Fabrication of caseins nanoparticles to improve the stability of cyanidin 3-O-glucoside

Journal Pre-proofs Fabrication of caseins nanoparticles to improve the stability of cyanidin 3-Oglucoside Yongzhong Ouyang, Lei Chen, Liu Qian, Xiujun Lin, Xiaoyun Fan, Hui Teng, Hui Cao PII: DOI: Reference:

S0308-8146(20)30278-8 https://doi.org/10.1016/j.foodchem.2020.126418 FOCH 126418

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Food Chemistry

Received Date: Revised Date: Accepted Date:

17 November 2019 10 February 2020 14 February 2020

Please cite this article as: Ouyang, Y., Chen, L., Qian, L., Lin, X., Fan, X., Teng, H., Cao, H., Fabrication of caseins nanoparticles to improve the stability of cyanidin 3-O-glucoside, Food Chemistry (2020), doi: https://doi.org/ 10.1016/j.foodchem.2020.126418

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1

Fabrication of caseins nanoparticles to improve the stability of cyanidin

2

3-O-glucoside

3

Yongzhong Ouyang1, Lei Chen2,#, Liu Qian2,#, Xiujun Lin2, Xiaoyun Fan2, Hui

4

Teng2,*, Hui Cao3,4*

5

1School

6

528000, China.

7

2College

8

China

9

3Guangdong-Macau

of Environmental and Chemical Engineering, Foshan University, Foshan

of Food Science, Fujian Agriculture and Forestry University, Fuzhou 350002,

Traditional Chinese Medicine Technology Industrial Park

10

Development Co., Ltd, Hengqin New Area, Zhuhai 519031, China

11

4Institute

12

Chinese Medicine, University of Macau, Macau

13

*Corresponding author: Hui Teng, [email protected]; Hui Cao,

14

[email protected]

15

#authors contributed equally to this study

of Chinese Medical Sciences, State Key Laboratory of Quality Research in

16 17

Abstract

18

The influence of encapsulation with caseins on the stability of cyanidin 3-O-glucoside

19

(C3G) was investigated. The modified casein nanoparticles (MCs) prepared at pH 5.5

20

after heated at 80 °C for 30 min was applied to encapsulate C3G. The diameter of

21

nanoparticle (MCs-C3G) was 110±0.31 nm and zeta-potential was -8.83±0.52 mV.

22

The molecular weight of α-casein (32 kDa) and β-casein (25 kDa) increased along 1

23

with the encapsulation of C3G. The interactions of MCs with C3G were examined at

24

pH 6.3 by fluorescence spectroscopy and IR spectroscopy. MCs encapsulated C3G

25

mainly via the hydrophobic interaction. The secondary structures of caseins were

26

changed along with the combination of C3G, with a decreasing in α-helix, turn

27

random, and coil structure, as well as increased β-sheet. In addition, the MCs-C3G

28

interaction appeared to have a positive effect on the thermal, oxidation and photo

29

stability of C3G.

30

Key words: cyanidin 3-O-glucoside; caseins; stability; nanoparticles; encapsulation

31 32

1. Introduction

33

Caseins (Cs) consist of phosphorylated α-, κ-, β-format, are the major proteins in

34

bovine milk (approximately 80% of the total milk proteins) (Dalgleish, 2011).

35

α-Casein contains two tryptophan (Trp) residues, while β-casein has one and with

36

stronger hydrophobic bond than α-casein and κ -casein (Dalgleish & Corredig, 2012).

