Real-time aptamer quantum dot fluorescent flow sensor

The goal of this work was to develop and test a novel real-time biosensing approach which can be adapted to either environmental or clinical monitoring of biological pathogens. We have developed a working prototype of a real-time aptamer-based fluorescent flow sensor. The sensor utilizes a competitive displacement approach to measure the binding of the analyte, which keeps the nonspecific binding below detectable levels. The complex of surface-immobilized DNA aptamer with fluorescent complementary oligonucleotide releases the oligonucleotide upon binding with a specific target, which is translated by a decrease in fluorescence. Bright and stable fluorescence of quantum dots is utilized for prolonged detection of the analyte in flow conditions. The real-time sensor prototype is developed with previously characterized ATP-specific aptamer and is capable of specifically detecting 0.1 mM of ATP in biological buffer, with a quantitative response up to 5 mM. The developed prototype is portable and easy to use and its design allows further miniaturization and multiplexing. The developed real-time sensing approach can be adapted to a variety of targets of environmental and clinical significance.     

Rapidly optimizing an aptamer based BoNT sensor by feedback system control (FSC) scheme

The sensitivity and detection time of an aptamer based biosensor for detecting botulinum neurotoxin (BoNT) depend upon the formation of proper tertiary architecture of aptamer, which closely correlates with the combinatorial effects of multiple types of ions and their concentrations presented in the buffer. Finding the optimal conditions for four different ions at 12 different concentrations, 20,736 possible combinations, by brute force is an extremely laborious and time-consuming task. Here, we introduce a feedback system control (FSC) scheme that can rapidly identify the best combination of components to form the optimal aptamer structure binding to a target molecule. In this study, rapid identification of optimized ionic combinations for electrochemical aptasensor of BoNT type A (BoNT/A) detection has been achieved. Only about 10 iterations with about 50 tests in each iteration are needed to identify the optimal ionic concentration out of the 20,736 possibilities. The most exciting finding was that a very short detection time and high sensitivity could be achieved with the optimized combinational ion buffer. Only a 5-min detection time, compared with hours or even days, was needed for aptamer-based BoNT/A detection with a limit of detection of 40 pg/ml. The methodologies described here can be applied to other multi-parameter chemical systems, which should significantly improve the rate of parameter optimization.     

A DNA aptamer sensor for 8-oxo-7,8-dihydroguanine

Abasic site-containing DNA duplex is a versatile structural motif that can be used for the design of purine aptamers and sensors. In this study, several modifications were introduced to the abasic site to explore possible specific binding of free 8-oxoG, a product of DNA base excision repair. The nucleoside opposite the abasic site was replaced by pyrrolo-dC as a reporter group. Binding of 8-oxoG quenched pyrrolo-dC fluorescence by as much as 70%. In contrast, adenine, guanine, thymine, and cytosine showed only minimal fluorescence quenching effect. The best aptamer binds 8-oxoG with a dissociation constant of 5.5±0.8μM. This sensor can be used to accurately measure 8-oxoG concentrations in the presence of guanine.     

A sensitive electrochemiluminescent sensor chip based on the ssDNA-Ru(II) complex and aptamer for the determination of thrombin

In this work, an electrochemiluminescence (ECL) sensor chip for sensitive detection of thrombin (TB) was prepared using a screen-printed electrode (SPE) as a working electrode and an aptamer as a specific recognition moiety. To produce an ECL sensor chip, a layer of pL-Cys was immobilized on the surface of the SPE using the cyclic voltammetry scanning method. A layer of gold nanoparticles (AuNPs) was assembled through an Au–S bond and hairpin DNA was further immobilized on the electrode surface. Ru(bpy)₂(mcpbpy)²⁺, as a luminescent reagent, was covalently bound to single-stranded DNA (ssDNA) to prepare a luminescence probe ssDNA-Ru. The probe was hybridized with TB aptamer to form a capture probe. In the presence of TB, the TB aptamer in the capture probe bound to TB, causing the release of ssDNA-Ru that could bind to hairpin DNA on the electrode surface. The Ru(II) complex as a luminescent reagent was assembled onto the electrode, and pL-Cys was used as a co-reactant to enhance the ECL efficiency. The ECL signal of the sensor chip generated based on the above principles had a linear relationship with log TB concentration at the range 10 fM to1 nM, and the detection limit was 0.2 fM. Finally, TB detection using this method was verified using real blood samples. This work provides a new method using an aptamer as a foundation and SPE as a material for the detection of biological substances.     

