The Synthesis of a Coumarin Carbohydrazide Dinuclear Copper Complex Based Fluorescence Probe and Its Detection of Thiols

Small-molecule thiols, such as cysteine (CYS) and glutathione (GSH), are essential for maintaining the cellular redox environment and play important roles in regulating various cellular physiological functions. A fluorescence probe (compound 1-Cu²⁺) for thiols based on coumarin carbohydrazide dinuclear copper complex was developed. Compound 1 was synthesized from the reaction of 7-(diethylamino)-2-oxo-2H-chromene-3-carbohydrazide with 4-tert-butyl-2,6- diformylphenol. Accordingly, the copper complex (compound 1-Cu²⁺) was prepared by mixing compound 1 with 2 equivalents copper ions. Compound 1 had strong fluorescence while compound 1-Cu²⁺ hardly possessed fluorescence owing to the quenching nature of paramagnetism Cu²⁺ to the fluorescence molecule excited state. However, the fluorescence intensity of compound 1-Cu²⁺ was increased dramatically after the addition of thiol-containing amino acids, but not the other non-sulfhydryl amino acids. UV-vis absorption and fluorescence spectra indicated that compound 1-Cu²⁺ had good selectivity and sensitivity for thiols such as glutathione in CH₃CN:H₂O (3:2, v/v) PBS solution. The fluorescence imaging experiments implied that compound 1-Cu²⁺ has potential application in thiol-containing amino acids detection in living cells.     

Fluorescent Protein-Based Optical Biosensor for Copper Ion Quantitation

In the present study, spectroscopic determinations of copper ions using chimeric metal-binding green fluorescent protein (His6GFP) as an active indicator have been explored. Supplementation of copper ions to the GFP solution led to a remarkable decrease of fluorescent intensity corresponding to metal concentrations. For circumstances, rapid declining of fluorescence up to 60% was detected in the presence of 500 μM copper. This is in contrast to those observed in the case of zinc and calcium ions, in which approximately 10–20% of fluorescence was affected. Recovery of its original fluorescence up to 80% was mediated by the addition of ethylenediamine tetraacetic acid. More importantly, in the presence of metal ions, the emission wavelength maximum remains unchanged while reduction of the optical density of the absorption spectrum has been observed. This indicates that the chromophore’s ground state was possibly affected by the static quenching process. Results from circular dichroism measurements revealed that the overall patterns of circular dichroism spectra after exposure to copper ions were not significantly different from that of the control, where the majority of sharp positive band around 195–196 nm in combination with a broad negative deflection around 215–216 nm was obtained. Taken together, it can be presumed that copper ions exerted their static quenching on the fluorescence rather than structural or conformational alteration. However, notification has to be made that some peptide rearrangements may also occur in the presence of metal ions. Further studies were conducted to investigate the feasibility of using the His6GFP as a sensing unit for copper ions. The His6GFP was encapsulated in Sol-gel and immobilized onto the optical fiber connected with a fluorescence detecting device. The Sol-gel was doped into the metal solution where the quenching of fluorescence could be monitored in real time. The sensing unit provided a high sensitivity of detection in the range of 0.5 μM to 50 mM with high selectivity for copper ions. All these findings open up a high potential to apply the fluorescent protein-based bioanalytical tool for copper determination in the future.     

Copper sensing based on the far-red fluorescent protein, HcRed, from Heteractis crispa

