Rational design of small-molecules to recognize G-quadruplexes of c-MYC promoter and telomere and the evaluation of their in vivo antitumor activity against breast cancer.

DNA G4-structures from human c-MYC promoter and telomere are considered as important drug targets; however, the developing of small-molecule-based fluorescent binding ligands that are highly selective in targeting these G4-structures over other types of nucleic acids is challenging. We herein report a new approach of designing small molecules based on a non-selective thiazole orange scaffold to provide two-directional and multi-site interactions with flanking residues and loops of the G4-motif for better selectivity. The ligands are designed to establish multi-site interactions in the G4-binding pocket. This structural feature may render the molecules higher selectivity toward c-MYC G4s than other structures. The ligand-G4 interaction studied with 1H NMR may suggest a stacking interaction with the terminal G-tetrad. Moreover, the intracellular co-localization study with BG4 and cellular competition experiments with BRACO-19 may suggest that the binding targets of the ligands in cells are most probably G4-structures. Furthermore, the ligands that either preferentially bind to c-MYC promoter or telomeric G4s are able to downregulate markedly the c-MYC and hTERT gene expression in MCF-7 cells, and induce senescence and DNA damage to cancer cells. The in vivo antitumor activity of the ligands in MCF-7 tumor-bearing mice is also demonstrated.

A small-sized benzothiazole-indolium fluorescent probe: the study of interaction specificity targeting c-MYC promoter G-quadruplex structures and live cell imaging.

A small-sized c-MYC promoter G-quadruplex selective fluorescent BZT-Indolium binding ligand was demonstrated for the first time as a highly target-specific and photostable probe for in vitro staining and live cell imaging and it was found to be able to inhibit the amplification of the c-MYC G-rich sequence (G-quadruplex) and down-regulate oncogene c-MYC expression in human cancer cells (HeLa).

A study on a telo21 G-quadruplex DNA specific binding ligand: enhancing the molecular recognition ability via the amino group interactions.

A symmetric ligand is synthesized composed of a core N-methylpyridinium scaffold and two para-substituted benzyl groups through a flexible ethylene bridge to form a novel three-ring-conjugated system. The ligand system was found to have only weak background fluorescent signal in aqueous or physiological conditions and exhibited strong fluorescent signal enhancement targeting at telo21 G-quadruplex structure rather than other types of nucleic acids. The comparison study with two terminal groups (-N(CH3)2 versus -SCH3) indicates that the stimulated signal enhancement of specific binding is probably attributed to the hydrogen-bonding interactions through the amino groups in the G-quartets. The docking result illuminates the experimental observation that the ligand system showed only weak fluorescent signals in aqueous or physiological conditions while exhibiting a strong fluorescent signal upon binding to the telo21 G-quadruplex structure (binding energy: -6.2 kcal mol-1).

Correction: A study on a telo21 G-quadruplex DNA specific binding ligand: enhancing the molecular recognition ability via the amino group interactions.

[This corrects the article DOI: 10.1039/C8RA03833C.].

Molecular Engineering of Thiazole Orange Dye: Change of Fluorescent Signaling from Universal to Specific upon Binding with Nucleic Acids in Bioassay.

The universal fluorescent staining property of thiazole orange (TO) dye was adapted in order to be specific for G-quadruplex DNA structures, through the introduction of a styrene-like substituent at the ortho-position of the TO scaffold. This extraordinary outcome was determined from experimental studies and further explored through molecular docking studies. The molecular docking studies help understand how such a small substituent leads to remarkable fluorescent signal discrimination between G-quadruplex DNA and other types of nucleic acids. The results reveal that the modified dyes bind to the G-quadruplex or duplex DNA in a similar fashion as TO, but exhibit either enhanced or quenched fluorescent signal, which is determined by the spatial length and orientation of the substituent and has never been known. The new fluorescent dye modified with a p-(dimethylamino)styryl substituent offers 10-fold more selectivity toward telomeric G-quadruplexes than double-stranded DNA substrates. In addition, native PAGE experiments, FRET, CD analysis, and live cell imaging were also studied and demonstrated the potential applications of this class of thiazole-orange-based fluorescent probes in bioassays and cell imaging.