37

As water soluble pigments, anthocyanins have been reported to present numerous

38

benefits for human health (Tang, Li, Bi, & Gao, 2016). There are six common

39

glycosidic and acylglycosidic derivatives of anthocyanidins, namely pelargonidin,

40

cyanidin, malvidin, delphinidin, peonidin, and petunidin, which are classified

41

according to the number and position of hydroxyl group on the flavan nucleus

42

(Sinopoli, Calogero & Bartolotta, 2019). Anthocyanins can exist in a stable form of

43

astragalus salt cations under acidic conditions, while with the increase of pH

44

gradually, the anthocyanins form become unstable chalcone. 2

45

Stability of polyphenols is crucial for the nutrition of the food and is directly

46

associated with the chemical structures of polyphenols (Xiao & Högger, 2015). The

47

physicochemical conditions such as pH, temperature, light, oxygen availability, metal

48

ions, chemical modification, enzyme, proteins, nitrite salt, sulfur dioxide as well as

49

ascorbic acid must be taken into account for the polyphenols’ stability (Xiao, 2018;

50

Cao et al., 2020). Our group's previous experiments optimized the extraction and

51

purification of anthocyanins in raspberry, and found that cyanidin 3-O-glucoside

52

(C3G) showed anti-diabetic and anti-obesity activities. However, C3G is susceptible

53

to the surrounding environment, such as temperature, pH, light intensity, and metal

54

ions, which greatly reduce its bioactivity and nutrition. Therefore, improving the

55

stability of anthocyanins is a current technical problem that needs to be solved. Based

56

on the important influence of the low stability of C3G on daily use, this study intends

57

to use C3G as the research object and α-casein as the conjugate, spectroscopic

58

techniques are used to analyze the combination mode, the binding distance and the

59

structural changes; the stability changes in different environments after their binding

60

were studied to determine the degradation mode and kinetic parameters. We aimed to

61

explain the influence mechanism of C3G and α-casein on the stability of anthocyanin

62

after binding, and provide a scientific theoretical basis for the rational and effective

63

development of the anthocyanins resources and its application in the food industry.

64 65

2. Materials and Methods

66

2.1.

Materials and chemicals 3

67

Casein with a protein content of 86% (41% α-casein, 35% β-casein) was purchased

68

from Kerry Group (Beloit, WI, USA). α-Casein with purity of 70% and β-casein with

69

purity of 98%，and C3G purity of 97% were purchased from Sigma-Aldrich Chemical

70

Co. (St. Louis, MO, USA). All other chemicals were of analytical grade and were

71

purchased from Sinopharm Chemical Reagent Co., Ltd. (Shanghai, China).

72 73

2.2. Modified casein preparation

74

Modified casein (MCs) preparation was acted as following: first, casein (Cs) was

75

dissolved in 10 mM PBS buffer (pH 7.4) to obtain the solutions with the

76

concentrations of 1.0, 2.0, 3.0, 4.0 and 5.0 mg/mL. Then, the solution was heated in

77

40-120 °C for 30 min, 60 min, 90 min and 120 min. After that, the mixtures were

78

placed in a water bath at 50 °C and stirred continuously for 60 min, and then acidified

79

with HCl 1 M to obtain MCs. The mean zeta potential value of Cs and MCs (0.05%

80

w/w) used in this study were measured by the Zetasizer Nano series from Malvern

81

Instruments Ltd (Worcs, UK). The data was analyzed using the Zetasizer Nano v3.30

82

software. The average value was taken from three readings and all measurements

83

were performed three times.

84 85

2.2. MCs-C3G preparation

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MCs-C3G was prepared following previous study with minor modification (He et al.,

87

2016). To ensure complete solubilization of powders, all dispersions were first stirred

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at 50 °C for 1 h using a magnetic stirrer and then kept at 4 °C for 24 h. The MCs-C3G 4

89

mixture was prepared with 1 mg/mL MCs and 100 μM C3G in PBS (pH 7.0). Final

90

sample powder was obtained by freeze-drying.

91 92

2.3. Transmission electron microscopy (TEM) analysis

93

The nanosphere aggregates was observed by using a HT 7700 transmission electron

94

microscopy (Tokyo, Japan) according to the method of McMahon, Du, McManus,

95

and Larsen (2009) with modifications. Dried MCs-C3G samples were diluted 10-fold

96

with ultra-pure water. The diluted sample and ammonium molybdate solution (2

97

g/100 mL) (1:1) were mixed and left for 3 min at room temperature. A drop of this

98

solution was placed on a copper mesh for 5 min before the excess liquid was drawn

99

off using filter papers. The mesh was examined using a TEM at an operating voltage

100

of 200 KV.

