Ruthenium Complex “Light Switches” that are Selective for Different G‐Quadruplex Structures

Recognition and regulation of G‐quadruplex nucleic acid structures is an important goal for the development of chemical tools and medicinal agents. The addition of a bromo‐substituent to the dipyridylphenazine (dppz) ligands in the photophysical “light switch”, [Ru(bpy)₂dppz]²⁺, and the photochemical “light switch”, [Ru(bpy)₂dmdppz]²⁺, creates compounds with increased selectivity for an intermolecular parallel G‐quadruplex and the mixed‐hybrid G‐quadruplex, respectively. When [Ru(bpy)₂dppz‐Br]²⁺ and [Ru(bpy)₂dmdppz‐Br]²⁺ are incubated with the G‐quadruplexes, they have a stabilizing effect on the DNA structures. Activation of [Ru(bpy)₂dmdppz‐Br]²⁺ with light results in covalent adduct formation with the DNA. These complexes demonstrate that subtle chemical modifications of Ru^II complexes can alter G‐quadruplex selectivity, and could be useful for the rational design of in vivo G‐quadruplex probes.     

Binding Behaviors for Different Types of DNA G‐Quadruplexes: Enantiomers of [Ru(bpy)2(L)]2+ (L=dppz,dppz‐idzo)

Polymorphic DNA G‐quadruplex recognition has attracted great interest in recent years. The strong binding affinity and potential enantioselectivity of chiral [Ru(bpy)₂(L)]²⁺ (L=dipyrido[3,2‐a:2′,3′‐c]phenazine, dppz‐10,11‐imidazolone; bpy=2,2′‐bipyridine) prompted this investigation as to whether the two enantiomers, Δ and Λ, can show different effects on diverse structures with a range of parallel, antiparallel and mixed parallel/antiparallel G‐quadruplexes. These studies provide a striking example of chiral‐selective recognition of DNA G‐quadruplexes. As for antiparallel (tel‐Na⁺) basket G‐quadruplex, the Λ enantiomers bind stronger than the Δ enantiomers. Moreover, the behavior reported here for both enantiomers stands in sharp contrast to B‐DNA binding. The chiral selectivity toward mixed parallel/antiparallel (tel‐K⁺) G‐quadruplex of both compounds is weak. Different loop arrangements can change chiral complex selectivity for both antiparallel and mixed parallel/antiparallel G‐quadruplex. Whereas both Δ and Λ isomers bind to parallel G‐quadruplexes with comparable affinity, no appreciable stereoselective G‐quadruplex binding of the isomers was observed. In addition, different binding stoichiometries and binding modes for Δ and Λ enantiomers were confirmed. The results presented here indicate that chiral selective G‐quadruplex binding is not only related to G‐quadruplex topology, but also to the sequence and the loop constitution.     

Towards the Development of Structure‐Selective G‐Quadruplex‐Binding Indolo[3,2‐b]quinolines

The interaction of phenyl‐substituted indolo[3,2‐b]quinolines with DNA G‐quadruplexes of different topology were studied by using a combination of spectroscopic and calorimetric methodologies. N5‐Methylated indoloquinoline derivatives (^MePIQ) with an aminoalkyl side chain exhibit high affinities for the parallel‐stranded MYC quadruplex and a (3+1)‐hybrid structure combined with an excellent discrimination against the antiparallel thrombin‐binding aptamer (TBA) and the human telomeric (HT) quadruplexes. Dissociation constants for the binding of the ligand to the MYC quadruplex are in the submicromolar range, being below the corresponding dissociation constants for the antiparallel‐stranded quadruplexes by about one order of magnitude. Competition experiments with double‐helical DNA reveal the impact of indoloquinoline structural features on the selectivity for the parallel quadruplex relative to duplex DNA. Based on a calorimetric analysis binding to MYC is shown to be equally driven by favorable enthalpic and entropic contributions with no significant impact on the type of cation present.     

