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Selective and sensitive detection of acetylcholinesterase activity using denatured proteinprotected gold nanoclusters as a label-free probe†

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Hongchang Li,‡ Yuxin Guo,‡ Lehui Xiao* and Bo Chen* Based on the fluorescence quenching of novel denatured protein-protected gold nanoclusters, a label-free detection method of acetylcholinesterase (AChE) activity has been developed. Using denatured bovine serum albumin (dBSA), in which 35 cysteine residues can interact polyvalently with Au nanoclusters (AuNCs) as a stabilizing agent, water-soluble and stable fluorescent gold nanoclusters were synthesized. The fluorescence of the AuNCs was quenched by thiocholine that was produced from the AChE

Received 11th September 2013 Accepted 17th October 2013

hydrolysis of S-acetylthiocholine iodide (ACTI) to detect the AChE activity. The linear range of the

DOI: 10.1039/c3an01736b

metal ions, i.e., GPT, g-GT, GOx, K+, Ca2+ and Na+, showed minimal interference. Using the fluorescence

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probe, satisfactory results for the detection of the AChE activity in human serum were obtained.

method was 0.005–0.15 U mL
1. The limit of detection (LOD) was 0.02 mU mL
1. Other enzymes and

1. Introduction Acetylcholinesterase (AChE: E.C.3.1.1.7) catalyzes the hydrolysis of acetylcholine (ACh), a neurotransmitter substance which functions in certain parts of the nervous system. ACh plays an important role in the physiological activity.1,2 A low level of acetylcholine is highly associated with Alzheimer’s disease (AD), since the hydrolysis of acetylcholine catalyzed by acetylcholinesterase (AChE) can promote the aggregation of amyloid-bpeptide which plays a crucial role in the development of AD.3 In other words, AChE shows a close relationship with cholinergic dysfunction, as well as Parkinson’s and Alzheimer’s diseases.1 Based on the above situations, it is essential for real-time monitoring of the level of activity of AChE to guide the AD therapies.4 A number of traditional methods, e.g., colorimetric Ellmann method, and detection of hydrogen peroxide produced by oxidation of choline, have been employed for the quantitative and qualitative determination of AChE acitivity.5–8 However, low sensitivity, false-positive effects, and the techniques containing multi-steps organic reactions have limited the application of these methods. To improve the performance of the AChE activity determination method, some novel materials have been applied.4,9 Nevertheless, these methods also demand labeling and multi-step operation which are both labor-intensive and time-consuming. Key Laboratory of Chemical Biology & Traditional Chinese Medicine Research, Ministry of Education, Hunan Normal University, Changsha 410081, China. E-mail: [email protected]; [email protected] † Electronic supplementary 10.1039/c3an01736b

information

(ESI)

‡ Contributed equally to this work.

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available.

See

DOI:

Noble metal nanoclusters (NCs) typically consist of a few to several hundred metal atoms and their sizes are smaller than 2 nm. Compared to semiconductor quantum dots (QDs) and organic dyes, NCs are of special interest as their ultrane size, non-toxicity, high uorescence and good biocompatibility mean that they have been used in biological detections, e.g., bioimaging, biosensing, specic protein detection etc.10–14 For the determination of AChE activity, several highly sensitive NCs methods, e.g., uorometric assay based on DNA-templated copper/silver nanoclusters15 and DNA-templated silver nanoclusters for uorescence turn-on assay,16 in addition to continuous colorimetric assay with gold nanoparticles, have been proposed.4 Among noble metal NCs, Au clusters have been extensively studied because of their intrinsic characteristics such as ease of preparation and chemical stability.17 The synthesis of metal nanoclusters including AuNCs can be divided into two categories: the template-based synthesis such as using poly(amidoamine) dendrimers and DNA as a sizeconning template, and monolayer-protected nanocluster synthesis such as protection by glutathione, tiopronin, meso-2,3-dimercaptosuccunic acid, phenylethylthiolate, dodecanethiol, and mercaptoundecanol.18 Compared with templatebased synthesis NCs, monolayer-protected nanoclusters contain large Stokes’s shis, and even tunable uorescence via the selection of appropriate length thiolated ligands.19 In 2009, a simple and green synthetic method of using native bovine serum albumin (BSA) as a stabilizing agent and a reductant to prepare AuNCs was proposed. The BSA-protected AuNCs exhibit photo-stable, non-toxic, and biocompatible features.20 Besides BSA, other proteins, e.g., trypsin, transferrin, insulin, ovalbumin, and papain, have also been used to prepare NCs.21–25

