Improvement of CaSO4-Induced Gelation Properties of Soybean Protein Isolate by Pre-crosslinking with Transglutaminase
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摘要: 酶法改性能够有效提升大豆蛋白的凝胶性。为了探讨谷氨酰胺转氨酶(transglutaminase, TGase)预交联对盐诱导大豆分离蛋白凝胶性的影响,通过控制酶浓度、预交联时间制备不同预交联程度的大豆分离蛋白(soy protein isolate,SPI)溶液,并研究其在CaSO4作用下的成胶性能。结果显示,与未经TGase处理的SPI相比,TGase适度预交联能够显著提升SPI的凝胶品质。经3~5 U/g TGase预交联20 min或3 U/g TGase预交联20~30 min后,SPI凝胶性得到了不同程度的提升,其中弹性模量、屈服应力、屈服应变、持水率最大分别提高了124.5%、269.0%、135.0%及53.0%。然而,过度预交联产生过大的蛋白聚集体,导致最终形成的凝胶结构粗糙、多孔,凝胶强度、持水力等均显著下降(P<0.05)。由此可见,合理利用TGase对蛋白进行预交联处理能够改善SPI凝胶制品品质,对于TGase在食品工业中的应用及传统豆制品质构改良具有重要的指导意义。Abstract: Enzymatic modification can effectively improve the gel property of soybean protein. In order to study the effect of transglutaminase (TGase) pre-crosslinking on the properties of salt induced soy protein isolate (SPI) gel, SPI dispersions with different crosslinking degree were prepared by controlling the enzyme concentration and the pre-crosslinking time, and their gelation properties under the action of CaSO4 were studied. The results showed that compared with SPI without TGase treatment, appropriate pre-crosslinking of protein could significantly improve the quality of SPI gels. After 3~5 U/g TGase crosslinking for 20 min or 3 U/g TGase crosslinking for 20~30 min, the properties of SPI gel were improved to different degrees, among which the elastic modulus, yield stress, yield strain and water holding capacity were increased by 124.6%, 269.0%, 135.0% and 53.0%, respectively. However, excessive crosslinking produced protein aggregates with too large size, resulting in coarse and porous gel structure and significantly decreased (P<0.05) in gel strength and water holding capacity. It can be seen that proper utilization of TGase can improve the quality of SPI gel products, which has important guiding significance for the application of TGase in food industry and the improvement of texture of traditional soybean products.
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Key words:
- soy protein isolate /
- transglutaminase /
- pre-crosslinking /
- gel property
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图 2 不同TGase预交联处理SPI的SDS-PAGE
注:1:Marker;2:未经TGase预交联的热处理后的SPI;3~6:TGase浓度分别为1、3、5、7 U/g,预交联20 min;7~10:TGase预交联时间分别为10、20、30、40 min,TGase浓度为3 U/g。
Figure 2. The SDS-PAGE of SPI with different TGases pre-crosslinking treatments
图 3 不同TGase预交联处理SPI凝胶过程中弹性模量随时间的变化
Figure 3. The change of G′ with time and temperature during the gelation process of SPI with different TGases pre-crosslinking treatments
图 4 不同TGase预交联处理SPI凝胶的频率扫描
Figure 4. Frequency sweep of SPI gels with different TGases pre-crosslinking treatments
图 5 不同TGase预交联处理SPI凝胶的大形变测试
Figure 5. Large deformation of SPI gels with different TGase pre-crosslinking treatments
图 6 不同TGase预交联处理SPI凝胶的持水力
注:不同小写字母(a~d)表示不同样品之间存在显著性差异(P<0.05)。
Figure 6. The WHC of SPI gels with different TGase pre-crosslinking treatments
图 7 不同TGase预交联处理SPI凝胶的微观结构
注:A~E:0、1、3、5、7 U/g TGase预交联20 min;a~e:TGase浓度3 U/g,预交联时间0、10、20、30、40 min。
Figure 7. Microstructures of SPI gels with different TGase pre-crosslinking treatments
表 1 不同TGase预交联处理SPI凝胶温度扫描终点G′、频率扫描幂律模型拟合的n值、屈服应力和屈服应变
Table 1. The G′ value, n value of power law model fitting, fracture stress and strain of SPI gels with different TGases pre-crosslinking treatments
预交联程度 G′ (Pa) n 应力(Pa) 应变(%) 空白 1059.85±105.80d 0.1040±0.0001 a 508.00±62.80d 43.83±5.78d 1 U/g 2056.90±884.60b 0.1020±0.0014 a 1163.60±55.44c 65.65±1.48c 浓度 3 U/g 2379.15±18.00a 0.0937±0.0005b 1474.60±126.70b 91.00±5.80b 5 U/g 1617.50±12.02c 0.0903±0.0001c 1874.50±72.80a 103.00±2.83a 7 U/g 1417.00±18.38c 0.0013±0.0001d 1742.95±215.00ab 99.05±2.76ab 10 min 1377.45±129.40c 0.0980±0.0016a 620.67±98.10cd 50.55±5.73cd 时间 20 min 2379.15±18.00a 0.0937±0.0005a 1474.67±126.70a 91.00±5.80a 30 min 1792.67±138.90b 0.1011±0.0031a 1252.00±89.10b 70.70±5.66b 40 min 1830.95±120.30b 0.0936±0.0013b 762.50±53.03c 62.65±5.73bc 注:不同小写字母(a~d)表示同组内不同样品之间存在显著性差异(P<0.05)。 