Quantitative Detection of G‐Quadruplex DNA in Live Cells Based on Photon Counts and Complex Structure Discrimination

G‐quadruplex DNA show structural polymorphism, leading to challenges in the use of selective recognition probes for the accurate detection of G‐quadruplexes in vivo. Herein, we present a tripodal cationic fluorescent probe, NBTE , which showed distinguishable fluorescence lifetime responses between G‐quadruplexes and other DNA topologies, and fluorescence quantum yield (Φ_f) enhancement upon G‐quadruplex binding. We determined two NBTE ‐G‐quadruplex complex structures with high Φ_f values by NMR spectroscopy. The structures indicated NBTE interacted with G‐quadruplexes using three arms through π–π stacking, differing from that with duplex DNA using two arms, which rationalized the higher Φ_f values and lifetime response of NBTE upon G‐quadruplex binding. Based on photon counts of FLIM, we detected the percentage of G‐quadruplex DNA in live cells with NBTE and found G‐quadruplex DNA content in cancer cells is 4‐fold that in normal cells, suggesting the potential applications of this probe in cancer cell detection.     

Duplex‐Guided Refolding into Novel G‐Quadruplex (3+1) Hybrid Conformations

The oligomer d(GCGTG₃TCAG₃TG₃TG₃ACGC) with short complementary flanking sequences at the 5′‐ and 3′‐ends was shown to fold into three different DNA G‐quadruplex species. In contrast, a corresponding oligomer that lacks base complementarity between the two overhang sequences folds into a single parallel G‐quadruplex. The three coexisting quadruplex structures were unambiguously identified and structurally characterized through detailed spectral comparisons with well‐defined G‐quadruplexes formed upon the deliberate incorporation of syn‐favoring 8‐bromoguanosine analogues into specific positions of the G‐core. Two (3+1) hybrid structures coexist with the parallel fold and feature a novel lateral–propeller–propeller loop architecture that has not yet been confirmed experimentally. Both hybrid quadruplexes adopt the same topology and only differ in their pattern of anti→syn transitions and tetrad stackings.     

Photoresponsive Formation of an Intermolecular Minimal G‐Quadruplex Motif

The ability of three different bifunctional azobenzene linkers to enable the photoreversible formation of a defined intermolecular two‐tetrad G‐quadruplex upon UV/Vis irradiation was investigated. Circular dichroism and NMR spectroscopic data showed the formation of G‐quadruplexes with K⁺ ions at room temperature in all three cases with the corresponding azobenzene linker in an E conformation. However, only the para–para‐substituted azobenzene derivative enables photoswitching between a nonpolymorphic, stacked, tetramolecular G‐quadruplex and an unstructured state after E–Z isomerization.     

Photo‐Cross‐Linking Probes for Trapping G‐Quadruplex DNA

We have developed a straightforward synthetic pathway to a set of six photoactivatable G‐quadruplex ligands with a validated G4‐binding motif (the bisquinolinium pyridodicarboxamide PDC‐360A) tethered through various spacers to two different photo‐cross‐linking groups: benzophenone and an aryl azide. The high quadruplex‐versus‐duplex selectivity of the PDC core was retained in the new derivatives and resulted in selective alkylation of two well‐known G‐quadruplexes (human telomeric G4 and oncogene promoter c‐myc G4) under conditions of harsh competition. The presence of two structurally different photoactivatable functions allowed the selective alkylation of G‐quadruplex structures at specific nucleobases and irreversible G4 binding. The topology and sequence of the quadruplex matrix appear to influence strongly the alkylation profile, which differs for the telomeric and c‐myc quadruplexes. The new compounds are photoactive in cells and thus provide new tools for studying G4 biology.     

NMR Structure of a Triangulenium‐Based Long‐Lived Fluorescence Probe Bound to a G‐Quadruplex

An NMR structural study of the interaction between a small‐molecule optical probe (DAOTA‐M2) and a G‐quadruplex from the promoter region of the c‐myc oncogene revealed that they interact at 1:2 binding stoichiometry. NMR‐restrained structural calculations show that binding of DAOTA‐M2 occurs mainly through π–π stacking between the polyaromatic core of the ligand and guanine residues of the outer G‐quartets. Interestingly, the binding affinities of DAOTA‐M2 differ by a factor of two for the outer G‐quartets of the unimolecular parallel G‐quadruplex under study. Unrestrained MD calculations indicate that DAOTA‐M2 displays significant dynamic behavior when stacked on a G‐quartet plane. These studies provide molecular guidelines for the design of triangulenium derivatives that can be used as optical probes for G‐quadruplexes.     

