CHARACTERIZATION OF INTERACTION BETWEEN BUDDLEOSIDE AND BOVINE SERUM ALBUMIN

Sun, Shan; Yuan, Zhe; Lu, Yuanqi

doi:10.21577/0100-4042.20170568

Abstract

The primary objective of this study was to investigate the binding of buddleoside to bovine serum albumin (BSA) by different analytical techniques. The analytical principles of affinity capillary electrophoresis (ACE) and fluorescence spectroscopy used in the experiments were different. Mobility (M) that is independent of viscosity of the operating buffer and voltage was chosen to eliminate the effects of electroosmotic flow (EOF) in ACE and was applied to estimate the binding constant Ka. The quenching constant K_sv, binding site number n and binding constant Kb were provided by the fluorescence quenching method. After data analysis of the fluorescence quenching process, it can be seen that the quenching of BSA by buddleoside is a static quenching method. The binding constants between buddleoside and BSA obtained from ACE and fluorescence spectra were 1.218×10⁵5 Nunes, N. M.; Pacheco, A. F. C.; Agudelo, Ã. J. P.; da Silva, L. H. M.; Pinto, M. S.; Hespanhol, M. C.; Pires, A. C. S.; Food Chem.2017, 237, 525. and 1.1915×10⁵5 Nunes, N. M.; Pacheco, A. F. C.; Agudelo, Ã. J. P.; da Silva, L. H. M.; Pinto, M. S.; Hespanhol, M. C.; Pires, A. C. S.; Food Chem.2017, 237, 525., respectively. According to the thermodynamic parameters of ΔG, ΔH and ΔS, it can be inferred that Van Der Waals force and hydrogen bonding force exist in the interaction between buddleoside and BSA. This study can provide a reference for the study of the transport and function mechanism of buddleoside in vivo.

Keywords:
buddleoside; bovine serum albumin (BSA); affinity capillary electrophoresis (ACE); fluorescence spectroscopy; binding constants

INTRODUCTION

After entering the blood circulatory system, drugs will be stored and transported by plasma to reach the target tissue and exert efficacy.¹1 Raza, M.; Ahmad, A.; Yue, F.; Khan, Z.; Jiang, Y.; Wei, Y.; Raza, S.; He, W. W.; Khan, F.; Qipeng, Y.; J. Photochem. Photobiol. B. 2017, 170, 6. Serum albumin is the most abundant carrier protein in plasma and the major soluble protein constituents of the blood circulation.²2 Poór, M.; Kunsági-Máté, S.; Bálint, M.; Hetényi, C.; Gerner, Z.; Lemli, B.; J. Photochem. Photobiol. B. 2017, 170, 16. So, the mechanism studying of the interaction between drugs and serum albumin is helpful to understand the transportation and distribution of drugs in vivo on the molecular level. Human serum albumin (HSA) usually play an important role in the pharmacokinetics and toxicokinetics.³3 Ma, L.; Maragos, C. M.; Y. H.; Mycotoxin Res. 2018, 34, 39. It has been reported that HSA can interact reversibly with a variety of exogenous and endogenous substances, including drugs.⁴4 Zhang, Y. L.; Sha, Y. J.; Qian, K.; Chen, X.; Chen, Q.; Electrophoresis 2017, 38, 1038. Bovine serum albumin (BSA) is composed of 583 amino acid residues. It has three domains: domain I, II, and III. Each domain has two subdomains, A and B. The two main drug-binding sites (site I and site II) are located in the subdomain IIA and the subdomain IIIA, respectively.⁵5 Nunes, N. M.; Pacheco, A. F. C.; Agudelo, Ã. J. P.; da Silva, L. H. M.; Pinto, M. S.; Hespanhol, M. C.; Pires, A. C. S.; Food Chem.2017, 237, 525.

6 Manjushree, M.; Revanasiddappa Hosakere, D.; J. Mol. Liq. 2017, 237, 23.^-⁷7 Minic, S.; Stanic-Vucinic, D.; Radomirovic, M.; Radibratovic, M.; Milcic, M.; Nikolic, M.; Cirkovic-Velickovic, T.; Food Chem.2018, 239, 1090. BSA is one of the most widely studied proteins because of its structural homology with HSA.⁸8 Lou, Y. Y.; Zhou, K. L.; Pan, D. Q.; Shen, J. L.; Shi, J. H.; J. Photochem. Photobiol. B 2017, 167, 158.

