Structures of the potassium-saturated, 2:1, and intermediate, 1:1, forms of a quadruplex DNA

Potassium can stabilize the formation of chair- or edge-type quadruplex DNA structures and appears to be the only naturally occurring cation that can do so. As quadruplex DNAs may be important in the structure of telomere, centromere, triplet repeat and other DNAs, information about the details of the potassium–quadruplex DNA interactions are of interest. The structures of the 1:1 and the fully saturated, 2:1, potassium–DNA complexes of d(GGTTGGTGTGGTTGG) have been determined using the combination of experimental NMR results and restrained molecular dynamics simulations. The refined structures have been used to model the interactions at the potassium binding sites. Comparison of the 1:1 and 2:1 potassium:DNA structures indicates how potassium binding can determine the folding pattern of the DNA. In each binding site potassium interacts with the carbonyl oxygens of both the loop thymine residues and the guanine residues of the adjacent quartet.     

Vertebrate telomere repeat DNAs favor external loop propeller quadruplex structures in the presence of high concentrations of potassium

The circular dichroism, CD, spectra of the telomere repeats of vertebrates, d(TTAGGG), indicate that parallel type quadruplex structures or disordered single-stranded structures are formed in low salt. Anti-parallel quadruplex structures are favored in the presence of high concentrations, 140 mM, of sodium. External loop, also known as propeller, parallel type structures are favored in the presence of high concentrations, 100 mM, of potassium in the presence of either 5 or 140 mM sodium. The cation dependence of the CD spectra of the vertebrate telomere repeat DNAs is distinctly different from that of the telomere repeats of Tetrahymena and Oxytricha as well as that of the thrombin binding aptamer. These results indicate that the external loop structures may be present in vertebrate telomeres under the conditions of high potassium and low sodium concentration found in nuclei.     

Finding and Characterizing the Complexes of Drug Like Molecules with Quadruplex DNA: Combined Use of an Enhanced Hydroxyl Radical Cleavage Protocol and NMR

Structural information on the complexes of drug like molecules with quadruplex DNAs can aid the development of therapeutics and research tools that selectively target specific quadruplex DNAs. Screening can identify candidate molecules that require additional evaluation. An enhanced hydroxyl radical cleavage protocol is demonstrated that can efficiently provide structural information on the complexes of the candidate molecules with quadruplex DNA. NMR methods have been used to offer additional structural information about the complexes as well as validate the results of the hydroxyl radical approach. This multi-step protocol has been demonstrated on complexes of the chair type quadruplex formed by the thrombin binding aptamer, d(GGTTGGTGTGGTTGG). The hydroxyl radical results indicate that NSC 176319, Cain’s quinolinium that was found by screening, exhibits selective binding to the two TT loops. The NMR results are consistent with selective disruption of the hydrogen bonding between T4 and T13 as well as unstacking of these residues from the bottom quartet. Thus, the combination of screening, hydroxyl radical footprinting and NMR can find new molecules that selectively bind to quadruplex DNAs as well as provide structural information about their complexes.     

Determination of the number and location of the manganese binding sites of DNA quadruplexes in solution by EPR and NMR.

The paramagnetic metal ion Mn2+ has been used to probe the electrostatic potentials of a DNA quadruplex that has two quartets with an overall fold of the chair type. A quadruplex with a basket type structure has also been examined. The binding of the paramagnetic ion manganese to these quadruplex DNAs has been investigated by solution state electron paramagnetic resonance (EPR) and nuclear magnetic resonance (NMR) spectroscopies. The EPR results indicate that the DNA aptamer, d(GGTTGGTGTGGTTGG), binds two manganese ions and that the binding constants for each of these sites is approximately 10(5) M-1. The NMR results indicate that the binding sites of the manganese are in the narrow grooves of this quadruplex DNA. The binding sites of the DNA quadruplex formed by dimers of d(GGGGTTTTGGGG) which forms a basket structure are also in the narrow groove. These results indicate that the close approach of phosphates in the narrow minor grooves of the quadruplex structures provide strong binding sites for the manganese ions and that EPR and NMR monitoring of manganese binding can be used to distinguish between the different types of quadruplex structures.     

