Physicochemical and functional properties of 11S globulin from chan (Hyptis suaveolens L. poit) seeds

Physicochemical and functional properties of 11S globulin from chan (Hyptis suaveolens L. poit) seeds

Accepted Manuscript Physicochemical and functional properties of 11S globulin from chan (Hyptis suaveolens L. poit) seeds Luis F. De la Cruz-Torres, ...

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Accepted Manuscript Physicochemical and functional properties of 11S globulin from chan (Hyptis suaveolens L. poit) seeds

Luis F. De la Cruz-Torres, Jaime D. Pérez-Martínez, Mayra Sánchez-Becerril, Jorge F. Toro-Vázquez, N. Alejandra Mancilla-Margalli, Juan A. Osuna-Castro, C.I. VillaVelázquezMendoza PII:

S0733-5210(16)30483-0

DOI:

10.1016/j.jcs.2017.06.017

Reference:

YJCRS 2390

To appear in:

Journal of Cereal Science

Received Date:

25 November 2016

Revised Date:

08 June 2017

Accepted Date:

27 June 2017

Please cite this article as: Luis F. De la Cruz-Torres, Jaime D. Pérez-Martínez, Mayra SánchezBecerril, Jorge F. Toro-Vázquez, N. Alejandra Mancilla-Margalli, Juan A. Osuna-Castro, C.I. VillaVelázquez-Mendoza, Physicochemical and functional properties of 11S globulin from chan ( Hyptis suaveolens L. poit) seeds, Journal of Cereal Science (2017), doi: 10.1016/j.jcs.2017.06.017

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ACCEPTED MANUSCRIPT

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Physicochemical and functional properties of 11S globulin from chan (Hyptis

2

suaveolens L. poit) seeds

3

Luis F. De la Cruz-Torresa, Jaime D. Pérez-Martínezb, Mayra Sánchez-Becerrilb,

4

Jorge F. Toro-Vázquezb, N. Alejandra Mancilla-Margallic, Juan A. Osuna-Castroa,*,

5

C.I. VillaVelázquez-Mendozad

6 7 8 9 10 11 12 13

aFacultad

de Ciencias Biológicas y Agropecuarias, Universidad de Colima, km 40

Autopista Colima-Manzanillo, C.P. 28100, Tecomán, Colima, México bFacultad

de Ciencias Químicas-CIEP, Universidad Autónoma de San Luis Potosí,

Manuel Nava 6, Zona Universitaria, C.P. 28210, San Luis Potosí, S. L. P., México cTecnológico

Nacional de México, Instituto Tecnológico de Tlajomulco, Carr. a San

Miguel Cuyutlán km 10, Tlajomulco de Zúñiga, Jalisco C.P. 45650, México dFacultad

de Ingeniería Civil, Universidad de Colima, Carr. Colima-Coquimatlán km 9, C.P. 28400, Coquimatlán, Colima, México

14

*Corresponding Author:

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Email: [email protected]

16 17 18

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Abstract

21

The 11S globulin is one of the most abundant and important storage proteins of the

22

chan grain (Hs11S). For this reason, we investigated its physicochemical and

23

functional properties (surface tension, zeta potential and thermo-mechanics

24

analysis). A decrement in surface tension was registered with an increment of

25

Hs11S concentration, such results suggested a critical micelle concentration

26

(CMC) at 0.6 mg/mL and a surface activity until 55.5 mN/m. The Hs11S solutions

27

showed isoelectric points (pI) with a clear NaCl influence (i.e., without NaCl pI =

28

3.5, at 0.05 M NaCl pI = 3, at 0.5 M NaCl pI = 2.5) and zeta potential dependent

29

upon the pH. Differential scanning calorimetry and rheology studies revealed the

30

onset for the heat-induced gelation of Hs11S which occurred around 74‒76 °C,

31

developing strong gels with an elasticity of ~103 Pa, a denaturation temperature of

32

94.1 °C and an enthalpy of 266.9 kJ/mol. Consequently, the Hs11S thermal

33

denaturation is not a cooperative process. According to the dynamic light scattering

34

(DLS) data as a function of temperature, the Hs11S organizes in oligomeric forms

35

of trimer, tetramer, hexamer, octamer and dodecamer as well as aggregates (Rh

36

higher than 100 nm).

