility mass spectrometry

The aggregation and conformation of deoxyguanosine (dG) in an ammonium acetate buffer solution were examined using mass spectrometry, ion mobility, and molecular mechanics/dynamics calculations. The nano-ESI mass spectrum indicated that 4 and 6 dGs cluster with 1 NH4+; 11 dGs with 2 NH4+; 14, 16, and 17 dGs with 3 NH4+; and 23 dGs with 4 NH4+. The collision cross sections with helium were measured and compared with calculated cross sections of theoretical structures generated by molecular mechanics/dynamics calculations. Three distinct arrival time distribution (ATD) peaks were observed for (4dG + NH4)+. One peak was assigned to the quadruplex structure of (4dG + NH4)+, while the other two peaks corresponded to the quadruplex structures of (8dG + 2NH4)2+ and (12dG + 3NH4)3+, all with the same m/z. Four ATD peaks were observed for (6dG + NH4)+ and assigned to the globular structure of (6dG + NH4)+, and the quadruplex structures of (12dG + 2NH4)2+, (18dG + 3NH4)3+, and (24dG + 4NH4)4+. Two ATD peaks were observed for (11dG + 2NH4)2+ and assigned to the quadruplex structures of (11dG + 2NH4)2+ and (22dG + 4NH4)4+. All of the other clusters in the mass spectrum (14, 16, and 17 dGs with 3 NH4+ and 23 dGs with 4 NH4+) only had one peak in their ATDs and in all cases the theoretical structures in a quadruplex arrangement agreed with the experimental cross sections. These results provide compelling evidence that quadruplexes are present in solution and retain their structure during the spray process, dehydration, and detection.     

Identification of Compounds that Selectively Stabilize Specific G‐Quadruplex Structures by Using a Thioflavin T‐Displacement Assay as a Tool

Small molecules are used in the G‐quadruplex (G4) research field in vivo and in vitro, and there are increasing demands for ligands that selectively stabilize different G4 structures. Thioflavin T (ThT) emits an enhanced fluorescence signal when binding to G4 structures. Herein, we show that ThT can be competitively displaced by the binding of small molecules to G4 structures and develop a ThT‐displacement high‐throughput screening assay to find novel and selective G4‐binding compounds. We screened approximately 28 000 compounds by using three different G4 structures and identified eight novel G4 binders. Analysis of the structural conformation and stability of the G4 structures in presence of these compounds demonstrated that the four compounds enhance the thermal stabilization of the structures without affecting their structural conformation. In addition, all four compounds also increased the G4‐structure block of DNA synthesis by Taq DNA polymerase. Also, two of these compounds showed selectivity between certain Schizosaccharomyces pombe G4 structures, thus suggesting that these compounds or their analogues can be used as selective tools for G4 DNA studies.     

Template‐Assembled Synthetic G‐Quadruplex (TASQ): A Useful System for Investigating the Interactions of Ligands with Constrained Quadruplex Topologies

A new biomolecular device for investigating the interactions of ligands with constrained DNA quadruplex topologies, using surface plasmon resonance (SPR), is reported. Biomolecular systems containing an intermolecular‐like G‐quadruplex motif 1 (parallel G‐quadruplex conformation), an intramolecular G‐quadruplex 2 , and a duplex DNA 3 have been designed and developed. The method is based on the concept of template‐assembled synthetic G‐quadruplex (TASQ), whereby quadruplex DNA structures are assembled on a template that allows precise control of the parallel G‐quadruplex conformation. Various known G‐quadruplex ligands have been used to investigate the affinities of ligands for intermolecular 1 and intramolecular 2 DNA quadruplexes. As anticipated, ligands displaying a π‐stacking binding mode showed a higher binding affinity for intermolecular‐like G‐quadruplexes 1 , whereas ligands with other binding modes (groove and/or loop binding) showed no significant difference in their binding affinities for the two quadruplexes 1 or 2 . In addition, the present method has also provided information about the selectivity of ligands for G‐quadruplex DNA over the duplex DNA. A numerical parameter, termed the G‐quadruplex binding mode index (G4‐BMI), has been introduced to express the difference in the affinities of ligands for intermolecular G‐quadruplex 1 against intramolecular G‐quadruplex 2 . The G‐quadruplex binding mode index (G4‐BMI) of a ligand is defined as follows: G4‐BMI=K_D^intra/K_D^inter, where K_D^intra is the dissociation constant for intramolecular G‐quadruplex 2 and K_D^inter is the dissociation constant for intermolecular G‐quadruplex 1 . In summary, the present work has demonstrated that the use of parallel‐constrained quadruplex topology provides more precise information about the binding modes of ligands.     

