Interactions of cryptolepine and neocryptolepine with unusual DNA structures

Cryptolepine, the main alkaloid present in the roots of Cryptolepis sanguinolenta, presents a large spectrum of biological properties. It has been reported to behave like a DNA intercalator with a preference for GC-rich sequences. In this study, dialysis competition assay and mass spectrometry experiments were used to determine the affinity of cryptolepine and neocryptolepine for DNA structures among duplexes, triplexes, quadruplexes and single strands. Our data confirm that cryptolepine and neocryptolepine prefer GC over AT-rich duplex sequences, but also recognize triplex and quadruplex structures. These compounds are weak telomerase inhibitors and exhibit a significant preference for triplexes over quadruplexes or duplexes.     

Fluorescence-based duplex-quadruplex competition test to screen for telomerase RNA quadruplex ligands

RNA and DNA guanine-rich sequences can adopt unusual structures called Guanine quadruplexes (G4). A quadruplex-prone RNA sequence is present at the 5'-end of the 451-nt-long RNA component of telomerase, hTERC. As this quadruplex may interfere with P1 helix formation, a key structural element for this RNA, we are seeking molecules that would alter this RNA duplex-quadruplex equilibrium. In this work, we present a fluorescence-based test designed to identify G4 ligands specific for the hTERC G-rich motif and that can prevent P1 helix formation. From an initial panel of 169 different molecules, 11 were found to be excellent P1 duplex inhibitors. Interestingly, some of the compounds not only exhibit a strong selectivity for quadruplexes over duplexes, but also demonstrated a preference for G4-RNA over all other quadruplexes. This test may easily be adapted to almost any quadruplex-forming sequence and converted into HTS format.     

Electrostatics dominate quadruplex stability

Stabilization of nucleic acid structures results from a balance of multiple interactions, including electrostatics, base stacking, hydrophobic interactions, hydrogen bonding, van der Waals forces, etc. Nucleic acid quadruplexes are unusual structures in that their formation is driven by specific binding of metal ions. This unique mode of metal binding, which is tightly coupled to oligonucleotide folding, can engender correspondingly unique solution behavior. In particular, we show that addition of many cosolvents, such as primary aliphatic alcohols, increases the thermal stability of quadruplexes, as determined by melting temperature, Tm, in direct contrast to the response of duplexes to the same admixture of solvents. Thermal stability is observed to increase as the dielectric constant of the composite solvent decreases. This behavior suggests a dominant role for electrostatics in quadruplex formation and stability. Additional studies done with other cosolvents and solutes suggest that, in some cases, other forces may come into play, including the possibility of direct interaction with the quadruplex structure. Nonetheless, many cosolvents and small molecules, such as ethanol, dimethylformamide, and betaine, stabilize the quadruplex conformation in sharp distinction to their destabilization of DNA duplexes.     

A Parallel Quadruplex DNA Is Bound Tightly but Unfolded Slowly by Pif1 Helicase

DNA sequences that can form intramolecular quadruplex structures are found in promoters of proto-oncogenes. Many of these sequences readily fold into parallel quadruplexes. Here we characterize the ability of yeast Pif1 to bind and unfold a parallel quadruplex DNA substrate. We found that Pif1 binds more tightly to the parallel quadruplex DNA than single-stranded DNA or tailed duplexes. However, Pif1 unwinding of duplexes occurs at a much faster rate than unfolding of a parallel intramolecular quadruplex. Pif1 readily unfolds a parallel quadruplex DNA substrate in a multiturnover reaction and also generates some product under single cycle conditions. The rate of ATP hydrolysis by Pif1 is reduced when bound to a parallel quadruplex compared with single-stranded DNA. ATP hydrolysis occurs at a faster rate than quadruplex unfolding, indicating that some ATP hydrolysis events are non-productive during unfolding of intramolecular parallel quadruplex DNA. However, product eventually accumulates at a slow rate.     

Biological aspects of DNA/RNA quadruplexes.

Among the many unusual conformations of DNA and RNA, quadruplex structures, based on the guanine quartet, possess several unique properties. These properties, along with the general features of guanine quadruplexes, are described in the context of possible roles for these structures in biological systems. A variety of experimental observations supporting the notion that quadruplexes are important in vivo is presented, including proteins known to specifically bind to quadruplex structures, guanine-rich DNA, and RNA sequences endowed with the potential for forming quartet-based structures in telomeres and regulatory regions, such as gene promoters, quadruplexes as DNA aptamer folding motifs arising from in vitro selection experiments, and potential chemotherapeutic, quadruplex-forming oligonucleotides. Taken together, all of these observations argue cogently not only for the presence of quadruplexes in biological systems but also for their significance in terms of their roles in various biological processes.     