37

Keywords

38

11S Globulin, Functional properties, Heat-induced gelation, Thermodynamic

39

properties

40

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Introduction

42

Globulins (salt-soluble storage proteins) are the main Osborne protein fraction in

43

legumes and some cereals such as oats and rice, constituting around 70 ‒ 80 % of

44

the total protein (Boulter and Croy, 1997). The 11S globulins (legumins) are

45

hexameric proteins of 300 ‒ 450 kDa, composed by six non-covalently bonded

46

subunits of approximately 50 ‒ 70 kDa, with an acidic polypeptide and a basic

47

polypeptide of about 30 ‒ 40 kDa and ~20 kDa, respectively, and linked by

48

disulfide bonds (Boulter and Croy, 1997).

49

The 11S globulins from different sources such as amaranth, sunflower, soybean

50

and mungbean have been purified and physicochemical and functionally

51

characterized for their use in the food industry for the development of traditional

52

and new food products (González-Pérez and Vereijken, 2007; Kimura et al., 2008;

53

Tang and Sun, 2010; Carrazco-Peña et al., 2013). On the other hand, the

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population growth and the emerging dietary preferences (e.g., vegans,

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vegetarians) demand for novel food ingredients and plant-based products with

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lower cost; therefore 11S globulins from non-conventional food crops are attractive

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options (Jarpa-Parra et al., 2015).

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Chan (Hyptis suaveolens L. Poit) is a dicotyledonous plant from the Lamiaceae

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family, considered as a pseudocereal and its seeds were cultivated and highly

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appreciated since pre-Colombian cultures due to its high nutritional and medicinal

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characteristics (Aguirre et al., 2004). Hyptis suaveolens has been used as food and

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traditional medicine in America, Asia and Africa (Aguirre et al., 2012). Chan seeds

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contain 13.9 % of protein on dry weight being globulins (39 %) the major fraction.

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Bojórquez-Velázquez et al. (2016) reported a simple purification procedure and

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biochemical characterization of 11S globulin from chan. This is a hexameric protein

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of 300 kDa, composed by four different monomers between 53.5 ‒ 49.5 kDa with

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the characteristic disulfide bond linking the acidic and basic polypeptides.

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However, required information about the physicochemical and functional properties

69

of Hs11S in order to use in foods remains unknown.

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Within this context, the objective of this investigation is to evaluate the following

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physicochemical and functional properties of Hs11S: surface tension and zeta

72

potential as a function of pH and NaCl concentration, thermo-mechanical

73

properties and aggregation/de-aggregation process as a function of temperature

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and ionic strength.

75 76

Materials and Methods

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2.1 Purification of Hs11S

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2.1.1 Protein extraction

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Seeds were purchased from a local market at Colima, Mexico. Fractionation of

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globulins was carried out according to Bojórquez-Velázquez et al. (2016). The

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pellet obtained after albumin extraction was suspended in buffer A (0.1 M Tris-HCl,

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10 mM EDTA, 1.7 M NaCl, pH 7.5) 1:10 (w/v), stirred 2 h at 4 °C, and centrifuged

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30 min at 13,800 g. Supernatant (crude globulins) was stored at -20 ºC.

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2.1.2 Hs11S purification

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10 mL of crude globulins were precipitated at 60 % of ammonium sulphate

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saturation,

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chromatography (SEC) using a Sephacryl S-300 HR column (GE Healthcare

88

Bioscience, NJ, USA). Proteins were eluted with buffer A at 1 mL/min flow rate.

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Fractions of 2.5 mL were analyzed by absorbance at 280 nm, dialyzed, freeze-

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dried, resolved in 12 % SDS-PAGE (Laemmli, 1970) and then stored at 4 °C for

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further analysis.

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2.1.4 Protein measurement

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The protein content was determined by the Bradford method (Bradford, 1976)

94

using bovine serum albumin as standard.