In this article, we report for the first time on the copper (Cu(2+)) binding characteristics of the far-red fluorescent protein, HcRed, and its application in the development of a reagentless sensing system for copper. The far-red emission of HcRed (lambda(max) = 645 nm) where background cellular fluorescence is low should prove to be advantageous in the development of the sensing system. In the studies performed in our laboratory, we found that the fluorescence of HcRed is quenched in the presence of copper ions (Cu(2+)). The results obtained through UV-visible and circular dichroism spectra generated in the presence and absence of copper, as well as Stern-Volmer plots at different temperatures, indicate static quenching of HcRed fluorescence in the presence of copper, possibly through the formation of a copper-protein complex. On the basis of this observation, we developed a reagentless sensing system for the detection of copper(II) based on HcRed as the biosensing element. A detection limit for Cu(2+) in the nanomolar range was obtained. HcRed was found to bind copper ions selectively when compared with other divalent ions. A dissociation constant of 3.6muM was observed for copper binding. Histidine and cysteine residues are commonly involved in copper binding within proteins; therefore, to investigate the role of these amino acids present in HcRed, we chemically modified Cys and His residues using iodoacetamide and diethyl pyrocarbonate, respectively. The effect of copper addition on the fluorescence of the chemically modified HcRed was investigated. The His modification of HcRed substantially affected copper ion binding, pointing to histidine as the possible amino acid residue involved in the binding of copper ions in HcRed. A purification strategy for HcRed was also developed based on a copper immobilized affinity column without the addition of any affinity tag on the protein. The HcRed-based copper sensing system can potentially be employed to perform intracellular copper detection by genetically encoding the biosensing element or can be employed in environmental sensing.     

DsRed as a highly sensitive, selective, and reversible fluorescence-based biosensor for both Cu(+) and Cu(2+) ions

The wild type form of Red fluorescent protein (DsRed), an intrinsically fluorescent protein found in tropical corals, is found to be highly selective, reversible and sensitive for both Cu(+) and Cu(2+), with a nanomolar detection limit. The selectivity towards these ions is retained even in the presence of other heavy metal ions. The K(d) values for monovalent and divalent copper, based on single binding isotherms, are 450 and 540 nM, respectively. The wild type DsRed sensitivity to Cu(2+) (below 1 ppb) is seven orders of magnitude better than that of the related wild type Green Fluorescent protein (GFP), and it is even 40 times more sensitive than engineered mutants of GFP. Potential binding sites have been proposed, based on amino acid sequences for copper binding and the distance from the chromophore, with the aid of computer modeling.     

Synthesis and application of a “turn on” fluorescent probe for glutathione based on a copper complex of coumarin hydrazide Schiff base derivative

Discrimination and quantification of intracellular biothiols, such as cysteine (Cys), homocysteine (Hcy), glutathione (GSH) under physiological conditions is significant for academic research and disease diagnosis. A new fluorescent probe (complex 1-Cu²⁺) for discriminate detection of GSH was prepared by copper ions coordinate with coumarin carbohydrazide Schiff base derivative 1. In suitable buffer solution (CH₃CN: HEPES = 3:2, v/v) and under appropriate pH condition (pH = 7.2–7.4), the UV–vis spectroscopy experiments showed that compound 1 and copper ion exhibited a 1:1 ratio binding mode and moderate binding ability. Fluorescence quenching of compound 1 was observed when it complexed with Cu²⁺ ions. An obviously fluorescence restoration appeared after addition of GSH to the solution of probe, which also exhibited a highly selectivity relative to cysteine (Cys) and homocysteine (Hcy) in the amino acid competitive experiments. The minimum detection limit was calculated to 0.12 μM by fluorescent method, which was distinctly below the physiological concentration of GSH in live cells. Its biological application to detect the endogenous GSH was further proved by the HepG2 cell fluorescence image test.     

5-(Pentafluorobenzoylamino)fluorescein: A selective substrate for the determination of glutathione concentration and glutathione S-transferase activity

