Macrocyclic Polyoxazoles as G‐Quadruplex Ligands

This review deals with recent progress in the synthesis and evaluation of our telomestatin‐inspired macrocyclic polyoxazoles as G‐quadruplex (G4) ligands. The hexaoxazole derivatives (6OTDs) interact with and stabilize G4‐forming oligonucleotides, depending upon the character of the side chain functional groups. Cationic functional groups are particularly effective due to their secondary interaction with phosphate in the DNA backbone. On the other hand, heptaoxazole derivatives (7OTDs) showed potent G4‐binding and stabilization activity regardless of the functional groups on the side chain. A caged G4 ligand, Y2Nv2‐6OTD ( 7 ), and a fluorescent G4 ligand, L1BOD‐7OTD ( 13 ), have been synthesized.     

Tetrasubstituted Phenanthrolines as Highly Potent,Water‐Soluble,and Selective G‐Quadruplex Ligands

Small molecules capable of stabilizing the G‐quadruplex (G4) structure are of interest for the development of improved anticancer drugs. Novel 4,7‐diamino‐substituted 1,10‐phenanthroline‐2,9‐dicarboxamides that represent hybrid structures of known phenanthroline‐based ligands have been designed. An efficient synthetic route to the compounds has been developed and their interactions with various G4 sequences have been evaluated by Förster resonance energy transfer (FRET) melting assays, fluorescent intercalator displacement (FID), electrospray ionization mass spectrometry (ESI‐MS), and circular dichroism (CD) spectroscopy. The preferred compounds have high aqueous solubility and are strong and potent G4 binders with a high selectivity over duplex DNA; thus, they represent a significant improvement over the lead compounds. Two of the compounds are inhibitors of HeLa and HT1080 cell proliferation.     

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.     

Click Chemistry for the Identification of G‐Quadruplex Structures: Discovery of a DNA–RNA G‐Quadruplex

A trap that closes with a “click” : The copper‐catalyzed azide–alkyne cycloaddition can occur in different G‐quadruplex structures (see scheme). The species trapped by the click reaction can then be separated and analyzed. By using this approach, a DNA–RNA hybrid‐type G‐quadruplex structure formed by human telomeric DNA and RNA sequences was detected.

     

Multitasking Water‐Soluble Synthetic G‐Quartets: From Preferential RNA–Quadruplex Interaction to Biocatalytic Activity

Natural G‐quartets, a cyclic and coplanar array of four guanine residues held together through a Watson–Crick/Hoogsteen hydrogen‐bond network, have received recently much attention due to their involvement in G‐quadruplex DNA, an alternative higher‐order DNA structure strongly suspected to play important roles in key cellular events. Besides this, synthetic G‐quartets (SQ), which artificially mimic native G‐quartets, have also been widely studied for their involvement in nanotechnological applications (i.e., nanowires, artificial ion channels, etc.). In contrast, intramolecular synthetic G‐quartets (iSQ), also named template‐assembled synthetic G‐quartets (TASQ), have been more sparingly investigated, despite a technological potential just as interesting. Herein, we report on a particular iSQ named ^PNADOTASQ, which demonstrates very interesting properties in terms of DNA and RNA interaction (notably its selective recognition of quadruplexes according to a bioinspired process) and catalytic activities, through its ability to perform peroxidase‐like hemin‐mediated oxidations either in an autonomous fashion (i.e., as pre‐catalyst for TASQzyme reactions) or in conjunction with quadruplex DNA (i.e., as enhancing agents for DNAzyme processes). These results provide a solid scientific basis for TASQ to be used as multitasking tools for bionanotechnological applications.     

