Electrochemiluminescence of CdTe quantum dots as labels at nanoporous gold leaf electrodes for ultrasensitive DNA analysis

A new electrochemiluminescence (ECL) DNA assay is developed using quantum dots (QDs) as DNA labels. When nanoporous gold leaf (NPGL) electrodes are used, sensitivity of the ECL assay is remarkably increased due to ultra-thin nanopores. In this assay, target DNA (t-DNA) is hybridized with capture DNA (c-DNA) bound on the NPGL electrode, which is fabricated by conjugating amino-modified c-DNA to thioglycolic acid (TGA) modified at the activated NPGL electrode. Following that, amino-modified probe DNA is hybridized with the t-DNA, yielding sandwich hybrids on the NPGL electrode. Then, mercaptopropionic acid-capped CdTe QDs are labeled to the amino group end of the sandwich hybrids. Finally, in the presence of S₂O₈²⁻ as coreactant, ECL emission of the QD-labeled DNA hybrids on the NPGL electrode is measured by scanning the potential from 0 to −2 V to record the curve of ECL intensity versus potential. The maximum ECL intensity (I_m,ECL) on the curve is proportional to t-DNA concentration with a linear range of 5 × 10⁻¹⁵ to 1 × 10⁻¹¹ mol/L. The ECL DNA assay can be used to determine DNA corresponding to mRNA in cell extracts in this study.     

A self-assembled deoxyribonucleic acid concatemer for sensitive detection of single nucleotide polymorphism

Polymerase-free and label-free strategies for DNA detection have shown excellent sensitivity and specificity in various biological samples. Herein, we propose a method for single nucleotide polymorphism (SNP) detection by using self-assembled DNA concatemers. Capture probes, bound to magnetic beads, can joint mediator probes by T4 DNA ligase in the presence of target DNA that is complementary to the capture probe and mediator probe. The mediator probes trigger self-assembly of two auxiliary probes on magnetic beads to form DNA concatemers. Separated by a magnetic rack, the double-stranded concatemers on beads can recruit a great amount of SYBR Green I and eventually result in amplified fluorescent signals. In comparison with reported methods for SNP detection, the concatemer-based approach has significant advantages of low background, simplicity, and ultrasensitivity, making it as a convenient platform for clinical applications. As a proof of concept, BRAF^T1799A oncogene mutation, a SNP involved in diverse human cancers, was used as a model target. The developed approach using a fluorescent intercalator can detect as low as 0.1 fM target BRAF^T1799A DNA, which is better than those previously published methods for SNP detection. This method is robust and can be used directly to measure the BRAF^T1799A DNA in complex human serum with excellent recovery (94–103%). It is expected that this assay principle can be directed toward other SNP genes by simply changing the mediator probe and auxiliary probes.     

An ultra-sensitive DNA assay based on single-molecule detection coupled with hybridization accumulation and its application

An ultra-sensitive assay for quantification of DNA based on single-molecule detection coupled with hybridization accumulation was developed. In this assay, target DNA (tDNA) in solution was accumulated on a silanized substrate blocked with ethanolamine and bovine serum albumin (BSA) through a hybridization reaction between tDNA and capture DNA immobilized on the substrate. The tDNA on the substrate was labeled with quantum dots which had been modified with detection DNA and blocked with BSA. The fluorescence image of single QD-labeled tDNA molecules on the substrate was acquired using total internal reflection fluorescence microscopy. The tDNA was quantified by counting the bright dots on the image from the QDs. The limit of detection of the DNA assay was as low as 6.4 × 10(-18) mol L(-1). Due to the ultra-high sensitivity, the DNA assay was applied to measure the beta-2-microglobulin messenger RNA level in single human breast cancer cells without a need for PCR amplification.     

