A Double‐Clicking Bis‐Azide Fluorogenic Dye for Bioorthogonal Self‐Labeling Peptide Tags

Herein, we give the very first example for the development of a fluorogenic molecular probe that combines the two‐point binding specificity of biarsenical‐based dyes with the robustness of bioorthogonal click‐chemistry. This proof‐of‐principle study reports on the synthesis and fluorogenic characterization of a new, double‐quenched, bis‐azide fluorogenic probe suitable for bioorthogonal two‐point tagging of small peptide tags by double strain‐promoted azide–alkyne cycloaddition. The presented probe exhibits remarkable increase in fluorescence intensity when reacted with bis‐cyclooctynylated peptide sequences, which could also serve as possible self‐labeling small peptide tag motifs.     

新型经由三氮唑连接的含芘基团的杯[4]芳烃：对锌离子的比率荧光识别及其在组合逻辑门中的应用

通过“click”反应合成了两个新的由三氮唑连接的含芘的杯[4]芳烃。 化合物1含有两个芘单元,对Zn2+表现出比率荧光响应,且对Cu2+, Hg2+ 和 Pb2+表现出选择性的荧光淬灭;而化合物2只含一个芘单元,对铜离子有显著的荧光淬灭,对汞离子有中等程度的荧光淬灭。利用化合物1对锌离子和铜离子不同的荧光响应,设计了INH和NOR逻辑门。     

A fluorescent sensor for Hg and Ag functions as a molecular switch based on click-generated triazole moiety

The novel (S)-BINOL-based sensor 1 incorporating triazole moieties could be obtained by click reaction. The results show that 1 can exhibit excellent fluorescence response behaviors toward Hg²⁺ (selective switching-off) and Ag⁺ (selective switching-on) without interference from other metal ions, which functions as a molecular switch. This work can expand the application of click reaction in design and synthesis of the novel fluorescence sensor molecules.     

基于喹啉和三唑环的开链冠醚对金属离子的选择传感

本文通过Click化学反应合成了一种含喹啉基和三唑基的开链冠醚, 考察和比较了主体化合物对镉等金属离子的荧光传感和选择性键合行为, 并通过荧光和核磁等手段研究了溶剂对其荧光传感的影响.     

BODIPY based ‘click on’ fluorogenic dyes: application in live cell imaging

The design, synthesis, and photophysical properties of new BODIPY-based fluorogenic ‘click on’ dyes are reported. CuAAC reaction of non-fluorescent BODIPY azide with a series of non-fluorescent alkyne molecules resulted in fluorescent triazoles which displayed up to 532-fold enhancement of fluorescence in the red region. Imaging studies confirmed the general trend of cell permeability and a cholesterol linked derivative exhibited selective localization into intracellular membranes.     

A fluorogenic probe for the copper(I)-catalyzed azide-alkyne ligation reaction: modulation of the fluorescence emission via 3(n,pi)-1(pi,pi) inversion

Chemoselective ligation reactions represent a powerful approach for labeling of proteins or small molecules in a biological environment. We report here a fluorogenic probe that is activated by click chemistry, a highly versatile bio-orthogonal and chemoselective ligation reaction which is based on the azide moiety as the functional group. The electron-donating properties of the triazole ring that is formed in the course of the coupling reaction was effectively utilized to modulate the fluorescence output of an electronically coupled coumarin fluorophore. Under physiological conditions the probe is essentially nonfluorescent and undergoes a bright emission enhancement upon ligation with an azide. Time-resolved emission spectroscopy and semiempirical quantum-mechanical calculations suggest that the fluorescence switching is due to an inversion of the energy ordering of the emissive 1(pi,pi*) and nonemissive 3(n,pi*) excited states. The rapid kinetics of the ligation reaction render the probe attractive for a wide range of applications in biology, analytical chemistry, or material science.     

Sensitive fluorescence sensor for nitroaniline isomers based on calix[4]arene bearing naphthyl groups

Novel naphthyl-modified calix[4]arene was synthesized by click chemistry, and exhibited high affinity and selectivity for p-nitroaniline by the fluorescence spectroscopy. However, the sensitivity toward other anilines 3a–e are negligible. The ¹H NMR, ¹H NOESY, MALDI-TOF mass spectroscopy and computational calculations revealed the formation of host–guest complex driven by H-bonding and hydrophobic interactions.     

