Quantitative analysis of cation binding to the adenosine nucleotides using the variable ionic strength method: validation of the Debye-Hückel-Onsager theory of electrophoresis in the absence of counterion binding

The free solution mobilities of the adenosine nucleotides 5'-adenosine triphosphate (ATP), 5'-adenosine diphosphate (ADP), 5'-adenosine monophosphate (AMP), and 3'-5'-cyclic AMP (cAMP) have been measured in diethylmalonate buffers containing a wide variety of monovalent cations. The mobilities of all nucleotides increase gradually with the increase in intrinsic conductivity of the cation in the BGE. However, at a given conductivity, the mobilities observed for ATP, ADP, and AMP in BGEs containing alkali metal ions and other cations are lower than these observed in BGEs containing tetraalkylammonium ions. Since the mobility of cAMP is independent of the cation in the BGE, the results suggest that the relatively low mobilities observed for ATP, ADP, and AMP in BGEs containing cations other than a tetraalkylammonium ion are due to cation binding, reducing the effective net charge of the nucleotide and thereby reducing the observed mobility. To measure the binding quantitatively, the mobilities of the nucleotides were measured as a function of ionic strength. The mobilities of ATP, ADP, and AMP decrease nonlinearly with the square root of ionic strength (I(1/2)) in BGEs containing an alkali metal ion or Tris(+). By contrast, the mobilities decrease linearly with I(1/2) in BGEs containing a nonbinding quaternary ammonium ion, as expected from Debye-Hückel-Onsager (DHO) theory. The mobility of cAMP, a nonbinding analyte, decreases linearly with I(1/2), regardless of the cation in the BGE. Hence, a nonlinear decrease of the mobility of an analyte with I(1/2) appears to be a hallmark of counterion binding. The curved mobility profiles observed for ATP, ADP, and AMP in BGEs containing an alkali metal ion or Tris(+) were analyzed by nonlinear curve fitting, using difference mobility profiles to correct for the effect of the physical properties of BGE on the observed mobilities. The calculated apparent dissociation constants range from 22 to 344 mM, depending on the particular cation-nucleotide pair. Similar values have been obtained by other investigators, using different methods. Interestingly, Tris(+) and Li(+) bind to the adenosine nucleotides with approximately equal affinities, suggesting that positively charged Tris(+) buffer ions can compete with alkali metal ions in Tris-buffered solutions.     

基于核酸适体检测ATP的酶联分析新方法

基于核酸适体对靶标的特异性识别和辣根过氧化物酶(HRP)的高效催化反应, 发展了一种用于检测三磷酸腺苷(ATP)的酶联核酸适体分析新方法. 核酸适体和靶标的特异性结合导致与核酸适体杂交的短链DNA解链, 解离的DNA通过杂交被固定在另一酶标板的DNA捕获. 解离的DNA预先标记了异硫氰酸荧光素(FITC)基团, FITC特异性结合HRP标记的FITC抗体, HRP作为信号传导元素催化四甲基二苯胺(TMB)底物显色, 通过颜色变化及450 nm波长处吸光度的变化检测ATP. 该方法对ATP具有良好的选择性, 检测不受其它物质如GTP, UTP和CTP的干扰, 且检测能在较复杂的试样(体积分数10%和50%的血清)中进行. 实验结果表明, 在ATP浓度为50~400 nmol/L范围内, 具有良好的线性关系, 检出限为26 nmol/L.     

Microelectrode Sensing of Adenosine/Adenosine‐5′‐triphosphate with Fast‐Scan Cyclic Voltammetry

Adenosine and adenosine‐5′‐triphosphate (ATP) are important extracellular signaling molecules. Here, we studied adenosine and ATP using fast‐scan cyclic voltammetry at carbon‐fiber microelectrodes. Although ATP and adenosine have similar oxidation potentials, ATP oxidation current was highly dependent on buffer pH and divalent cation concentrations but adenosine current was not. Therefore, they can be distinguished by adding a divalent cation chelator or calibrating electrodes at different pH values. The enzymatic degradation of adenosine by adenosine deaminase was monitored in a mixture of adenosine and ATP in presence of EDTA (ethylenediaminetetraacetate). This sensing method is promising for enzyme kinetics or in vitro studies.     