Development and characterization of a magnetic bead-quantum dot nanoparticles based assay capable of Escherichia coli O157:H7 quantification

The development and characterization of a magnetic bead (MB)-quantum dot (QD) nanoparticles based assay capable of quantifying pathogenic bacteria is presented here. The MB-QD assay operates by having a capturing probe DNA selectively linked to the signaling probe DNA via the target genomic DNA (gDNA) during DNA hybridization. The signaling probe DNA is labeled with fluorescent QD₅₆₅ which serves as a reporter. The capturing probe DNA is conjugated simultaneously to a MB and another QD₆₅₅, which serve as a carrier and an internal standard, respectively. Successfully captured target gDNA is separated using a magnetic field and is quantified via a spectrofluorometer. The use of QDs (i.e., QD₅₆₅/QD₆₅₅) as both a fluorescence label and an internal standard increased the sensitivity of the assay. The passivation effect and the molar ratio between QD and DNA were optimized. The MB-QD assay demonstrated a detection limit of 890 zeptomolar (i.e., 10⁻²¹ mol L⁻¹) concentration for the linear single stranded DNA (ssDNA). It also demonstrated a detection limit of 87 gene copies for double stranded DNA (dsDNA) eaeA gene extracted from pure Escherichia coli (E. coli) O157:H7 culture. Its corresponding dynamic range, sensitivity, and selectivity were also presented. Finally, the bacterial gDNA of E. coli O157:H7 was used to highlight the MB-QD assay's ability to detect below the minimum infective dose (i.e., 100 organisms) of E. coli O157:H7 in water environment.     

Simple and sensitive fluorometric sensing of malachite green with native double-stranded calf thymus DNA as sensing material

A novel fluorometric sensing of malachite green is proposed in this paper. The native double-stranded calf thymus DNA was used as sensing material. In the presence of native double-stranded calf thymus DNA, malachite green could interact with the DNA, which resulted in a strong fluorescence emission. The fluorescent intensity was linear with malachite green concentration in the range of 4.0 × 10⁻¹⁰ − 1.8 × 10⁻⁷ g ml⁻¹ and the limit of detection was 2.0 × 10⁻¹⁰ g ml⁻¹. Before fluorescence measurement, the only required operation is the mixing of two solutions. So, this method is rather simple and rapid. The method is very safe for the analyst. Furthermore, the mechanism for fluorescence enhancing of native double-stranded calf thymus DNA on MG was proposed based on a series of experiments. The results suggest that the interaction between MG and calf thymus DNA is intercalation in nature.     

Detection of single-molecule DNA hybridization by using dual-color total internal reflection fluorescence microscopy

We examined the use of prism-type simultaneous dual-color total internal reflection fluorescence microscopy (TIRFM) to probe DNA molecules at the single-molecule level. The system allowed the direct detection of the complementary interactions between single-stranded probe DNA molecules (16-mer) and various lengths of single-stranded target DNA molecules (16-mer and 55-mer) that had been labeled with different fluorescent dyes (Cy3, Cy5, and fluorescein). The polymer-modified glass substrate and the extent of DNA probe immobilization were easily characterized either with standard TIRFM or with atomic force microscopy. However, only dual-color TIRFM could provide unambiguous images of individual single-stranded target DNA molecules hybridized with the correct sequence in the range of fM–aM. Succinic anhydride showed low RMS roughness and was found to be an optimal blocking reagent against non-specific adsorption, with an efficiency of 92%. This study provides a benchmark for directly monitoring the interactions and the detection of co-localization of two different DNA molecules and can be applied to the development of a nanoarray biochip at the single-molecule level.     