Rational design of modular allosteric aptamer sensor for label-free protein detection

An aptamer can be redesigned to new functional molecules by conjugating with other oligonucleotides. However, it requires experimental trials to optimize the conjugating module with the sensitivity and selectivity toward a target. To reduce these efforts, we report rationally-designed modular allosteric aptamer sensor (MAAS), which is composed of coupled two aptamers and the regulator. For label-free protein detection, the protein-aptamer was conjugated with the malachite green (MG) aptamer for signaling. The MAAS additionally has the regulator domain which is designed to hybridize to a protein binding domain. The regulator makes MAAS to be inactive by destructing the original structure of the two aptamers. However, its conformation becomes active by dissociating the hybridization from the protein recognition signal, thereby inducing the binding of MG emitting the enhanced fluorescence. The design of regulator is based on the thermodynamic energy difference by the RNA conformational change and protein-aptamer affinity. Here we first demonstrated the MAAS for hepatitis C helicase and replicase. The target proteins were detected up to 250nM with minimized blank signals and displayed high specificities 10-fold greater than in non-specific proteins. The MAAS provides valuable tools that can be adapted to a wide range of configurations in bioanalytical applications.     

Biomolecular structure refinement based on adaptive restraints using local-elevation simulation

Introducing experimental values as restraints into molecular dynamics (MD) simulation to bias the values of particular molecular properties, such as nuclear Overhauser effect intensities or distances, dipolar couplings, ³ J-coupling constants, chemical shifts or crystallographic structure factors, towards experimental values is a widely used structure refinement method. Because multiple torsion angle values ϕ correspond to the same ³ J-coupling constant and high-energy barriers are separating those, restraining ³ J-coupling constants remains difficult. A method to adaptively enforce restraints using a local elevation (LE) potential energy function is presented and applied to ³ J-coupling constant restraining in an MD simulation of hen egg-white lysozyme (HEWL). The method succesfully enhances sampling of the restrained torsion angles until the 37 experimental ³ J-coupling constant values are reached, thereby also improving the agreement with the 1,630 experimental NOE atom–atom distance upper bounds. Afterwards the torsional angles ϕ are kept restrained by the built-up local-elevation potential energies.     

DNA-Ag nanoclusters as fluorescence probe for turn-on aptamer sensor of small molecules

As promising substitutes for organic dyes and quantum dots, few-atom fluorescent silver nanoclusters (Ag NCs) have recently gained much attention in a wide range from cellular imaging to chemical/biological detection applications owing to their ultrasmall size (<2 nm), excellent photostability, good biocompatibility and water solubility. Herein, we design an aptamer, guanine-rich (G-rich) DNA and Ag NCs nanocomplex to investigate its ability for the detection of small molecules. The design contains two DNA strands which are both chimeric conjugates of the DNA aptamer sequence fragment and G-rich sequence fragment. Using cocaine as a model molecule, the two DNA strands are in free state if there is no cocaine present, and the formed Ag NCs through the reduction of Ag(+) by NaBH(4) show weak fluorescence emission. In the presence of cocaine, however, the two aptamer fragments bind cocaine, which in turn puts the two G-rich sequence fragments in proximity and the fluorescent intensity of DNA-Ag NCs enhances greatly. As a result, DNA-Ag NCs are demonstrated as a novel, cost-effective and turn-on fluorescent probe for the analysis of cocaine, with a detection limit of 0.1 μM. Besides, successful detection of adenosine triphosphate (ATP) with detection limit of 0.2 μM demonstrates its potential to be a general method.     

A simple fluorescent biosensor for theophylline based on its RNA aptamer

Theophylline is a potent bronchodilator with a narrow therapeutic index. A simple fluorescent biosensor that detects clinically relevant theophylline concentrations has been developed using the well-characterized theophylline binding RNA aptamer. Hybridization of the RNA aptamer to a fluorescently labeled DNA strand (FL-DNA) yields a fluorescent RNA:DNA hybrid that is sensitive to theophylline. The biosensor retains the remarkable selectivity of the RNA aptamer for theophylline over caffeine and is sensitive to 0-2 muM theophylline, well below the clinically relevant concentration (5-20 mg/L or approximately 10-50 muM). Adding a dabcyl quenching dye to the 3'-terminus of the fluorescently labeled DNA strand yielded a dual-labeled DNA strand (FL-DNA-Q) and increased the dynamic range of this simple biosensor from 1.5-fold to 4-fold.     

