Detection of DNA Hybridization via Fluorescence Intensity Variations of ZnSe-DNA Quantum Dot Biosensors

ZnSe quantum dots (QDs) that were capped with 11-mercaptoundecanoic acid (MUA) and conjugated to amino-modified ssDNA molecules exhibited variations in fluorescence emission intensity upon hybridization with complementary ssDNA in solution, a phenomenon that can be exploited for rapid detection of free ssDNA sequences. Conjugation of MUA-capped ZnSe QDs to amino-modified ssDNA molecules resulted in increased fluorescence emission intensity and stability at room temperature. Increasing the length of the ssDNA, that was conjugated to the QDs, resulted in increased fluorescence emission intensity up to a length of about 50 nucleotide bases, beyond which the peak emission intensity reached a plateau. Hybridization of QD-ssDNA conjugates with complementary ssDNA, either in free form or bound to QDs from the same population, resulted in additional fluorescence emission intensity amplification. A small red shift was observed when three-dimensional QD-dsDNA-QD structures were formed. The QD-ssDNA sensors with single ssDNA molecule per QD were developed and used for rapid quantitative detection of fully or partially complementary free ssDNA sequences in aqueous solution. Partial hybridization of the QD-ssDNA sensors with short ssDNA targets resulted in smaller QD emission intensity amplification, when compared to full hybridization. A QD-ssDNA sensor containing a sequence corresponding to the hemoglobin beta gene was used to detect and discriminate between free ssDNA targets consisting of a complementary ssDNA sequence and targets containing a single-base mutation that can cause sickle-cell anemia. Such QD-based biosensors can form the basis for rapid separation-free assays that can be used to detect target biomolecules in solution.     

Lable‐Free Electrochemical DNA Sensor Based on Gold Nanoparticles/Poly(neutral red) Modified Electrode

We present a new strategy for the label‐free electrochemical detection of DNA hybridization based on gold nanoparticles (AuNPs)/poly(neutral red) (PNR) modified electrode. Probe oligonucledotides with thiol groups at the 5‐end were covalently linked onto the surface of AuNPs/PNR modified electrode via S‐Au binding. The hybridization event was monitored by using differential pulse voltammetry (DPV) upon hybridization generates electrochemical changes at the PNR‐solution interface. A significant decrease in the peak current was observed upon hybridization of probe with complementary target ssDNA, whereas no obvious change was observed with noncomplementary target ssDNA. And the DNA sensor also showed a high selectivity for detecting one‐mismatched and three‐mismatched target ssDNA and a high sensitivity for detecting complementary target ssDNA, the detection limit is 4.2×10^?12 M for complementary target ssDNA. In addition, the DNA biosensor showed an excellent reproducibility and stability under the DNA‐hybridization conditions.     

Detection of influenza A virus based on fluorescence resonance energy transfer from quantum dots to carbon nanotubes

In this paper, a simple and sensitive approach for H5N1 DNA detection was described based on the fluorescence resonance energy transfer (FRET) from quantum dots (QDs) to carbon nanotubes (CNTs) in a QDs-ssDNA/oxCNTs system, in which the QDs (CdTe) modified with ssDNA were used as donors. In the initial stage, with the strong interaction between ssDNA and oxCNTs, QDs fluorescence was effectively quenched. Upon the recognition of the target, the effective competitive bindings of it to QDs-ssDNA occurred, which decreased the interactions between the QDs-ssDNA and oxCNTs, leading to the recovery of the QDs fluorescence. The recovered fluorescence of QDs was linearly proportional to the concentration of the target in the range of 0.01–20 μM with a detection limit of 9.39 nM. Moreover, even a single-base mismatched target with the same concentration of target DNA can only recover a limited low fluorescence of QDs, illustrating the good anti-interference performance of this QDs-ssDNA/oxCNTs system. This FRET platform in the QDs-ssDNA/oxCNTs system was facilitated to the simple, sensitive and quantitative detection of virus nucleic acids and could have a wide range of applications in molecular diagnosis.     

