Control of the Fluorescence of DNA‐templated Silver Nanoclusters by Adenosine Triphosphate and Mercury(II)

Several DNA templates with the sequence 5′‐T _n TAACCCCTAACCCCT ‐3′ (n = 0, 15, 30, and 45) were used to prepare DNA template–silver nanoclusters (DNA –Ag NCs ). The T _n sequence acts as a recognition element for Hg²⁺, while the rest of the sequence acts as a template for DNA –Ag NCs . At pH 3.0, the fluorescence intensity of DNA –Ag NCs is enhanced by ATP , and the enhanced fluorescence is quenched by Hg²⁺. The length of polyT shows a slight effect on the sensitivity for the detection of Hg²⁺ but almost no effect on the optical properties of DNA –Ag NCs . The fluorescence response of DNA –Ag NCs (T₁₅‐DNA –Ag NCs ) vs. Hg²⁺ concentration shows two linear ranges over 10–100 and 100–1000 nM , mainly because of the fluorescence quenching due to DNA conformational changes through T–Hg²⁺–T coordination and the formation of an amalgam with Ag NCs , respectively. The sensitivity of the T₁₅‐DNA –Ag NC probe was validated through the analysis of Hg²⁺ in spiked pond water. Based on the switch‐on and switch‐off fluorescence properties of T₁₅‐DNA –Ag NCs , an IMPLICATION logic gate was fabricated using the concentrations of ATP and Hg²⁺ as inputs and the fluorescence intensity at 585 nm as output.     

Upconversion emission of fluorescent silver nanoclusters and in situ selective DNA biosensing

Due to their good photostability, high quantum yield and low toxicity, fluorescent silver nanoclusters (Ag NCs) have received much attention as novel fluorophores for sensing applications. In this work, we investigate the upconversion emission of Ag NCs templated by single- and double-stranded DNAs. DNA-templated Ag NCs exhibit upconversion emission at wavelengths identical to those observed for the corresponding Stokes emission. Consequently, the Ag NCs' upconversion behavior can be easily tuned by the used DNA sequences. In addition, the Ag NCs are more stable under such an NIR excitation with the upconversion mode relative to the Stokes mode. As a proof-of-concept application, DNA nucleobase recognition with the in situ formed Ag NCs is realized using the Ag NCs' upconversion emission. We expect that the Ag NCs' upconversion emission is more advantageous than the previously used rare-earth materials, at least with respect to easy modulation of the emission energies by DNA sequences, and could find wide application in sensor design.     

High‐Level Incorporation of Silver in Gold Nanoclusters: Fluorescence Redshift upon Interaction with Hydrogen Peroxide and Fluorescence Enhancement with Herbicide

High‐level incorporation of Ag in Au nanoclusters (NCs) is conveniently achieved by controlling the concentration of Ag⁺ in the synthesis of bovine serum albumin (BSA)‐protected Au NCs, and the resulting structure is determined to be bimetallic Ag₂₈Au₁₀‐BSA NCs through a series of characterizations including energy‐dispersive X‐ray spectroscopy, mass spectroscopy, and X‐ray photoelectron spectroscopy, together with density functional theory simulations. Interestingly, the Ag₂₈Au₁₀ NCs exhibit a significant fluorescence redshift rather than quenching upon interaction with hydrogen peroxide, providing a new approach to the detection of hydrogen peroxide through direct comparison of their fluorescence peaks. Furthermore, the Ag₂₈Au₁₀ NCs are also used for the sensitive and selective detection of herbicide through fluorescence enhancement. The detection limit for herbicide (0.1 nm ) is far below the health value established by the U.S. Environmental Protection Agency; such sensitive detection was not achieved by using AuAg NCs with low‐level incorporation of Ag or by using the individual metal NCs.     

Gap site-specific rapid formation of fluorescent silver nanoclusters for label-free DNA nucleobase recognition

Silver nanoclusters (Ag NCs) templated with DNAs have attracted much attention as novel fluorophores because of their convenient emission tunability by the sequence and length of the template DNAs. However, the precise production of Ag NCs in a site-specific manner still remains a challenge to attain highly selective and label-free DNA recognition. Here we exploited the availability of a gap site in DNA duplexes as a new scaffold for the synthesis of Ag NCs. Compared to the commonly used DNA templates for the creation of Ag NCs, the gap site in DNA duplexes was found to facilitate the rapid formation of the fluorescent Ag NCs without sacrifice of their bright emission and excellent stability. We found that fluorescent Ag NCs were highly selectively formed when cytosine faced toward the gap site in DNA duplexes, and they were in situ utilized as readout by signal-on manner for the DNA mutation assays. This base-selective growth of the fluorescent Ag NCs at the gap site would find promising applications in practical detection of single nucleotide polymorphism (SNP) and construction of DNA-based functional sensors with label-free and cost-effective merits.     