A ribonucleopeptide module for effective conversion of an RNA aptamer to a fluorescent sensor

Ribonucleopeptide (RNP) is a new class of scaffold for modular fluorescent sensors. We report here a short RNA motif that induces an efficient communication between the structural changes associated with the ligand-binding event of RNA aptamer and an optical response of a fluorescent RNP module. An optimized short RNA motif was used as a communication module for the rational design of modular RNP sensors. A modular combination of a GTP-binding RNA aptamer, the short RNA motif and the fluorophore-labeled RNP module afforded a fluorescent GTP sensor that retain the ligand-binding affinity of the parent aptamer.     

Detection of adenosine using surface-enhanced Raman scattering based on structure-switching signaling aptamer

In the present study, we report a novel sensitive method for the detection of adenosine using surface-enhanced Raman scattering (SERS) sensing platform based on a structure-switching aptamer. First, Ag-clad Au colloids film on a polished gold disc is prepared as enhanced substrate and modified with thiolated capture DNA. The formation of an aptamer/DNA duplex of expanded anti-adenosine aptamer and tetramethylrhodamine-labeled DNA (denoted TMR-DNA) is then developed, in which TMR-DNA could also hybridize completely with capture DNA. The introduction of adenosine thus triggers structure switching of the aptamer from aptamer/DNA duplex to aptamer/target complex. As a result, the released TMR-DNA is captured onto the SERS substrate, resulting in an increase of SERS signal. Under optimized assay conditions, a wide linear dynamic range (2.0x10(-8)M to 2x10(-6)M) was reached with low detection limit (1.0x10(-8)M). Moreover, high selectivity, stability and facile regeneration are achieved. The successful test demonstrates the feasibility of the strategy for adenosine assay.     

Amplified surface plasmon resonance immunosensor for interferon-gamma based on a streptavidin-incorporated aptamer

Interferon-gamma (IFN-γ) is associated with susceptibility to tuberculosis, which is a major public health problem worldwide. Although significant progress has been made with regard to the design of enzyme immunoassays for IFN-γ, this assay is still labor-intensive and time-consuming. We therefore designed a DNA aptamer hairpin structure for the detection of IFN-γ with high sensitivity and selectivity. A streptavidin DNA aptamer was incorporated into the IFN-γ binding aptamer probe for the amplified detection of the target molecules. Initially, the probe remained in the inactive configuration. The addition of IFN-γ induced the rearrangement of the aptamer structure, allowing the self-assembly of the active streptavidin aptamer conformation for the streptavidin molecular recognition. Under optimized conditions, the detection limit was determined to be 33 pM, with a dynamic range from 0.3 to 333 nM, both of which were superior to those of corresponding optical sensors. Because combined aptamers are composed of nucleic acids, this optical aptasensor provided the advantages of high sensitivity, simplicity, reusability, and no further labeling or sample pre-treatment.     

Electrochemical detection of thrombin based on aptamer and ferrocenylhexanethiol loaded silica nanocapsules

A sensitive and specific electrochemical assay for detection of thrombin based on aptamer and ferrocenylhexanethiol loaded silica nanocapsules (FcSH/SiNCs) amplification is described. In the protocol, a double aptamer sandwich structure was formed in the presence of thrombin, in which an aptamer-labeled FcSH/SiNCs for electrochemical detection, and a streptavidin-coated magnetic bead immobilized aptamer for rapid and specific separation of target protein. After separated from the sample mixture under a magnetic field, the sandwich complex was treated with NaOH to release the loaded ferrocenylhexanethiol (FcSH) from the silica nanocapsules (SiNCs). Differential pulse voltammetry (DPV) was employed to detect the released FcSH, which was related to the concentration of the thrombin. The method took advantage of sandwich binding of two affinity aptamers for increased specificity, high payload of FcSH in SiNCs for signal amplification, magnetic beads for fast magnetic separation. The peak current of released FcSH had a good linear relationship with the thrombin concentration in the range of 0.1-5 nmol/L, and the detection limit of thrombin in the method was 0.06 nmol/L. The detection was also specific for thrombin without being affected by other proteins, such as immunoglobulin G, bovine serum albumin, lysozyme and human serum albumin. The method has been used to detect thrombin in human serum albumin with minimum background interference.     

