Structure of a parallel-stranded tetramer of the Oxytricha telomeric DNA sequence dT4G4

Interaction of a Cationic Porphyrin and Its Metal Derivatives with G-Quadruplex DNA

G-quadruplex (GQ) structures formed from guanine-rich sequences are found throughout the genome and are overrepresented in the promoter regions of some oncogenes, at the telomeric ends of eukaryotic chromosomes, and at the 5'-untranslated regions of mRNA. Interaction of small molecule ligands with GQ DNA is an area of great research interest to develop novel anticancer therapeutics and GQ sensors. In this paper we examine the interactions of TMPyP4, its isomer TMPyP2 (containing N-methyl-2-pyridyl substituents, N-Me-2Py) as well as two metal derivatives ZnTMPyP4 and CuTMPyP4 with GQs formed by dT₄G₄ and dT₄G₄T in 100 mM K⁺ or Na⁺ conditions. The DNA sequences were chosen to elucidate the effect of the 3'-T on the stabilization effect of porphyrins, binding modes, affinities, and stoichiometries determined via circular dichroism melting studies, UV-vis titrations, continuous variation analysis, and fluorescence studies. Our findings demonstrate that the stabilizing abilities of porphyrins are stronger toward (dT₄G₄)₄ as compared to (dT₄G₄T)₄ (ΔT_m is 4.4 vs -6.4 for TMPyP4; 12.7 vs 5.7 for TMPyP2; 16.4 vs 12.1 for ZnTMPyP4; and 1.9 vs -8.4 °C for CuTMPyP4) suggesting that the 3'G-tetrad presents at least one of the binding sites. The binding affinity was determined to be moderate (K_a ∼ 10⁶-10⁷ μM^-1) with a typical binding stoichiometry of 1:1 or 2:1 porphyrin-to-GQ. In all studies, ZnTMPyP4 emerged as a ligand superior to TMPyP4. Overall, our work contributes to clearer understanding of interactions between porphyrins and GQ DNA.

Structural polymorphism of the four-repeat Oxytricha nova telomeric DNA sequences

G-quadruplexes are four-stranded nucleic acid complexes that exhibit a great deal of polymorphism. Recently a group described the polymorphism exhibited by the four-repeat of the Oxytricha nova telomeric sequences (Lee, J.Y., Yoon, J., Kihm, H.W., Kim, D.S., Biochemistry 2008, 47, 3389-3396). In this study we evaluated the effects of G-tract and loop lengths on this behaviour using circular dichroism (CD) and gel electrophoresis. The largest changes were detected for oligonucleotides with different numbers of consecutive G residues. Furthermore, decreasing the number of residues between the G runs, the loops, from four to three only results in minor alteration in the polymorphism. However, the shortening of the G-tract from four to three guanine residues led to characteristically anti-parallel G-quadruplex CD spectra. Finally, we show that adenine bases in the loop sequences are less likely to form G-quadruplexes in the presence of Na(+) cations than those comprised of thymine residues. The results presented here are an addition to the modest information available for predicting the type of G-quadruplex to be formed from G-rich sequences in aqueous solutions containing sodium or potassium ions.

End-stacking of copper cationic porphyrins on parallel-stranded guanine quadruplexes

Nucleic acids that contain multiple sequential guanines assemble into guanine quadruplexes (G-quadruplexes). Drugs that induce or stabilize G-quadruplexes are of interest because of their potential use as therapeutics. Previously, we reported on the interaction of the Cu(2+) derivative of 5,10,15,20-tetrakis(1-methyl-4-pyridyl)-21H,23H-porphine (CuTMpyP4), with the parallel-stranded G-quadruplexes formed by d(T(4)G( n )T(4)) (n = 4 or 8) (Keating and Szalai in Biochemistry 43:15891-15900, 2004). Here we present further characterization of this system using a series of guanine-rich oligonucleotides: d(T(4)G( n )T(4)) (n = 5-10). Absorption titrations of CuTMpyP4 with all d(T(4)G( n )G(4)) quadruplexes produce approximately the same bathochromicity (8.3 +/- 2 nm) and hypochromicity (46.2-48.6%) of the porphyrin Soret band. Induced emission spectra of CuTMpyP4 with d(T(4)G( n )T(4))(4) quadruplexes indicate that the porphyrin is protected from solvent. Electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry revealed a maximum porphyrin to quadruplex stoichiometry of 2:1 for the shortest (n = 4) and longest (n = 10) quadruplexes. Electron paramagnetic resonance spectroscopy shows that bound CuTMpyP4 occupies magnetically noninteracting sites on the quadruplexes. Consistent with our previous model for d(T(4)G(4)T(4)), we propose that two CuTMpyP4 molecules are externally stacked at each end of the run of guanines in all d(T(4)G( n )T(4)) (n = 4-10) quadruplexes.

Kinetics of tetramolecular quadruplexes

The melting of tetramolecular DNA or RNA quadruplexes is kinetically irreversible. However, rather than being a hindrance, this kinetic inertia allows us to study association and dissociation processes independently. From a kinetic point of view, the association reaction is fourth order in monomer and the dissociation first order in quadruplex. The association rate constant k (on), expressed in M(-3) x s(-1) decreases with increasing temperature, reflecting a negative activation energy (E (on)) for the sequences presented here. Association is favored by an increase in monocation concentration. The first-order dissociation process is temperature dependent, with a very positive activation energy E (off), but nearly ionic strength independent. General rules may be drawn up for various DNA and RNA sequence motifs, involving 3-6 consecutive guanines and 0-5 protruding bases. RNA quadruplexes are more stable than their DNA counterparts as a result of both faster association and slower dissociation. In most cases, no dissociation is found for G-tracts of 5 guanines or more in sodium, 4 guanines or more in potassium. The data collected here allow us to predict the amount of time required for 50% (or 90%) quadruplex formation as a function of strand sequence and concentration, temperature and ionic strength.

