[Objective]The milk-derived glycomacropeptide(CGMP) was obtained by enzymatic hydrolysis of cow's milk using rennet.Due to the tolerance difference of CGMP to trichloroacetic acid,the separation and purification of CGMP was realized. The β-casein was separated from the casein hydrolyzed by rennet by the characteristic that β-casein was easily freed under low temperature and low acid conditions.[Method]The defatted fresh milk was fully enzymatically hydrolyzed by adding an appropriate amount of rennet at 35 ℃,and centrifuged to obtain the supernatant and precipitate. Trichloroacetic acid was added to the supernatant to remove the impurities of CGMP,and the purity of the obtained precipitated CGMP was measured by high performance liquid chromatography.The precipitation was redissolved in alkaline and the temperature was lowered.Then the pH value was adjusted to 3.5 under the condition of low temperature throughout the whole process.The supernatant was collected by centrifugation at low temperature.After that,the temperature was raised to 35 ℃ to gain β-casein with centrifugation at room temperature.Its purity was determined by high performance liquid chromatography.[Result]3% trichloroacetic acid could better remove impurities after CGMP enzymatic hydrolysis.CGMP was completely precipitated by 10% trichloroacetic acid.The purity of the final CGMP product was 80% to 90% and the β-casein with treatment of low temperature and low acid had a purity of 85% to 90%.
PAN Xuechun, HUANG Yu, QIAN Chenglin
. Separation and Purification of Milk Derived Glycomegapeptide and β-Casein[J]. China Dairy, 2024
, 0(2)
: 89
-93
.
DOI: 10.12377/1671-4393.24.02.17
[1] Tanimoto M,Kawasaki Y,Dosako Shun’ichi,et al.Large-scale preparation of κ-casein glycomacropeptide from rennet casein whey[J].Bioscience,Biotechnology,and Biochemistry,1992,56(1):140-141.
[2] Nakano T,Ozimek L,Betti M.Separation of bovine K-casein glycomacropeptide from sweet whey protein products with undetectable level of phenylalanine by protein precipitation followed by anion exchange chromatography[J].Journal of Dairy Research,2018,85(1):110-113.
[3] Hoefle A S,Bangert A M,Rist M J,et al.Postprandial metabolic responses to ingestion of bovine glycomacropeptide compared to a whey protein isolate in prediabetic volunteers[J]. European Journal of Nutrition,2018,58(5):2067-2077.
[4] Li E W Y,Mine Y. Technical note:Comparison of chromatographic profile of glycomacropeptide from cheese whey isolated using different methods[J].Journal of Dairy Science,2004,87(1):174-177.
[5] 石卉,郑少伟,黄龙光,等.母乳及配方乳中糖巨肽对体外婴儿双歧杆菌增殖活性的影响[J].中华围产医学杂志,2016,19(7):528-533.
[6] 秦玉兰,苏雅洁.苯丙酮尿症治疗研究新进展[J].国际儿科学杂志,2018,45(8):624-628.
[7] 朱玉英,王存芳.凝乳酶的发展及其在奶酪生产中的应用[J].乳业科学与技术,2015,38(4):25-28.
[8] 李委红,刘会平,孙娜新,等.酪蛋白糖巨肽(GMP)的研究进展[J].中国乳品工业,2018,46(8):37-40,64. 曹荣安,贾建,杨楠,等.牛乳清中酪蛋白糖巨肽的分离纯化[J]. 现代食品,2016,1(1):89-93.
[9] 吴疆,班立桐,童应凯,等.乳源酪蛋白糖巨肽分离条件的研究[J].天津农学院学报,2009,16(1):32-34.
[10] 张艳,胡志和,赖宜萍.牛乳中α_s-、β-酪蛋白组分的分离[J].食品科学,2009,30(14):31-36.
[11] 闫亚丽,陈庆森,李博智,等.酪蛋白巨肽(Caseinomacropeptides)检测方法的初步研究[J].食品科技,2010,35(7):284-286,299.
[12] 蔡焕新,殷宝茹,姚萍.酪蛋白多肽的制备和色谱分离方法[J].色谱,2010,28(7):637-643.
[13] 潘宇,朱学军,牟颖.高效液相色谱法分析纯化合成肽[J].生命科学仪器,2008,6(9):13-18.
[14] 李武祎,郭顺堂,俞树孝,等.酪蛋白组分分离技术及消化性测定[J].食品科学,2005,26(7):70-73.
