热效应对小麦醇溶蛋白起泡性与结构的影响

doi:10.3864/j.issn.0578-1752.2021.04.013

摘要/Abstract

摘要：

【目的】来源于小麦面筋的醇溶蛋白由于具有较强的表面疏水性能,其通过乙醇-水溶液反溶剂制备的胶体粒子展现突出的起泡能力和稳定性。然而,小麦醇溶蛋白胶体粒子在热效应作用下的泡沫特性表现还未得到揭示。因此,为进一步推动小麦醇溶蛋白胶体粒子在真实食品体系中的应用,研究了不同加热温度和加热时间对小麦醇溶蛋白胶体粒子起泡能力和稳定性的影响。【方法】将小麦醇溶蛋白在不同温度下（50、70和90℃）分别处理15、30和60 min后,通过反溶剂法制备小麦醇溶蛋白胶体粒子,测定其起泡能力和泡沫稳定性。通过测定热处理后胶体粒子的尺寸、表面电势、蛋白溶解度的变化,借助原子力显微镜、SDS凝胶电泳、红外光谱、荧光光谱、圆二色谱、紫外光谱、DSC及小角X光散射分析热处理后的小麦醇溶蛋白表面形态及微观结构的变化规律。【结果】经热处理后的小麦醇溶蛋白胶体粒子的起泡能力和泡沫稳定性分别提高了25%和85%。随着加热温度的升高和加热时间的延长,小麦醇溶蛋白胶体粒子发生了部分聚集,粒子尺寸增加,颗粒尺寸主要分布在105—122 nm,ζ-电位降低,90℃时聚集程度更高;加热温度对蛋白溶解度无明显影响,随着加热时间的增加,蛋白的溶解度有了显著的提高;热效应使蛋白分子内部的疏水氨基酸暴露,导致了表面疏水性的增加;二硫键含量减少,游离巯基含量并无显著差异,其原因可能是醇溶蛋白在受热过程中发生了SH/SS交换反应。高温处理改变了小麦醇溶蛋白二级结构,90℃下的蛋白荧光强度降低,β-折叠含量减少,无规则卷曲含量增加,蛋白结构高度伸展,并伴随着部分去折叠。DSC结果显示小麦醇溶蛋白胶体粒子的最高能量从54.33 mW降低到3 mW左右,加热后的谱图比较平缓,蛋白质的构象随着加热时间的延长趋向于无定形态。【结论】热效应使小麦醇溶蛋白胶体粒子发生聚集,蛋白内部疏水基团的暴露使粒子表面疏水性增强;热处理改善了小麦醇溶蛋白的结构柔性（尤其是90℃的处理）,这更有利于形成稳定的界面膜从而更好地稳定泡沫,能够有效改善小麦醇溶蛋白胶体粒子的泡沫特性,对于增强其在食品工业中的应用具有突出的实际意义。

关键词: 小麦醇溶蛋白, 起泡性, 结构柔性, 表面疏水性

Abstract:

