Enzyme-conjugated hybridization chain reaction for magneto-controlled immunoassay of squamous cell carcinoma antigen with pH meter

A nanoparticle-based potentiometric immunoassay was designed for sensitive detection of squamous cell carcinoma antigen on a portable pH meter by coupling enzyme-labeled hybridization chain reaction with two alternating hairpin DNA probes for the signal amplification.     

Sensitive electrochemical monitoring of nucleic acids coupling DNA nanostructures with hybridization chain reaction

Methods based on metal nanotags have been developed for metallobioassay of nucleic acids, but most involve complicated labeling or stripping procedures and are unsuitable for routine use. Herein, we report the proof-of-concept of a novel and label-free metallobioassay for ultrasensitive electronic determination of human immunodeficiency virus (HIV)-related gene fragments at an ultralow concentration based on target-triggered long-range self-assembled DNA nanostructures and DNA-based hybridization chain reaction (HCR). The signal is amplified by silver nanotags on the DNA duplex. The assay mainly consists of capture probe, detection probe, and two different DNA hairpins. In the presence of target DNA, the capture probe immobilized on the sensor sandwiches target DNA with the 3′ end of detection probe. Another exposed part of detection probe at the 5′ end opens two alternating DNA hairpins in turn, and propagates a chain reaction of hybridization events to form a nicked double-helix. Finally, numerous silver nanotags are immobilized onto the long-range DNA nanostructures, each of which produces a strong electronic signal within the applied potentials. Under optimal conditions, the target-triggered long-range DNA nanostructures present good electrochemical behaviors for the detection of HIV DNA at a concentration as low as 0.5 fM. Importantly, the outstanding sensitivity can make this approach a promising scheme for development of next-generation DNA sensors without the need of enzyme labeling or fluorophore labeling.     

Enzyme-conjugated hybridization chain reaction for magneto-controlled immunoassay of squamous cell carcinoma antigen with pH meter

A nanoparticle-based potentiometric immunoassay was designed for the sensitive detection of squamous cell carcinoma antigen (SCCA; cervical carcinoma marker) on a portable pH meter coupling enzyme-labeled hybridization chain reaction (HCR) with two alternating hairpin DNA probes for the signal amplification. Initially, a sandwich-type immunoreaction was carried out between anti-SCCA capture antibody-conjugated magnetic bead and detection antibody/initiator strand-coated gold nanoparticle (AuNP). Then, the HCR reaction was readily executed between two glucose oxidase (GOx)-labeled hairpins through the initiator strand to form numerous GOx concatamers on the AuNP via the long nicked double-helix. The concatenated GOx oxidized glucose into gluconic acid and hydrogen peroxide, thus resulting in the pH change of the detection solution on a handheld pH meter. Several labeling protocols including GOx-antibody, GOx-AuNP-antibody and GOx-HCR-AuNP-antibody were investigated for detection of target SCCA, and improved analytical features were obtained with the immune-HCR assay. Under optimum conditions, the immune-HCR assay exhibited good pH responses for the determination of SCCA at a concentration as low as 5.7 pg/mL. Additionally, the immune-HCR assay had good precision and reproducibility, high specificity, and acceptable accuracy for analyzing human serum specimens.     

Label-free colorimetric aptasensor for sensitive detection of ochratoxin A utilizing hybridization chain reaction

The combination of high selectivity of aptamer with the peroxidase-mimicking property of DNAzyme has presented considerable opportunities for designing colorimetric aptasensor for detection of ochratoxin A (OTA). The activities of both aptamer (as biorecognition element) and DNAzyme (as signal amplification element) are blocked via base pairing in the hairpin structure. Hybridization chain reaction (HCR) between two hairpin DNAs was employed to further improve the sensitivity of this method. The presence of OTA triggers the opening of the hairpin structure and the beginning of HCR, which results in the release of many DNAzyme, and generates enhanced colorimetric signals, which is correlated to the amounts of OTA with linear range between 0.01 to 0.32 nM, and the limit of detection is 0.01 nM under optimal conditions. OTA in yellow rice wine and wheat flour samples was also detected using this method. We demonstrate that a new colorimetric method for the detection of OTA has been established, which is simple, easy to conduct, label-free, sensitive, high throughput, and cost-saving.     