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2.2 Functional characterization Hs11S

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2.2.1 Surface activity and CMC

97

A DuNouy tensiometer (CSC Scientific Company, INC USA) was used to measure

98

the surface tension of Hs11S solutions by the method of Tomczyńska-Mleko et al.

99

(2014) with some modifications. Protein was dissolved in HPLC-degree water at a

100

concentration range from 0.1 to 1 mg/mL (0.1, 0.2, 0.3, 0.4, 0.6, 0.8 and 1.0

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mg/mL). All measurements were carried out at 25 °C. The CMC of Hs11S was

resuspended

in

buffer

A

5

and

subjected

to

size-exclusion

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determined from the graph of interfacial tension vs. natural logarithm of protein

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concentration.

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2.2.2 Zeta potential and isoelectric point

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The zeta potential (ζ-potential) of Hs11S was measured at 25 °C as a function of

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pH using a Zetasizer Nano ZS (Malvern Instrument Ltd., Malvern, Worcestershire,

107

UK) according to the modified method of Withana-Gamage et al. (2013). The pH

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adjustments were performed with 0.5 M and 0.005 M HCl and 0.1 NaOH aqueous

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solutions using an MPT-2 autotitrator (Malvern Instruments. Worcestershire,

110

Ukraine). Protein dispersions of 0.02 % in deionized water were prepared. Three

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different treatments with NaCl were tested (0.05 M, 0.5 M and without NaCl). The

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pH value of zero ζ-potential was considered as the pI of the protein.

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2.3 Hs11S physicochemical characterization

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2.3.1 Heat-induced gelation by oscillatory rheology

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The gelation of Hs11S was evaluated by oscillatory rheology following the method

116

proposed by Shevkani et al. (2015). Measurements were determined in a MCR 302

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rheometer (Anton Paar, Stuttgart, Germany) with plate-plate measuring geometry

118

(25 mm in diameter, PP25/TG, Anton-Paar, Germany) equipped with the TruGapTM

119

system. The temperature control was performed with two peltier systems located at

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the base of the lower plate and a peltier hood covering the measuring geometry (C-

121

PDT200, Anton-Paar, Germany). The Hs11S solutions were prepared at 20 %

122

(w/v) in buffer B (35 mM KH2PO4-K2HPO4, 0.1 M NaCl, pH 7.6). Samples were

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heated at 1 °C/min from 20 to 90 °C, held at 90 °C for 3 min and then cooled from

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90 to 20 °C (5 °C/min). To prevent sample dehydration, the edge of the plate was

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covered with low viscosity silicone. The elastic (G′) and loss (G″) moduli of the gel

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were obtained as function of temperature (Shevkani et al., 2015). A frequency

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sweep (1 ‒ 100 Hz) at constant strain of 0.002 % was performed on the gel

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subjected to the thermal treatment previously described. For each sample solution

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and the different stages of the test, measurements were done within the linear

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viscoelastic region (LVR). The instrument uses the Rheoplus/32 v3.61, Anton Paar

131

(MCR 302) software.

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2.3.2 Thermal characterization by differential scanning calorimetry (DSC)

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Thermal denaturalization of Hs11S was established by differential scanning

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calorimetry using a DSC discovery (TA Instruments, USA). Protein dispersion at 25

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% (w/v) in buffer C (35 mM KH2PO4-K2HPO4, pH 7.6) was prepared and 15 mg of

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mixture were weighed in T-ZeroTM pan, hermetically sealed and hydrated in the

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same buffer for 2 h prior to the test. The sample pan was loaded in the calorimeter

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and equilibrated for 5 min at 20 °C, heated from 20 to 150 °C at 5 °C/min. A sealed

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empty pan was used as a reference. The analysis of the thermograms was carried

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out according to Withana-Gamage et al. (2013) for the calculation of the

141

calorimetric van’t Hoff enthalpy change (ΔHvHTm) and the entropy change upon

142

(ΔSTm). The denaturation peak temperature (Tm), width at half peak height (ΔT1/2),

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maximum heat capacity at denaturation (Cpmax), denaturation enthalpy (ΔHexpTm)

144

and heat capacity change (ΔCpN→U) were computed with the DSC Discovery

145

instrument software (TRIOS Q111 C53 V.52 2002).

