核酸G-四链体的识别、复合物结构与细胞内探测的研究进展

富含鸟嘌呤的DNA或RNA序列可以折叠成非典型G-四链体二级结构. G-四链体结构丰富多样,在生物体内动态存在,参与了转录、复制、基因组稳定性和表观遗传调控等关键的基因组功能,与癌症生物学密切相关. G-四链体的结构与功能机制研究促进了以G-四链体为靶点的肿瘤治疗干预.本文综合评述了核酸G-四链体的特异性识别、细胞内探测及生物学功能的调控,总结了识别靶向G-四链体的小分子及复合物结构的研究进展,讨论了以G-四链体为靶点的靶向干预及疾病治疗的可能性,最后展望了G-四链体未来研究所面临的挑战与机遇.     

以G-四链体为靶点的小分子端粒酶抑制剂研究进展

富含鸟嘌呤碱基的DNA序列能够通过鸟嘌呤环的互联作用形成四链螺旋结构,这种结构被称为G-四链体。G-四链体由于能够抑制端粒酶的活性而成为抗肿瘤药物的新靶点,能促使G-四链体形成或稳定该结构的物质则可能对癌症有潜在的治疗意义。本文对以G-四链体为靶点的小分子端粒酶抑制剂的研究进行了综述。     

原癌基因c-myc启动区G-四链体结构及靶向小分子配体*

随着DNA G-四链体结构的发现和现代分子生物学技术对其与癌症关系的揭示,DNA G-四链体逐渐成为抗肿瘤药物研究的新靶点。c-myc启动区 G-四链体由于在细胞生长、增殖、凋亡、衰老及肿瘤形成等过程中的重要作用,成为DNA G-四链体中最受关注的序列之一。本文旨在对c-myc启动区 G-四链体的结构及靶向c-myc G-四链体的小分子配体的研究进展进行综述。首先,介绍c-myc G-四链体的生物学意义;其次,对几种常用的c-myc G-四链体的结构进行解析;最后,对以c-myc为靶点的小分子配体的研究进展及其与G-四链体的作用模式进行综述,并对目前以c-myc G-四链体为靶点、已经走向临床实验的CX-3543的开发与作用机制进行介绍。     

DNA G-四链体识别探针研究进展

G-四链体是一种由富含鸟嘌呤核酸序列形成的独特的二级结构,广泛分布于真核生物基因组,如端粒DNA、r DNA和一系列基因中的启动子区域。G-四链体结构对很多重要的生理过程如基因的转录、复制、重组以及保持染色体的稳定性方面具有重要作用。G-四链体的特异、高灵敏检测将为进一步了解G-四链体结构在人类细胞基因组中的分布、功能和机制奠定基础,也可能为靶向G-四链体的肿瘤治疗方法提供新的思路。因而过去几十年人们一直致力于开发设计具有高选择性和高灵敏度的G-四链体识别探针,这些探针已经广泛应用于溶液中G-四链体的识别,而且具有良好的选择性。目前也有少数探针能够直接用于检测活体G-四链体结构。本文综述了一些常见的靶向G-四链体的小分子配体,以及它们在染色体和活体细胞G-四链体检测中的应用。笔者希冀本文能为设计识别G-四链体的高性能探针,进一步实现活细胞内G-四链体的检测提供借鉴。     

无标记筛选G-四链体小分子配体的荧光新方法

能够诱导端粒DNA(GDNA)形成G-四链体结构的小分子化合物具有重大的抗肿瘤意义。本文以天然抗肿瘤药物槲皮素为研究对象,基于N-甲基卟啉二丙酸Ⅸ(NMM)与G-四链体的特异性结合,以及配体加入NMM/GDNA体系前后荧光强度的变化,建立了一种简单快速、无需标记筛选G-四链体配体的新方法,并应用该方法考察了黄酮类化合物、生物碱类和有机酸类化合物对NMM/GDNA体系的影响。结果显示黄酮类化合物容易诱导端粒DNA形成G-四链体结构,而生物碱类和有机酸等比较困难。     

G-四链体的构型、热稳定性测试及其在钾离子定量检测中的应用

G-四链体是由具有连续鸟嘌呤(G)序列的DNA或RNA形成的一种特殊的核酸二级结构,由于有望形成G-四链体结构的序列广泛地分布于人类基因组的许多重要区域,有关G-四链体的研究已经成为国际上的一个研究热点。本文对G-四链体构型的多态性、G-四链体热稳定性的测试手段及G-四链体在K+定量检测方面的应用研究进行了简单的介绍和评述。     