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[1] ZHAO H, CHEN J, HEMAR Y, et al. Improvement of the rheological and textural properties of calcium sulfate-induced soy protein isolate gels by the incorporation of different polysaccharides[J]. Food Chemistry,2020,310:125983. doi: 10.1016/j.foodchem.2019.125983 [2] ZHU Q, ZHAO L, ZHANG H, et al. Impact of the release rate of magnesium ions in multiple emulsions (water-in-oil-in-water) containing BSA on the resulting physical properties and microstructure of soy protein gel[J]. Food Chemistry,2017,220:452−459. doi: 10.1016/j.foodchem.2016.10.016 [3] ZHAO Y Y, CAO F H, LI X J, et al. Effects of different salts on the gelation behaviour and mechanical properties of citric acid-induced tofu[J]. International Journal of Food Science & Technology,2020,55(2):785−794. [4] 王旭峰. CaSO4诱导大豆分离蛋白乳状液凝胶性质影响因素的研究[D]. 无锡: 江南大学, 2017.WANG X F. Study of influencing factors on the properties of soy protein isolate emulsion gels induced by CaSO4[D]. Wuxi: Jiangnan University, 2017. [5] 孟旭, 吴立业, 程超. 豆腐凝固过程的研究进展[J]. 中国调味品,1992(7):2−5. [MENG X, WU L Y, CHENG C. Research progress in tofu solidification process[J]. China Condiment,1992(7):2−5. [6] MYLLARINEN P, BUCHERT J, AUTIO K. Effect of transglutaminase on rheological properties and microstructure of chemically acidified sodium caseinate gels[J]. International Dairy Journal,2007,17(7):800−807. doi: 10.1016/j.idairyj.2005.10.031 [7] 任凯. 豆腐的物性评价模型构建及感官品质优化研究[D]. 南昌: 南昌大学, 2019.REN K. Establishment of tofu physical property evaluation model and sensory quality optimization[D]. Nanchang: Nanchang University, 2019. [8] ERDEM N, BABAOGLU A S, POCAN H B, et al. The effect of transglutaminase on some quality properties of beef, chicken, and turkey meatballs[J]. Journal of Food Processing and Preservation,2020,44(10):14158. [9] ALVES M C, PAULA M M D O, COSTA C G C D, et al. Restructured fish cooked ham: Effects of the use of carrageenan and transglutaminase on textural properties[J]. Journal of Aquatic Food Product Technology,2021,30(4):451−461. doi: 10.1080/10498850.2021.1895942 [10] 汪长青. 预处理对TG酶促小麦与大豆蛋白混合凝胶性质的影响[D]. 合肥: 合肥工业大学, 2018.WANG C Q. Effect of physicochemical pretreatment on transglutaminase-set wheat gluten and soy protein isolate mixture gel[D]. Hefei: Hefei University of Technology, 2018. [11] 臧学丽, 陈光. 转谷氨酰胺酶对大豆蛋白凝胶特性及结构的影响[J]. 西北农林科技大学学报(自然科学版),2018,46(1):86−94. [ZANG X L, CHEN G. Influence of transglutaminase on soybean protein gel preparation and structure[J]. Journal of Northwest A & F University (Natural Science Edition),2018,46(1):86−94. [12] YASIR S B M, SUTTON K H, NEWBERRY M P, et al. The impact of transglutaminase on soy proteins and tofu texture[J]. Food Chemistry,2007,104(4):1491−1501. doi: 10.1016/j.foodchem.2007.02.026 [13] DUARTE L, MATTE C R, BIZARRO C V, et al. Review transglutaminases: Part II-industrial applications in food, biotechnology, textiles and leather products[J]. World Journal of Microbiology & Biotechnology,2019,36(1):1−20. [14] EISSA A S, KHAN S A. Acid-induced gelation of enzymatically modified, preheated whey proteins[J]. Journal of Agricultural & Food Chemistry,2005,53(12):5010−5017. [15] JAROS D, JACOB M, OTTO C, et al. Excessive cross-linking of caseins by microbial transglutaminase and its impact on physical properties of acidified milk gels[J]. International Dairy Journal,2010,20(5):321−327. doi: 10.1016/j.idairyj.2009.11.021 [16] GUO Y, HU H, WANG Q, et al. A novel process for peanut tofu gel: its texture, microstructure and protein behavioral changes affected by processing conditions[J]. LWT-Food Science and Technology,2018,96:140−146. doi: 10.1016/j.lwt.2018.05.020 [17] WAN Y, LIU J, GUO S. Effects of succinylation on the structure and thermal aggregation of soy protein isolate[J]. Food