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对植物源活性肽按来源和结构特点进行分类,论述链状植物源活性肽如大豆(Glycine max)、核桃(Juglans mandshurica)、辣木(Moringa oleifera),以及植物环肽如亚麻籽环肽(Linosorbs)等的基本结构、组成以及生物活性。同时对化妆品中具有不同功效的植物源活性肽进行归纳总结和讨论,为其作为功效化妆品原料研究与应用提供科学依据与理论支撑。
Abstract:Plant-derived bioactive peptides were categorized based on their sources and structural characteristics. The basic structure, composition, and biological activities of linear plant-derived bioactive peptides such as those from soybean(Glycine max), walnut(Juglans mandshurica), and moringa(Moringa oleifera) were discussed, as well as plant cyclic peptides like linseed cyclic peptides(Linosorbs). Additionally, it summarized and discussed the various plant-derived bioactive peptides used in cosmetics with different efficacy, providing a scientific basis and theoretical support for their research and application as effective cosmetic ingredients.
[1]董转年,曹佳敏,邓棚,等.不同来源生物活性肽的研究进展[J].安徽农业科学, 2013, 41(9):3768-3769, 3771.
[2] CHAI T T, EE K Y, KUMAR D T, et al. Plant bioactive peptides:current status and prospects towards use on human health[J]. Protein and Peptide Letters, 2021, 28(6):623-642.
[3] SÁNCHEZ A, VÁZQUEZ A. Bioactive peptides:a review[J].Food Quality and Safety, 2017, 1(1):29-46.
[4] REDDY B, JOW T, HANTASH B M. Bioactive oligopeptides in dermatology:part I[J]. Experimental Dermatology, 2012,21(8):563-568.
[5] KARAMI Z, PEIGHAMBARDOUST S H, HESARI J, et al.Antioxidant, anticancer and ACE-inhibitory activities of bioactive peptides from wheat germ protein hydrolysates[J].Food Bioscience, 2019, 32:100450.
[6] TOK K, MOULAHOUM H, KOCADAG KOCAZORBAZ E,et al. Bioactive peptides with multiple activities extracted from Barley(Hordeum vulgare L.)grain protein hydrolysates:biochemical analysis and computational identification[J].Journal of Food Processing and Preservation, 2021, 45(1):e15024.
[7] LIU P, LIAO W, QI X P, et al. Identification of immunomodulatory peptides from zein hydrolysates[J]. European Food Research and Technology, 2020, 246(5):931-937.
[8] LIU N X, WANG Y, ZENG L, et al. RDP3, a novel antigout peptide derived from water extract of rice[J]. Journal of Agricultural and Food Chemistry, 2020, 68(27):7143-7151.
[9] NAISBITT G H, LU M R, GRAY W R, et al. Properties of a small basic peptide from pumpkin seeds[J]. Plant Physiology,1988, 88(3):770-773.
[10] MA S, ZHANG M L, BAO X L, et al. Preparation of antioxidant peptides from oat globulin[J]. Cy TA-Journal of Food, 2020, 18(1):108-115.
[11] ZHANG L Y, MIAO J Y, GUO J B, et al. Two novel angiotensin I-converting enzyme(ACE)inhibitory peptides from rice(Oryza sativa L.)bran protein[J]. Journal of Agricultural and Food Chemistry, 2023, 71(9):4153-4162.
[12]周海军.一种具有美白、抗氧化活性的藜麦肽及其制备方法和应用:113337563B[P]. 2022-09-30.
[13]周媛媛,周瑞宝.大豆多肽的分离纯化与抗氧化活性研究[J].中国油脂, 2008, 33(5):34-36.
[14]陈海敏,华欲飞.大豆蛋白产品的功能及在化妆品中的应用[J].日用化学工业, 2000, 30(6):62-64.
[15] SONKLIN C, ALASHI M A, LAOHAKUNJIT N, et al.Identification of antihypertensive peptides from mung bean protein hydrolysate and their effects in spontaneously hypertensive rats[J]. Journal of Functional Foods, 2020, 64:103635.
[16] DIAO J J, CHI Z P, GUO Z W, et al. Mung bean protein hydrolysate modulates the immune response through NF-κB pathway in lipopolysaccharide-stimulated RAW 264.7macrophages[J]. Journal of Food Science, 2019, 84(9):2652-2657.
[17] KENNEDY K, CAL R, CASEY R, et al. The anti-ageing effects of a natural peptide discovered by artificial intelligence[J].International Journal of Cosmetic Science, 2020, 42(4):388-398.
[18] YANG J J, HU L, CAI T T, et al. Purification and identification of two novel antioxidant peptides from Perilla(Perilla frutescens L. Britton)seed protein hydrolysates[J]. PLo S One,2018, 13(7):e0200021.
[19] MOYER T B, BRECHBILL A M, HICKS L M. Mass spectrometric identification of antimicrobial peptides from medicinal seeds[J]. Molecules, 2021, 26(23):7304.
[20]王虹霁,赵展展,李梦圆,等.植物源抗真菌肽原材料的筛选及桂皮抗菌肽提取工艺的优化[J].西南大学学报(自然科学版), 2023, 45(12):76-84.
[21] ZHANG S B. In vitro antithrombotic activities of peanut protein hydrolysates[J]. Food Chemistry, 2016, 202:1-8.
