A Phenothiazine-HPQ Based Fluorescent Probe with a Large Stokes Shift for Sensing Biothiols in Living Systems

Due to the redox properties closely related to numerous physiological and pathological processes, biothiols, including cysteine (Cys), homocysteine (Hcy) and glutathione (GSH), have received considerable attention in biological science. On account of the important physiological roles of these biothiols, it is of profound significance to develop sensitive and selective detection of biothiols to understand their biological profiles. In this work, we reported an efficient fluorescent probe, PHPQ-SH, for detecting biothiols in vitro and vivo, based on the phenothiazine-HPQ skeleton, with DNBS (2,4-dinitrobenzenesulfonate) as the response unit. Probe PHPQ-SH exhibited brilliant sensing performances toward thiols, including a large Stokes shift (138 nm), excellent sensitivity (for GSH, LOD = 18.3 nM), remarkable fluorescence enhancement (163-fold), low cytotoxicity, rapid response (8 min), and extraordinary selectivity. Finally, the probe PHPQ-SH illustrated herein was capable of responding and visualizing biothiols in MCF-7 cells and zebrafish.


Introduction
Biothiols including cysteine (Cys), homocysteine (Hcy), and glutathione (GSH) are vital members of amino acids, which have received considerable attention in biological science because of the redox properties closely related to numerous physiological and pathological processes [1][2][3]. For instance, cysteine (Cys), as a precursor of acetyl CoA and taurine, plays important functions in protein functionality and metabolism. Aberrant levels of Cys are correlated with poor growth, muscle and fat loss, skin lesions and lethargy [4,5]. Glutathione (GSH), as the most abundant endogenous biothiol, is essential for maintaining biological redox homeostasis by scavenging free radicals and peroxides. Data studies showed that many clinical diseases, such as human immunodeficiency disease (HIV), liver damage, leukopenia, and some cancers are directly associated with irregular levels of GSH [6][7][8]. Homocysteine (Hcy) is an important influencing factor of cardiovascular and Alzheimer's disease. In addition, elevated levels of Hcy in plasma will lead to folate and vitamin B 12 deficiency, nervous system defects, and osteoporosis [9][10][11]. On account of the important physiological roles of these biothiols, it is of profound significance to develop sensitive and selective detection methods for biothiols to understand their biological profiles.
In recent years, several detection techniques have been exploited for the detection of biothiols, such as high-performance liquid chromatography (HPLC), chemiluminescence method, colorimetric assays, electrochemical analysis and fluorescent detection [12][13][14][15][16]. Among them, fluorescence detection approaches, owing to their advantages of excellent sensitivity, low cost, high spatiotemporal resolution, ease of observation and noninvasive detection, have attracted interest in biological imaging analysis, clinical disease diagnosis, food detection, and environmental detection [17][18][19][20]. At present, a number of fluorescent

Spectral Response of Probe PHPQ-SH towards Biothiols
First, we investigated the sensing properties of PHPQ-SH toward thiols in a PBS/CH3CN solution (v/v = 1/1, pH 7.4). As seen in Figure 3, the free PHPQ-SH (10.0 µM) displayed an extremely weak fluorescence (Φ = 0.01). After adding GSH (0.0-100.0 µM), a green-colored fluorescence emission peak at 535 nm gradually increased. About a 163fold enhancement in the emission intensity was obtained in the presence of 10.0 equiv. of GSH. Notably, the Stokes shift for PHPQ-SH (10.0 µM) in response to GSH (100.0 µM) Scheme 2. The mechanism of PHPQ-SH towards biothiols.