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However, there are 34 cysteine residues in the formation of disulde bonds and only 1 free cysteine in BSA. If the 35 cysteine residues could be completely liberated, they could act as polyvalent ligands for passivating the surface of metallic materials.26 Inspired by this thinking, denatured BSA (dBSA)protected Ag NCs have been synthesized.17 The dBSA-protected Ag NCs exhibit higher stability vs. BSA-protected Ag NCs. Here we synthesized water-soluble, uorescent dBSA-protected AuNCs and used the AuNCs as a label-free uorescent sensor for the sensitive and selective detection of AChE activity in human serum (Fig. 1 and Fig. 2). S-Acetylthiocholine iodide (ACTI) was used as the substrate. AChE hydrolyzed ACTI to give thiocholine whose sulydryl group can combine with the dBSA–AuNCs leading to uorescence quenching of the NCs. The method is label-free, selective and sensitive.

2.

Experimental

2.1

Materials and reagents

Lyophilized bovine serum albumin (BSA), N-ethylmaleimide (NEM) acetylcholinesterase (AChE), and S-acetylthiocholine iodide (ACTI) were purchased from Sigma-Aldrich Chemical Co. (St. Louis, MO, USA). Sodium borohydride (NaBH4), tetrachloroauric acid tetrahydrate (HAuCl4$4H2O), and sodium hydroxide (NaOH) were purchased from Sinopharm Chemical Reagent Co., Ltd. (Beijing, China). Water (>18.2 MU) used for the experiments was puried using a Milli-Q System. Human serum samples derived from volunteers in Hunan normal university (all experiments were performed in compliance with the relevant laws and institutional guidelines). 2.2

Apparatus

Fluorescence emission spectra were recorded using an F-4500 uorescence spectrometer (Hitachi, Japan). Absorption spectra were recorded using a UV 2450 UV-Vis spectrophotometer (Shimadzu, Japan). UV light excitation was at 365 nm. The morphology of the AuNCs was obtained by TEM.

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Fluorescence quenching of dBSA–AuNCs with different substrates: dBSA–AuNCs only (black), dBSA–AuNCs with 3 mM ACTI (red), dBSA–AuNCs with 0.4 U mL
1 AChE (green), dBSA–AuNCs with both 3 mM ACTI and 0.4 U mL
1 AChE (blue). Fig. 2

2.3

Preparation of dBSA-templated gold nanoclusters

The dBSA was prepared according to the literature reports.27,28 The steps were as follows: 1 g of BSA was dissolved in 25 mL of deionized water, then 30 mg of sodium borohydride was added under stirring, the reaction was kept at room temperature for 1 h, and was then maintained at 70  C until no more gas (H2) was generated. Whereaer, 9 mL of 24.3 mM HAuCl4 was added under stirring, and 2 min later, 4 mL of 1 M NaOH was added. The reaction was kept for 12 h at room temperature. Aer completing the reaction, the solution was separated by dialysis to remove the residual ions (i.e., Na+, Au3+, and OH
). The color of the solution changed from light yellow to deep brown. Finally, the solution was diluted with deionized water to 100 mL. 2.4 The linear curves of the uorescence intensity of dBSA– AuNCs vs. the enzyme activity of AChE The reaction solution contained 100 mL of diluted AuNCs and 100 mL of 3 mM ACTI, and was kept at 37  C in a water bath for 10 min; then, 20 mL of various concentrations AChE were added to the reaction solution at 37  C and reacting for 30 min. The change of uorescence intensity of the solution was recorded using the F-4500 spectrometer. 2.5 The specicity of AChE detection by dBSA-protected gold nanoclusters

Fig. 1 Schematic of the dBSA-directed synthesis of fluorescent Au clusters and the detection of AChE activity.

