Benzothiazole-substituted benzofuroquinolinium dye: a selective switch-on fluorescent probe for G-quadruplex

A new switch-on fluorescent probe containing the natural product cryptolepine analogue benzofuroquinolinium moiety (binding scaffold) and a benzothiazole moiety (signalling unit) shows a remarkable fluorescence enhancement selective for the G-quadruplex nucleic acid structure. Binding studies revealed that the highly selective response of the fluorescent probe arises from end-stack binding to G-quadruplex.     

Synthesis and evaluation of 10-(3,5-dimethoxy)benzyl-9(10H)-acridone derivatives as selective telomeric G-quadruplex DNA ligands

A class of 9(10H)-acridone derivatives with terminal ammonium substituents at C2 (and C7) position(s) on the acridone ring were successfully synthesized. The relative affinities of the acridone compounds to G-quadruplex DNA have been investigated and the results showed that these compounds had a binding specificity for G-quadruplex over duplex sequences. The acridones with two terminal ammonium substituents had much more effects on the human telomeric G-quadruplex DNA than the corresponding acridone derivatives with one terminal ammonium substituent, and more positive charges introduced to the side chains can improve the formation and stabilization of the G-quadruplex.     

Diarylethynyl amides that recognize the parallel conformation of genomic promoter DNA G-quadruplexes

We report bis-phenylethynyl amide derivatives as a potent G-quadruplex binding small molecule scaffold. The amide derivatives were efficiently prepared in 3 steps by employing Sonogashira coupling, ester hydrolysis and a chemoselective amide coupling. Ligand-quadruplex recognition has been evaluated using a fluorescence resonance energy transfer (FRET) melting assay, surface plasmon resonance (SPR), circular dichroism (CD) and (1)H nuclear magnetic resonance (NMR) spectroscopy. While most of the G-quadruplex ligands reported so far comprise a planar, aromatic core designed to stack on the terminal tetrads of a G-quadruplex, these compounds are neither polycyclic, nor macrocyclic and have free rotation around the triple bond enabling conformational flexibility. Such molecules show very good binding affinity, excellent quadruplex:duplex selectivity and also promising discrimination between intramolecular promoter quadruplexes. Our results indicate that the recognition of the c-kit2 quadruplex by these ligands is achieved through groove binding, which favors the formation of a parallel conformation.     

Synthesis and binding studies of novel diethynyl-pyridine amides with genomic promoter DNA G-quadruplexes

Herein, we report the design, synthesis and biophysical evaluation of novel 1,2,3-triazole-linked diethynyl-pyridine amides and trisubstituted diethynyl-pyridine amides as promising G-quadruplex binding ligands. We have used a Cu(I)-catalysed azide-alkyne cycloaddition click reaction to prepare the 1,2,3-triazole-linked diethynyl-pyridine amides. The G-quadruplex DNA binding properties of the ligands have been examined by using a F?rster resonance energy transfer (FRET) melting assay and surface plasmon resonance (SPR) experiments. The investigated compounds are conformationally flexible, having free rotation around the triple bond, and exhibit enhanced G-quadruplex binding stabilisation and specificity between intramolecular promoter G-quadruplex DNA motifs compared to the first generation of diaryl-ethynyl amides (J. Am. Chem. Soc. 2008, 130, 15950-15956). The ligands show versatility in molecular recognition and promising G-quadruplex discrimination with 2-50-fold selectivity exhibited between different intramolecular promoter G-quadruplexes. Circular dichroism (CD) spectroscopic analysis suggested that at higher concentration these ligands disrupt the c-kit2 G-quadruplex structure. The studies validate the design concept of the 1,3-diethynyl-pyridine-based scaffold and demonstrate that these ligands exhibit not only significant selectivity over duplex DNA but also variation in G-quadruplex interaction properties based on small chemical changes in the scaffold, leading to unprecedented differential recognition of different DNA G-quadruplex sequences.     

Phthalocyanines: a new class of G-quadruplex-ligands with many potential applications

A G-quadruplex is a four-stranded DNA structure featuring stacked guanine tetrads, G-quartets. Formation of a G-quadruplex in telomere DNA can inhibit telomerase activity; therefore, development of G-quadruplex-ligands, which induce and/or stabilize G-quadruplexes, has become an area of great interest. Phthalocyanine derivatives have substantial potential as high-affinity G-quadruplex-ligands because these planar chromophores are similar in size and shape to the G-quartets. Here, we focus on the latest findings on phthalocyanine derivatives as G-quadruplex-ligands, and discuss the mechanisms by which phthalocyanines bind to G-quadruplexes with high affinity and selectivity. We also discuss potential biomedical and organic electronic applications of phthalocyanines that are dependent on their photophysical properties.     