基于计时库仑技术的可再生型三磷酸腺苷适配体电化学传感器的研究

构建了一种可再生型三磷酸腺苷(ATP)适配体计时库仑电化学传感器.将一条短链DNA通过AuS键自组装固定在电极表面, ATP的核酸适配体与该短链DNA杂交而结合在电极表面.带负电的DNA通过静电吸引结合电解液中的六氨合钌(RuHex)阳离子.当传感器和靶分子ATP孵育后,ATP与核酸适配体结合,使适配体链从电极表面解离,电极表面吸附的DNA量减少,结合RuHex的量随之降低.通过计时库仑技术检测RuHex响应信号降低的量 ,可以对ATP进行定量测定.此传感器的电化学响应信号与ATP浓度对数值呈线性关系,线性检测范围为0.001~100 μmol/L,检出限(S/N=3)为0.5 nmol/L.此传感器检测靶分子ATP后,可以通过简单的操作步骤再生,再生5次后的响应信号为初始信号的90%以上.采用此传感器检测大鼠脑透析液中ATP的含量为(19.2±3.7) nmol/L (n=3).     

Structural basis of DNA folding and recognition in an AMP-DNA aptamer complex: distinct architectures but common recognition motifs for DNA and RNA aptamers complexed to AMP

Background: Structural studies by nuclear magnetic resonance (NMR) of RNA and DNA aptamer complexes identified through in vitro selection and amplification have provided a wealth of information on RNA and DNA tertiary structure and molecular recognition in solution. The RNA and DNA aptamers that target ATP (and AMP)' with micromolar affinity exhibit distinct binding site sequences and secondary structures. We report below on the tertiary structure of the AMP-DNA aptamer complex in solution and compare it with the previously reported tertiary structure of the AMP-RNA aptamer complex in solution.Results: The solution structure of the AMP-DNA aptamer complex shows, surprisingly, that two AMP molecules are intercalated at adjacent sites within a rectangular widened minor groove. Complex formation involves adaptive binding where the asymmetric internal bubble of the free DNA aptamer zippers up through formation of a continuous six-base mismatch segment which includes a pair of adjacent three-base platforms. The AMP molecules pair through their Watson-Crick edges with the minor groove edges of guanine residues. These recognition G·A mismatches are flanked by sheared G·A and reversed Hoogsteen G·G mismatch pairs.Conclusions: The AMP-DNA aptamer and AMP-RNA aptamer complexes have distinct tertiary structures and binding stoichiometries. Nevertheless, both complexes have similar structural features and recognition alignments in their binding pockets. Specifically, AMP targets both DNA and RNA aptamers by intercalating between purine bases and through identical G·A mismatch formation. The recognition G·A mismatch stacks with a reversed Hoogsteen G·G mismatch in one direction and with an adenine base in the other direction in both complexes. It is striking that DNA and RNA aptamers selected independently from libraries of 10¹⁴ molecules in each case utilize identical mismatch alignments for molecular recognition with micromolar affinity within binding-site pockets containing common structural elements.     

ATP detection using a label-free DNA aptamer and a cationic tetrahedralfluorene

A simple and sensitive method for ATP detection using a label-free DNA aptamer as the recognition element and ethidium bromide (EB) as the signal reporter is reported. The ATP-binding aptamer undergoes a conformational switch from the aptamer duplex to the aptamer/target complex upon target binding, which induces the fluorescence change of intercalated EB emission. Good selectivity between ATP and CTP, GTP or UTP has been demonstrated, which is due to the specific recognition between the ATP aptamer and ATP. Using EB alone as a signal reporter, the ATP detection limit was estimated to be approximately 0.2 mM. When a light harvesting cationic tetrahedralfluorene was used as an energy donor to sensitize the intercalated EB emission, a 10-fold increase in detection limit and a 2-fold increase in detection selectivity was demonstrated. The sensitivity and selectivity of the tetrahedralfluorene sensitized assay is comparable to or better than most fluorescent ATP assays with multiple labels.     

Enantioselective aptameric molecular recognition material: Design of a novel chiral stationary phase for enantioseparation of a series of chiral herbicides by capillary electrochromatography

A chiral stationary phase derived from an L-RNA aptamer is evaluated for the enantiomer separation of a series of herbicide molecules (aryloxypropionic, aryloxyphenoxypropionic, and aminopropionic acid) by CEC after binding to biotin and grafting upon streptavidin-modified porous glass beads. We demonstrated that the aptamer capillary was stable in term of efficiency and retention during a long period. The influences of the mobile phase constitution and its flow-velocity on the enantioseparation were also investigated. The results suggest that the interactions of the enantiomer during CEC are solely based on chromatographic mechanisms and that the electrophoresis plays only a minor role. The separation efficiency and peak shape could be improved by Mg2+ divalent cation that stabilized the aptamer secondary structure and thus enhanced the mass transfer kinetics during the ligand-aptamer binding process. In addition, it was demonstrated that the determination of the enantiomerization barrier of flamprop was possible using this chiral stationary phase.     