Label-free and fluorescence turn-on aptasensor for protein detection via target-induced silver nanoclusters formation

A simple turn-on and homogeneous aptasensor, which relies on target induced formation of silver nanoclusters (Ag NCs), was developed for the determination of platelet-derived growth factor B-chain homodimer (PDGF-BB). The aptasensor contains two hairpin DNA probes termed as P1 and P2. P1 consists of the aptamer sequence of PDGF-BB. Meanwhile, P2 contains the Ag NCs nucleation sequence, which is blocked by the hairpin stem region. P1 and P2 can co-exist metastably in the absence of PDGF-BB and maintain hairpin structure. However, in the presence of PDGF-BB, the binding of PDGF-BB with aptamer will result in the hybridization between P1 and P2, and release the Ag NCs nucleation sequence. In this case, Ag NCs can be formed via the reduction of Ag⁺ by NaBH₄. By monitoring the increase in fluorescence intensity, we could detect the target protein with high sensitivity. The detection limit of this aptasensor is 0.37 nM, which is comparable with that of other reported aptasensors. Furthermore, this proposed aptasensor shows high selectivity toward its target protein. Thus, the proposed aptasensor based on target induced formation of Ag NCs could be used as a sensitive and selective platform for the detection of target protein.     

Detection of oncoprotein platelet-derived growth factor using a fluorescent signaling complex of an aptamer and TOTO

There have recently been advances in the application of aptamers, a new class of nucleic acids that bind specifically with target proteins, as protein recognition probes for biomedical study. The development of a signaling aptamer with the capability of simple and rapid real-time detection of disease-related proteins has attracted increasing interest. We have recently reported a new protein-detection strategy using a signaling aptamer based on a DNA molecular light-switching complex, [Ru(phen)₂(dppz)]²⁺. In this work we have used the commercially available DNA-intercalating dye, TOTO, to replace [Ru(phen)₂(dppz)]²⁺ for detection of oncoprotein platelet-derived growth factor BB (PDGF-BB), a potential cancer marker. Taking advantage of the high affinity of the aptamer to PDGF-BB and the sensitive fluorescence change of the aptamer–TOTO signaling complex on protein binding, PDGF-BB was detected in physiological buffer with high selectivity and sensitivity. The detection limit was 0.1 nmol L⁻¹, which was better than that of other reported aptamer-based methods for PDGF-BB, including that using [Ru(phen)₂(dppz)]²⁺. The method is very simple with no need for covalent labeling of the aptamer or probe synthesis. It facilitates wide application of the signaling mechanism to the analysis and study of cancer markers and other proteins.      

Determination of the platelet-derived growth factor BB by a competitive thrombin-linked aptamer-based Fluorometric assay

The authors describe a competitive aptamer based assay for detection of the platelet-derived growth factor BB (PDGF-BB; used as a model protein). The assay is making use of thrombin (a serine protease) as an enzyme label for reporting signals. It is taking advantage of a highly selective aptamer and of the fairly specific enzymatic activity of thrombin in terms of cleaving artificial fluorogenic peptide substrates. In a first step, the surface of wells of microplates is coated with PDGF-BB. On addition of a sample containing PDGF-BB, free and bound PDGF-BB compete with each other for binding to a DNA probe that consists of an aptamer sequence for PDGF-BB and a 29-mer aptamer sequence for thrombin. After washing, thrombin is added and will attach to the DNA probe that bound to the PDGF-BB on the microplates. Following addition of a fluorogenic peptide substrate, the bound thrombin will catalyze the cleavage of the substrate to generate a fluorescent product whose fluorescence intensity is measured at excitation/emission wavelengths of 370/440 nm. Fluorescence intensity decreases with increasing PDGF-BB concentration in the sample because less thrombin will bind to the PDGF-BB coated surface of the microplate. Under optimal conditions, PDGF-BB can be quantified in the 0.125 to 3 nM concentration range. This assay was successfully applied to the determination of PDGF-BB in spiked 100-fold diluted human serum.

Open image in new window

Graphical abstract In a competitive thrombin-linked aptamer assay, free platelet-derived growth factor BB (PDGF-BB) sample competes with the PDGF-BB coated on microplates for binding to a DNA probe containing PDGF-BB-binding aptamer and thrombin-binding aptamer. The labeled thrombin cleaves substrate into product, achieving signal generation.

