A ratiometric and two-photon fluorescent probe for imaging hydrogen peroxide in living cells

As an important reactive oxygen species (ROS), hydrogen peroxide plays a significant role in the life activity system, and its abnormal levels are closely related to many diseases. Developing effective fluorescent probes for detecting hydrogen peroxide is very urgent. Therefore, we constructed a probe Z that can detect hydrogen peroxide in ratio. It has naphthimide as the fluorophore and phenylboronic acid pinacol esters as the recognition group. It shows higher sensitivity, lower detection limit, higher selectivity, and broad pH applicability. Moreover, probe Z has low cytotoxicity that can be used to detect exogenous hydrogen peroxide in HeLa cells and might be a potential tool for studying hydrogen peroxide in physiological activities.     

Synthesis,characterization, and cellular localization of a fluorescent probe of the antimalarial 8-aminoquinoline primaquine

Primaquine (PQ) is the only commercially available drug that clears dormant liver stages of malaria and blocks transmission to mosquito vectors. Although an old drug, much remains to be known about the mechanism(s) of action. Herein we develop a fluorescent tagged PQ to discover cellular localization in the human malaria parasite, Plasmodium falciparum. Successful synthesis and characterization of a primaquine-coumarin fluorescent probe (PQCP) demonstrated potency equivalent to the parent drug and the probe was not cytotoxic to HepG2 carcinoma cells. Cellular localization was found primarily in the cytosol of the asexual erythrocytic and gametocyte stages of parasite development.     

A ratiometric fluorescent probe for rapid and specific detection of hypochlorite

Hypochlorite (ClO⁻), as a kind of essential reactive oxygen species, plays a crucial role in vitro and in vivo. Here, a ratiometric fluorescent probe ( TPAM ) was designed and constructed for sensing ClO⁻ based on substituted triphenylamine and malononitrile, which exhibited obvious colour transfer from orange to colourless under daylight accompanied by noticeable fluorescence change from red to green in response to ClO⁻. TPAM could effectively monitor ClO⁻ with the merits of fast response, excellent selectivity, high sensitivity and a low detection limit of 0.1014 μM. ¹H NMR, mass spectra and theoretical calculations proved that ClO⁻ caused the oxidation of the carbon–carbon double bond in TPAM , resulting in compound 1 and marked changes in colour and fluorescence. In addition, TPAM was utilized for imaging ClO⁻ in living cells successfully with good photostability and biocompatibility.     

A dual-emission fluorescent probe for discriminating cysteine from homocysteine and glutathione in living cells and zebrafish models

Cellular biothiols function crucially and differently in physiological and pathological processes. However, it is still challenging to detect and discriminate thiols within a single one molecule, especially for cysteine (Cys) and homocysteine (Hcy). In this study, a simple two-emission turn-on fluorescent biothiol probe (ICN-NBD) was rationally designed and synthesized through a facile ether bond linking 7-nitro-1,2,3-benzoxadiazole (NBD) and phenanthroimidazole containing a cyano tail. The probe in the presence of Cys elicited two fluorescence responses at 470 nm and 550 nm under excitation at 365 nm and 480 nm, respectively, because of the concomitant generation of both the fluorophore and NBD-N-Cys. In contrast, addition of Hcy and glutathione (GSH) could result in only a blue fluorescence enhancement at 470 nm. which was reasonably attributed to rearrangement from NBD-S-Hcy/GSH to NBD-N-Hcy/GSH as a result of geometrical constraints or solvent effects. Therefore, the fluorescent probe with the NBD scaffold could detect biothiols and simultaneously discriminate Cys from Hcy/GSH in both blue and green channels. The probe has been successfully applied for visualizing biothiols in living cells and zebrafish.     