Clustering of nucleosides in the presence of alkali metals: Biologically relevant quartets of guanosine, deoxyguanosine and uridine observed by ESI-MS/MS

Electrospray ionization (ESI) mass spectra of nucleosides, recorded in the presence of alkali metals, display alkali metal ion-bound quartets and other clusters that may have implications for understanding non-covalent interactions in DNA and RNA. The tetramers of guanosine and deoxyguanosine and also their metaclusters (clusters of clusters), cationized by alkali metals, were observed as unusually abundant magic number clusters. The observation of these species in the gas phase parallels previous condensed-phase studies, which show that guanine derivatives can form quartets and metaclusters of quartets in solution in the presence of metal cations. This parallel behavior and also internal evidence suggest that bonding in the guanosine tetramers involves the bases rather than the sugar units. The nucleobases thymine and uracil are known to form magic number pentameric adducts with K+, Cs+ and NH4+ in the gas phase. In sharp contrast, we now show that the nucleosides uridine and deoxythymidine do not form the pentameric clusters characteristic of the corresponding bases. More subtle effects of the sugars are evident in the fact that adenosine and cytidine form numerous higher order clusters with alkali metals, whereas deoxyadenosine and deoxycytidine show no clustering. It is suggested that hydrogen bonding between the bases in the tetramers of dG and rG are the dominant interactions in the clusters, hence changing the ribose group to deoxyribose (and vice versa) generally has little effect. However, the additional hydroxyl group of RNA nucleosides enhances the non-selective formation of higher-order aggregates for adenosine and cytidine and results in the lack of highly stable magic number clusters. Some clusters are the result of aggregation in the course of ionization (ESI) whereas others appear to be intrinsic to the solution being examined.

Thermodynamic and kinetic characterization of the dissociation and assembly of quadruplex nucleic acids

The dissociation and assembly of quadruplex DNA structures (and a few quadruplex RNAs) have been characterized at several levels of rigor, ranging from gross descriptions of factors that govern each process, to semiquantitative comparisons of the relative abilities of these factors to induce stabilization or destabilization, to quantitative studies of binding energies (thermodynamics), transformational rates (kinetics), and analysis of their transition-state energies and mechanisms. This survey classifies these factors, describes the trends and focuses on their interdependencies. Quadruplex assembly is induced most efficiently by added K(+) and elevating the strand concentration; however, Na(+), NH(4)(+), Sr(2+), and Pb(2+) are also very effective stabilizers. Quadruplex dissociation is typically accomplished by thermal denaturation, "melting"; however, when the quadruplex and monovalent cation concentrations are low enough, or the temperature is sufficiently high, several divalent cations, e.g., Ca(2+), Co(2+), Mn(2+), Zn(2+), Ni(2+) and Mg(2+) can induce dissociation. Stabilization also depends on the type of structure adopted by the strand (or strands) in question. Variants include intramolecular, two- and four-stranded quadruplexes. Other important variables include strand sequence, the size of intervening loops and pH, especially when cytosines are present, base methylation, and the replacement of backbone phosphates with phosphorothioates. Competitive equilibria can also modulate the formation of quadruplex DNAs. For example, reactions leading to Watson-Crick (WC) duplex and hairpin DNAs, triplex DNAs, and even other types of quadruplexes can compete with quadruplex association reactions for strands. Others include nonprotein catalysts, small molecules such as aromatic dyes, metalloporphyrins, and carbohydrates (osmolytes). Other nucleic acid strands have been found to drive quadruplex formation. To help reinforce the implications of each piece of information, each functional conclusion drawn from each cited piece of thermodynamic or kinetic data has been summarized briefly in a standardized table entry.

Quadruplex structures in nucleic acids

DNA oligonucleotides that have repetitive tracts of guanine bases can form G-quadruplex structures that display an amazing polymorphism. Structures of several new G-quadruplexes have been solved recently that greatly expand the known structural motifs observed in nucleic acid quadruplexes. Base triads, base hexads, and quartets that contain cytosine have recently been identified stacked over the familiar G-quartets. The current status of the diverse array of structural features in quadruplexes is described and used to provide insight into the polymorphism and folding pathways. This review also summarizes recent progress in the techniques used to probe the structures of G-quadruplexes and discusses the role of ion binding in quadruplex formation. Several of the quadruplex structures featured in this review can be accessed in the online version of this review as CHIME representations.

Metal-modified nucleobase sextet: joining four linear metal fragments (trans-a2PtII) and six model nucleobases to an exceedingly stable entity

Crosslinking of three different model nucleobases (9-ethyladenine, 9-EtA; 9-ethylguanine, 9-EtGH; 1-methyluracil, 1-MeU) by two linear trans-aPtII (a = NH3 or CH3NH2) entities leads to a flat metal-modified base triplet, trans,trans-[(NH3)2Pt(1-MeU-N3)(mu-9-EtA-N7,N1)Pt(CH3NH2)2(9-EtGH-N7)]3+ (4b). Upon hemideprotonation of the 9-ethylguanine base at the N1 position. 4b spontaneously dimerizes to the metalated nucleobase sextet 5, [(4b)(triple bond)(4b-H)]5+. In this dimeric structure a neutral and an anionic guanine ligand, which are complementary to each other, are joined through three H bonds and additionally by two H bonds between guanine and uracil nucleobases. Four additional interbase H bonds maintain the approximate coplanarity of all six bases. The two base triplets form an exceedingly stable entity (KD = 500 +/- 150 M(-1) in DMSO), which is unprecedented in nucleobase chemistry. The precursor of 4b and several related complexes are described and their structures and solution properties are reported.

A nanosecond molecular dynamics study of antiparallel d(G)7 quadruplex structures: effect of the coordinated cations

Nanosecond scale molecular dynamics simulations have been performed on antiparallel Greek key type d(G7) quadruplex structures with different coordinated ions, namely Na+ and K+ ion, water and Na+ counter ions, using the AMBER force field and Particle Mesh Ewald technique for electrostatic interactions. Antiparallel structures are stable during the simulation, with root mean square deviation values of approximately 1.5 A from the initial structures. Hydrogen bonding patterns within the G-tetrads depend on the nature of the coordinated ion, with the G-tetrad undergoing local structural variation to accommodate different cations. However, alternating syn-anti arrangement of bases along a chain as well as in a quartet is maintained through out the MD simulation. Coordinated Na+ ions, within the quadruplex cavity are quite mobile within the central channel and can even enter or exit from the quadruplex core, whereas coordinated K+ ions are quite immobile. MD studies at 400K indicate that K+ ion cannot come out from the quadruplex core without breaking the terminal G-tetrads. Smaller grooves in antiparallel structures are better binding sites for hydrated counter ions, while a string of hydrogen bonded water molecules are observed within both the small and large grooves. The hydration free energy for the K+ ion coordinated structure is more favourable than that for the Na+ ion coordinated antiparallel quadruplex structure.