Biomolecular Engineering

Cover illustration: Biotechnology Journal's latest Special Issue on “Biomolecular Engineering” is based peer-reviewed papers derived from some of the best presentations at the 4^th International Conference on Biomolecular Engineering. The cover is a snapshot of solvated HER4/ErbB4 kinase domain with juxtamembrane region; image provided by Ravi Radhakrishnan.     

生物分子自组装

分子自组装是一种普遍存在于生命体系中的现象,是生命科学最本质的内容之一。开展分子自组装的研究具有重要意义,有助于人们从分子水平上认识自然界中生命形成和演变的过程,并为人们提供新的思路,开展生物医学基础研究、新材料合成及分子器件研制等。该文介绍了自组装的基本含义,对分子自组装技术在生物材料、生物分子器件研究方面的进展作了综述。     

多孔硅Bragg反射镜适配子生物传感器检测心肌肌钙蛋白I

通过脉冲腐蚀法制备多孔硅Bragg反射镜,将心肌肌钙蛋白I（cTnI）适配子共价固定到多孔硅Bragg反射镜的孔洞中,发现适配子能与cTnI分子特异性结合。定量分析不同浓度的cTnI与适配子结合后多孔硅Bragg反射镜的反射谱峰位的红移情况。结果表明：基于多孔硅Bragg反射镜适配子生物传感器的光学检测具有良好的特异性,且具有免标记及检测时间短等优异性能。传感器的线性检测范围0．05-4nmol／L,最低检测限为0．05nmol／L。     

A colorimetric sandwich-type assay for sensitive thrombin detection based on enzyme-linked aptamer assay

A colorimetric sandwich-type assay based on enzyme-linked aptamer assay has been developed for the fast and sensitive detection of as low as 25 fM of thrombin with high linearity. Aptamer-immobilized glass was used to capture the target analyte, whereas a second aptamer, functionalized with horseradish peroxidase (HRP), was employed for the conventional 3,5,3′,5′-tetramethylbenzidine (TMB)-based colorimetric detection. Without the troublesome antibody requirement of the conventional enzyme-linked immunosorbent assay (ELISA), as low as 25 fM of thrombin could be rapidly and reproducibly detected. This assay has superior, or at least equal, recovery and accuracy to that of conventional antibody-based ELISA.     

An electrochemical competitive biosensor for ochratoxin A based on a DNA biotinylated aptamer

Ochratoxin A (OTA) is one of the most important mycotoxin contaminants of foods, particularly cereals and cereal products, with strict low regulatory levels (of ppb) in many countries worldwide. An electrochemical competitive aptamer-based biosensor for OTA is described. Paramagnetic microparticle beads (MBs) were functionalized with an aptamer specific to OTA, and were allowed to compete with a solution of the mycotoxin conjugated to the enzyme horseradish peroxidase (OTA-HRP) and free OTA. After separation and washing steps helped with magnetic separations, the modified MBs were localized on disposable screen-printed carbon electrodes (SPCEs) under a magnetic field, and the product of the enzymatic reaction with the substrate was detected with differential-pulse voltammetry. In addition to magnetic separation assays, other competitive schemes (direct/indirect aptasensors performed on the SPCEs surface or using gold nanoparticles functionalized with the aptamer) were preliminary tested, optimized and compared. The magnetic aptasensor showed a linear response to OTA in the range 0.78-8.74 ng mL(-1) and a limit of detection of 0.07±0.01 ng mL(-1), and was accurately applied to extracts of certified and spiked wheat samples with an RSD lower than about 8%.     

Biomolecular diffusional association

The primary method for the computational study of biomolecular diffusional association is Brownian dynamics. Recent work has seen advances in the efficiency of computing association rates and in the accuracy of simulation models. New areas to which Brownian dynamics has been applied include protein polymerisation and protein adsorption to a surface. There has recently been particularly intense study of protein-protein association, and Brownian dynamics, together with other theoretical and experimental approaches, has led to new insights into the determinants of protein-protein binding kinetics.