A reactive probe for Co2+ ion detection based on a catalytic decomposition process and its fluorescence imaging in living cells

A novel reactive fluorescent probe for cobalt ions was prepared based on integration of thiourea functional groups, coumarin, and naphthalimide fluorophores. There was no fluorescence observed for the probe itself, however, in the presence of cobalt ions, catalytic decomposition occurred for the probe and coumarin molecular fragments were produced that emitted blue fluorescence. This enabled the probe to be used as a ‘turn on’ reagent for detection of cobalt ions. Under physiological pH conditions and in appropriate solvent systems, an obvious fluorescence enhancement for cobalt ions was observed in selective experiments. Competition experiments indicated that cobalt ions could still induce fluorescence enhancement in the presence of other metal ions. Sensitivity experiments showed that the detection limit for cobalt ions was 6.0 nM. Dynamics research demonstrated that the catalytic process was a pseudo‐first‐order reaction and the reaction constant (k_obs) was calculated to be 1.49 × 10^?2 min^?1. In addition, the mechanism of catalytic decomposition could be demonstrated using electrospray ionization mass spectrometry and thin layer chromatography experiments. Cell fluorescence imaging experiments demonstrated that the probe could be used to detect cobalt ions in living HeLa cells.     

A simple boronic acid-based fluorescent probe for selective detection of hydrogen peroxide in solutions and living cells

An approach of high sensitivity and selectivity for hydrogen peroxide (H₂O₂) detection is highly demanded due to its important roles in regulating diverse biological process. In this work, we introduced an easily synthesized fluorescent “turn off” probe, BNBD. It is designed based on the core structure of 4-chloro-7-nitrobenzofurazan as a fluorophore and incorporated with a specific H₂O₂-reactive group, aryl boronate, for sensitive and selective detection of H₂O₂. We demonstrated its selectivity by incubating the probe with other types of ROS, and measured the limit of detection of BNBD as 1.8 nM. BNBD is also conducive to H₂O₂ detection at physiological conditions. We thus applied it to detect both exogenous and endogenous changes of H₂O₂ in living cells by confocal microscopy, supporting its future applications to selectively monitor H₂O₂ levels and identify H₂O₂-related physiological or pathological responses from live cells or tissues in the near future.     

A new fluorescent pH probe for imaging lysosomes in living cells

A new rhodamine B-based pH fluorescent probe has been synthesized and characterized. The probe responds to acidic pH with short response time, high selectivity and sensitivity, and exhibits a more than 20-fold increase in fluorescence intensity within the pH range of 7.5–4.1 with the pK_a value of 5.72, which is valuable to study acidic organelles in living cells. Also, it has been successfully applied to HeLa cells, for its low cytotoxicity, brilliant photostability, good membrane permeability and no ‘alkalizing effect’ on lysosomes. The results demonstrate that this probe is a lysosome-specific probe, which can selectively stain lysosomes and monitor lysosomal pH changes in living cells.     

A coumarin‐based fluorescent probe for Hg2+ and its application in living cells and zebrafish

Mercury (Hg) is a heavy metal with high toxicity and easy migration; it can be enriched through the food chain, and cause serious threats to the natural environment and human health. So, the development of a method that can be used to detect mercury ions (Hg²⁺) in the environment, in cells, and in organisms is very important. Here, a new 7‐hydroxycoumarin‐derived carbonothioate‐based probe ( CC‐Hg ) was designed and synthesized for detection of Hg²⁺. After addition of Hg²⁺, a large fluorescence enhancement was observed due to the formation of 7‐hydroxyl, which reinforced the intramolecular charge transfer process. The CC‐Hg probe had good water solubility and selectivity. Moreover, the probe was able to detect Hg²⁺ quantitatively over the concentration range 0–2 μM and with a detection limit of 7.9 nM. Importantly, we successfully applied the probe to detect Hg²⁺ in water samples, in living cells, and in zebrafish. The experimental results demonstrated its potential value in practical applications.     