Enoxacin-Tb complex as an environmentally friendly fluorescence probe for DNA and its application

The fluorescence intensity of the enoxacin (ENX)-Tb³⁺ complex enhanced by DNA was studied. On the basis of this study, an environmentally friendly fluorescence probe of enoxacin-Tb³⁺ for the determination of single-stranded and double-stranded DNA was developed. Under the optimal conditions, the enhanced fluorescence intensity was in proportion to the concentration of DNA in the range of 2.0 × 10⁻⁸ to 2.0 × 10⁻⁶ g mL⁻¹ for hsDNA, 1.0 × 10⁻⁸ to 1.0 × 10⁻⁶ g mL⁻¹ for ctDNA and 5.0 × 10⁻⁹ to 1.0 × 10⁻⁶ g mL⁻¹ for thermally denatured ctDNA. The detection limits (S/N = 3) were 5.0, 9.0 and 3.0 ng mL⁻¹, respectively. The interaction modes between ENX-Tb³⁺ and DNA and the mechanism of the fluorescence enhancement were also discussed in details. The experimental results from UV absorption spectra, fluorescence spectra and the competing combination tests between the ENX-Tb³⁺ complex and EB probe indicated that the possible interaction modes between enoxacin-Tb³⁺ complex and DNA had at least two different binding modes: the electrostatic binding and the intercalation binding. Additionally, this fluorescence probe was used to study the interaction between heavy metals and DNA.     

Quantum-dot-labeled DNA probes for fluorescence in situ hybridization (FISH) in the microorganism Escherichia coli.

Semiconductor quantum dots (QDs) as a kind of nonisotopic biological labeling material have many unique fluorescent properties relative to conventional organic dyes and fluorescent proteins, such as composition- and size-dependent absorption and emission, a broad absorption spectrum, photostability, and single-dot sensitivity. These properties make them a promising stable and sensitive label, which can be used for long-term fluorescent tracking and subcellular location of genes and proteins. Here, a simple approach for the construction of QD-labeled DNA probes was developed by attaching thiol-ssDNA to QDs via a metal-thiol bond. The as-prepared QD-labeled DNA probes had high dispersivity, bioactivity, and specificity for hybridization. Based on such a kind of probe with a sequence complementary to multiple clone sites in plasmid pUC18, fluorescence in situ hybridization of the tiny bacterium Escherichia coli has been realized for the first time.     

基于环状DNA-银纳米簇荧光探针对微囊藻毒素-LR的传感检测

以新型环状DNA为模板, 制备了环状DNA-银纳米簇(Circular DNA-AgNCs)荧光探针, 构建了一种无酶无标记检测微囊藻毒素-LR(MC-LR)的荧光传感分析方法. 设计的环状DNA由MC-LR适体链(Apt)和适体链的互补链(cDNA)杂交形成, 且cDNA可作为DNA模板用于合成AgNCs. 利用透射电子显微镜(TEM)、 紫外-可见光谱(UV-Vis)和荧光光谱(FL)表征了AgNCs的形貌和光学特性.结果表明, 当存在目标物MC-LR时, 由于MC-LR与环状DNA中Apt高特异性和高亲和力结合, 导致环状DNA解体, 释放出的cDNA-AgNCs在610 nm处呈现强荧光. 在优化实验条件下, 环状DNA-AgNCs荧光探针对MC-LR检测的线性范围为0.005~500 μg/L, 检出限为1.7 ng/L(S/N=3). 该荧光探针具有制备简单、 无需任何标记和灵敏度高等特点, 为环境水样中微囊藻毒素-LR的快速和准确测定提供了一种简单、 可靠和有效的方法.     

A New Trace Analytic Method for the Determination of Sequence-Specific DNA with Fluorescent Probes

A new method of fluorescence spectrometry detection of single-strand DNA (ssDNA) was established by hybridizing the ssDNA with its complementary ssDNA to form double-stranded DNA (dsDNA). Our results show that the fluorescence intensity increased significantly when the nucleic acid molecular “light switch"(Ru(phen)₂dppx²⁺) or Hoechst 33258 dye interacted with dsDNA, and the fluorescence intensity also increased as the DNA concentration increased. The changing law was also studied about how the fluorescence intensity changed when the two kinds of fluorescent probes interacted with oligonucleotide of different lengths and different sequences, as well as DNA-DNA′ hybridization products. Then, the effect of the bases mismatch, varying length of DNA chain, and different DNA sequences on the fluorescence intensity were explored at the same time, by detecting the specific DNA sequence of avian influenza H1N1 virus, cauliflower mosaic virus, and hepatitis C virus. Additionally, the selectivity, linear range, and sensitivity of the two probes were compared.     