Spectral Response of Probe PHPQ-SH towards Biothiols
First, we investigated the sensing properties of PHPQ-SH toward thiols in a PBS/CH 3 CN solution (v/v = 1/1, pH 7.4). As seen in Figure 3, the free PHPQ-SH (10.0 µM) displayed an extremely weak fluorescence (Φ = 0.01). After adding GSH (0.0-100.0 µM), a green-colored fluorescence emission peak at 535 nm gradually increased. About a 163-fold enhancement in the emission intensity was obtained in the presence of 10.0 equiv. of GSH. Notably, the Stokes shift for PHPQ-SH (10.0 µM) in response to GSH (100.0 µM) was as high as 138 nm, which was positive for bioimaging in living systems. The large fluorescence changes in spectral properties in PHPQ-SH solution after the addition of GSH indicated that PHPQ (Φ = 0.22) was produced. The strategy in this work was also verified by the HRMS spectra ( Figure S13). The mixture of PHPQ-SH with GSH (m/z = 416.1421) and PHPQ (cal. 416.1433) nearly had a same molecular weight. The excellent linear response in Figure 4 indicated that the emission intensity at 535 nm increased linearly with the concentration of GSH (y = 1.138 + 6.572x, R 2 = 0.9917), increasing from 0.0 to 7.0 µM (for Cys, y = 3.721 + 7.334x, R 2 = 0.9900) (for Hcy, y = −0.195 + 4.739x, R 2 = 0.9931) (Figures S1-S4). The detection limit of probe PHPQ-SH for GSH was further calculated to be 18.3 nM (for Cys, LOD = 20.1 nM) (for Hcy, LOD = 20.6 nM), based on the LOD = 3 σ/s. Probe PHPQ-SH demonstrated high sensitivity for the identification of biothiols, with a large Stokes shift in a turn-on mode. Scheme 2. The mechanism of PHPQ-SH towards biothiols.

Spectral Response of Probe PHPQ-SH towards Biothiols
First, we investigated the sensing properties of PHPQ-SH toward thiols in a PBS/CH3CN solution (v/v = 1/1, pH 7.4). As seen in Figure 3, the free PHPQ-SH (10.0 µM) displayed an extremely weak fluorescence (Φ = 0.01). After adding GSH (0.0-100.0 µM), a green-colored fluorescence emission peak at 535 nm gradually increased. About a 163fold enhancement in the emission intensity was obtained in the presence of 10.0 equiv. of GSH. Notably, the Stokes shift for PHPQ-SH (10.0 µM) in response to GSH (100.0 µM) was as high as 138 nm, which was positive for bioimaging in living systems. The large fluorescence changes in spectral properties in PHPQ-SH solution after the addition of GSH indicated that PHPQ (Φ = 0.22) was produced. The strategy in this work was also verified by the HRMS spectra ( Figure S13). The mixture of PHPQ-SH with GSH (m/z = 416.1421) and PHPQ (cal. 416.1433) nearly had a same molecular weight. The excellent linear response in Figure 4 indicated that the emission intensity at 535 nm increased linearly with the concentration of GSH (y = 1.138 + 6.572x, R 2 = 0.9917), increasing from 0.0 to 7.0 µM (for Cys, y = 3.721 + 7.334x, R 2 = 0.9900) (for Hcy, y = −0.195 + 4.739x, R 2 = 0.9931) (Figures S1-S4). The detection limit of probe PHPQ-SH for GSH was further calculated to be 18.

Selectivity and Interference Studies of PHPQ-SH
To evaluate the availability of a fluorescent probe selective towards biothiols, the reactivity of PHPQ-SH towards various amino acids was studied. As displayed in Figure 5, upon the addition of representative amino acids (including Ala, Arg, Glu, Asp, Ser, Lys,