A simple visual method for DNA detection based on the formation of gold nanoparticles

A simple visual method for DNA detection during the formation of gold nanoparticles (AuNPs) was developed based on different electrostatic properties of single strand DNA (ssDNA) and double strand DNA (dsDNA). Since the ssDNA is easy to bind to AuNPs due to its exposed bases which could prevent salt-induced aggregation of AuNPs. The dsDNA always present negative charge because its negatively charged phosphate backbone is exposed. In this case, the dsDNA could disturb the adsorption between dsDNA and AuNPs and result in non-aggregation of AuNPs. After hybridization, chloroauric acid and ascorbic acid were added to the mixture solution, and the solution changed to red immediately and turned to purple in 10 min in the present of target DNA. TEM results confirmed that the change of color stemed from aggregation of AuNPs. In order to obtain accurate results by naked eye, the DNA detection assay should be conducted under pH 7.0.     

A simple visual method for DNA detection based on the formation of gold nanoparticles

A simple visual method for DNA detection during the formation of gold nanoparticles (AuNPs) was developed based on different electrostatic properties of single strand DNA (ssDNA) and double strand DNA (dsDNA). It could identify target DNA in 10 min.     

基于阳离子型共轭聚合物和核酸适体的腺苷检测新方法

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

基于聚多巴胺磁性纳米微球的洛美沙星适配体筛选研究

基于纳米材料与单链核苷酸可能存在的氢键作用、π-π结合、电荷转移等非共价结合方式,可快速区分对目标靶分子有特异性结合的单链核酸适配体候选分子,从而缩短适配体筛选周期、提高筛选的成功率.本研究采用聚多巴胺磁性纳米微球(MNPs@PDAs)为分离载体,以洛美沙星(LMX)为靶标分子,利用磁分离技术建立了一种小分子的适配体筛选新方法.经过7轮筛选,获得了对洛美沙星分子具有高亲和性(KD=(17.57±0.5)nmol/L)的核酸适配体AF-3,且AF-3对于结构相似分子培氟沙星(PEFX)、氧氟沙星(OFLX)、诺氟沙星(NFLX)不具有亲和性.基于MNPs@PDAs的筛选方法有望于应用于其它重要靶分子的高效适配体探针获取.     

Simultaneous electrochemical DNA hybridization assay for PAT and FMV 35S gene sequence using quantum dots as labels

An electrochemical method for the simultaneous detection of two different DNA sequences from PAT and FMV 35S gene sequence using CdS and PbS quantum dots （QDs） as labels was described. The QDs were readily functionalized with oligonucleotides as electrochemical DNA probes and selectively hybridized to the complementary sequences immobilized on the microplate. The QDs anchored on the hybrids were dissolved in the solution by the oxidation of HNO3 and further detected by a sensitive differential pulse anodic stripping voltammetric method （DPASV）. The DPASV signals of the oxidation of Cd^2＋ and Pb^2＋ ions present in the solution were different and reflected the identity of corresponding ssDNA targets sequences.     

细菌的核酸适配体筛选的研究进展

核酸适配体(aptamer)是通过指数富集配体系统进化技术(SELEX)筛选的能够以高亲和力和高特异性识别靶标分子或细胞的核糖核酸(RNA)和单链脱氧核糖核酸(ssDNA)。作为化学抗体,核酸适配体的制备和合成比抗体的成本更低。核酸适配体的靶标范围极其广泛,包括小分子、生物大分子、细菌和细胞等。针对细菌靶标筛选的适配体,目前主要应用于食品、医药和环境中的细菌检测。细菌的核酸适配体筛选可以通过离心法将菌体-适配体复合物与游离的适配体分离,并通过荧光成像、荧光光谱分析、流式细胞仪分选、DNA捕获元件、酶联适配体分析等方法表征适配体与靶标的相互作用。筛选出的适配体可结合生物、化学检测方法用于细菌检测。本文介绍了细菌适配体的筛选和表征方法以及基于适配体的检测方法的最新进展,分析了不同检测方法的利弊,并列出了2011~2015年筛选的细菌的核酸适配体。     