9 Gałęcki, K.; Despotović, B.; Galloway, C.; Ioannidis, A. G.; Janani, T.; Nakamura, Y.; Oluyinka, G.; Biotechnol. Food Sci. 2012, 76, 3.

10 Swarup, R.; Raj Kumar, N.; Sintu, G.; Majumdar, K. C.; Tapan, K. D.; J. Pharm. Anal.2017, 7, 19.^-¹¹11 Domínguez, M.; Cortes-Figueroa, J. E.; Melendez, E.; J. Chem. Educ.2018, 95, 152.

Buddleoside is a major biological active substance derived from the traditional Chinese herbal medicine called Chrysanthemum indicum.¹²12 He, D.; Ru, X.; Wen, L.; Wen, Y.; Jiang, H.; Bruce, I. C.; Jin, J.; Ma, X.; Xia, Q.; J. Ethnopharmacol.2012, 139, 68.^,¹³13 Chen, H. Y.; Ni, J.; Zhang, H.; Chin. J. Exp. Tradit. Med. Formulae 2013, 19, 122. The structure of buddleoside is shown in Figure 1. Buddleoside is a kind of flavonoids in Chrysanthemum indicum, with anti-inflammatory, analgesic, sweating, lowering blood pressure, anti-stress, anxiety, antipyretic and so on.¹⁴14 Martínez-Vázquez, M.; Ramírez Apan, T. O.; Lastra, A. L.; Bye, R.; Planta Med.1998, 64, 134.

15 Yang, Y.; Chen, B.; Liang, K. L.; Su, J.; Chen, S. H.; Lv, G. Y.; China J. Chin. Mater. Med. 2017, 42, 1370.^-¹⁶16 Han, Y. C.; Gong, H. Y.; Liu, W.; Chen, N.; Cui, Y. X.; Wu, M. X.; Wang, L. G.; Rui, F. S.; Chin. J. Exp. Tradit. Med. Formulae 2013, 19, 88. At present, there are many studies on buddleoside,¹⁷17 Huang, Y.; Feng, Y.; Tang, G. Y.; Li, M. Y.; Zhang, T. T.; Fillet, M.; Crommen, J.; Jiang, Z. J.; J. Pharm. Bio. Anal.2017, 140, 348.^,¹⁸18 Wu, M. X.; Wang, J. J.; Zhang, G. J.; Sun S. Q.; Chin. J. Exp. Tradit. Med. Formulae 2010, 16, 54. but no any research on the interaction between buddleoside and serum albumin.

Figure 1
The molecular structure of buddleoside

In this paper, affinity capillary electrophoresis (ACE) and fluorescence spectroscopy were used to study the spectral characteristics about the binding interaction between buddleoside and BSA in detail. The data of the study showed that the binding constants and the binding sites numbers obtained by the two analytical methods were very similar. The results can provide theoretical support for the research of medicinal mechanism of buddleoside.

EXPERIMENTAL PART

Instrument

The ACE experiment was performed on a Beckman P/ACE MDQ system with a photodiode array detector. Data collection and analysis was done with Beckman 32 Karat software (version 7.0). An uncoated fused silica capillary (Yongnian reafine chromatograph, China) of 64.5 cm (54 cm of effective length) x 75 µm (i.d.) was used. The fluorescence spectroscopy experiments were performed by using the F-4600 type Fluorescence Spectrophotometer (Hitachi High-Technologies Co., Ltd., Tokyo, Japan). During the experiment, PHSJ-4A measuring instrument (Shanghai Precision & Scientific Instrument Co., Shanghai, China) was applied to determine different pH.

Chemicals and solutions

Buddleoside and BSA were purchased from Shanghai Yuanye Biotechnology Company (Shanghai, China) and Shanghai Aladdin Biotechnology Co., Ltd. (Shanghai, China), respectively. Both borax and boric acid were bought from Sigma (St. Louis, Missouri, USA). The other reagents used in the experiments were of analytical grade.