原癌基因c-myc G-四链体配体甲基蓝衍生物的设计、合成及其活性研究

采用计算机辅助药物设计方法,将以甲基蓝为先导化合物设计的配体分子与端粒DNA、原癌基因cmyc、c-kit2等形成的G-四链体三维结构进行分子对接模拟,发现目标化合物选择性靶向c-myc G-四链体,其对接分值为7.74。以吩噻嗪为起始原料合成出目标化合物,其结构经~1H-NMR、~(13)C-NMR和HRMS等确证。采用圆二色光谱实验测试了化合物与端粒、原癌基因c-myc和c-kit2等DNA的相互作用,结果表明目标化合物选择性诱导c-myc DNA形成G-四链体。     

用结晶紫为荧光指示剂筛选G-四链体的小分子配体

基于结晶紫(CV)与G-四链体的特异性结合以及结晶紫和端粒DNA(G-DNA)、G-四链体作用后荧光强度的差异,以天然抗肿瘤中药槲皮素为研究对象,建立了一种简单、快速、无标记筛选G-四链体配体的方法。研究了槲皮素与G-DNA的相互作用,并考察了G-DNA在K+存在下形成G-四链体后与槲皮素的作用情况。该方法已用于筛选G-四链体的小分子配体。     

Loop长度对G-四链体DNA识别和结合肿瘤细胞的能力的影响

G-四链体是由富含鸟嘌呤(G)的核酸通过π-π堆积形成的核酸二级结构。前期研究发现,G-四链体DNA对肿瘤细胞具有普遍识别和结合能力,且具有如抗肿瘤增殖等生物学活性,但G-四链体DNA的结构对其识别和结合肿瘤细胞的能力的影响还未见报道。本文采用圆二色光谱和凝胶电泳对不同连接环(loop)长度G-四链体DNA的结构和稳定性进行了研究,利用流式细胞术和激光共聚焦显微成像技术,研究了G-四链体DNA的连接环(loop)长度在其与肿瘤细胞结合中的作用。结果表明,loop长度越短的G-四链体DNA越易形成平行结构,识别和结合肿瘤细胞的能力越强,也更容易被细胞摄取;loop长度长的G-四链体DNA倾向于形成混合平行结构,这类G-四链体DNA识别和结合肿瘤细胞的能力较弱。     

利用对G-四链体环部的构型调节进行传感器的设计

对鸟嘌呤碱基G重复序列之间连接环结构对G-四链体形成的影响进行了研究。发现在连接环较长,DNA链不易形成G-四链体的情况下,可以通过将环序列设计成双链结构的方式促进G-四链体的重新形成。这就为传感器的设计提供了一个新途径,即可以利用目标分子对环部双链的调节作用控制G-四链体DNA酶的活性。为证明这一点,在双链区域引入T-T碱基错配,破坏双链结构使DNA链不能形成G-四链体。Hg2+对T-T错配的稳定作用可以促进双链结构的形成,DNA链重新折叠成G-四链体,得到的G-四链体与氯化血红素(Hemin)结合后形成具有过氧化物酶活性的G-四链体DNA酶,据此构建了Hg2+传感器。利用此传感器可在10~700 nmol/L范围内实现Hg2+的定量检测,检出限为8.7 nmol/L。在此基础上,利用半胱氨酸可以将Hg2+从T-Hg2+-T碱基对上竞争下来的能力,设计了一种半胱氨酸的检测方法。此方法可以在20~600 nmol/L范围内实现半胱氨酸的定量检测,检出限为14 nmol/L。     

Ligand Design to Acquire Specificity to Intended G-Quadruplex Structures

A G-quadruplex is a nucleic acid secondary structure that is adopted by guanine-rich sequences, and is considered to be relevant in various pharmacological and biological contexts. G-Quadruplexes have also attracted great attention in the field of DNA nanotechnology because of their extremely high thermal stability and the availability of many defined structures. To date, a large repertory of DNA/RNA G-quadruplex-interactive ligands has been developed by numerous laboratories. Several relevant reviews have also been published that have helped researchers to grasp the full scope of G-quadruplex research from its outset to the present. This review focuses on the G-quadruplex ligands that allow targeting of specific G-quadruplexes. Moreover, unique ligands, successful methodologies, and future perspectives in relation to specific G-quadruplex recognition are also addressed.     

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.     

