Label-free and non-enzymatic detection of DNA based on hybridization chain reaction amplification and dsDNA-templated copper nanoparticles

A label-free and non-enzymatic amplification fluorescent method for detection of DNA has been developed by using hybridization chain reaction (HCR) and dsDNA-templated copper nanoparticles (CuNPs). First, the biotinylated capture DNA probes were immobilized on the streptavidin-modified beads through the interaction of biotin and streptavidin. Then, target DNA hybridized with the capture DNA probes, which formed a hybridized DNA with sticky end. The sticky end triggered the HCR process and formation of dsDNA polymers while two hairpin probes coexisted. Subsequently, the dsDNA polymers were employed as template for synthesis of CuNPs with excellent fluorescent properties, which provided a label-free, non-enzymatic signal response. Meanwhile, the fluorescence sensing depended on the target DNA triggered HCR, which render this method a high selectivity against single-base mismatch sequences. The concept and methodology developed in this work show great promise in the quantitative detection of DNA in biological and medical applications.     

Electrochemical Quantitative Analysis of Nucleic Acids Using β‐Cyclodextrin Modified Gold Electrode

We present an electrochemical biosensor for the analysis of nucleic acids upon hybridization on the β‐cyclodextrin (β‐CD)‐modified gold electrode. The strategy is based on the following: The 5’‐ferrocene‐labeled single stranded capture probe DNA (5’‐fc‐ss‐DNA) was incorporated into the cavity of thiolated β‐CD which was immobilized on the surface of gold electrode. After hybridization of complementary target DNA, hybridized double stranded DNA (ds‐DNA) was released from the cavity of β‐CD. The difference of electrochemical properties on the modified gold electrode was characterized by cyclic voltametry and surface plasmon resonance. We successfully applied this method to the investigation of the sensor responses due to hybridization on various concentrations of applied target DNA. As a result, the label‐free electrochemical DNA sensor can detect the target DNA with a detection limit of 1.08 nM. Finally, our method does not require either hybridization indicators or other signalling molecules such as DNA intercalaters which most of electrochemical hybridization detection systems require.     

Hairpin Assembly Amplified Electrochemical Biosensor for Highly Sensitive and Specific Detection of DNA

In this report, a simple electrochemical biosensor has been developed for highly sensitive and specific detection of DNA based on hairpin assembly amplification. In the presence of target DNA, the biotin‐labelled hairpin H1 is opened by hybridizing with target DNA through complementary sequences. Then the opened hairpin H1 assembles with the hairpin H2 to displace the target DNA, generating H1‐H2 complex. The displaced target DNA could trigger the next cycle of hairpins assembly, resulting in the generation of numerous H1‐H2 complexes. Subsequently, the H1‐H2 complex hybridizes with the capture probe immobilized on the electrode. Finally, the streptavidin alkaline phosphatase (ST‐ALP) binds to biotin in the capture probe‐H1‐H2 complex and catalyzes the substrate α‐naphthol (α‐NP) to produce electrochemical signal. To make a more fascinating hairpin assembly amplification strategy in signal amplification, mismatched base sequences are designed in hairpin H2 to decrease non‐specific binding of the hairpin substrates. The developed biosensor achieves a sensitivity of 20 pM with a linear range from 25 pM to 25 nM, and shows high selectivity toward single‐base mismatch. Thus, the proposed electrochemical biosensor might have the potential for early clinical diagnosis and therapy.     

Label-free electrochemical detection of DNA hybridization on gold electrode

A label-free electrochemical detection protocol for DNA hybridization is reported for the first time by using a gold electrode (AuE). The oxidation signal of guanine was monitored at +0.73 V by using square wave voltammetry (SWV) on self-assembled l-cysteine monolayer (SAM) modified AuE. The electrochemical determination of hybridization between an inosine substituted capture probe and native target DNA was also accomplished. 6-mer adenine probe was covalently attached to SAM via its amino link at 5^′ end. Then, 6-mer thymine-tag of the capture probe was hybridized with the adenine probe, thus left the rest of the oligonucleotide available for hybridization with the target. The dependence of the guanine signal upon the concentration of the target was observed. Probe modified AuE was also challenged with non-complementary and mismatch containing oligonucletides. Label-free detection of hybridization on AuE is greatly advantageous over the existing carbon and mercury electrode materials, because of its potential applicability to microfabrication techniques. Performance characteristics of the genosensor are described, along with future prospects.     

