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Improved low pH emulsification properties of glycated peanut protein isolate by ultrasound Maillard reaction Lin Chen, Jianshe Chen, Kegang Wu, and Lin Yu J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.6b00989 • Publication Date (Web): 22 Jun 2016 Downloaded from http://pubs.acs.org on June 28, 2016
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Journal of Agricultural and Food Chemistry
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Improved low pH emulsification properties of glycated peanut protein isolate by
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ultrasound Maillard reaction
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LIN CHEN †, JIANSHE CHEN ‡,§, KEGANG WU † AND LIN YU †,*
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†
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Guangzhou, China, 510006
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‡
College of Chemical Engineering and Light Industry, Guangdong University of Technology,
School of Food Science and Biotechnology, Zhejiang Gongshang University, Hangzhou, China,
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310018
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§
School of Food Science and Nutrition, University of Leeds, LS2 9JT, Leeds, UK
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* corresponding author: Lin Yu, Prof.
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Tel/Fax: +86 203 9322 203.
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E-mail:
[email protected] 17
6 Figures
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2 Tables
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Running title: Emulsification properties of pea protein-maltodextrin conjugates
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ABSTRACT
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In this work, peanut protein isolate (PPI) was grafted with maltodextrin (MD) through the
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ultrasound-assisted Maillard reaction. Sodium dodecyl sulphate-polyacrylamide gel electrophoresis
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(SDS-PAGE) analysis showed link between PPI and MD. The substantially increased accessibility
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of the major subunits (conarachin, acidic subunit of arachin, and basic subunit of arachin) in PPI
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under high-intensity ultrasound treatment led to changes in the degree of graft (DG), zeta-potential,
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protein solubility, and surface hydrophobicity of conjugates. Emulsion systems (20 % v/v oil, 2.0 %
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w/v PPI equivalent, pH 3.8) formed by untreated PPI, PPI-MDC (PPI-MD conjugates obtained with
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wet-heating alone) and UPPI-MDC (PPI-MD conjugates obtained with ultrasound-assisted wet-
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heating) were characterized using light-scatter particle size analyzer and confocal laser scanning
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microscope. Results showed that emulsions of untreated PPI and PPI-MDC were not stable due to
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immediate bridging flocculation and coalescence of droplets, whilst that formed by UPPI-MDC
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with 32.4 % DG was stable with a smaller mean droplet size. It was believed that high-intensity
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ultrasound promoted production of glycated PPI that was soluble and surface active at pH 3.8 and
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thus improved emulsification properties for UPPI-MDC. This study showed that glycated PPI by
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ultrasound-assisted Maillard reaction is an effective emulsifying agent for low pH applications.
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KEYWORDS: peanut protein isolate; maltodextrin; ultrasound treatment; glycation; emulsification
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property
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INTRODUCTION
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Interest has developed in the use of peanut protein isolate (PPI) as emulsifying agent or emulsion
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stabilizer in formulated foods, ranging from sausages to vegetable creams (1–3). PPI is favoured
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because of the surface active properties of its major constitutive proteins: conarachin and arachin,
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which take up nearly 75 % of the total proteins (2). Furthermore, peanut protein is considered as
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good nutritional source for its high content of essential amino acids and has palatable taste (3).
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However, emulsifying behaviour of PPI is poor under certain conditions due to aggregation or
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precipitation of protein and the associated loss of colloidal stability. This instability is most
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pronounced under acidic pH near the isoelectric point (pI, 4.5) of peanut protein (4,5).
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Unfortunately, many emulsion-based foods (e.g., mayonnaise, salad dressings, cream beverages,
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sauces) are normally quite acidic (pH 3.6–4.6).
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One way to improve the solubility and emulsification properties of proteins under unfavourable
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aqueous conditions of low pH, is by direct conjugation with a hydrophilic polymer such as a non-
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ionic polysaccharide (e.g., maltodextrin, dextran) (6–11). The formation of these high-molecular-
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weight protein-polysaccharide conjugates combines the characteristic property of proteins to adsorb
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strongly to the oil-water interface with that of the polysaccharide for quick solvation in aqueous
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medium (12). A safe and practical way to achieve grafting of protein with polysaccharide is by
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using the Maillard reaction carried out under controlled dry-heating or wet-heating conditions (6–
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11). During this complex sequence of reactions, the terminal and side-chain amine groups on a
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protein molecule become covalently linked to the terminal reducing group of the carbonyl of
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polysaccharide (13).
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However, the grafting of protein-polysaccharide through the Maillard reaction is a time-
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consuming process using dry-heating or wet-heating alone, which usually takes several days (6–11).