Chemistry,2018,245:542−550. doi: 10.1016/j.foodchem.2017.10.137 [18] HSIEH J F, YU C J, CHANG J Y, et al. Microbial transglutaminase-induced polymerization of beta-conglycinin and glycinin in soymilk: A proteomics approach[J]. Food Hydrocolloids,2014,35:678−685. doi: 10.1016/j.foodhyd.2013.08.020 [19] NOGUEIRA S N F, CASANOVA F, GAUCHERON F, et al. Combined effect of transglutaminase and sodium citrate on the microstructure and rheological properties of acid milk gel[J]. Food Hydrocolloids,2018,82:304−311. doi: 10.1016/j.foodhyd.2018.03.038 [20] DICKINSON E. Enzymic crosslinking as a tool for food colloid rheology control and interfacial stabilization[J]. Trends in Food Science & Technology,1997,8(10):334−339. [21] 邓涵. 转谷氨酰胺酶交联协同热加工对豆腐品质特性和潜在致敏性的影响[D]. 南昌: 南昌大学, 2018.DENG H. Effect of cross-linking with transglutaminase and thermal processing on quality and potential allergenicity of tofu[D]. Nanchang: Nanchang University, 2018. [22] CHANYONGVORAKUL Y, MATSUMURA Y, SAKAMOTO H, et al. Gelation of bean 11S globulins by Ca2+-independent transglutaminase[J]. Bioscience, Biotechnology, and Biochemistry,1994,58(5):864−869. doi: 10.1271/bbb.58.864 [23] LUO K, LIU S, MIAO S, et al. Effects of transglutaminase pre-crosslinking on salt-induced gelation of soy protein isolate emulsion[J]. Journal of Food Engineering,2019,263:280−287. doi: 10.1016/j.jfoodeng.2019.07.008 [24] HESARINEJAD M A, KOOCHEKI A, RAZAVI S M A. Dynamic rheological properties of Lepidium perfoliatum seed gum: Effect of concentration, temperature and heating/cooling rate[J]. Food Hydrocolloids,2014,35:583−589. doi: 10.1016/j.foodhyd.2013.07.017 [25] OZCAN Y T, LEE W J, HORNE D, et al. Effect of trisodium citrate on rheological and physical properties and microstructure of yogurt[J]. Journal of Dairy Science,2007,90(4):1644−1652. doi: 10.3168/jds.2006-538 [26] TSEVDOU M S, ELEFTHERIOU E G, TAOUKIS P S. Transglutaminase treatment of thermally and high pressure processed milk: Effects on the properties and storage stability of set yoghurt[J]. Innovative Food Science and Emerging Technologies,2013,17:144−152. doi: 10.1016/j.ifset.2012.11.004 [27] MAO L, ROOS Y H, MIAO S. Study on the rheological properties and volatile release of cold-set emulsion-filled protein gels[J]. Journal of Agricultural and Food Chemistry,2014,62(47):11420−11428. doi: 10.1021/jf503931y [28] NAJI T S, RAZAVI S M A. New studies on basil (Ocimum bacilicum L.) seed gum: Part II-Emulsifying and foaming characterization[J]. Carbohydrate Polymers,2016,149:140−150. doi: 10.1016/j.carbpol.2016.04.088 [29] RENZETTI S, DAL B F, ARENDT E K. Microstructure, fundamental rheology and baking characteristics of batters and breads from different gluten-free flours treated with a microbial transglutaminase[J]. Journal of Cereal Science,2008,48(1):33−45. doi: 10.1016/j.jcs.2007.07.011 [30] ERCILI C D, LILLE M, LEGLAND D, et al. Structural mechanisms leading to improved water retention in acid milk gels by use of transglutaminase[J]. Food Hydrocolloids,2013,30(1):419−427. doi: 10.1016/j.foodhyd.2012.07.008 [31] LIU Y, ZHANG Y, GUO Z, et al. Enhancing the functional characteristics of soy protein isolate via cross-linking catalyzed by Bacillus subtilis transglutaminase[J]. Journal of the Science of Food and Agriculture,2021,101(10):4154−4160. doi: 10.1002/jsfa.11052 [32] LIU Y, HUANG L, ZHENG D, et al. Characterization of transglutaminase from Bacillus subtilis and its cross-linking function with a bovine serum albumin model[J]. Food and Function,2018,9(11):5560−5568. doi: 10.1039/C8FO01503A [33] DOMAGALA J, NAJGEBAUER L D, WIETESKA S I, et al. Influence of milk protein cross-linking by transglutaminase on the rennet coagulation time and the gel properties[J]. Journal of the Science of Food and Agriculture,2016,96(10):3500−3507. doi: 10.1002/jsfa.7534 -
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