Chemiluminescent detection of DNA hybridization and single-nucleotide polymorphisms on a solid surface using target-primed rolling circle amplification

A new chemiluminescent (CL) method has been developed for the sensitive detection of DNA hybridization and single-nucleotide polymorphisms (SNPs) with target-primed rolling circle amplification (RCA). The capture oligonucleotide probe is firstly immobilized on a polystyrene well plate and then hybridized with the wild DNA target. A designed padlock probe is circularized after perfect hybridization to the DNA target. Then the RCA reaction can be initiated from the DNA target that acts as a primer and generates a long tandem single-strand of DNA with repeat sequences. In contrast, the mutant DNA target, which contains a mismatched base with the padlock probe, cannot initiate the RCA reaction and primes only a limited extension with the unligated padlock probe. Afterwards, a biotinylated oligonucleotide is used to hybridize with the RCA product in each repeat sequence and streptavidin-alkaline phosphatase (STV-AP) is employed to combine the anchored biotin. The DNA target is detected with the CL reaction of STV-AP and 3-(2'-spiroadamantane)-4-methoxy-4-(3'-phosphoryloxy)phenyl-1,2-dioxetane (AMPPD). With the RCA-based method, the sensitivity of DNA detection can be increased by about two orders of magnitude compared with that of direct DNA hybridization. A DNA target as low as 3.6 pM can be detected. Wild-type DNA and the one-base mutant DNA can be differentiated with high selectivity through this RCA reaction.     

A Sandwich‐Type Electrochemical Biosensor for Detection of BCR/ABL Fusion Gene Using Locked Nucleic Acids on Gold Electrode

In this study, a sandwich‐type electrochemical enzyme‐based LNA‐modified DNA biosensor was developed to detect relative gene in chronic Myelogenous Leukemia first. This biosensor is based on a ‘sandwich’ detection strategy, which involves a pair of probes (a capture probe immobilized at the electrode surface and a reporter probe labeled biotin as an affinity tag for avidin‐HRP) modified LNA. Since biotin can be connected with avidin‐HRP, this biosensor offers an enzymatically amplified electrochemical current signal for the detection of target DNA. This new pattern exhibits high sensitivity and selectivity, and this biosensor has been used for an assay of PCR real sample with satisfactory result.     

Determination of micro‐RNA in cardiomyoblast cells using CE with LIF detection

Micro‐RNAs (miRNAs) are small, endogenous, singlestranded, and noncoding RNAs. The miRNAs have been found to perform important functions in many cellular processes, such as development, proliferation, differentiation, and apoptosis. Circulating miRNAs have been proposed as emerging biomarkers in diseases such as cancer, diabetes, and cardiovascular disease including acute myocardial infarction (AMI). In this study, we developed CE with LIF (CE‐LIF) using fluorescence‐labeled DNA probe for determination of low abundance miRNA in cell extracts. The target miRNA is miRNA‐499, a biomarker candidate of AMI with low abundance in biological samples. In order to measure the trace level of miRNA, we optimized the hybridization conditions such as hybridization time, temperature, and buffer solution. The highest fluorescence intensity of the hybridized miRNA‐499 was found when hybridization was conducted at 40°C in 50 mM Tris‐acetate (pH 8.0) buffer containing 50 mM NaCl, and 10 mM EDTA for 15 min. The hybridized miRNA‐499 was detected in cultured H9c2 cardiomyoblast cells and the analysis of miRNA‐499 was completed within 1 h using CE‐LIF. These results showed the potential of CE for fast, specific, and sensitive high‐throughput analysis of low‐abundance miRNAs in cell extracts, biofluids, and tissues.     

Rapid Electrochemical Assessment of Tumor Suppressor Gene Methylations in Raw Human Serum and Tumor Cells and Tissues Using Immunomagnetic Beads and Selective DNA Hybridization

We report a rapid and sensitive electrochemical strategy for the detection of gene‐specific 5‐methylcytosine DNA methylation. Magnetic beads (MBs) modified with an antibody for 5‐methylcytosines (5‐mC) are used for the capture of any 5‐mC methylated single‐stranded (ss)DNA sequence. A flanking region next to the 5‐mCs of the captured methylated ssDNA is recognized by hybridization with a synthetic biotinylated DNA sequence. Amperometric transduction at disposable screen‐printed carbon electrodes (SPCEs) is employed. The developed biosensor has a dynamic range from 3.9 to 500 pm and a limit of detection of 1.2 pm for the methylated synthetic sequence of the tumor suppressor gene O‐6‐methylguanine‐DNA methyltransferase (MGMT) promoter region. The method is applied in the 45‐min analysis of specific methylation in the MGMT promoter region directly in raw spiked human serum samples and in genomic DNA extracted from U‐87 glioblastoma cells and paraffin‐embedded brain tumor tissues without any amplification and pretreatment step.     