5-(Pentafluorobenzoylamino)fluorescein (PFB-F), a new thiol-reactive molecule was synthesized to improve the detection limits and specificity of the assays for glutathione S-transferase (GST) activity and glutathione (GSH). A rapid assay method to measure GSH concentration or GST activity and the simultaneous analysis of multiple samples is possible because the glutathione adduct, GS-TFB-F, is separated from PFB-F by thin-layer chromatography (TLC) and can be quantitated by a fluorescence scanner. The detection limits for GSH and for GST activity using TLC were found to be as low as 10 pmol/microl and 1 ng/microl using equine liver GST, respectively. Determination of GSH concentration or GST activity in bovine pulmonary artery endothelial (BPAE) cell lysates gave a linear response for samples corresponding to 500-2500 cells. PFB-F could also measure GST activities of GST fusion proteins and prove to be a suitable substrate for determining the activities of human GST isozymes and other sources of mammalian GST. The selectivity of PFB-F with GSH was proven by comparing trace amount of the adducts that formed with cysteine and beta-galactosidase to that formed with GSH. The HPLC profile of a reaction mixture where cell lysate was used in place of purified GST, also shows only two main peaks, corresponding to GS-TFB-F and unreacted PFB-F. The selectivity of PFB-F for GSH was further confirmed by exposing BPAE cells to dl-buthionine-[S,R]-sulfoximine (BSO). Our results of GS-TFB-F determination indicate that 12-, 24-, or 36-h incubations with BSO caused 2-, 6-, or 7.6-fold reductions in GSH levels, respectively.     

一株产漆酶真菌新月弯孢霉JQH-100在染料脱色中的应用

从感染叶斑病的玉米叶片中分离、纯化得到一株高产漆酶的新月弯孢霉Curvularia lunata JQH-100菌株。液体培养Curvularia lunata JQH-100可产漆酶且活性较高,产酶高峰出现在第3天;以ABTS为底物粗酶液的最适反应温度是30℃,最适反应pH是2.8;染料脱色的研究表明,共培养体系对茜素红的脱色率达到了92.6%,对中性红和刚果红的脱色率也都在80%以上;Curvularia lunata JQH-100所产漆酶经纯化后对染料茜素红和刚果红有较高的脱色率,分别为82.1%和81.2%。研究结果显示Curvularia lunata JQH-100在染料废水处理中有较大应用潜力。     

A novel metallobridged bis(beta-cyclodextrin)s fluorescent probe for the determination of glutathione

A novel metallobridged bis(beta-cyclodextrin)s 2 [bis(beta-CD)s 2] was synthesized and characterized by means of (1)H NMR, IR, element analysis and redox iodometric titration. The fluorescence of metallobridged bis(beta-CD)s 2 was weak compared with bis(beta-CD)s 1 because of the paramagnetism of copper (II) ions. Glutathione was able to form complexes with copper (II) derived from the metallobridged bis(beta-CD)s 2. This competitive complexation with copper (II) may lead to a significant fluorescence recovery of the bis(beta-CD)s. Therefore, a rapid and simple spectrofluorimetric method was developed for the determination of glutathione. The analytical application for glutathione was investigated in NaCl/P(i) (pH 6.00) at room temperature. The linear range of the method was 0.30-20.0 micromol.L(-1) with a detection limit of 63.8 nmol.L(-1). There was no interference from the plasma constituents. The proposed method had been successfully used to determine glutathione in human plasma.     

An Amplex Red-based fluorometric and spectrophotometric assay for l-asparaginase using its natural substrate

We report on the development of a sensitive real-time assay for monitoring the activity of l-asparaginase that hydrolyzes l-asparagine to l-aspartate and ammonia. In this method, l-aspartate is oxidized by l-aspartate oxidase to iminoaspartate and hydrogen peroxide (H₂O₂), and in the detection step horseradish peroxidase uses H₂O₂ to convert the colorless, nonfluorescent reagent Amplex Red to the red-colored and highly fluorescent product resorufin. The assay was validated in both the absorbance and the fluorescence modes. We show that, due to its high sensitivity and substrate selectivity, this assay can be used to measure enzymatic activity in human serum containing l-asparaginase.     