Macrochelation, cyclometallation and G-quartet formation: N3- and C8-bound PdII complexes of adenine and guanine

The reactions of Pd(II) ions with a series of chelate-tethered derivatives of adenine and guanine have been studied and reveal a difference in the reactivity of the purine bases. Reactions of [PdCl2(MeCN)2] and A-alkyl-enH x Cl (alkyl = propyl or ethyl, A adenine, en = ethylenediamine) yield the monocationic species [PdCl(A-N3-Et-en)]+ (1) and [PdCl(A-N3-Pr-en)]+ (2). Both involve co-ordination at the minor groove site N3 of the nucleobase as confirmed by single-crystal X-ray analysis. Reactions with the analogous G-alkyl-enH x Cl derivatives (G=guanine, alkyl = ethyl or propyl) were more complex with a mixture of species being observed. For G-Et-en HCI a product was isolated which was identified as [PdCl(G-C8-Et-en)]+ (3). This compound contains a biomolecular metal-carbon bond involving C8 of the purine base. Crystallography of a product obtained from reaction of G-Pr-enH x Cl and [Pd(MeCN)4][NO3]2 reveals an octacationic tetrameric complex (4), in which each ligand acts to bridge two metal ions through a combination of a tridentate binding mode involving the diamine and N3 and monodentate coordination at N7.

Cation-dependent conformational switches in d-TGGCGGC containing two triplet repeats of Fragile X Syndrome: NMR observations

Higher ordered structures formed by different DNA sequences have been widely investigated in recent years because of their implications in a variety of biological functions. Among these, G-quadruplexes have exhibited a great variety depending on the exact sequence, the lengths of the G-stretches, interception by other nucleotides, and environmental conditions such as pH, temperature, salt type, and its concentration. We report here interesting conformational switches observed by NMR in the sequence d-TGGCGGC containing two GGC triplet repeats related to the disease Fragile X-Syndrome. At neutral pH, the solution structure is a parallel-stranded quadruplex in presence of K(+) ions. Lowering the pH does not cause a major change in the structure; however, the chemical shift patterns of the C4 and G3 base protons suggest protonation of the C-tetrad in the center of the quadruplex. In contrast, the sequence forms an antiparallel duplex in Na(+) containing solutions. As the pH of the Na(+) sample is lowered, an equilibrium mixture of a duplex and a quadruplex appears, and at pH 2.2, the molecule exists entirely as a quadruplex. These results would be of significance from the point of view of recognition and regulation by different helicase enzymes, which have been found to discriminate between different types of quadruplex structures.

Effect of coordinated ions on structure and flexiblity of parallel G-quandruplexes: a molecular dynamics study

Single tract guanine residues can associate to form stable parallel quadruplex structures in the presence of certain cations. Nanosecond scale molecular dynamics simulations have been performed on fully solvated fibre model of parallel d(G7) quadruplex structures with Na+ or K+ ions coordinated in the cavity formed by the 06 atoms of the guanine bases. The AMBER 4.1 force field and Particle Mesh Ewald technique for electrostatic interactions have been used in all simulations. These quadruplex structures are stable during the simulation, with the middle four base tetrads showing root mean square deviation values between 0.5 to 0.8 A from the initial structure as well the high resolution crystal structure. Even in the absence of any coordinated ion in the initial structure, the G-quadruplex structure remains intact throughout the simulation. During the 1.1 ns MD simulation, one Na+ counter ion from the solvent as well as several water molecules enter the central cavity to occupy the empty coordination sites within the parallel quadruplex and help stabilize the structure. Hydrogen bonding pattern depends on the nature of the coordinated ion, with the G-tetrad undergoing local structural variation to accommodate cations of different sizes. In the absence of any coordinated ion, due to strong mutual repulsion, 06 atoms within G-tetrad are forced farther apart from each other, which leads to a considerably different hydrogen bonding scheme within the G-tetrads and very favourable interaction energy between the guanine bases constituting a G-tetrad. However, a coordinated ion between G-tetrads provides extra stacking energy for the G-tetrads and makes the quadruplex structure more rigid. Na+ ions, within the quadruplex cavity, are more mobile than coordinated K+ ions. A number of hydrogen bonded water molecules are observed within the grooves of all quadruplex structures.

Formation and structural determinants of multi-stranded guanine-rich DNA complexes

We have investigated the complexes formed by oligonucleotides with the general sequence d(T15,Gn), where n = 4-15. Two distinct classes of structures are formed, namely, the four-stranded tetraplex and frayed wires. Frayed wires differ from four-stranded tetraplexes in both strand association stoichiometry and the ability of dimethyl sulfate to methylate the N7 position of guanine. Thus, it appears that these two guanine-rich multistranded assemblies are stabilised by different guanine-guanine interactions. The number of contiguous guanine residues determines which of the complexes is favoured. Based on the stoichiometry of the associated species and the accessibility of the N7 position of guanine to methylation we have found that oligonucleotides with smaller number of contiguous guanines; n = 5-8, form primarily four-stranded tetraplex. Oligonucleotides with larger numbers of contiguous guanines adapt primarily the frayed wire structure. The stability of the complexes formed by this series of oligonucleotides is determined by the number and arrangement of the guanines within the sequences. We propose that the formation of the two types of complex proceed by a parallel reaction pathways that may share common intermediates.