Role of loop residues and cations on the formation and stability of dimeric DNA G-quadruplexes

Formation of guanine-quadruplexes by four DNA oligonucleotides with common sequence dG4-loop-dG4 has been studied by a combination of NMR and UV spectroscopy. The loops consisted of 1',2'-dideoxyribose, propanediol, hexaethylene glycol, and thymine residues. The comparison of data on modified and parent oligonucleotides gave insight into the role of loop residues on formation and stability of dimeric G-quadruplexes. All modified oligonucleotides fold into dimeric fold-back G-quadruplexes in the presence of sodium ions. Multiple structures form in the presence of potassium and ammonium ions, which is in contrast to the parent oligonucleotide with dT4 loop. 15N-filtered 1H NMR spectra demonstrate that all studied G-quadruplexes exhibit three 15NH4(+) ion binding sites. Topology of intermolecular G-quadruplexes was evaluated by NMR measurements and diffusion experiments. The spherical, prolate-ellipsoid and symmetric cylinder models were used to interpret experimental translational diffusion constants in terms of diameters and lengths of unfolded oligonucleotides and their respective G-quadruplexes. UV melting and annealing curves show that oligonucleotides with non-nucleosidic loop residues fold faster, exhibit no hysteresis, and are less stable than dimeric d(G4T4G4)2 which can be attributed to the absence of H-bonds, stacking between loop residues and the outer G-quartets as well as cation-pi interactions. Oligonucleotide consisting of hexaethylene glycol linkage with only two phosphate groups in the loop exhibits higher melting temperature and more negative deltaH(o) and deltaG(o) values than oligonucleotides with four 1',2'-dideoxyribose or propanediol residues.     

Monovalent cation induced structural transitions in telomeric DNAs: G-DNA folding intermediates

Telomeric DNA consists of G- and C-rich strands that are always polarized such that the G-rich strand extends past the 3' end of the duplex to form a 12-16-base overhang. These overhanging strands can self-associate in vitro to form intramolecular structures that have several unusual physical properties and at least one common feature, the presence of non-Watson-Crick G.G base pairs. The term "G-DNA" was coined for this class of structures (Cech, 1988). On the basis of gel electrophoresis, imino proton NMR, and circular dichroism (CD) results, we find that changing the counterions from sodium to potassium (in 20 mM phosphate buffers) specifically induces conformational transitions in the G-rich telomeric DNA from Tetrahymena, d(T2G4)4 (TET4), which results in a change from the intramolecular species to an apparent multistranded structure, accompanied by an increase in the melting temperature of the base pairs of greater than 25 degrees, as monitored by loss of the imino proton NMR signals. NMR semiselective spin-lattice relaxation rate measurements and HPLC size-exclusion chromatography studies show that in 20 mM potassium phosphate (pH 7) buffer (KP) TET4 is approximately twice the length of the form obtained in 20 mM sodium phosphate (pH 7) buffer (NaP) and that mixtures of Na+ and K+ produce mixtures of the two forms whose populations depend on the ratio of the cations. Since K+ and NH4+ are known to stabilize a parallel-stranded quadruplex structure of poly[r(I)4], we infer that the multistranded structure is a quadruplex. Our results indicate that specific differences in ionic interactions can result in a switch in telomeric DNAs between intramolecular hairpin-like or quadruplex-containing species and intermolecular quadruplex structures, all of which involve G.G base pairing interactions. We propose a model in which duplex or hairpin forms of G-DNA are folding intermediates in the formation of either 1-, 2-, or 4-stranded quadruplex structures. In this model monovalent cations stabilize the duplex and quadruplex forms via two distinct mechanisms, counterion condensation and octahedral coordination to the carbonyl groups in stacked planar guanine "quartet" base assemblies. Substituting one of the guanosine residues in each of the repeats of the Tetrahymena sequence to give the human telomeric DNA, d(T2AG3)4, results in less effective K(+)-dependent stabilization. Thus, the ion-dependent stabilization is attenuated by altering the sequence. Upon addition of the Watson-Crick (WC) complementary strand, only the Na(+)-stabilized structure dissociates quickly to form a WC double helix.(ABSTRACT TRUNCATED AT 400 WORDS)     