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Moreover, previous studies found that peanut protein was generally resistant to graft reaction due to
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their compact quaternary and tertiary structures that protect many of the reactive amine groups (9,
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10). Therefore, new emerging technologies, avoiding high temperatures and/or long processing
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times, should be applied to improve the efficiency of graft reaction for peanut protein. Recently,
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several studies have reported that the grafting of protein-polysaccharide through the Maillard
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reaction could be substantially enhanced and accelerated under high-intensity ultrasound treatment
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(10, 14–16). For example, Li et al. (10) reported that after wet-heating at 80 ºC for 24 h, a DG
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(degree of graft) of 35.7 % was obtained by PPI-dextran conjugate; however, with the assistance of
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ultrasound, a significantly higher DG of 45.4 % was reached at a much shorter reaction time (40
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min). Stanic-Vucinic et al. (16) also observed such an sonocatalysis effect during the Maillard
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reaction of β-lactoglobulin with different kinds of saccharide. It has been suggested that local
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translational motions induced by ultrasound cavitation might allow reactive groups to be brought
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into closer proximity, resulting in more steady Maillard reaction (17). In addition, high-intensity
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ultrasound could disrupt the tertiary and quaternary structure of globular proteins, causing the
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exposure of reactive amine groups (i.e., free amine groups) for grfat reaction (10, 14).
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Although ultrasound-assisted Maillard reaction has been used to modify the emulsifying
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properties of food proteins (10, 14, 15), the experimental results reported in the literature seems
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ambiguous. As Li et al. (10) reported, ultrasound treatment caused an increase in both emulsifying
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activity index (EAI) and emulsion stability index (ESI) for PPI-dextran conjugates, while Mu et al.
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(14) observed that such a treatment caused a decrease in ESI for soy protein isolate-gum aracia
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conjugates. It should be noted that emulsifying properties in these studies were mainly characterized
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by EAI and ESI using turbidity meansurement. However, this relatively simple approach should be
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treated with caution, because the differences in turbidity between emulsions may not only reflect
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differences in droplet size but also in the state of the oil droplets and/or polymer aggregation, which
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may give incorrect conclusions about their emulsifying properties (6, 18). Among various
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experimental techniques, multi-angle static light-scattering and confocal laser scanning microscopy
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(CLSM) are usually preferred for determining droplet sizes and visualizing microstructures in fine
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emulsions (18) and are widely used not only for emulsification capability assessment of an
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emulsifying agent, but also for exploring fundamental mechanisms of emulsion formation and
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stabilization (19, 20). So far, however, few such work has been done to investigate the
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emulsification properties of glycated PPI.
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Therefore, the current study is designed to improve emulsification properties of PPI-MD
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conjugates made with ultrasound-assisted Maillard reaction and the possible mechanisms.
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Emulsification properties of different samples were studied by analyzing the droplet size and
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microstructure of freshly made O/W emulsions (20 vol.% oil, 2 % w/v PPI equivalent, pH 3.8) by
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light-sactter particle size analysis and CLSM. Results obtained from this study could provide a new
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possibility to food industry of improved emulsification functionality for low pH applications.
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MATERIALS AND METHODS
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Materials and Chemicals. PPI was prepared from low-temperature defatted peanut meal
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(Tianshen Bioprotein Co. Ltd., Taixing, China) according to the method of Liu et al. (9), with slight
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modifications. The protein content of PPI was 88.6 g/100 g of powder, which was determined by
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micro-Kjeldahl method (N × 6.25). MD sample (Glucidex IT 6) with a dextrose equivalent of 4.2
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was obtained from Roquette (Lestrem, France). According to the manufacturer, it had an average
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molecular weight Mw of 8.1 kDa. O-Phthaldialdehyde (OPA), 6-propionyl-2-(N,N-dimethy-amino)
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naphthalene (PRODAN) and Nile Red were obtained from Sigma Chemicals (St. Louis, MO, USA).
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All other chemicals used in this study were at least of analytical grade. Water purified with a Milli-
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Q filtration unit (Millipore, Bedford, UK) was used for the preparation of solutions. The pH was
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adjusted using 0.1–1.0 M HCl solutions and 0.1–1.0 M NaOH solutions.
