Synthesis and characterization of DNA quadruplexes containing T-tetrads formed by bunch-oligonucleotides

The solid phase syntheses of the bunch oligonucleotides and based on the sequences of the natural oligodeoxynucleotides (ODNs) d(TG2TG2C) and d(CG2TG2T), respectively, attached to a non-nucleotidic tetrabranched linker, are reported. Bunch-ODNs and were shown to form more stable monomolecular parallel G-quadruplexes and when compared with their tetramolecular counterparts [d(TG2TG2C)]4 and [d(CG2TG2T)]4, respectively. The structure and stability of all the synthesized complexes have been investigated by circular dichroism (CD), CD thermal denaturation experiments, and 1H-NMR (nuclear magnetic resonance) experiments at variable temperatures. Particularly, the spectroscopic data confirmed that 1 adopts a T-tetrad containing parallel-stranded quadruplex structure as in the tetramolecular complex.     

Effect of gamma-hydroxypropano deoxyguanosine, the major acrolein-derived adduct, on monomolecular quadruplex structure of telomeric repeat d(TTAGGG)(4)

The three oligodeoxyribonucleotides (ODNs) a-c, having the telomeric repeat d(TTAGGG)(4) sequence and incorporating gamma-hydroxypropano deoxyguanosine at different positions, were synthesized. Gel electrophoresis and CD analyses indicated that the ODNs assume monomolecular quadruplex structures in Na+ and in K+ buffers. The T(m) values, obtained by CD melting experiments, showed that the presence of the acrolein-dG adduct into the ODN b decreases the thermal stability of the monomolecular quadruplex structure in Na+ solution, whereas for a and c no significant effect could be detected in the same experimental conditions. On the contrary, all ODNs a-d show the same behaviour in K+ buffer. These findings are briefly discussed.     

Characterization of an unusual folding pattern in a catalytically active guanine quadruplex structure

In the presence of certain metal ions, DNA and RNA can form guanine quadruplex structures, which have been proposed to play a functional role in a variety of biological processes. An 18-nucleotide DNA oligomer, PS2.M, d(GTG3TAG3CG3T2G2), was previously reported to bind hemin and the resulting complex exhibited peroxidase activity. It was proposed that PS2.M folds unimolecularly into an antiparallel quadruplex with unusual, single-base loops and terminal guanines positioned in adjacent quartets. Here we describe structural and stability properties of PS2.M alone in different buffers and metal ions, using gel electrophoresis, circular dichroism (CD), ultraviolet (UV)-visible spectroscopies, and one-dimensional 1H nuclear magnetic resonance (NMR). Native gel behavior of PS2.M in the presence of either Na+ or Pb2+ suggests the formation of unimolecular structures but, in the presence of K+, both unimolecular and multistranded structures are observed. In the presence of Pb2+ ions, PS2.M forms a unimolecular quadruplex containing three guanine quartets. CD titrations reveal that binding of Pb2+ ions to PS2.M is stoichiometric, and a single lead cation suffices to fully fold PS2.M. The PS2.M-Na+ system also forms a similar unimolecular quadruplex. In the presence of K+, the PS2.M-K+ system forms mixed species. With increasing time and PS2.M concentration, the contribution of unimolecular species decreases while that of multimolecular species increases, and this behavior is independent of buffer media. These results suggest that the catalytically active form, studied in the presence of K+, may be a parallel, multistranded quadruplex rather than an antiparallel, unimolecular quadruplex.     

Cation-dependent transition between the quadruplex and Watson-Crick hairpin forms of d(CGCG3GCG).

The DNA oligonucleotide d(CGCG3GCG) can form either a Watson-Crick (WC) hairpin or a parallel-stranded quadruplex structure containing six G-quartet base pair assemblies. The exchange between these forms and single strands can be monitored using circular dichroism (CD). NMR results verified the assignment of specific CD bands to quadruplex and hairpin species, respectively. Cations stabilize the quadruplex in the order K+ greater than Ca2+ greater than Na+ greater than Mg2+ greater than Li+ and K+ greater than Rb+ greater than Cs+, indicating that K+ has an optimum ionic radius for complex formation and that ionic charge affects the extent of ion-induced stabilization. The quadruplex is stable in the presence of 40 mM K+ at micromolar DNA concentration and can be kinetically trapped as a metastable form when prepared at millimolar DNA concentration and then diluted into buffer containing 40 mM Na+. The concentration of K+ required to reverse the equilibrium from the hairpin to the quadruplex decreases sharply with increased DNA concentration. The quadruplex has an unusual pKa of ca. 6.8, indicating that C.C+ base pairs are probably forming. This system provides insights into some of the detailed structural characteristics of a ["G4-DNA".ion] complex and an experimental model for the recently proposed "sodium-potassium conformational switch" [Sen, D., & Gilbert, W. (1988) Nature 334, 364-366; Sen, D., & Gilbert, W. (1990) Nature 344, 410-414]. These results may help to explain the lack of cytidine residues in G-rich telomeric DNAs and suggest that methylation of GC-rich duplex DNAs in "GpC islands" may induce quadruplex formation within heterochromatin domains, resulting in reversible chromosomal condensation.     

