Poly(methyl methacrylate) microchip affinity capillary gel electrophoresis of aptamer-protein complexes for the analysis of thrombin in plasma

Thrombin generation in blood serves as an important marker for various hemostasis-related diseases and conditions. Analytical techniques currently utilized for determining the thrombin potential of patients rely primarily on the enzymatic activity of thrombin. Microfluidic-based ACE using fluorescently labeled aptamers as affinity probes could provide a simple and efficient technique for the real-time analysis of thrombin levels in plasma. In this study, aptamers were used for the analysis of thrombin by affinity microchip CGE. The CGE used a poly(methyl methacrylate) (PMMA) microfluidic device for the sorting of the affinity complexes with a linear polyacrylamide (LPA) serving as the sieving matrix. Due to the fact that the assay was run under nonequilibrium electrophoresis conditions, the presence of the sieving gel was found to stabilize the affinity complex, providing improved electrophoretic performance compared to free-solution electrophoresis. Two fluorescently labeled aptamer affinity probes, HD1 and HD22, which bind to exosites I and II, respectively, of thrombin were investigated. With an electric field strength of 300 V/cm, two well-resolved peaks corresponding to free aptamer and the thrombin-aptamer complex were obtained in less than 1 min of separation time with a run-to-run and chip-to-chip reproducibility (RSD) of migration times <10% using both aptamers. HD22 affinity assays of thrombin produced baseline-resolved peaks with favorable efficiency due to its higher binding affinity, whereas HD1 assays showed poorer resolution of the free aptamer and complex peaks. HD22 was used in determining the level of thrombin in human plasma. Assays were performed directly on plasma that was diluted to 10% v/v. Thrombin was successfully analyzed by microchip CGE at a concentration level of 543.5 nM for the human plasma sample.     

Frontal analysis in microchip CE: a simple and accurate method for determination of protein-DNA dissociation constant

Equilibrium constants, such as the dissociation constant (K(d)), are a key measurement of noncovalent interactions that are of importance for the proper functioning of molecules in living systems. Frontal analysis (FA) is a simple and accurate CE method for the determination of K(d). Microchip CE coupled with LIF detection was used to determine K(d) of protein-DNA interactions using the FA method. A model system of IgE and the IgE-binding aptamer was selected to demonstrate the capability of FA in microchip CE. Because the fluorescence emission was dependent on the dye migration velocity, the velocity of the free aptamer was adjusted to be the same as that of the aptamer-IgE complex by setting up individual separation voltage configurations for the free and bound aptamers. The ratio of the free and bound aptamers in the equilibrium mixture was directly measured from the heights of their plateaus detected at 1.0 cm from the intersection of the microchip, and no internal standard was needed. The K(d) of the IgE-aptamer pair was determined as 6 +/- 2 nM which is consistent with the reported results (8 nM).     

High-sensitive determination of human alpha-thrombin by its 29-mer aptamer in affinity probe capillary electrophoresis

ACE technique provides an effective tool for the separation and identification of disease-related biomarkers in clinical analysis. In recent years, a couple of synthetic DNA or RNA oligonucleotides, known as aptamers, rival the specificity and affinity for targets to antibodies and are employed as one kind of powerful affinity probe in ACE. In this work, based on high affinity between antithrombin aptamer and thrombin (their dissociation constant is 0.5 nM), a carboxyfluorescein-labeled 29-nucleotide (nt) aptamer (F29-mer) was used and an aptamer-based affinity probe CE (aptamer-based APCE) method was successfully established for high-sensitive detection and quantitative analysis of thrombin. Experimental conditions including incubation temperature and time, buffer composition, and concentration of cations were investigated and optimized. Under the optimized condition, the linear range was from 0 to 400 nM and the LOD was 2 nM (74 ng/mL, S/N = 3), i.e., 40 amol, both in running buffer and in 5% v/v human serum. This LOD is the lowest one than those achieved by the previous APCE methods but based on a 15-mer aptamer. This approach offers a promising method for the rapid, selective, and sensitive detection of thrombin in practical utility. Further binding experiments using one carboxyfluorescein-labeled aptamer and the other nonlabeled aptamer or vice versa were carried out to deduce the formation of ternary complex when these two aptamers coexisted in the free solution with thrombin.     