A dimeric DNA interface stabilized by stacked A.(G.G.G.G).A hexads and coordinated monovalent cations

We report on the identification of an A.(G.G.G.G).A hexad pairing alignment which involves recognition of the exposed minor groove of opposing guanines within a G.G.G.G tetrad through sheared G.A mismatch formation. This unexpected hexad pairing alignment was identified for the d(G-G-A-G-G-A-G) sequence in 150 mM Na(+) (or K(+)) cation solution where four symmetry-related strands align into a novel dimeric motif. Each symmetric half of the dimeric "hexad" motif is composed of two strands and contains a stacked array of an A.(G.G.G.G).A hexad, a G.G.G.G tetrad, and an A.A mismatch. Each strand in the hexad motif contains two successive turns, that together define an S-shaped double chain reversal fold, which connects the two G-G steps aligned parallel to each other along adjacent edges of the quadruplex. Our studies also establish a novel structural transition for the d(G-G-A-G-G-A-N) sequence, N=T and G, from an "arrowhead" motif stabilized through cross-strand stacking and mismatch formation in 10 mM Na(+) solution (reported previously), to a dimeric hexad motif stabilized by extensive inter-subunit stacking of symmetry-related A.(G.G.G.G).A hexads in 150 mM Na(+) solution. Potential monovalent cation binding sites within the arrowhead and hexad motifs have been probed by a combination of Brownian dynamics and unconstrained molecular dynamics calculations. We could not identify stable monovalent cation-binding sites in the low salt arrowhead motif. By contrast, five electronegative pockets were identified in the moderate salt dimeric hexad motif. Three of these are involved in cation binding sites sandwiched between G.G.G. G tetrad planes and two others, are involved in water-mediated cation binding sites spanning the unoccupied grooves associated with the adjacent stacked A.(G.G.G.G).A hexads. Our demonstration of A.(G. G.G.G).A hexad formation opens opportunities for the design of adenine-rich G-quadruplex-interacting oligomers that could potentially target base edges of stacked G.G.G.G tetrads. Such an approach could complement current efforts to design groove-binding and intercalating ligands that target G-quadruplexes in attempts designed to block the activity of the enzyme telomerase.

Probing the structure of multi-stranded guanine-rich DNA complexes by Raman spectroscopy and enzymatic degradation

The multi-stranded DNA complexes formed by the oligonucleotides d(T15G4T2G4), Tel, and d(T15G15), TG, were examined by nuclease digestion and Raman spectroscopy. Both Tel and TG can aggregate to form structures consisting of multiple, parallel-oriented DNA strands with two independent structural domains. Overall, the structures of the TG and Tel aggregates appear similar. According to the Raman data, the majority of bases are in C2'-endo/anti conformation. The interaction of guanines at the 3'-ends in both complexes stabilizes the complexes and protects them from degradation by exonuclease III. The 5'-extensions remain single-stranded and the thymines are accessible to single-strand-specific nuclease digestion. The extent of enzymatic cleavage at the junction at the 5' end of the 15 thymines implies a conformational change between this part of the molecule and the guanine-rich region. The differential enzymatic sensitivity of the complexes suggests there are variations in backbone conformations between TG and Tel aggregates. TG aggregates were more resistant to digestion by DNase I, Mung Bean nuclease, and S1 nuclease than Tel complexes. It is proposed that the lower DNase I sensitivity may be partly due to the more stable backbone exhibited by TG than Tel complexes. Structural uniformity along the guanine core of TG is suggested, as there is no indication of structural discontinuities or protected sites in the guanine-rich regions of TG aggregates. The lower extent of digestion by Mung Bean nuclease at the 3' end implies that these bases are inaccessible to the enzyme. This suggests that there is minimal fraying at the ends, which is consistent with the extreme thermal stability of the TG aggregates.

Binding sites and dynamics of ammonium ions in a telomere repeat DNA quadruplex

Guanine quartets are readily formed by guanine nucleotides and guanine-rich oligonucleotides in the presence of certain monovalent and divalent cations. The quadruplexes composed of these quartets are of interest for their potential roles in vivo, their relatively frequent appearance in oligonucleotides derived from in vitro selection, and their inhibition of template directed RNA polymerization under proposed prebiotic conditions. The requirement of cation coordination for the stabilization of G quartets makes understanding cation-quadruplex interactions an essential step towards a complete understanding of G quadruplex formation. We have used 15NH4+ as a probe of cation coordination by the four G quartets of the DNA bimolecular quadruplex [d(G4T4G4)]2, formed from oligonucleotides with the repeat sequence found in Oxytricha nova telomeres. 1H and 15N heteronuclear NMR spectroscopy has allowed the direct localization of monovalent cation binding sites in the solution state and the analysis of cation movement between the binding sites. These experiments show that [d(G4T4G4)]2 coordinates three ammonium ions, one in each of two symmetry related sites and one on the axis of symmetry of the dimeric molecule. The NH4+ move along the central axis of the quadruplex between these sites and the solution, reminiscent of an ion channel. The residence time of the central ion is determined to be 250 ms. The 15NH4+ is shown to be a valuable probe of monovalent cation binding sites and dynamics.

Following G-quartet formation by UV-spectroscopy

Oligodeoxynucleotides which include stretches of guanines form a well-known tetrameric structure. We show that the recording of reversible absorbance changes at 295 nm allows to precisely monitor intramolecular guanine (G)-quartet formation and dissociation. Accurate Tm and thermodynamic values could be easily extracted from the data, whereas classical recordings at 260 nm led to a much larger uncertainty and in extreme cases, to completely inaccurate measurements. This inverted denaturation profile was observed for all G-quartet-forming oligonucleotides studied so far. This technique is very useful in all cases where intramolecular or intermolecular quadruplex formation is suspected.

Porphyrin binding to quadrupled T4G4

We have recently reported the cation-induced self-assembly of DNA oligomers of the general sequence C4T4G4T1-4G4 into high-molecular weight multistranded structures [Marotta, S.P., Tamburri, P.A., and Sheardy, R.D. (1996) Biochemistry 35, 10484-10492]. The architecture of the proposed structure consists of a series of four leafed G4 tetrads tethered together via one or two T1-4 strands and thus resembles a long four-sided hollow tube with periodic "pockets". These pockets possess electrostatic, hydrogen bonding, and hydrophobic contact points and should be ideal candidates for the binding of small molecules. To assess the potential of using porphyrins as probes for these structures, we have investigated the interaction of tetrakis(4-N-methylpyridyl)porphine (H2TMPyP) with the simple quadruplex formed by T4G4 and with the duplex formed by CGCGATATCGCG. Visible absorption, circular dichroism, and fluorescent energy transfer studies indicate that H2TMPyP binds to both the duplex and quadruplex via intercalation at low [porphyrin]/[DNA molecule] ratios, i.e., in the presence of excess potential DNA binding sites. Analyses of Scatchard plots show that H2TMpyP binds with high affinity to both DNA secondary structures but binds to the quadruplex with an affinity 2 times greater than that of the duplex.