Chitosan/Nitrogen Doped Reduced Graphene Oxide Modified Biosensor for Impedimetric Detection of microRNA

The development of a low‐cost and disposable biosensor platform for the sensitive and rapid detection of microRNAs (miRNAs) is of great interest for healthcare, pharmaceuticals, and medical science. We designed an impedimetric biosensing platform using Chitosan (CHIT)/nitrogen doped reduced graphene oxide (NRGO) conductive composite to modify the surface of pencil graphite electrodes (PGE) for the sensitive detection of miRNAs. An initial optimisation protocol involved investigation of the effect of NRGO concentration and miR 660 DNA probe concentration on the response of the modified electrode. After the optimization protocol, the sequence‐selective hybridization between miR 660 DNA probe and its RNA target was evaluated by measuring changes on charge transfer resistance, R_ct values. Moreover, the selectivity of impedimetric biosensor was tested in the presence of non‐complementary miRNA (NC) sequences, such as miR 34a and miR 16. The hybridization process was examined both in phosphate buffer (PBS) and in PBS diluted fetal bovine serum (FBS:PBS) solutions. The biosensor demonstrated a detection limit of 1.72 μg/mL in PBS and 1.65 μg/mL in FBS:PBS diluted solution. Given the easy, quick and disposable attributes, the proposed conductive nanocomposite biosensor platform shows great promise as a low‐cost sensor kit for healthcare monitoring, clinical diagnostics, and biomedical devices.     

An electrochemical biosensor based on DNA “nano-bridge” for amplified detection of exosomal microRNAs

Exosomal miRNAs, as potential biomarkers in liquid biopsy for cancer early diagnosis, have aroused widespread concern. Herein, an electrochemical biosensor based on DNA “nano-bridge” was designed and applied to detect exosomal microRNA-21 (miR-21) derived from breast cancer cells. In brief, the target miR-21 can specifically open the hairpin probe 1(HP1) labeled on the gold electrode (GE) surface through strand displacement reaction. Thus the exposed loop region of HP1 can act as an initiator sequence to activate the hybridization chain reaction (HCR) between two kinetically trapped hairpin probes: HP2 immobilized on the GE surface and biotin labeled HP3 in solution. Cascade HCR leads to the formation of DNA “nano-bridge” tethered to the GE surface with a great deal of “piers”. Upon addition of avidin-modified horseradish peroxidase (HRP), numerous HRP were bound to the formed “nano-bridge” through biotin-avidin interaction to arouse tremendous current signal. In theory, only a single miR-21 is able to trigger the continuous HCR between HP2 and HP3 until all of the HP2 are exhausted. Therefore the proposed biosensor achieved ultrahigh sensitivity toward miR-21 with the detection limit down to 168 amol/L, as well as little cross-hybridization even at the single-base-mismatched level. Successful attempts were also made in the detection of exosomal miR-21 obtained from the MCF-7 of breast cancer cell line. To our knowledge, this is the first attempt to built horizontal DNA nano-structure on the electrode surface for exosomal miRNAs detection. In a word, the high sensitivity, selectivity, low cost make the proposed method hold great potential application for early point-of-care (POC) diagnostics of cancer.     

DNA-based hybridization chain reaction amplification for assaying the effect of environmental phenolic hormone on DNA methyltransferase activity

In this work, a novel electrochemical protocol with signal amplification for determination of DNA methylation and methyltransferase activity using DNA-based hybridization chain reaction (HCR) was proposed. After the gold electrode was modified with dsDNA, it was treated with M.SssI MTase, HpaII endonuclease, respectively. And then the HCR was initiated by the target DNA and two hairpin helper DNAs, which lead to the formation of extended dsDNA polymers on the electrode surface. The signal was amplified by the labeled biotin on the hairpin probes. As a result, the streptavidin-alkaline phosphatase (S-ALP) conjugated on the electrode surface through the specific interaction between biotin and S-ALP. ALP could convert 1-naphthyl phosphate into 1-naphthol and the latter could be electrochemically oxidized, which was used to monitor the methylation event and MTase activity. The HCR assay presents good electrochemical responses for the determination of M.SssI MTase at a concentration as low as 0.0067 unit mL⁻¹. Moreover, the effects of anti-cancer drug and environmental phenolic hormone on M.SssI MTase activity were also investigated. The results indicated that 5-fluorouracil and daunorubicin hydrochloride could inhibit the activity, and the opposite results were obtained with bisphenol A and nonylphenol. Therefore, this method can not only provide a platform to screen the inhibitors of DNA MTase and develop new anticancer drugs, but also offer a novel technique to investigate the possible carcinogenesis mechanism.     