Methods for investigating G-quadruplex DNA/ligand interactions

DNA is considered an important target for drug design and development. Until recently, the focus was on double-stranded (duplex) DNA structures. However, it has now been shown that single stranded DNA can fold into hairpin, triplex, i-motif and G-quadruplex structures. The more interesting G-quadruplex DNA structures comprise four strands of stacked guanine (G)-tetrads formed by the coplanar arrangement of four guanines, held together by Hoogsteen bonds. The DNA sequences with potential to form G-quadruplex structures are found at the chromosomal extremities (i.e. the telomeres) and also at the intra-chromosomal region (i.e. oncogenic promoters) in several important oncogenes. The formation of G-quadruplex structures is considered to have important consequences at the cellular level and such structures have been evoked in the control of expression of certain genes involved in carcinogenesis (c-myc, c-kit, K-ras etc.) as well as in the perturbation of telomeric organization. It has been shown that the formation of quadruplexes inhibits the telomere extension by the telomerase enzyme, which is up-regulated in cancer cells. Therefore, G-quadruplex structures are an important target for drug design and development and there is a huge interest in design and development of small molecules (ligands) to target these structures. A large number of so-called G-quadruplex ligands, displaying varying degrees of affinity and more importantly selectivity (i.e. the ability to interact only with quadruplex-DNA and not duplex-DNA), have been reported. Access to efficient and robust in vitro assays is needed to effectively monitor and quantify the G-quadruplex DNA/ligand interactions. This tutorial review provides an overview of G-quadruplex ligands and biophysical techniques available to monitor such interactions.     

The application of DNA and RNA G-quadruplexes to therapeutic medicines

The intriguing structural diversity in folded topologies available to guanine-rich nucleic acid repeat sequences have made four-stranded G-quadruplex structures the focus of both basic and applied research, from cancer biology and novel therapeutics through to nanoelectronics. Distributed widely in the human genome as targets for regulating gene expression and chromosomal maintenance, they offer unique avenues for future cancer drug development. In particular, the recent advances in chemical and structural biology have enabled the construction of bespoke selective DNA based aptamers to be used as novel therapeutic agents and access to detailed structural models for structure based drug discovery. In this critical review, we will explore the important underlying characteristics of G-quadruplexes that make them functional, stable, and predictable nanoscaffolds. We will review the current structural database of folding topologies, molecular interfaces and novel interaction surfaces, with a consideration to their future exploitation in drug discovery, molecular biology, supermolecular assembly and aptamer design. In recent years the number of potential applications for G-quadruplex motifs has rapidly grown, so in this review we aim to explore the many future challenges and highlight where possible successes may lie. We will highlight the similarities and differences between DNA and RNA folded G-quadruplexes in terms of stability, distribution, and exploitability as small molecule targets. Finally, we will provide a detailed review of basic G-quadruplex geometry, experimental tools used, and a critical evaluation of the application of high-resolution structural biology and its ability to provide meaningful and valid models for future applications (255 references).     

Platinum(II)-Based Optical Probes for Imaging Quadruplex DNA Structures via Phosphorescence Lifetime Imaging Microscopy

G-quadruplex DNA is a non-canonical structure that forms in guanine-rich regions of the genome. There is increasing evidence showing that G-quadruplexes have important biological functions, and therefore molecular tools to visualise these structures are important. Herein we report on a series of new cyclometallated platinum(II) complexes which, upon binding to G-quadruplex DNA, display an increase in their phosphorescence, acting as switch-on probes. More importantly, upon binding to G-quadruplexes they display a selective and distinct lengthening of their emission lifetime. We show that this effect can be used to selectively visualise these structures in cells using Phosphorescence Lifetime Imaging Microscopy (PLIM).     

Structural basis for telomeric G-quadruplex targeting by naphthalene diimide ligands

The folding of the single-stranded 3' end of the human telomere into G-quadruplex arrangements inhibits the overhang from hybridizing with the RNA template of telomerase and halts telomere maintenance in cancer cells. The ability to thermally stabilize human telomeric DNA as a four-stranded G-quadruplex structure by developing selective small molecule compounds is a therapeutic path to regulating telomerase activity and thereby selectively inhibit cancer cell growth. The development of compounds with the necessary selectivity and affinity to target parallel-stranded G-quadruplex structures has proved particularly challenging to date, relying heavily upon limited structural data. We report here on a structure-based approach to the design of quadruplex-binding ligands to enhance affinity and selectivity for human telomeric DNA. Crystal structures have been determined of complexes between a 22-mer intramolecular human telomeric quadruplex and two potent tetra-substituted naphthalene diimide compounds, functionalized with positively charged N-methyl-piperazine side-chains. These compounds promote parallel-stranded quadruplex topology, binding exclusively to the 3' surface of each quadruplex. There are significant differences between the complexes in terms of ligand mobility and in the interactions with quadruplex grooves. One of the two ligands is markedly less mobile in the crystal complex and is more quadruplex-stabilizing, forming multiple electrostatic/hydrogen bond contacts with quadruplex phosphate groups. The data presented here provides a structural rationale for the biophysical (effects on quadruplex thermal stabilization) and biological data (inhibition of proliferation in cancer cell lines and evidence of in vivo antitumor activity) on compounds in this series and, thus, for the concept of telomere targeting with DNA quadruplex-binding small molecules.     