DNA microspot assay using single-molecule detection and requiring 1.8 nL samples only

An ultra-sensitive DNA microspot assay was developed that required 1.8?nL samples and was based on single-molecule detection. The solution of the target DNA (tDNA) was spotted onto the coverslip modified with capture DNA (DNA1) and blocked with ethanolamine and bovine serum albumin using a pintool type microspoting robot. The microspot had a diameter of ~300???m. The tDNA was captured by the DNA1, and the tDNA was then labeled with a detection DNA that previously was labeled with a quantum dot. Next, a fluorescence microscopic image of the microspot was acquired using a single-molecule microspot reader during total internal reflection fluorescence excitation. As little as 4?×?10^?22 mole (240 molecules) of tDNA can be detected by this method. The response is linear in the range from 6.0?×?10^?22 to 1.2?×?10^?19 mole of tDNA. All operations (including the acquisition of microspot images and single-molecule counting) were performed using the MetaMorph software. The assay was applied to the determination of osteopontin messenger RNA in single decidual stromal cells without the need for PCR amplification.

Tris(2,2′-bipyridyl)cobalt(III)-doped silica nanoparticle DNA probe for the electrochemical detection of DNA hybridization

A new and sensitive electrochemical DNA hybridization detection assay, using tris(2,2′-bipyridyl)cobalt(III) [Co(bpy)₃³⁺]-doped silica nanoparticles as the oligonucleotide (ODN) labeling tag, and based on voltammetric detection of Co(bpy)₃³⁺ inside silica nanoparticles, is described. Electro-active Co(bpy)₃³⁺ is not possible for directly linking with DNA, it is doped into the silica nanoparticles in the process of nanoparticles synthesis for DNA labeling with trimethoxysilylpropydiethylenetriamine (DETA) and glutaraldehyde as linking agents. The Co(bpy)₃³⁺ labeled DNA probe is used to hybridize with target DNA immobilized on the surface of glassy carbon electrode. Only the complementary sequence DNA (cDNA) could form a double-stranded DNA (dsDNA) with the DNA probe labeled with Co(bpy)₃³⁺ and give an obvious electrochemical response. A three-base mismatch sequence and non-complementary sequence had negligible response. Due to the large number of Co(bpy)₃³⁺ molecules inside silica nanoparticles linked to oligonucleotide DNA probe, the assay showed a high sensitivity. It allows the detection at levels as low as 2.0×10⁻¹⁰ mol l⁻¹ of the target oligonucleotides.     

Simultaneous detection of ultraviolet B-induced DNA damage using capillary electrophoresis with laser-induced fluorescence

An immunoassay based on CE–LIF was developed for the simultaneous detection of cyclobutane pyrimidine dimers (CPDs) and pyrimidine 6-4 pyrimidone photoproducts (6-4PPs) in genomic DNA irradiated with UVB or natural sunlight. Human cells were first exposed to varying amounts of UVB or natural sunlight to induce DNA damage. Genomic DNA was extracted and incubated with anti-CPD and anti-6-4PP primary antibodies attached to secondary antibodies with a fluorescent quantum dot (QD) reporter that emitted either red or yellow fluorescence. CE was used to separate the unbound antibodies from those bound to the photoproducts, and LIF with appropriate optical filters was used to separate the fluorescence signals from each QD to individual photomultiplier tubes for simultaneous photoproduct detection. Using this strategy, photoproducts were detected from ∼6 ng (200 ng μL⁻¹) of DNA under a low UVB fluence of 65 J m⁻² for CPDs or 195 J m⁻² for 6-4PPs. This assay was also the first to demonstrate the detection of CPDs in human cells after only 15 min of irradiation under natural sunlight.     