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Preparations of PPI-MDC and UPPI-MDC. Based on the previously reported method (11), PPI
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(10.0%, w/v) and MD (10.0%, w/v) were fully dispersed in phosphate buffer solution (0.2 M, pH
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7.0, 0.02% (w/v) sodium azide to prevent bacterial growth) by magnetically stirring at 4 ºC
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overnight. The following day, an ultrasound processor (XingDongLi Ultrasonic Electron Equipment
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Co. Ltd, Guangzhou, China) with a 1.5 cm diameter titanium probe was used to sonicate 150 mL of
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PPI-MD dispersions in 250 mL tall beakers that were immersed in a temperature-controlled shaking
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water bath set at 70 ºC and 10 rpm. Samples were sonicated with a power output of 250 W at a
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frequency of 20 kHz and an amplitude of 95 % (wave amplitude of 121 µm at 100 % amplitude) for
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different time (10, 20, 40, 60, 80, 100 min). Pulsed sonication (2 s on and 2 s off) was used to
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minimize the intrinsic heating effect of ultrasound and ensured that samples remained within ± 5 ºC
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of the ultrasonic bath temperature. After ultrasound-assisted wet-heating, the PPI-MD dispersions
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were cooled to room temperature and dialyzed at 4 ºC for 24 h. Finally, the resulting products were
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lyophilized, finely ground and kept in a desiccator for further use. The same PPI-MD dispersion
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was treated by wet-heating alone at 70 ºC for different times (1, 4, 12, 24, 32, 48 h), and the
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subsequent procedure was the same to ultrasound treatment. As controls, PPI was treated under
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glycation conditions in the absence of MD as described above. Samples were designated
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subsequently according to the grafting methods used and the DG obtained. For example, UPPI-
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MDC-32.4% means PPI-MD conjugate was prepared with ultrasound-assisted wet-heating and had
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a DG of 32.4 %.
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Degree of Graft (DG) Measurements. Free amine groups were measured using the o-
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phthaldialdehyde (OPA) assay according to the method of Vigo et al. (21), with slight modifications.
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OPA of 40 mg was dissolved in 1 mL methanol and mixed with 25 mL of 10 mM sodium
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tetraborate, 100 µL of β-mercaptoethanol, and 2.5 mL of 20% (w/v) sodium dodecyl sulphate (SDS),
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and was then diluted to a final volume of 50 mL with deionized water to form the OPA reagent. 4
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mL of OPA reagent was added into 200 µL of sample solution (10 mg/mL). After incubated at 35
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°C for 2 min, the absorbance at 340 nm was measured immediately. A calibration curve was made
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using 0.25–2 mM L-Lysine. DG was calculated as follow: DG = (Ac – At)/ A0 × 100%, where Ac is
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the level of free amine groups in controls; At is the level of free amine groups in conjugates; A0 is
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the level of free amine groups in untreated PPI.
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Sodium Dodecyl Sulphate-Polyacrylamide Gel Electrophoresis (SDS-PAGE). SDS-PAGE
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was carried out using a precast 4–15 % gradient polyacrylamide gel (Bio-Rad Laboratories,
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Hercules, CA) according to the method of Liu et al (7), with slight modifications. Samples were
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dissolved in a SDS-PAGE sample buffer (catalog no. 161-0737, Bio-Rad Laboratories) to a
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concentration of 1 µg/µL. The mixture was shaken for 10 s and heated at 95 °C for 5 min. After
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centrifuging at 12,000 × g for 10 min, fifteen microliters of each sample were applied to the gel
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lanes for electrophoresis running in a Mini-protean IV system (Bio-Rad Laboratories). Afterward,
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the gel sheets were stained for protein with 0.2 % Coomassie Brilliant Blue G-250 and were stained
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for carbohydrate with 0.5% periodic acid fuchsin (PAS).
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Protein Solubility (PS) Measurements. The PS refers to the percentage of soluble protein
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against original protein presented in samples, and is measured as described by Petruccelli et al. (22).
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Zeta Potential (ζ-potential) Measurements. The ζ-potential of protein samples was measured
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using a Zetasizer Nano ZS (Malvern Instruments, Worcs, UK). Sample dispersions (0.2 %, w/v)
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were adjusted to pH 7.0 or 3.8, and then were magnetically stirred at room temperature for 2 h. The
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resulting dispersions were filtered through a 0.45 µm HA Millipore membrane prior to analysis.
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Based on an analysis of particle electrophoretic mobility measurements, the ζ-potential of samples
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was automatically calculated by the instrument.
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Surface Hydrophobicity (H0) Measurements. An unchanged fluorescent probe, PRODAN, was
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used to measure the H0 of different samples at pH 7.0 or 3.8 according to the method of Haskard et
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al. (23), with slight modifications. For buffers at pH 7.0 and 3.8, a mixture of 0.1 M citric acid and
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0.2 M Na2HPO4 were used in the following proportions (v/v), respectively: 3.5/16.5, 12.9/7.1.