A general strategy to the intracellular sensing of glycosidases using AIE-based glycoclusters

Glycosidases, which are the enzymes responsible for the removal of residual monosaccharides from glycoconjugates, are involved in many different biological and pathological events. The ability to detect sensitively the activity and spatiotemporal distribution of glycosidases in cells will provide useful tools for disease diagnosis. However, the currently developed fluorogenic probes for glycosidases are generally based on the glycosylation of the phenol group of a donor–acceptor type fluorogen. This molecular scaffold has potential drawbacks in terms of substrate scope, sensitivity because of aggregation-caused quenching (ACQ), and the inability for long-term cell tracking. Here, we developed glycoclusters characterized by aggregation-induced emission (AIE) properties as a general platform for the sensing of a variety of glycosidases. To overcome the low chemical reactivity associated with phenol glycosylation, here we developed an AIE-based scaffold, which is composed of tetraphenylethylene conjugated with dicyanomethylene-4H-pyran (TPE–DCM) with a red fluorescence emission. Subsequently, a pair of dendritic linkages was introduced to both sides of the fluorophore, to which six copies of monosaccharides (d-glucose, d-galactose or l-fucose) were introduced through azide–alkyne click chemistry. The resulting AIE-active glycoclusters were shown to be capable of (1) fluorogenic sensing of a diverse range of glycosidases including β-d-galactosidase, β-d-glucosidase and α-l-fucosidase through the AIE mechanism, (2) fluorescence imaging of the endogenous glycosidase activities in healthy and cancer cells, and during cell senescence, and (3) glycosidase-activated, long-term imaging of cells. The present study provides a general strategy to the functional, in situ imaging of glycosidase activities through the multivalent display of sugar epitopes of interest onto properly designed AIE-active fluorogens.

We report a general strategy for the fluorogenic sensing of glycosidases in cells based on aggregation-induced emission of glycoclusters.     

Selective sensing of Hg2+ by a proton-ionizable calix[4]arene fluoroionophore

A fluorogenic derivative of a calix[4]arene with two proton-ionizable N-(phenyl)sulfonyl carboxamide-containing side arms in the 1,3-positions on the lower rim is employed for the selective sensing of Hg²⁺ at low concentration levels in water/MeCN (1:1, v/v) solutions containing Pb²⁺ and Cd²⁺. All three metal ions quench the fluorescence of the ligand in pure MeCN. However, in water/MeCN mixed solvent, the recognition of such cations occurs differently as only Hg²⁺ complexation quenches the fluorescence of the calixarene. Experiments carried out in the presence of an acid and a bulky non-complexing cation shows that the quenching of the calixarene fluorescence upon Hg²⁺ addition is likely due to proton displacement from the proton-ionizable side arms of the ligand. The system may be employed as a simple tool for the selective and efficient mercury sensing in mixed water/organic solvent.     

Rhodamine triazole-based fluorescent probe for the detection of Pt(2+)

A rhodamine triazole-based fluorescent chemosensor has been developed for the selective detection of platinum ions in aqueous solutions. The rhodamine 6G hydroxamate linked with a propargyl group is converted to the corresponding triazole by a "click" reaction. The dual binding unit composed of a hydroxamate and a triazole shows high selectivity and sensitivity toward Pt(2+) over a range of other metal ions in water. The fluorescent probe is applied to monitor cisplatin in aqueous solutions.     

A new click reaction generated AIE-active polymer sensor for Hg2+ detection in aqueous solution

We described herein a new AIE-active polymer sensor incorporating triazole moiety for Hg²⁺ detection in aqueous solution. The polymer sensor P1 was synthesized from tetraphenylethene and diazidobenzene via click reaction. It shows typical AIE feature, and emits cyan fluorescence in the mixture of tetrahydrofuran and water, reaching the strongest fluorescence when the fraction of water (f_w) is 90%. In aqueous solution (f_w?=?90%), the polymer sensor can exhibit fluorescence quenching response towards Hg²⁺ over other competing metal ions, with the fluorescence color changed from cyan to almost no emission, which can be clearly observed by the naked eyes under 365?nm UV lamp.     