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2.3.4 Assembly capacity by dynamic light scattering (DLS)

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The effect of NaCl and temperature on Hs11S was studied measuring the

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hydrodynamic radius (Rh) (molecular size) by DLS using a zetasizer Nano-ZS

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(Malvern Instrument Ltd., Malvern, Worcestershire, UK) with a light source from

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633 nm He–Ne laser. Measurements were performed at a scattering angle of 173°.

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Protein dispersions at 0.2 mg/mL in buffer C with different NaCl concentrations (0.1

152

M, 0.4 M and without NaCl) were measured from 10 to 90 °C (sampling every 5

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°C).

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2.4 Statistical analysis

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Assembly capacity was carried out ten times each experiment, while surface

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tension and zeta potential experiments were conducted in quadruplicate and

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calorimetric properties in triplicate. The data were expressed as the mean ±

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standard error (SE). Gelation capacity was obtained in duplicate each experiment.

159 160

Results and discussion

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3.1 Hs11S purification and SDS-PAGE analysis

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Hs11S was purified by size-exclusion chromatography using a Sephacryl S-300.

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This protein was eluted from 40 until 62 fraction number (Fig. 1a), and its purity

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was corroborated by 12 % SDS-PAGE (Fig. 1b). In non-reducing conditions,

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Hs11S showed four bands with estimated molecular weight of 50 kDa; meanwhile,

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under reducing conditions, four acidic (α) subunits of around 32 kDa and four basic

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(β) subunits of approximately 20 kDa were shown. These data confirm the first

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report of the Hs11S purification (Bojórquez-Velázquez et al., 2016). The purified

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protein was used for the following analyses.

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3.2 Functional characterization of Hs11S

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3.2.1 Surface activity and CMC

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As shown in Figure 2a, the surface tension of Hs11S aqueous solutions decreased

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from 68 mN/m to 55.5 mN/m as protein concentration increased from 0.1 mg/mL to

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0.6 mg/mL. This behavior has also been reported at low protein concentration of

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whey protein isolates (Tomczyńska-Mleko et al., 2014) and seed storage proteins

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like a soybean 7S globulin (β-conglycinin), 11S globulin (glycinin) and 11S globulin

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from lentil (Pizones Ruiz-Henestrosa et al., 2014; Jarpa-Parra et al., 2015). The

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surface tension decrement with increasing protein concentration is due to the

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preferential accumulation of proteins at the air-water interface and the exposition of

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hydrophobic residues (Jarpa-Parra et al., 2015); therefore, the adsorption capacity

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is influenced by some intrinsic factors of the protein such as its molecular size,

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structure, hydrophobicity and solubility (Pizones Ruiz-Henestrosa et al., 2014).

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At Hs11S concentrations higher than 0.6 mg/mL the surface tension remained

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constant, since the system achieved the formation of a fully packed monolayer and

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no further accumulation of protein at the interface took place. Thus, the CMC for

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the Hs11S occurred at 0.6 mg/mL and it was considered the minimum protein

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concentration above which stable micelles are formed (Tomczyńska-Mleko et al.,

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2014). The surface tension can be affected in addition by extrinsic variables such

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as temperature, pH, ionic strength, surfactant concentration, and preheating of the

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sample (Tomczyńska-Mleko et al., 2014) therefore, the CMC might be affected

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equally.

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A CMC of 5 mg/mL in 11S globulin from lentil using the ring method (Jarpa-Parra

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et al., 2015) and in whey protein isolate has been reported (Tomczyńska-Mleko et

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al., 2014). Our results suggest that Hs11S could show higher emulsifying

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properties than 11S globulin from lentil and whey protein isolate.