46 Effect of guanine substitutions in human telomeric G3(T2AG3)3 DNA sequence

In addition to the well-known Watson–Crick double helix, DNA can form other structures. One of them is a four-stranded quadruplex, formation of which was also acknowledged in in vivo conditions. It was suggested that the presence of quadruplexes in e.g. telomeric region has a significant biological importance. We have studied structural properties of the human telomeric quadruplex formed by G₃(T₂AG₃)₃ and related sequences, in which each guanine base was one-by-one replaced by adenine. In the next step, we have studied sequences, in which two, or even four guanines were replaced by adenine. These sequences were studied in the presence of sodium or potassium ions. Using CD spectroscopy, UV thermal stability measurements, and polyacrylamide gel electrophoresis we found that none of the substitutions hindered the formation of the antiparallel quadruplex formed by the unsubstituted sequence in sodium solutions. However, the effect of substitution differed depending on the position of the guanine replaced. The middle quartet of the antiparallel basket scaffold was the most sensitive and led to the least stable structures. With other sequences, the effect of substitution depends on the position and also on the syn/anti glycosidic bond orientation of the appropriate guanosine in the original quadruplex structure. In the case of the multiple A for G substitutions, the G₃(T₂AG₃)₃ quadruplex was most destabilized by the G:G:A:A tetrad, in which the adenosines substituted syn guanosines. Interestingly, unlike with G₃(T₂AG₃)₃, no structural transitions were observed with the A-containing analogs of the sequence when sodium ions were replaced by potassium ions. The basic quadruplex topology remained antiparallel for all modified sequences in both salts. As in vivo misincorporation of A for a G in the telomeric sequence is possible and potassium is a physiological salt, these findings may be biologically important. In our next studies, we have compared the effect of the G to A substitutions in the human telomere sequence with 8-oxoguanine substituted samples or samples containing guanine apurinic sites. Data obtained from our study show a noticeable trend: it is not the type of the lesion but the position of the modification determines the effect on the conformation and stability of the quadruplex.     

Circular dichroism of quadruplex DNAs: applications to structure, cation effects and ligand binding

Circular dichroism, CD, spectra can be used to gain information about quadruplex structures of DNAs as well as the effects of sequence, cations, chemical modification and ligand binding on quadruplex structure. There is not yet a validated approach to calculate a CD spectrum from a quadruplex structure nor is their one to go from a CD spectrum to a structure. However, it is possible to empirically correlate CD spectra features with quadruplex structural type in many cases. In this article four case studies are presented to indicate the strengths and limitations of CD in investigations of the properties of quadruplex structures formed by telomere repeat sequences. The case studies include determination of the quadruplex structural type present as a function of potassium concentration, the effect of sequence on the equilibrium between quadruplex structural types as a function of potassium concentration, the effect of ligand binding on quadruplex structure and the effect of 5' phosphorylation on quadruplex structural type.     

The effect on quadruplex stability of North-nucleoside derivatives in the loops of the thrombin-binding aptamer

Modified thrombin-binding aptamers (TBAs) carrying uridine (U), 2'-deoxy-2'-fluorouridine (FU) and North-methanocarbathymidine (NT) residues in the loop regions were synthesized and analyzed by UV thermal denaturation experiments and CD spectroscopy. The replacement of thymidines in the TGT loop by U and FU results in an increased stability of the antiparallel quadruplex structure described for the TBA while the presence of NT residues in the same positions destabilizes the antiparallel structure. The substitution of the thymidines in the TT loops for U, FU and NT induce a destabilization of the antiparallel quadruplex, indicating the crucial role of these positions. NMR studies on TBAs modified with uridines at the TGT loop also confirm the presence of the antiparallel quadruplex structure. Nevertheless, replacement of two Ts in the TT loops by uridine gives a more complex scenario in which the antiparallel quadruplex structure is present along with other partially unfolded species or aggregates.     

