Screening chemical libraries for nucleic-acid-binding drugs by in vitro selection: A test case with lividomycin

Summary Screening new drugs is a costly and time-consuming process. Identifying new targets for existing therapeutics is often a particularly effective avenue for drug development. We have investigated whether in vitro selection can be used for target acquisition. Aminoglycoside antibiotics are known to bind to and inactivate functional natural nucleic acids, such as ribosomal RNA. As an example of how new targets for aminoglycosides could be identified, a lividomycin aptamer was iteratively isolated from a random sequence pool. The consensus sequence of this and other anti-aminoglycoside aptamers was used as the basis for a comprehensive search of natural sequence databases. Surprisingly, a high degree of similarity was found between aptamers and genomic sequences from a variety of organisms. While many of the similarities found are in regions of unknown or nonessential function, some of the sequences are found in critical genes in pathogenic organisms.     

The limits of specificity: An experimental analysis with RNA aptamers to MS2 coat protein variants

It has been hypothesized that selections for aptamers with high affinity for a given target molecule will of necessity identify aptamers that have high specificity for that target. We have attempted to assess this hypothesis by selecting aptamers that can bind to MS2 coat protein or to single- or double-substitution variants of the coat protein. Some aptamers selected to bind MS2 coat protein or its variants were mildly specific for their cognate targets, discriminating by two- to fourfold against closely related proteins. Specificity determinants on both the coat proteins and the aptamers could be identified. However, many aptamers could readily bind to each of the different coat proteins. The identification of such aptamer 'generalists belies the proposed relationship between the affinities and specificities of selected RNA ligands. These results imply that, while aptamers may not finely discriminate between closely related targets, neither will their binding be negated by mutations in targets. Aptamer pharmaceuticals may therefore better resist the evolution of resistance.     

基于功能性核酸识别的荧光各向异性分析方法与应用

荧光各向异性方法又称荧光偏振法,基于相互作用的分子结合前后发射光退偏振的不同而实现对相互作用的研究或对目标物的检测。20世纪50年代Gregorio Weber用荧光各向异性法研究了氮磺酰氯与牛血清白蛋白和卵清白蛋白的作用,开启了该方法在生物化学研究中应用的先河。而20世纪90年代开始的功能性核酸(FNAs,包括核酸适配体和核酸酶等)的发现与合成,使基于功能性核酸的传感得到了广泛的应用。核酸适配体能够特异性识别目标分子,基于核酸识别的荧光各向异性分析方法具有高选择性、高灵敏度、高通量等优势,在研究蛋白质、核酸和小分子的相互作用中起到重要作用,然而如何提高结合前后的荧光各向异性信号变化,尤其是小分子识别前后,在基于功能性核酸识别的分析方法发展中是一个挑战。介绍了基于功能性核酸识别的荧光各向异性的方法应用于检测蛋白质、核酸及其他在生命活动中起重要作用的小分子的基本原理及设计理念。     

核酸功能化纳米探针在细胞荧光成像中的应用

核酸是携带遗传信息的物质,既存在于自然界中也能够通过成熟技术人工合成。通过体外筛选技术还可以筛选出具有特殊功能的核酸序列,例如核酸适体和脱氧核酶。核酸通过沃森-克里克碱基互补配对原则进行杂交,具有很强的专一性。无论是通过序列设计还是体外筛选,核酸探针在生物标志物的分析与成像应用方面都发挥着重要作用。纳米材料辅助构建核酸功能化纳米探针,可以保护负载的核酸探针不被核酸酶降解,并且无需转染试剂就能进入细胞,在细胞荧光成像应用上具有很大优势。为解决细胞内有些生物标志物含量低、难于检测的问题,目前已构建多种适用于细胞水平的成像信号放大方法来实现对低丰度生物标志物的高灵敏成像。本文主要综述了核酸功能化纳米探针在细胞荧光成像中的应用进展,包括反义寡核苷酸功能化纳米探针、核酸适体功能化纳米探针、脱氧核酶功能化纳米探针等,同时介绍了他们在成像信号放大中的应用。     

核酸识体的研究及应用

核酸识体(aptamer)是近年来发展起来的一类经体外人工进化程序筛选出的寡聚核苷酸。它能高效、特异地结合各种配体，在蛋白质的分析检测、医学诊断治疗、生物传感器和分子开关的开发等方面有很大的应用前景，文章对核酸识体的研究和应用进展进行了综述。     

Aptamer-modified gold nanoparticles for targeting breast cancer cells through light scattering

In this study, we demonstrated the potential use of nucleic acid ligand (aptamers) conjugated gold nanoparticles (AuNPs) for cancer cell detection. Through specific binding of the aptamers toward platelet-derived growth factor (PDGF), MDA-MB-231 and Hs578T cells (cancer cells) that over-express PDGF, interact with Apt-AuNPs to a greater extent than do H184B5F5/M10 cells (normal cells). These results were confirmed through inductively coupled plasma mass spectrometry measurements of the gold ion concentrations within these cells. Aggregation of the Apt-AuNPs in the cytoplasm of the cancer cells led to the generation of an intense scattered light upon photo-illumination; this phenomenon allows the differentiation of cancer cells from normal cells using a dark field optical microscope. The presence of Apt-AuNPs suppressed the proliferation of MDA-MB-231 cancer cells, but not H184B5F5/M10 cells.     