A selective adenosine sensor derived from a triplex DNA aptamer

The aim of this study is to develop a selective adenosine aptamer sensor using a rational approach. Unlike traditional RNA aptamers developed from SELEX, duplex DNA containing an abasic site can function as a general scaffold to rationally design aptamers for small aromatic molecules. We discovered that abasic site-containing triplex DNA can also function as an aptamer and provide better affinity than duplex DNA aptamers. A novel adenosine aptamer sensor was designed using such a triplex. The aptamer is modified with furano-dU in the binding site to sense the binding. The sensor bound adenosine has a dissociation constant of 400 nM, more than tenfold stronger than the adenosine aptamer developed from SELEX. The binding quenched furano-dU fluorescence by 40%. It was also demonstrated in this study that this sensor is selective for adenosine over uridine, cytidine, guanosine, ATP, and AMP. The detection limit of this sensor is about 50 nM. The sensor can be used to quantify adenosine concentrations between 50 nM and 2 μM.     

A Paper Sensor Printed with Multifunctional Bio/Nano Materials

We report a paper‐based aptasensor platform that uses two reaction zones and a connecting bridge along with printed multifunctional bio/nano materials to achieve molecular recognition and signal amplification. Upon addition of analyte to the first zone, a fluorescently labelled DNA or RNA aptamer is desorbed from printed graphene oxide, rapidly producing an initial fluorescence signal. The released aptamer then flows to the second zone where it reacts with printed reagents to initiate rolling circle amplification, generating DNA amplicons containing a peroxidase‐mimicking DNAzyme, which produces a colorimetric readout that can be read in an equipment‐free manner or with a smartphone. The sensor was demonstrated using an RNA aptamer for adenosine triphosphate (a bacterial marker) and a DNA aptamer for glutamate dehydrogenase (Clostridium difficile marker) with excellent sensitivity and specificity. These targets could be detected in spiked serum or feacal samples, demonstrating the potential for testing clinical samples.     

非标记纳米银探针催化共振散射光谱检测痕量ATP

在pH 7.8 Tris-HCl缓冲液中, 三磷酸腺苷(adenosine triphosphate, ATP)的核酸适体(Apt 1)与其互补链(Apt 2)结合生成双链DNA (double-strand DNA, dsDNA). 此dsDNA不能稳定纳米银(AgNP), NaCl可致AgNP聚集, 在500 nm波长处产生一个较强的共振散射峰. 加入ATP后, ATP与dsDNA中的Apt 1结合形成较稳定的发夹结构结合物并释放出可稳定AgNP的Apt 2. 随着ATP浓度(16.5～1650 nmol/L)增加, 生成的Apt 2增加, 被Apt 2稳定的AgNP即AgNP-Apt 2结合物增加, 聚集的AgNP减少, 500 nm处的共振散射值线性减小. 该适配体反应中的AgNP-Apt 2对葡萄糖-铜(II)微粒反应具有较强的催化作用, 其产物氧化亚铜微粒在610 nm处有一较强共振散射峰. 随着ATP浓度增大, 反应液中AgNP-Apt 2增多, 催化作用增强, 610 nm处的共振散射峰增强. ATP浓度在4.95～165 nmol/L范围内与共振散射增大值ΔI_{610 nm}呈线性关系, 检出限为1.8 nmol/L ATP. 据此建立了灵敏度高、选择性好、简便快速检测ATP的共振散射光谱新方法.     

Molecule-binding dependent assembly of split aptamer and γ-cyclodextrin: A sensitive excimer signaling approach for aptamer biosensors

A highly sensitive and selective fluorescence aptamer biosensors for the determination of adenosine triphosphate (ATP) was developed. Binding of a target with splitting aptamers labeled with pyrene molecules form stable pyrene dimer in the γ-cyclodextrin (γ-CD) cavity, yielding a strong excimer emission. We have found that inclusion of pyrene dimer in γ-cyclodextrin cavity not only exhibits additive increases in quantum yield and emission lifetime of the excimer, but also facilitates target-induced fusion of the splitting aptamers to form the aptamer/target complex. As proof-of-principle, the approach was applied to fluorescence detection of adenosine triphosphate. With an anti-ATP aptamer, the approach exhibits excimer fluorescence response toward ATP with a maximum signal-to-background ratio of 32.1 and remarkably low detection limit of 80 nM ATP in buffer solution. Moreover, due to the additive fluorescence lifetime of excimer induced by γ-cyclodextrin, time-resolved measurements could be conveniently used to detect as low as 0.5 μM ATP in blood serum quantitatively.     