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Sample dispersions were serially diluted with appropriate buffers at pH 7.0 or 3.8 to a final
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concentration of 0.004–0.02% (w/v), and then were centrifuged (12,000 × g, 20min) to obtain the
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supernatants. Ten microliters of PRODAN solution (1.5 mmol/L in the same buffer) was mixed to 4
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mL aliquots of diluted samples. After 15 min in the dark, the fluorescence intensity (FI) was
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measured at 465 nm (emission) using an excitation at 365 nm. A plot of initial slope of the FI versus
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protein concentration (mg/mL) plot was used as an index of surface hydrophobicity (H0).
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Emulsion Preparation and Characterization. Dispersions of different samples were adjusted to
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pH 3.8, and were magnetically stirred at room temperature for 2 h to ensure complete hydration,
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with 0.02% (w/v) sodium azide added to retard microbial growth. The subsequently quoted pH
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referred to that of sample dispersions. The dispersions contained 2.0 % (w/v) PPI equivalent for
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samples of pure protein or Maillard conjugates. O/W emulsions containing 20 vol.% sunflower seed
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oil were made using a high-pressure jet homogenizer operating at a pressure of 300 bar.
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Droplet size distributions (DSD) of freshly made emulsions were determined using a Mastersizer
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2000 particle size analyzer (Malvern Instruments). Refractive indices of water and sunflower seed
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oil were taken as 1.330 and 1.462, respectively. The average droplet size was reported as volume
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mean diameter d43 = ∑nidi4/∑nidi3, where ni is the number of droplets of diameter di.
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Microstructure of freshly made emulsions was visualized using an upright Leica TCS SP2
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confocal laser scanning microscope (CLSM) (Leica, Heidelberg, Germany) operating in
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fluorescence mode. A 63× water-immersion objective (NA 1.20) was used to scan the samples. Nile
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Red dye (Twenty microliters of 0.01% w/v dye in polyethylene glycol mixed with 5 mL of emulsion)
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was used to stained the emulsion oil phase, with fluorescence excited with an Argon laser line (488
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nm). Because only oily substances in emulsions were stained by Nile Red, the oil phase appeared as
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bright blobs, whilst the water/protein phase appeared dark in all the CLSM images.
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Statistical Analysis. All the tests were performed in triplicate, and results were expressed as
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mean ± standard deviation. Duncan’s multiple-range test was applied to identify significant
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differences between results (p < 0.05).
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RESULTS AND DISCUSSION
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Effects of Ultrasound Treatment on the Graft Reaction between PPI and MD. In order to
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analyze the effect of ultrasound treatment on the graft reaction between PPI and MD, the degree of
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graft (DG) and SDS-PAGE profiles of conjugates prepared with and without ultrasound treatment
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were investigated. Table 1 shows the DG values of PPI-MDC and UPPI-MDC prepared at different
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reaction times. A DG of 26.8 % was obtained by PPI-MDC prepared with wet-heating alone for 48h.
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In contrast, with the assistance of ultrasound, a significantly (p < 0.05) higher DG of 35.6 % was
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obtained by UPPI-MDC at a much shorter reaction time of 100 min. These results were similar with
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previous studies and confirmed that ultrasound treatment was an highly effective way to accelerate
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and enhance the graft reaction between proteins and polysaccharides (10, 14–16). It was reported
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that ultrasound posed a sonocatalysis effect during the protein-polysaccharide Maillard reaction,
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which made the occurence of protein glycation more readily (16). In addition, high-intensity
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ultrasound could disrupt the tertiary and quaternary structure of globular proteins, causing the
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exposure of more reactive amine groups (i.e., free amine groups) for the Maillard reaction (10, 14,
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15).
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SDS-PAGE has been proved to be a reliable method to establish the covalent link between
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proteins and polysaccharides during the Maillard reaction (9, 10). Fig. 1 shows the SDS-PAGE
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profiles of untreated PPI-MD mixture, PPI-MDC and UPPI-MDC prepared at different reaction
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times. Protein components stained by Coomassie blue appeared as blue and polysaccharide
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components stained by PAS appeared as pink. We can see that for both PPI-MDC and UPPI-MDC,
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with the increase of reaction time, the polysaccharide components was increasingly attached to the
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protein components, forming characteristic new polydisperse bands, suggesting that the PPI was
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indeed complexed with MD to form conjugates with high molecular weight. The positions of
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protein bands in Fig. 1A are in accordance with polysaccharide bands in Fig. 1B provides further
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evidence for strong linkage between PPI and the MD.
