| Citation: |
ZHAO Yi-ke, WU Tong, SUN Meng-qi, WAN Xi-lin, ZHANG Zhe, YANG Hong-mei. Analysis of Antioxidant Peptides Extracted from Freeze-dried American Ginseng by High Resolution Liquid Chromatography Tandem Mass Spectrometry[J]. Journal of Chinese Mass Spectrometry Society, 2024, 45(6): 851-860. DOI: 10.7538/zpxb.2024.0100
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American ginseng contains a variety of active ingredients. Bioactive peptides with biological functions can be obtained by protease hydrolysis, which has physiological activities such as lowering blood pressure, anti-oxidation and antibacterial. The inorganic salts, polysaccharides and free amino acids contained in the hydrolysate of protease will affect the biological activity of peptides to some extent, so it is necessary to further separate and purify the hydrolysate. At present, the commonly used peptides separation methods are time-consuming and labor-intensive, and the yield of target peptide components is low. In this study, large-scale separation and purification of proteins in a short time can be achieved by the protein purification system, which improves work efficiency and reduces costs. Biological activity and functional properties of peptides are stronger than those of protein. Therefore, it is of great significance to study the antioxidant peptides in freeze-dried American ginseng for nutritional evaluation and pharmacological effects. The amino acid composition of the peptides extracted from freeze-dried American ginseng was investigated by ultra-high performance liquid chromatography-quadrupole electrostatic field-Orbitrap tandem mass spectrometry (UHPLC-Q-Orbitrap MS/MS). The crude protein in freeze-dried American ginseng was extracted by alkali-soluble acid precipitation method, and hydrolyzed by various proteases. The optimal protease for enzymatic defrosting of the crude protein was screened out using DPPH free radical clearance as an evaluation index. The crude protein was enzymolized with the best protease, and different components were obtained by 3 ku dialysis bags. The components with better anti-oxidation activity were separated by protein liquid phase analysis system. The results showed that after pepsin hydrolysis for 1 h, DPPH free radical scavenging activity is the best, and the clearance rate is (56.02±2.01)%. Further, the antioxidant activity of <3 ku components is better than that of >3 ku components or endogenous peptides. The components with good antioxidant activity (<3 ku) were separated by ÄKTATMpure protein liquid phase analysis system to evaluate the DPPH free radical scavenging ability and hydroxyl free radical scavenging ability of each fraction, among which F1 and F2 have strong antioxidant activities. The amino acid composition was identified by UHPLC-Q-Orbitrap MS/MS. The hydrophobic amino acids such as Gly, Val and Leu are identified in F1 and F2, which may make them have good antioxidant activities. This method can quickly and effectively identify the antioxidant peptides composition in freeze-dried American ginseng, and provides a basis for revealing the relationship between antioxidant peptides composition and antioxidant activity.
| [1] |
于晓艳, 张宇弛, 方粟一, 葛鹏玲. 西洋参的化学成分和药理作用研究进展[J]. 中医药学报, 2024, 52(4):
YU Xiaoyan, ZHANG Yuchi, FANG Suyi, GE Pengling. Research progress on chemical constituents and pharmacological action of Radix Panacis Quinquefolii[J]. Acta Chinese Medicine and Pharmacology, 2024, 52(4):
|
| [2] |