【Objective】Gliadin derived from wheat gluten has strong surface hydrophobic properties, and the gliadin colloid particles prepared by ethanol-water solution anti-solvent exhibit outstanding foaming ability and stability. However, the foam properties of gliadin under the action of heat have not been revealed yet. Therefore, in order to further promote the application of gliadin particles in real food systems, the effects of different heating temperatures and heating times on the foaming ability and stability of gliadin particles were studied in this paper. 【Method】After treating the gliadin at different temperatures (50, 70 and 90℃) for 15, 30 and 60 minutes, the gliadin particles were prepared by the anti-solvent method, and the foaming ability and foam stability were measured. By measuring the size, zeta potential, protein solubility, atomic force microscopy, infrared spectroscopy, fluorescence spectroscopy, circular dichroism, ultraviolet spectroscopy, DSC and small-angle X-ray scattering of the heat-treated wheat gliadin particles, the changing law of its surface morphology and microstructure were analyzed. 【Result】The results showed that the foaming ability and foam stability of the heat-treated wheat gliadin particles increased by 25% and 85%, respectively. With the increase of the heating temperature and the extension of the heating time, the gliadin particles had partially aggregated; the particle size increases, and it mainly distributed around 105-122 nm, and the zeta potential decreases; the degree of aggregation became greater at 90℃. The heating temperature had no obvious effect on protein solubility, but the solubility of protein has been significantly improved with the increase of heating time; the thermal effect exposed the hydrophobic amino acids inside the protein molecule, resulting in an increase in surface hydrophobicity; the content of disulfide bonds decreases, and the content of free sulfhydryl groups had no significant difference. The reason might be that the SH/SS exchange reaction of the prolamin occurs during the heating process. High temperature treatment changed the secondary structure of wheat gliadin. The fluorescence intensity of the protein at 90℃ decreased, the β-sheet content decreased, while the irregular curl content increased, and the protein was highly stretched, accompanied by partial unfolding. DSC results showed that the highest energy of wheat gliadin particles decreased from 54.33 mW to about 3 mW, the spectrum after heating was relatively flat, and the protein conformation tended to be amorphous with the extension of heating time.【Conclusion】The thermal effect caused the wheat gliadin particles to aggregate, and the exposure of the hydrophobic groups in the protein enhanced the hydrophobicity of the particle surface. Heat treatment improved the structural flexibility of the wheat gliadin (especially the 90℃ treatment), which was more conducive to the formation of stability. The interfacial film could better stabilize the foam and effectively improve the foam characteristics of the wheat gliadin colloid particles, which had outstanding practical significance for enhancing its application in the food industry.

Key words: gliadin, foamability, structural flexibility, surface hydrophobicity

王立峰,朱洁,熊文飞,赵萌,袁建,鞠兴荣. 热效应对小麦醇溶蛋白起泡性与结构的影响[J]. 中国农业科学, 2021, 54(4): 820-830.

WANG LiFeng,ZHU Jie,XIONG WenFei,ZHAO Meng,YUAN Jian,JU XingRong. Insight into the Impact of Heat Treatment on the Foamability and Structure of Gliadin Colloidal Particles[J]. Scientia Agricultura Sinica, 2021, 54(4): 820-830.