101 102

2.4. FTIR spectroscopic measurement

103

FTIR spectra were recorded on a Bruker Vertex 70 FTIR spectrometer (Beijing,

104

China). Sample powders were blended with KBr at a mass ratio of 1:100 and pressed

105

into a tablet for FTIR analysis. Interferograms were obtained at the spectral range of

106

4000-400 cm-1 with a resolution of 2 cm-1 and 32 scans. Additionally, PeakFit v4.12

107

software was used to separate peaks in the FTIR spectrogram to obtain peak area of

108

each absorption peak.

109 110

2.5. Fluorescence spectroscopy 5

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Fluorescence spectroscopy was recorded on a Hitachi F-4600 Spectrometer (Tokyo,

112

Japan). The final concentration of MCs in each mixture was 1 mg/mL, and the

113

concentrations of C3G in the mixtures were 0, 10, 20, 30, 40, 50 and 60 μM. The

114

mixture solutions were determined by scanning emission wavelengths from 300 to

115

400 nm, with excitation wavelength of 280 nm at 293, 303 and 313 K to obtain the

116

intrinsic fluorescence spectroscopy of MCs. The excitation and emission slit widths

117

were 5.0 nm.

118 119

2.6 Data processing

120

In order to further understand the binding mechanism for MCs-C3G, the fluorescence

121

data were performed using the Stern-Volmer equation:

122

F0  1  K SV cq  1  K q 0C q F

(1)

123

where F0 and F are the fluorescence intensities in the absence and presence of

124

quencher, respectively. Kq is the bimolecular quenching constant, KSV is the

125

Stern-Volmer dynamic quenching constant, cq is the concentration of the quencher

126

and τ0 is the average lifetime of the molecule without any quencher [τ0 =10−8 s]. Ksv

127

and Kq are determined from the slope of the regression curves of F0/F against cq. The

128

quenching mechanism is divided into static quenching and dynamic quenching. When

129

Kq calculated according to Eq. (1) was much higher than the limiting diffusion rate

130

constant of the biomolecules (2×1010 M-1 s-1), indicated that static, and not dynamic

131

quenching was the main quenching mechanism between MCs and C3G.

132

For the static quenching mechanism, the binding constant (KS) of the complexes 6

133

and the binding sites numbers (n) were calculated by using the double logarithmic

134

Stern-Volmer equation (Eq. (2)).

135

log

136

The non-covalent forces of protein-ligand binding were calculated by the

137

thermodynamic parameters calculated from the following equations (Eqs. (3)-(5)).

138

 G  1 H  d   d   T  T 

139

G   RT ln K s

140

G  H  TS

141

Where  H is the enthalpy change, S is the entropy change and G is the free energy

142

change, R is the gas constant (8.314 J/mol K), T is the absolute temperature (K), and

143

KS is the binding constant at the corresponding temperature.

F0  F  log K s  n log cq F

(2)

(3) (4) (5)

144 145

2.7. Thermal, oxidation, photo and storage stability

146

The MCs-C3G mixtures and their corresponding MCs samples were subjected to

147

thermal, oxidation, photo and storage stability by following previous study (He et al.,

148

2016). The thermal stability test was performed by heating the samples in 10 mL

149

tubes wrapped in a water bath for 30 °C, 60 °C, 90 °C with 30 min, and then rapidly

150

cooled down for further analysis. The oxidation stability test was carried out by

151

addition of H2O2 into the samples at a final concentration of 0.5 %, 1%, 1.5% and

152

oxidizing for 1 h at room temperature in the dark. The photo stability test was

153

measured by illuminating the samples in 10 mL transparent tubes for 6 h, 18 h, 30 h at 7