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3.2.2 ζ-potential and isoelectric point of Hs11S

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The ζ-potential curve of Hs11S without NaCl exhibited a progressive increase of

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the ζ-potential from a negative (-34.5 mV) to a positive value (+18.7 mV) from pH

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10 to pH 2 (Fig. 2b). This behavior showed that zeta potential is pH dependent,

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typically reported for others 11S globulins from mungbean, pea and A. thaliana

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(cruciferin) (Tang and Sun, 2010; Klassen and Nickerson, 2012; Whitana-Gamage

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et al., 2013) and explained as changes in the electrostatic repulsion may be

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attributed at a gradual protonation of carboxyl groups and de-protonation of amino

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groups of the proteins when pH medium goes from alkaline to acidic values (Tang

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and Sun, 2011; Klassen and Nickerson, 2012). It is noteworthy the high potential

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stability exhibited for Hs11S in the pH range of 6.5 − 10, where the zeta potential is

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kept in a narrow range between -30.3 mV to -34 mV (considering -30 mV as the

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dividing value between stable and unstable colloidal systems) (Whitana-Gamage et

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al., 2013).

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Influence of NaCl on ζ-potential was observed. At both NaCl concentrations tested

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(0.05 M and 0.50 M), the stability in the colloidal system measured in protein

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solution by ζ-potential values were lower than those without salt in overall pH range

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from 2 to 10 (Fig. 2b). It may be attributed to chemical composition influencing the

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conductivity of the solutions and therefore the ζ-potential. The conformation of

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Hs11S in solution was influenced by the pH, which affects the extent of ionized

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residues available for the interaction and charge neutralization by H3O+, Na+ and

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Cl- ions (Salgin et al., 2012; Whitana-Gamage et al., 2013).

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The effect of NaCl on the pI of Hs11S solution is clearly shown in Fig. 2b. The

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Hs11S solution without NaCl has a pI around 3.5, while the presence of NaCl

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modified this value to 3 and was 2.5 when concentrations were 0.05 and 0.5 M,

221

respectively. These differences in the pI by addition of NaCl might be attributed to

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structural changes in the superficial properties which could modify the protein food

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functionality (Salgin et al., 2012).

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Witana-Gamage et al. (2013) reported similar pI for native cruciferin at pH of 3.8

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while the calculated with amino acid composition of the subunits differed greatly,

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indicating that theoretical values do not always agree with experimental values.

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3.3 Physicochemical characterization of Hs11S

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3.3.1 Gelation capacity

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The storage modulus (G’) values during heating of Hs11S dispersion are presented

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in Figure 3a, showing a progressive increase of G’ indicating the formation of a gel

231

network (Rao, 2007). The onset of Hs11S gelation occurred at 74 – 76 °C

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determined by extrapolation of the rapidly rising values of G’. Generally, the onset

233

temperatures for the main protein gels ranges from 65 to 80 °C (Chambal et al.,

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2014). Hs11S denaturation peak temperature was around 94 °C, moreover, onset

235

thermal denaturation is around 76 °C (Fig. 4). These data suggest detectable

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structural changes of Hs11S about 74 – 76 °C, finishing at 94 °C with thermal

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denaturation of Hs11S. During cooling, values of G’ and G” increased indicating

238

formation of gel network (Fig. 3b). The increase in moduli during cooling may be

239

attributed to reversible formation of hydrogen bonds and Van der Waals

240

interactions between protein molecules within the gel primary network (Shevkani et

241

al., 2015). Gel reinforcement during cooling had been observed in pea legumin,

242

cruciferin and soybean glycinin (O’Kane et al., 2004; Withana-Gamage et al.,

243

2015).

244

Magnitudes of G’ and G” are influenced by frequency, temperature and strain for a

245

specific food. The loss tangent (tan δ = G”/G’) is the ratio of the dissipated energy

246

to the stored energy per cycle of deformation and it plays important roles in the

247

rheology of structural gels (Rao, 2007). The tan δ values of Hs11S in the LVR

248

showed a value of 0.22 (Fig. 3c), indicating that G’ was always higher than G” over

249

the whole frequency interval tested. The tan δ values lesser than 1 (0.22 in our

250

case) are associated with the formation of strong gels (Rao, 2007; Carrazco-Peña

251

et al., 2013). Figure 3c shows G’ and G” values as a function of frequency sweep

252

(Hertz) in the LVR, where Hs11S showed G’ values from 843.3 to 1338 Pa.