Chemical intervention of the NM23-H2 transcriptional programme on c-MYC via a novel small molecule.

c-MYC is an important oncogene that is considered as an effective target for anticancer therapy. Regulation of this gene's transcription is one avenue for c-MYC-targeting drug design. Direct binding to a transcription factor and generating the intervention of a transcriptional programme appears to be an effective way to modulate gene transcription. NM23-H2 is a transcription factor for c-MYC and is proven to be related to the secondary structures in the promoter. Here, we first screened our small-molecule library for NM23-H2 binders and then sifted through the inhibitors that could target and interfere with the interaction process between NM23-H2 and the guanine-rich promoter sequence of c-MYC. As a result, a quinazolone derivative, SYSU-ID-01: , showed a significant interference effect towards NM23-H2 binding to the guanine-rich promoter DNA sequence. Further analyses of the compound-protein interaction and the protein-DNA interaction provided insight into the mode of action for SYSU-ID-01: . Cellular evaluation results showed that SYSU-ID-01: could abrogate NM23-H2 binding to the c-MYC promoter, resulting in downregulation of c-MYC transcription and dramatically suppressed HeLa cell growth. These findings provide a new way of c-MYC transcriptional control through interfering with NM23-H2 binding to guanine-rich promoter sequences by small molecules.

Identification of a selective G-quadruplex DNA binder using a multistep virtual screening approach.

To efficiently identify small molecules binding to a G-quadruplex structure while avoiding binding to duplex DNA, we performed a multistep structure-based virtual screening by simultaneously taking into account G-quadruplex DNA and duplex DNA. Among the 13 compounds selected, one outstanding ligand shows significant selectivity for G-quadruplex binding as determined using SPR, FRET-based competition and luciferase activity assay.

3D-QSAR studies of azaoxoisoaporphine, oxoaporphine, and oxoisoaporphine derivatives as anti-AChE and anti-AD agents by the CoMFA method.

In the present study, a series of novel azaoxoisoaporphine derivatives were reported and their inhibitory activities toward acetylcholinesterase (AChE), butyrylcholinesterase (BuChE), and Aß aggregation were evaluated. The new compounds remained high inhibitory potency on Aß aggregation, with inhibitory activity from 29.42% to 89.63% at a concentration of 10µM, but had no action on AChE or BuChE, which was very different from our previously reported oxoaporphine and oxoisoaporphine derivatives. By 3D-QSAR studies, we constructed a reliable CoMFA model (q(2)=0.856 and r(2)=0.986) based on the inhibitory activities toward AChE and discovered key information on structure and anti-AChE activities among the azaoxoisoaporphine, oxoaporphine, and oxoisoaporphine derivatives. The model was further confirmed by the test-set validation (q(2)=0.873, r(2)=0.937, and slope k=0.902) and Y-randomization examination. The statistically significant and physically meaningful 3D-QSAR/CoMFA model provided better insight into understanding the inhibitory behaviors of those chemicals, which may provide useful information for the rational molecular design of azaoxoisoaporphine derivatives anti-AChE and anti-AD agents.

Stabilization of G-quadruplex DNA by C-5-methyl-cytosine in bcl-2 promoter: implications for epigenetic regulation.

The C-5-methylation of cytosine in the CpG islands is an important pattern for epigenetic modification of gene, which plays a key role in regulating gene transcription. G-quadruplex is an unusual DNA secondary structure formed in G-rich regions and is identified as a transcription repressor in some oncogenes, such as c-myc and bcl-2. In the present study, the results from CD spectrum and FRET assay showed that the methylation of cytosine in the CpG islands could induce a conformational change of the G-quadruplex in the P1 promoter of bcl-2, and greatly increase the thermal-stability of this DNA oligomer. Moreover, the methylation of cytosine in the G-quadruplex could protect the structure from the disruption by the complementary strand, showing with the increasing ability to arrest the polymerase in PCR stop assay. This data indicated that the stabilization of the G-quadruplex structure in the CpG islands might be involved in the epigenetical transcriptional regulation for specific genes through the C-5-methylation modification pattern.