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On the other hand, as shown in Fig. 1A, there were five major bands presented in the SDS-
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PAGE profile of untreated PPI (lane 1), referring to S1−S5, respectively. Band S1 at around 64 kDa
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was identified as the subunit of conarachin. Bands S2−S4 (approximately 40, 39, and 37 kDa) were
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identified as the acidic subunits of arachin (AS-arachin), and band S5 (around 25 kDa) was
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identified as the basic subunit of arachin (BS-arachin) (24). Under wet-heating condition, different
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subunits in PPI showed different grafting accessibilities: a gradual disappearance in the
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characteristic band for the conarachin (S1) could be observed as the graft reaction proceeded from
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60 min to 24 h; AS-arachin (S2−S4) and BS-arachin (S5) appeared highly resistant to graft reaction,
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and were still identifiable after incubation for 24 h. In contrast, under ultrasound-assisted wet-
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heating condition, conarachin, AS-arachin and BS-arachin turned out to be grafted with MD more
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readily: after incubated for 60 min, conarachin and AS-arachin disappeared almost completely; the
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band intensity of BS-arachin in UPPI-MDC was noticably weaker than that in PPI-MDC. It can be
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inferred from these observations that the accessibility of the major subunits in PPI to graft with MD
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were substantially increased under ultrasound treatment, which made UPPI-MDC obtain higher DG
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at a much shorter reaction time as compared with PPI-MDC.
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Zeta-Potential of PPI-MDC and UPPI-MDC. In order to investigate the changes in
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electrostatic interactions of PPI after different treatments, we measured the ζ-potentials of
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dispersions of untreated PPI, PPI-MDC and UPPI-MDC at pH 7.0 and 3.8. As shown in Table 2 the
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absolute magnitude of the ζ-potential was significantly (p < 0.05) lower at pH 3.8 (+21.3 mV) than
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that at pH 7.0 (-35.2 mV) for untreated PPI dispersion. This indicated that peanut protein carried
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less net charge at acidity near its pI (pH 4.5), which might weaken the intra- and inter- molecular
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electrostatic repulsions, promote the folding of protein, enhance the protein-protein aggregation and
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decrease the protein-water interaction (25). In contrast, after 20 min of ultrasound treatment, UPPI-
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20min dispersion showed a higher negative ζ-potential (-43.7 mV) at pH 7.0, which might suggest
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that ultrasound treatment induced the exposure of charged groups previously hidden in protein
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structures, as also reported by Gülseren et al. (26). However, at pH 3.8, the ζ-potential of UPPI-
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20min dispersion was not significantly (p > 0.05) different from that of untreated PPI dispersion.
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After glycation, the magnitude of the ζ-potential of PPI-MDC and UPPI-MDC dispersions both
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decreased gradually with increasing DG (Fig. 2). This may be because the ζ-potentials were
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measured at the slip plane of the PPI-MD conjugates, which is the edge of the MD layer. But the
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charge was on the protein which was several nanometers away from the slip plane. As the MD layer
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got denser, more charge on the protein would be shielded, thus reducing the measured protein
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charge (8). It can be seen that UPPI-MDC dispersions showed a relatively lower ζ-potential than
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PPI-MDC dispersions at high DG, which may suggest that more peanut protein in UPPI were
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grafted with MD, as also observed in SDS-PAGE profiles.
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Protein Solubility of PPI-MDC and UPPI-MDC. Protein solubility is probably the most
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important influencing factor on its functionality. Poor solubility is often accompanied with poor
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functionality. As shown in Table 2, The PS of untreated PPI was 79.6 % at pH 7.0, and decreased to
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43.5 % at pH 3.8, which may be due to the aggregation of peanut protein near its pI (pH 4.5). UPPI-
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20min showed a PS of 45.4 % at pH 3.8, which suggested that ultrasound treatment had a limited
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effect on improving the PS of PPI at acidity near its pI.
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The PS of PPI-MDC and UPPI-MDC as a function of DG at pH 3.8 is shown in Fig. 3. After
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glycation, with the increase of DG, the PS of both PPI-MDC and UPPI-MDC increased gradually,
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and then decreased slightly at high DG. The higher PS of protein-polysaccharide conjugates than
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the original protein around pI could be attributed to the steric effects provided by the glycated MD,
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as suggested by Liu et al. (7). The nonionic MD used in this study kept almost completely soluble at
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pH 3.8, and provided steric repulsion as a dominant mechanism account for the improved PS of
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glycated PPI around its pI. However, it is noteworthy that UPPI-MDC showed higher PS than PPI-
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MDC, even though they had similar DG values. For example, UPPI-MDC-21.7% showed a PS of
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60.3 % at pH 3.8, significantly higher than that of PPI-MDC-22.5% (PS = 52.3 %). These results
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suggest that ultrasound-assisted Maillard reaction exerted a marked effect on improving the PS of
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glycated PPI at acidity around its pI. This finding may be due to the fact the grafting accessibility of
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the major subunits in PPI (conarachin, AS-arachin and BS-arachin) were increased under ultrasound
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treatment, which made more peanut protein in UPPI can be grafted readily with MD and keep
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soluble around its pI. However, both PPI-MDC and UPPI-MDC showed a slight decrease in PS at
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high DG. This finding was similar with some previous studies that denaturation and aggregation of
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peanut proteins may occur at long incubation periods during the Maillard reactoin, resulting in the
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decrease of PS (6, 9).