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.     

A parallel stranded G‐quadruplex composed of threose nucleic acid (TNA)

G‐rich sequences can adopt four‐stranded helical structures, called G‐quadruplexes, that self‐assemble around monovalent cations like sodium (Na⁺) and potassium (K⁺). Whether similar structures can be formed from xeno‐nucleic acid (XNA) polymers with a shorter backbone repeat unit is an unanswered question with significant implications on the fold space of functional XNA polymers. Here, we examine the potential for TNA (α‐l ‐threofuranosyl nucleic acid) to adopt a four‐stranded helical structure based on a planar G‐quartet motif. Using native polyacrylamide gel electrophoresis (PAGE), circular dichroism (CD) and solution‐state nuclear magnetic resonance (NMR) spectroscopy, we show that despite a backbone repeat unit that is one atom shorter than the backbone repeat unit found in DNA and RNA, TNA can self‐assemble into stable G‐quadruplex structures that are similar in thermal stability to equivalent DNA structures. However, unlike DNA, TNA does not appear to discriminate between Na⁺ and K⁺ ions, as G‐quadruplex structures form equally well in the presence of either ion. Together, these findings demonstrate that despite a shorter backbone repeat unit, TNA is capable of self‐assembling into stable G‐quadruplex structures.     

Stability of intramolecular quadruplexes: sequence effects in the central loop

Hundreds of thousands of putative quadruplex sequences have been found in the human genome. It is important to understand the rules that govern the stability of these intramolecular structures. In this report, we analysed sequence effects in a 3-base-long central loop, keeping the rest of the quadruplex unchanged. A first series of 36 different sequences were compared; they correspond to the general formula GGGTTTGGGHNHGGGTTTGGG. One clear rule emerged from the comparison of all sequence motifs: the presence of an adenine at the first position of the loop was significantly detrimental to stability. In contrast, adenines have no detrimental effect when present at the second or third position of the loop. Cytosines may either have a stabilizing or destabilizing effect depending on their position. In general, the correlation between the T_m or ΔG° in sodium and potassium was weak. To determine if these sequence effects could be generalized to different quadruplexes, specific loops were tested in different sequence contexts. Analysis of 26 extra sequences confirmed the general destabilizing effect of adenine as the first base of the loop(s). Finally, analysis of some of the sequences by microcalorimetry (DSC) confirmed the differences found between the sequence motifs.     

Mix and measure fluorescence screening for selective quadruplex binders

The human genome contains thousands of regions, including that of the telomere, that have the potential to form quadruplex structures. Many of these regions are potential targets for therapeutic intervention. There are many different folding patterns for quadruplex DNAs and the loops exhibit much more variation than do the quartets. The successful targeting of a particular quadruplex structure requires distinguishing that structure from all of the other quadruplex structures that may be present. A mix and measure fluorescent screening method has been developed, that utilizes multiple reporter molecules that bind to different features of quadruplex DNA. The reporter molecules are used in combination with DNAs that have a variety of quadruplex structures. The screening is based on observing the increase or decrease in the fluorescence of the reporter molecules. The selectivity of a set of test molecules has been determined by this approach.     

Conformational analysis and clustering of short and medium size loops connecting regular secondary structures: a database for modeling and prediction.