A highly sensitive ratiometric fluorescent probe based on fluorescein coumarin for detecting hydrazine in actual water and biological samples

Hydrazine (N₂H₄) is a highly toxic and harmful chemical reagent. Fluorescent probes are simple and efficient tools for sensitive monitoring of N₂H₄ enrichment in the environment, humans, animals, and plants. In this work, a ratiometric fluorescent probe (FP-1) containing coumarin was used for hydrazine detection. The proposed FP-1 probe had a linear detection range of 0–250 μM and a limit of detection (LOD) of 0.059 μM (1.89 ppb). A large red Stokes shift was observed in fluorescence and UV–vis absorption spectra due to the hydrolysis of ester bonds between FP-1 and hydrazine. The hydrazine detection mechanism of FP-1 was also investigated using density functional theory (DFT) calculations. Finally, FP-1 could sensitively and selectively monitor hydrazine in actual water samples and BEAS-2B cells. Therefore, it has great application potential in environmental monitoring and disease diagnosis.     

A fast‐responsive fluorescent probe for sulfite and its bioimaging

A turn‐on fluorescent probe Coumarin‐SO2 based on a nucleophilic addition reaction was developed for the rapid detection of SO₃^2– in aqueous media. The probe Coumarin‐SO2 displays excellent water solubility, fast response, highly sensitivity and highly selectivity over other biological related species. More importantly, living cell imaging experiments indicate the feasibility of using the probe for the detection of SO₃^2– in biological systems. Copyright © 2015 John Wiley & Sons, Ltd.     

Influence of DNA-methylation on zinc homeostasis in myeloid cells: Regulation of zinc transporters and zinc binding proteins

The distribution of intracellular zinc, predominantly regulated through zinc transporters and zinc binding proteins, is required to support an efficient immune response. Epigenetic mechanisms such as DNA methylation are involved in the expression of these genes. In demethylation experiments using 5-Aza-2′-deoxycytidine (AZA) increased intracellular (after 24 and 48 h) and total cellular zinc levels (after 48 h) were observed in the myeloid cell line HL-60. To uncover the mechanisms that cause the disturbed zinc homeostasis after DNA demethylation, the expression of human zinc transporters and zinc binding proteins were investigated. Real time PCR analyses of 14 ZIP (solute-linked carrier (SLC) SLC39A; Zrt/IRT-like protein), and 9 ZnT (SLC30A) zinc transporters revealed significantly enhanced mRNA expression of the zinc importer ZIP1 after AZA treatment. Because ZIP1 protein was also enhanced after AZA treatment, ZIP1 up-regulation might be the mediator of enhanced intracellular zinc levels. The mRNA expression of ZIP14 was decreased, whereas zinc exporter ZnT3 mRNA was also significantly increased; which might be a cellular reaction to compensate elevated zinc levels. An enhanced but not significant chromatin accessibility of ZIP1 promoter region I was detected by chromatin accessibility by real-time PCR (CHART) assays after demethylation. Additionally, DNA demethylation resulted in increased mRNA accumulation of zinc binding proteins metallothionein (MT) and S100A8/S100A9 after 48 h. MT mRNA was significantly enhanced after 24 h of AZA treatment also suggesting a reaction of the cell to restore zinc homeostasis. These data indicate that DNA methylation is an important epigenetic mechanism affecting zinc binding proteins and transporters, and, therefore, regulating zinc homeostasis in myeloid cells.     

Design of a phosphinate‐based bioluminescent probe for superoxide radical anion imaging in living cells

Superoxide radical anion (O₂˙^?) as an important member of reactive oxygen species (ROS) plays a vital role both in physiology and pathology. Herein we designed and synthesized a novel phosphinate‐based bioluminescence probe for O₂˙^? detection in living cells, which exhibited good sensitivity for capturing O₂˙^? at the nanomole level and high selectivity against other ROS. The probe was further found to be of low toxicity for living cells and was then successfully employed for sensing endogenous O₂˙^? by using phorbol‐12‐myristate‐13‐acetate (PMA) as a traditional O₂˙^? stimulator in Huh7 cells. Moreover, the increasing production and use of nanoparticles, has given rise to many concerns and debates among the public and scientific authorities regarding their safety and final fate in biological systems. Herein it was found that mondisperse polystyrene particles could stimulate O₂˙^? generation in Huh7 cells. Overall, the probe was demonstrated to have a great potential as a novel bioluminescent sensor for detecting O₂˙^? in living cells. To our knowledge, this is the first small‐molecule phosphinate‐based bioluminescence probe that will open up great opportunities for unlocking the mystery of O₂˙^? in human health and disease.     