154

room temperature in YZ18RR fluorescent lamps (Osram Co., Foshang, China). The

155

storage stability test was determined by placing in brown tubes for 15 days at -4 °C in

156

the dark. During the storage period, the content was analyzed (Lee, Durst, &

157

Wrolstad, 2005). The method based on the structural change of the C3G chromophore

158

between pH 1.0 and 4.5, calculated as follows:

159

A  A 530 nm  A 700 nm  pH 1.0  A 530 nm  A 700 nm  pH 4.5

160

TAC (mg/L) 

161

where TAC is the total anthocyanins contents (mg/L); MW (the molecular

162

weight)=449.2 g/mol; DF is the dilution factor; ε (molar extinction coefficient) =

163

26900; b is the path length in cm.

A  MW  DF  103  b

164 165

2.8. Statistical analysis

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All experiments were repeated at least three times. Data were expressed as the mean

167

± the standard deviation (SD). Significant differences (p < 0.05) were identified by

168

the least significant difference procedure between the means.

169 170

3. Results and discussion

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3.1 MCs structure

172

The intermolecular aggregation was generated through the hydrophobic interaction to

173

form unstable nanoparticles (Vemula, Li & John, 2006). As shown in Fig. 1, when the

174

concentration of casein is more than 2 mg/mL, casein will start to form polymers with 8

175

the increased particle size. The optimum formulation of MCs was 2 mg/mL casein at

176

80 °C for 30 min (Fig. 1) with the particle size of 110±0.31 nm and zeta potential of

177

-8.83±0.52 mV. When the pH of casein solution approached to the isoelectric point,

178

the protonation of amino acids on the protein led to enhance hydrogen and ionic bond

179

in the process of casein micelle formation (Ding, Huang, Cai & Wang, 2019). The

180

special interaction of π electrons provided by amino acid residues such as

181

phenylalanine, tryptophan, and tyrosine with cations provided by protonation of side

182

chains of amino acid residues could also result in a smaller particle size (Gallivan &

183

Dougherty, 2000). Meanwhile, the reduction of electrostatic repulsion interaction led

184

to the reduction of intermolecular distance, and the micellar structure became more

185

compact, which was manifested as the reduction of particle size.

186 187

3.2 Analysis of transmission electron microscopic (TEM) in the presence of C3G

188

As shown in Fig. 2, the TEM results clearly indicated the acidification and thermal

189

treatment cause the change in the structural features and associated function of caseins

190

(Fig. 2A, B). When C3G added to MCs solution, a thin coated layer covered upon the

191

interface (Fig. 2C), indicating the core-shell structure consequently formed. Caseins

192

underwent a series of physical and chemical alterations by the guidance of acid-heat

193

treatment, and made the C3G and MCs bind more closely by the ultrasonic dispersion

194

and shearing effect. It was supposed that the lighter spot (Fig. 2D) in the center of

195

MCs-C3G nanocomplexe was C3G core, which was in agreement with published

196

results (Chitkara and Kumar, 2013; Fang et al., 2014). It was further confirmed that 9

197

the encapsulation of C3G with MCs and the formation of core–shell nano-complexes.

198

The changes of nanoparticles size are in agreement with the findings from casein

199

modification studies, which casein tends to shrink in acidic solution and swell in

200

alkaline solution (Liu & Guo, 2008).

201 202

3.3 FTIR spectroscopy of MCs-C3G

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FTIR spectroscopy is an effective method to determine the secondary structure of

204

caseins. Both intensity variations and spectral shifting for the protein amide I band at

205

1600–1700 cm-1 (C=O stretch) and the amide II band, which occurs in the region

206

<1548 cm-1 (C–N stretching coupled with N–H bending), have been widely used upon

207

polyphenol interaction and are related to the secondary structure of the proteins (Peng

208

et al., 2015; Zhang, Wright, & Zhong, 2013). As shown in Fig. 3A, the peak position