The pH of the borate buffer containing 30 mmol L^-1 borax was adjusted to 8.8 with 100 mmol L^-1 boric acid. The 1 mmol L^-1 buddleoside stock solution was prepared in DMSO and the 100 µmol L^-1 BSA stock solution was dissolved in 30 mmol L^-1 borate buffer. During the ACE, the sample solution was diluted to 100 µmol L^-1 with borate buffer solution prior to each injection. DMSO was chosen to label EOF which is a cationic sheath formed on the inner wall of the capillary tube. EOF can drive the whole fluid in the capillary tube to the cathode. Experimental BSA solution (0-10 µmol L^-1) was prepared by diluting BSA stock solution with borate buffer containing 0.05 mol L^-1 glycine (Gly). During the fluorescence measurement, the BSA and NaCl concentrations were keeped at 2 µmol L^-1 and 0.1 mol L^-1 in 30 mmol L^-1 borax buffer solution (pH=8.8), respectively. At the same time, the ratios of the concentration ratios of buddleoside to BSA were 0, 3, 5, 7, 8, 9 and 10, respectively. All solutions needed to be filtered through 0.22 µm filters and stored refrigerator at 4 ºC before experiments.

Procedures

New capillaries were rinsed with 1 mol L^-1 NaOH for 5 min, washed with water for 10 min and conditioned with borax buffer for 15 min before use. To improve great peak shape and reproducibility, the capillary was rinsed sequentially for 3 min by NaOH, water and buffer.

In the ACE analysis, analytes were detected at 334 nm and injected by applying a pressure of 0.5 psi for 5 s. The operating voltage was set to 15 kV. The electrophoresis was performed with 30 mmol L^-1 borate buffer (pH 8.8, 0.05 mol L^-1 Gly) including different concentrations of BSA (0-10 µmol L^-1). In order to eliminate the effect of BSA adsorption on the inner wall of the capillary, Gly, an amphotericion, was added to compete with BSA. Besides, the BSA concentration was low (0 to 10 µmol L^-1) in this study. In fluorescence experiments, 2 µmol L^-1 BSA solution was titrated with different buddleoside concentrations (0, 6, 10, 14, 16, 18, 20 µmol L^-1). Fluorescence spectra were recorded at 298 K and the scanning wavelength range was 290-600 nm. The excitation wavelength was set at 280 nm. Emission and excitation slits were 10 nm.

RESULTS AND DISCUSSION

Theory of the estimation of binding constants by ACE method

In the research of drug and protein interaction, drugs or the protein can be added into the ACE running buffer. In this experiment, considering the cost of the experiment, BSA was added to the buffer solution as an additive, and the drug concentration was used as a fixed amount. The drug and serum albumin are assumed to be a 1:1 combination. The following equation represents the drug-serum albumin binding reaction.¹⁹19 Michalcová, L.; Glatz, Z.; J. Sep. Sci.2016, 39, 3631.^,²⁰20 Qian, C.; Wang, S.; Fu, H.; Turner, RFB.; Li, H.; Chen, D. D. Y.; Electrophoresis 2018, 39, 1786.

(1)

\frac{D + P = DP}{Ka = [DP] / [D] [P]}

where [D], [P], [DP] represent the concentrations of the drug, serum albumin and drug-protein complex, respectively. Equation (2) is used to calculate Ka.²¹21 Zhang, B.; Li, Y. X.; Gao, H. N.; Bian, J.; Bao, J. J.; Electrophoresis 2011, 32, 3589.

(2)

\frac{1 / Δ μ_{D}^{P} = [1 / (Ka \times Δ μ_{\max}) \times 1 / c (P)] + 1 / Δ μ_{\max}}{Δ μ_{D}^{P} = μ_{D}^{P} - μ_{D}}