ZOU Y, DING M, WANG H, XIE H, JIANG M, ZHAO Y, XU X, HU Y, GAO X, WANG H, YANG W. Integration of ion-mobility high-resolution liquid chromatography/mass spectrometry-based untargeted metabolomics and desorption electrospray ionization-mass spectrometry imaging to unveil the ginsenosides variation induced by steaming for Panax ginseng, P. quinquefolius and P. notoginseng[J]. Arabian Journal of Chemistry, 2024, 17(6):
|
| [3] |
汤慧丽, 王宪昌, 李佳, 张教洪, 单成钢. 西洋参皂苷类成分及其生物活性、质量控制的研究进展[J]. 中国中药杂志, 2022, 47(1):
TANG Huili, WANG Xianchang, LI Jia, ZHANG Jiaohong, SHAN Chenggang. Research progress on saponins, biological activities of saponins, and quality control of Panax quinquefolium[J]. China Journal of Chinese Materia Medica, 2022, 47(1):
|
| [4] |
WANG W, SONG L, YANG L, LI C, MA Y, XUE M, SHI D. Panax quinquefolius saponins combined with dual antiplatelet therapy enhanced platelet inhibition with alleviated gastric injury via regulating eicosanoids metabolism[J]. BMC Complementary Medicine and Therapies, 2023, 23(1):
|
| [5] |
FAN J, LIU F, JI W, WANG X, LI L. Comprehensive investigation of ginsenosides in the steamed Panax quinquefolius with different processing conditions using LC-MS[J]. Molecules, 2024, 29(3):
|
| [6] |
JEE H S, CHANG K H, PARK S H, KIM K T, PAIK H D. Morphological characterization, chemical components, and biofunctional activities of Panax ginseng, Panax quinquefolium, and Panax notoginseng Roots: a comparative study[J]. Food Reviews International, 2014, 30(2):
|
| [7] |
翟晓娜, 胡龙彪, 李媛媛, 梁亮, 胡雪芳, 张志民, 班世栋, 王萍, 裴海生. 菜籽饼超微粉酶解制备抗氧化活性肽[J]. 农业工程学报, 2024, 40(4):
ZHAI Xiaona, HU Longbiao, LI Yuanyuan, LIANG Liang, HU Xuefang, ZHANG Zhimin, BAN Shidong, WANG Ping, PEI Haisheng. Preparing antioxidant peptides from ultra-fine powder of rapeseed meal[J]. Transactions of the Chinese Society of Agricultural Engineering, 2024, 40(4):
|
| [8] |
MARCONE S, BELTON O, FITZGERALD D J. Milk-derived bioactive peptides and their health promoting effects: a potential role in atherosclerosis[J]. British Journal of Clinical Pharmacology, 2017, 83(1):
|
| [9] |
XU B, DONG, YU C, CHEN H, ZHAO Y, ZHANG B, YU P, CHEN M. Advances in research on the activity evaluation, mechanism and structure-activity relationships of natural antioxidant peptides[J]. Antioxidants, 2024, 13(4):
|
| [10] |
ZHANG M, HUANG T, MU T. Improvement of thermal, microwave and ultrasonication pretreatment on the production of antioxidant peptides from sweet potato protein via in vitro gastrointestinal digestion[J]. International Journal of Food Science and Technology, 2019, 54(7):
|
| [11] |
WANG W, CHU L, CHEN L, YANG R, ZHU S, ZHANG Y, YANG H. Authentication of Asini Corii Colla and Taurus Corii Colla based on UPLC-MS/MS and the discovery of antioxidant peptides associated with the PI3K-AKT pathway[J]. Natural Product Research, 2023, 37(23):
|
| [12] |
HO T J, TSAI W T, WU J R, CHEN H P. Biological activities of deer antler-derived peptides on human chondrocyte and bone metabolism[J]. Pharmaceuticals, 2024, 17(4):
|
| [13] |
付镓榕, 胡小静, 马尚玄, 王芳, 郭刚军, 黄克昌, 杨悦雪, 贺熙勇. 不同分子量澳洲坚果多肽制备工艺与抗氧化活性[J]. 食品工业科技, 2023, 44(20):
FU Jiarong, HU Xiaojing, MA Shangxuan, WANG Fang, GUO Gangjun, HUANG Kechang, YANG Yuexue, HE Xiyong. Preparation technology and antioxidant activities of different molecular weight macadamia nut polypeptides[J]. Science and Technology of Food Industry, 2023, 44(20):
|
| [14] |
TANG Y, LIANG F, YAN Y, ZENG Y, LI Y, ZHOU R. Purification and identification of peptides from Hydrilla verticillata (Linn. f.) royle with cytoprotective and antioxidative effect against H2O2-treated HepG2 cells[J]. Journal of Agricultural and Food Chemistry, 2024, 72(8):