Loops are regions of nonrepetitive conformation connecting regular secondary structures. We identified 2,024 loops of one to eight residues in length, with acceptable main-chain bond lengths and peptide bond angles, from a database of 223 protein and protein-domain structures. Each loop is characterized by its sequence, main-chain conformation, and relative disposition of its bounding secondary structures as described by the separation between the tips of their axes and the angle between them. Loops, grouped according to their length and type of their bounding secondary structures, were superposed and clustered into 161 conformational classes, corresponding to 63% of all loops. Of these, 109 (51% of the loops) were populated by at least four nonhomologous loops or four loops sharing a low sequence identity. Another 52 classes, including 12% of the loops, were populated by at least three loops of low sequence similarity from three or fewer nonhomologous groups. Loop class suprafamilies resulting from variations in the termini of secondary structures are discussed in this article. Most previously described loop conformations were found among the classes. New classes included a 2:4 type IV hairpin, a helix-capping loop, and a loop that mediates dinucleotide-binding. The relative disposition of bounding secondary structures varies among loop classes, with some classes such as beta-hairpins being very restrictive. For each class, sequence preferences as key residues were identified; those most frequently at these conserved positions than in proteins were Gly, Asp, Pro, Phe, and Cys. Most of these residues are involved in stabilizing loop conformation, often through a positive phi conformation or secondary structure capping. Identification of helix-capping residues and beta-breakers among the highly conserved positions supported our decision to group loops according to their bounding secondary structures. Several of the identified loop classes were associated with specific functions, and all of the member loops had the same function; key residues were conserved for this purpose, as is the case for the parvalbumin-like calcium-binding loops. A significant number, but not all, of the member loops of other loop classes had the same function, as is the case for the helix-turn-helix DNA-binding loops. This article provides a systematic and coherent conformational classification of loops, covering a broad range of lengths and all four combinations of bounding secondary structure types, and supplies a useful basis for modelling of loop conformations where the bounding secondary structures are known or reliably predicted.     

Sequence effects in single-base loops for quadruplexes

Intramolecular G-quadruplexes formed by a single DNA strand have attracted much interest due to the possibility that they may form in telomeres, oncogene promoter sequences and other biologically relevant regions of the genome. Therefore, it is important to understand the rules that govern the formation of these intramolecular structures and to determine their stabilities. We compared here 27 different sequences containing four tracts of three guanines with a medium (3) or relatively long (6-9 bases) central loop and two loops composed of a single nucleotide H (A, T or C) corresponding to the GGGHGGGN3-9GGGHGGG motif. These sequences are similar to sequence motifs that can be found in repeated and promoter sequences. Several conclusions were reached: (i) all sequences are prone to form very stable quadruplexes in potassium (Tm between 55 degrees C and 83 degrees C); (ii) these quadruplexes also form in sodium but with a strongly decreased Tm, with a 21 to 36 degrees C difference in melting temperature between Na+ and K+; (iii) a long (9 bases) central loop had a minimal deleterious impact on the stability of the quadruplex; (iv) pyrimidines are preferred over adenine in both single-base loops; (v) the folding topology is relatively robust in potassium: the CD spectra of all oligonucleotides matched the one of all-parallel stranded reference quadruplexes; (vi) conversely, in sodium the folding is diverse and sequence-dependent, as judged from CD and electrophoresis results.     

Synchrotron radiation circular dichroism of various G‐quadruplex structures

Here we report synchrotron radiation circular dichroism spectra of various G‐quadruplexes from 179 to 350 nm, and a number of bands in the vacuum ultraviolet (VUV) are reported for the first time. For a tetramolecular parallel structure, the strongest band in the spectrum is a negative band in the VUV at 182 nm; for a bimolecular antiparallel structure with diagonal loops, a new strong positive band is found at 190 nm; for a bimolecular parallel structure with edgewise loops, a strong positive band at 189 nm is observed; and for a self‐folded chair‐type structure, the strongest band in the spectrum is a positive band at 187 nm. For the tetramolecular parallel structure, the CD signals at all wavelengths are dominated by contributions from quartets of G bases, and the signal strength is approximately proportional to the number of quartets. Our experiments on well‐characterized G‐quadruplex structures lead us to question past attributions of CD signals to helix handedness and G quartet polarity. Although differences can be observed in the VUV region for the various quadruplex types, there do not appear to be clear‐cut spectral features that can be used to identify specific topological features. It is suggested that this is because a dominant positive band in the VUV seen near 190 nm in all quadruplex structures is due to intrastrand guanine–guanine base stacking. However, our spectra can serve as reference spectra for the G‐quadruplex structures investigated and, not least, to benchmark theoretical calculations and empirical models. © 2009 Wiley Periodicals, Inc. Biopolymers 93: 429–433, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