Guanine tetraplex formation by short DNA fragments containing runs of guanine and cytosine

Using CD spectroscopy, guanine tetraplex formation was studied with short DNA fragments in which cytosine residues were systematically added to runs of guanine either at the 5' or 3' ends. Potassium cations induced the G-tetraplex more easily with fragments having the guanine run at the 5' end, which is just an opposite tendency to what was reported for (G+T) oligonucleotides. However, the present (G+C) fragments simultaneously adopted other conformers that complicated the analysis. We demonstrate that repeated freezing/thawing, performed at low ionic strength, is a suitable method to exclusively stabilize the tetraplex in the (G+C) DNA fragments. In contrast to KCl, the repeated freeze/thaw cycles better stabilized the tetraplex with fragments having the guanine run on the 3' end. The tendency of guanine blocks to generate the tetraplex destabilized the d(G5).d(C5) duplex whose strands dissociated, giving rise to a stable tetraplex of (dG5) and single-stranded (dC5). In contrast to d(G3C3) and d(G5C5), repeated freezing/thawing induced the tetraplex even with the self-complementary d(C3G3) or d(C5G5); hence the latter oligonucleotides preferred the tetraplex to the apparently very stable duplex. The tetraplexes only included guanine blocks while the 5' end cytosines interfered neither with the tetraplex formation nor the tetraplex structure.

Telomeric and tetraplex DNA binding properties of qTBP42: a homologue of the CArG box binding protein CBF-A

qTBP42, a rat liver binding protein of telomeric and of guanine-rich single stranded or tetraplex DNA (Sarig, G., Weisman-Shomer, P., Erlitzki, R., and Fry, M. (1997) J. Biol. Chem. 272, 4474-4482), is identified here by its partial amino acid sequence as a homologue of the mouse muscle cell CArG box binding protein CBF-A. Complexes of qTBP42 with single stranded telomeric DNA or with double or single stranded CArG DNA are formed non-cooperatively and have a similar nanomolar-range dissociation constants, Kd. Double stranded telomeric or Plasmid DNA or poly d[(I-C)] are bound by qTBP42 less tightly. Analysis of the binding of tetramolecular quadruplex structures of the IgG switch sequence indicates that one molecule of qTBP42 associates with a single cluster of guanine quartets. The tight binding by qTBP42 of CArG box DNA, telomeric DNA and quadruplex DNA suggests that this protein may bind multiple targets in cellular DNA.

Sequence-specific binding protein of single-stranded and unimolecular quadruplex telomeric DNA from rat hepatocytes

A rat liver nuclear protein, unimolecular quadruplex telomere-binding protein 25, (uqTBP25) is described that binds tightly and specifically single-stranded and unimolecular tetraplex forms of the vertebrate telomeric DNA sequence 5'-d(TTAGGG)n-3'. A near homogeneous uqTBP25 was purified by ammonium sulfate precipitation, chromatographic separation from other DNA binding proteins, and three steps of column chromatography. SDS-polyacrylamide gel electrophoresis and Superdex copyright 200 gel filtration disclosed for uqTBP25 subunit and native Mr values of 25.4 +/- 0.5 and 25.0 kDa, respectively. Sequences of uqTBP25 tryptic peptides were closely homologous, but not identical, to heterogeneous nuclear ribonucleoprotein A1, heterogeneous nuclear ribonucleoprotein A2/B1, and single-stranded DNA-binding proteins UP1 and HDP-1. Complexes of uqTBP25 with single-stranded or unimolecular quadruplex 5'-d(TTAGGG)4-3', respectively, had dissociation constants, Kd, of 2.2 or 13.4 nM. Relative to d(TTAGGG)4, complexes with 5'-r(UUAGGG)4-3', blunt-ended duplex telomeric DNA, or quadruplex telomeric DNA had >10 to >250-fold higher Kd values. Single base alterations within the d(TTAGGG) repeat increased the Kd of complexes with uqTBP25 by 9-215-fold. Association with uqTBP25 protected d(TTAGGG)4 against nuclease digestion, suggesting a potential role for the protein in telomeric DNA transactions.

The DNA structures at the ends of eukaryotic chromosomes

The sequence organisation of the telomeric regions is extremely similar for all eukaryotes examined to date. Subtelomeric areas may contain large sequence arrays of middle repetitive, complex elements that sometimes have similarities to retrotransposons. In between and within these complex sequences are short, satellite-like repeats. These areas contain very few genes and are thought to be organised into a heterochromatin-like domain. The terminal regions almost invariably consist of short, direct repeats. These repeats usually contain clusters of 2-4 G residues and the strand that contains these clusters (the G strand) always forms the extreme 3'-end of the chromosome. Thus, most telomeric repeats are clearly related to each other which in turn suggests a common evolutionary origin. A number of different structures can be formed by single-stranded telomeric G strand repeats and, as has been suggested recently, by the G strand. Since the main mechanism for the maintenance of telomeric repeats predicts the occurrence of single-stranded extensions of the G strand, the propensity of G-rich DNA to fold into alternative DNA structures may have implications for telomere biology.

Purification and characterization of qTBP42, a new single-stranded and quadruplex telomeric DNA-binding protein from rat hepatocytes

Telomeres of vertebrate chromosomes terminate with a short 5'-d(TTAGGG)-3' single-stranded overhang that can form in vitro tetrahelical structures. Here we describe a new protein from rat hepatocyte nuclei designated quadruplex telomere-binding protein 42 (qTBP42) that tightly binds 5'-d(TTAGGG)n-3' and 5'-d(CCCTAA)n-3' single-stranded and tetraplex forms of 5'd(TTAGGG)n-3'. The thermostable qTBP42 was isolated from boiled nuclear extracts and purified to near homogeneity by successive steps of column chromatography on DEAE-cellulose, phosphocellulose, and phenyl-Sepharose. A subunit molecular size of 42.0 +/- 2.0 kDa was determined for qTBP42 by Southwestern blotting and SDS-polyacrylamide gel electrophoresis of the protein and its UV cross-linked complex with labeled telomeric DNA. A native size of 53. 5 +/- 0.9 kDa, estimated by Superdex copyright 200 gel filtration, suggests that qTBP42 is a monomeric protein. Sequences of five tryptic peptides of qTBP42 contained motifs shared by a mammalian CArG box-binding protein, hnRNP A/B, hnRNP C, and a human single-stranded telomeric DNA-binding protein. Complexes of qTBP42 with each complementary strand of telomeric DNA and with quadruplex forms of the guanine-rich strand had 3.7-14.6 nM dissociation constants, Kd, whereas complexes with double-stranded telomeric DNA had up to 100-fold higher Kd values. By associating with tetraplex and single-stranded telomeric DNA, qTBP42 increased their heat stability and resistance to digestion by micrococcal nuclease.