基于适配体亲和毛细管电泳-激光诱导荧光检测的凝血酶分析

以一种高亲和力适配体作为亲和荧光探针,以自建的毛细管电泳-激光诱导荧光(CE-LIF)检测装置为基础,建立了一种高灵敏、快速测定人凝血酶的方法。荧光标记的凝血酶适配体特异性地与凝血酶结合并形成稳定的凝血酶-适配体复合物,采用CE-LIF对复合物进行分离检测,从而测定凝血酶浓度。探讨了盐离子种类及浓度对适配体与凝血酶结合的影响,并在选定的电泳条件下对凝血酶检测的线性范围、检出限和重现性进行了测定。结果表明,盐离子存在的条件下适配体与凝血酶的亲和力降低,不利于两者的结合;人血清溶液中,凝血酶浓度在0.25～10 nmol/L范围内与复合物峰面积具有良好的线性相关性(r20.991),检出限(S/N3)为55.6 pmol/L;精密度和回收率测定结果均能满足分析的要求。     

Determination of binding parameters between lysozyme and its aptamer by frontal analysis continuous microchip electrophoresis (FACMCE)

An original and simple methodology based on microchip electrophoresis (MCE) in a continuous frontal analysis mode (named frontal analysis continuous microchip electrophoresis, FACMCE) was developed for the simultaneous determination of the binding parameters, i.e. ligand-site dissociation constant (k(d)) and number of binding sites on the substrate (n). This simultaneous determination was exemplified with the interaction between an aptamer and its target. The selected target is a strongly basic protein, lysozyme, as its quantification is of great interest due to its antimicrobial and allergenic properties. A glass microdevice equipped with a fluorescence detection system was coated with hydroxypropylcellulose, reducing the electroosmotic flow and adsorption onto the channel walls. This microdevice allowed the continuous electrokinetic injection of a mixture of fluorescently labelled aptamer and non-labelled lysozyme. By determining the concentration of the free fluorescently labelled aptamer thanks to its corresponding plateau height, mathematical linearization methods allowed to determine a k(d) value of 48.4±8.0 nM, consistent with reported results (31 nM), while the average number of binding sites n on lysozyme, never determined before, was 0.16±0.03. These results seem to indicate that the buffer nature and the SELEX process should influence the number and affinity of the binding sites. In parallel it has been shown that the binding between lysozyme and its aptamer presents two sites of different binding affinities.     

A simple and rapid approach for measurement of dissociation constants of DNA aptamers against proteins and small molecules via automated microchip electrophoresis

Automated microchip electrophoresis was used as a simple and rapid method to measure effective dissociation constants (K(d,eff)) of aptamers against both large and small molecule targets. Human thrombin, immunoglobulin E (IgE), and adenosine triphosphate (ATP) were selected as model analytes to validate the method, with four ligands including two DNA aptamers for thrombin (two distinct epitopes), an IgE aptamer, and an ATP aptamer. The approach is based on a microchip version of a DNA mobility shift assay. Non-denaturing microchip gel electrophoresis separations of DNA could resolve and quantify unbound from target-bound aptamers when using large molecules as targets. To extend the technique to small molecule targets such as ATP, an aptamer/competitor strategy was used, in which a DNA competitor complementary to the aptamer could be displaced by ATP and electrophoretically resolved. Using an automated microchip electrophoresis platform, parallel separations of 11 titration samples were completed in ~0.5 h. Analytical performance comparisons show that our approach provides significant advantages in minimized reagent consumption (typically tens of pmol of aptamer and target), reduced analysis time, and minimized user interaction when compared to previously reported methods for aptamer K(d) measurement. Moreover, the flexibility and ease of K(d,eff) measurement for aptamers against large and small targets make this a unique and valuable approach that should find widespread use. Finally, the feasibility of using this method during aptamer selection processes (e.g. SELEX) was shown by accurate bulk K(d,eff) measurement of a known thrombin aptamer (THRaptA) spiked into a random-sequence DNA pool at as low as 5.0% (molar %) of the total pool; only ~825 fmol of total binding sequences were needed for an 11-point titration curve.     