Triplex and quadruplex DNA structures studied by electrospray mass spectrometry

DNA triplex and quadruplex structures have been successfully detected by electrospray ionization mass spectrometry (ESI-MS). Circular dichroism and UV-melting experiments show that these structures are stable in 150 mM ammonium acetate at pH 7 for the quadruplexes and pH 5.5 for the triplexes. The studied quadruplexes were the tetramer [d(TGGGGT)](4), the dimer [d(GGGGTTTTGGGG)](2), and the intramolecular folded strand dGGG(TTAGGG)(3), which is an analog of the human telomeric sequence. The absence of sodium contamination allowed demonstration of the specific inclusion of n - 1 ammonium cations in the quadruplex structures, where n is the number of consecutive G-tetrads. We also detected the complexes between the quadruplexes and the quadruplex-specific drug mesoporphyrin IX. MS/MS spectra of [d(TGGGGT)](4) and the complex with the drug are also reported. As the drug does not displace the ammonium cations, one can conclude that the drug binds at the exterior of the tetrads, and not between them. For the triplex structure the ESI-MS spectra show the detection of the specific triplex, at m/z values typically higher than those typically observed for duplex species. Upon MS/MS the antigene strand, which is bound into the major groove of the duplex, separates from the triplex. This is the same dissociation pathway as in solution. To our knowledge this is the first report of a triplex DNA structure by electrospray mass spectrometry.     

Human telomeric DNA forms parallel-stranded intramolecular G-quadruplex in K+ solution under molecular crowding condition

The G-rich strand of human telomeric DNA can fold into a four-stranded structure called G-quadruplex and inhibit telomerase activity that is expressed in 85-90% tumor cells. For this reason, telomere quadruplex is emerging as a potential therapeutic target for cancer. Information on the structure of the quadruplex in the physiological environment is important for structure-based drug design targeting the quadruplex. Recent studies have raised significant controversy regarding the exact structure of the quadruplex formed by human telomeric DNA in a physiological relevant environment. Studies on the crystal prepared in K+ solution revealed a distinct propeller-shaped parallel-stranded conformation. However, many later works failed to confirm such structure in physiological K+ solution but rather led to the identification of a different hybrid-type mixed parallel/antiparallel quadruplex. Here we demonstrate that human telomere DNA adopts a parallel-stranded conformation in physiological K+ solution under molecular crowding conditions created by PEG. At the concentration of 40% (w/v), PEG induced complete structural conversion to a parallel-stranded G-quadruplex. We also show that the quadruplex formed under such a condition has unusual stability and significant negative impact on telomerase processivity. Since the environment inside cells is molecularly crowded, our results obtained under the cell mimicking condition suggest that the parallel-stranded quadruplex may be the more favored structure under physiological conditions, and drug design targeting the human telomeric quadruplex should take this into consideration.     

Fast gas-phase hydrogen/deuterium exchange observed for a DNA G-quadruplex

The gas-phase hydrogen/deuterium (H/D) exchange kinetics of DNA G-quadruplexes has been investigated using Fourier transform ion cyclotron resonance mass spectrometry (FTICRMS). The quadruplex [(TGGGGT)4 . 3NH4+] undergoes very fast H/D exchange, in both the positive and in the negative ion modes, compared to DNA duplexes and other quadruplexes tested, and compared to the corresponding single-stranded TGGGGT. Substitution of NH4+ for K+ did not alter this fast H/D exchange, indicating that the hydrogens of the ammonium ions are not those exchanged. However, stripping of the interior cations of the quadruplex by source collision-induced dissociation (CID) in the positive ion mode showed that the presence of the inner cations is essential for the fast exchange to be possible. Molecular dynamics simulations show that the G-quadruplex is very rigid in the gas phase with NH4+ ions inside the tetrads. We suggest that the fast H/D exchange is favored by this rigid quadruplex conformation. This example illustrates that the concept that compact DNA structures exchange H for D slower than unfolded ones is a misconception.     

Effects of Six‐Membered Carbohydrate Rings on Structure,Stability, and Kinetics of G‐Quadruplexes

We have evaluated the conformational, thermal, and kinetic properties of d(TGGGGT) analogues with one or five of the ribose nucleotides replaced with the carbohydrate residues hexitol nucleic acid (HNA), cyclohexenyl nucleic acid (CeNA), or altritol nucleic acid (ANA). All of the modified oligonucleotides formed G‐quadruplexes, but substitution with the six‐membered rings resulted in a mixture of G‐quadruplex structures. UV and CD melting analyses showed that the structure formed by d(TGGGGT) modified with HNA was stabilized whereas that modified with CeNA was destabilized, relative to the structure formed by the unmodified oligonucleotide. Substitution at the fourth base of the G‐tract with ANA resulted in a greater stabilization effect than substitution at the first G residue; substitution with five ANA residues resulted in significant stabilization of the G‐quadruplex. A single substitution with CeNA at the first base of the G‐tract or five substitutions with HNA resulted in striking deceleration or acceleration of G‐quadruplex formation, respectively. Our results shed light on the effect of the sugar moiety on the properties of G‐quadruplex structures.     