253

Carrazco-Peña et al. (2013) reported gelation of amarantin with G’ values of ~5 Pa

12

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254

at 21.8 % protein solution in 35 mM potassium phosphate (pH 7.6). The gelation

255

profiles of Hs11S could be useful to improve the texture of many food products.

256

3.3.2 Thermodynamic properties

257

Heat treatment is one of the most important processes in food industry. The Tm can

258

reflect the temperature needed to get the disruption of hydrogen bonds and Van

259

der Waals interactions stabilizing the tertiary and quaternary conformations of

260

proteins (Kimura et al., 2008; Tang & Sun, 2011). As depicted in Table 1, Tm of

261

Hs11S was 94.1 ± 1 °C, exhibits high thermostability at low ionic strength (μ =

262

0.08) than others 11S globulins like fava bean, pea and glycinin, whose

263

denaturation temperatures vary from 81 ‒ 85ºC (Kimura et al., 2008). Moreover,

264

Hs11S shows an endothermic peak, indicating a transition of protein denaturation

265

with experimental enthalpy (∆HexpTm) of 44.49 ± 6 kJ/mol (Table 1). Likewise, the

266

entropy (∆STm) was obtained from ∆HexpTm and Tm values, being of 0.12 ± 0.01

267

kJ/mol•K. This result indicates a lower degree of disordered conformation for

268

thermal unfolding of Hs11S than other cruciferin variants (0.26 ‒ 0.47 kJ/mol•K)

269

reported by Whitana-Gamage et al. (2013).

270

Variations in heat flow occurring after denaturation for the purified proteins can be

271

defined in terms of specific heat capacity change (∆pN→U) (Oates and Ledward,

272

1991). This thermodynamic parameter shows positive values for β-conglycinin,

273

glycinin and cruciferins (Danilenko et al., 1985 ; Oates and Ledward, 1991;

274

Whitana-Gamage, et al., 2013). The ∆pN→U value for Hs11S was 0.17 ± 0.0

13

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275

kJ/mol•K, with a maximum heat capacity of denaturation (Cpmax) of 0.50 ± 0.13

276

kJ/mol•K, obtained at Tm (Table 1).

277

The van’t Hoff enthalpy is dependent on fractions of the native and denatured

278

forms of the proteins, and is associated with the temperature dependence on the

279

excess heat capacities (native and denatured) and enthalpies in simple two-state

280

transition (Privalov and Potekhin, 1986). The ΔHvHTm can be used to describe the

281

transition mode or cooperative unfolding of 11S globulins. Comparison of the

282

directly measured ΔHexpTm with ΔHvHTm provides information of a cooperative unit

283

during the denaturation process (Tandang et al., 2004). A ratio ΔHvHTm/ΔHexpTm > 1

284

indicates that each subunit works as a cooperative unit in the unfolding process as

285

well as formation of an oligomer, whereas ΔHvHTm/ΔHexpTm < 1 indicates the

286

presence

287

cooperativeness (Privalov and Potekhin, 1986; Tandang et al., 2004; Whitana-

288

Gamage et al., 2013). The ΔHvHTm calculated for Hs11S was 260.5 ± 31 kJ/mol

289

(Table 1). The ratio ΔHvHTm/ΔHexpTm determined was 0.18 ± 0.04 (Table 1). This

290

data was corroborated with the high width at half peak height (ΔT1/2, 15.32 ± 0.66

291

°C). A low ΔT1/2 value indicates a highly cooperative unfolding process, and high

292

ΔT1/2 refers a not cooperative process. Moreover, the ratio ΔHvHTm/ΔHexpTm is

293

different to ~1, therefore, each monomer of Hs11S is not considered as a

294

cooperative unit in the denaturation process, indicating existence of possible

295

folding intermediates during the unfolding process (Privalov and Potekhin, 1986;

296

Whitana-Gamage et al., 2013).

of

folding

intermediates

during

14

denaturation,

indicating

not

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297

The native cruciferin and glycinin have been reported as a cooperative unit in the

298

denaturation process (ΔHvHTm/ΔHexpTm > 1) (Danilenko et al., 1985, Whitana-

299

Gamage et al., 2013), whereas some cruciferins from mutant Arabidopsis line

300

(triple-knockout line, CRU-) and modified procruciferins expressed in E. coli

301

showed a not cooperative behavior reporting ratios ΔHvHTm/ΔHexpTm <1 (Tandang et

302

al., 2004; Whitana-Gamage et al., 2013).