Divalent transition metal cations counteract potassium-induced quadruplex assembly of oligo(dG) sequences.

Nucleic acids containing tracts of contiguous guanines tend to self-associate into four-stranded (quadruplex) structures, based on reciprocal non-Watson-Crick (G*G*G*G) hydrogen bonds. The quadruplex structure is induced/stabilized by monovalent cations, particularly potassium. Using circular dichroism, we have determined that the induction/stabilization of quadruplex structure by K+is specifically counteracted by low concentrations of Mn2+(4-10 mM), Co2+(0.3-2 mM) or Ni2+(0.3-0.8 mM). G-Tract-containing single strands are also capable of sequence-specific non-Watson-Crick interaction with d(G. C)-tract-containing (target) sequences within double-stranded DNA. The assembly of these G*G.C-based triple helical structures is supported by magnesium, but is potently inhibited by potassium due to sequestration of the G-tract single strand into quadruplex structure. We have used DNase I protection assays to demonstrate that competition between quadruplex self-association and triplex assembly is altered in the presence of Mn2+, Co2+or Ni2+. By specifically counteracting the induction/stabilization of quadruplex structure by potassium, these divalent transition metal cations allow triplex formation in the presence of K+and shift the position of equilibrium so that a very high proportion of triplex target sites are bound. Thus, variation of the cation environment can differentially promote the assembly of multistranded nucleic acid structural alternatives.     

A comparative study on the interaction of acridine and synthetic bis-acridine with G-quadruplex structure

DNA from the telomeres contains a stretch of simple tandemly repeated sequences in which clusters of G residues alternate with clusters of T/A sequences along one DNA strand. Model telomeric G-clusters form four-stranded structures in presence of Na(I), K(I) and NH(4)(I) ions. Electrophoretic and spectroscopic studies were made with the telomeric related sequences d(T6G16) or d(G4T2G4T2G4T2G4). It was noticed earlier that G-quadruplex may either be inter-molecular, or intra-molecular, or a mixture of both. CD spectral characteristics of various G-quadruplex DNA suggests that the CD maximum at 293 nm corresponds to that of an intra-molecular G-quadruplex structure or hairpin dimers. Fluorescence titration studies also show that acridine and the bis-acridine are interacting with G-quadruplex DNA and destabilize the K(I)-quadruplex structure more efficiently than the quadruplex formed by NH(4)(I) ion. Among the two drugs studied, acridine is more capable of breaking the G-quadruplex structure than bis-acridine. This result is further confirmed by the CD experiments.     

Heat capacity changes associated with guanine quadruplex formation: an isothermal titration calorimetry study

This study addresses the temperature dependence of the enthalpy of formation for several unimolecular quadruplexes in the presence of excess monovalent salt. We examined a series of biologically significant guanine-rich DNA sequences: thrombin binding aptamer (TBA) (d(G(2)T(2)G(2)TGTG(2)T(2)G(2)), PS2.M, a catalytically active aptamer (d(GTG(3)TAG(3)CG(3)T(2)G(2))), and the human telomere repeat (HT) (d(AG(3)(T(2)AG(3))(3))). Using CD spectra and UV melting, we confirmed the presence of quadruplex structures and established the temperature range in which quadruplex conformation is stable. We then performed ITC experiments, adding DNA to a solution containing excess NaCl or KCl. In this approach, only several additions are made, and only the enthalpy of quadruplex formation is measured. This measurement was repeated at different temperatures to determine the temperature dependence of the enthalpy change accompanying quadruplex formation. To control for the effect of nonspecific salt interactions during DNA folding, we repeated the experiment by replacing the quadruplex-forming sequences with a similar but nonfolding sequence. Dilution enthalpies were also subtracted to obtain the final enthalpy value involving only the quadruplex folding process. For all sequences studied, quadruplex formation was exothermic but with an increasing magnitude with increasing temperature. These results are discussed in terms of the change in heat capacity associated with quadruplex formation.     