Synthesis of abasic locked nucleic acid and two seco-LNA derivatives and evaluation of their hybridization properties compared with their more flexible DNA counterparts

To investigate the structural basis of the unique hybridization properties of LNA (locked nucleic acid) three novel LNA derivatives with modified carbohydrate parts were synthesized and evaluated with respect to duplex stabilities. The abasic LNA monomer (X(L), Figure 1) with the rigid carbohydrate moiety of LNA but no nucleobase attached showed no enhanced duplex stabilities compared to its more flexible abasic DNA counterpart (X, Figure 1). These results suggest that the exceptional hybridization properties of LNA primarily originate from improved intrastrand nucleobase stacking and not backbone preorganization. Two monocyclic seco-LNA derivatives, obtained by cleavage of the C1'-O4' bond of an LNA monomer or complete removal of the O4'-furanose oxygen atom (Z(L) and dZ(L), respectively, Figure 1), were compared to their acyclic DNA counterpart (Z, Figure 1). Even though they are more constrained than Z, the seco-LNA derivatives Z(L) and dZ(L) destabilize duplex formation even more than the flexible seco-DNA monomer Z.     

高选择性端粒G-四链体稳定性配体:9-O-多胺取代小檗碱衍生物的合成及活性评价

设计合成了3个多胺取代的小檗碱衍生物5a~5c, 并利用圆二色(CD)光谱、 荧光共振能量转移(FRET)熔点实验、 荧光光谱和聚合酶链反应(PCR)终止实验等手段研究了小檗碱衍生物5a~5c与端粒DNA的相互作用. 结果表明, 小檗碱衍生物5a~5c可以诱导端粒DNA序列形成反平行结构G-四链体, 显著地提高了端粒G-四链体的稳定性, 有效地抑制了端粒的扩增; 而与双链DNA的相互作用则很小, 是高选择性的端粒G-四链体配体.     

Contribution of telomere G-quadruplex stabilization to the inhibition of telomerase-mediated telomere extension by chemical ligands

Inhibition of telomerase activity through stabilizing telomere G-quadruplex with small chemical ligands is emerging as a novel strategy for cancer therapy. For the large number of ligands that have been reported to inhibit telomerase activity, it is difficult to validate the contribution of G-quadruplex stabilization to the overall inhibition. Using a modified telomere repeat amplification protocol (TRAP) method to differentiate the telomere G-quadruplex independent effect from dependent ones, we analyzed several ligands that have high affinity and/or selectivity to telomere G-quadruplex. Our results show that these ligands effectively inhibited telomerase activity in the absence of telomere G-quadruplex. The expected G-quadruplex-dependent inhibition was only obvious for the cationic ligands at low K(+) concentration, but it dramatically decreased at physiological concentration of K(+). These observations demonstrate that the ligands are much more than G-quadruplex stabilizers with a strong G-quadruplex-irrelevant off-target effect. They inhibit telomerase via multiple pathways in which stabilization of telomere G-quadruplex may only make a minor or neglectable contribution under physiologically relevant conditions depending on the stability of telomere G-quadruplex under ligand-free conditions.     

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.     

Design, synthesis, and biological evaluation of novel spin-labeled derivatives of podophyllotoxin as potential antineoplastic agents. Part XII

Five novel nitroxyl spin-labeled ester derivatives of podophyllotoxin (11a-11e) have been prepared and their structural information on these nitroxyl spin-labeled ester derivatives of podophyllotoxin (11a-11e) using (1)HNMR spectroscopy was efficiently obtained by application of the in situ reduction of representative nitroxyl spin-labeled ester derivative of podophyllotoxin 11e with phenylhydrazine for the preparation of N-hydroxylamine 12 in the NMR tube. These novel derivatives were further evaluated for their in vitro cytotoxic activity against five neoplastic cell lines (K562, HL-60, SPCA-1, Lewis, and L-1210) using MTT assay. Most of the target compounds (except for all these compounds against SPCA-1) exhibited more pronounced cytotoxicity against several neoplastic cell lines than that of the prototypical inhibitor etoposide.     

Cationic metal-corrole complexes: design, synthesis, and properties of guanine-quadruplex stabilizers

A series of pyridinium and quaternary ammonium copper corroles has been designed and synthesized. All new compounds have been fully characterized by NMR spectroscopy, high-resolution mass spectrometry, UV/Vis spectrscopy, and elemental analysis. Biochemical studies have indicated that all of these corrole derivatives can stabilize G-quadruplex structures, with corrole 4 being the most effective according to the results of circular dichroism (CD) melting experiments, polymerase chain reaction (PCR) stop assays, and surface plasmon resonance (SPR) experiments. Moreover, both corroles 3 and 4 tend to induce the human telomeric sequence to form hybrid G-quadruplex structures, whereas corroles 8 and 9 are more inclined to induce the human telomeric sequence to form antiparallel G-quadruplex structures.     

咪唑修饰萘酰亚胺与DNA的作用及其细胞毒性

设计合成了咪唑及其烷基化咪唑阳离子基团修饰的萘酰亚胺衍生物。利用紫外-可见吸收光谱、荧光光谱、圆二色谱和荧光共振能量转移等方法研究了它们与小牛胸腺DNA(CT DNA)和G-四链体DNA的相互作用。这些化合物对端粒DNA序列的G-四链体有很高的结合能力(K_α4×10~6 L·mol~(-1)),并能够稳定G-四链体。DNA粘度实验结果表明萘酰亚胺衍生物与CT DNA通过插入作用结合。Autodock分子对接模拟结果表明这些化合物通过疏水作用、静电作用或氢键等方式与人体端粒G-四链体的loop和沟槽部分结合。咪唑阳离子基团修饰的萘酰亚胺衍生物4a–c能够定位于细胞核,对肺癌细胞的细胞毒性要高于咪唑基团修饰的萘酰亚胺衍生物3。化合物4a和4b对肺癌细胞A549的细胞毒性明显高于正常人胚肺成纤维细胞MRC-5,表现出良好的抗癌活性。     

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.     