286 | Analyst, 2014, 139, 285–289

The reaction solution contained 100 mL of diluted AuNCs and 100 mL of 3 mM ACTI, and was kept at 37  C in a water bath for 10 min; then, 20 mL of different enzymes, thiol-containing compounds and metal ions (AChE, GPT (glutamic-pyruvic transaminase), g-GT (g-glutamyltransferase), GOx, L-cysteine, homocysteine, GSH (glutathione), K+, Ca2+, and Na+) were added to the reaction solution at 37  C and allowed to react for 30 min. The change of uorescence intensity of reaction solution was recorded using the F-4500 spectrometer.

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2.6

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Detection of AChE activity in serum

The reaction solution contained 100 mL of diluted AuNCs and 100 mL of 3 mM ACTI, it was kept at 37  C in a water bath for 10 min, and then 20 mL of human serum in 0.1 M PBS buffer (pH ¼ 8.0) was added, and the reaction was kept at 37  C for 30 min. The change of the uorescence intensity reaction solution was recorded using the F-4500 spectrometer.

3.

Results and discussion

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3.1 Preparation and characterization of dBSA-coated gold nanoclusters BSA has been widely used in the synthesis of gold nanoclusters. It consists of 35 thiol groups including 17 disulde bonds and 1 free group. Aer reduction, 35 thiol groups could be free, which then could act as chelating groups for entrapping metal ions (e.g., Au3+) and as polyvalent groups for covalence-crosslinking with metallic nanomaterials (e.g., Au clusters). In this work, the denatured BSA was prepared by reducing the native BSA with sodium borohydride; then, the Tyr residues with phenolic groups in the BSA would reduce Au3+ to luminescent AuNCs at physiological temperature.29 The insert in Fig. 3 shows that the formed AuNC solutions were deep brown in color under visible light (le), whereas they emitted red uorescence under UV light with 365 nm (right). Fluorescent AuNCs with red or nearinfrared emissions that offered improved tissue penetration depth and reduced background uorescence would be effective for cellular biosensing and bioimaging in further work. From the optical absorption and photoemission spectra of these asprepared AuNCs (Fig. 3), it could be concluded that no apparent surface plasmon resonance absorption peak in the range between 400 and 600 nm could be observed to indicate the existence of small Au nanoparticles. While the emission band of dBSA-capped AuNCs was 640 nm with excitation at 520 nm, the uorescence quantum yield of the Au clusters was 6.5%, calculated with Rhodamine B as a reference according to the

UV-Vis absorption (black line), fluorescence emission (red line) spectra of the as-prepared AuNCs. The excitation wavelength was 520 nm. Insert: the photographs of the aqueous solution of AuNCs under visible (left) and UV light (right) with excitation at 365 nm.

Fig. 3

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method of Williams et al.30 To further conrm the formation of the dBSA-coated AuNCs, transmission electron microscopic images were obtained. As shown in Fig. S1,† the as-prepared uorescent AuNCs were mostly spherical dots with high monodispersity. The size is uniform, averaging about 1.5 nm in diameter. For application in biosensing and bioimaging, one of the primary requirements of NCs is water-solubility and stability under high ionic strength environments. Whereas proteinstabilized uorescent metal clusters are sufficiently watersoluble, their stability in high ionic strength environments is still a challenge. The normalized uorescent spectra of the dBSA-coated Au clusters in the absence and presence of various ionic strengths of PBS buffer are shown in Fig. S2D,† showing that the photoluminescence intensity was hardly changed. Under further investigation, such as variation of temperature, storage time, as well as pH, the PL intensity was not obviously changed (Fig. S2A–C†). The stability of the dBSA–AuNCs was enhanced by the polyvalent interactions between the ligand and the metal core.

3.2

Sensitivity of sensor

Under the optimum conditions (Fig. S3†), we used the uorescent materials to detect the enzyme activity of AChE, which would catalyze the hydrolysis of ACTI and then produce thiocholine that could quench the uorescence of AuNCs (Fig. 1 and 2). With the increase in enzyme activity of the AChE, the uorescence of the AuNCs could decrease. As depicted in Fig. S4† and Fig. 4, the linear range of the sensor was 0.005–0.15 U mL
1 and the corresponding linear function was y ¼
2.9231x + 0.5729 with a correlation coefficient of R2 ¼ 0.9276. The limit of detection (LOD) was 0.02 mU mL
1 (S/N ¼ 3), which was lower than that of previous methods, and detailed comparison is shown in Table S1.† However, with higher

Fig. 4 The fluorescence intensity of dBSA–AuNCs in the presence of

various enzyme activities (0–2.0 U mL
1). Inset: the linear relationship of the quenching efficiency of dBSA–AuNCs vs. the enzyme activity of AChE (0.005–0.15 U mL
1). The error bars represent the standard deviation of three independent measurements.