Luminescence study of G-quadruplex formation in the presence of Tb3+ ion

The interactions of Tb3+ with the quadruplex-forming oligonucleotide bearing human telomeric repeat sequence d(G(3)T(2)AG(3)T(2)AG(3)T(2)AG(3)), (htel21), have been studied using luminescence spectroscopy and circular dichroism (CD). Enhanced luminescence of Tb3+, resulting from energy transfer from guanines, indicated encapsulation of Tb3+ ion in the central cavity of quadruplex core. The ability of lanthanide ions (Eu3+ and Tb3+) to mediate formation of quadruplex structure has been further evidenced by the fluorescence energy transfer measurements with the use of oligonucleotide probe labeled with fluorescein and rhodamine FRET partners, FAM-htel21-TAMRA. The CD spectra revealed that Tb3+/htel21 quadruplex possesses antiparallel strand orientation, similarly as sodium quadruplex. Tb3+ binding equilibria have been investigated in the absence and the presence of competing metal cations. At low Tb3+ concentration (8 microM) Tb3+/htel21 quadruplex stability is very high (5 x 10(6) M(-1)) and stoichiometry of 5-7 Tb3+ ions per one quadruplex molecule is observed. Luminescence and CD titration experiments suggested that the cavity of quadruplex accommodates two Tb3+ ions and the remaining Tb3+ ions bind probably to TTA loops of quadruplex. Higher concentration of Tb3+ (above 10 microM) results in the excessive binding of Tb3+ ions that finally destabilizes quadruplex, which undergoes transformation into differently organized assemblies. Such assemblies (probably possessing multiple positive charge) exhibit kinetic stability, which is manifested by a very slow kinetics of displacement of Tb3+ ion by competing cations (Li+, Na+, K+).     

Sr2+ facilitates intermolecular G-quadruplex formation of telomeric sequences.

Electrophoretic and spectroscopic studies were made with the telomere-related sequences d(G4T2G4T2G4T2G4) (T2) and d(G4T4G4T4G4T4G4) (T4) in the presence of Na+, K+, and Sr2+. Electrophoretic evidence indicates that these two oligomers exist in multiconformational states in solutions. A band identified as that of intermolecular (tetramolecular) G-quadruplex is apparent in both T2 and T4, whereas a band identified as intramolecular (monomeric) G-quartet is only evident in T4. The remaining electrophoretic bands that exhibit mobilities intermediate of these two extremes are identified as those of hairpin-related duplexes and tetraplexes. In the presence of millimolar concentrations of Sr2+ and subsequent thermal treatment, the intensity corresponding to the band attributable to the intermolecular G-quadruplex is dramatically enhanced in T2 while those of the hairpin-related bands of intermediate mobility are greatly reduced. Similar but less dramatic enhancement of the intermolecular quadruplex band is also observed in T4. Although these effects can also be induced by K+, orders of magnitude higher concentrations are needed. The intensity of the intramolecular G-quartet band, apparent in T4 but not in T2, appears to be relatively insensitive to the type of cation present in the solution. These results demonstrate that both Sr2+ and K+ facilitate the intermolecular G-tetraplex formation, with the divalent cation being much more effective. Comparison with the corresponding CD spectral characteristics suggests that the electrophoretic intensity enhancement of the intermolecular G-quadruplex band is correlated to the intensity enhancement of of the positive CD maximum at 265 nm.(ABSTRACT TRUNCATED AT 250 WORDS)     

The contribution of thymine-thymine interactions to the stability of folded dimeric quadruplexes.

The loop of four thymines in the sodium form of the dimeric folded quadruplex [d(G3T4G3)]2 assumes a well-defined structure in which hydrogen bonding between the thymine bases appears to contribute to the stability and final conformation of the quadruplex. We have investigated the importance of the loop interactions by systematically replacing each thymine in the loop with a cytosine. The quadruplexes formed by d(G3CT3G3), d(G3TCT2G3), d(G3T2CTG3) and d(G3T3CG3) in the presence of 150 mM Na+ were studied by gel mobility, circular dichroism and 1H NMR spectroscopy. The major species formed by d(G3CT3G3), d(G3TCT2G3) and d(G3T3CG3) at 1 mM strand concentration at neutral pH is a dimeric folded quadruplex. d(G3T2CTG3) has anomalous behaviour and associates into a greater percentage of linear four-stranded quadruplex than the other three oligonucleotides at neutral pH and at the same concentration. The linear four-stranded quadruplex has a greater tendency to oligomerize to larger ill-defined structures, as demonstrated by broad 1H NMR resonances. At pH 4, when the cytosine is protonated, there is a greater tendency for each of the oligonucleotides to form some four-stranded linear quadruplex, except for d(G3T2CTG3), which has the reverse tendency. The experimental results are discussed in terms of hydrogen bonding within the thymine loop.     