Electrochemical studies of the interaction of Basic Brown G with DNA and determination of DNA

A new method of electrochemical probe has been proposed for the determination of Herring Sperm DNA (DNA) based on its interaction with Basic Brown G (BBG). The electrochemical behavior of interaction of BBG with DNA was investigated on Hg electrode. In 0.1 mol L⁻¹ NH₃-NH₄Cl buffer solution (pH 8.0), BBG can be reduced on Hg electrode with a well-defined voltammetric peak at −0.67 V (versus SCE). In the presence of DNA, the reduction peak current of BBG decreases and the peak potential shifts to a more positive potential without the appearance of new peak. The study shows that a new BBG-DNA complex is formed by linear sweep voltammetry (LSV) and spectrophotometry. The decrease of the second order derivative of reductive peak current (Δi^″p) of BBG is proportional to the concentration of DNA in the range of 0.10-36 μg mL⁻¹. Limit of detection of DNA is 0.04 μg mL⁻¹. DNA of Hepatitis B Virus in serum samples was determined satisfactorily. Additionally, the binding mechanism was preliminarily discussed. The mode of interaction between BBG and DNA was found to be intercalation binding.     

罗丹明6G衍生物基偏酸性“关开型”pH荧光探针

以罗丹明6G和水合肼为原料,先制备罗丹明6G酰肼,接着在乙醇中滴加少量冰醋酸做催化剂后与2,5-二甲氧基苯甲醛反应,合成了一种新型的pH荧光分子探针(RGSBD),进行了结构表征及荧光性能研究。结果表明,原本在氢离子浓度较低,即体系pH较高时(pH≥4.0),探针RGSBD内酰胺螺环闭环导致不显示荧光并且无色,然而在氢离子浓度较大即体系pH较低时(pH<4.0)时,其内酰胺螺环闭环产生了明显的颜色变化,发出强烈的荧光。pH 1.9时,探针的荧光强度达到最大,最大荧光峰发生显著的红移。进一步研究表明,探针RGSBD的荧光峰强度差值与pH在1.9~3.2范围内呈良好的线性关系,探针RGSBD识别H^+的选择性高,稳定性与可逆性强,可发展用作生物体内pH荧光传感材料。     

A method for visualization of biomolecules labeled by a single quantum dot in living cells by a combination of total internal reflection fluorescence microscopy and intracellular fluorescence microscopy

We developed a simple fluorescence microscopy for acquisition of high-resolution images of single quantum dots (QDs) labeled to biomolecules on apical plasma membrane, in cell interior and on basal plasma membrane of living cells. The method was a combination of total internal reflection fluorescence microscopy (TIRFM) at apical cell surface and intracellular microscopy coupled with focusing objective. Insulin conjugated to single QD (insulin-QD) was chosen as the model system. In order to bind insulin-QDs to insulin receptors on the plasma membrane through the interaction between insulin and its receptor, as well as internalize them, the cells attached on a coverslip were incubated with biotinylated insulin and QD-streptavidin conjugate at 37 °C. Next, fluorescent molecules in the cells were photobleached by illuminating the cells using a 100-W mercury lamp with the wavelengths from 460 to 490 nm. Then, the incident angle of a laser beam was adjusted to produce total internal reflection at the apical surface of a single cell. In this case, the insulin-QDs in the whole cell were excited, and the fluorescent molecules outside the cell were not illuminated. Finally, the images of single insulin-QDs on the apical plasma membrane, in the cell interior and on the basal plasma membrane of the cell were taken by focusing the objective to different positions, respectively. The resolution and contrast of the fluorescent spots in the images were much higher than those obtained by using epi-fluorescence microscopy and comparable to those obtained by using the conventional TIRFM. The method improved the image acquisition speed for the images on the apical and basal plasma membrane using the conventional TIRFM, and could acquire the high-resolution images in the cell interior quickly.     