核酸-甲基青莲6B分子作用体系的研究与应用

基于核酸对甲基青莲6B的减色效应,以阳离子型染料甲基青莲6B为生色探针,研究该染料与核酸的结合反应,建立了新的核酸测定体系,研究探讨了体系的作用机理。在pH＝9.0条件下,hs-DNA,sm-DNA, ct-DNA,yeast RNA的浓度与甲基青莲6B减色效应成线性关系,响应线性范围分别为0.50～4.00 μg·mL-1,0.20～5.00 μg·mL-1,0.20～5.00 μg·mL-1,0.20～4.50 μg·mL-1,检出限(3σ/K)分别为0.082,0.037,0.038,0.041 μg·mL-1。分析核酸合成样品,回收率为93.5%～105.0%。     

Nucleic acid hydration: a volumetric perspective

Hydration represents a major force governing the conformational preferences and drug binding properties of nucleic acids. Volumetric measurements have proven useful in characterizing the hydration properties of nucleic acid structures and their complexes with other molecules. In this paper, we present an overview of recent developments in the field of volumetric investigations of nucleic acids. We discuss, in particular, the volumetric properties of nucleic acids, their molecular components and analogs, conformational transitions of DNA and RNA, and drug–DNA interactions. We emphasize the importance of hydration as a major contributor to the energetics of molecular recognition. We also emphasize the need of expanding the field of volumetric characterizations of nucleic acid structures in an effort to gain further insight into the molecular origins of various nucleic acid recognition processes, including helix-to-coil and helix-to-helix conformational transitions, as well as drug–DNA and protein–DNA interactions.     

核酸与有机小分子反应机理的荧光特性研究

核酸与有机小分子的反应机理对认识核酸的结构与功能具有重要作用,也是揭示核酸的生物功能与一些药物的作用机制的重要途径。研究核酸与有机小分子之间的相互作用对生命过程的模拟和生命本质的探索具有十分重要的意义,并对近年来该领域采用的荧光光谱法进行了综述,从温度、双分子猝灭过程的速率常数、荧光寿命以及吸收光谱的变化等方面作了论述,从而确定了核酸与有机小分子(染料和药物)之间相互作用的荧光猝灭类型;总结了结合常数、荧光给体-受体间的作用距离、作用力类型及结合方式的多种求算方法,并分别阐述了核酸与染料及药物在不同结合数下生成常数的计算方法。这对研究核酸与有机小分子之间的作用机理、开发新的核酸探针以及以核酸为靶标的药物分子的设计有一定的指导意义。     

Using solid-state 31P{19F} REDOR NMR to measure distances between a trifluoromethyl group and a phosphodiester in nucleic acids

REDOR is a solid-state NMR technique frequently applied to biological structure problems. Through incorporation of phosphorothioate groups in the nucleic acid backbone and mono-fluorinated nucleotides, 31P{19F} REDOR has been used to study the binding of DNA to drugs and RNA to proteins through the detection of internuclear distances as large as 13-14 A. In this work, 31P{19F} REDOR is further refined for use in nucleic acids by the combined use of selective placement of phosphorothioate groups and the introduction of nucleotides containing trifluoromethyl (-CF3) groups. To ascertain the REDOR-detectable distance limit between an unique phosphorous spin and a trifluoromethyl group and to assess interference from intermolecular couplings, a series of model compounds and DNA dodecamers were synthesized each containing a unique phosphorous label and trifluoromethyl group or a single 19F nucleus. The dipolar coupling constants of the various 31P and 19F or -CF3 containing compounds were compared using experimental and theoretical dephasing curves involving several models for intermolecular interactions.     

The fluorescence of dye-nucleic acid complexes

Numerous fluorescent compounds, predominantly dyes, are able to form intermolecular complexes with deoxyribonucleic acid (DNA), ribonucleic acid (RNA), nucleoproteins, and various of their synthetic analogues. As a consequence of the binding, fluorescence spectroscopic data, i.e. quantum yield, decay time, and polarization properties, are altered as compared with the free dye. Fluorescence measurements are well suited to gain information on binding processes, steric location of the fluorescent ligands at the nucleic acid template, and energy transfer processes from the nucleic acid bases to complexed compounds. Moreover, conclusions on conformational structures in nucleic acids in vitro and in vivo can be drawn. Finally, they help to study the biological activity of various compounds on a molecular level, including problems involved in chromosomal fluorescence staining.     