209

of amide I moved from 1656.63 to 1653.47 cm-1 and that of amide II moved from

210

1538.17 to 1543.05 cm-1 in the MCs IR spectrum after interaction with C3G,

211

respectively. Changes of amide I and II bands were due to C3G binding to the caseins

212

C=O, C–N and N–H groups and modified casein via hydrogen bonding and

213

hydrophobic attraction. In addition, the intensities of the amide I of casein decreased

214

after binding with C3G, indicating that the α-helical content in the casein structure

215

was reduced. A peak position of amide A moved from 3411.2 to 3408.1 cm-1 in the

216

MCs and MCs-C3G, the shifting of the amide A band at 3300-3400 cm-1 (N–H

217

stretching mode) could be the additional evidence on caseins structure changes (Qi,

218

Ren, Xiao, & Tomasula, 2015). 10

219

A quantitative analysis of the caseins secondary structure for the MCs and MCs-C3G

220

has been carried out and the results are shown in Fig. 3C and 3D. The MCs has 18%

221

α-helix, 28.3% β-sheet, 36.5% turn structure and random 17.2% coil. The MCs-C3G

222

has 15.9% α-helix, 24.0% β-sheet, 44.9% turn structure and random 15.2% coil.

223

These results are consistent with spectroscopic study of caseins previously reported

224

(Menikh & Fragata, 1994). Upon the interaction, the α-helix, β-sheet and random

225

decreased, whilst turn structure increased in the MCs-C3G complexes, which are

226

indicative of larger perturbations of caseins secondary structure by C3G. The changes

227

of the caseins secondary structure will be discussed with fluorescence data further on.

228 229

3.4 Fluorescence spectroscopy of MCs-C3G

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Figure 3B showed the fluorescence emission spectra of MCs in the presence of C3G

231

(0–60 μM) with an excitation wavelength of 280 nm. The fluorescence intensities of

232

caseins decreased with the increasing concentration of C3G, which is ascribed to the

233

quenching effect of C3G. The quenching efficiency of 60 μM C3G on MCs

234

fluorescence was 66.7%. The λmax of MCs appeared a blue shift with higher C3G

235

concentrations. This indicated that the polarity of microenvironment around the Trp

236

and Tyr residues in modified caseins had increased and the hydrophobicity had

237

decreased after the addition of C3G. In addition, the results revealed that modified

238

caseins conformations changes were ascribed to binding with C3G (Chen, Xie, Jiang,

239

& Yao, 2008).

240 11

241

3.5 The mechanism of encapsulation

242

The quenching parameters of caseins with different concentrations of C3G at 293, 303

243

and 313 K are shown in Figure 4 and Table 1. The values of KSV were Kq values were

244

all much higher than the dynamic quenching constant 2×1010 M-1 s-1, which indicated

245

that C3G could quench the fluorescence of MCs via the static quenching process

246

predominantly caused by the formation of complex. The Ks of MCs bound with C3G

247

fluorescence quenched at 293 K, 303 K, 313 K were all in the order of 105, with the

248

values of 2.54, 3.03, 1.04, respectively, which confirmed the strong binding affinity

249

between C3G and MCs. Additionally, all of the values of n were approximately 1,

250

suggesting there was around one binding site in the MCs for C3G and the static

251

complex was formed with a molar ratio of about 1:1. As shown in the Table 1, G

252

values were all negative, which revealed that the binding process of MCs with C3G

253

was spontaneous.  H < 0 and S < 0 indicated that the Van der Waals forces or

254

hydrogen binding were the dominant binding force (Xiao et al., 2007). However, the

255

result is different from the findings of He, Xu, Zeng, Qin, & Chen, (2016) that

256

showed the quenching parameters of caseins were decreased with increasing

257

temperature, possibly due to the structural difference of the phenolic ligands.