Effect of the Ancillary Ligands on the Spectral Properties and G‐Quadruplexes DNA Binding Behavior: A Combined Experimental and Theoretical Study

In an effort to explore the effect of ancillary ligands on the spectral properties and overall G‐quadruplex DNA binding behavior, two new ruthenium(II) complexes [Ru(phen)₂(dppzi)]²⁺ ( 1 ) and [Ru(dmp)₂(dppzi)]²⁺ ( 2 ) (phen=1,10‐phenanthroline, dmp=2,9‐dimethyl‐1,10‐phenanthroline, dppzi=dipyrido[3,2‐a:2′,3′‐c]phenazine‐10,11‐imidazole) were prepared. Complex 1 can emit luminescence in the absence and presence of G‐quadruplexes DNA. However, with ?CH₃ substituent on the 2‐ and 9‐positions of the phen ancillary ligand, no detectable luminescence is observed for complex 2 in any organic solvent or in the absence and/or presence of G‐quadruplex DNA. Experimental and molecular docking studies indicated that both complexes interacted with the human telomeric repeat AG3(T2AG3)3 (22AG) G‐quadruplex with the stoichiometric ratio of 1:1, but the two complexes showed different G‐quadruplex DNA binding affinity. Complex 1 binds to the G‐quadruplexes DNA more tightly than complex 2 does. Our results demonstrate that methyl groups on the phen ancillary ligand significantly affect the spectral properties and the overall DNA binding behavior of the complexes. Such difference in spectral properties and DNA binding affinities of these two complexes can be reasonably explained by DFT/TD‐DFT calculations. This work provides guidance not only on exploring the G‐quadruplexes DNA binding behavior of complexes, but also understanding the unique luminescence mechanism.     

Structure‐Based Design of Platinum(II) Complexes as c‐myc Oncogene Down‐Regulators and Luminescent Probes for G‐Quadruplex DNA

A series of platinum(II) complexes with tridentate ligands was synthesized and their interactions with G‐quadruplex DNA within the c‐myc gene promoter were evaluated. Complex 1 , which has a flat planar 2,6‐bis(benzimidazol‐2‐yl)pyridine (bzimpy) scaffold, was found to stabilize the c‐myc G‐quadruplex structure in a cell‐free system. An in silico G‐quadruplex DNA model has been constructed for structure‐based virtual screening to develop new Pt^II‐based complexes with superior inhibitory activities. By using complex 1 as the initial structure for hit‐to‐lead optimization, bzimpy and related 2,6‐bis(pyrazol‐3‐yl)pyridine (dPzPy) scaffolds containing amine side‐chains emerge as the top candidates. Six of the top‐scoring complexes were synthesized and their interactions with c‐myc G‐quadruplex DNA have been investigated. The results revealed that all of the complexes have the ability to stabilize the c‐myc G‐quadruplex. Complex 3 a ([Pt^II L2R ] ⁺ ; L2 =2,6‐bis[1‐(3‐piperidinepropyl)‐1H‐enzo[d]imidazol‐2‐yl]pyridine, R =Cl) displayed the strongest inhibition in a cell‐free system (IC₅₀=2.2 μM ) and was 3.3‐fold more potent than that of 1 . Complexes 3 a and 4 a ([Pt^II L3R ]⁺; L3 =2,6‐bis[1‐(3‐morpholinopropyl)‐1H‐pyrazol‐3‐yl]pyridine, R =Cl) were found to effectively inhibit c‐myc gene expression in human hepatocarcinoma cells with IC₅₀ values of ≈17 μM , whereas initial hit 1 displayed no significant effect on gene expression at concentrations up to 50 μM . Complexes 3 a and 4 a have a strong preference for G‐quadruplex DNA over duplex DNA, as revealed by competition dialysis experiments and absorption titration; 3 a and 4 a bind G‐quadruplex DNA with binding constants (K) of approximately 10⁶–10⁷ dm³ mol^?1, which are at least an order of magnitude higher than the K values for duplex DNA. NMR spectroscopic titration experiments and molecular modeling showed that 4 a binds c‐myc G‐quadruplex DNA through an external end‐stacking mode at the 3′‐terminal face of the G‐quadruplex. Intriguingly, binding of c‐myc G‐quadruplex DNA by 3 b is accompanied by an increase of up to 38‐fold in photoluminescence intensity at λ_max=622 nm.     