Three-dimensional model of a selective theophylline-binding RNA molecule

A three-dimensional (3D) model for an RNA molecule that selectively binds theophylline but not caffeine is proposed. This RNA, which was found using SELEX (Jenison et al., 1994), is 10,000 times more specific for theophylline (Kn = 320 nM) than for caffeine (KD = 3.5 mM), although the two ligands are identical except for a methyl group substituted at N7 (present only in caffeine). The binding affinity for ten xanthine-based ligands was used to derive a comparative molecular field analysis model (R2 = 0.93 for three components, with cross-validated R2 of 0.73), using the SYBYL and GOLPE programs. A pharmacophoric map was generated to locate steric and electrostatic interactions between theophylline and the RNA binding site. This information was used to identify putative functional groups of the binding pocket and to generate distance constraints. On the basis of a model for the secondary structure (Jenison et al., 1994), the 3D structure of this RNA was then generated using the following method: each helical region of the RNA molecule was treated as a rigid body; single-stranded loops with specific end-to-end distances were generated. The structures of RNA-xanthine complexes were studied using a modified Monte Carlo algorithm. The detailed structure of an RNA-ligand complex model, as well as possible explanations for the theophylline selectivity are discussed.

Solution structure of the Na+ form of the dimeric guanine quadruplex [d(G3T4G3)]2

The solution structure of the DNA quadruplex formed by the association of two strands of the DNA oligonucleotide, d(G3T4G3), in NaCl solution has been determined by 1H two-dimensional NMR techniques, full relaxation matrix calculations and restrained molecular dynamics. The refined structure incorporates the sequences 5'-G1sG2AG3AT4AT5AT6AT7AG8sG9AG10A-3' and 5'-G11sG12AG13AT14AT15AT16AT17AG18sG19sG20A-3' (where S and A denote syn and anti, respectively) in a three-quartet, diagonal-looped structure that we [Strahan, G. D., Shafer, R. H. & Keniry, M. A. (1994) Nucleic Acids Res. 22, 5447-5455] and others [Smith, F. W., Lau, F. W. & Feigon, J. (1994) Proc. Natl. Acad. Sci. USA 91, 10546-10550] have described. The loop structure is compact and incorporates many of the features found in duplex hairpin loops including base stacking, intraloop hydrogen bonding and extensive van der Waals' interactions. The first and third loop thymines stack over the outermost G-quartet and are also associated by hydrogen bonding. The second and the fourth loop thymines fold inwards in order to enhance van der Waals' interactions. The unexpected sequential syn-syn deoxyguanosines in the quadruplex stem appear to be a direct consequence of the way DNA oligonucleotides fold and the subsequent search for the most stable loop structure. The implications of loop sequence and length on the structure of quadruplexes are discussed.

Solution structures of unimolecular quadruplexes formed by oligonucleotides containing Oxytricha telomere repeats

BACKGROUND

Oligonucleotides containing the guanine-rich telomeric sequence of Oxytricha chromosomes (dT4G4) have previously been shown to form DNA quadruplexes comprising guanine quartets stabilized by cations. Two different structures have been reported for both d(G4T4G4) (Oxy1.5) and d(G4T4G4T4G4T4G4) (Oxy3.5).

RESULTS

Here we present the solution structure of a uracil- and inosine-containing derivative of Oxy3.5, d(G4TUTUG4T4G4UUTTG3I) (Oxy3.5-U4128), determined using two-dimensional 1H and 31P NMR techniques. This oligonucleotide forms a unimolecular quadruplex that is very similar to the dimeric Oxy1.5 solution structure, in that it contains a loop spanning the diagonal of an end quartet. The groove widths, strand polarities, and positions of the syn bases along the G4 tracts and within the quartets are all as reported for Oxy1.5. The first and third pyrimidine tracts form parallel loops spanning a wide groove and a narrow groove respectively.

CONCLUSIONS

Both Oxy3.5 and Oxy3.5-U(4)128 form unimolecular quadruplexes in solution with a diagonal central T4 loop. These results conflict with those reported for d(G4TUTUG4TTUUG4UUTTG4) in solution, in which the central loop spans a wide groove.

Chain folding and A:T pairing in human telomeric DNA: a model-building and molecular dynamics study

The various types of chain folding and possible intraloop as well as interloop base pairing in human telomeric DNA containing d(TTAG3) repeats have been investigated by model-building, molecular mechanics, and molecular dynamics techniques. Model-building and molecular mechanics studies indicate that it is possible to build a variety of energetically favorable folded-back structures with the two TTA loops on same side and the 5' end thymines in the two loops forming TATA tetrads involving a number of different intraloop as well as interloop A:T pairing schemes. In these folded-back structures, although both intraloop and interloop Watson-Crick pairing is feasible, no structure is possible with interloop Hoogsteen pairing. MD studies of representative structures indicate that the guanine-tetraplex stem is very rigid and, while the loop regions are relatively much more flexible, most of the hydrogen bonds remain intact throughout the 350-ps in vacuo simulation. The various possible TTA loop structures, although they are energetically similar, have characteristic inter proton distances, which could give rise to unique cross-peaks in two-dimensional nuclear Overhauser effect spectroscopy (NOESY) experiments. These folded-back structures with A:T pairings in the loop region help in rationalizing the data from chemical probing and other biochemical studies on human telomeric DNA.