2-(2-indolyl-)-4(3H)-quinazolines derivates as new inhibitors of AChE: design, synthesis, biological evaluation and molecular modelling.

We recently reported that synthetic derivatives of rutaecarpine alkaloid exhibited high acetyl cholinesterase (AChE) inhibitory activity and high selectivity for AChE over butyrylcholinesterases (BuChE). To explore novel effective drugs for the treatment of Alzheimer's disease (AD), in this paper, further research results were presented. Starting from a structure-based drug design, a series of novel 2-(2-indolyl-)-4(3H)-quinazolines derivates were designed and synthesized as the ring-opened analogues of rutaecarpine alkaloid and subjected to pharmacological evaluation as AChE inhibitors. Among them, derivates 3a-c and 3g-h exhibited strong inhibitory activity for AChE and high selectivity for AChE over BuChE. The structure-activity relationships were discussed and their binding conformation and simultaneous interactions mode were further clarified by kinetic characterization and the molecular docking studies.

Synthesis and Evaluation of Quinazolone Derivatives as a New Class of c-KIT G-Quadruplex Binding Ligands.

The c-KIT G-quadruplex structures are a novel class of attractive targets for the treatment of gastrointestinal stromal tumor (GIST). Herein, a series of new quinazolone derivatives with the expansion of unfused aromatic ring system were designed and synthesized. Subsequent biophysical studies demonstrated that the derivatives with adaptive scaffold could effectively bind to and stabilize c-KIT G-quadruplexes with good selectivity against duplex DNA. More importantly, these ligands further inhibited the transcription and expression of c-KIT gene and exhibited significant cytotoxicity on the GIST cell line HGC-27. Overall, these quinazolone derivatives represent a new class of promising c-KIT G-quadruplex ligands. The experimental results have also reinforced the idea of inhibition of c-KIT expression through targeting c-KIT G-quadruplex DNA.

New insights from molecular dynamic simulation studies of the multiple binding modes of a ligand with G-quadruplex DNA.

G-quadruplexes are higher-order DNA and RNA structures formed from guanine-rich sequences. These structures have recently emerged as a new class of potential molecular targets for anticancer drugs. An understanding of the three-dimensional interactions between small molecular ligands and their G-quadruplex targets in solution is crucial for rational drug design and the effective optimization of G-quadruplex ligands. Thus far, rational ligand design has been focused mainly on the G-quartet platform. It should be noted that small molecules can also bind to loop nucleotides, as observed in crystallography studies. Hence, it would be interesting to elucidate the mechanism underlying how ligands in distinct binding modes influence the flexibility of G-quadruplex. In the present study, based on a crystal structure analysis, the models of a tetra-substituted naphthalene diimide ligand bound to a telomeric G-quadruplex with different modes were built and simulated with a molecular dynamics simulation method. Based on a series of computational analyses, the structures, dynamics, and interactions of ligand-quadruplex complexes were studied. Our results suggest that the binding of the ligand to the loop is viable in aqueous solutions but dependent on the particular arrangement of the loop. The binding of the ligand to the loop enhances the flexibility of the G-quadruplex, while the binding of the ligand simultaneously to both the quartet and the loop diminishes its flexibility. These results add to our understanding of the effect of a ligand with different binding modes on G-quadruplex flexibility. Such an understanding will aid in the rational design of more selective and effective G-quadruplex binding ligands.

Development of a universal colorimetric indicator for G-quadruplex structures by the fusion of thiazole orange and isaindigotone skeleton.