Novel high-sensitive fluorescent detection of deoxyribonuclease I based on DNA-templated gold/silver nanoclusters

Herein, fluorescent DNA-templated gold/silver nanoclusters (DNA-Au/Ag NCs) are presented as a novel probe for sensitive detection of deoxyribonuclease I (DNase I). The procedure is based on quenching fluorescence of DNA-Au/Ag NCs by DNase I digestion of the DNA (5′-CCCTTAATCCCC-3′) template. This decrease in fluorescence intensity permitted sensitive detection of DNase I in a linear range of 0.013–60 μg mL⁻¹, with a detection limit of 3 ng mL⁻¹ at a signal-to-noise ratio of 3. Furthermore, the practicality of this probe for detection of DNase I in human serum and saliva samples was validated, demonstrating its advantages of simplicity, selectivity, sensitivity and low cost. Importantly, satisfactory agreement between results obtained by the fluorescent method described here and high performance liquid chromatography (HPLC) further confirmed the reliability and accuracy of this approach.     

Enzymatic Synthesis of a DNA Triblock Copolymer that is Composed of Natural and Unnatural Nucleotides

DNA molecules have come under the spotlight as potential templates for the fabrication of nanoscale products, such as molecular‐scale electronic or photonic devices. Herein, we report an enhanced approach for the synthesis of oligoblock copolymer‐type DNA by using the Klenow fragment exonuclease minus of E. coli DNA polymerase I (KF^?) in a multi‐step reaction with natural and unnatural nucleotides. First, we confirmed the applicability of unnatural nucleotides with 7‐deaza‐nucleosides—which was expected because they were non‐metalized nucleotides—on the unique polymerization process known as the “strand‐slippage model”. Because the length of the DNA sequence could be controlled by tuning the reaction time, analogous to a living polymerization reaction on this process, stepwise polymerization provided DNA block copolymers with natural and unnatural bases. AFM images showed that this DNA block copolymer could be metalized sequence‐selectively. This approach could expand the utility of DNA as a template.     

Pre‐Incubation of Auric Acid with DNA Is Unnecessary for the Formation of DNA‐Templated Gold Nanoclusters

The rationale for the preparation of DNA‐templated gold nanoclusters (DNA‐Au NCs) has not been well understood, thereby slowing down the advancement of the synthesis and applications of DNA‐Au NCs. The interaction between metal ions and the DNA template seems to be the key factor for the successful preparation of DNA‐templated metal nanoclusters. With the help of circular dichroism in this contribution, we put efforts into interrogating the necessity of pre‐incubation of HAuCl₄ with poly‐adenine template in the formation of Au NCs by citrate reduction. Our results revealed that the pre‐incubation of HAuCl₄ with poly‐adenine is not favorable for the formation of Au NCs, which is distinctly different from the formation process for silver nanoclusters. It is our hope that this study can provide guidance in the preparation of Au NCs with more DNA templates.     

Electrochemical Detection of DNA Hybridization Based on the Probe Labeled with Carbon‐Nanotubes Loaded with Silver Nanoparticles

A sensitive electrochemical method for the detection of DNA hybridization based on the probe labeled with multiwall carbon‐nanotubes (MWNTs) loaded with silver nanoparticles (Ag‐MWNTs) has been developed. MWNTs were electroless‐plated with a large number of silver nanoparticles to form Ag‐MWNTs. Probe single strand DNA (ss‐DNA) with a thiol group at the 3′‐terminal labeled with Ag‐MWNTs by self‐assembled monolayer (SAM) technique was employed as an electrochemical probe. Target ss‐DNA with a thiol group was immobilized on a gold electrode by SAM technique and then hybridized with the electrochemical probe. Binding events were monitored by differential pulse voltammetric (DPV) signal of silver nanoparticles. The signal difference permitted to distinguish the match of two perfectly complementary DNA strands from the near perfect match where just three base pairs were mismatched. There was a linear relation between the peak current at +120 mV (vs. SCE) and complementary target ss‐DNA concentration over the range from 3.1×10^?14 to 1.0×10^?11 mol/L with a detection limit of 10 fmol/L of complementary target ss‐DNA. The proposed method has been successfully applied to detection of the DNA sequence related to cystic fibrosis. This work demonstrated that the MWNTs loaded with silver nanoparticles offers a great promising approach for sensitive detection of DNA hybridization.     