A comparison of DNA and RNA quadruplex structures and stabilities

Guanosine-rich sequences are prone to fold into four-stranded nucleic acid structures. Such quadruplex sequences have long been suspected to play important roles in regulatory processes within cells. Although DNA quadruplexes have been studied in great detail, four-stranded structures made up from RNA have received only minor attention, although it is known that RNA is able to form stable quadruplexes as well.Here, we compare quadruplex structures and stabilities of a variety of DNA and RNA sequences. We focus on well established DNA sequences and determine the topologies and stabilities of the corresponding RNA sequences by CD spectroscopy and CD thermal melting experiments. We find that the RNA sequences exclusively fold into the all-parallel conformation in contrast to the diverse topologies adopted by DNA quadruplexes. The thermal stabilities of the RNA structures rival those of the corresponding DNA sequences, often displaying enhanced stabilities compared to their DNA counterparts. Especially thermodynamically less stable sequences show a strong preference for potassium, with the RNA quadruplexes exhibiting much higher stabilities than the corresponding DNAs. The latter finding suggests that quadruplexes formed at critical positions in mRNAs might perturb gene expression to a larger extend than previously anticipated.     

Molecular dynamics and principal components analysis of human telomeric quadruplex multimers

Guanine-rich DNA repeat sequences located at the terminal ends of chromosomal DNA can fold in a sequence-dependent manner into G-quadruplex structures, notably the terminal 150-200 nucleotides at the 3′ end, which occur as a single-stranded DNA overhang. The crystal structures of quadruplexes with two and four human telomeric repeats show an all-parallel-stranded topology that is readily capable of forming extended stacks of such quadruplex structures, with external TTA loops positioned to potentially interact with other macromolecules. This study reports on possible arrangements for these quadruplex dimers and tetramers, which can be formed from 8 or 16 telomeric DNA repeats, and on a methodology for modeling their interactions with small molecules. A series of computational methods including molecular dynamics, free energy calculations, and principal components analysis have been used to characterize the properties of these higher-order G-quadruplex dimers and tetramers with parallel-stranded topology. The results confirm the stability of the central G-tetrads, the individual quadruplexes, and the resulting multimers. Principal components analysis has been carried out to highlight the dominant motions in these G-quadruplex dimer and multimer structures. The TTA loop is the most flexible part of the model and the overall multimer quadruplex becoming more stable with the addition of further G-tetrads. The addition of a ligand to the model confirms the hypothesis that flat planar chromophores stabilize G-quadruplex structures by making them less flexible.     

Intramolecular and intermolecular guanine quadruplexes of DNA in aqueous salt and ethanol solutions

DNA guanine quadruplexes are all based on stacks of guanine tetrads, but they can be of many types differing by mutual strand orientation, topology, position and structure of loops, and the number of DNA molecules constituting their structure. Here we have studied a series of nine DNA fragments (G(3)Xn)(3)G(3), where X = A, C or T, and n = 1, 2 or 3, to find how the particular bases and their numbers enable folding of the molecule into quadruplex and what type of quadruplex is formed. We show that any single base between G(3) blocks gives rise to only four-molecular parallel-stranded quadruplexes in water solutions. In contrast to previous models, even two Ts in potential loops lead to tetramolecular parallel quadruplexes and only three consecutive Ts lead to an intramolecular quadruplex, which is antiparallel. Adenines make the DNA less prone to quadruplex formation. (G(3)A(2))(3)G(3) folds into an intramolecular antiparallel quadruplex. The same is true with (G(3)A(3))(3)G(3) but only in KCl. In NaCl or LiCl, (G(3)A(3))(3)G(3) prefers to generate homoduplexes. Cytosine still more interferes with the quadruplex, which only is generated by (G(3)C)(3)G(3), whereas (G(3)C(2))(3)G(3) and (G(3)C(3))(3)G(3) generate hairpins and/or homoduplexes. Ethanol is a more potent DNA guanine quadruplex inducer than are ions in water solutions. It promotes intramolecular folding and parallel orientation of quadruplex strands, which rather corresponds to quadruplex structures observed in crystals.     

Binding properties of human telomeric quadruplex multimers: a new route for drug design

Human telomeric G-quadruplex structures are known to be promising targets for an anticancer therapy. In the past decade, several research groups have been focused on the design of new ligands trying to optimize the interactions between these small molecules and the G-quadruplex motif. In most of these studies, the target structures were the single quadruplex units formed by short human DNA telomeric sequences (typically 21-26 nt). However, the 3′-terminal single-stranded human telomeric DNA is actually 100-200 bases long and can form higher-order structures by clustering several consecutive quadruplex units (multimers). Despite the increasing number of structural information on longer DNA telomeric sequences, very few data are available on the binding properties of these sequences compared with the shorter DNA telomeric sequences.In this paper we use a combination of spectroscopic (CD, UV and fluorescence) and calorimetric techniques (ITC) to compare the binding properties of the (TTAGGG)₈TT structure formed by two adjacent quadruplex units with the binding properties of the (AG₃TT)₄ single quadruplex structure. The three side-chained triazatruxene derivative azatrux and TMPyP4 cationic porphyrin were used as quadruplex ligands. We found that, depending on the drug, the number of binding sites per quadruplex unit available in the multimer structure was smaller or greater than the one expected on the basis of the results obtained from individual quadruplex binding studies. This work suggests that the quadruplex units along a multimer structure do not behave as completely independent. The presence of adjacent quadruplexes results in a diverse binding ability not predictable from single quadruplex binding studies. The existence of quadruplex-quadruplex interfaces in the full length telomeric overhang may provide an advantageous factor in drug design to enhance both affinity and selectivity for DNA telomeric quadruplexes.     