Fabrication and evaluation of a carbon-based dual-electrode detector for poly(dimethylsiloxane) electrophoresis chips

The first carbon-based dual-electrode detector for microchip capillary electrophoresis (CE) is described. The poly(dimethylsiloxane) (PDMS)-based microchip CE devices were constructed by reversibly sealing a PDMS layer containing separation and injection channels to another PDMS layer containing carbon fiber working electrodes. End-channel amperometric detection was employed and the performance of the chip was evaluated using catechol. The response was found to be linear between 1 and 600 microM with an experimentally determined limit of detection (LOD) of 500 nM and a sensitivity of 30 pA/microM. Collection efficiencies for catechol ranged from 36.0 to 43.7% at field strengths of 260-615 V/cm. The selectivity that can be gained with these devices is demonstrated by the first CE-based dual-electrode detection of a Cu(II) peptide complex. These devices illustrate the potential for a rugged and easily constructed microchip CE system with an integrated carbon-based detector of similar scale.     

Aptamer-based electrochemical sensors that are not based on the target binding-induced conformational change of aptamers

This study describes a new kind of aptamer-based electrochemical sensor that is not based on the target binding-induced conformational change of the aptamers by using a 15-mer thrombin-binding aptamer (5'-GGTTGGTGTGGTTGG-3') as the model oligonucleotide. The sensors are developed by first self-assembling the aptamer (i.e. a thrombin-binding aptamer) onto an Au electrode and then hybridizing the assembled aptamer with a ferrocene (Fc)-labeled short aptamer-complementary DNA oligonucleotide to form an electroactive double-stranded DNA (ds-DNA) oligonucleotide onto the Au electrode. The binding of the target (i.e. thrombin) towards the aptamer essentially destroys the Watson-Crick helix structure of the ds-DNA oligonucleotide assembled onto the electrode and leads to the dissociation of the Fc-labeled short complementary DNA oligonucleotide from the electrode surface to the solution, resulting in a decrease in the current signal obtained at the electrode, which can be used for the determination of the target. With the thrombin-binding aptamer as the model oligonucleotide, the current decrease obtained with the aptamer-based electrochemical sensors is linear with the concentration of thrombin within the concentration range from 0 to 10 nM (DeltaI/nA = 6.7C(thrombin)/nM + 2.8, gamma = 0.975). Unlike most kinds of existing aptamer-based electrochemical sensor, the electrochemical aptasensors demonstrated here are not based on the conformational change of the aptamers induced by the specific target binding. Moreover, the aptasensors are essentially label-free and are very responsive toward the targets. This study may pave a facile and general way to the development of aptamer-based electrochemical sensors.     

Fluorescence detection in short capillary and chip using a variable wavelength epi-fluorescence microscope

Fast, efficient separation of five free acid forms of porphyrins was achieved in a short capillary and a chip, respectively. The capillary was 6 cm long from injection end to detector with an electric field strength of 214 V cm(-1). Separations were performed within 5 min. A glass microchip device was fabricated using standard photolithographic procedures and chemical wet etching. The channels were sealed using a direct bonding technique. For a separation length of 2.8 cm with electric field strength of 500 V cm(-1), electrophoretic separations with baseline resolution were achieved in less than 2 min. A variable wavelength epi-fluorescence microscope was used as an on-column detector.     