The Effect of DNA Sequence Directionality on G‐Quadruplex Folding

Sequence inversion in G‐rich DNA from 5′→3′ to 3′→5′ exerts a substantial effect on the number of structures formed, while the type of G‐quadruplex fold is in fact determined by the presence of K⁺ or Na⁺ ions. The melting temperatures of G‐quadruplexes adopted by oligonucleotides with sequences in the 5′→3′ direction are higher than those of their 3′→5′ counterparts with both KCl and NaCl. CD, UV, and NMR spectroscopy demonstrates the importance of primary sequence for the structural diversity of G‐quadruplexes. The changes introduced by mere sequence reversal of the G‐rich DNA segment have a substantial impact on the polymorphic nature of the resulting G‐quadruplexes and their potential physiological roles. The insights resulting from this study should enable extension of the empirical rules for the prediction of G‐quadruplex topology.     

An Unprecedented Knot‐like G‐Quadruplex Peripheral Motif

A knot‐like G‐quadruplex peripheral structure is formed by a 7‐nt DNA sequence DL7 (TGTTGGT), in which six out of its seven nucleobases participate in compact base‐pairing interactions. Here, the solution NMR structure of a 24‐nt DNA oligonucleotide containing the DL7 sequence shows the interaction between a two‐layer anti‐parallel G‐quadruplex core and the peripheral knot‐like structure, including the construction of two sharp turns in the DNA backbone. The formation of this novel structural element highlights the intricate properties of single‐stranded DNA folding in presence of G‐quadruplex‐forming motifs. We demonstrated the compatibility of the DL7 knot‐like structure with various G‐quadruplexes, which could have implications in drug design and DNA engineering.     

Asymmetric Distyrylpyridinium Dyes as Red‐Emitting Fluorescent Probes for Quadruplex DNA

The interactions of three cationic distyryl dyes, namely 2,4‐bis(4‐dimethylaminostyryl)‐1‐methylpyridinium ( 1 a ), its derivative with a quaternary aminoalkyl chain ( 1 b ), and the symmetric 2,6‐bis(4‐dimethylaminostyryl)‐1‐methylpyridinium ( 2 a ), with several quadruplex and duplex nucleic acids were studied with the aim to establish the influence of the geometry of the dyes on their DNA‐binding and DNA‐probing properties. The results from spectrofluorimetric titrations and thermal denaturation experiments provide evidence that asymmetric (2,4‐disubstituted) dyes 1 a and 1 b bind to quadruplex DNA structures with a near‐micromolar affinity and a fair selectivity with respect to double‐stranded (ds) DNA [K_a(G4)/K_a(ds)=2.5–8.4]. At the same time, the fluorescence of both dyes is selectively increased in the presence of quadruplex DNAs (more than 80–100‐fold in the case of human telomeric quadruplex), even in the presence of an excess of competing double‐stranded DNA. This optical selectivity allows these dyes to be used as quadruplex‐DNA‐selective probes in solution and stains in polyacrylamide gels. In contrast, the symmetric analogue 2 a displays a strong binding preference for double‐stranded DNA [K_a(ds)/K_a(G4)=40–100), presumably due to binding in the minor groove. In addition, 2 a is not able to discriminate between quadruplex and duplex DNA, as its fluorescence is increased equally well (20–50‐fold) in the presence of both structures. This study emphasizes and rationalizes the strong impact of subtle structural variations on both DNA‐recognition properties and fluorimetric response of organic dyes.     