Structure-specific recognition of quadruplex DNA by organic cations: influence of shape, substituents and charge

Combining structure-specific recognition of nucleic acids with limited sequence reading is a promising method to reduce the size of the recognition unit required to achieve the necessary selectivity and binding affinity to control function. It has been demonstrated recently that G-quadruplex DNA structures can be targeted by organic cations in a structure-specific manner. Structural targets of quadruplexes include the planar end surfaces of the G-tetrad stacked columns and four grooves. These provide different geometries and functional groups relative to duplex DNA. We have used surface plasmon resonance and isothermal titration calorimetry to show that binding affinity and selectivity of a series of quadruplex end-stacking molecules to human telomeric DNA are sensitive to compound shape as well as substituent type and position. ITC results indicate that binding is largely enthalpy driven. Circular dichroism was also used to identify a group of structurally related compounds that selectively target quadruplex grooves.     

NMR solution structures of LNA (locked nucleic acid) modified quadruplexes

We have determined the NMR solution structures of the quadruplexes formed by d(TGLGLT) and d(TL₄T), where L denotes LNA (locked nucleic acid) modified G-residues. Both structures are tetrameric, parallel and right-handed and the native global fold of the corresponding DNA quadruplex is retained upon introduction of the LNA nucleotides. However, local structural alterations are observed owing to the locked LNA sugars. In particular, a distinct change in the sugar–phosphate backbone is observed at the G2pL3 and L2pL3 base steps and sequence dependent changes in the twist between tetrads are also seen. Both the LNA modified quadruplexes have raised thermostability as compared to the DNA quadruplex. The quadruplex-forming capability of d(TGLGLT) is of particular interest as it expands the design flexibility for stable parallel LNA quadruplexes and shows that LNA nucleotides can be mixed with DNA or other modified nucleic acids. As such, LNA-based quadruplexes can be decorated by a variety of chemical modifications. Such LNA quadruplex scaffolds might find applications in the developing field of nanobiotechnology.     

Water spines and networks in G-quadruplex structures

Quadruplex DNAs can fold into a variety of distinct topologies, depending in part on loop types and orientations of individual strands, as shown by high-resolution crystal and NMR structures. Crystal structures also show associated water molecules. We report here on an analysis of the hydration arrangements around selected folded quadruplex DNAs, which has revealed several prominent features that re-occur in related structures. Many of the primary-sphere water molecules are found in the grooves and loop regions of these structures. At least one groove in anti-parallel and hybrid quadruplex structures is long and narrow and contains an extensive spine of linked primary-sphere water molecules. This spine is analogous to but fundamentally distinct from the well-characterized spine observed in the minor groove of A/T-rich duplex DNA, in that every water molecule in the continuous quadruplex spines makes a direct hydrogen bond contact with groove atoms, principally phosphate oxygen atoms lining groove walls and guanine base nitrogen atoms on the groove floor. By contrast, parallel quadruplexes do not have extended grooves, but primary-sphere water molecules still cluster in them and are especially associated with the loops, helping to stabilize loop conformations.     

DNA G-quadruplexes are uniquely stable in the presence of denaturants and monovalent cations

Ions in the Hofmeister series exhibit varied effects on biopolymers. Those classed as kosmotropes generally stabilize secondary structure, and those classed as chaotropes generally destabilize secondary structure. Here, we report that several anionic chaotropes exhibit unique effects on one DNA secondary structure - a G quadruplex. These chaotropes exhibit the expected behaviour (destabilization of secondary structure) in two other structural contexts: a DNA duplex and i-Motifs. Uniquely among secondary structures, we observe that G quadruplexes are comparatively insensitive to the presence of anionic chaotropes, but not other denaturants. Further, the presence of equimolar NaCl provided greater mitigation of the destabilization caused by other non-anionic denaturants. These results are consistent with the presence of monovalent cations providing an especially pronounced stabilizing effect to G quadruplexes when studied in denaturing solution conditions.     