A novel aptasensor strategy for protein detection based on G-quadruplex and exonuclease III-aided recycling amplification

The detection of biomarkers is of great significance in the diagnosis of numerous diseases,especially cancer.Herein,we developed a sensitive and universal fluorescent aptasensor strategy based on magnetic beads,DNA G-quadruplex,and exonuclease Ⅲ(Exo Ⅲ).In the presence of a target protein,a label-free single strand DNA(ssDNA)hybridized with the aptamer was released as a trigger DNA due to specific recognition between the aptamer and target.Subsequently,ssDNA initiates the ExoⅢ-aided recycling to amplify the fluorescence signal,which was caused by N-methylmesoporphyrin IX(NMM)insertion into the G-quadruplex structure.This proposed strategy combines the excellent specificity between the aptamer and target,high sensitivity of the fluorescence signal by G-quadruplex and ExoⅢ-aided recycling amplification.We selected(50-1200 nmol/L)MUC1,a common tumor biomarker,as the proof-of-concept target to test the specificity of our aptasenso r.Results reveal that the sensor sensitively and selectively detected the target protein with limits of detection(LODs)of 3.68 and 12.83 nmol/L in buffer solution and 10%serum system,respectively.The strategy can be easily applied to other targets by simply substituting corresponding aptamers and has great potential in the diagnosis and monitoring of several diseases.     

A general approach for rational design of fluorescent DNA aptazyme sensors based on target-induced unfolding of DNA hairpins

DNA aptazymes are allosteric DNAzymes activated by the targets of DNA aptamers. They take the advantages of both aptamers and DNAzymes, which can recognize specific targets with high selectivity and catalyze multiple-turnover reactions for signal amplification, respectively, and have shown their great promise in many analytical applications. So far, however, the available examples of DNA aptazyme sensors are still limited in utilizing only several DNAzymes and DNA aptamers, most likely due to the lack of a general and simple approach for rational design. Herein, we have developed such a general approach for designing fluorescent DNA aptazyme sensors. In this approach, aptamers and DNAzymes are connected at the ends to avoid any change in their original sequences, therefore enabling the general use of different aptamers and DNAzymes in the design. Upon activation of the aptazymes by the targets of interest, the rate of fluorescence enhancement via the cleavage of a dually labeled substrate by the active aptazymes is then monitored for target quantification. Two DNAzymes and two aptamers are used as examples for the design of three fluorescent aptazyme sensors, and they all show high selectivity and sensitivity for the detection of their targets. More DNA aptazyme sensors for a broader range of targets could be developed by this general approach as long as suitable DNAzymes and aptamers are used.     

CdS quantum dots as a fluorescent sensing platform for nucleic acid detection

We demonstrate that CdS quantum dots (QDs) can be applied to fluorescence-enhanced detection of nucleic acids in a two-step protocol. In step one, a fluorescently labeled single-stranded DNA probe is adsorbed on the QDs to quench its luminescence. In step two, the hybridization of the probe with its target ssDNA produces a double-stranded DNA which detaches from the QD. This, in turn, leads to the recovery of the fluorescence of the label. The lower detection limit of the assay is as low as 1?nM. The scheme (that was applied to detect a target DNA related to the HIV) is simple and can differentiate between perfectly complementary targets and mismatches.

Ultrasensitive detection of potassium ions based on target induced DNA conformational switch enhanced fluorescence polarization

We have developed a simple, highly sensitive and selective fluorescence polarization assay for the detection of potassium ions based on target induced DNA conformational switch from hairpin to G-quadruplex enhanced fluorescence polarization. The assay was applied in the detection of low nM concentrations of potassium ions and was highly selective over other cations.     