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Surface Hydrophobicity of PPI-MDC and UPPI-MDC. In order to accurately predict protein
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functionality, quantitative analysis of protein surface hydrophobicity is essential. Table 2 shows that
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the H0 of untreated PPI was 537.6 at pH 7.0, and decreased to 423.2 at pH 3.8. It has been reported
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that compared to a more hydrophobic and flexible molecule at neutral pH, peanut protein underwent
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specific structural changes characterized by a tighter conformation at acidic pH (25). This is to be
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expected since the intra- and inter- molecular electrostatic repulsions decreased near the pI of
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peanut protein as demonstrated before, which could lead to the folding/aggregation of protein
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molecules and therefore the loss of hydrophobic groups on protein surface. In contrast, UPPI-20min
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showed significantly higher H0 at both pH 7.0 (581.3) and 3.8 (457.5), which might be due to the
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exposure of previously buried hydrophobic groups after ultrasound treatment, as suggested
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previously (27, 28). In addition, this finding may imply that the compacted structure of peanut
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protein could be effectively unfolded by high-intensity ultrasound, causing the exposure of
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hydrophobic/hydrophilic groups as well as the reactive amine groups previously buried. The H0 of
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of PPI-MDC and UPPI-MDC as a function of DG at pH 3.8 is shown in Fig. 4. After glycation, the
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H0 of PPI-MDC decreased markedly with increasing DG. The reduced H0 after glycation is also
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reported in the literature, which might be due to (1) the shielding effect of the polysaccharide chain
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bound to proteins, (2) burial of effective hydrophobic regions due to protein aggregation during the
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glycation, and (3) formation of advanced glycation products or melanoidins with little surface
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hydrophobicity (7, 9, 29). As a consequence, PPI-MDC exhibited very low H0 at high DG, although
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increased PS at pH 3.8. On contrast, it is noteworthy that when the glycation was conducted under
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ultrasound treatment, the H0 of UPPI-MDC increased at initial stage, and then decreased relatively
290
moderately with a further increase in DG. The reason for this may be due to the fact that the
291
ultrasound treatment unfolded globular peanut protein and/or dissociated protein aggregates,
292
causing the exposure of hydrophobic groups previously buried. More significantly, with the
293
assistance of ultrasound, more peanut protein could be grafted readily with MD and kept stable at
294
acidic pH as demonstrated before, resulting in the preservation of more hydrophobic groups on
295
protein surface. We can see that compared with the untreated PPI, some UPPI-MDC (DG = 18.7–
296
32.4 %) had much increased PS at pH 3.8, but still maintained comparably high H0.
297
Emulsification Properties of PPI-MDC and UPPI-MDC. An effective emulsifying agent
298
should rapidly lower the interfacial tension at the freshly created oil-water interface during
299
emulsification, thus facilitating droplet fromation, and quickly form an interfacial membrane at the
300
droplet surface, effectively protecting the newly created droplets against immediate bridging
301
flocculation and coalescence. Therefore, the emulsification property of an emulsifying agent refers
302
to its ability to generate and stabilize fine droplets during emulsification (18). In this study, the
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emulsification properties of different samples were assessed according to average droplet size d43
304
and microstructure of freshly made O/W emulsions (20 vol.% oil, 2 % w/v PPI equivalent, pH 3.8)
305
as measured by light-sacttering particle size analysis and CLSM. The d43 of emulsions formed by
306
PPI-MDC and UPPI-MDC at pH 3.8 is plotted as a function of DG in Fig. 5, and CLSM images of
307
some selected sample emulsions with their DSD superimposed are shown in Fig.6. Emulsions
308
formed by untreated PPI and UPPI-20min both showed a relatively big d43 of ca. 21 µm at pH 3.8.