Flexibility and structural conservation in a c-KIT G-quadruplex

A quadruplex sequence from the promoter region of the c-KIT gene forms a stable quadruplex, as characterized by crystallographic and NMR methods. Two new crystal structures are reported here, together with molecular dynamics simulation studies on these quadruplex crystal structures and an NMR structure. The new crystal structures, each in a distinct space group and lattice packing arrangement, together with the existing structures, demonstrate that the c-KIT quadruplex fold does not change with differing environments, suggesting that quadruplex topological dynamism is not a general phenomenon. The single and dinucleotide loops in these structures show a high degree of conformational flexibility within the three crystal forms and the NMR ensemble, with no evidence of clustering to particular conformers. This is in accord with the findings of high loop flexibility from the molecular dynamics studies. It is suggested that intramolecular quadruplexes can be grouped into two broad classes (i) those with at least one single-nucleotide loop, often showing singular topologies even though loops are highly flexible, and (ii) with all loops comprising at least two nucleotides, leading to topological dynamism. The loops can have more stable and less dynamic base-stacked secondary structures.     

Intramolecular DNA quadruplexes with different arrangements of short and long loops

We have examined the folding, stability and kinetics of intramolecular quadruplexes formed by DNA sequences containing four G₃ tracts separated by either single T or T₄ loops. All these sequences fold to form intramolecular quadruplexes and 1D-NMR spectra suggest that they each adopt unique structures (with the exception of the sequence with all three loops containing T₄, which is polymorphic). The stability increases with the number of single T loops, though the arrangement of different length loops has little effect. In the presence of potassium ions, the oligonucleotides that contain at least one single T loop exhibit similar CD spectra, which are indicative of a parallel topology. In contrast, when all three loops are substituted with T₄ the CD spectrum is typical of an antiparallel arrangement. In the presence of sodium ions, the sequences with two and three single T loops also adopt a parallel folded structure. Kinetic studies on the complexes with one or two T₄ loops in the presence of potassium ions reveal that sequences with longer loops display slower folding rates.     

Synthesis and characterization of monomolecular DNA G-quadruplexes formed by tetra-end-linked oligonucleotides

Guanine-rich DNA sequences are widely dispersed in the eukaryotic genome and are abundant in regions with relevant biological significance. They can form quadruplex structures stabilized by guanine quartets. These structures differ for number and strand polarity, loop composition, and conformation. We report here the syntheses and the structural studies of a set of interconnected d(TG(4)T) fragments which are tethered, with different orientations, to a tetra-end-linker in an attempt to force the formation of specific four-stranded DNA quadruplex structures. Two synthetic strategies have been used to obtain oligodeoxyribonucleotide (ODN) strands linked with their 3'- or 5'-ends to each of the four arms of the linker. The first approach allowed the synthesis of tetra-end-linked ODN (TEL-ODN) containing the four ODN strands with a parallel orientation, while the latter synthetic pathway led to the synthesis of TEL-ODNs each containing antiparallel ODN pairs. The influence of the linker at 3'- or 5'-ODN, on the quadruplex typology and stability, in the presence of sodium or potassium ions, has been investigated by circular dichroism (CD), CD thermal denaturation, (1)H NMR experiments at variable temperature, and molecular modeling. All synthesized TEL-ODNs formed parallel G-quadruplex structures. Particularly, the TEL-ODN containing all parallel ODN tracts formed very stable parallel G-quadruplex complexes, whereas the TEL-ODNs containing antiparallel ODN pairs led to relatively less stable parallel G-quadruplexes. The molecular modeling data suggested that the above antiparallel TEL-ODNs can adopt parallel G-quadruplex structures thanks to a considerable folding of the tetra-end-linker around the whole quadruplex scaffold.