where µ_D^P and µ_D represents the electrophoretic mobility of drugs in the presence and absence of protein. Δµ_max = µ_DP - µ_D , where µ_DPis the mobility of the complex. Linear graphs were obtained by plotting 1/Δµ_D^P against 1/c(P). Therefore, the binding constant can be calculated from the intercept/slope. However, the analysis method has limitations due to the protein added to the buffer. Protein adsorption onto the capillary wall can cause problems in separation and loss of protein and drug. The buffer viscosity and EOF varies as the protein concentration changes and causes a difference in Ka.²²22 Liu, X. P.; Du, Y. X.; Eur. J. Med. Chem.2010, 45, 4043. In order to minimize this phenomenon, the mobility ratio (M) was introduced.²³23 Bose, S.; Yang, J.; Hage, D. S.; J. Chromatogr. B 1997, 697, 77. M has proven to be independent of operating voltage and buffer viscosity, so it can estimate Ka more accurately. The following formula shows the calculation of M.²⁴24 Liu, C.; Wei, Y.; Miao, Y.; Zhang, Y.; Pharmazie 2012, 67, 839.

(3)

M = (μ_{eo} + μ_{D}^{P}) / μ_{eo} = t_{eo} / t_{D}^{P} + 1

where t_eo represents the migration time of the EOF and t_D^P represents the migration time of the analyte. Therefore, the Scatchard equation is corrected to the following equation (4).²⁵25 Xu, Y.; Hong, T.; Chen, X.; Ji, Y.; Electrophoresis 2017, 38, 1366.

(4)

\frac{1 / Δ M_{D}^{P} = [1 / (Ka \times Δ M_{\max}) \times 1 / c (P)] + 1 / Δ M_{\max}}{Δ M_{D}^{P} = M_{D}^{P} - M_{D}, Δ M_{\max} = M_{DP} - M_{D}}

where M^P_D and M_D represent the mobility of the drug in the presence and absence of the protein, respectively. M_DP represents the mobility of the complex. In this study, Scatchard analysis is carried out with equation 4, and Ka is obtained by linear fitting.

Measurement of the drug/BSA binding constant by ACE

Peak time of buddleoside (t^P_D) and DMSO (t_R) are listed in Table 1. At 298K, with the change of BSA concentration, the electrophoretograms of the complex formed by buddleoside and BSA is shown in Figure 2. From Table 1 and Figure 2, it can be seen that with the increase of BSA concentration, the peaks of buddleoside and DMSO shift to the right. Due to the complexation between buddleoside and BSA, the m/z of the complex increases and the peak time of the complex is later than the uncomplexed form. With the increase of BSA concentration, the peak pattern of the buddleoside is gradually asymmetric. At different temperatures, the Scatchard equation and Ka calculated from the intercept and slope ratios of buddleoside and BSA are shown in Table 2. The binding constant Ka decreased from 1.218 ×10⁵5 Nunes, N. M.; Pacheco, A. F. C.; Agudelo, Ã. J. P.; da Silva, L. H. M.; Pinto, M. S.; Hespanhol, M. C.; Pires, A. C. S.; Food Chem.2017, 237, 525. to 2.330 ×10⁴4 Zhang, Y. L.; Sha, Y. J.; Qian, K.; Chen, X.; Chen, Q.; Electrophoresis 2017, 38, 1038. with the increase of temperature.

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Table 1
Migration time of buddleoside obtained by ACE method and their transformation

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Table 2
The Ka and Scatchard equation of buddleoside-protein at different temperatures

Figure 2
Electropherograms of buddleoside and BSA conjugate at different BSA concentrations in 30 mmol L^-1 borate buffer (pH =8.8, 0.05 mol L^-1 Gly). Among them, a-f represents the BSA concentration of 0, 2, 4, 6, 8, and 10 µmol L^-1, respectively, and the concentration of buddleoside is fixed at 100 µmol L^-1. Peak 1: DMSO, 2: buddleoside

Affinity measurements using fluorescence spectroscopy

To further clarify the interaction between buddleoside and BSA, fluorescence quenching experiment was carried out. The binding of buddleoside and BSA was realized by evaluating the intrinsic fluorescence intensity of BSA after adding different concentrations of buddleoside. The quenching effect of fluorescence can usually be categorized into dynamic quenching and static quenching. Dynamic quenching is the process of fluorescence weakening caused by collision between fluorescent group and quenching agent, while static quenching is the process of fluorescence weakening caused by the formation of complex of fluorophore and quencher. In order to explore the mechanism of fluorescence quenching of buddleoside to BSA, we firstly assume that it is a dynamic quenching process. According to Stern-Volmer equation (5), the regression curve is drawn.²⁶26 Makarska-Bialokoz, M.; Spectrochim. Acta, Part A 2017, 193, 23.