Faster and improved microchip electrophoresis using a capillary bundle

Joule heating generated in CE microchips is known to affect temperature gradient, electrophoretic mobility, diffusion of analytes, and ultimately the efficiency and reproducibility of the separation. One way of reducing the effect of Joule heating is to decrease the cross-section area of microchannels. Currently, due to the limit of fabrication technique and detection apparatus, the typical dimensions of CE microchannels are in the range of 50-200 microm. In this paper, we propose a novel approach of performing microchip CE in a bundle of extremely narrow channels by using photonic crystal fiber (PCF) as separation column. The PCF was simply encapsulated in a poly(methyl methacrylate) (PMMA) microchannel right after a T-shaped injector. CE was simultaneously but independently carried out in 54 narrow capillaries, each capillary with diameter of 3.7 microm. The capillary bundle could sustain high electric field strength up to 1000 V/cm due to efficient heat dissipation, thus faster and enhanced separation was attained.     

Characterization of DNA-protein complexes by capillary electrophoresis-single molecule fluorescence correlation spectroscopy

A high-speed capillary electrophoresis mobility shift assay (CEMSA) for determining the binding ratios of DNA-protein complexes in solution is demonstrated. Single molecule fluorescence correlation spectroscopy (FCS) was used to resolve the bound and unbound fluorescently labeled DNA molecules as they flowed continuously through a fused silica capillary under the influence of an applied electric field. Resolution of the bound and unbound complexes was based on the difference in their electrophoretic mobilities, and was accomplished without the need to perform a chemical separation. Data sufficient to perform the analysis was acquired in less than 10 s, compared to the minutes that are normally needed to carry out such measurement via CE separation. The binding ratios were determined with 5 to 10% precision and agreed with the results obtained by CE separation within experimental error. The resolution of the CEMSA based FCS analysis (CEMSA-FCS) was significantly higher than for the analysis performed by conventional diffusional FCS, due to the higher mass sensitivity of the electrophoretic mobility compared to the translational diffusion coefficient. Fluorescently labeled 39-mer single stranded DNA (ssDNA) and the single stranded binding protein (SSB) from Escherichia coli was used as the model system. The dissociation constant of the ssDNA-SSB complex was estimated to be approximately 2 nM based on the CEMSA-FCS analysis.     

Design of separation length and electric field strength for high-speed DNA electrophoresis

Gel-based DNA separation on microchip will play an important role in future genomic analysis due to its potential for high-efficiency and high-speed. Optimal design of microchip and separation condition is essential to take full advantage of high-speed separation on microchip. Separation length L and electric field strength E, which are crucial for design of microchip system, are focused on in this paper. Simultaneous optimization of L and E was carried out to achieve the most rapid separation. It was shown that the condition of L and E and the shortest separation time is closely related to the shape of resolution Rs surface in a three-dimensional space with axes E, L, and Rs. This surface was investigated, taking sample injection, detector, diffusion, and Joule heating into account. Thermal gradient broadening due to Joule heating helps to produce camber or ridge shape of Rs surface, which is essential for the shortest separation length and separation time. Sample plug length and detection volume should be more carefully controlled in microchip. The property of diffusion coefficient was shown to play a key role in determining Rs surface.     

Effect of buffer,electric field,and separation time on detection of aptamer-ligand complexes for affinity probe capillary electrophoresis

The separation and detection of complexes of aptamers and protein targets by capillary electrophoresis (CE) with laser-induced fluorescence was examined. Aptamer-thrombin and aptamer-immunoglobulin E (IgE) were used as model systems. Phosphate, 3-(N-morpholino)propanesulfonic acid with phosphate, and tris(hydroxyamino)methane-glycine-potassium (TGK) buffer at pH 8.4 were tested as electrophoresis media. Buffer had a large effect with TGK providing the most stable complexes for both protein-aptamer complexes. Conditions that suppressed electroosmotic flow, such as addition of hydroxypropylmethylcellulose to the media or modification of the capillary inner wall with polyacrylamide, were found to prevent detection of complexes. The effect of separation time and electric field were evaluated by monitoring complexes with electric field varied from 150-2850 V/cm and effective column lengths of 3.5 and 7.0 cm. As expected, shorter times on the column greatly increased peak heights for the complexes due to a combination of less dilution by diffusion and less dissociation on the column. High fields were found to have a detrimental effect on detection of complexes. It is concluded that the best conditions for detection of noncovalent complexes involve use of the minimal column length and electric field necessary to achieve separation. The results will be of interest in developing affinity probe CE assays wherein aptamers are used as affinity ligands.     