258 259

3.6 Stability of C3G as influenced by complexing with MCs

260

Color and anthocyanin content are the two important quality traits for natural

261

anthocyanins pigment products. The stability of natural anthocyanin pigments can be

262

evaluated by measuring the changes of color and anthocyanin content in the 12

263

accelerated tests. The effects of different concentrations of casein on the thermal,

264

oxidation, and photo stability of the C3G solution at pH 6.3 are shown in Table 2.

265

Caseins could increase the thermal stability of C3G, oxidation and illumination

266

treatment dramatically. For instance, C3G was significantly affected by heating

267

treatments at 60 °C for 30 min; contrastingly, desirable protective effect of MCs on

268

C3G was found. Nevertheless, when the heating temperature was set at 90°C, the

269

stabilities of C3G and MCs-C3G declined sharply, while the MCs played an

270

important role in protecting C3G from heat destruction. In addition, it can be found

271

that more than half C3G degraded with illuminating for 30 min. After adding 0.1

272

mg/mL MCs, C3G degradation in the PBS solution at pH 6.3 induced by thermal

273

treatment (30-90 °C /2 h), oxidation (0.5-1.5% H2O2/1 h) and photo illumination

274

(6-30 h). The C3G in the presence of MCs had significantly (p < 0.05) higher contents

275

than the C3G samples without MCs after the stability testing, which indicated that the

276

degradation of C3G alone was greater than that of the samples with MCs. C3G

277

degradation probably because the pyrylium ring of anthocyanin opened and produced

278

a chalcone structure via hydrolysis of the carbon atom at position C2 position

279

(Norman, Bartczak, Zdarta, Ehrlich, & Jesionowski, 2016). The caseins can be used

280

as a natural nano-delivery vehicle and interacted with C3G via hydrogen bonding and

281

hydrophobic reaction to form complexes, thereby effectively protecting C3G from

282

degradation and improving their thermal, oxidation photo and storage stability.

283 284

4. Conclusions 13

285

In summary, the optimal modification for caseins were performed at the pH value of

286

5.5 after heated at 80 °C for 30 min. The spectroscopic analyses showed that MCs

287

bound with C3G and formed complexes via hydrophobic interactions. MCs indicated

288

stronger binding affinity toward C3G. Binding of C3G caused different alterations of

289

the secondary structures of the MCs, with a decrease in α-helix, turn random, coil

290

structure and an increase in β-sheet. The addition of casein significantly (p < 0.05)

291

prevented the thermal (90 °C/30 min), oxidation (15% H2O2 / 1 h), photo (30 h)

292

degradation and storage stability of C3G. These results may be helpful in expanding

293

the protection mechanism of C3G and caseins as natural embedding medium used

294

with small molecular substances.

295 296

Acknowledgments

297

This work is supported by the National Natural Science Foundation of China

298

(NSFC, Grant No. 31801459 and 31701520), China Postdoctoral Science Foundation

299

Funded Project (No. 2018M642551), the Funds for Distinguished Young Scientists

300

(Grant No. kxjq17012) at Fujian agriculture and forestry university of China.

301 302 303

Conflict of interest The authors declare no conflict of interest

304 305 306

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358

Anthocyanin dye conjugated with Hippospongia communis marine demosponge

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skeleton and its antiradical activity. Dyes and Pigments, 134, 541-552.

360

Peng, X., Wang, X., Qi, W., Huang, R., Su, R., & He, Z. (2015). Deciphering the

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binding patterns and conformation changes upon the bovine serum albumin–

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rosmarinic acid complex. Food & Function, 6(8), 2712-2726.

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Pillai, S. S., Yukawa, H., Onoshima, D., Biju, V., & Baba, Y. (2015).

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Fluorescence Quenching of CdSe/ZnS Quantum Dots by Using Black Hole Quencher

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Qi, P. X., Ren, D., Xiao, Y., & Tomasula, P. M. (2015). Effect of

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homogenization and pasteurization on the structure and stability of whey protein in

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milk. Journal of Dairy Science, 98(5), 2884-2897.