DNAzyme self-assembled gold nanoparticles for determination of metal ions using fluorescence anisotropy assay

Gold nanoparticles can be exploited to facilitate a highly sensitive and selective metal ion detection based on fluorescence anisotropy assay with metal ion-dependent DNA-cleaving DNAzyme. This assay allows rapid and accurate determination of metal ions in aqueous medium at room temperature. The method has been demonstrated for determination of Cu²⁺ and Pb²⁺ ions. The detection sensitivity can be significantly improved to 1 nM by using a “nanoparticle enhancement” approach. Moreover, the assay was also tested in 384-well plates for high-throughput routine determination of toxic metal ions in environmental samples. The method showed distinct advantages over conventional methods in terms of its potential sensitivity, specificity, and ability for rapid response.     

Oligonucleotide-based fluorogenic sensor for simultaneous detection of heavy metal ions

In this study, we report a new fluorogenic sensor based on fluorescence resonance energy transfer (FRET) for detection of heavy metal ions in aqueous solution. The method showed the advantage of being simple, highly sensitive and selective, and rapid. The donor (CdTe QDs) and acceptor (TAMRA or Cy5) are brought into close proximity to one another due to Hg(2+) and Ag(+) form strong and stable T-Hg(2+)-T complexes and C-Ag(+)-C complexes, which quenches the fluorescent intensity of CdTe QDs and enables the energy transfer from donor to acceptor. This sensor showed high sensitivity and selectivity when only one kind of ion (Ag(+) or Hg(2+)) exists. Furthermore, the assay can also simultaneously detect Ag(+) and Hg(2+) in water media with the limit of detection (LOD) of 2.5 and 1.8 nM, separately, which satisfactorily meets the sensitivity demands of Environmental Protection Agency (EPA) and World Health Organization (WHO). This assay also exhibits excellent selectivity toward Ag(+) and Hg(2+). Therefore, this method is of great practical and theoretical importance for detecting heavy metal ions in aqueous solution.     

Highly sensitive and selective detection of thiol-containing biomolecules using DNA-templated silver deposition

In this work, we report a new fluorescent method for the label-free assay of thiol-containing amino acids and peptide by use of silver deposited DNA duplex and the intercalating dye. The sensing approach is based on the specific interactions between thiols and DNA-templated silver deposition via robust Ag-S bonds. In the presence of thiols, the intercalating dye gives a dramatic increase in fluorescence as a result of the strong interaction between the intercalator and the released DNA from silver surfaces. The detection limit of this method is lower than or at least comparable to previous fluorescence-based methods, and the turn-on sensing mode offers additional advantage to efficiently reduce background noise. Moreover, the detection and discrimination process can be observed by the naked eye with the aid of an UV transilluminator. This method also exhibits excellent selectivity for these thiol-containing biomolecules over various other amino acids. As far as we know, our method is the first example using the specific interaction between thiols and silver-coated DNA to fabricate a turn-on fluorescent sensor for biological thiols with high sensitivity and selectivity.     

Expression and purification recombinant human dentin sialoprotein in Escherichia coli and its effects on human dental pulp cells

Dentin sialoprotein (DSP) is cleaved from dentin sialophosphoprotein (DSPP) and most abundant dentinal non-collagenous proteins in dentin. DSP is believed to participate in differentiation and mineralization of cells. In this study, we first constructed recombinant human DSP (rhDSP) in Escherichia coli (E. coli) and investigated its odontoblastic differentiation effects on human dental pulp cells (hDPCs). Cell adhesion activity was measured by crystal violet assay and cell proliferation activity was measured by MTT assay. To assess mineralization activity of rhDSP, Alizarin Red S staining was performed. In addition, the mRNA levels of collagen type ? (Col ?), alkaline phosphatase (ALP), and osteocalcin (OCN) were measured due to their use as mineralization markers for odontoblast-/osteoblast-like differentiation of hDPCs. The obtained rhDSP in E. coli was approximately identified by SDS-PAGE and Western blot. Initially, rhDSP significantly enhanced hDPCs adhesion activity and proliferation (p<0.05). In Alizarin Red S staining, stained hDPCs increased in a time-dependent manner. This odontoblastic differentiation activity was also verified through mRNA levels of odontoblast-related markers. Here, we first demonstrated that rhDSP may be an important regulatory ECM in determining the hDPCs fate including cell adhesion, proliferation, and odontoblastic differentiation activity. These findings indicate that rhDSP can induce growth and differentiation on hDPCs, leading to improve tooth repair and regeneration.     