303

3.3.3 Assembly capacity and aggregation/de-aggregation of Hs11S by DLS

304

During industrial processes, seed storage proteins have structural changes, and

305

they can be studied and understood throughout the association/dissociation,

306

assembly, and aggregation/de-aggregation analysis. The Hs11S assembly was

307

dependent on temperature and ionic strength at pH 7.6 (Fig. 5a, b and c). At low

308

ionic strength (Fig. 5a, without NaCl) Hs11S presented a Rh of 6.77 nm (280 kDa)

309

at temperatures of 30, 40, 45, 50 and 60 °C, where the hexameric structure form

310

was predominant. At 25 and 55 °C, Hs11S showed an Rh of 5.85 (208.4 kDa)

311

indicating tetrameric form, and was found as trimer (Rh 5.05, 157 kDa) and

312

dodecamer (Rh 9.08, 562.2 kDa) at 35 °C. At 0.1 M NaCl, Hs11S was observed in

313

two assemblies: trimeric and hexameric quaternary structures from 20 until 60 °C

314

(Fig. 5b), meanwhile, at 65 °C it was showed as a dodecamer. On the other hand,

315

Hs11S at 0.4 M NaCl has three oligomeric states: trimer (25, 35, 40 and 45 °C),

316

hexamer (20, 30, 50, 60 and 65 °C) and octamer at 55 °C (Rh 7.85, 390.4 kDa).

317

Hs11S assembly was dependent on temperature and ionic strength. Bojórquez-

318

Velázquez et al. (2016) reported trimeric, tetrameric, hexameric and dodecameric

15

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forms on Hs11S assembly by DLS studies at different pH values at a range from

320

20 – 30 °C.

321

On the other hand, higher ionic strength contributes to the hexameric assembly of

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the 11S form at 65 °C of our chan globulin (aggregates without NaCl, dodecamer

323

at 0.1 M NaCl, and hexamer at 0.4 M) showing greater stability with increment of

324

NaCl. Molina et al. (2004) studied the effect of NaCl and pH in the thermal stability

325

of helianthinin, showing hexameric form at µ = 0.5, but it converts to a 15S form

326

when the ionic strength falls below µ = 0.1, phenomena observed in Hs11S at 65

327

°C. As well, 7-8 (González-Pérez and Vereijken, 2007), which coincides with the

328

main Hs11S assemblies found in this work at pH 7.6.

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In overall tests, the particle size distribution also exhibited peaks with high

330

molecular weights, indicating an Hs11S aggregation (Rh higher than 100 nm) (Fig.

331

5a, b and c). The protein aggregation/de-aggregation phenomena is one of the

332

most important parameters for functional properties in protein-based foods;

333

moreover these conditions influence their rheological properties (Boulet et al.,

334

2000; Ruan et al., 2014).

335

At higher temperatures than 70 °C, an increase in the Rh of Hs11S in overall tests,

336

was detected as aggregation (Fig. 5a, b and c). Physicothermally, the onset

337

denaturation temperature of Hs11S detected by DSC measurements was 80 °C

338

(Fig. 4) and gelation point by rheological behavior was around 7 °C (Fig. 3a).

339

However, a DLS study is a sensitive technical with real-time measuring, which

340

detects slight changes in aggregation phenomena of Hs11S at lower temperatures

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than 75 °C that are not detectable in DSC and rheology measurements (Pizones

342

Ruiz-Henestrosa et al., 2012).