A novel “Turn-On” fluorescent probe for F detection in aqueous solution and its application in live-cell imaging

A novel probe incorporating quaternized 4-pyridinium group into a BODIPY molecule was synthesized and studied for the selective detection of fluoride ions (F⁻) in aqueous solution. The design was based on a fluoride-specific desilylation reaction and the “Turn-On” fluorescent response of probe 1 to F⁻ was ascribed to the inhibition of photoinduced electron transfer (PET) process. The probe displayed many desired properties such as high specificity, appreciable solubility, desirable response time and low toxicity to mammalian cells. There was a good linearity between the fluorescence intensity and the concentrations of F⁻ in the range of 0.1–1 mM with a detection limit of 0.02 mM. The sensing mechanism was confirmed by the NMR, electrospray ionization mass spectrum, optical spectroscopy and the mechanism of “Turn-On” fluorescent response was also determinated by a density functional theory (DFT) calculation using Gaussian 03 program. Moreover, the probe was successfully applied for the fluorescence imaging of F⁻ in human epithelial lung cancer (A549) cells and alveolar type II (ATII) cells under physiological conditions.     

High-Affinity Ratiometric Fluorescence Probe Based on 6-Amino-2,2′-Bipyridine Scaffold for Endogenous Zn2+ and Its Application to Living Cells

Zinc is an essential trace element involved in many biological activities; however, its functions are not fully understood. To elucidate the role of endogenous labile Zn²⁺, we developed a novel ratiometric fluorescence probe, 5-(4-methoxyphenyl)-4-(methylsulfanyl)-[2,2′-bipyridin]-6-amine (6 (rBpyZ)) based on the 6-amino-2,2′-bipyridine scaffold, which acts as both the chelating agent for Zn²⁺ and the fluorescent moiety. The methoxy group acted as an electron donor, enabling the intramolecular charge transfer state of 6 (rBpyZ), and a ratiometric fluorescence response consisting of a decrease at the emission wavelength of 438 nm and a corresponding increase at the emission wavelength of 465 nm was observed. The ratiometric probe 6 (rBpyZ) exhibited a nanomolar-level dissociation constant (K_d = 0.77 nM), a large Stokes shift (139 nm), and an excellent detection limit (0.10 nM) under physiological conditions. Moreover, fluorescence imaging using A549 human lung adenocarcinoma cells revealed that 6 (rBpyZ) had good cell membrane permeability and could clearly visualize endogenous labile Zn²⁺. These results suggest that the ratiometric fluorescence probe 6 (rBpyZ) has considerable potential as a valuable tool for understanding the role of Zn²⁺ in living systems.     

Magnetic porous carbon nanocomposites derived from metal-organic frameworks as a sensing platform for DNA fluorescent detection

Metal-organic frameworks (MOFs) have emerged as very fascinating functional materials due to their tunable nature and diverse applications. In this work, we prepared a magnetic porous carbon (MPC) nanocomposite by employing iron-containing MOFs (MIL-88A) as precursors through a one-pot thermolysis method. It was found that the MPC can absorb selectively single-stranded DNA (ssDNA) probe to form MPC/ssDNA complex and subsequently quench the labelled fluorescent dye of the ssDNA probe, which is resulted from the synergetic effect of magnetic nanoparticles and carbon matrix. Upon the addition of complementary target DNA, however, the absorbed ssDNA probe could be released from MPC surface by forming double-stranded DNA with target DNA, and accompanied by the recovery of the fluorescence of ssDNA probe. Based on these findings, a sensing platform with low background signal for DNA fluorescent detection was developed. The proposed sensing platform exhibits high sensitivity with detection limit of 1 nM and excellent selectivity to specific target DNA, even single-base mismatched nucleotide can be distinguished. We envision that the presented study would provide a new perspective on the potential applications of MOF-derived nanocomposites in biomedical fields.