Structure and dynamics of interstrand guanine association in quadruplex telomeric DNA

Exchanges of the amino and imino protons in guanine quartets of telomeric DNA have been time-resolved by laser Raman spectroscopy. The Raman dynamic probe has been applied to parallel and antiparallel quadruplexes formed by the telomeric repeat of Oxytricha nova, d(T4G4)4, and to the highly thermostable parallel quadruplex formed by d(G12). Time-dependent Raman spectra of the d(G12) quadruplex reveal two characteristic exchange reactions for guanine N2 amino groups. At 10 degrees C, the pseudo-first-order exchange rates are kN2H(10 degrees C) = 5.7 x 10(-3) and k'N2H'(10 degrees C) = 1.2 x 10(-2) min-1, assignable to Hoogsteen-hydrogen-bonded and non-hydrogen-bonded N2 protons, respectively. These measurements provide the first quantitative determination of two kinetically distinct N2 amino proton exchange reactions in the guanine quartet and demonstrate that amino group rotation about the C2-N2 bond is highly restricted in the quadruplex. No exchange of guanine N1 imino sites occurs in d(G12) at 10 degrees C, and N1 exchange remains slow even at 95 degrees C [kN1H(95 degrees C) = 2.7 x 10(-2) min-1], indicating severe suppression of imino exchange in guanine quartets. For both parallel and antiparallel quadruplexes of d(T4G4)4, proton exchange rates decrease in the order thymine N3 imino > guanine N2 amino > guanine N1 imino. The rapid exchange of thymine N3 imino sites indicates that thymine quartets are not stabilized in Oxytricha quadruplexes. The protium-->deuterium exchange experiments also establish new guanine Raman band assignments. Importantly, the 1603 cm-1 band is due to in-plane bending of N1-H, while the 1644 cm-1 band involves scissoring of the N2 amino group. Accordingly, the 1603 and 1644 cm-1 bands are potentially valuable markers of hydrogen-bonding interactions specific to guanine imino and amino sites, respectively. The present findings also show that guanine hydrogen bonding and exchange dynamics are not interrelated in a simple manner. Despite extraordinary retardation of N1 imino proton exchange, Raman markers suggest that Hoogsteen-type guanine-guanine hydrogen bonding (N1-H...O=C6) is comparable in strength to hydrogen bonding of N1-H with water and, surprisingly, much weaker than hydrogen bonding between N1-H and the cytosine N3 acceptor of Watson-Crick B DNA.

Telomere structure and function

Telomeres, the termini of linear eukaryotic chromosomes, contain specific DNA sequences that are widely conserved. These sequences not only recruit telomere-specific proteins, but also give telomeric DNA the ability to fold into four-stranded DNA structures. Recent structural studies have shown that the repertoire of quadruplexes formed by the G-rich strand is larger than had been envisaged. Even more surprising is a novel four-stranded structure formed by the C-rich strand, called the i-tetraplex. Genetic and biochemical analyses have been used to identify proteins involved in telomeric DNA packaging and organization. The possibility that four-stranded structures may play a role in telomere function has been strengthened by the discovery that telomeric proteins can bind to and promote the formation of G-quadruplexes.

Duplex to quadruplex equilibrium of the self-complementary oligonucleotide d(GGGGCCCC)

The structure of the deoxyoligonucleotide d(GGGGCCCC) has been monitored by 1H and 31P NMR, and by gel electrophoresis. In low-salt solution, this oligonucleotide forms a stable duplex structure. Upon titration with KCl, an equilibrium is established between duplex and quadruplex forms. The quadruplex form is the dominant one at physiological KCl concentrations, despite the fact that fewer hydrogen bonds are formed per strand in the quadruplex than in the duplex.

Solution structure of the Tetrahymena telomeric repeat d(T2G4)4 G-tetraplex

BACKGROUND

Telomeres in eukaryotic organisms are protein-DNA complexes which are essential for the protection and replication of chromosomal termini. The telomeric DNA of Tetrahymena consists of T2G4 repeats, and models have been previously proposed for the intramolecular folded structure of the d(T2G4)4 sequence based on chemical footprinting and cross-linking data. A high-resolution solution structure of this sequence would allow comparison with the structures of related G-tetraplexes.

RESULTS

The solution structure of the Na(+)-stabilized d(T2G4)4 sequence has been determined using a combined NMR-molecular dynamics approach. The sequence folds intramolecularly into a right-handed G-tetraplex containing three stacked G-tetrads connected by linker segments consisting of a G-T-T-G lateral loop, a central T-T-G lateral loop and a T-T segment that spans the groove through a double chain reversal. The latter T-T connectivity aligns adjacent G-G-G segments in parallel and introduces a new G-tetraplex folding topology with unprecedented combinations of strand directionalities and groove widths, as well as guanine syn/anti distributions along individual strands and around individual G-tetrads.

CONCLUSIONS

The four repeat Tetrahymena and human G-tetraplexes, which differ by a single guanine for adenine substitution, exhibit strikingly different folding topologies. The observed structural polymorphism establishes that G-tetraplexes can adopt topologies which project distinctly different groove dimensions, G-tetrad base edges and linker segments for recognition by, and interactions with, other nucleic acids and proteins.

Structural properties of the [d(G3T4G3)]2 quadruplex: evidence for sequential syn-syn deoxyguanosines

Two-dimensional 1H NMR studies on the dimeric hairpin quadruplex formed by d(G3T4G3) in the presence of either NaCl or KCl are presented. In the presence of either salt, the quadruplex structure is characterized by half the guanine nucleosides in the syn conformation about the glycosidic bond, the other half in the anti conformation, as reported for other similar sequences. However, 1H NOESY and 1H-31P heteronuclear correlation experiments demonstrate that the deoxyguanosines do not strictly alternate between syn and anti along individual strands. Thus we find the following sequences with regard to glycosidic bond conformation: 5'-G1SG2SG3AT4AT5A-T6AT7AG8SG9AG10A-3' and 5'-G11SG12AG13AT14AT1 5AT16AT17AG18SG19SG20A-3', where S and A denote syn and anti, respectively. This represents the first experimental evidence for a nucleic acid structure containing two sequential nucleosides in the syn conformation. The stacking interactions of the resulting quadruplex quartets and their component bases have been evaluated using unrestrained molecular dynamics calculations and energy component analysis. These calculations suggest that the sequential syn-syn/anti-anti and syn-anti quartet stacks are almost equal in energy, whereas the anti-syn stack, which is not present in our structure, is energetically less favorable by about 4 kcal/mol. Possible reasons for this energy difference and its implications for the stability of quadruplex structures are discussed.