Selectivity and Interference Studies of PHPQ-SH
To evaluate the availability of a fluorescent probe selective towards biothiols, the reactivity of PHPQ-SH towards various amino acids was studied. As displayed in Figure 5, upon the addition of representative amino acids (including Ala, Arg, Glu, Asp, Ser, Lys, Thr, Val, Tyr, Pro, Trp, Leu, Phe, Gly, Ile, Met, His, Gln, Asn), the fluorescence intensities of the testing solution (100.0 µM) were barely varied compared with that of the initial probe PHPQ-SH (10.0 µM). On the contrary, a prominent enhancement of the fluorescence intensity was only triggered in the case of biothiols (GSH, Cys, Hcy). Furthermore, the performance of PHPQ-SH (10.0 µM) for recognizing GSH in the presence of (100.0 µM) competitive amino acids (Ala, Arg, Glu, Asp, Ser, Lys, Thr, Val, Tyr, Pro, Trp, Leu, Phe, Gly, Ile, Met, His, Gln, Asn, GSH) was investigated ( Figure 6). As expected, no significant interference of PHPQ-SH in the detection of GSH with other coexisted amino acids was observed. As shown in Figure S5, the presence of relevant ions (100.0 µM for Cl − , NO 3 − , SO 4 2− , PO 3 4− , Ca 2+ , Cu 2+ , Na + ) also caused no effect on the fluorescence intensity of PHPQ-SH. The result indicated that PHPQ-SH can be served as a specific indicator for biothiols rather than other amino acids.

Effects of Response Time and pH
The kinetic spectra analysis of probe PHPQ-SH upon introducing biothiols (GSH,

Effects of Response Time and pH
The kinetic spectra analysis of probe PHPQ-SH upon introducing biothiols (GSH, Cys and Hcy) was monitored at 25/37 °C temperature ( Figure 7). The time-dependent fluorescence intensity of PHPQ-SH (10.0 µM) at 535 nm indicated that the probe itself had

Effects of Response Time and pH
The kinetic spectra analysis of probe PHPQ-SH upon introducing biothiols (GSH, Cys and Hcy) was monitored at 25/37 • C temperature ( Figure 7). The time-dependent fluorescence intensity of PHPQ-SH (10.0 µM) at 535 nm indicated that the probe itself had high photostability, with no fluorescence change at test temperature. However, the fluorescence intensities can increase rapidly at the beginning and level out within 8 min after adding GSH (100.0 µM) to the solution of PHPQ-SH (10.0 µM) at 25 • C. Moreover, a similar quick fluorescence intensity enchantment appeared with probe PHPQ-SH in response to Cys and Hcy at 25 • C. It is obvious that probe PHPQ-SH could be used as a realtime candidate for biothiols' determination. In addition, the reaction time of probe PHPQ-SH with thiols at 37 • C was investigated. The results are shown in Figure 8, indicating that the reaction was accelerated compared with the reaction at room temperature. The observed rated constants at 37 • C were found to be 4.458, 4.124 and 7.312 min −1 for Cys, Hcy and GSH, respectively.   In order to assess the possibility of practical use for probe PHPQ-SH in biological systems, the effect of pH is considered an essential factor. The behavior of probe PHPQ-SH at various pH values was conducted through recording the fluorescence spectra. As shown in Figure 9, in the absence of GSH, an almost horizontal fluctuation curve of fluorescence intensity was observed for free PHPQ-SH (10.0 µM) over a broad pH range from 2.0 to 12.0, which demonstrated a strong stability of PHPQ-SH with pH. After adding biothiols (GSH, Cys, Hcy, respectively) (100.0 µM), remarkable fluorescence signal enhancements of systems were seen in the pH range of 6.0-9.0. The optimal working range suggested that probe PHPQ-SH could be used to detect biothiols in biological systems. Meanwhile, the changes of fluorescence intensity in different concentrations of buffer solution were studied ( Figure S6). They indicated that the fluorescence intensity of the reaction system increased slightly with the increase of buffer concentration, which had a neg-   In order to assess the possibility of practical use for probe PHPQ-SH in biological systems, the effect of pH is considered an essential factor. The behavior of probe PHPQ-SH at various pH values was conducted through recording the fluorescence spectra. As shown in Figure 9, in the absence of GSH, an almost horizontal fluctuation curve of fluorescence intensity was observed for free PHPQ-SH (10.0 µM) over a broad pH range from 2.0 to 12.0, which demonstrated a strong stability of PHPQ-SH with pH. After adding biothiols (GSH, Cys, Hcy, respectively) (100.0 µM), remarkable fluorescence signal enhancements of systems were seen in the pH range of 6.0-9.0. The optimal working range suggested that probe PHPQ-SH could be used to detect biothiols in biological systems. Meanwhile, the changes of fluorescence intensity in different concentrations of buffer solution were studied ( Figure S6). They indicated that the fluorescence intensity of the reaction system increased slightly with the increase of buffer concentration, which had a negligible impact on the fluorescence response of the test system. In order to assess the possibility of practical use for probe PHPQ-SH in biological systems, the effect of pH is considered an essential factor. The behavior of probe PHPQ-SH at various pH values was conducted through recording the fluorescence spectra. As shown in Figure 9, in the absence of GSH, an almost horizontal fluctuation curve of fluorescence intensity was observed for free PHPQ-SH (10.0 µM) over a broad pH range from 2.0 to 12.0, which demonstrated a strong stability of PHPQ-SH with pH. After adding biothiols (GSH, Cys, Hcy, respectively) (100.0 µM), remarkable fluorescence signal enhancements of systems were seen in the pH range of 6.0-9.0. The optimal working range suggested that probe PHPQ-SH could be used to detect biothiols in biological systems. Meanwhile, the changes of fluorescence intensity in different concentrations of buffer solution were studied ( Figure S6). They indicated that the fluorescence intensity of the reaction system increased slightly with the increase of buffer concentration, which had a negligible impact on the fluorescence response of the test system.