Kinetic assay of fluorescein mono-beta-D-galactoside hydrolysis by beta-galactosidase: a front-face measurement for strongly absorbing fluorogenic substrates

A novel enzymatic assay method was developed for fluorogenic substrates that have significant intrinsic absorbance and fluorescence under the assay conditions. Fluorescein mono-beta-D-galactoside (FMG) was chosen as the substrate for the fluorescence enzymatic assay because of the high fluorescence of its hydrolytic product (fluorescein) and suitability of being hydrolyzed by beta-galactosidase. The fluorescence-concentration relationships for fluorescein and for FMG in both the right-angle detection mode of a fluorometer and the front-face detection mode of a fluorescence plate reader were exactly established and used to determine the kinetics of the enzyme assay. The results show that only front-face detection in the fluorescence plate reader can overcome the fluorescence concentration quenching that inevitably results from high absorbance by the intrinsically absorbing substrate in the conventional fluorometer, which utilizes right-angle detection. Only with front-face detection was the fluorescent assay of FMG hydrolysis under conditions of high optical density possible. The enzymatic measurements on the fluorescence plate reader were particularly efficient for determination of the enzyme kinetics because of the high rate of data collection. In this assay system, Michaelis-Menten constant Km and enzymatic catalysis rate k2 of FMG were determined as 117.6 microM and 22.7 mumol-(min.mg)-1, respectively. The results and methods described in this paper can be generalized for any assay using a fluorogenic substrate whether or not it has a high background absorbance.     

Sensitivity limits of biosensors used for the detection of metals in drinking water

Even when present in very low concentrations, certain metal ions can have significant health impacts depending on their concentration when present in drinking water. In an effort to detect and identify trace amounts of such metals, environmental monitoring has created a demand for new and improved methods that have ever-increasing sensitivities and selectivity. This paper reviews the sensitivities of over 100 recently published biosensors using various analytical techniques such as fluorescence, voltammetry, inductively coupled plasma techniques, spectrophotometry and visual colorimetric detection that display selectivity for copper, cadmium, lead, mercury and/or aluminium in aqueous solutions.     

Metal-binding stoichiometry and selectivity of the copper chaperone CopZ from Enterococcus hirae.

We studied the interaction of several metal ions with the copper chaperone from Enterococcus hirae (EhCopZ). We show that the stoichiometry of the protein-metal complex varies with the experimental conditions used. At high concentration of the protein in a noncoordinating buffer, a dimer, (EhCopZ)2-metal, was formed. The presence of a potentially coordinating molecule L in the solution leads to the formation of a monomeric ternary complex, EhCopZ-Cu-L, where L can be a buffer or a coordinating molecule (glutathione, tris(2-carboxyethyl)phosphine). This was demonstrated in the presence of glutathione by electrospray ionization MS. The presence of a tyrosine close to the metal-binding site allowed us to follow the binding of cadmium to EhCopZ by fluorescence spectroscopy and to determine the corresponding dissociation constant (Kd = 30 nm). Competition experiments were performed with mercury, copper and cobalt, and the corresponding dissociation constants were calculated. A high preference for copper was found, with an upper limit for the dissociation constant of 10-12 m. These results confirm the capacity of EhCopZ to bind copper at very low concentrations in living cells and may provide new clues in the determination of the mechanism of the uptake and transport of copper by the chaperone EhCopZ.     