Natural products and their derivatives as G-quadruplex binding ligands

G-quadruplexes comprise a class of secondary structures that are formed in guanine-rich sequences in eukaryotic genomes and play a crucial role in the regulation of many biological events. G-quadruplexes have become targets for anticancer drugs with high selectivity vs. duplex DNA and low cytotoxicity against normal cells. Natural products and their derivatives display polymorphism, structural complexity, and potent activity. It is, therefore, reasonable to seek ligands targeting G-quadruplexes from natural products. Recently, many successful examples have been reported, showing ligands with excellent anticancer activities. In this review, we summarized the development of research on natural products and derivatives that target G-quadruplex structures in an effort to guide future studies.     

Analytical potential of the quadruplex DNA-based FRET probes

DNA exhibits structural flexibility and may adopt also tetraplex structures known as guanine-quadruplexes or G-quadruplexes. These G-quadruplexes have recently received great attention because G-rich sequences are often found in genome and because of their potential links to mechanisms that relate to cancer, HIV, and other diseases. The unique structure of quadruplexes has also stimulated development of new analytical and bioanalytical assays based on fluorescence resonance energy transfer (FRET). Intramolecular folding of a flexible single-stranded DNA molecule into a compact G-quadruplex is a structural transition leading to closer proximity of its 5'- and 3'-ends. Thus, labeling both ends of a DNA strand with donor and acceptor fluorophores enables monitoring the quadruplex formation process by means of the FRET signal. This review shows how FRET technique contributes to G-quadruplex research and focuses mainly on analytical applications of FRET-labeled quadruplexes. Applications include studies of structural transitions of quadruplexes, FRET-based selection of ligands that bind to quadruplexes, design of molecular probes for protein recognition and development of sensors for detection of potassium ions in aqueous solution.     

Selective G-quadruplex DNA stabilizing agents based on bisquinolinium and bispyridinium derivatives of 1,8-naphthyridine

Various biologically relevant G-quadruplex DNA structures offer a platform for therapeutic intervention for altering the gene expression or by halting the function of proteins associated with telomeres. One of the prominent strategies to explore the therapeutic potential of quadruplex DNA structures is by stabilizing them with small molecule ligands. Here we report the synthesis of bisquinolinium and bispyridinium derivatives of 1,8-naphthyridine and their interaction with human telomeric DNA and promoter G-quadruplex forming DNAs. The interactions of ligands with quadruplex forming DNAs were studied by various biophysical, biochemical, and computational methods. Results indicated that bisquinolinium ligands bind tightly and selectively to quadruplex DNAs at low ligand concentration (～0.2-0.4 μM). Furthermore, thermal melting studies revealed that ligands imparted higher stabilization for quadruplex DNA (an increase in the T(m) of up to 21 °C for human telomeric G-quadruplex DNA and >25 °C for promoter G-quadruplex DNAs) than duplex DNA (ΔT(m) ≤ 1.6 °C). Molecular dynamics simulations revealed that the end-stacking binding mode was favored for ligands with low binding free energy. Taken together, the results indicate that the naphthyridine-based ligands with quinolinium and pyridinium side chains form a promising class of quadruplex DNA stabilizing agents having high selectivity for quadruplex DNA structures over duplex DNA structures.     

Bioactive papaverine derivatives bind G-quadruplexes selectively

G-quadruplexes are a family of DNA secondary structures resulting from the folding of a guanine-rich sequence. Targeting quadruplexes by small molecules is an approach that is currently being studied with the aim of exploring their biological roles and developing new anti-cancer agents. There is evidence that the formation of G4 structures by telomeric DNA can be used to inhibit the enzyme activity of telomerase, and thereby to activate the pathway to senescence in tumour cells. It was previously shown that the papaverine oxidation products 6a,12a-diazadibenzo-[a,g]fluorenylium derivative (ligand I) and 2,3,9,10-tetramethoxy-12-oxo-12H-indolo[2,1-a]isoquinolinium chloride (ligand II) bind to G-quadruplex representing the human telomeric sequence. These ligands possess the ability to inhibit telomerase and polymerase action at the micromolar level. Here we report a DNA binding study on these two ligands and a new derivative 2-(2-carboxy-4,5-dimethoxyphenyl0-6,7-dimethoxyisoquiloliniuminner salt (ligand III) in order to evaluate their binding selectivity to samples of nucleic acids (ssDNA, dsDNA, triplexes, and quadruplexes). Simultaneous investigations on several DNA-ligand complexes carried out using an equilibrium dialysis approach revealed pronounced binding selectivity of ligand I and ligand II to tetraplex DNA structures over the doublestranded DNA forms.