Cell Imaging
Inspired by the aforementioned excellent fluorescent characteristics of PHPQ-SH, cell imaging performance for biothiols determination was investigated with MCF-7. As presented in Figure 10, standard MTT assays showed that cell viability was estimated to be as high as 91% after 24 h of incubation at different concentrations of 0.0-20.0 µM of PHPQ-SH, which confirmed that PHPQ-SH had low cytotoxicity and was suitable for intracellular biothiols detection. Next, fluorescence imaging experiments were carried out to evaluate the capability of sensing biothiols in living cells. When the cells were stained with 10.0 µM PHPQ-SH alone, a strong green fluorescence was captured under the confocal microscope ( Figure 11A1,A2). In contrast, the cells were preincubated with NEM (as thiol scavenger, 1.0 mM) and treated with probe PHPQ-SH (10.0 µM); no fluorescence output in the cells was observed ( Figure 11B1, B2). Moreover, after further treatment of the cells with increasing concentrations of GSH (15.0 µM, 50.0 µM, 100.0 µM), fluorescence intensity enhanced significantly ( Figure 11C1,D1,E1), indicating that PHPQ-SH has the potential to be applied in the quantification of biothiols with dose dependently intensified.

Cell Imaging
Inspired by the aforementioned excellent fluorescent characteristics of PHPQ-SH, cell imaging performance for biothiols determination was investigated with MCF-7. As presented in Figure 10, standard MTT assays showed that cell viability was estimated to be as high as 91% after 24 h of incubation at different concentrations of 0.0-20.0 µM of PHPQ-SH, which confirmed that PHPQ-SH had low cytotoxicity and was suitable for intracellular biothiols detection. Next, fluorescence imaging experiments were carried out to evaluate the capability of sensing biothiols in living cells. When the cells were stained with 10.0 µM PHPQ-SH alone, a strong green fluorescence was captured under the confocal microscope ( Figure 11A1,A2). In contrast, the cells were preincubated with NEM (as thiol scavenger, 1.0 mM) and treated with probe PHPQ-SH (10.0 µM); no fluorescence output in the cells was observed ( Figure 11B1, B2). Moreover, after further treatment of the cells with increasing concentrations of GSH (15.0 µM, 50.0 µM, 100.0 µM), fluorescence intensity enhanced significantly ( Figure 11C1,D1,E1), indicating that PHPQ-SH has the potential to be applied in the quantification of biothiols with dose dependently intensified.