|
| [15] |
CHEN X, ZHANG S, CAO M, GUO J, LUO R. Isolation of peptide inhibiting SGC-7901 cell proliferation from Aspongopus chinensis Dallas[J]. International Journal of Molecular Sciences, 2022, 23(20):
|
| [16] |
唐晓宁, 吕应年, 吴斌华, 林芊杏, 黄庆, 戚怡. 海洋来源多肽生物活性及提纯方法研究进展[J]. 中国海洋药物, 2021, 40(1):
TANG Xiaoning, LV Yingnian, WU Binhua, LIN Qianxing, HUANG Qing, QI Yi. Advances in research on biological activity and purification methods of marine peptides[J]. Chinese Journal of Marine Drugs, 2021, 40(1):
|
| [17] |
NIU Y, CHEN Y, ZHOU J, SUN W. Online electrochemistry coupling liquid chromatography-mass spectrometry for rapid investigation on the phase I and phase II simulated metabolic reactions of flavonoids[J]. Analytical and Bioanalytical Chemistry, 2024, 416(10):
|
| [18] |
DONG H, YAN G L, HAN Y, SUN H, ZHANG A H, LI X N, WANG X J. UPLC-Q-TOF/MS-based metabolomic studies on the toxicity mechanisms of traditional Chinese medicine Chuanwu and the detoxification mechanisms of Gancao, Baishao, and Ganjiang[J]. Chinese Journal of Natural Medicines, 2015, 13(9):
|
| [19] |
王东萍, 葛万文, 邵晶, 孙延庆. 液相色谱-质谱联用技术分析秦巴硒菇提取物活性成分及其治疗慢性粒细胞白血病的网络药理学研究[J]. 中国药理学通报, 2024, 40(1):
WANG Dongping, GE Wanwen, SHAO Jing, SUN Yanqing. Analysis of effective components of Agaricus blazei Murill extract by LC-MS and network pharmacology analysis in treatment of chronic myeloid leukemia[J]. Chinese Pharmacological Bulletin, 2024, 40(1):
|
| [20] |
毛前程, 马柯, 王嘉昀, 房天赫, 刘蔚然, 张洪秀, 张琦, 田义昭, 徐敏真, 宗鑫. 基于LC-MS法研究百合地黄汤单煎及共煎液中化学成分变化[J]. 辽宁中医药大学学报, 2024, 26(2):
MAO Qiancheng, MA Ke, WANG Jiayun, FANG Tianhe, LIU Weiran, ZHANG Hongxiu, ZHANG Qi, TIAN Yizhao, XU Minzhen, ZONG Xin. Study of the changes of chemical composition in single frying and co-decoction of Baihe Dihuang Decoction based on LC-MS method[J]. Journal of Liaoning University of TCM, 2024, 26(2):
|
| [21] |
GONG P, ZONG W, LI H, WU Y, JU H, FAN Z, MA C, LIU W, LI H. Comprehensive analysis of different types of ginsenosides in the different parts of American ginseng by targeted and nontargeted MS/MS scanning[J]. Journal of Food Science, 2023, 88(12):
|
| [22] |
石杰, 宋淑敏, 魏连会, 杨庆丽, 董艳, 姬妍茹. 碱提酸沉法提取汉麻籽蛋白粉的优化[J]. 食品工业, 2021, 42(9):
SHI Jie, SONG Shumin, WEI Lianhui, YANG Qingli, DONG Yan, JI Yanru. Optimization of extraction of hemp seed protein powder by alkali extraction and acid precipitation[J]. The Food Industry, 2021, 42(9):
|
| [23] |
陈敏, 高广春, 田新朋, 李艳群, 丁文平, 李姣, 尹浩. 皱纹盘鲍内脏抗氧化肽的制备及活性分析[J]. 食品科技, 2022, 47(6):
CHEN Min, GAO Guangchun, TIAN Xinpeng, LI Yanqun, DING Wenping, LI Jiao, YIN Hao. Antioxidant peptides from Haliotis Discus viscera: preparation and in vitro activity evaluation[J]. Food Science and Technology, 2022, 47(6):
|
| [24] |
ZHUANG H, TANG N, YUAN Y. Purification and identification of antioxidant peptides from corn gluten meal[J]. Journal of Functional Foods, 2013, 5(4): 1 810-1 821.
|
| [25] |
刘建伟. 鲢鱼皮多肽的制备及抗氧化活性研究[D]. 武汉: 华中农业大学, 2018.
|
| [26] |
朱清清, 马瑞娟, 陈剑锋, 谢友坪. 响应面法优化鱿鱼皮蛋白肽的制备工艺及其理化性质分析[J]. 食品工业科技, 2024, 45(7):
ZHU Qingqing, MA Ruijuan, CHEN Jianfeng, XIE Youping. Optimization of preparation process of squid skin peptides by response surface methodology and its physicochemical properties[J]. Science and Technology of Food Industry, 2024, 45(7):
|
| [27] |
ZHENG Z, SI D, AHMAD B, LI Z, ZHANG R. A novel antioxidative peptide derived from chicken blood corpuscle hydrolysate[J]. Food Research International, 2018, 106:
|
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