     

A novel electrochemiluminescence aptasensor for protein based on a sensitive N-(aminobutyl)-N-ethylisoluminol-functionalized gold nanoprobe

A novel electrochemiluminescence (ECL) aptasensor for platelet-derived growth factor B chain (PDGF-BB) assay was developed by assembling N-(aminobutyl)-N-ethylisoluminol functionalized gold nanoparticles (ABEI-AuNPs) with aptamers as nanoprobes. In the protocol, the biotinylated aptamer capture probes were first immobilized on a streptavidin coated gold nanoparticle (AuNPs) modified electrode, afterwards, the target PDGF-BB and the ABEI-AuNPs tagged aptamer signal probe were successively attached to the modified electrode by virtue of the dimer structure of PDGF-BB to fabricate a "sandwich" conjugate modified electrode, i.e. an aptasensor. ECL measurement was carried out with a double-step potential in carbonate buffer solution containing H(2)O(2). The aptasensor showed high sensitivity and selectivity toward PDGF-BB and specificity toward PDGF-BB aptamer. The detection limit was as low as 2.7 × 10(-14) M. In this work, the ABEI-AuNPs synthesized by a simple seed growth method have been successfully used as aptamer labels, which greatly amplified the ECL signal by binding numbers of ABEI molecules on the surface of AuNPs. The ABEI-AuNPs signal amplification is superior to other reported signal amplification strategies based on aptamer-related polymerase chain reaction or functionalized nanoparticles in simplicity, stability, labeling property and practical applicability. And the ABEI-AuNPs based nanoprobe is more sensitive than the luminol functionalized AuNPs based nanoprobe. Moreover, such an ultra-sensitive and low-cost assay can be accomplished with a simple and fast procedure by using a simple ECL instrumentation. The aptasensor was also applied for the detection of PDGF-BB in human serum samples, showing great application potential. Given these advantages, the ECL aptasensor is well suited for the direct, sensitive and rapid detection of protein in complex clinical samples.     

A minimal hybridization chain reaction (HCR) system using peptide nucleic acids

The HCR represents a powerful tool for amplification in DNA-based circuitry and sensing applications, yet requires the use of long DNA sequences to grant hairpin metastability. Here we describe a minimal HCR system based on peptide nucleic acids (PNAs). A system comprising a 5-mer stem and 5-mer loop/toehold hairpins was found to be suitable to achieve rapid amplification. These hairpins were shown to yield >10-fold amplification in 2 h and be suitable for the detection of a cancer biomarker on live cells. The use of γ-peg-modified PNA was found to be beneficial.

A minimal peptide nucleic acid (PNA) HCR system based on a 5-mer stem and 5-mer loop/toehold hairpins was developed. The system was applied to the detection of a cancer biomarker on the surface of living cells.     

Effect of secondary structure on the thermodynamics and kinetics of PNA hybridization to DNA hairpins.

The binding of a series of PNA and DNA probes to a group of unusually stable DNA hairpins of the tetraloop motif has been observed using absorbance hypochromicity (ABS), circular dichroism (CD), and a colorimetric assay for PNA/DNA duplex detection. These results indicate that both stable PNA-DNA and DNA-DNA duplexes can be formed with these target hairpins, even when the melting temperatures for the resulting duplexes are up to 50 degrees C lower than that of the hairpin target. Both hairpin/single-stranded and hairpin/hairpin interactions are considered in the scope of these studies. Secondary structures in both target and probe molecules are shown to depress the melting temperatures and free energies of the probe-target duplexes. Kinetic analysis of hybridization yields reaction rates that are up to 160-fold slower than hybridization between two unstructured strands. The thermodynamic and kinetic obstacles to hybridization imposed by both target and probe secondary structure are significant concerns for the continued development of antisense agents and especially diagnostic probes.     

DNA hybridization chain reaction and DNA supersandwich self-assembly for ultrasensitive detection

The fabrication of sensitive sensors with high selectivity is highly desirable for the detection of some important biomarkers,such as nucleic acids,proteins,small molecules and ions.DNA hybridization chain reaction(HCR) and DNA supersandwich self-assembly(SSA) are two prevalent enzyme-free signal amplification strategies to improve sensitivity of the sensors.In this review,we firstly describe the characteristics about DNA HCR and DNA SSA,and then summarize the advances in the one-dimensional DNA nanostructures assisted by HCR and SSA.This review has been divided into three parts according to the two signal amplification methods and highlights recent progress in these two strategies to improve the detection sensitivity of proteins,nucleic acids,small molecules and ions.     