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Tang, L., Li, S., Bi, H., & Gao, X. (2016). Interaction of cyanidin-3-O-glucoside with three proteins. Food Chemistry, 196, 550-559. Tang, L., Li, S., Bi, H., & Gao, X. (2016). Interaction of cyanidin-3-O-glucoside 17

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static versus dynamic quenching processes. Photochemistry and Photobiology, 65(1),

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Xiao J.B., Högger P. (2015). Stability of dietary polyphenols under the cell

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389

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391 392 393 394 18

395 396

Figure legends

397

Figure 1. Particle size and zeta-potential of casein at the different concentration (A)

398

(pH=6.5). Effects of heating temperature (B) on the particle size and

399

zeta-potential of casein for heating 30min, and different heating time (C) at

400

80 °C ( 2 mg/mL casein concentration at pH 5.5).

401

Figure 2. TEM images of native Cs (A) and MCs (B) showing the caseins structure

402

changes induced by acidification and thermal treatment. The nanoparticle

403

changes of C3G were shown the significant changes with MCs (C, D).

404

Figure 3. FTIR spectra of native Cs and MCs powder in the absence and presence of

405

C3G for heating 80 °C with 30 min at pH 5.5 (A); Fluorescence emission

406

spectra of modified caseins at excitation wavelength 280 nm in presence of

407

C3G (0, 10, 20, 30, 40, 50, 60 μmol/L) (1–7) (B); second derivative resolution

408

enhancement and curve-fitted amide I region (1700–1600 cm -1) for MCs (C)

409

and MCs-C3G (D).

410

Figure 4. The Stern-Volmer curves of C3G (A) at 297K, 317K and 337 K. The double

411

logarithm regression curve of log [(F0-F)/F] versus log [cq] of

412

Cyanidin-3-o-glucoside (B) at 297 K, 317 K and 337K.; the effect of storage

413

stability on the C3G and MCs-C3G that kept away from light at -4°C after

414

15days (C).

415 416 19

417 418 419 420

Table 1. The quenching constants (KSV), bimolecular quenching constant (Kq), binding constants (KS), binding sites numbers (n) and thermodynamic parameters for C3G binding to caseins at 293, 303 and 313 K. 293

T(K) 303

313

KSV(×104 M-1)

2.95±0.01

2.69±0.04

2.47±0.02

Kq (×1012 M-1·S-1)

2.95±0.01

2.69±0.04

2.47±0.02

KS (×105 M-1)

2.54±0.13

3.03±0.10

1.04±0.12

n △H (kJ·mol-1)

1.21±0.00

1.23±0.00 -33.51

1.14±0.01

△G (kJ·mol-1)

-30.32

-31.80

-30.06

△S (J·mol-1·K-1)

-10.89

-5.65

-11.01

Parameters

421 422 423 424 425 426 427 428 429 430 431 432 433 434 435 436 437 438 20

Table 2. Effect of casein on stability of C3G at pH 6.3 after heat, oxidation and illumination treatment.

MCs

C3G (μM)