Dinuclear Ruthenium(II) Complexes That Induce and Stabilise G‐Quadruplex DNA

A series of dinuclear ruthenium(II) complexes were synthesised, and the complexes were determined to be new highly selective compounds for binding to telomeric G‐quadruplex DNA. The interactions of these complexes with telomeric G‐quadruplex DNA were studied by using circular dichroism (CD) spectroscopy, fluorescence resonance energy transfer (FRET) melting assays, isothermal titration calorimetry (ITC) and molecular modelling. The results showed that the complexes 1 , 2 and 4 induced and stabilised the formation of antiparallel G‐quadruplexes of telomeric DNA in the absence of salt or in the presence of 100 mM K⁺‐containing buffer. Furthermore, complexes 1 and 2 strongly bind to and effectively stabilise the telomeric G‐quadruplex structure and have significant selectivity for G‐quadruplex over duplex DNA. In comparison, complex 3 had a much lesser effect on the G‐quadruplex, suggesting that possession of a suitably sized plane for good π–π stacking with the G‐quadruplets is essential for the interaction of the dinuclear ruthenium(II) complexes with the G‐quadruplex. Moreover, telomerase inhibition by the four complexes and their cellular effects were studied, and complex 1 was determined to be the most promising inhibitor of both telomerase and HeLa cell proliferation.     

Molecular Recognition and Visual Detection of G‐Quadruplexes by a Dicarbocyanine Dye

The interactions of a dicarbocyanine dye 3,3′‐diethylthiadicarbocyanine, DiSC₂(5) , with DNA G‐quadruplexes were studied by means of a combination of various spectroscopic techniques. Aggregation of excess dye as a result of its positive charge is promoted by the presence of the polyanionic quadruplex structure. Specific high‐affinity binding to the parallel quadruplex of the MYC promoter sequence involves stacking of DiSC₂(5) on the external G‐tetrads; the 5′‐terminal tetrad is the favored binding site. Significant energy transfer between DNA and the dye in the UV spectral region is observed upon DiSC₂(5) binding. The transfer efficiency strongly depends on the DNA secondary structure as well as on the G‐quadruplex topology. These photophysical features enable the selective detection of DNA quadruplexes through sensitized DiSC₂(5) fluorescence in the visible region.     

Ion‐Responsive Hemin–G‐Quadruplexes for Switchable DNAzyme and Enzyme Functions

Programmed nucleic acid sequences undergo K⁺ ion‐induced self‐assembly into G‐quadruplexes and separation of the supramolecular structures by the elimination of K⁺ ions by crown ether or cryptand ion‐receptors. This process allows the switchable formation and dissociation of the respective G‐quadruplexes. The different G‐quadruplex structures bind hemin, and the resulting hemin–G‐quadruplex structures reveal horseradish peroxidase DNAzyme catalytic activities. The following K⁺ ion/receptor switchable systems are described: 1) The K⁺‐induced self‐assembly of the Mg²⁺‐dependent DNAzyme subunits into a catalytic nanostructure using the assembly of G‐quadruplexes as bridging unit. 2) The K⁺‐induced stabilization of the anti‐thrombin G‐quadruplex nanostructure that inhibits the hydrolytic functions of thrombin. 3) The K⁺‐induced opening of DNA tweezers through the stabilization of G‐quadruplexes on the “tweezers’ arms" and the release of a strand bridging the tweezers into a closed structure. In all of the systems reversible, switchable, functions are demonstrated. For all systems two different signals are used to follow the switchable functions (fluorescence and the catalytic functions of the derived hemin–G‐quadruplex DNAzyme).     

Polycyclic Azoniahetarenes: Assessing the Binding Parameters of Complexes between Unsubstituted Ligands and G‐Quadruplex DNA