0
/ / 推荐

导出引用管理器 EndNote|Reference Manager|ProCite|BibTeX|RefWorks

链接本文: https://www.chinaagrisci.com/CN/10.3864/j.issn.0578-1752.2021.04.013

https://www.chinaagrisci.com/CN/Y2021/V54/I4/820

图/表 8

图1

图2

图3

图4

图5

图6

图7

表1

参考文献 34

[1]	FUJII S, AKIYAMA K, NAKAYAMA S, HAMASAKI S, YUSA S, NAKAMURA Y. pH- and temperature-responsive aqueous foams stabilized by hairy latex particles. Soft Matter, 2015,11(3):572-579.
[2]	CARL A, BANNUSCHER A, VON KLITZING R. Particle stabilized aqueous foams at different length scales: Synergy between silicaparticles and alkylamines. Langmuir, 2015,31:1615-1622.
[3]	WANG J M, YANG X Q, YIN S W, ZHANG Y, TANG C H, LI B S, YUAN D B, GUO J. Structural rearrangement of ethanol-denatured soy proteins by high hydrostatic pressure treatment. Journal of Agricultural and Food Chemistry, 2011,59(13):7324-7332.
[4]	BANC A, DESBAT B, RENARD D, POPINEAU Y, MANGAVEL C, NAVAILLES L. Structure and orientation changes of ω-and γ-gliadins at the air-water interface: A PM-IRRAS spectroscopy and brewster angle microscopy study. Langmuir, 2008,23:13066-13075.
[5]	PENG D F, JIN W P, LI J, XIONG W F, PEI Y Q, WANG Y T, LI Y, LI B. Adsorption and distribution of edible gliadin nanoparticles at the air/water interface. Journal of Agricultural & Food Chemistry, 2017,65(11):2454-2460.
[6]	NICORESCU I, VIAL C, LOISEL C, RIAUBLANC A, DJELVEH G, CUVELIER G, LEGRAND J. Influence of protein heat treatment on the continuous production of food foams. Food Research International, 2010,43(6):1585-1593.
[7]	SHAO Y Y, LIN K H, KAO Y J. Modification of foaming properties of commercial soy protein isolates and concentrates by heat treatments. Journal of Food Quality, 2016,39(6):695-706.
[8]	PHILLIPS L G, SCHULMAN W, KINSELLA J E. pH and heat treatment effects on foaming of whey protein isolate. Journal of Food Science, 1990,55(4):1116-1119.
[9]	王金梅. 大豆蛋白热聚集行为及界面、乳化性质研究[D]. 广州: 华南理工大学, 2012.
	WANG J M. Thermally aggregation behaviors, interfacial and emulsifying properties of soy protein[D]. Guangzhou: South China University of Technology, 2012.(in Chinese)
[10]	ALIZADEH-PASDAR N, LI-CHAN E C, . Comparison of protein surface hydrophobicity measured at various pH values using three different fluorescent probes. Journal of Agricultural and Food Chemistry, 2000,48:328-334.
[11]	LIU L Y, ZHAO Q Z, LIU T X, ZHAO M M. Dynamic surface pressure and dilatational viscoelasticity of sodium caseinate/xanthan gum mixtures at the oil-water interface. Food Hydrocolloids, 2011,25:921-927.
[12]	SHI C, TANG H F, XIAO J, CUI F C, YANG K C, LI J, ZHAO Q, HUANG Q R, LI Y Q. Small-angle X-ray scattering study of protein complexes with tea polyphenols. Journal of Agricultural and Food Chemistry, 2017,65(3):656-665.
[13]	ZUNIGA R N, TOLKACH A, KULOZIK U, AGUILERA J M. Kinetics of formation and physicochemical characterization of thermally-induced beta-lactoglobulin aggregates. Journal of Food Science, 2010,75:261-268.
[14]	TACO N, DOMINIQUE D. Controlled food protein aggregation for new functionality. Current Opinion in Colloid & Interface Science, 2013,18(4):249-256.
[15]	周伟, 刘玮琳, 刘伟, 刘成梅, 杨水兵, 郑会娟. 不同因素对中链脂肪酸脂质体Zeta电位的影响. 食品科学, 2012,33(19):128-132.
	ZHOU W, LIU L W, LIU W, LIU C M, YANG S B, ZHENG H J. Effects of different factors on zeta potential of medium-chain fatty acid liposomes. Journal of Food Science, 2012,33(19):128-132. (in Chinese)
[16]	MORRIS A M, WATZKY M A, FINKE R G. Protein aggregation kinetics, mechanism, and curve-fitting: a review of the literature. Biochimica et Biophysica Acta (BBA) -Proteins and Proteomics, 2009,1794(3):375-397.