Microcalorimetrics studies of the thermodynamics and binding mechanism between L-tyrosinamide and aptamer

In recent years, several high-resolution structures of aptamer complexes have shed light on the binding mode and recognition principles of aptamer complex interactions. In some cases, however, the aptamer complex binding behavior and mechanism are not clearly understood, especially with the absence of structural information. In this study, it was demonstrated that isothermal titration calorimetry (ITC) and circular dichroism (CD) were useful tools for studying the fundamental binding mechanism between a DNA aptamer and L-tyrosinamide (L-TyrNH2). To gain further insight into this behavior, thermodynamic and conformational measurements under different parameters such as salt concentration, temperature, pH value, analogue of L-TyrNH2, and metal ion were carried out. The thermodynamic signature along with the coupled CD spectral change suggest that this binding behavior is an enthalpy-driven process, and the aptamer has a conformational change from B-form to A-form. The results showed that the interaction is an induced fit binding, and the driving forces in this binding behavior may include electrostatic interactions, hydrophobic effects, hydrogen bonding, and the binding-linked protonation process. The amide group and phenolic hydroxyl group of the L-TyrNH2 play a vital role in this binding mechanism. In addition, it should be noted that Mg(2+) not only improves binding affinity but also helps change the structure of the DNA aptamer.     

Electrospray ionization of nucleic acid aptamer/small molecule complexes for screening aptamer selectivity

Molecular recognition of small molecule ligands by the nucleic acid aptamers for tobramycin, ATP, and FMN has been examined using electrospray ionization mass spectrometry (ESI-MS). Mass spectrometric data for binding stoichiometry and relative binding affinity correlated well with solution data for tobramycin aptamer complexes, in which aptamer/ligand interactions are mediated by hydrogen bonds. For the ATP and FMN aptamers, where ligand interactions involve both hydrogen bonding and significant pi-stacking, the relative binding affinities determined by MS did not fully correlate with results obtained from solution experiments. Some high-affinity aptamer/ligand complexes appeared to be destabilized in the gas phase by internal Coulombic repulsion. In CAD experiments, complexes with a greater number of intermolecular hydrogen bonds exhibited greater gas-phase stability even in cases when solution binding affinities were equivalent. These results indicate that in at least some cases, mass spectrometric data on aptamer/ligand binding affinities should be used in conjunction with complementary techniques to fully assess aptamer molecular recognition properties.     

Turbidimetric detection of ATP using polymeric micelles and DNA aptamers

Two types of turbidimetric detection of adenosine 5'-triphosphate (ATP) by the naked eye were achieved through a combination of non-cross-linking aggregation of DNA-linked polymeric micelles and molecular recognition of ATP by a DNA aptamer.     

基于阳离子型共轭聚合物和核酸适体的腺苷检测新方法

建立了一种基于阳离子型共轭聚合物和核酸适体的腺苷检测新方法. 荧光素修饰的短链DNA与腺苷的核酸适体部分互补, 形成双链DNA; 阳离子型共轭聚合物通过静电作用与双链DNA结合, 发生高效率的荧光共振能量转移(FRET). 加入腺苷后, 腺苷与核酸适体发生特异性结合, 导致双链DNA分解成单链, 使静电吸引力下降, 能量转移效率降低. 通过阳离子型共轭聚合物对单双链DNA的高效识别, 可快速简易地检测出腺苷.     

Determination of levels of adenosine phosphates in blood by ion chromatography

A new method was developed for simultaneous determination of levels of AMP,ADP and ATP in blood by anion-exchange chromatography.The three adenosine phosphates were separated by Dionex IonPac AG18(50 mm×4 mm) guard column and IonPac AS 18(250 mm×4 mm) analytical column using a gradient method and detected with a suppressed conductivity detector. The detection limits(S/N=3) of AMP,ADP and ATP were 38,47,108 ng/L,respectively.The relative standard deviations of retention time,peak area and peak height were all less than 1.87%and a good linear relationship was obtained.This method was applied to analyze human blood samples.     