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enzyme activity, the quenching curve tended towards being attened. This tendency is consistent with the kinetics of enzyme-catalyzed reactions.31,32

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3.3

Specicity of sensor

To evaluate the novel uorescence sensor for the detection of AChE activity, a series of relevant enzymes, thiol-containing compounds and metal ions (AChE, GPT, g-GT, GOx; L-cysteine, homocysteine, GSH; K+, Ca2+, and Na+) were studied as a control. As demonstrated in Fig. 5 (black bars), except for GPT, g-GT, GOx, K+, Ca2+, and Na+, obvious uorescence quenching was obtained with different sensitivity toward AChE and thiolcontaining compounds. AChE was the most efficient in quenching the uorescence intensity of the dBSA–Au clusters. However, in order to improve the accuracy of the uorescent probe, interferences of thiol-containing compounds could be eliminated by using thiol-blocking reagents, such as N-ethylmaleimide (NEM). As shown in Fig. 5 (gray bars), thiol-containing compounds showed minimal interference by using NEM compared to the control without NEM. In brief, the uorescence probe could be used for the selective and sensitive detection of AChE activity. 3.4

Detection of AChE activity in human serum

The selective and sensitive sensor could be directly applied for detecting AChE activity in real samples. We further investigated the practicality of the development of the label-free sensor by detecting AChE activity in human serum samples. The enzyme activity of AChE in human serum samples detected by dBSA– AuNCs is shown in the Fig. 6. The results showed almost no

Fig. 6 Quenched fluorescence intensity of the dBSA–AuNCs by dilute human serum samples before (black bars) and after (gray bars) pretreatment with NEM. All measurement were performed in 100 mM PBS, pH ¼ 8.0, thermostatted at 37  C for 30 min. The error bars represent the standard deviation of three independent measurements.

difference between the quenched uorescence intensity induced by the diluted serum samples with and without NEM, which indicated that any thiols in the diluted serum samples did not affect the detection of AChE activity. Therefore, no sample pretreatment of human serum was used except for appropriate dilution. So the specicity of the developed biosensor might be a most possible candidate to detect the enzyme activity of AChE in human serum without any pretreatment.

4. Conclusion

Fluorescence responses of dBSA–AuNCs to different enzymes, thiol-containing compounds and ions. AChE, GPT, g-GT, and GOx were 0.4 U mL
1; L-cysteine, homocysteine, GSH, K+, Ca2+, and Na+ were 10 nM. The gray bars and black bars represent the control samples with and without NEM, respectively. All measurements were performed in PBS, pH ¼ 8.0, thermostatted at 37  C for 30 min. I0 and I are the PL intensities of the dBSA–AuNCs in the absence and presence of analytes, respectively. Fig. 5

288 | Analyst, 2014, 139, 285–289

In summary, we reported a simple, ‘green’ synthetic route to prepare dBSA-protected AuNCs. The as-prepared AuNCs were satisfactorily water-soluble and stable under high ionic strength environments. The dBSA with its 35 cysteine residues could act as a polyvalent ligand to stabilize the metal core and lead to the formation of stable AuNCs in aqueous solutions. The dBSAcoated Au clusters were further used as a label-free sensor for the sensitive and selective detection of AChE activity in human serum. The strategy could be described as their uorescence being quenched by thiocholine that was produced from the acetylcholinesterase (AChE) hydrolysis of S-acetylthiocholine iodide (ACTI). Importantly, the method was simple to apply because it did not require complicated modications and expensive instrumentation. Moreover, the as-prepared uorescent AuNCs with red emission could improve the tissue penetration depth and reduce background uorescence, which presage more opportunities for the study of biological systems in future applications.

Acknowledgements This work was nancially supported by the National Natural Science Foundation of China (21205037, 21275049, 21275052),

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the aid program for S&T innovation research team in higher education institutions and the construct program of the key disciplines of Hunan province. Project supported by the foundation for innovative research groups of the Hunan Natural Science Foundation of China.

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