309
Based on CLSM observation, these emulsions were found to be highly flocculated, containing some
310
big flocs/droplets (see Fig. 6A and Fig. 6D). These findings suggest that PPI alone exhibited a poor
311
emulsification property at acidity near the pI of peanut protein, which was consistent with previous
312
studies (4, 5). This may be mainly attributed to the aggregation of peanut protein induced by
313
inadequate electrostatic repulsion under conditions close to pI, resulting in the loss of protein
314
solubility and the formation of insoluble protein particles. It should be noted that under the turbulent
315
flow conditions of homogenization, protein particles could also adsorb onto the surface of newly
316
created droplets (30). However, compared to soluble proteins, protein particles are less effective in
317
covering oil droplets due to their much higher saturation surface load and much slower diffusion.
318
Consequently, emulsions tend to have bridging flocculation (the sharing of adsorbed particles or
319
macromolecules amongst adjacent droplets) and coalescence during and immediately after the
320
homogenization (31, 32), as illustrated here in the emulsion formed by PPI alone at pH 3.8.
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However, d43 of emulsions formed by PPI-MDC and UPPI-MDC showed gradual decrease
322
gradually at initial stage, and then sharply increased at high DG. This finding is in accordance with
323
some previous research and suggests that controlled glycation by the Maillard reaction improved
324
the emulsification property of PPI, but excessive glycation was detrimental (6, 14, 33). Emulsions
325
formed by PPI-MDC showed a minimum d43 of 14.6 µm at DG 18.3 %. Microstructure observation
326
showed that flocculation still occurred in the emulsion formed by PPI-MDC-18.3% (see Fig. 6B),
327
although at a less extent as compared with that in untreated PPI emulsion. In addition, an increase in
328
droplets with small size (ranging from 0.1 to 1 µm) was observed. It seems that PPI-MDC-18.3%
329
contained some conjugates that are soluble and surface active at pH 3.8, enabling the formation and
330
stabilization of fine droplets. However, with only 53.5% PS for PPI-MDC-18.3% at pH 3.8, it is
331
obvious that emulsifying agent is not sufficiently available for full surface coverage of newly
332
formed droplets. Therefore, it is reasonable to conclude that wet-heating of PPI with MD could only
333
induce a limited improvement in emulsification property under acidic pH.
334
In contrast, emulsions formed by UPPI-MDC showed a minimum d43 of ca. 6.0 µm at DG of
335
18.7–32.4 %. Microstructure observation showed that the emulsion formed by UPPI-MDC-32.4%
336
was homogeneous with no sign of flocculation (Fig. 6E). Compared with PPI-MDC-18.3%
337
emulsion, UPPI-MDC-32.4% emulsion contained many more fine droplets ranged between 0.1 and
338
10 µm. These results clearly showed that glycation of PPI with MD using ultrasound-assisted wet-
339
heating was more effective in improving the emulsification property of PPI at acidic pH than that
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using wet-heating alone. As has been shown that under ultrasound treatment, the grafting
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accessibility of the major subunits (conaracin, AS-arachin and BS-arachin) in PPI was substantially
342
increased, so more peanut protein in PPI could be readily grafted with MD and remained soluble
343
and surface active around its pI. As a result, compared with untreated PPI and PPI-MDC-18.3%,
344
UPPI-MDC-32.4% showed a much increased PS (65.3 %) and a comparably high H0 (409.5) at pH
345
3.8, and might contain a lot of more conjugates that were soluble and surface-active at pH 3.8, a
346
highly feasible explanation for its much improved emulsification property under acidic pH.
347
However, it was observed that the d43 of emulsions formed by PPI-MDC and UPPI-MDC both
348
increased strongly at high DG. In addition, both CLSM images and DSD measurements showed the
349
appearance of many big droplets in emulsions formed by PPI-MDC-26.8% (Fig. 6C) and UPPI-
350
MDC-35.6% (Fig. 6F). This phenomenon might arise from the strong decrease in H0 at high DG for
351
both PPI-MDC and UPPI-MDC, resulting in the loss of surface activity for the conjugates. It has
352
been reported that some techniques (e.g. static high pressure, microwave heating) used to accelerate
353
the the Maillard reaction between proteins and polysaccharides tended to promote the formation of
354
advanced glycation products or melanoidins, which had shown to possess poor surface activity (34–
355
36). By contrast, it seems that high-intensity ultrasound is a more appropriate technique to promote
356
the Maillard reaction for the functional modifications of globular proteins, since the extent of the
357
Maillard reaction could be well controlled in terms of DG as demonstrated in this study.
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In summary, this study demonstrated that with the assistance of ultrasound, the grafting between
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PPI and MD through the Maillard reaction was markedly accelerated and enhanced in terms of DG.