Highly sensitive detection of human thrombin in serum by affinity capillary electrophoresis/laser-induced fluorescence polarization using aptamers as probes

The detection and quantification of disease-related proteins play critical roles in clinical practice and diagnostic assays. We present an affinity probe capillary electrophoresis/laser-induced fluorescence polarization (APCE/LIFP) assay for detection of human thrombin using a specific aptamer as probe. In the APCE/LIFP assay, the mobility and fluorescence polarization of complex are measured simultaneously during CE analysis. The affinity complex of human thrombin can be well separated from unbound aptamer on CE and clearly identified on the basis of its fluorescence polarization and migration. Because of the binding favorable G-quartet conformation potentially involved in the specific aptamer, it was assumed that monovalent and bivalent cations promoting the formation of a stable G quadruplex conformation in the aptamer may enhance the binding of the aptamer and thrombin. Therefore, we investigated the effects of various metal cations on the binding of human thrombin and the aptamer. Our results show that cations like K⁺ and Mg²⁺ could not stabilize the affinity complex. Without the use of typical cations, a highly sensitive assay of human thrombin was developed with the corresponding detection limits of 4.38 × 10⁻¹⁹ and 2.94 × 10⁻¹⁹ mol in mass for standard solution and human serum, respectively.     

Miniaturization in carbohydrate analysis

Recent progress of microchip electrophoresis (ME) of carbohydrates is overviewed. Carbohydrate analysis by ME encounters difficulties such as lack of electric charge and deficiency of a chromophore/fluorophore in analyte molecules, however, it benefits from the accumulated knowledge of capillary electrophoresis (CE) and rapid separation of simple sugars also by ME, with high column efficiency comparable to CE, has become possible. Analysis at high pH, with electrochemical detection, is a promising approach because carbohydrates can be ionized by weak dissociation of the hydroxyl groups and the in situ formed ionic species can be effectively separated by the zone electrophoresis mode. The separated species can be sensitively monitored by electrochemical detection on a gold or copper electrode. Ionization as borate complexes and refractometric detection is also possible, though sensitivity is lower. Introduction of UV-absorbing or fluorescent tags is potentially useful but the time-consuming derivatization processes sacrifice the rapidity of ME. Examples of ME of carbohydrates as 1-phenyl-3-methyl-5-pyrazolone (PMP; for simple mono- and oligosaccharides with UV detection), 8-aminopyrene-1,3,6-trisulfonate (APTS; for oligosaccharides ladders with LIF detection), and 4-nitro-2,1,3-benzoxadiazole (NBD-F; for amino sugars and aminoalditols with LIF detection) derivatives are presented, with details of the analytical conditions. Since ME in a short separation channel enables rapid analysis within 1 min, it presents an ideal tool for clinical analysis, as shown in a few papers reporting protocols for specific blood glucose assay. Finally, the usefulness of microfluidic reactors and microarrays for enzyme-assisted carbohydrate analysis as well as glycan profiling is pointed out.     

Novel application of fluorescence coupled capillary electrophoresis to resolve the interaction between the G‐quadruplex aptamer and thrombin

The dynamic binding status between the thrombin and its G‐quadruplex aptamers and the stability of its interaction partners were probed using our previously established fluorescence‐coupled capillary electrophoresis method. A 29‐nucleic acid thrombin binding aptamer was chosen as a model to study its binding affinity with the thrombin ligand. First, the effects of the cations on the formation of G‐quadruplex from unstructured 29‐nucleic acid thrombin binding aptamer were examined. Second, the rapid binding kinetics between the thrombin and 6‐carboxyfluorescein labeled G‐quadruplex aptamer was measured. Third, the stability of G‐quadruplex aptamer–thrombin complex was also examined in the presence of the interfering species. Remarkably, it was found that the complementary strand of 29‐nucleic acid thrombin binding aptamer could compete with G‐quadruplex aptamer and thus disassociated the G‐quadruplex structure into an unstructured aptamer. These data suggest that our in‐house established fluorescence‐coupled capillary electrophoresis assay could be applied to binding studies of the G‐quadruplex aptamers, thrombin, and their ligands, while overcoming the complicated and costly approaches currently available.     