Lead‐Free Sodium–Indium Double Perovskite Nanocrystals through Doping Silver Cations for Bright Yellow Emission

Lead‐free halide perovskite nanocrystals (NCs) have drawn wide attention for solving the problem of lead perovskites toxicity and instability. Herein, we synthesize the direct band gap double perovskites undoped and Ag‐doped Cs₂NaInCl₆ NCs by variable temperature hot injection. The Cs₂NaInCl₆ NCs have little photoluminescence because of dark self‐trapped excitons (STEs). The dark STEs can be converted into bright STEs by doping with Ag⁺ to produce a bright yellow emission, with the highest photoluminescence quantum efficiency of 31.1 %. The dark STEs has been directly detected experimentally by ultrafast transient absorption (TA) techniques. The dynamics mechanism is further studied. In addition, the Ag‐doped NCs show better stability than the undoped ones. This result provides a new way to enhance the optical properties of lead‐free perovskites NCs for high‐performance light emitters.     

Ligation-triggered fluorescent silver nanoclusters system for the detection of nicotinamide adenine dinucleotide

Herein, we demonstrate a novel silver nanocluster-based fluorescent system for the detection of nicotinamide adenine dinucleotide (NAD⁺), an important biological small molecule involved in a wide range of biological processes. A single-stranded dumbbell DNA probe was designed and used for the assay, which contained a nick in the stem, a poly-cytosine nucleotide loop close to 5′ end as the template for the formation of highly fluorescent silver nanoclusters (Ag NCs) and another loop close to 3′ end. Only in the presence of NAD⁺, the probe was linked at 5′ and 3′ ends by Escherichia coli DNA ligase, which blocked the DNA polymerase-based extension reaction, ensuring the formation of fluorescent Ag NCs. This technique provided a logarithmic linear relationship in the range of 1 pM–500 nM with a detection limit of as low as 1 pM NAD⁺, and exhibited high selectivity against its analogues, and was then successfully used for the detection of NAD⁺ level in four kinds of cell homogenates. In addition, this new approach was conducted in an isothermal and homogeneous condition without the need of any thermal cycling, washing, and separation steps, making it very simple. Overall, this label-free protocol offers a promising alternative for the detection of NAD⁺, taking advantage of specificity, sensitivity, cost-efficiency, and simplicity.

Primer Extension Reaction Assays for Incorporation of Deoxynucleotide Analogue into DNA

Incorporation of deoxynucleotide analogues into DNA is important for the expansion of DNA functions. Primer extension reactions are commonly used for the assay of such reaction events. However, current assay protocols generally rely on radiolabeling, fluorescence reporter labeling, or removal of specific deoxynucleotide triphosphate in the reaction mixture. Herein we report on the design of two novel assay protocols that utilize a dideoxynucleotide‐terminated template strand and a phosphorothiolate‐modified deoxynucleotide‐terminated template strand. We designed and synthesized a deoxyuridine triphosphate analogue (dU*TP) containing 2‐bromoisobutyryl group and demonstrated that it could be well recognized by ?29DNA polymerase, E. coli DNA polymerase I Klenow Fragment, Bst DNA polymerase Large Fragment, and E. coli DNA polymerase I Klenow Fragment (exo⁽), which translated to effective incorporation of dU*TP into DNA. dU*TP was also successfully incorporated into extremely long single‐stranded DNA at high‐density using ?29 DNA polymerase by rolling circle amplification.     