(5)

F_{0} / F = 1 + K_{Q} \times τ_{0} \times [Q] = 1 + K_{SV} \times [Q]

In the above formula, F₀ and F represent the fluorescence intensity of BSA before and after the addition of buddleoside, respectively. K_Q and K_SV represent the quenching rate constant and dynamic quenching constant, respectively, while τ₀ and [Q] represent the average lifespan of biomolecules without a quencher (τ₀ =10^-8 s)²⁷27 Li, G.; Liu, B. S.; Zhang, Q.; Han, R.; Luminescence 2015, 31, 1054. and quencher concentration, respectively. The calculated K_Q is 5.17 ×10¹²12 He, D.; Ru, X.; Wen, L.; Wen, Y.; Jiang, H.; Bruce, I. C.; Jin, J.; Ma, X.; Xia, Q.; J. Ethnopharmacol.2012, 139, 68., which is much larger than the maximum scattering collision quenching constant (2.0 × 10¹⁰10 Swarup, R.; Raj Kumar, N.; Sintu, G.; Majumdar, K. C.; Tapan, K. D.; J. Pharm. Anal.2017, 7, 19. L mol^-1 s^-1).²⁸28 Cheng, X. X.; Fan, X. Y.; Jiang, F. L.; Liu, Y.; Lei, K. L.; Luminescence 2015, 30, 1026. It can be seen from the above data that the quenching of buddleoside on BSA should not be a dynamic quenching process, but a static quenching. The following formula (6) represents the calculation method of the binding constant in the static quenching form.²⁹29 He, T. X.; Liang, Q. L.; Luo, T. T.; Wang, Y. M.; Luo, G. A.; J. Solution Chem.2010, 39, 1653.^,³⁰30 Tian, Z.; Zang, F.; Luo, W.; Zhao, Z.; Wang, Y.; Xu, X.; Wang, C.; J. Photochem. Photobiol. B 2015, 142, 103.

(6)

\log_{10} [(F_{0} - F) / F] = \log_{10} (Kb) + n \log_{10} [Q]

In the above formula, Kb is the binding constant of buddleoside and BSA, which can be determined by formula (6). And n is the number of binding sites of each BSA. F₀, F and Q in the formula have the same meaning as formula 5. The fluorescence spectrum of the interaction between the buddleoside and BSA is shown in Figure 3. The fluorescence intensity of BSA decreased with the increase of the concentration of buddleoside, which indicated that buddleoside could quench BSA obviously. The static quenching equation and linear regression are shown in Figure 4. The experimental results of static quenching (Table 3) are basically the same as the binding constant and number of binding sites of ACE. Because the sensitivity and detection principle of the two methods are different, it is acceptable that there are slight differences between them.

Figure 3
Fluorescence spectrum of buddleoside and BSA complex. The concentration of BSA was fixed at 2 µmol L^-1, and the concentration of buddleoside changed from 0 to 20 µmol L^-1 (a-g:0, 6, 10, 14, 16, 18 and 20 µmol L^-1)

Figure 4
Stern-Volmer equation and linear regression diagram of static quenching

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Table 3
Stern-Volmer quenching constants and binding parameters for the interaction of BSA with buddleoside at 298 K

Analysis of interaction forces by ACE method

Generally speaking, four forces including hydrogen bond, Van Der Waals force, electrostatic interaction and hydrophobic interaction are the main interactions between small molecules and proteins. The thermodynamic parameters such as entropy change(ΔS), enthalpy change (ΔH) and free energy change (ΔG) are of great significance for the determination of the binding mode of drugs and proteins. Equation 7, 8 and 9 are applied to calculate the thermodynamic constants of the binding process of buddleoside and BSA:³¹31 He, T. X.; Liang, Q. L.; Wang, Y. M.; Luo, G. A.; J. Liq. Chromatogr. Relat. Technol. 2010, 33, 548.