Heterogeneous transportation of alpha1B-adrenoceptor in living cells

The heterogeneous motion of alpha(1B)-adrenoceptor (alpha(1B)-AR) was visualized in living cells with BODIPY-labeled antagonist of AR by single molecule fluorescence microscopy at high spatial resolution. The moving trajectory was reconstructed by precise localization (better than 20 nm) with a least-square fit of a two-dimensional Gaussian point spread function to each single spot. Trajectory analysis revealed two apparent groups of movements: directed motion and hindered motion. The directed motion had speeds higher than 0.1 mum/s. The histogram of diffusion coefficients of the hindered motion showed distinction between the cell membrane and the cytoplasm: the diffusion coefficient was lower near the cell membrane than in the internal cytoplasm, suggesting that alpha(1B)-AR was located or trapped in different networks, which was consistent with the natural distribution of cytoskeleton in living cells. These results suggested that the heterogeneity in the motion of alpha(1B)-AR in living cell might be associated with different localizations of cell skeleton proteins in the cell, which could provide molecular insight of AR regulation in living cells.     

TMA-DPH A fluorescent probe of membrane dynamics in living cells

Trimethylammonium-diphenylhexatriene (TMA-DPH), a hydrophobic fluorescent probe, has been shown in earlier studies to possess a variety of particular properties in interaction with intact living cells —specific and rapid incorporation into the plasma membrane and partition equilibrium between the membranes and the buffer. These properties offer promising applications in membrane fluidity studies and in monitoring exocytosis kinetics. Furthermore, these properties offer a method described here for quantitative monitoring of phago-cytosis kinetics, by means of simple fluorescence intensity measurements. This method is original in that it evaluates only the particles which have actually been internalized by phagocytosis, and not those adsorbed on the cell surface, and that it gives quantitative information on the amount of plasma membrane involved in the process. It has been tested on mouse bone marrow macrophages.     

Direct visualization of nucleolar G-quadruplexes in live cells by using a fluorescent light-up probe

Background

Direct detection of G-quadruplexes in human cells has become an important issue due to the vital role of G-quadruplex related to biological functions. Despite several probes have been developed for detection of the G-quadruplexes in cytoplasm or whole cells, the probe being used to monitor the nucleolar G-quadruplexes is still lacking.

PeakForce Tapping resolves individual microvilli on living cells

Microvilli are a common structure found on epithelial cells that increase the apical surface thus enhancing the transmembrane transport capacity and also serve as one of the cell's mechanosensors. These structures are composed of microfilaments and cytoplasm, covered by plasma membrane. Epithelial cell function is usually coupled to the density of microvilli and its individual size illustrated by diseases, in which microvilli degradation causes malabsorption and diarrhea. Atomic force microscopy (AFM) has been widely used to study the topography and morphology of living cells. Visualizing soft and flexible structures such as microvilli on the apical surface of a live cell has been very challenging because the native microvilli structures are displaced and deformed by the interaction with the probe. PeakForce Tapping® is an AFM imaging mode, which allows reducing tip–sample interactions in time (microseconds) and controlling force in the low pico‐Newton range. Data acquisition of this mode was optimized by using a newly developed PeakForce QNM‐Live Cell probe, having a short cantilever with a 17‐µm‐long tip that minimizes hydrodynamic effects between the cantilever and the sample surface. In this paper, we have demonstrated for the first time the visualization of the microvilli on living kidney cells with AFM using PeakForce Tapping. The structures observed display a force dependence representing either the whole microvilli or just the tips of the microvilli layer. Together, PeakForce Tapping allows force control in the low pico‐Newton range and enables the visualization of very soft and flexible structures on living cells under physiological conditions. © 2015 The Authors Journal of Molecular Recognition Published by John Wiley & Sons Ltd.     