Ag nanoclusters as probes for turn-on fluorescence recognition of TpG dinucleotide with a high selectivity

CpG dinucleotide in DNA has a great tendency to mutate to TpG dinucleotide and this transition can cause some serious diseases. In this work, fluorescent Ag nanoclusters (Ag NCs) were employed as useful inorganic fluorophores for the potential of selectively discriminating TpG dinucleotide from CpG dinucleotide. Opposite the base Y of interest in YpG dinucleotide (Y = C or T), a bulge site was introduced so as to make the base Y to be unpaired and ready for Ag⁺ binding. Such that the unpaired Y and context base pairs can provide a specific space suitable for creating fluorescent Ag NCs. We found that in comparison with CpG dinucleotide, TpG dinucleotide is much more efficient in growing fluorescent Ag NCs. Therefore, mutation of CpG dinucleotide to TpG can be identified by a turn-on fluorescence response and a high selectivity. More interestingly, Ag NCs exhibit a better performance in the TpG recognition over the other dinucleotides (Y = A and G) than the previously used organic fluorophores. Additionally, the effectiveness of the bulge site design in discriminating these dinucleotides was evidenced by control DNAs having the abasic site structure. We expect that a practical method for TpG dinucleotide recognition with a high selectivity can be developed using the bulge site-grown fluorescent Ag NCs as novel probes.     

Luminescent Noble Metal Nanoclusters as an Emerging Optical Probe for Sensor Development

In the past few years, highly luminescent noble metal nanoclusters (e.g., Au and Ag NCs or Au/Ag NCs in short) have emerged as a class of promising optical probes for the construction of high‐performance optical sensors because of their ultrasmall size (<2 nm), strong luminescence, good photostability, excellent biocompatibility, and unique metal‐core@ligand‐shell structure. In this Focus Review, we briefly summarize the common syntheses for water‐soluble highly‐luminescent thiolate‐ and protein‐protected Au/Ag NCs and their interesting luminescence properties, highlight recent progress in their use as optical sensors with an emphasis on the mechanisms underlying their selectivity, and finally discuss approaches to improving their sensitivity. The scope of the works surveyed is confined to highly luminescent thiolate‐ and protein‐protected Au/Ag NCs.     

Fluorescent Silver Nanoclusters as Effective Probes for Highly Selective Detection of Mercury(II) at Parts‐per‐Billion Levels

Facile preparation of water‐soluble and fluorescent Ag nanoclusters (NCs) stabilized by glutathione at room temperature is described. Although the glutathione layer was introduced to prevent the silver nanoparticles from decomposition and increase their water solubility, this simple surface optimization resulted in surprisingly high efficiency of selective Hg²⁺ sensing, where the limit of detection (LOD) was as low as 10^?10 M (0.02 ppb, 0.1 nM ). This result revealed a simple and practical strategy for Hg²⁺ detection using fluorescent Ag NCs as sensor probe, with the lowest detecting limits reported to date.     

Construction of an Upconversion Nanoprobe with Few‐Atom Silver Nanoclusters as the Energy Acceptor

Herein we report that few‐atom silver nanoclusters (Ag NCs) can be effective energy acceptors for upconversion phosphors (UCPs). A luminescence resonance energy transfer (LRET) probe for biothiols was constructed by decorating UCPs with dithiol‐stabilized Ag NCs. Owing to the unique properties of ultrasmall NCs, properties which bridge the gap between those of small molecules and those of nanoparticles, the use of approximately 1.9 nm Ag NCs as energy acceptors endows the probe with high energy‐transfer efficiency, good biocompatibility, and flexibility. The UCP–Ag NC nanoprobe enables rapid and robust target assay in solutions. It was also uploaded into living cells and used to detect intracellular biothiol levels with high discrimination. Moreover, the probe shows transportability in vivo and can be used for tissue imaging. The facile growth of few‐atom metal NCs on diverse templates may enable the development of various nanoprobes combining UCPs and metal NCs.     

日光辐射光还原合成左旋多巴胺功能化的荧光发射的银纳米簇和铁离子检测

以左旋多巴胺(L-3,4-dihydroxyphenylalanine,DOPA)为稳定剂,采用日光辐射光还原法,合成了强荧光发射的银纳米簇(silver nanoclusters,Ag NCs)。透射电镜分析表明,所合成的Ag NCs表现亚纳米非晶态结构。Ag NCs在可见-近红外波长范围内(400~750 nm)有明显光吸收带,最大荧光激发和发射峰分别为550和630 nm,荧光量子产率为2.3%(相对于罗丹明B)。Ag NCs的荧光强度与合成时的日光辐射时间、DOPA浓度以及pH值等因素有关。进一步优化了合成Ag NCs的条件。基于荧光猝灭原理,所合成的DOPA功能化的Ag NCs能选择性地灵敏响应Fe3+。修饰在Ag NCs表面的配体DOPA能够选择性地结合Fe3+,导致Ag NCs显著聚集,伴随荧光猝灭。Ag NCs具有的较高量子产率和红荧光发射特性,有利于提高Fe3+的分析灵敏度。     