d(G3T4G3) forms an asymmetric diagonally looped dimeric quadruplex with guanosine 5'-syn-syn-anti and 5'-syn-anti-anti N-glycosidic conformations

The structure formed by the DNA oligonucleotide d(G3T4G3) has been studied by one- and two-dimensional 1H NMR spectroscopy. In NaCl solution, d(G3T4G3), like d(G4T4G4) (Oxy-1.5), forms a dimeric quadruplex with the thymines in loops across the diagonal of the end quartets. Unlike Oxy-1.5, the dimer is not symmetric, and both monomer strands are observed in NMR spectra. Three quartets are formed from the GGG tracts. Glycosidic conformations of the guanines are 5'-syn-syn-anti-(loop)-syn-anti-anti in one strand and 5'-syn-anti-anti-(loop)-syn-syn-anti in the other strand. Thus, the stacking of the quartets (tail-to-tail, head-to-tail) is unlike all previously described fold-back (tail-to-tail, head-to-head) and parallel-stranded (head-to-tail, head-to-tail) quadruplexes.

Conformational polymorphism in telomeric structures: loop orientation and interloop pairing in d(G4TnG4)

Sequence repeats constituting the telomeric regions of chromosomes are known to adopt a variety of unusual structures, consisting of a G tetraplex stem and short stretches of thymines or thymines and adenines forming loops over the stem. Detailed model building and molecular mechanics studies have been carried out for these telomeric sequences to elucidate different types of loop orientations and possible conformations of thymines in the loop. The model building studies indicate that a minimum of two thymines have to be interspersed between guanine stretches to form folded-back structures with loops across adjacent strands in a G tetraplex (both over the small as well as large groove), while the minimum number of thymines required to build a loop across the diagonal strands in a G tetraplex is three. For two repeat sequences, these hairpins, resulting from different types of folding, can dimerize in three distinct ways--i.e., with loops across adjacent strands and on same side, with loops across adjacent strands and on opposite sides, and with loops across diagonal strands and on opposite sides--to form hairpin dimer structures. Energy minimization studies indicate that all possible hairpin dimers have very similar total energy values, though different structures are stabilized by different types of interactions. When the two loops are on the same side, in the hairpin dimer structures of d(G4TnG4), the thymines form favorably stacked tetrads in the loop region and there is interloop hydrogen bonding involving two hydrogen bonds for each thymine-thymine pair. Our molecular mechanics calculations on various folded-back as well as parallel tetraplex structures of these telomeric sequences provide a theoretical rationale for the experimentally observed feature that the presence of intervening thymine stretches stabilizes folded-back structures, while isolated stretches of guanines adopt a parallel tetraplex structure.

Monoclonal antibodies targeted to alpha-oligonucleotides. Characterisation and application in nucleic acid detection

The aim of the present study was to test the antigenicity of alpha-deoxyribonucleotides in order to develop a new tool for the detection of nucleic acid sequences for use in diagnostic applications. We describe four monoclonal antibodies (Mabs) which recognize alpha-deoxyribonucleotides. Two were raised against a poly(alpha-dT) sequence and specifically recognized the alpha-dT nucleotide. Two were raised against a sequence containing all four common nucleotides as alpha-nucleotides and, surprisingly, only recognized the alpha-dG nucleotide. For all four Mabs, no cross reactivity was observed with beta-oligonucleotides. These Mabs were reactive with alpha-oligonucleotide sequences whether these sequences were single-stranded or hybridized to DNA or RNA. The four Mabs were tested in a sandwich hybridization assay that consisted of an alpha-oligonucleotide (for target sequence recognition), one of the four Mabs (for recognition of the hybridized alpha-oligonucleotide), and goat anti-mouse antibody conjugated to horse radish peroxidase (HRP) (for detection). One of the monoclonal antibodies, Mab 2E11D7, was directly conjugated to HRP and used in sandwich hybridization to detect PCR fragments of HPV 18 DNA. The sensitivity of this reaction was 1 pg of plasmid DNA containing the HPV 18 fragment. The specificity of the detection was demonstrated using HPV 6/11 and 16 DNA sequences.

Oligo[d(C).(G)] runs exhibit a helical repeat of 11.1 bp in solution and cause slight DNA curvature when properly phased

We have inserted d(C)10 in a set of DNA fragments with bent segments on both ends, which are rotated with respect to each other by base pair wise increasing insertions. The electrophoretic mobilities on polyacrylamide gels of these DNA fragments were used to identify insertion sizes with cis conformations of the bent ends. These experiments revealed a helical repeat in solution of d(C).d(G) tracts of 11.1 +/- 0.08 bp. The electrophoretic mobilities of ligation ladders with properly phased d(C)5 and d(C)16 runs demonstrate a small but clearly detectable curvature of these fragments.

Solution structure of the human telomeric repeat d[AG3(T2AG3)3] G-tetraplex

BACKGROUND

Repeats of Gn sequences are detected as single strand overhangs at the ends of eukaryotic chromosomes together with associated binding proteins. Such telomere sequences have been implicated in the replication and maintenance of chromosomal termini. They may also mediate chromosomal organization and association during meiosis and mitosis.

RESULTS

We have determined the three-dimensional solution structure of the human telomere sequence, d[AG3(T2AG3)3] in Na(+)-containing solution using a combined NMR, distance geometry and molecular dynamics approach (including relaxation matrix refinement). The sequence, which contains four AG3 repeats, folds intramolecularly into a G-tetraplex stabilized by three stacked G-tetrads which are connected by two lateral loops and a central diagonal loop. Of the four grooves that are formed, one is wide, two are of medium width and one is narrow. The alignment of adjacent G-G-G segments in parallel generates the two grooves of medium width whilst the antiparallel arrangement results in one wide and one narrow groove. Three of the four adenines stack on top of adjacent G-tetrads while the majority of the thymines sample multiple conformations.

CONCLUSIONS

The availability of the d[AG3(T2AG3)3] solution structure containing four AG3 human telomeric repeats should permit the rational design of ligands that recognize and bind with specificity and affinity to the individual grooves of the G-tetraplex, as well as to either end containing the diagonal and lateral loops. Such ligands could modulate the equilibrium between folded G-tetraplex structures and their unfolded extended counterparts.