(7)

\ln Ka = (- Δ H / RT) + Δ S / R

(8)

Δ G = - RT \ln K

(9)

Δ S = (Δ H - Δ G) / T

where R and Ka are gas constants and binding constants at corresponding temperatures, respectively. In order to further elaborate the process of the combination of buddleoside and BSA, ACE method is used to study the thermodynamic parameters of the interaction process of buddleoside and BSA at 298, 303 and 308 K in this study. The data is shown in Table 4. The negative ΔG indicates that the interaction between buddleoside and BSA is spontaneous. The negative ΔS and ΔH are often used as evidence of Van Der Waals force.³²32 Li, G.; Liu, B. S.; Zhang, Q.; Han, R.; Luminescence 2015, 31, 1054. In the exothermic process or in the presence of hydrogen bonds, the phenomenon of ΔH less than zero can also be observed. When ΔS is greater than zero, it is often considered to have hydrophobic effect. In aqueous solution, when ΔS is greater than zero and ΔH is less than zero (close to zero), it indicates the generation of electrostatic interaction.³³33 Tayyab, S.; Izzudin, M. M.; Kabir, M. Z.; Feroz, S. R.; Tee, W. V.; J. Photochem. Photobiol. B 2016, 162, 386.

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Table 4
Thermodynamic parameters of the buddleoside-protein binding process at different temperatures

CONCLUSIONS

In the present work, the interaction between buddleoside and BSA was studied by ACE and fluorescence spectroscopy. The binding constant of fluorescence quenching of buddleoside and BSA is 1.1915 ×10⁵5 Nunes, N. M.; Pacheco, A. F. C.; Agudelo, Ã. J. P.; da Silva, L. H. M.; Pinto, M. S.; Hespanhol, M. C.; Pires, A. C. S.; Food Chem.2017, 237, 525., and the binding constant obtained by ACE is 1.218 ×10⁵5 Nunes, N. M.; Pacheco, A. F. C.; Agudelo, Ã. J. P.; da Silva, L. H. M.; Pinto, M. S.; Hespanhol, M. C.; Pires, A. C. S.; Food Chem.2017, 237, 525.. The results of the two methods are basically the same. This shows that both methods have good applicability in the study of substance binding. At the same time, it can be seen that buddleoside has strong binding ability to BSA. From the fluorescence spectrum data, buddleoside quenches the endogenous fluorescence of BSA. And this is a static quenching process. The binding site n obtained in the study is about one, which is consistent with the experimental hypothesis. This indicates that there is only one binding site between buddleoside and BSA. The number of binding sites can provide reference for the study on the mechanism of transport of buddleoside by serum albumin in vivo. The thermodynamic parameters of the buddleoside and BSA obtained by the ACE method during the binding process indicate that Van Der Waals forces and hydrogen bonding play important roles. This research can provide theoretical guidance for the clinical application of buddleoside. The efficacy and metabolism of buddleoside in the human body will be further studied in future studies.

ACKNOWLEDGEMENT

We are very grateful for the support of Natural Science Foundation of Shandong Province (Grant No. ZR 2018LB 021) for our work.