Novel fluorene/fluorenone DNA and RNA binders as efficient non-toxic ds-RNA selective fluorescent probes

A series of structurally similar 1-substitued heteroaryl fluorene derivatives were prepared in a simple single step reaction, oxidized to fluorenones and then both, fluorenes and fluorenones, were methylated to enhance the solubility and increase the affinity to DNA/RNA. Interactions of both, fluorene and fluorenone analogues with various ds-DNA, ds-RNA revealed strong ds-DNA/RNA binding, and various thermal stabilization effects. Most intriguingly, some fluorene derivatives showed opposite fluorescence change (increase for ds-RNA and decrease for ds-DNA), which was not previously reported for any fluorene analogue. CD experiments along with other methods support ds-DNA minor groove binding and major groove ds-RNA binding. All compounds showed negligible interaction with G-quadruplex DNA. Very low cell cytotoxicity of studied compounds combined with very efficient cellular uptake makes these fluorescent dyes safe for laboratory applications. Moreover, especially compounds which show opposite fluorescence response to ds-DNA and ds-RNA, are promising lead compounds for further studies aimed toward ds-RNA-specific fluorescence markers.     

A hitchhiker's guide to G-quadruplex ligands

Over the past decade, nucleic acid chemists have seen the spectacular emergence of molecules designed to interact efficiently and selectively with a peculiar DNA structure named G-quadruplex. Initially derived from classical DNA intercalators, these G-quadruplex ligands progressively became the focal point of new excitement since they appear to inhibit selectively the growth of cancer cells thereby opening interesting perspectives towards the development of novel anti-cancer drugs. The present article aims to help researchers enter this exciting research field, and to highlight recent advances in the design of G-quadruplex ligands.     

苝二酰亚胺衍生物/三联吡啶铂配合物超分子在G-四链体检测中的应用

合成了3种三联吡啶铂(Ⅱ)配合物(Pt1、Pt2、Pt3)和两种苝二酰亚胺衍生物(PDI1、PDI2),构建了三联吡啶铂配合物/苝二酰亚胺衍生物超分子体系。所得超分子体系可作为"turn-on"型荧光传感器用于检测c-myc G-四链体。三联吡啶铂配合物可通过电子转移作用猝灭苝二酰亚胺的荧光,利用最小二乘法求得三联吡啶铂配合物与PDIs的结合常数为5.57×104~5.28×106 L/mol。加入G-四链体后,三联吡啶铂配合物/苝二酰亚胺超分子发生解离,苝二酰亚胺衍生物的荧光得到恢复。在Pt2/PDI2体系中加入1.5μmol/L c-myc G-四链体可使其荧光增强63倍。在c-myc的浓度为25nmol/L~1.0μmol/L范围内,Pt2/PDI2超分子体系荧光增强(F/F0)与c-myc的浓度呈良好的线性关系(R2=0.995),检测限为1.37nmol/L,表明Pt2/PDI2超分子体系可用于检测c-myc序列DNA。     

Telomestatin and diseleno sapphyrin bind selectively to two different forms of the human telomeric G-quadruplex structure

The human telomeric sequence d[T(2)AG(3)](4) has been demonstrated to form different types of G-quadruplex structures, depending upon the incubation conditions. For example, in sodium (Na(+)), a basket-type G-quadruplex structure is formed. In this investigation, using circular dichroism (CD), biosensor-surface plasmon resonance (SPR), and a polymerase stop assay, we have examined how the addition of different G-quadruplex-binding ligands affects the conformation of the telomeric G-quadruplex found in solution. The results show that while telomestatin binds preferentially to the basket-type G-quadruplex structure with a 2:1 stoichiometry, 5,10,15,20-[tetra-(N-methyl-3-pyridyl)]-26-28-diselena sapphyrin chloride (Se2SAP) binds to a different form with a 1:1 stoichiometry in potassium (K(+)). CD studies suggest that Se2SAP binds to a hybrid G-quadruplex that has strong parallel and antiparallel characteristics, suggestive of a structure containing both propeller and lateral, or edgewise, loops. Telomestatin is unique in that it can induce the formation of the basket-type G-quadruplex from a random coil human telomeric oligonucleotide, even in the absence of added monovalent cations such as K(+) or Na(+). In contrast, in the presence of K(+), Se2SAP was found to convert the preformed basket G-quadruplex to the hybrid structure. The significance of these results is that the presence of different ligands can determine the type of telomeric G-quadruplex structures formed in solution. Thus, the biochemical and biological consequences of binding of ligands to G-quadruplex structures found in telomeres and promoter regions of certain important oncogenes go beyond mere stabilization of these structures.