Impedimetric DNA‐Based Biosensor for Silver Ions Detection with Hemin/G‐Quadruplex Nanowire as Enhancer

A DNA‐based biosensor was reported for detection of silver ions (Ag⁺) by electrochemical impedance spectroscopy (EIS) with [Fe(CN)₆]^4?/3? as redox probe and hybridization chain reaction (HCR) induced hemin/G‐quadruplex nanowire as enhanced label. In the present of target Ag⁺, Ag⁺ interacted with cytosine‐cytosine (C? C) mismatch to form the stable C? Ag⁺? C complex with the aim of immobilizing the primer DNA on electrode, which thus triggered the HCR to form inert hemin/G‐quadruplex nanowire with an amplified EIS signal. As a result, the DNA biosensor showed a high sensitivity with the concentration range spanning from 0.1 nM to 100 µM and a detection limit of 0.05 nM.     

基于磁性辅助的杂交链反应放大检测三磷酸腺苷

本文提出了一种基于磁性辅助的杂交链反应放大检测三磷酸腺苷(ATP)的传感策略。磁性纳米粒子表面易于修饰,而且操作方便,具有很好的分离效果,能够提高生物传感的选择性。首先,利用生物素与链霉亲和素之间的亲和力作用,将生物素标记的ATP核酸适配体连接到链霉亲和素修饰的磁性纳米粒子表面,加入与ATP核酸适配体互补的一段DNA进行杂交,通过磁性分离除去未杂交上的DNA,加入靶向ATP,ATP与其适配体特异性结合将适配体的互补链通过磁性分离出来,磁性分离出的信号DNA继续用于下一步的杂交链反应,将信号放大,最后利用氧化石墨烯(GO)对荧光的猝灭效应降低背景荧光,达到高灵敏度、高选择性检测靶向ATP。其中,ATP的最低检测浓度为0.1nmol/L。     

Au NPs-aptamer conjugates as a powerful competitive reagent for ultrasensitive detection of small molecules by surface plasmon resonance spectroscopy

Features of Au NPs-aptamer conjugates as a powerful competitive reagent to substitute antibody in enhancing surface plasmon resonance spectroscopy (SPR) signal for the detection of small molecule are explored for the first time. In order to evaluate the sensing ability of Au NPs-aptamer conjugates as a competitive reagent, a novel SPR sensor based on indirect competitive inhibition assay (ICIA) for the detection of adenosine is constructed by employing the competitive reaction between antiadenosine aptamer with adenosine and antiadenosine aptamer with its partial complementary ss-DNA. The partial complementary ss-DNA of antiadenosine aptamer is firstly immobilized on SPR gold film as sensing surface. When the Au NPs-antiadenosine aptamer conjugates solution is added to SPR cell in the absence of adenosine, Au NPs-antiadenosine aptamer conjugates is adsorbed to SPR sensor by the DNA hybridization reaction, and results in a large change of SPR signal. However, the change of SPR signal is decreased when the mixing solution of adenosine with Au NPs-antiadenosine aptamer conjugates is added. This is because adenosine reacts with antiadenosine aptamer in Au NPs-antiadenosine aptamer conjugates and changes its structure from ss-DNA to tertiary structure, which cannot hybridize with its partial complementary ss-DNA immobilized on SPR gold surface. Based on this principle, a SPR sensor for indirect detection of adenosine can be developed. The experimental results confirm that the SPR sensor possesses a good sensitivity and a high selectivity for adenosine, which indirectly confirms that Au NPs-aptamer conjugates is a powerful competitive reagent. More significantly, it can be used to develop other SPR sensors based on ICIA to detect different targets by changing the corresponding type of aptamer in Au NPs-aptamer conjugates.     

Coupling hybridization chain reaction with DNAzyme recycling for enzyme-free and dual amplified sensitive fluorescent detection of methyltransferase activity

Aberrant DNA methylation originated from changes in DNA methyltransferase activity can lead to many genetic diseases and tumor types, and the monitoring of methyltransferase activity is thus of great importance in disease diagnosis and drug screening. In this work, by combing hybridization chain reaction (HCR) and metal ion-dependent DNAzyme recycling, we have developed a convenient enzyme-free signal amplification strategy for highly sensitive detection of DNA adenine methyltransferase (Dam MTase) activity and its inhibitors. The Dam MTase-induced methylation and subsequent cleavage of the methylated hairpin DNA probes by DpnI endonuclease lead to the release of ssDNA triggers for HCR formation of many Mg²⁺-dependent DNAzymes, in which the fluorescently quenched substrate sequences are catalytically and cyclically cleaved by Mg²⁺ to generate remarkably amplified fluorescent signals for highly sensitive detection of Dam MTase at 7.23 × 10⁻⁴ U/mL. In addition, the inhibition of different drugs to Dam MTase activity can also be evaluated with the developed method. With the advantages of simplicity and significant signal amplification over other common methods, the demonstrated biosensing approach thus offers great potential for highly sensitive detection of various methyltransferases and provides a convenient platform for drug screening for therapeutic applications.     