Cell Imaging
Inspired by the aforementioned excellent fluorescent characteristics of PHPQ-SH, cell imaging performance for biothiols determination was investigated with MCF-7. As presented in Figure 10, standard MTT assays showed that cell viability was estimated to be as high as 91% after 24 h of incubation at different concentrations of 0.0-20.0 µM of PHPQ-SH, which confirmed that PHPQ-SH had low cytotoxicity and was suitable for intracellular biothiols detection. Next, fluorescence imaging experiments were carried out to evaluate the capability of sensing biothiols in living cells. When the cells were stained with 10.0 µM PHPQ-SH alone, a strong green fluorescence was captured under the confocal microscope ( Figure 11A1,A2). In contrast, the cells were preincubated with NEM (as thiol scavenger, 1.0 mM) and treated with probe PHPQ-SH (10.0 µM); no fluorescence output in the cells was observed ( Figure 11B1, B2). Moreover, after further treatment of the cells with increasing concentrations of GSH (15.0 µM, 50.0 µM, 100.0 µM), fluorescence intensity enhanced significantly ( Figure 11C1,D1,E1), indicating that PHPQ-SH has the potential to be applied in the quantification of biothiols with dose dependently intensified.

Imaging Biothiols in Zebrafish
Based on the cell imaging performance for biothiols determination, the capability of PHPQ-SH to visualize biothiols in zebrafish was carried out using a laser confocal microscope. As shown in Figure 12, when zebrafish were incubated with PHPQ-SH (10.0 µM) for 30 min, an intense green fluorescence appeared (Figure 12a,c), suggesting that endogenous biothiols could be conveniently detected with PHPQ-SH. In a control experiment, zebrafish were pretreated with NEM (1.0 mM) for 30 min, and then incubated with PHPQ-SH (10.0 µM) for another 30 min; negligible fluorescence (Figure 12e,g) in green channel was obtained. These data clearly implied that PHPQ-SH could successfully detect biothiols in zebrafish, with a brilliant performance.

Imaging Biothiols in Zebrafish
Based on the cell imaging performance for biothiols determination, the capability of PHPQ-SH to visualize biothiols in zebrafish was carried out using a laser confocal microscope. As shown in Figure 12, when zebrafish were incubated with PHPQ-SH (10.0 µM) for 30 min, an intense green fluorescence appeared (Figure 12a,c), suggesting that endogenous biothiols could be conveniently detected with PHPQ-SH. In a control experiment, zebrafish were pretreated with NEM (1.0 mM) for 30 min, and then incubated with PHPQ-SH (10.0 µM) for another 30 min; negligible fluorescence (Figure 12e,g) in green channel was obtained. These data clearly implied that PHPQ-SH could successfully detect biothiols in zebrafish, with a brilliant performance.

Imaging Biothiols in Zebrafish
Based on the cell imaging performance for biothiols determination, the capability of PHPQ-SH to visualize biothiols in zebrafish was carried out using a laser confocal microscope. As shown in Figure 12, when zebrafish were incubated with PHPQ-SH (10.0 µM) for 30 min, an intense green fluorescence appeared (Figure 12a,c), suggesting that endogenous biothiols could be conveniently detected with PHPQ-SH. In a control experiment, zebrafish were pretreated with NEM (1.0 mM) for 30 min, and then incubated with PHPQ-SH (10.0 µM) for another 30 min; negligible fluorescence (Figure 12e,g) in green channel was obtained. These data clearly implied that PHPQ-SH could successfully detect biothiols in zebrafish, with a brilliant performance.