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.     

Biophysical characterization of the human telomeric (TTAGGG)4 repeat in a potassium solution

Quadruplex structures arise from four coplanar G bases arranged in a Hoogsteen base pairing motif to create a central pore that can coordinate cations. The termini of eukaryotic chromosomes contain structures, known as telomeres, which are capable of forming quadruplex structures. Quadruplexes have been implicated in a variety of disease states, including cancer. The literature seems to agree that the human telomeric repeat containing four stretches of three guanines displays conformational states that are different in the presence of Na+ and K+ and an unknown number of species involved in the quadruplex to single strand transition. Using circular dichroism spectroscopy, differential scanning calorimetry, and singular-value decomposition, the number of species present in the dissociation process is assessed. The results indicate that three species exist in equilibria during the melting process. We present a model for the heat-induced denaturation from the folded to the unfolded state, whereby the hybrid parallel-antiparallel quadruplex undergoes a transition to an unknown intramolecular intermediate followed by a transition to a single strand.     

Stability of intramolecular DNA quadruplexes: comparison with DNA duplexes

We have determined the stability of intramolecular quadruplexes that are formed by a variety of G-rich sequences, using oligonucleotides containing appropriately placed fluorophores and quenchers. The stability of these quadruplexes is compared with that of the DNA duplexes that are formed on addition of complementary C-rich oligonucleotides. We find that the linkers joining the G-tracts are not essential for folding and can be replaced with nonnucleosidic moieties, though their sequence composition profoundly affects quadruplex stability. Although the human telomere repeat sequence d[G(3)(TTAG(3))(3)] folds into a quadruplex structure, this forms a duplex in the presence of the complementary C-rich strand at physiological conditions. The Tetrahymena sequence d[G(4)(T(2)G(4))(3)], the sequence d[G(3)(T(2)G(3))(3)], and sequences related to regions of the c-myc promoter d(G(4)AG(4)T)(2) and d(G(4)AG(3)T)(2) preferentially adopt the quadruplex form in potassium-containing buffers, even in the presence of a 50-fold excess of their complementary C-rich strands, though the duplex predominates in the presence of sodium. The HIV integrase inhibitor d[G(3)(TG(3))(3)] forms an extremely stable quadruplex which is not affected by addition of a 50-fold excess of the complementary C-rich strand in both potassium- and sodium-containing buffers. Replacing the TTA loops of the human telomeric repeat with AAA causes a large decrease in quadruplex stability, though a sequence with AAA in the first loop and TTT in the second and third loops is slightly more stable.     

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)     

Interaction of pyrrolobenzodiazepine (PBD) ligands with parallel intermolecular G-quadruplex complex using spectroscopy and ESI-MS

Studies on ligand interaction with quadruplex DNA, and their role in stabilizing the complex at concentration prevailing under physiological condition, has attained high interest. Electrospray ionization mass spectrometry (ESI-MS) and spectroscopic studies in solution were used to evaluate the interaction of PBD and TMPyP4 ligands, stoichiometry and selectivity to G-quadruplex DNA. Two synthetic ligands from PBD family, namely pyrene-linked pyrrolo[2,1-c][1,4]benzodiazepine hybrid (PBD1), mixed imine-amide pyrrolobenzodiazepine dimer (PBD2) and 5,10,15,20-tetrakis(N-methyl-4-pyridyl)porphyrin (TMPyP4) were studied. G-rich single-stranded oligonucleotide d(5'GGGGTTGGGG3') designated as d(T(2)G(8)), from the telomeric region of Tetrahymena Glaucoma, was considered for the interaction with ligands. ESI-MS and spectroscopic methods viz., circular dichroism (CD), UV-Visible, and fluorescence were employed to investigate the G-quadruplex structures formed by d(T(2)G(8)) sequence and its interaction with PBD and TMPyP4 ligands. From ESI-MS spectra, it is evident that the majority of quadruplexes exist as d(T(2)G(8))(2) and d(T(2)G(8))(4) forms possessing two to ten cations in the centre, thereby stabilizing the complex. CD band of PBD1 and PBD2 showed hypo and hyperchromicity, on interaction with quadruplex DNA, indicating unfolding and stabilization of quadruplex DNA complex, respectively. UV-Visible and fluorescence experiments suggest that PBD1 bind externally where as PBD2 intercalate moderately and bind externally to G-quadruplex DNA. Further, melting experiments using SYBR Green indicate that PBD1 unfolds and PBD2 stabilizes the G-quadruplex complex. ITC experiments using d(T(2)G(8)) quadruplex with PBD ligands reveal that PBD1 and PBD2 prefer external/loop binding and external/intercalative binding to quadruplex DNA, respectively. From experimental results it is clear that the interaction of PBD2 and TMPyP4 impart higher stability to the quadruplex complex.     