Glucose detection at attomole levels using dynamic light scattering and gold nanoparticles

Glucose is directly related to brain activity and to diabetes.Therefore,developing a rapid and sensitive method for glucose detection is essential.Here,label-free glucose detection at attomole levels was realized by detecting the average diameter change of gold nanoparticles(AuNPs)utilizing dynamic light scattering(DLS).Single-strand DNA(ssDNA)adsorbed into the AuNPs’surfaces and prevented them from aggregating in solution that contained NaCl.However,ssDNA cleaved onto ssDNA fragments upon addition of glucose,and these fragments could not adsorb onto the AuNPs’surfaces.Therefore,in high-salt solution,AuNPs would aggregate and their average diameter would increase.Based on monitoring the average diameter of AuNPs with DLS,glucose could be detected in the range from 15 pmol/L to 2.0 nmol/L,with a detection limit of 8.3 pmol/L.Satisfactory results were also obtained when the proposed method was applied in human serum glucose detection.     

Target induced dissociation (TID) strategy for the development of electrochemical aptamer-based biosensor

In this paper, we report a novel and more general signal-on strategy for the fabrication of electrochemical aptamer-based (E-AB) biosensor. The principle is that the interaction between the target and the aptamer strand may induce the formation and subsequent dissociation of target–aptamer complex from an electrode surface, and consequently, the remaining DNA strand on the electrode surface can hybridize again with a ssDNA containing an electrochemical probe. Differential pulse voltammetric studies have revealed that this target induced disassociation (TID) strategy is an effective signal-on method for the detection of ATP molecules with good selectivity. The TID strategy may also have several advantages, such as independence on the specific structure of either the aptamers or their complementary sequences and promotion of the generalization of E-AB sensors, the more convincible results due to the signal-on model, and the unnecessity to label the aptamers, which provides the optimized status for the reaction with the targets, etc.     

ssDNA-QDs/GO multicolor fluorescence system for synchronous screening of hepatitis virus DNA

Viral hepatitis is a common infectious disease caused by five viruses (hepatitis virus A, B, C, D, and E). Given the diversity of hepatitis virus, rapid screening and accurate typing of viral hepatitis are the prerequisites for hepatitis therapy. Here, a multicolor fluorescence system was constructed by combining with the multi-color fluorescence properties of CdSe/ZnS quantum dots (QDs, emission wavelengths: 525 nm, 585 nm and 632 nm) and the broad-spectrum fluorescence quenching performance of GO. Taking advantage of the specific recognition of ssDNA modified CdSe/ZnS QDs to target hepatitis virus DNA, the constructed system could effectively distinguish hepatitis A virus DNA (HAV-DNA), hepatitis B virus DNA (HBV-DNA), and hepatitis C virus DNA (HCV-DNA) in a homogeneous solution. Based on the different adsorption property of GO for ssDNA and dsDNA, the fluorescence Forster resonance energy transfer (FRET) process between ssDNA modified QDs and GO could be regulated. The fluorescence signal of the constructed system presented a sensitive response to HAV-DNA, HBV-DNA, and HCV-DNA content in the range of 1.0–192 nM, 8.0–192 nM, and 1.0–128 nM, respectively. The limit of detection for HAV-DNA, HBV-DNA, and HCV-DNA is 0.46 nM, 1.53 nM, and 0.58 nM. The constructed system can be used to screen hepatitis virus DNA in real samples, which provides an alternative strategy for rapid screening and diagnosis of viral hepatitis.     