[17]	张海华, 朱科学, 周惠明. 超声波对小麦面筋蛋白结构的影响. 中国农业科学, 2010,43(22):4687-4693.
	ZHANG H H, ZHU K X, ZHOU H M. Effect of ultrasonic on the structure of wheat gluten protein. Scientia Agricultura Sinica, 2010,43(22):4687-4693. (in Chinese)
[18]	GU X, CAMPBELL L J, EUSTON S R. Influence of sugars on the characteristics of glucono-δ-lactone-induced soy protein isolate gels. Food Hydrocolloids, 2009,23:314-326.
[19]	KIM D A, CORNEC M, NARSIMHAN G. Effect of thermal treatment on interfacial properties of β-lactoglobulin. Journal of Colloid and Interface Science, 2005,285:100-109.
[20]	STĂNCIUC N, BANU I, BOLEA C, PATRAŞCU L, APRODU I. Structural and antigenic properties of thermally treated gluten proteins. Food Chemistry, 2018,267:43-51.
[21]	刘安然, 李宗军. 纳米食品加工技术及安全性评价. 河南工业大学学报(自然科学版), 2014,35(6):103-108.
	LIU A R, LI Z J. Nano food processing technology and safety evaluation. Journal of Henan University of Technology (Natural Science Edition), 2014,35(6):103-108. (in Chinese)
[22]	SCHMID F X. Biological macromolecules: UV-visible spectrophotometry// eLS. 2001.
[23]	TAHERI-KAFRANI A, CHOISET Y, FAIZULLIN D A, ZUEZ Y F, BEZUGLOV V V, CHOBERT J M, BORDBAR A K, HAERTLE T. Interactions of β-lactoglobulin with serotonin and arachidonyl serotonin. Biopolymers, 2011,95:871-880.
[24]	NIEUWLAND M, BOUWMAN W G, POUVREAU L, MARTIN A H, DE JONGH H H J. Relating water holding of ovalbumin gels to aggregate structure. Food Hydrocolloids, 2016,52:87-94.
[25]	BECKTEL W J, SCHELLMAN J A. Protein stability curves. Biopolymers, 1987,26(11):1859-1877.
[26]	ZHU H M, DAMODARAN S. Heat-induced conformational changes in whey protein isolate and its relation to foaming properties. Journal of Agriculture and Food Chemistry, 1994,42:846-855.
[27]	OBOROCEANU D, WANG L Z, MAGNER E, AUTY M A E. Fibrillization of whey proteins improves foaming capacity and foam stability at low protein concentrations. Journal of Food Engineering, 2014,121:102-111.
[28]	CAO Y Y, XIONG Y L L, CAO Y G, TRUE A D. Interfacial properties of whey protein foams as influenced by preheating and phenolic binding at neutral pH. Food Hydrocolloids, 2018,82:379-387.
[29]	NICORESCU I, LOISEL C, RIAUBLANC A, VIAL C, DJELVEH G, CUVELIER G, LEGRAND J. Effect of dynamic heat treatment on the physical properties of whey protein foams. Food Hydrocolloids, 2009,23(4):1209-1219.
[30]	DAVIS J P, FOEGEDING E A. Foaming and interfacial properties of polymerized whey protein isolate. Journal of Food Science, 2004,69:404-410.
[31]	ZHAO M, XIONG W F, CHEN B X, ZHU J, WANG L F. Enhancing the solubility and foam ability of rice glutelin by heat treatment at pH12: Insight into protein structure. Food Hydrocolloids, 2020,103:105626.
[32]	KIEFFER R, SCHURER F, KÖHLER P, WIESER H. Effect of hydrostatic pressure and temperature on the chemical and functional properties of wheat gluten: studies on gluten, gliadin and glutenin. Journal of Cereal Science, 2007,45(3):285-292.
[33]	HUSSAIN R, GAIANI C, JEANDEL C, GHANBAJA J, SCHER J. Combined effect of heat treatment and ionic strength on the functionality of whey proteins. Journal of Dairy Science, 2012,95(11):6260-6273.
[34]	CHEN N N, LIN L Z, SUN W Z, ZHAO M M. Stable and pH-sensitive protein nanogels made by self-assembly of heat denatured soy protein. Journal of Agricultural and Food Chemistry, 2014,62:9553-9561.

处理 Treatment	起始温度Onset (℃)	结束温度End (℃)	峰值Peak (℃)	峰高Peak height (mW)
对照Control	187.65	196.67	188.72	54.33
90-15	187.83	194.55	189.97	3.99
90-30	183.55	226.34	189.93	2.99
90-60	185.75	253.79	189.65	3.34