Delineation of G‐Quadruplex Alkylation Sites Mediated by 3,6‐Bis(1‐methyl‐4‐vinylpyridinium iodide)carbazole‐Aniline Mustard Conjugates

A new G‐quadruplex (G‐4)‐directing alkylating agent BMVC‐C3M was designed and synthesized to integrate 3,6‐bis(1‐methyl‐4‐vinylpyridinium iodide)carbazole (BMVC) with aniline mustard. Various telomeric G‐4 structures (hybrid‐2 type and antiparallel) and an oncogene promoter, c‐MYC (parallel), were constructed to react with BMVC‐C3M, yielding 35 % alkylation yield toward G‐4 DNA over other DNA categories (<6 %) and high specificity under competition conditions. Analysis of the intact alkylation adducts by electrospray ionization mass spectroscopy (ESI‐MS) revealed the stepwise DNA alkylation mechanism of aniline mustard for the first time. Furthermore, the monoalkylation sites and intrastrand cross‐linking sites were determined and found to be dependent on G‐4 topology based on the results of footprinting analysis in combination with mass spectroscopic techniques and in silico modeling. The results indicated that BMVC‐C3M preferentially alkylated at A15 (H26), G12 (H24), and G2 (c‐MYC), respectively, as monoalkylated adducts and formed A15–C3M–A21 (H26), G12–C3M–G4 (H24), and G2–C3M–G4/G17 (c‐MYC), respectively, as cross‐linked dialkylated adducts. Collectively, the stability and site‐selective cross‐linking capacity of BMVC‐C3M provides a credible tool for the structural and functional characterization of G‐4 DNAs in biological systems.     

A Photoreactive G‐Quadruplex Ligand Triggered by Green Light

A photoreactive molecular dye targeting the G‐quadruplex nucleic acid (G4) of the human telomeric sequence Tel22, and several mutated analogues, was activated by green light (λ=532 nm). Highly selective covalent modification of G4 versus single‐stranded and double‐stranded DNA was achieved with efficiency up to 64 %. The phenoxyl radical was generated and detected by laser‐flash photolysis as a reactive intermediate that targeted loop thymine residues. These insights may suggest a non‐invasive tool for selective nucleic acid tagging and “pull‐down” cellular applications.     

Inverting the G‐Tetrad Polarity of a G‐Quadruplex by Using Xanthine and 8‐Oxoguanine

G‐quadruplexes are four‐stranded nucleic acid structures that are built from consecutively stacked guanine tetrad (G‐tetrad) assemblies. The simultaneous incorporation of two guanine base lesions, xanthine (X) and 8‐oxoguanine (O), within a single G‐tetrad of a G‐quadruplex was recently shown to lead to the formation of a stable G?G?X?O tetrad. Herein, a judicious introduction of X and O into a human telomeric G‐quadruplex‐forming sequence is shown to reverse the hydrogen‐bond polarity of the modified G‐tetrad while preserving the original folding topology. The control exerted over G‐tetrad polarity by joint X?O modification will be valuable for the design and programming of G‐quadruplex structures and their properties.     

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.     

Tetraphenylethene Derivatives with Different Numbers of Positively Charged Side Arms have Different Multimeric G‐Quadruplex Recognition Specificity

Some G‐rich sequences in the human genome have the potential to fold into a multimeric G‐quadruplex (G4) structure and the formation of telomeric multimeric G4 has been demonstrated. Searching for highly specific multimeric G4 ligands is important for structure probing and for study of the function of G‐rich gene sequences, as well as for the design of novel anticancer drugs. We found different numbers of positively charged side‐arm substituents confer tetraphenylethene (TPE) derivatives with different multimeric G4 recognition specificity. 1,2‐Bis{4‐[(trimethylammonium)butoxy]phenyl}‐1,2‐tetraphenylethene dibromide (DATPE), which contains two side arms and gives a fluorescence response to only multimeric G4, has a low level of cytotoxicity and little or no effect on multimeric G4 conformation or stability. These features make DATPE a promising fluorescent probe for detection of multimeric G4 specifically in biological samples or in vivo. 1,1,2,2‐Tetrakis{4‐[(trimethylammonium)butoxy]phenyl}tetraphenylethene tetrabromide (QATPE), which contains four side arms, has a lower level of specificity for multimeric G4 recognition compared to DATPE but its binding affinity to multimeric G4 is higher compared to other structural DNAs. Its high multimeric G4‐binding affinity, excellent multimeric G4‐stabilizing ability, and the promotion of parallel G4 formation make QATPE a good candidate for novel anticancer drugs targeting multimeric G4 specifically, especially telomeric multimeric G4. This work provides information that might aid the design of specific multimeric G4 probes and the development of novel anticancer drugs.