The inhibition of fluorescence resonance energy transfer between quantum dots for glucose assay

Fluorescence resonance energy transfer (FRET) between two quantum dots of different sizes causes fluorescence quenching. Hereby a binding site pre-blocking approach is proposed to avoid this effect. Pre-binding of glucose on the donor occupies the binding sites and thus blocks resonance energy transfer between the two quantum dots, protecting the fluorescence from being quenched. A glucose assay is developed based on this approach. The glucose content is correlated with the fluorescence difference in the absence and in the presence of glucose. In practice, Green QDs-Con A conjugates are used as donors and Red QDs-NH(2)-glu conjugates as acceptors to form FRET system. The inhibition of fluorescence quenching is then measured in the presence of glucose. A linear calibration graph is achieved within 0.1-2.0 mmolL(-1), along with a detection limit of 0.03 mmolL(-1) and a RSD of 2.1% (1.0 mmolL(-1)). 91-105% of glucose in serum and urine samples is recovered. It is worth mentioning that the present glucose assay approach also generates a fluorescence chromatic difference imaging, and the color display clearly identifies the glucose contents by visual detection with a distinguishing ability of ca. 0.5 mmolL(-1). The present approach can potentially be used for the clinical determination of glucose in biological samples which can be further developed into a glucose sensor.     

基于钙黄绿素的荧光分光光度法测定谷胱甘肽

目的：基于钙黄绿素的荧光分光光度法建立一种测定谷胱甘肽的新方法。方法：在pH=8.0介质中,铜（Ⅱ）与钙黄绿素配位引起荧光猝灭,由于谷胱甘肽与铜（Ⅱ）的亲和力很强,可从钙黄绿素-铜离子的络合物中夺取铜离子而使钙黄绿素游离出来使荧光强度得以恢复,荧光恢复的程度与加入谷胱甘肽的浓度在一定浓度范围内成线性。结果：据此建立了一种测定谷胱甘肽的新方法,该方法的线性范围为2.0×10-6～1.4×10-5mol.L-1,F=8.1964C＋196.43,检测限为1.0×10-6mol/L。结论：用此法测定谷胱甘肽简便快速,灵敏度高。     

Caspase-1抑制剂对大鼠血管平滑肌细胞钙化的初步影响

目的:研究Caspase-1抑制剂zVAD对大鼠血管平滑肌细胞钙化的影响。方法:体外分离、培养大鼠血管平滑肌细胞,加入β-磷酸甘油酯(β-GP)诱导细胞发生钙化;在细胞中加入Caspase-1抑制剂zVAD或DMSO对照,按照不同时间点收取细胞进行半定量PCR,检测骨保护素(OPG)/核因子κB受体活化因子配体(RANKL)的表达变化;通过茜素红钙化染色,直观观察zVAD对血管平滑肌细胞钙化的影响。结果:β-GP加入细胞后,可见细胞内OPG/RANKL的mRNA表达水平逐步增加,加入zVAD后增加趋势减缓;茜素红钙化染色显示,zVAD可抑制血管平滑肌细胞钙化。结论:分离、体外培养了大鼠的血管平滑肌细胞,并且发现在钙化过程中OPG/RANKL表达增加,而Caspase-1抑制剂zVAD可有效抑制OPG/RANKL的表达,提示炎症小体可能通过OPG/RANKL诱导动脉钙化的产生。     

Real-Time Vital Mineralization Detection and Quantification during In Vitro Osteoblast Differentiation

Background

In vitro studies of osteoblasts traditionally use Alizarin Red as a golden standard for the detection and quantification of mineralization, which is a marker of osteoblast differentiation. However, this method presents a number of drawbacks, including the need to fix cells, which prevents additional measurements. Years ago, Calcein Green was proposed as an alternative to Alizarin Red, with the advantage to be directly detectable in live cells. However, the protocol was still time-consuming, and it never managed to replace Alizarin Red. Now, with more efficient imaging systems, we present a protocol using Calcein Green which provides significant advantages.

Results

The osteoblast mineralization was efficiently detected and accurately quantified in real time at any desired time point across the entire differentiation period, with a minimum time expenditure.

Conclusions

The combination of Calcein Green and the real-time imaging station IncuCyte ZOOM can efficiently replace the Alizarin Red method, and allows very accurate and time-saving assessment of the level and the dynamics of matrix mineralization.