Interaction between human telomere and a carbazole derivative: a molecular dynamics simulation of a quadruplex stabilizer and telomerase inhibitor

The mechanism of inhibition of telomerase by drugs is a key factor in an understanding of guanine-quadruplex complex stabilization during human cancer. This study describes a simulated annealing docking and molecular dynamics simulation to investigate a synthesized potent inhibitor, 3,6-bis(1-methyl-4-vinylpyridinium iodine) carbazole (BMVC), which stabilizes the quadruplex structure of the human telomeric DNA sequence d[AG3(T(2)AG(3))3] and inhibits telomerase activity. The compound was predicted to selectively interact with the quadruplex structure. During our simulation, the binding affinities were calculated and used to predict the best drug-binding sites as well as enhanced selectivity compared with other compounds. Our studies suggest that the simulation results quite coincide with the experimental results. In addition, molecular modeling shows that a 2:1 binding model involving the external binding of BMVC to both ends of the G-quartet of d[AG(3)(T(2)AG)3))3] is the most stable binding mode and this agrees with the absorbance titration results that show two binding sites. Of particular interest is that one pyridinium ring and carbazole moiety of the BMVC can stack well at the end of G-quartet. This implies that BMVC is a good human quadruplex stabilizer and also a good telomerase inhibitor.     

Four-stranded DNA structures can be stabilized by two different types of minor groove G:C:G:C tetrads

Four-stranded nucleic acid structures are central to many processes in biology and in supramolecular chemistry. It has been shown recently that four-stranded DNA structures are not only limited to the classical guanine quadruplex but also can be formed by tetrads resulting from the association of Watson-Crick base pairs. Such an association may occur through the minor or the major groove side of the base pairs. Structures stabilized by minor groove tetrads present distinctive features, clearly different from the canonical guanine quadruplex, making these quadruplexes a unique structural motif. Within our efforts to study the sequence requirements for the formation of this unusual DNA motif, we have determined the solution structure of the cyclic oligonucleotide dpCCGTCCGT by two-dimensional NMR spectroscopy and restrained molecular dynamics. This molecule self-associates, forming a symmetric dimer stabilized by two G:C:G:C tetrads with intermolecular G-C base pairs. Interestingly, although the overall three-dimensional structure is similar to that found in other cyclic and linear oligonucleotides of related sequences, the tetrads that stabilize the structure of dpCCGTCCGT are different to other minor groove G:C:G:C tetrads found earlier. Whereas in previous cases the G-C base pairs aligned directly, in this new tetrad the relative position of the two base pairs is slipped along the axis defined by the base pairs. This is the first time that a quadruplex structure entirely stabilized by slipped minor groove G:C:G:C tetrads is observed in solution or in the solid state. However, an analogous arrangement of G-C base pairs occurs between the terminal residues of contiguous duplexes in some DNA crystals. This structural polymorphism between minor groove GC tetrads may be important in stabilization of higher order DNA structures.     

Tridentate N-donor palladium(II) complexes as efficient coordinating quadruplex DNA binders

Fifteen complexes of palladium, platinum, and copper, featuring five different N‐donor tridentate (terpyridine‐like) ligands, were prepared with the aim of testing their G‐quadruplex–DNA binding properties. The fluorescence resonance energy transfer melting assay indicated a striking positive effect of palladium on G‐quadruplex DNA stabilization compared with platinum and copper, as well as an influence of the structure of the organic ligand. Putative binding modes (noncoordinative π stacking and base coordination) of palladium and platinum complexes were investigated by ESI‐MS and UV/Vis spectroscopy experiments, which all revealed a greater ability of palladium complexes to coordinate DNA bases. In contrast, platinum compounds tend to predominantly bind to quadruplex DNA in their aqua form by noncoordinative interactions. Remarkably, complexes of [Pd(ttpy)] and [Pd(tMebip)] (ttpy=tolylterpyridine, tMebip=2,2′‐(4‐p‐tolylpyridine‐2,6‐diyl)bis(1‐methyl‐1H‐benzo[d]imidazole)) coordinate efficiently G‐quadruplex structures at room temperature in less than 1 h, and are more efficient than their platinum counterparts for inhibiting the growth of cancer cells. Altogether, these results demonstrate that both the affinity for G‐quadruplex DNA and the binding mode of metal complexes can be modulated by modifying either the metal or the organic ligand.     

The structure of LNA:DNA hybrids from molecular dynamics simulations: the effect of locked nucleotides

Locked nucleic acids (LNAs) exhibit a modified sugar fragment that is restrained to the C3'-endo conformation. LNA-containing duplexes are rather stable and have a more rigid structure than DNA duplexes, with a propensity for A-conformation of the double helix. To gain detailed insight into the local structure of LNA-modified DNA oligomers (as a foundation for subsequent exploration of the electron-transfer capabilities of such modified duplexes), we carried out molecular dynamics simulations on a set of LNA:DNA 9-mer duplexes and analyzed the resulting structures in terms of base step parameters and the conformations of the sugar residues. The perturbation introduced by a single locked nucleotide was found to be fairly localized, extending mostly to the first neighboring base pairs; such duplexes featured a B-type helix. With increasing degree of LNA modification the structure gradually changed; the duplex with one complete LNA strand assumed a typical A-DNA structure. The relative populations of the sugar conformations agreed very well with NMR data, lending credibility to the validity of the computational protocol.