The rapid and convenient method for identification of all kinds of G-quadruplex is highly desirable. In the present study, a novel colorimetric indicator for a vast variety of G-quadruplex was designed and synthesized on the basis of thiazole orange and isaindigotone skeleton. Its distinct color change enables label-free visual detection of G-quadruplexes, which is due to the disassembly of dye H-aggregates to monomers. This specific detection of G-quadruplex arises from its end-stacking interaction with G-quartet. On the basis of this universal indicator, a facile approach for large-scale identification of G-quadruplex was developed.

Design, synthesis and evaluation of isaindigotone derivatives as dual inhibitors for acetylcholinesterase and amyloid beta aggregation.

A series of isaindigotone derivatives and analogues were designed, synthesized and evaluated as dual inhibitors of cholinesterases (ChEs) and self-induced ß-amyloid (Aß) aggregation. The synthetic compounds had IC(50) values at micro or nano molar range for cholinesterase inhibition, and some compounds exhibited strong inhibitory activity for AChE and high selectivity for AChE over BuChE, which were much better than the isaindigotone derivatives previously reported by our group. Most of these compounds showed higher self-induced Aß aggregation inhibitory activity than a reference compound curcumin. The structure-activity relationship studies revealed that the derivatives with higher inhibition activity on AChE also showed higher selectivity for AChE over BuChE. Compound 6c exhibiting excellent inhibition for both AChE and self-induced Aß aggregation was further studied using CD, EM, molecular docking and kinetics.

Impact of planarity of unfused aromatic molecules on G-quadruplex binding: learning from isaindigotone derivatives.

G-quadruplex structures are a new class of attractive targets for DNA-interactive anticancer agents. The primary building block of this structure is the G-quartet, which is composed of four coplanar guanines and serves as the major binding site for small molecules. NMR studies and molecular dynamics simulations have suggested that the planarity of G-quartet surface has been highly dynamic in solution. To better investigate how the planarity of unfused aromatic ligand impacts on its quadruplex binding properties, a variety of planarity controllable isaindigotone derivatives were designed and synthesized. The interaction of G-quadruplex DNA with these designed ligands was systematically explored using a series of biophysical studies. The FRET-melting, SPR, and CD spectroscopy results showed that reducing the planarity of their unfused aromatic core resulted in their decreased binding affinity and stabilization ability for G-quadruplex. NMR studies also suggested that these compounds could stack on the G-quartet surface. Such results are in parallel with subsequent molecular modeling studies. A detailed binding energy analysis indicated that van der Waals energy (ΔE(vdw)) and entropy (TΔS) are responsible for their decreased quadruplex binding and stabilization effect. All these results provided insight information about how quadruplex recognition could be controlled by adjusting the planarity of ligands, which shed light on further development of unfused aromatic molecules as optimal G-quadruplex binding ligands.

Inhibition of cell proliferation by quindoline derivative (SYUIQ-05) through its preferential interaction with c-myc promoter G-quadruplex.

G-Quadruplex is a special DNA secondary structure and present in many important regulatory regions in human genome, such as the telomeric end and the promoters of some oncogenes. Specially, different forms of G-quadruplexes exist in telomeric DNA and c-myc promoter and play important roles in the pathway of cell proliferation and senescence. The effects of G-quadruplex ligands for either telomeric or c-myc G-quadruplex in vitro have been widely studied, but the specificity of these effects in vivo is still unknown. In the present research, various experiments were carried out to study the effect of G-quadruplex ligand SYUIQ-05 on tumor cell lines and the mechanism of this effect. Our results showed that it preferred to bind with G-quadruplex in c-myc and had rather insignificant effect on G-quadruplex in telomere. Therefore, it is possible that this compound had its antitumor activity for cancer cells mainly through its interaction with c-myc quadruplex.

Disubstituted 2-phenyl-benzopyranopyrimidine derivatives as a new type of highly selective ligands for telomeric G-quadruplex DNA.