Electrochemical detection of miRNA-222 by use of a magnetic bead-based bioassay

MicroRNAs (miRNAs, miRs) are naturally occurring small RNAs (approximately 22 nucleotides in length) that have critical functions in a variety of biological processes, including tumorigenesis. They are an important target for detection technology for future medical diagnostics. In this paper we report an electrochemical method for miRNA detection based on paramagnetic beads and enzyme amplification. In particular, miR 222 was chosen as model sequence, because of its involvement in brain, lung, and liver cancers. The proposed bioassay is based on biotinylated DNA capture probes immobilized on streptavidin-coated paramagnetic beads. Total RNA was extracted from the cell sample, enriched for small RNA, biotinylated, and then hybridized with the capture probe on the beads. The beads were then incubated with streptavidin–alkaline phosphatase and exposed to the appropriate enzymatic substrate. The product of the enzymatic reaction was electrochemically monitored. The assay was finally tested with a compact microfluidic device which enables multiplexed analysis of eight different samples with a detection limit of 7 pmol L^?1 and RSD?=?15 %. RNA samples from non-small-cell lung cancer and glioblastoma cell lines were also analyzed.     

Direct Determination of miR‐21 in Total RNA Extracted from Breast Cancer Samples Using Magnetosensing Platforms and the p19 Viral Protein as Detector Bioreceptor

A novel magnetobiosensing approach for the rapid, sensitive and selective miR‐21 detection is reported involving the use of a specific RNA probe (antimiR‐21), streptavidin‐magnetic beads (Strep‐MBs), the siRNA Binding Protein p19 as detector bioreceptor, and amperometric detection with the H₂O₂/hydroquinone (HQ) system at disposable screen‐printed carbon electrodes. The magnetosensor exhibited a dynamic range from 1.4 to 10 nM and a detection limit of 4.2 fmol of synthetic target miR‐21 without any amplification step in 75 min. The usefulness of the approach was evaluated by analyzing total RNA (RNA_t) extracted from metastatic breast cancer cell lines, human tissues and breast cytologies.     

Hybridization detection of enzyme-labeled DNA at electrically heated electrodes

In this report we describe an electrochemical DNA hybridization sensor approach, in which signal amplification is achieved using heated electrodes together with an enzyme as DNA-label. On the surface of the heatable low temperature co-fired ceramic (LTCC) gold electrode, an immobilized thiolated capture probe was hybridized with a biotinylated target using alkaline phosphatase (SA-ALP) as reporter molecule. The enzyme label converted the redox-inactive substrate 1-naphthyl phosphate (NAP) into the redox-active 1-naphthol voltammetrically determined at the modified gold LTCC electrode. During the measurement only the electrode was heated leaving the bulk solution at ambient temperature. Elevated temperature during detection led to increased enzyme activity and enhanced analytical signals for DNA hybridization detection. The limit of detection at 53 °C electrode temperature was 1.2 nmol/L.     

基于杂交链式反应辅助多重信号放大的端粒酶灵敏检测

端粒酶是真核细胞维持端粒长度的关键逆转录酶,其生物活性的高低可以为多种癌症的临床诊断和预后治疗提供有价值的信息.本研究以人宫颈癌细胞(HeLa细胞)裂解液中的端粒酶为研究对象,通过借助杂交链式反应辅助多重信号放大策略,提出了一种新颖、灵敏的检测端粒酶电化学方法.首先将端粒酶的延伸引物自组装在金电极表面,当端粒酶存在时,端粒酶能够催化引物的延伸,产生与发卡环探针H1部分互补的序列,进而引发杂交链式反应,形成由两个发卡环探针(H1和H2)交替杂交而形成的DNA长链.由于H1和H2末端均修饰有生物素,加入链霉亲和素修饰辣根过氧化物酶后,辣根过氧化物酶被被连接到电极表面,催化邻苯二胺氧化生成2,3-二氨基吩嗪,产生显著的电化学信号.实验结果表明,本研究建立的端粒酶电化学检测方法高效、可行,线性范围宽,灵敏度高,可以检测每毫升10个HeLa细胞裂解液中的端粒酶.本方法具有较好的选择性,能有效区分端粒酶和对照蛋白.     