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.     

Possibility of an antiparallel (tetramer) quadruplex exhibited by the double repeat of the human telomere

Under physiological concentrations of Na+ and K+, human telomeric DNA can self-associate into G-quadruplexes. On the basis of circular dichroism, gel electrophoresis, gel filtration, and UV-melting experiments, we report here that the double repeat of human telomere (d-TTAGGGTTAGGG; HUM2) forms parallel as well as antiparallel quadruplexes in the presence of K+, whereas Na+ facilitates only the antiparallel form. Here, the gel techniques and CD studies have proved to be complementary in detecting the molecularity and pattern of strand orientation. By correlating the gel and CD experiments, the antiparallel G-quadruplex was identified as a tetrameric species, whereas the parallel G-quadruplex was found to be dimeric. Both structural species were separated through gel filtration, which when run on native polyacrylamide gel electrphoresis (PAGE), confirmed their molecularity. UV-melting profiles also confirm the presence of two biphasic and one monophasic structural species in the presence of K+ and Na+, respectively. Though our observation is consistent with the recent NMR report (Phan, A. T., and Patel, D. J. (2003) J. Am. Chem. Soc. 125, 15021-15027), it seems to differ in terms of the molecularity of the antiparallel quadruplex. A model is proposed for an antiparallel tetrameric quadruplex, showing the possibility of Watson-Crick hydrogen bonds between intervening bases on antiparallel strands. This article expands the known structural motifs of DNA quadruplexes. To the best of our knowledge, four-stranded antiparallel quadruplexes have not been characterized to date. On the basis of the model, we hypothesize a possible mechanism for telomere-telomere association involving their G-overhangs, during certain stages of the cell cycle. The knowledge of peculiar geometries of the G-quadruplexes may also have implications for its specific recognition by ligands.     

Effect of a modified thymine on the structure and stability of [d(TGGGT)]4 quadruplex

Telomeric guanine-rich sequence can adopt quadruplex structures that are important for their biological role in chromosomal stabilisation. G quartets are characterised by the cyclic hydrogen bonding of four guanine bases in a coplanar arrangement and their stability is ion-dependent. In this work we compare the stability of [d(TGGGT)]₄ and [d(T*GGGT)]₄ quadruplexes. The last one contains a modified thymine, where the hydroxyl group substitutes one hydrogen atom of the methyl group of the thymine in the [d(TGGGT)]₄ sequence. We used a combination of spectroscopic, calorimetric and computational techniques to characterise the G-quadruplex formation. NMR and CD spectra of [d(T*GGGT)]₄ were characteristic of parallel-stranded, tetramolecular quadruplex. CD and DSC melting experiments reveal that [d(T*GGGT)]₄ is less stable that unmodified quadruplex. Molecular models suggest possible explanation for the observed behaviour.     

The insertion of two 8-methyl-2'-deoxyguanosine residues in tetramolecular quadruplex structures: trying to orientate the strands

In this article, we report a structural study, based on NMR and CD spectroscopies, and molecular modelling of all possible d(TG(3)T) and d(TG(4)T) analogues containing two 8-methyl-2'-deoxyguanosine residues (M). Particularly, the potential ability of these modified residues to orientate the strands and then to affect the folding topology of tetramolecular quadruplex structures has been investigated. Oligodeoxynucleotides (ODNs) TMMGT (T12) and TMMGGT (F12) form parallel tetramolecular quadruplexes, characterized by an all-syn M-tetrad at the 5'-side stacked to all-anti M- and G-tetrads. ODNs TMGMT (T13) and TMGGMT (F14) form parallel tetramolecular quadruplexes, in which an all-anti G core is sandwiched between two all-syn M-tetrads at the 5'- and the 3'-side. Notably, the quadruplex formed by T13 corresponds to an unprecedented structure in which the syn residues exceed in number the anti ones. Conversely, ODN TGMGMT (F24) adopts a parallel arrangement in which all-anti G-tetrads alternate with all-syn M-tetrads. Most importantly, all data strongly suggest that ODN TMGMGT (F13) forms an unprecedented anti-parallel tetramolecular quadruplex in which G and M residues adopt anti and syn glycosidic conformations, respectively. This article opens up new understandings and perspectives about the intricate relationship between the quadruplex strands orientation and the glycosidic conformation of the residues.