An Autonomous Bio‐barcode DNA Machine for Exponential DNA Amplification and Its Application to the Electrochemical Determination of Adenosine Triphosphate

A novel autonomous bio‐barcode DNA machine that is driven by template‐dependent DNA replication is developed to exponentially amplify special DNA sequences. Combined with a DNA aptamer recognition element, the DNA machine can be further applied in the aptamer‐based, amplified analysis of small molecules. As a model analyte, adenosine triphosphate (ATP) is determined by using the DNA machine system in combination with a DNA aptamer recognition strategy and differential pulse anodic stripping voltammetry (DPASV). Under the optimum conditions, detection limits as low as 2.8×10^?17 M (3σ) for target DNA and 4.7×10^?9 M (3σ) for ATP are achieved. The satisfactory determination of ATP in K562 leukemia cell and Ramos Burkitt’s lymphoma cell reveal that this protocol possesses good selectivity and practicality. As a promising biomolecular device, this DNA machine may have an even broader application in the rapidly developing field of nanobiotechnology.     

Aptamer–Target Interaction: A Comprehensive Study by Microchip Electrophoresis in Frontal Mode

An original methodology based on microchip electrophoresis in a continuous frontal analysis mode (FACMCE) was employed to provide new insights into the interaction between an aptamer and its target (lysozyme), i.e., the influence of various experimental conditions on possible conformation change of the aptamer. The parameters evaluated were: background electrolyte (BGE) nature and ionic strength, nature and concentration of an added divalent cation, use of an aptamer thermal treatment, conditions classically used when employing aptamers. Increasing the BGE ionic strength led to a decrease in the dissociation constant highlighting the role played by the non-ionic interactions, and a decrease in the number of binding sites due to a change of binding mode and/or an amplification of selectivity. Divalent cation addition in the BGE improved the binding affinity. We demonstrated that this is not exclusively related to an increase in ionic strength but also certainly to an aptamer conformational change. Furthermore, changing the BGE nature permitted to modulate the binding parameters. Finally, we showed that an initial heating of the aptamer solution has been proved critical to stabilize the optimal conformation and thus to get a high binding affinity as well as a smaller standard deviation on the binding parameters values. This study has evidenced the influence of a wide range of parameters so as to better grasp the target/aptamer interaction, and thus highlight some phenomena involved in such an interacting system. This work will therefore help for further applications of this binding system for selectivity improvement in bioanalytical development.     

Dynamic,Bioresponsive Hydrogels via Changes in DNA Aptamer Conformation

DNA aptamers are integrated into synthetic hydrogel networks with the aim of creating hydrogels that undergo volume changes when exposed to target molecules. Specifically, single‐stranded DNA aptamers in cDNA‐bound, extended state are incorporated into hydrogel networks as cross‐links, so that the nanoscale conformational change of DNA aptamers upon binding to target molecules will induce macroscopic volume decreases of hydrogels. Hydrogels incorporating adenosine triphosphate (ATP)–binding aptamers undergo controllable volume decreases of up to 40.3 ± 4.6% when exposed to ATP, depending on the concentration of DNA aptamers incorporated in the hydrogel network, temperature, and target molecule concentration. Importantly, this approach can be generalized to aptamer sequences with distinct binding targets, as demonstrated here that hydrogels incorporating an insulin‐binding aptamer undergo volume changes in response to soluble insulin. This work provides an example of bioinspired hydrogels that undergo macroscopic volume changes that stem from conformational shifts in resident DNA‐based cross‐links.     

Covalently bonded DNA aptamer chiral stationary phase for the chromatographic resolution of adenosine

In this work, a target-specific aptamer chiral stationary phase (CSP) based on the oligonucleotidic selector binding to silica particles through a covalent linkage was developed. An anti-d-adenosine aptamer was coupled, using an in-situ method, by way of an amide bond to macroporous carboxylic acid based silica. Frontal chromatography analysis was performed to evaluate the column properties, i.e., determination of the stationary phase binding capacity and the dissociation constant of the target-immobilized aptamer complex. It was found that such covalent immobilization was able to maintain the aptamer binding properties at a convenient level for an efficient enantioseparation. Subsequently, the separation of adenosine enantiomers was investigated under different operating conditions, including changes in the eluent’s ionic strength and the proportion of organic modifiers as well as column temperatures. It was demonstrated that, under various conditions of use and storage, the present CSP was stable over time.