Stability and structure of telomeric DNA sequences forming quadruplexes containing four G-tetrads with different topological arrangements

Telomeres are DNA-protein structures at the ends of eukaryotic chromosomes, the DNA of which comprise noncoding repeats of guanine-rich sequences. Telomeric DNA plays a fundamental role in protecting the cell from recombination and degradation. Telomeric sequences can form quadruplex structures stabilized by guanine quartets. These structures can be constructed from one, two, or four oligonucleotidic strands. Here, we report the thermodynamic characterization of the stability, analyzed by differential scanning calorimetry, of three DNA quadruplexes of different molecularity, all containing four G-tetrads. The conformational properties of these quadruple helices were studied by circular dichroism. The investigated oligomers form well-defined G-quadruplex structures in the presence of sodium ions. Two have the truncated telomeric sequence from Oxytricha, d(TGGGGT) and d(GGGGTTTTGGGG), which form a tetramolecular and bimolecular quadruplex, respectively. The third sequence, d(GGGGTTGGGGTGTGGGGTTGGGG) was designed to form a unimolecular quadruplex. The thermodynamic parameters of these quadruplexes have been determined. The tetramolecular structure is thermodynamically more stable than the bimolecular one, which, in turn, is more stable than the unimolecular one. The experimental data were discussed in light of the molecular-modeling study.     

A comparison of the properties and the solution structure for RNA and DNA quadruplexes which contain two GGAGG sequences joined with a tetranucleotide linker

We have determined solution structure of r(GGAGGUUUUGGAGG) (R14) by NMR; the RNA 14-mer forms an intra-strand parallel quadruplex with a G-tetrad and a hexad, in which a G-tetrad core is augmented by association of two A residues. The quadruplex further forms a dimer through stacking interaction between the hexads. In order to obtain insight into the difference between RNA and DNA quadruplexes, we synthesized the corresponding DNA 14-mer, d(GGAGGTTTTGGAGG) (D14), and examined its properties and structure by CD, gel electrophoresis, and NMR. K+ ions increased the thermal stability of both R14 and D14 structures. The binding affinity of K+ ions to R14 was much higher than that to D14. The CD and gel electrophoretic studies suggest that D14 forms a quadruplex entirely different from that of R14 in the presence of K+ ions; two molecules of D14 form a quadruplex with both antiparallel and parallel strand alignments and with diagonal loops at both ends of the stacked G-tetrads. The NMR study also gave results that are consistent with such structure: alternate glycosidic conformation, 5'G(syn)-G(anti)3', and characteristic chemical shift data observed for many quadruplexes containing diagonal TTTT loops.     

Synthesis and in vitro antitumor activity of ring C and D-substituted phenanthrolin-7-one derivatives, analogues of the marine pyridoacridine alkaloids ascididemin and meridine

A series of cycle C and D-substituted phenanthrolin-7-ones, analogues of the marine pyridoacridines meridine and ascididemin have been synthesized on the basis of Diels-Alder reactions involving quinoline-5,8-dione and 2- (or un)-substituted-N,N-dimethylhydrazones. All the compounds were evaluated for in vitro cytotoxic activity against 12 distinct human cancer cell lines. They all exhibit cytotoxic activity with IC(50) values at least of micromolar order.     

The stability of intramolecular DNA G-quadruplexes compared with other macromolecules

DNA quadruplexes are often conceived as very stable structures. However, most of the free energy of stabilization derives from specific ion binding via inner sphere coordination of the GO6 of the guanine residues comprising the basic quartet. When compared with other nucleic acid structures such as DNA or RNA duplexes and hairpins, or proteins of the same number of atoms, metal-coordinated intramolecular quadruplexes are found to be of comparable or lower thermodynamic stability under similar solution conditions. Furthermore, intramolecular quadruplexes are actually less stable kinetically, than DNA duplexes or hairpins of the same size.     

Surface plasmon resonance for probing quadruplex folding and interactions with proteins and small molecules

Surface plasmon resonance is a technique for detecting binding events at the surface of a thin metal film. Through the commercial availability of instrumentation and sensor chips, the technique has found widespread application for determining the affinity and kinetics of macromolecular interactions. A variety of quadruplex forming oligonucleotides have been immobilized to sensor chips to permit analysis of their binding interactions with both small molecule and protein analytes. The fold of the quadruplex must be maintained through an appropriate choice of buffer, and care must be taken to ensure that data interpretation is not hampered by non-specific binding and adsorption of the analyte to the sensor surface and instrument. Affinity constants determined by surface plasmon resonance for interactions with quadruplexes correlate meaningfully with other methods, such as UV-visible and fluorescence titrations, enzyme linked immunosorbent assay, thermal melting studies and telomerase inhibition. Kinetic measurements of the association and dissociation of duplexes of quadruplex forming oligonucleotides and their complementary strands have enabled calculation of the folding and unfolding rates of the quadruplex itself, and determination of its stability as a function of buffer composition.