Mechanism of mercury detection based on interaction of single-strand DNA and hybridized DNA with gold nanoparticles

Mechanisms of interaction of single-strand DNA and hybridized DNA on gold nanoparticles in the presence of Hg²⁺ was studied in this work. Recently the detection of Hg²⁺ using unmodified gold nanoparticles (AuNPs) combined with DNA is becoming a promising technique with the advantages of simplicity, cost-effectiveness and high sensitivity. However, few studies focused on the interaction of ssDNA and hybridized DNA on AuNPs to date. In the present work, we compared the interactions of different DNA probes on AuNPs using both absorption and fluorescence detection. It was found that there were only small partial dsDNA dissociated from the surface of AuNPs after hybridization in the presence of Hg²⁺. Moreover, we found that the aggregated AuNPs/DNA system tended to be dispersed again with increasing Hg²⁺ concentration up to 250 μM. Based on these results, the mechanisms of mercury detection based on interaction between DNA-conjugated gold nanoparticles were investigated. Positively charged dsDNA could bind to the surface of AuNPs and dominate the electrostatic interactions and consequently aggregation of the AuNPs/DNA system.     

蛋白质的核酸适配体筛选的研究进展

核酸适配体是通过指数富集系统配体进化(SELEX)筛选获得的,与靶标具有高亲和力和特异性结合的单链DNA或RNA。蛋白质是生命进程中的关键功能分子。近年来,以蛋白质为靶标的适配体筛选在蛋白质相关的基础及应用研究领域受到广泛关注。核酸适配体应用性能的优劣取决于其亲和力、特异性与稳定性。目前,适配体筛选方法的优化主要是提高筛选效率、提升适配体性能及降低筛选成本。适配体主要筛选步骤包括复合物分离、核酸库优化、次级库的富集、适配体序列分析以及亲和力表征等。迄今为止,以蛋白质-核酸复合物的分离为核心步骤的适配体筛选方法有20余种。本文归纳总结了2005年以来以蛋白质为靶标的适配体筛选技术,讨论了各方法的缺陷与局限。介绍了核酸库的设计优化方法、适配体的序列特征,以及常用的亲和力表征方法。     

Microfluidic nanoplasmonic-enabled device for multiplex DNA detection

We describe a rapid, quantitative, multiplex, self-labelled, and real-time DNA biosensor employing Ag nanoparticle-bound DNA hairpin probes immobilized in a microfluidic channel. Capture of complementary target DNAs by the microarrayed DNA hairpin probes results in a positive fluorescence signal via a conformational change of the probe molecules, signalling the presence of target DNAs. The device's capability for quantitative analyses was evaluated and a detection time as low as 6 min (with a target flow rate of 0.5 μl min(-1)) was sufficient to generate significant detection signals. This detection time translates to merely 3 μl of target solution consumption. An unoptimized sensitivity of 500 pM was demonstrated for this device.     

Fluorescence energy transfer-based multiplexed hybridization assay using gold nanoparticles and quantum dot conjugates on photonic crystal beads

A multiplexed assay strategy was developed for the detection of nucleic acid hybridization. It is based on fluorescence resonance energy transfer (FRET) between gold nanoparticles (AuNPs) and multi-sized quantum dots (QDs) deposited on the surface of silica photonic crystal beads (SPCBs). The SPCBs were first coated with a three-layer primer film formed by the alternating adsorption of poly(allylamine hydrochloride) and poly(sodium 4-styrensulfonate). Probe DNA sequences were then covalently attached to the carboxy groups at the surface of the QD-coated SPCBs. On addition of DNA-AuNPs and hybridization, the fluorescence of the donor QDs is quenched because of the close proximity of the AuNPs. However, the addition of target DNA causes a recovery of the fluorescence of the QD-coated SPCBs, thus enabling the quantitative assay of hybridized DNA. Compared to fluorescent dyes acting as acceptors, the use of AuNPs results in much higher quenching efficiency. The multiplexed assay displays a wide linear range, high sensitivity, and very little cross-reactivity. This work, where such SPCBs are used for the first time in a FRET assay, is deemed to present a new and viable approach towards high-throughput multiplexed gene assays.