Polycyclic azoniahetarenes were employed to determine the effect of the structure of unsubstituted polyaromatic ligands on their quadruplex‐DNA binding properties. The interactions of three isomeric diazoniadibenzo[b,k]chrysenes ( 4 a – c ), diazoniapentaphene ( 5 ), diazoniaanthra[1,2‐a]anthracene ( 6 ), and tetraazoniapentapheno[6,7‐h]pentaphene ( 3 ) with quadruplex DNA were examined by DNA melting studies (FRET melting) and fluorimetric titrations. In general, penta‐ and hexacyclic azoniahetarenes bind to quadruplex DNA (K_b≈10⁶ M ^?1) even in the absence of additional functional side chains. The binding modes of 4 a – c and 3 were studied in more detail by ligand displacement experiments, isothermal titration calorimetry, and CD and NMR spectroscopy. All experimental data indicate that terminal π stacking of the diazoniachrysenes to the quadruplex is the major binding mode; however, because of different electron distributions of the π systems of each isomer, these ligands align differently in the binding site to achieve ideal binding interactions. It is proposed that tetraazonia ligand 3 binds to the quadruplex by terminal stacking with a small portion of its π system, whereas a significant part of the bulky ligand most likely points outside the quadruplex structure, and is thus partially placed in the grooves. Notably, 3 and the known tetracationic porphyrin TMPyP4 exhibit almost the same binding properties towards quadruplex DNA, with 3 being more selective for quadruplex than for duplex DNA. Overall, studies on azonia‐type hetarenes enable understanding of some parameters that govern the quadruplex‐binding properties of parent ligand systems. Since unsubstituted ligands were employed in this study, complementary and cooperative effects of additional substituents, which may interfere with the ligand properties, were eliminated.     

Ion‐Selective Formation of a Guanine Quadruplex on DNA Origami Structures

DNA origami nanostructures are a versatile tool that can be used to arrange functionalities with high local control to study molecular processes at a single‐molecule level. Here, we demonstrate that DNA origami substrates can be used to suppress the formation of specific guanine (G) quadruplex structures from telomeric DNA. The folding of telomeres into G‐quadruplex structures in the presence of monovalent cations (e.g. Na⁺ and K⁺) is currently used for the detection of K⁺ ions, however, with insufficient selectivity towards Na⁺. By means of FRET between two suitable dyes attached to the 3′‐ and 5′‐ends of telomeric DNA we demonstrate that the formation of G‐quadruplexes on DNA origami templates in the presence of sodium ions is suppressed due to steric hindrance. Hence, telomeric DNA attached to DNA origami structures represents a highly sensitive and selective detection tool for potassium ions even in the presence of high concentrations of sodium ions.     

Synthesis of New DNA G‐Quadruplex Constructs with Anthraquinone Insertions and Their Anticoagulant Activity

1,4‐Dihydroxyanthraquinone and 1,8‐dihydroxyanthraquinone were alkylated with 3‐bromopropan‐1‐ol and subsequently transformed into the corresponding DMT protected phosphoramidite building blocks for insertion into loops of the G‐quadruplex of the thrombin binding aptamer (TBA). The 1,4‐disubstituted anthraquinone linker led to a significant stabilization of the G‐quadruplex structure upon replacing a T in each of two neighboring lateral TT loops and a 26.2° increase in thermal melting temperature was found. CD Spectra of the modified quadruplexes confirmed anti‐parallel conformations in all cases under potassium buffer conditions as previously observed for TBA. Although the majority of the anthraquinone modified TBA analogues showed a decrease in clotting times in a fibrinogen clotting assay when compared to TBA, modified aptamers containing a 1,8‐disubstituted anthraquinone linker replacing G₈ or T₉ in the TGT loop showed improved anticoagulant activities. Molecular modeling studies explained the increased thermal melting temperatures of anthraquinone‐modified G‐quadruplexes.     

Cationic Pentaheteroaryls as Selective G‐Quadruplex Ligands by Solvent‐Free Microwave‐Assisted Synthesis

We report herein a solvent‐free and microwaved‐assisted synthesis of several water soluble acyclic pentaheteroaryls containing 1,2,4‐oxadiazole moieties ( 1 – 7 ). Their binding interactions with DNA quadruplex structures were thoroughly investigated by FRET melting, fluorescent intercalator displacement assay (G4‐FID) and CD spectroscopy. Among the G‐quadruplexes considered, attention was focused on telomeric repeats together with the proto‐oncogenic c‐kit sequences and the c‐myc oncogene promoter. Compound 1 , and to a lesser extent 2 and 5 , preferentially stabilise an antiparallel structure of the telomeric DNA motif, and exhibit an opposite binding behaviour to structurally related polyoxazole ( TOxaPy ), and do not bind duplex DNA. The efficiency and selectivity of the binding process was remarkably controlled by the structure of the solubilising moieties.