A series of 2-phenyl-benzopyranopyrimidine (PBPP) derivatives with alkylamino side chains were synthesized and found to be a new type of highly selective ligand to bind with telomeric G-quadruplex DNA, and their biological properties were reported for the first time. Their interactions with telomeric G-quadruplex DNA were studied with FRET melting, surface plasmon resonance, CD spectroscopy, and molecular modeling. Our results showed that the disubstituted PBPP derivatives could strongly bind to and effectively stabilize the telomeric G-quadruplex structure, and had significant selectivity for G-quadruplex over duplex DNA. In comparison, the mono substituted derivatives had much less effect on the G-quadruplex, suggesting that the disubstitution of PBPP is essential for its interaction with the G-quadruplex. Furthermore, telomerase inhibition of the PBPP derivatives and their cellular effects were studied, and compound 11b was found to be the most promising compound as a telomerase inhibitor and telomeric G-quadruplex binding ligand for further development for cancer treatment.

Quinolino-benzo-[5, 6]-dihydroisoquindolium compounds derived from berberine: a new class of highly selective ligands for G-quadruplex DNA in c-myc oncogene.

A series of quinolino-benzo-[5, 6]-dihydroisoquindolium compounds (3a, 3f, 3g, and 3j) derived from alkaloid berberine were designed and synthesized as novel G-quadruplex ligands. Subsequent biophysical and biochemical evaluation demonstrated that the addition of pyridine ring and amino group into berberine improved the binding ability and selectivity towards G-quadruplex DNA in comparison with the previously reported 9-N-substituted berberine derivatives. Furthermore, qRT-PCR assay showed compound 3j led the down-regulation of c-myc gene transcription in leukemia cell line HL60, while little effect on normal cell line ECV-304, which was consistent with the behavior of an effective G-quadruplex ligand targeting c-myc oncogene.

Studies on the binding of 5-N-methylated quindoline derivative to human telomeric G-quadruplex.

Quindoline derivatives as telomeric quadruplex ligands have shown good biological activity for telomerase inhibition. In the present study, we used spectroscopic and calorimetric methods to investigate the interactions between a quindoline derivative (5-methyl-11-(2-morpholinoethylamino)-10-H-indolo-[3,2-b]quinolin-5-ium iodide, compound 1) and human telomeric G-quadruplex. The thermodynamic studies using isothermal titration calorimetry (ITC) indicated that their binding process was temperature-dependent and enthalpy-entropy co-driven. The significant negative heat capacity was obtained experimentally from the temperature dependence of enthalpy changes, which was consistent with that from theoretical calculation, and all suggesting significant hydrophobic contribution to the molecular recognition process. Based on the results from UV-vis, ITC, steady-state and time-resolved fluorescence, their binding mode was determined as two ligand molecules stacking on the quartets on both ends of the quadruplex. These results shed light on rational design and development of quindoline derivatives as G-quadruplex binding ligands.

New insights into the structures of ligand-quadruplex complexes from molecular dynamics simulations.

G-quadruplexes are higher-order DNA and RNA structures formed from guanine-rich sequences, and they are attractive anticancer drug targets. Understanding the three-dimensional interactions between a G-quadruplex and its ligand in solution is the key to discovering a drug lead. Hence, from crystallographic or NMR structures, molecular dynamics studies have been performed on six ligand-quadruplex complexes. BRACO-19, BSU6039, daunomycin, RHPS4, MMQ1, and TMPyP4 are the six ligands that bind to the G-quadruplex structures in the studies. Based on molecular dynamics simulations and a series of computational analyses, the results suggest that ions move away from the external G-quartet to let the ligand bind to the quadruplex in aqueous solution. The ligand binding can increase the stability of the Hoogseen hydrogen bonds within the G-quartet. However, the G-quartet binding site can only fit one ligand molecule. The ligand can form hydrogen bonds at the loop or flank of the quadruplex. However, not all the interactions will stabilize the ligand-quadruplex complex in aqueous solution. These findings can assist in the design of selective and potent G-quadruplex ligands.