Two-dye and one- or two-quencher DNA probes for real-time PCR assay: synthesis and comparison with a TaqMan? probe

A typical TaqMan? real-time PCR probe contains a 5'-fluorescent dye and a 3'-quencher. In the course of the amplification, the probe is degraded starting from the 5'-end, thus releasing fluorescent dye. Some fluorophores (including fluorescein) are known to be prone to self-quenching when located near each other. This work is aimed at studying dye-dye and dye-quencher interactions in multiply modified DNA probes. Twenty-one fluorogenic probes containing one and two fluoresceins (FAM), or a FAM-JOE pair, and one or two BHQ1 quenchers were synthesized using non-nucleoside reagents and "click chemistry" post-modification on solid phase and in solution. The probes were tested in real-time PCR using an ~300-bp-long natural DNA fragment as a template. The structural prerequisites for lowering the probe background fluorescence and increasing the end-plateau fluorescence intensity were evaluated and discussed.     

The effect of substituents on the response of 3,4-dihydro-3-(2-oxo-2-phenylethylidene)-quinoxalin-2(1H)-one derivatives toward binding of Cu2+

A new series of fluorogenic chelating reagents based on phenylethylidene-3,4-dihydro-1H-quinoxalin-2-one with different substituents (attached either to the quinoxaline-2-one (3) or phenyl ring (4)) have been investigated to examine the effect of the substituent (nature/position) on the spectral properties and response toward Cu²⁺ in the presence of other metal cations, in ethanol. It was found that all of the examined ligands exhibit a pronounced response to Cu²⁺ addition resulting in a red-shift in the UV–vis spectra and a strong quenching in the fluorescence spectra. Among the ligands examined, 3a exhibits the highest selectivity toward various metal cations. In general it appears that the best response selectivity of these ligands toward Cu²⁺ ion is obtained by either EDG in 3 or EWG in 4. For example, the fluorescence intensity of 3a (with OMe substituent) increases to about three times that of the unsubstituted derivative.     

‘Click’ to bidentate bis-triazolyl sugar derivatives with promising biological and optical features

Bidentate 1-O-methyl-α-d-pyranoglucosides bearing two triazolyl α-ketoester groups on the 2,6- or 3,4-positions of sugar scaffold were efficiently synthesized via Cu(I)-catalyzed azide-alkyne 1,3-dipolar cycloaddition (click reaction) in good yields. These newly featured sugar derivatives displayed favorable inhibitory activity on protein tyrosine phosphatase 1B (PTP1B) and unexpected selective fluorescence quenching in the presence of Ni²⁺.     

Dual-mode unsymmetrical squaraine-based sensor for selective detection of Hg2+ in aqueous media

A novel chemosensor based on unsymmetrical squaraine dye (USQ-1) for the selective detection of Hg(2+) in aqueous media is described. USQ-1 in combination with metal ions shows dual chromogenic and "turn-on" fluorogenic response selectivity toward Hg(2+) as compared to Li(+), Na(+), K(+), Mg(2+), Ca(2+), Ba(2+), Al(3+), Cu(2+), Cd(2+), Mn(2+), Fe(3+), Ag(+), Pb(2+), Zn(2+), Ni(2+) and Co(2+) due to the Hg(2+)-induced deaggregation of the dye molecule. A recognition mechanism based on the binding mode is proposed based on the absorption and fluorescence changes, (1)H NMR titration experiments, ESI-MS study, and theoretical calculations.     

Tetrazine-functionalized and vertically-aligned mesoporous silica films with electrochemical activity and fluorescence properties

In spite of their attractive physico-chemical properties making them very promising in the field of functional molecular materials, s-tetrazine derivatives remain underexploited in practical devices mainly because their immobilization in a stable form maintaining all their features is still challenging. Here, we show that combining a ‘click chemistry azide/alkyne’ approach with an electrochemically-assisted self-assembly (EASA) method, which is likely to generate azide-functionalized and vertically-aligned mesoporous silica films, and further derivatization of the ordered mesoporous material with propargyl–tetrazine via a soft Huisgen coupling reaction, enable one to reach this goal. The resulting tetrazine-functionalized films formed onto transparent indium–tin oxide (ITO) electrodes exhibit well-defined voltammetric signals, with peak currents proportional to the functionalization level and stable upon multiple potential scanning, as well as effective fluorescence properties as evidenced from fluorescence spectra with maximum emission at 555–560 nm.     