Temperature

Photo illuminate

H2O2

Untreated 30°C

60°C

90°C

6h

18h

30h

0.5%

1.0%

1.5%

100

11.66±0.06a

10.87±0.22a

5.23±0.1b

0.24±0.02c

9.76±0.3b

6.27±0.29c

3.34±0.12d

0.55±0.02b

0.33±0.07bc

0.17±0.03c

200

22.1±0.89a

21.59±0.15a

12.08±0.08b

0.27±0.18c

19.01±0.08a

12.77±0.28b

8.13±0.11c

2.66±0.13b

1.68±0.4c

0.65±0.04d

300

32.28±0.89a

31.01±0.37a

17.18±0.42b

0.34±0.15c

27.76±0.58a

18.99±0.3b

11.66±0.66c

4.54±0.1b

2.8±0.05c

1.51±0.14d

400

42.84±0.26a

41.19±1.27a

19.36±0.33b

0.37±0.24c

36.23±0.59b

25.04±0.24c

17.29±0.16d

6.48±0.04b

4.37±0.82b

2.62±0.22c

100

9.26±0.25a

8.45±0.39a

7.66±0.44a

2.67±0.1b

7.93±0.48a

7.33±0.63a

5.39±0.52b

0.32±0.05b

0.24±0.02b

0.15±0.02b

200

20.48±0.78a

18.86±1.42ab

17.8±1.33ab

3.37±0.46b

17.66±0.66a

16.77±0.46a

12.25±0.89b

2.62±0.07b

1.11±0.13bc

0.73±0.08c

300

31.94±0.78a

28.82±1.51a

26.62±1.6a

9.43±2.3b

27.4±1.14a

26.32±2.13a

19.83±0.57a

7.76±0.66b

3.01±0.16c

1.76±0.11d

400

44.72±0.39a

38.96±1.36a

36.83±1.45a

9.61±1.39b

37.46±2.6a

35.39±1.5ab

27.48±1.02b

11.97±0.25b

5.62±1.05bc

3.89±0.05c

Non

1 mg/mL

Values are expressed as the mean ± standard deviation. Different letters in the same column for each treatment indicate significant differences (p < 0.05).

21

Fig. 1.

0

116

-2

150

-2

125

145

-4

114

-4

112

-6

110

-8

108

-10

106 104

-12 40

60

80

100

120

Temperature（℃） particle size zeta-potential

particle size（d.nm）

155

zeta-potential（mV）

0

particle size（d.nm）

118

130

120

-6

135

-8

130

-10

100

-12

95

125 1

2

3

4

5

Concentration（μM） particle size zata-potential

22

-2 -4

115

140

0

-6

110

-8

105

zeta-potential（mV）

C

B zeta-potential（mV）

particle size（d.nm）

A

-10 -12 0

30

60

Time（min） particle size

90

120

zeta-potential

Fig. 2. A

B

C

D

23

Fig. 3. 100

A

2000

% Transmittance

100

80

MCs MCs-C3G 1538.17

1656.63

60

3408.10

1543.05

80

1538.17

2000

3000

7 1000

500

0

4000

300

320

Wavenumbers（cm )

1656.63

3408.10

340

360

380

Wavelength（nm）

3411.20

1653.47

0.15

0.15 α-Helix β-Sheet Turn 4000 Random coil

C 1000

1500

-1

60 1543.05

3411.20

1653.47

1000

B 1

Fluorescence intensity

% Transmittance

MCs MCs-C3G

2000

3000

MCs R2 =0.9994 -1) Wavenumbers（cm 0.10

18.0% 28.3% 36.5% 17.2%

0.10

0.05

0.00 1600

α-Helix β-Sheet Turn Random coil

D MCs-C3G R2 =0.9994

15.9% 24.0% 44.9% 15.2%

0.05

1620

1640

1660

1680

0.00 1600

1700

Wavelength（cm-1）

1620

1640

1660

Wavelength（cm-1）

24

1680

1700

Fig. 4. Highlights

A

3.50

-

MCs

bound with

F0 /F

3.00

C3G and formed

2.50

complexes

2.00

293K

via

303K

1.50

313K

hydrophobic

1.00 0

80

interactions -

Casein

significantly

B

-0.8

Log[(F0 -F)/F]

20 40 60 C3G concentration (10 -6 M)

prevented the

-0.6

thermal,

-0.4

oxidation,

-0.2

photo degradation

293K

0

303K

and storage

313K

0.2

stability of

0.4 -4

-4.2

-4.4 -4.6 -4.8 Log[C3G](M)

-5

-5.2

C3G. -

C

Binding

of C3G caused alterations of the secondary structures of the MCs.

25

CRediT author statement Yongzhong Ouyang: Conceptualization, Methodology, Software Lei Chen: Writing- Original draft preparation Liu Qian: Investigation Xiujun Lin: Investigation, Validation Xiaoyun Fan: Investigation Hui Teng: Data curation, Supervision Hui Cao: Reviewing and Editing,

26