A novel fluorescent probe with large Stokes shift for the detection of viscosity changes and its imaging in living cells

As an important cellular microenvironmental parameter, viscosity could reflect the status of living cells. Small molecular fluorescent probes are a vital tool to measure the change of viscosity in living cells. A novel fluorescence probe ZL-1 with a large Stokes shift (in methanol it reached to 153 nm and in glycerol it reached to 125 nm) and excellent sensitivity toward viscosity was developed. The sharp enhancement of the emission intensity for the probe ZL-1 from low viscous methanol to high viscous glycerol indicated that the probe ZL-1 could respond to the viscosity variations. Moreover, the probe ZL-1 has been successfully utilized to detect of the viscosity variations in living cells.     

Ratiometric fluorimetric and colorimetric probe for sensing and imaging pH changes in living cells

Cell, enzyme, and tissue activity in living organisms are closely related to intracellular pH. Detecting the changes of intracellular pH is important to understanding the physiological and pathological changes in the process of crucial cell metabolism. A pH probe (HTBI) based on hemicyanine was synthesized. The probe solution displayed a marked colour change from yellow to amaranth with the pH increase from neutral to basic; simultaneously, the emission spectra showed a significant red shift. The probe exhibited a ratiometric fluorescence emission (F_586nm/F_542nm) characteristic of pK_a 8.82. As expected, HTBI exhibited high sensitivity and selectivity for pH, fine photostability, reversibility, and low cytotoxicity. Therefore, it would be a very useful tool for measuring the intracellular pH changes.     

The relationship between beta cell activation and SLC30A8/ZnT8 levels of the endocrine pancreas and maternal zinc deficiency in rats

ObjectivesZinc, which is found in high concentrations in the β-cells of the pancreas, is also a critical component for the endocrine functions of the pancreas. SLC30A8/ZnT8 is the carrier protein responsible for the transport of zinc from the cytoplasm to the insulin granules. The aim of this study was to investigate how dietary zinc status affects pancreatic beta cell activation and ZnT8 levels in infant male rats born to zinc-deficient mothers.MethodsThe study was performed on male pups born to mothers fed a zinc-deficient diet. A total of 40 male rats were divided into 4 equal groups. Group 1: In addition to maternal zinc deficiency, this group was fed a zinc-deficient diet. Group 2: In addition to maternal zinc deficiency, this group was fed a standard diet. Group 3: In addition to maternal zinc deficiency, this group was fed a standard diet and received additional zinc supplementation. Group 4: Control group. Pancreas ZnT8 levels were determined by ELISA method and insulin-positive cell ratios in β-cells by immunohistochemistry.ResultsThe highest pancreatic ZnT8 levels and anti-insulin positive cell ratios in the current study were obtained in Group 3 and Group 4. In our study, the lowest pancreatic ZnT8 levels were obtained in Group 1 and Group 2, and the lowest pancreatic anti-insulin positive cell ratios were obtained in Group 1.ConclusionThe results of the present study; in rats fed a zinc-deficient diet after maternal zinc deficiency has been established shows that ZnT8 levels and anti-insulin positive cell ratios in pancreatic tissue, which is significantly suppressed, reach control values with intraperitoneal zinc supplementation.     

A novel colorimetric fluorescent probe for detecting hydrazine in living cells and zebrafish

Hydrazine (NH₂NH₂) is a highly toxic organic substance that poses a threat to human health. Monitoring hydrazine with high sensitivity and selectivity is very important. Here, a simple colorimetric fluorescent probe for hydrazine detection, which is a seminaphthorhodafluor derivative containing thiophene-2-carboxylic acid ester reaction site, was rationally constructed. The probe itself exhibits weak fluorescence. The fluorescence is significantly enhanced when hydrazine is added. The probe exhibited a broad linear range (0–1 mM) with satisfactory selectivity and sensitivity (limit of detection 36.4 μM), which turned out to be an excellent fluorescent probe for monitoring hydrazine. Additionally, the probe was used to track hydrazine in living cells and zebrafish with great success, and the detection performance was satisfying. These results proved that this type of fluorescent probe with the thiophene-2-carboxylic acid ester structure can detect hydrazine with higher selectivity and sensitivity.