REFERENCES

¹
Raza, M.; Ahmad, A.; Yue, F.; Khan, Z.; Jiang, Y.; Wei, Y.; Raza, S.; He, W. W.; Khan, F.; Qipeng, Y.; J. Photochem. Photobiol. B. 2017, 170, 6.
²
Poór, M.; Kunsági-Máté, S.; Bálint, M.; Hetényi, C.; Gerner, Z.; Lemli, B.; J. Photochem. Photobiol. B. 2017, 170, 16.
³
Ma, L.; Maragos, C. M.; Y. H.; Mycotoxin Res. 2018, 34, 39.
⁴
Zhang, Y. L.; Sha, Y. J.; Qian, K.; Chen, X.; Chen, Q.; Electrophoresis 2017, 38, 1038.
⁵
Nunes, N. M.; Pacheco, A. F. C.; Agudelo, Ã. J. P.; da Silva, L. H. M.; Pinto, M. S.; Hespanhol, M. C.; Pires, A. C. S.; Food Chem2017, 237, 525.
⁶
Manjushree, M.; Revanasiddappa Hosakere, D.; J. Mol. Liq. 2017, 237, 23.
⁷
Minic, S.; Stanic-Vucinic, D.; Radomirovic, M.; Radibratovic, M.; Milcic, M.; Nikolic, M.; Cirkovic-Velickovic, T.; Food Chem2018, 239, 1090.
⁸
Lou, Y. Y.; Zhou, K. L.; Pan, D. Q.; Shen, J. L.; Shi, J. H.; J. Photochem. Photobiol. B 2017, 167, 158.
⁹
Gałęcki, K.; Despotović, B.; Galloway, C.; Ioannidis, A. G.; Janani, T.; Nakamura, Y.; Oluyinka, G.; Biotechnol. Food Sci. 2012, 76, 3.
¹⁰
Swarup, R.; Raj Kumar, N.; Sintu, G.; Majumdar, K. C.; Tapan, K. D.; J. Pharm. Anal2017, 7, 19.
¹¹
Domínguez, M.; Cortes-Figueroa, J. E.; Melendez, E.; J. Chem. Educ2018, 95, 152.
¹²
He, D.; Ru, X.; Wen, L.; Wen, Y.; Jiang, H.; Bruce, I. C.; Jin, J.; Ma, X.; Xia, Q.; J. Ethnopharmacol2012, 139, 68.
¹³
Chen, H. Y.; Ni, J.; Zhang, H.; Chin. J. Exp. Tradit. Med. Formulae 2013, 19, 122.
¹⁴
Martínez-Vázquez, M.; Ramírez Apan, T. O.; Lastra, A. L.; Bye, R.; Planta Med1998, 64, 134.
¹⁵
Yang, Y.; Chen, B.; Liang, K. L.; Su, J.; Chen, S. H.; Lv, G. Y.; China J. Chin. Mater. Med. 2017, 42, 1370.
¹⁶
Han, Y. C.; Gong, H. Y.; Liu, W.; Chen, N.; Cui, Y. X.; Wu, M. X.; Wang, L. G.; Rui, F. S.; Chin. J. Exp. Tradit. Med. Formulae 2013, 19, 88.
¹⁷
Huang, Y.; Feng, Y.; Tang, G. Y.; Li, M. Y.; Zhang, T. T.; Fillet, M.; Crommen, J.; Jiang, Z. J.; J. Pharm. Bio. Anal2017, 140, 348.
¹⁸
Wu, M. X.; Wang, J. J.; Zhang, G. J.; Sun S. Q.; Chin. J. Exp. Tradit. Med. Formulae 2010, 16, 54.
¹⁹
Michalcová, L.; Glatz, Z.; J. Sep. Sci2016, 39, 3631.
²⁰
Qian, C.; Wang, S.; Fu, H.; Turner, RFB.; Li, H.; Chen, D. D. Y.; Electrophoresis 2018, 39, 1786.
²¹
Zhang, B.; Li, Y. X.; Gao, H. N.; Bian, J.; Bao, J. J.; Electrophoresis 2011, 32, 3589.
²²
Liu, X. P.; Du, Y. X.; Eur. J. Med. Chem2010, 45, 4043.
²³
Bose, S.; Yang, J.; Hage, D. S.; J. Chromatogr. B 1997, 697, 77.
²⁴
Liu, C.; Wei, Y.; Miao, Y.; Zhang, Y.; Pharmazie 2012, 67, 839.
²⁵
Xu, Y.; Hong, T.; Chen, X.; Ji, Y.; Electrophoresis 2017, 38, 1366.
²⁶
Makarska-Bialokoz, M.; Spectrochim. Acta, Part A 2017, 193, 23.
²⁷
Li, G.; Liu, B. S.; Zhang, Q.; Han, R.; Luminescence 2015, 31, 1054.
²⁸
Cheng, X. X.; Fan, X. Y.; Jiang, F. L.; Liu, Y.; Lei, K. L.; Luminescence 2015, 30, 1026.
²⁹
He, T. X.; Liang, Q. L.; Luo, T. T.; Wang, Y. M.; Luo, G. A.; J. Solution Chem2010, 39, 1653.
³⁰
Tian, Z.; Zang, F.; Luo, W.; Zhao, Z.; Wang, Y.; Xu, X.; Wang, C.; J. Photochem. Photobiol. B 2015, 142, 103.
³¹
He, T. X.; Liang, Q. L.; Wang, Y. M.; Luo, G. A.; J. Liq. Chromatogr. Relat. Technol. 2010, 33, 548.
³²
Li, G.; Liu, B. S.; Zhang, Q.; Han, R.; Luminescence 2015, 31, 1054.
³³
Tayyab, S.; Izzudin, M. M.; Kabir, M. Z.; Feroz, S. R.; Tee, W. V.; J. Photochem. Photobiol. B 2016, 162, 386.