1H‐1,2,3‐Triazole: From Structure to Function and Catalysis

The heterocyclic family of azoles have recently become one of the most widely used members of the N‐heterocycles; the most prominent one being 1H‐1,2,3‐triazole and its derivatives. The sudden growth of interest in this structural motif was sparked by the advent of click chemistry, first described in the early 2000s. From the early days of click chemistry, when the accessibility of triazoles made them into one of the most versatile linkers, interest has slowly turned to the use of triazoles as functional building blocks. The presence of multiple N‐coordination sites and a highly polarized carbon atom allows for metal coordination and the complexation of anions by both hydrogen and halogen bonding. Exploitation of these multiple binding sites makes it possible for triazoles to be used in various functional materials, such as metallic and anionic sensors. More recently, triazoles have also shown their potential in catalytic systems, thus increasing their impact far beyond the initial purpose of click chemistry. This report gives an overview of the structure, functionalities, and use of triazoles with a focus on their use in catalytic systems.     

Live-Cell Localization Microscopy with a Fluorogenic and Self-Blinking Tetrazine Probe

Recent developments in fluorescence microscopy call for novel small-molecule-based labels with multiple functionalities to satisfy different experimental requirements. A current limitation in the advancement of live-cell single-molecule localization microscopy is the high excitation power required to induce blinking. This is in marked contrast to the minimal phototoxicity required in live-cell experiments. At the same time, quality of super-resolution imaging depends on high label specificity, making removal of excess dye essential. Approaching both hurdles, we present the design and synthesis of a small-molecule label comprising both fluorogenic and self-blinking features. Bioorthogonal click chemistry ensures fast and highly selective attachment onto a variety of biomolecular targets. Along with spectroscopic characterization, we demonstrate that the probe improves quality and conditions for regular and single-molecule localization microscopy on live-cell samples.     

One‐Pot Multicomponent Synthesis of Glycopolymers through a Combination of Host–Guest Interaction,Thiol‐ene,and Copper‐Catalyzed Click Reaction in Water

There is a common phenomenon that the heterogeneity of natural oligosaccharides contains various sugar units, which can be used to enhance affinity and selectivity toward a specific receptor, so the synthesis of heterogeneous glycopolymers is always an important issue in the glycopolymer field. Herein, this study conducts a one‐pot method to prepare polyrotaxane‐based heteroglycopolymers anchored with different sugar units and fluorescent moieties via the combination of host–guest interaction, thiol‐ene, and copper‐catalyzed click chemistry in water. Fourier transform infrared spectroscopy, nuclear magnetic resonance spectroscopy, gel permeation chromatography, X‐ray diffraction, and Ellman's assay test are used in the paper to characterize the compounds. Quartz crystal microbalance‐dissipation (QCD‐D) experiments and bacterial adhesion assay are utilized to study the interactions of polyrotaxane‐based heteroglycopolymers with Con A and Escherichia coli . The results reveal that polyrotaxanes (PRs) with mannose and glucose present better specificity toward Con A and E. coli than PRs with glucose due to synergistic effects.     

“Click” Chemistry Mildly Stabilizes Bifunctional Gold Nanoparticles for Sensing and Catalysis

A large family of bifunctional 1,2,3‐triazole derivatives that contain both a polyethylene glycol (PEG) chain and another functional fragment (e.g., a polymer, dendron, alcohol, carboxylic acid, allyl, fluorescence dye, redox‐robust metal complex, or a β‐cyclodextrin unit) has been synthesized by facile “click” chemistry and mildly coordinated to nanogold particles, thus providing stable water‐soluble gold nanoparticles (AuNPs) in the size range 3.0–11.2 nm with various properties and applications. In particular, the sensing properties of these AuNPs are illustrated through the detection of an analogue of a warfare agent (i.e., sulfur mustard) by means of a fluorescence “turn‐on” assay, and the catalytic activity of the smallest triazole–AuNPs (core of 3.0 nm) is excellent for the reduction of 4‐nitrophenol in water.