Detection of GSH in Real Sample
Finally, the practical application of the probe PHPQ-SH was evaluated by measuring GSH in spiked urine sample. The recoveries and the relative errors of the proposed methods  Table S2. Probe PHPQ-SH exhibited a recovery range (98.6%-101.4%) for GSH detection in samples, and the relative standard deviations (RSD) were all less than 2.13%. The results indicated that the probe PHPQ-SH, as a fluorescent sensor, could be used for the detection of GSH with good recovery and precision.

Spectrum Analysis
The stock solution of PHPQ-SH (1.0 mM) was the prepared in CH 3 CN. Amino acid solutions (including Ala, Arg, Glu, Asp, Ser, Lys, Thr, Val, Tyr, Pro, Trp, Leu, Phe, Gly, Ile, Met, His, Gln, Asn, GSH, Cys, Hcy) for measurement were each prepared in twicedistilled water (10.0 mM). Then, the test solution was prepared by placing PHPQ-SH stock solution and appropriate testing analyte in phosphate buffered saline (PBS) buffer solution (pH = 7.4, containing 50% acetonitrile). The resulting mixtures were incubated well for 8 min at room-temperature and recorded by spectral measurements. The parameters of fluorescence spectra were set to λ ex / em = 397/535 nm.

Cell Cytotoxicity Assay and Fluorescence Imaging
The fluorescence imaging tests to biothiols were performed in MCF-7 cells. The cells were cultured in Dulbecco's modified Eagle's medium (DMEM) at 5% CO 2

Zebrafish Imaging
The 4-day-old zebrafish were fed in E3 embryo culture water to conduct imaging study. For zebrafish imaging experiment, zebrafish were stained with PHPQ-SH (10 µM) for 30 min. For the control case, zebrafish were pretreated with NEM (1.0 mM) for 30 min, followed by treatment with PHPQ-SH (10 µM) for another 30 min. Each fluorescence image of zebrafish was performed with confocal microscope after adopting E3 media to wash away the excess incubate reagents.

Sample Determination
The urine sample was treated with N-ethyl maleimide (NEM) to block the thiol groups for 1.5 h, then was diluted (1:10, v/v) with Tris-HAc buffer. For the analysis, each stock solution was added with probe PHPQ-SH and a known concentration of GSH (ranged from 1.0 to 20.0 µM). The resulting solution was shaken well, and then the fluorescence spectra were recorded.

Synthesis of PHPQ
2-Aminobenzamide 54.5 mg (0.4 mmol), compound 1 [36] (119 mg, 0.4 mmol) and 10 mL of anhydrous ethanol were added to a 100 mL round bottom single neck round bottom flask under argon atmosphere. The resulting mixture was stirred at refluxing temperature for 50 min. Then, 5 mg of p-toluenesulfonic acid was added and the resulting mixture was stirred at refluxing temperature for 2 h. After cooling to the room temperature, 90.8 mg of DDQ was added and the mixture was stirred at room temperature for 2 h. Finally, the reaction solution was filtered and washed with anhydrous ethanol. Dried and purified by column chromatography (mixtures of dichloromethane and ethyl acetate as eluent; 30:1, v/v) to obtain the probe PHPQ (53.8%). 1

Conclusions
In conclusion, an efficient fluorescent probe, PHPQ-SH, for detecting biothiols in vitro and vivo, based on the phenothiazine-HPQ skeleton, with the DNBS as the response unit, was synthesized. By taking advantage of the transformable PET process, probe PHPQ-SH was shown to be capable of sensitively monitoring biothiols in a turn-on signaling mode. Meanwhile, the probe PHPQ-SH features remarkable fluorescence enhancement (163-fold), rapid response (8 min), a large Stokes shift (138 nm), excellent sensitivity (for GSH, LOD = 18.3 nM), low cytotoxicity, and extraordinary selectivity in response to biothiols. Probe PHPQ-SH was also applied to monitor levels of GSH in realistic samples. Furthermore, the fluorescence imaging data clearly implied that PHPQ-SH could successfully detect biothiols in MCF-7 cells and zebrafish, with brilliant performances.