Competitive FRET-Aptamer-Based Detection of Methylphosphonic Acid,a Common Nerve Agent Metabolite

Competitive fluorescence resonance energy transfer (FRET)-aptamer-based assay formats are described for one-step detection of methylphosphonic acid (MPA; a metabolite of several organophosphorus (OP) nerve agents). AminoMPA was attached to tosyl-magnetic beads and used for DNA aptamer selection from which one dominant aptamer sequence emerged. Two different FRET approaches were attempted. In one approach, the complementary DNA sequence was used as a template for labeling the aptamer with Alexa Fluor 546 (AF 546)-14-dUTP by asymmetric PCR. Following 3-dimensional (3-D), molecular modeling of the aptamer-MPA complex, a series of three fluoresceinated aptamers labeled at positions 50, 51, and 52 in the putative optimal binding pocket were synthesized. In both FRET formats, aminoMPA was linked to Black Hole Quencher (BHQ-1 or BHQ-2)-succinimides and allowed to bind the fluorescein or AF 546-labeled MPA aptamer. Following gel filtration to purify the labeled MPA aptamer-BHQ-aminoMPA FRET complexes, the complexes were competed against various concentrations of unlabeled MPA, MPA derivatives, and unrelated compounds in titration and cross-reactivity studies. Both approaches yielded low microgram per milliliter detection limits for MPA with generally low levels of cross-reactivity for unrelated compounds. However, the data suggest a pattern of traits that may effect the direction (lights on or off) and intensity of the FRET.     

Studies on the Spectral-Luminescent Properties of the Novel Homodimer Styryl Dyes in Complexes with DNA

Series of homodimer styryls containing on (p-dimethylaminostyryl) pyridinium residues that are connected with aliphatic linkage group was synthesized. Spectral luminescent properties of obtained dyes in free state and in nucleic acids presence were studied. It was shown that DNA binding affinity of the novel homodimers exceeds that of parent monomer (p-dimethylaminostyryl)pyridine iodide. For homodimers with the linkage 4–10 carbon atoms preference in binding to DNA than to RNA was observed. It could be concluded that parent monomer has different mechanisms of binding to nucleic acids than corresponding homodimer dye.     

Complexes of the ATP-dependent Lon protease and DNA aptamers with G-quadruplexes as a model for developing a nanosensor biomagnetic immunoassay system

The binding to Lon protease through biotinylated aptamers whose structures contain G-quadruplex fragments with magnetic nanoparticles (MNPs) functionalized by streptavidin was investigated. The conditions of binding of target aptamers to MNPs are met. The resulting complexes are proposed for detection of Lon protease in different biological sources and for constructing a novel biomagnetic nanosensor immunoassay system.     

DNA and PNA as templates for building nanoassemblies via electrostatic complexation with gold nanoparticles

Organisation of nanoparticles on structurally well-defined templates is a first step towards creating nanomachines. In this respect, nucleic acids are ideal structural templates and a variety of secondary structures realizable from DNA/RNA––e.g., duplexes, hairpins, triplexes, cruciforms, tetraplexes can be exploited to engineer nanoparticle organization at will. We have used oligonucleotides and their analogues such as phosphorothioates and peptide nucleic acids to electrostatically encapsulate cationic-capped gold nanoparticles. This article describes synthesis and characterization of DNA/PNA-gold nanoparticle composites using TEM and UV-T_m techniques. These types of assemblies may have potential for creating nanowires and lithographic circuits.     

In situ studies of microbial inactivation during high pressure processing

High pressure processing (HPP) has been shown to reduce microbial concentration in foods. The mechanisms of microbial inactivation by HPP have been associated with damage to cell membranes. The real-time response of bacteria to HPP was measured to elucidate the mechanisms of inactivation, which can aid in designing more effective processes. Different pressure cycling conditions were used to expose Enterobacter aerogenes cells to HPP. Propidium iodide (PI) was used as a probe, which fluoresces after penetrating cells with damaged membranes and binding with nucleic acids. A HPP vessel with sapphire windows was used for measuring fluorescence in situ. Membrane damage was detected during pressurization and hold time, but not during depressurization. The drop in fluorescence was larger than expected after pressure cycles at higher pressure and longer times. This indicated possible reversible disassociation of ribosomes resulting in additional binding of PI to exposed RNA under pressure and its release after depressurization.     

用于检测水环境中银离子浓度的荧光适体传感器研究

银凭借其独特的性能,在医疗材料、摄影、电子、成像等行业中应用广泛.然而,银离子被列为最具毒性的重金属离子之一,会对环境以及人类的生命健康造成严重威胁.为了灵敏、特异性的检测水环境中的银离子浓度,利用纳米金的优良光学猝灭性以及双链核酸适体捕获银离子能力更强的优点,结合荧光能量共振转移原理,提出一种用于检测水环境中银离子浓...     

Unravelling the mechanism of RNA-polymerase forward motion by using mechanical force

Polymerases form a class of enzymes that act as molecular motors as they move along their nucleic acid substrate during catalysis, incorporating nucleotide triphosphates at the end of the growing chain and consuming chemical energy. A debated issue is how the enzyme converts chemical energy into motion [J. Gelles and R. Landick, Cell 93, 13 (1998)]. In a single molecule assay, we studied how an opposing mechanical force affects the translocation rate of T7 RNA polymerase. Our measurements show that force acts as a competitive inhibitor of nucleotide binding. This result is interpreted in the context of possible models, and with respect to published crystal structures of T7 RNA polymerase. The transcribing complex appears to utilize only a small fraction of the energy of hydrolysis to perform mechanical work, with the remainder being converted to heat.