360
Under ultrasound-assisted wet-heating condition, the major graft-resistant subunits of conarachin,
361
AS-arachin and BS-arachin in PPI, became more readily grafted with MD through the Maillard
362
reaction. Compared with PPI-MDC, UPPI-MDC showed a stronger increase in PS and a more
363
moderate change in H0 at pH 3.8 during the Maillard reaction, resulting in the production of some
364
UPPI-MDC with much increased PS and comparably high H0. Fresh emulsions formed by untreated
365
PPI and PPI-MDC were unstable due to the bridging flocculation and coalescence of droplets
366
during homogenization, whilst that formed by UPPI-MDC with 32.4 % DG was stable and had a
367
smaller average droplet size d43, suggesting its remarkably improved emulsification properties at
368
acidity near the pI of peanut protein. In conclusion, glycated PPI could be an effective emulsifying
369
agent for acidic emulsion-based foods. High-intensity ultrasound is an efficient technique to
370
promote the Maillard reaction for the functional modifications of globular proteins. But how could
371
ultrasound treatment make PPI readily graft with MD is still not fully clear, and future work on this
372
topic is needed.
373
374 375
376
ACKNOWLEDGEMENTS This work was supported by National Research Fund for Doctoral Program of China (No. 20134420120008)
and
Guangdong
Provincial
Science
and
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Technology
Project
(No.
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Journal of Agricultural and Food Chemistry
2013B020311015). We thank Professors E. Dickinson and B. Murray for useful discussions.
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FIGURE CAPTIONS
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Fig. 1. Changes of SDS-PAGE profiles of PPI-MDC and UPPI-MDC prepared at different reaction
474
times. S1: conarachin; S2–S4: acidic subunits of arachin; S5: basic subunits of arachin; M,
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molecular weight markers.
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Fig. 2. Effects of DG on zeta-potentials (ζ-potential) of PPI-MDC and UPPI-MDC at pH 3.8.
477
Fig. 3. Effects of DG on protein solubility (PS) of PPI-MDC and UPPI-MDC at pH 3.8.
478
Fig. 4. Effects of DG on surface hydrophobicity (H0) of PPI-MDC and UPPI-MDC at pH 3.8.
479
Fig. 5. Effects of DG on average droplet size (d43) of fresh emulsions (20 vol.% oil, 2.0 % w/v PPI
480
equivalent) formed by PPI-MDC and UPPI-MDC at pH 3.8.
481
Fig. 6. Microstructure of fresh emulsions (20% vol.% oil, 2 % w/v PPI equivalent) formed by PPI-
482
MDC and UPPI-MDC with selected DG values at pH 3.8: (A) untreated PPI; (B) PPI-MDC-18.3%;
483
(C) PPI-MDC-26.8%; (D) UPPI-20min: (E) UPPI-MDC-32.4%; (F) UPPI-MDC-35.6%. DSD is
484
superimposed on the microimages, with horizontal scale showing particle size (µm).
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Table 1. DG values of PPI-MDC and UPPI-MDC prepared at different reaction times* PPI-MDC
486
UPPI-MDC
Time (h)
DG (%)
Time (min)
DG (%)
1
9.5 (±0.5) i
10
3.2 (±0.4) j
4
12.7 (±0.4) h
20
9.3 (±0.7) i
12
18.3 (±0.7) g
40
21.7 (±0.5) f
24
22.5 (±0.6) f
60
32.4 (±0.6) c
32
24.6 (±0.4) e
80
34.1 (±0.3) b
48
26.8 (±0.3) d
100
35.6 (±0.4) a
* Results having different letters are significantly different (p < 0.05).
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Table 2. Protein solubility (PS), surface hydrophobicity (H0) and zeta-potential (ζ-potential) of
488
different samples* Samples
489
PS (%)
H0
ζ-potential (mV)
PPI (pH 7.0)
79.6 (±0.3) b
537.6 (±4.7) b
-35.2 (±0.3) b
PPI (pH 3.8)
43.8 (±0.4) f
423.2 (±5.2) d
+21.3 (±0.4) c
UPPI-20 min (pH 7.0)
83.6 (±0.5) a
581.3 (±6.4) a
-43.7 (±0.4) a
UPPI-20 min (pH 3.8)
45.4 (±0.6) e
457.5 (±6.6) c
+21.6 (±0.5) c
PPI-MDC-18.3% (pH 3.8)
53.5 (±0.4) d
366.2 (±4.5) f
+13.4 (±0.5) d
UPPI-MDC-32.4% (pH 3.8)
65.3 (±0.6) c
409.5 (±4.3) e
+9.1 (±0.4) e
* Results within a column having different letters are significantly different (p