Aptamer structure switch fluorescence anisotropy assay for aflatoxin B1 using tetramethylrhodamine-guanine interaction to enhance signal change

Fluorescence anisotropy (FA) assay in homogenous solution is simple, sensitive and reproducible. Here, we reported an aptamer structure switch FA assay for detection of aflatoxin B1 (AFB1), one of the most toxic mycotoxins, by using tetramethylrhodamine (TMR)-labeled aptamer probe and its complementary DNA (cDNA) with tandem G bases extension, to meet the demand in sensitive and selective detection of AFB1. The hybridization of aptamer and cDNA drew TMR close to the repeated guanine (G) bases, and a high FA value was induced due to TMR-G interaction and restricted local rotation of TMR. In the presence of AFB1, aptamer bound to AFB1 instead of the cDNA due to competition. Thus, the TMR-G interaction was eliminated, and FA value of TMR decreased. This assay enabled the detection of AFB1 with detection limit of 125 pmol/L and dynamic range from 125 pmol/L to 31.2 nmol/L     

Electrochemical analysis of microRNAs with hybridization chain reaction-based triple signal amplification

Selective and sensitive detection of trace microRNA is important for early diagnosis of diseases due to its expression level related to diseases. Herein, a triple signal amplification strategy is developed for trace microRNA-21 (miRNA-21) detection by combining with target-triggered cyclic strand displacement reaction (TCSDR), hybridization chain reaction (HCR) and enzyme catalytic amplification. Four DNA hairpins (H1, H2, H3, H4) are employed to form an ultralong double-strand DNA (dsDNA) structure, which is initiated by target miRNA-21. As H3 and H4 are labeled with horseradish peroxidase (HRP), numerous HRPs are loaded on the long dsDNA, producing significantly enhanced electrocatalytic signals in the hydrogen peroxide (H₂O₂) and 3,3′,5,5′-tetramethylbenzidine (TMB) reaction strategy. Compared with single signal amplification, the triple signal amplification strategy shows higher electrochemical response, wider dynamic range and lower detection limit for miRNA-21 detection with excellent selectivity, reproducibility and stability. Taking advantage of the triple signal amplification strategy, the proposed electrochemical biosensor can detect miRNA-21 in 10 HeLa cell lysates, suggesting that it is a promising method for fruitful assay in clinical diagnosis.     

Ratiometric Detection of microRNA Using Hybridization Chain Reaction and Fluorogenic Silver Nanoclusters

miRNA (miR)-155 is a potential biomarker for breast cancers. We aimed at developing a nanosensor for miR-155 detection by integrating hybridization chain reaction (HCR) and silver nanoclusters (AgNCs). HCR serves as an enzyme-free and isothermal amplification method, whereas AgNCs provide a built-in fluorogenic detection probe that could simplify the downstream analysis. The two components were integrated by adding a nucleation sequence of AgNCs to the hairpin of HCR. The working principle was based on the influence of microenvironment towards the hosted AgNCs, whereby unfolding of hairpin upon HCR has manipulated the distance between the hosted AgNCs and cytosine-rich toehold region of hairpin. As such, the dominant emission of AgNCs changed from red to yellow in the absence and presence of miR-155, enabling a ratiometric measurement of miR with high sensitivity. The limit of detection (LOD) of our HCR-AgNCs nanosensor is 1.13 fM in buffered solution. We have also tested the assay in diluted serum samples, with comparable LOD of 1.58 fM obtained. This shows the great promise of our HCR-AgNCs nanosensor for clinical application.     

AFM Imaging of Hybridization Chain Reaction Mediated Signal Transmission between Two DNA Origami Structures

Signal transfer is central to the controlled exchange of information in biology and advanced technologies. Therefore, the development of reliable, long‐range signal transfer systems for artificial nanoscale assemblies is of great scientific interest. We have designed such a system for the signal transfer between two connected DNA nanostructures, using the hybridization chain reaction (HCR). Two sets of metastable DNA hairpins, one of which is immobilized at specific points along tracks on DNA origami structures, are polymerized to form a continuous DNA duplex, which is visible using atomic force microscopy (AFM). Upon addition of a designed initiator, the initiation signal is efficiently transferred more than 200 nm from a specific location on one origami structure to an end point on another origami structure. The system shows no significant loss of signal when crossing from one nanostructure to another and, therefore, has the potential to be applied to larger multi‐component DNA assemblies.     

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.