Microwave‐Assisted Synthesis of Glycopolymer‐Functionalized Silver Nanoclusters: Combining the Bioactivity of Sugar with the Fluorescence and Cytotoxicity of Silver

Copolymers of 2‐(methacrylamido)glucopyranose (MAG) and methacrylic acid (MAA) are synthesized by RAFT polymerization and then used as templates to prepare glycopolymer‐functionalized Ag nanoclusters (Gly‐Ag NCs) through microwave irradiation. Polymers and the resulting nanoclusters are characterized by NMR, GPC, UV‐Vis, SEM, TEM, AAS and fluorescence spectroscopy. The bio‐activity of the fluorescent Gly‐Ag NCs are further examined using GLUT‐1 over‐expressing cancer cells K562. Gly‐Ag NCs show efficient binding ability toward K562 cells and inhibit the cell viability in a dose dependent manner (IC50 = 0.65 μg mL^–1), indicating their potential biological applications for both cancer imaging and targeted cancer therapy.

     

日光辐射光还原合成左旋多巴胺功能化的荧光发射的银纳米簇和铁离子检测

以左旋多巴胺（L-3,4-dihydroxyphenylalanine,DOPA）为稳定剂,采用日光辐射光还原法,合成了强荧光发射的银纳米簇（silvernanoclusters,AgNCs）。透射电镜分析表明,所合成的AgNCs表现亚纳米非晶态结构。AgNCs在可见-近红外波长范围内（400~750nm）有明显光吸收带,最大荧光激发和发射峰分别为550和630nm,荧光量子产率为2.3%（相对于罗丹明B）。AgNCs的荧光强度与合成时的日光辐射时间、DOPA浓度以及pH值等因素有关。进一步优化了合成AgNCs的条件。基于荧光猝灭原理,所合成的DOPA功能化的AgNCs能选择性地灵敏响应Fe³⁺。修饰在AgNCs表面的配体DOPA能够选择性地结合Fe³⁺,导致AgNCs显著聚集,伴随荧光猝灭。AgNCs具有的较高量子产率和红荧光发射特性,有利于提高Fe³⁺的分析灵敏度。     

Silver Doping‐Induced Luminescence Enhancement and Red‐Shift of Gold Nanoclusters with Aggregation‐Induced Emission

A deep understanding on the luminescence property of aggregation‐induced emission (AIE) featured metal nanoclusters (NCs) is highly desired. This paper reports a systematic study on enhancing the luminescence of AIE‐featured Au NCs, which is achieved by Ag doping to engineer the size/structure and aggregation states of the Au^I‐thiolate motifs in the NC shell. Moreover, by prolonging the reaction time, the luminescence of the as‐synthesized AuAg NCs could be further tailored from orange to red, which is also due to the variation of the Au^I‐thiolate motifs of NCs. This study can facilitate a better understanding of this AIE‐featured luminescent probe and the design of other synthetic routes for this rising family of functional materials.     

Divalent Europium Nanocrystals: Controllable Synthesis,Properties, and Applications

Magnetic and luminescent bifunctional divalent europium nanocrystals (Eu²⁺ NCs) are a promising class of novel advanced materials that have various applications in magneto‐optic devices, catalysis, bioimaging, and solar cells. In the past few decades, much work has been carried out to study the synthesis, properties, and applications of Eu²⁺ NCs. The aim of this Minireview is to present the progress in preparing Eu²⁺ NCs based on the reported research, by describing the advantages and disadvantages of the synthesis methods. The morphologies and size are controlled through adjusting the experimental conditions. Eu²⁺ NCs show superior magnetic and luminescence properties simultaneously. Self‐assembly and doping with other ions are important routes to improve their magnetic and luminescence properties. Their applications in magneto‐optic devices are discussed. Some difficulties and challenges in the fabrication of Eu²⁺ NCs are discussed, such as water‐soluble Eu²⁺ NCs and tunable luminescence in the whole visible region.