Publication Dates

Publication in this collection
21 Aug 2020
Date of issue
Aug 2020

History

Received
07 Jan 2020
Accepted
15 Apr 2020
Published
15 June 2020

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Raza, M.; Ahmad, A.; Yue, F.; Khan, Z.; Jiang, Y.; Wei, Y.; Raza, S.; He, W. W.; Khan, F.; Qipeng, Y.; J. Photochem. Photobiol. B. 2017, 170, 6.

[2] ²
Poór, M.; Kunsági-Máté, S.; Bálint, M.; Hetényi, C.; Gerner, Z.; Lemli, B.; J. Photochem. Photobiol. B. 2017, 170, 16.

[3] ³
Ma, L.; Maragos, C. M.; Y. H.; Mycotoxin Res. 2018, 34, 39.

[4] ⁴
Zhang, Y. L.; Sha, Y. J.; Qian, K.; Chen, X.; Chen, Q.; Electrophoresis 2017, 38, 1038.

[5] ⁵
Nunes, N. M.; Pacheco, A. F. C.; Agudelo, Ã. J. P.; da Silva, L. H. M.; Pinto, M. S.; Hespanhol, M. C.; Pires, A. C. S.; Food Chem2017, 237, 525.

[6] ⁶
Manjushree, M.; Revanasiddappa Hosakere, D.; J. Mol. Liq. 2017, 237, 23.

[7] ⁷
Minic, S.; Stanic-Vucinic, D.; Radomirovic, M.; Radibratovic, M.; Milcic, M.; Nikolic, M.; Cirkovic-Velickovic, T.; Food Chem2018, 239, 1090.

[8] ⁸
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	t_R, min	t_D^P, min	ΔM_D^P	1 / ΔM_D^P	1 / c(P), (µmol L^-1)
0	4.986	5.179
2	5.415	5.654	-0.0050	-200.000	0.5000
4	5.609	5.867	-0.0067	-149.254	0.2500
6	5.756	6.042	-0.0100	-100.000	0.1667
8	5.866	6.183	-0.0140	-71.429	0.1250
10	6.003	6.339	-0.0148	-67.568	0.1000

	T	Scatchard equation	Ka, (L mol^-1)	R²
Buddleoside	298K	$y = - 335.95 x - 40.94$	1.218 ×10 ⁵	0.9324
	303K	$y = - 475.46 x - 43.60$	9.100×10⁴	0.9757
	308K	$y = - 511.26 x - 11.93$	2.330×10⁴	0.9406

T	Stern-Volmer quenching constants				Binding parameters
T	K_SV, (L mol^-1)	K_Q, (L mol^-1 ·s^-1)	R²		Kb, (L mol^-1)	n	R²
298 K	5.17×10⁴	5.17×10¹²	0.9566		1.1915×10⁵	1.0902	0.9617

	T	△H, (kJ L mol^-1)	△S, (kJ L mol^-1)	△G, (kJ L mol^-1)
Buddleoside	298K		-0.3246	-29.0127
	303K	-125.749	-0.3201	-28.7651
	308K		-0.3247	-25.7511

Brasil

Brasil

CHARACTERIZATION OF INTERACTION BETWEEN BUDDLEOSIDE AND BOVINE SERUM ALBUMIN

Abstract

INTRODUCTION

EXPERIMENTAL PART

Instrument

Chemicals and solutions

Procedures

RESULTS AND DISCUSSION

Theory of the estimation of binding constants by ACE method

Measurement of the drug/BSA binding constant by ACE

Affinity measurements using fluorescence spectroscopy

Analysis of interaction forces by ACE method

CONCLUSIONS

ACKNOWLEDGEMENT

REFERENCES

Publication Dates

History