343

Some proteins as globulins from soybean are widely used in food applications as

344

an ingredient in the formation of heat-induced gels (Ruan et al., 2014). Therefore,

345

Hs11S could be proposed as an attractive ingredient for the food industry due to its

346

physicochemical

347

investigation.

and

functional

characteristics

17

reported

in

the

present

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349

Conclusions

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The functionality of Hs11S was characterized in addition to its physicothermal

351

properties. A decrement in surface tension was registered with increment of protein

352

concentration, showing a CMC at 0.6 mg/mL. Hs11S solutions showed ζ-potentials

353

and pIs with a clear NaCl and pH dependence. Also Hs11S presented a good heat

354

stability and high thermal denaturation. The onset for the heat-induced gelation of

355

Hs11S occurred around 74 – 76 °C, developing strong gels. Hs11S exhibited

356

assemblies in several oligomeric forms. Our results indicate that Hs11S might be

357

used as a potential heat-stable ingredient to improve the hardness in food systems.

358 359

Acknowledgements

360

We thank student Fabiola Blanco-García for technical support in DLS experiments.

361

We also thank Dr. Abel Moreno for the providing of zetasizer Nano-ZS used and

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technical support in the DLS experiments.

363 364

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TABLES

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Table 1. Physicothermal properties of Hs11S by DSC measurements*. Tm (ºC) Hs11S

464

ΔT1/2 (°C)

ΔSTm ΔCpN→U (kJ/mol•K) (kJ/mol•K)

94.10 ± 1.0 15.32 ± 0.66 0.12 ± 0.01 0.169 ± 0.0

* Heating from 20 to 150 °C, at flow rate 5 ºC/min.

465

23

Cpmax (kJ/mol•K)

ΔHExpTm (kJ/mol)

0.502 ± 0.02 44.49 ± 6

ΔHVHTm (kJ/mol)

ΔHExpTm/ ΔHVHTm

260.5 ± 31 0.18 ± 0.04

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FIGURE CAPTIONS

467

Figure 1. Purification of Hs11S.

468

a) Elution profile of Hs11S applied onto Sephacryl S-300.

469 470 471 472

b) SDS−PAGE profile of Hs11S. Line MW = molecular weight marker, line 1 and 2 = pure Hs11S in non-reducing conditions (4 µg and 16 µg, respectively), line 3 and 4 = Hs11S in reducing conditions using 2-mercaptoethanol (4 µg and 16 µg respectively). α and β are the acidic and basic polypeptides, respectively.

473

Figure 2. Functional characterization of Hs11S.

474 475

a) Critical micelle concentration measured by surface tension in HPLC-degree water at 25 ºC.

476 477

b) Effect of NaCl concentrations on zeta potential as function of pH. Zeta potential was measured at pH 2 - 10 with different NaCl concentrations.

478

Figure 3. Profile of Hs11S [20 % (w/v) in buffer B] gelation by oscillatory rheology.

479

a) Heating rate from 20 to 90 ºC, at a flow rate of 1 ºC/min.

480

b) Cooling rate from 90 to 20 ºC, at a flow rate of 5 ºC/min.

481

c) Frequency sweep in linear viscoelastic region (1 - 100 Hz) at 20 ºC.

482 483

Figure 4. Differential scanning calorimetry profile of Hs11S. Heating from 20 to 150 °C, at a flow rate 5 °C/min.

484 485 486

Figure 5. Effect of temperature and NaCl concentrations on assembly capacity and aggregation/de-aggregation of Hs11S in buffer C by DLS. A) without NaCl, B) 0.1 M NaCl, C) 0.4 M NaCl.

487

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488 489 490

FIGURES Figure 1

491 492 493 494 495 496 497 498 499 500 501

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Figure 2

503 504 505 506 507 508 509 510 511 512 513 514 515

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Figure 3

517 518

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Figure 4

520 521 522 523 524 525 526 527 528 529

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530 531

Figure 5

532 533

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1) Hs11S had a surface activity until 55.5 mN/m and a CMC value of 0.6 mg/mL. 2) Different isoelectric points (2, 3 and 3.5) were revealed in Hs11S with NaCl variations. 3) The denaturation temperature of the Hs11S was 94.1 °C, with an enthalpy of 44.49 kJ/mol. 4) Hs11S showed gelation temperature around 74–76°C and strong gels (~1000 Pa). 5) Hs11S exhibited assemblies in several oligomeric forms, predominating trimer, tetramer, hexamer and aggregates.