Ultrasensitive electrogenerated chemiluminescence detection of DNA hybridization using carbon-nanotubes loaded with tris(2,2′-bipyridyl) ruthenium derivative tags

An ultrasensitive electrogenerated chemiluminescence (ECL) detection method of DNA hybridization based on single-walled carbon-nanotubes (SWNT) carrying a large number of ruthenium complex tags was developed. The probe single strand DNA (ss-DNA) and ruthenium complex were loaded at SWNT, which was taken as an ECL probe. When the capture ss-DNA with a thiol group was self-assembled onto the surface of gold electrode, and then hybridized with target ss-DNA and further hybridized with the ECL probe to form DNA sandwich conjugate, a strong ECL response was electrochemically generated. The ECL intensity was linearly related to the concentration of perfect-matched target ss-DNA in the range from 2.4 × 10⁻¹⁴ to 1.7 × 10⁻¹² M with a detection limit of 9.0 × l0⁻¹⁵ M. The ECL signal difference permitted to discriminate the perfect-matched target ss-DNA and two-base-mismatched ss-DNA. This work demonstrates that SWNT can provide an amplification platform for carrying a large number of ECL probe and thus resulting in an ultrasensitive ECL detection of DNA hybridization.     

Hyperbranched Hybridization Chain Reaction for Triggered Signal Amplification and Concatenated Logic Circuits

A hyper‐branched hybridization chain reaction (HB‐HCR) is presented herein, which consists of only six species that can metastably coexist until the introduction of an initiator DNA to trigger a cascade of hybridization events, leading to the self‐sustained assembly of hyper‐branched and nicked double‐stranded DNA structures. The system can readily achieve ultrasensitive detection of target DNA. Moreover, the HB‐HCR principle is successfully applied to construct three‐input concatenated logic circuits with excellent specificity and extended to design a security‐mimicking keypad lock system. Significantly, the HB‐HCR‐based keypad lock can alarm immediately if the “password” is incorrect. Overall, the proposed HB‐HCR with high amplification efficiency is simple, homogeneous, fast, robust, and low‐cost, and holds great promise in the development of biosensing, in the programmable assembly of DNA architectures, and in molecular logic operations.     

Rapid and sensitive DNA target detection using enzyme amplified electrochemical detection based on microchip

A rapid and sensitive DNA targets detection using enzyme amplified electrochemical detection (ED) based on microchip was described. We employed a biotin‐modified DNA, which reacted with avidin‐conjugated horseradish peroxidase (avidin–HRP) to obtain the HRP‐labeled DNA probe and hybridized with its complementary target. After hybridization, the mixture containing dsDNA‐HRP, excess ssDNA‐HRP, and remaining avidin–HRP was separated by MCE. The separations were performed at a separation voltage of +1.6 kV and were completed in less than 100 s. The HRP was used as catalytic labels to catalyze H₂O₂/o‐aminophenol reaction. Target DNA could be detected by the HRP‐catalyzed reduction with ED. With this protocol, the limits of quantification for the hybridization assay of 21‐ and 39‐mer DNA fragments were of 8×10^?12 M and 1.2×10^?11 M, respectively. The proposed method has been applied satisfactorily in the analysis of Escherichia coli genomic DNA. We selected the detection of PCR amplifications from the gene of E. coli to test the real applicability of our method. By using an asymmetric PCR protocol, we obtained ssDNA targets of 148 bp that could be directly hybridized by the single‐stranded probe and detected with ED.     

Hybridization Detection of Osmium Tetroxide Bipyridine‐Labeled DNA and RNA on Heated Gold Wire Electrodes

We report about hybridization detection of different nucleic acids on capture probe‐modified heated gold wire electrodes. We have compared three kinds of nucleic acid targets: DNA, uracil‐conjugated DNA, and RNA. All three sorts of nucleic acids targets could be labeled with osmium tetroxide bipyridine, hybridized with immobilized DNA capture probes and then detected by square‐wave voltammetry. Heating the gold electrode instead of the entire bulk hybridization solution leads to improved hybridization efficiency in most cases. The reason could be found in a thermal micro‐stirring effect around the heated wire electrode. Also selectivity was improved. Mismatches could be discriminated for DNA and uracil‐conjugated DNA targets. Mismatches in RNA strands, however, are more difficult to detect due to relatively stable secondary structures.     

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.