Capillary electrophoresis with on-chip four-electrode capacitively coupled conductivity detection for application in bioanalysis

Microchip capillary electrophoresis (CE) with integrated four-electrode capacitively coupled conductivity detection is presented. Conductivity detection is a universal detection technique that is relatively independent on the detection pathlength and, especially important for chip-based analysis, is compatible with miniaturization and on-chip integration. The glass microchip structure consists of a 6 cm etched channel (20 microm x 70 microm cross section) with silicon nitride covered walls. In the channel, a 30 nm thick silicon carbide layer covers the electrodes to enable capacitive coupling with the liquid inside the channel as well as to prevent interference of the applied separation field. The detector response was found to be linear over the concentration range from 20 microM up to 2 mM. Detection limits were at the low microM level. Separation of two short peptides with a pI of respectively 5.38 and 4.87 at the 1 mM level demonstrates the applicability for biochemical analysis. At a relatively low separation field strength (50 V/cm) plate numbers in the order of 3500 were achieved. Results obtained with the microdevice compared well with those obtained in a bench scale CE instrument using UV detection under similar conditions.     

采用超低场生物力谱技术研究核酸适配体与凝血酶蛋白的相互作用

蛋白质和核酸是构成生命体最为重要的两类生物大分子,它们之间的相互作用是分子生物学研究的中心问题之一,也是许多生命活动的重要组成部分。本文基于一种全新的超低场生物力谱技术,以凝血酶蛋白为研究对象,考察了凝血酶与其对应的核酸适配体之间的相互作用。结果表明,凝血酶蛋白与核酸适配体之间的结合力大小约为80 p N。同时,在分子水平上获得了凝血酶蛋白与核酸适配体之间的解离动力学信息。     

Fluorescence detection of DNA by the catalytic activation of an aptamer/thrombin complex

A conjugate consisting of a thrombin aptamer tethered to the thrombin, Th, with a sensing nucleic acid (1) is used for the optical detection of DNA. The thrombin/aptamer complex blocks the biocatalytic functions of Th. Hybridization of the analyte DNA (2) to the sensing nucleic acid 1 yields a rigid duplex that detaches the aptamer from Th, a process that activates the protein toward the hydrolysis of bis(p-tosyl-Gly-Pro-Arg)-R110 (3) to the rhodamine 110 fluorophore (4). The system allows the DNA sensing with a sensitivity limit of 1 x 10-8 M. The aptamer/Th conjugate is also immobilized on glass slides for the optical detection of DNA. The dissociation of the aptamer/Th complex upon hybridization and the subsequent dehybridization of the duplex and the regeneration of the catalytically inactive Th/aptamer complex duplicate machinery functions.     

Au Nanoparticle-DNAzyme Dual Catalyst System for Sensitively Colorimetric Detection of Thrombin

A novel colorimetric aptasensor was developed for thrombin detection with high sensitivity and specificity. The assay takes the advantage of Au nanoparticles-DNAzyme as a dual catalytic system for signal amplification. Au nanparticles were modified with peroxidase mimicking DNAzyme sequence as well as thrombin binding aptamer. And then the thrombin binding aptamer hybridized with its complementary sequence which was immobilized on the surface of the magnetic nanoparticles to construct the colorimetric aptasensor. In the presence of thrombin, the target-induced displacement takes place, resulting in the dissociation of the aptasensor. The DNAzyme functioned Au NPs are released due to the combine ability of thrombin binding aptamer with thrombin. The released Au NPs are capable of catalyzing the colorless 2,2'-azino-bis(3-ethylbenzothiazoline)-6-sulfonic acid(ABTS) conversion into a blue-green product by H₂O₂-mediated oxidation, thus can amplify the colorimetric readout signals of thrombin detection. Such a device can serve as a novel selectivity sensor for thrombin with a detection limit of 0.6 nmol/L.