[22] WANG M, SUN X Y, LUO W, et al. Characterization and analysis of antioxidant activity of walnut-derived pentapeptide PW5 via nuclear magnetic resonance spectroscopy[J]. Food Chemistry, 2021, 339:128047.
[23] FANG L, REN D Y, WANG Z H, et al. Protective role of hazelnut peptides on oxidative stress injury in human umbilical vein endothelial cells[J]. Journal of Food Biochemistry, 2019,43(3):e12722.
[24] MOAYEDI A, MORA L, ARISTOY M C, et al. Peptidomic analysis of antioxidant and ACE-inhibitory peptides obtained from tomato waste proteins fermented using Bacillus subtilis[J]. Food Chemistry, 2018, 250:180-187.
[25] KIMURA S, UCHIDA T, TOKUYAMA Y, et al. Identification of Rubisco anxiolytic-like peptides(r ALPs)by comprehensive analysis of spinach green leaf protein digest[J]. Biochemical and Biophysical Research Communications, 2018, 505(4):1050-1056.
[26]许金光.软枣猕猴桃多肽制备、纯化及其生物活性研究[D].沈阳:沈阳农业大学, 2012.
[27]孙崇臻.桑叶抗氧化肽的酶法制备、结构鉴定及免疫活性分析[D].广州:华南理工大学, 2017.
[28] LIANG L L, CAI S Y, GAO M, et al. Purification of antioxidant peptides of Moringa oleifera seeds and their protective effects on H2O2 oxidative damaged Chang liver cells[J]. Journal of Functional Foods, 2020, 64:103698.
[29]孔箫亭,毛肇洁,胡宁,等.人参肽的分离纯化及活性分析[J].中国食品添加剂, 2022, 33(8):50-57.
[30]陈茜,许泽.一种天然来源的多肽及祛斑美白用途:111593084B[P]. 2022-06-10.
[31] ZHU X C, ZHANG X Y, WANG Z Y, et al. Screening and preparation of highly active antioxidant peptides of apricot and their inhibitory effect on ultraviolet radiation[J]. Food Chemistry, 2025, 463:141336.
[32] GUO X J, SHANG W T, STRAPPE P, et al. Peptides derived from lupin proteins confer potent protection against oxidative stress[J]. Journal of the Science of Food and Agriculture, 2018,98(14):5225-5234.
[33]李笑蕊,王世霞,幺杨,等.裸燕麦和皮燕麦的营养及功能活性成分对比分析[J].粮油食品科技, 2015, 23(5):50-54.
[34] DALY N L, WILSON D T. Plant derived cyclic peptides[J].Biochemical Society Transactions, 2021, 49(3):1279-1285.
[35]赵冕,王磊,冯子迈,等.植物环肽研究进展[J].中国中药杂志, 2024, 49(5):1172-1185.
[36]覃婷,张军.植物环肽生物活性及其作用机制研究进展[J].中草药, 2021, 52(1):255-266.
[37] LINKER S M, SCHELLHAAS C, KAMENIK A S, et al.Lessons for oral bioavailability:how conformationally flexible cyclic peptides enter and cross lipid membranes[J]. Journal of Medicinal Chemistry, 2023, 66(4):2773-2788.
[38]朱洪珍,刘淑集,吴成业,等.海地瓜中具吸湿保湿特性的胶原蛋白肽提取工艺研究[J].福建水产, 2011, 33(5):24-30.
[39] HU D J, SHAKERIAN F, ZHAO J, et al. Chemistry,pharmacology and analysis of Pseudostellaria heterophylla:a mini-review[J]. Chinese Medicine, 2019, 14:21.
[40] YANG C, RUBIN L, YU X Y, et al. Preclinical evidence using synthetic compounds and natural products indicates that AMPK represents a potential pharmacological target for the therapy of pulmonary diseases[J]. Medicinal Research Reviews, 2024, 44(3):1326-1369.
[41] YOON J H, JANG W Y, PARK S H, et al. Anti-melanogenesis effects of a cyclic peptide derived from flaxseed via inhibition of CREB pathway[J]. International Journal of Molecular Sciences, 2022, 24(1):536.
[42] NOH H J, HWANG D, LEE E S, et al. Anti-inflammatory activity of a new cyclic peptide, citrusin XI, isolated from the fruits of Citrus unshiu[J]. Journal of Ethnopharmacology,2015, 163:106-112.
[43] WU P, WU M, XU L X, et al. Anti-inflammatory cyclopeptides from exocarps of sugar-apples[J]. Food Chemistry, 2014, 152:23-28.
[44] SHI W, HAO J T, WU Y L, et al. Protective effects of heterophyllin B against bleomycin-induced pulmonary fibrosis in mice via AMPK activation[J]. European Journal of Pharmacology, 2022, 921:174825.
[45] ROGOZHIN E, RYAZANTSEV D, SMIRNOV A, et al.Primary structure analysis of antifungal peptides from cultivated and wild cereals[J]. Plants, 2018, 7(3):74.
[46]肖怀秋,李玉珍,林亲录,等.抗菌肽结构优化与改造策略研究进展[J].中国酿造, 2021, 40(10):12-18.
[47]李富强,张廷新,朱丽萍,等.食物蛋白源免疫调节肽研究进展[J].食品与发酵工业, 2022, 48(1):308-314.
[48] YAP P G, GAN C Y. Tyrosinase inhibitory peptides:structureactivity relationship study on peptide chemical properties,terminal preferences and intracellular regulation of melanogenesis signaling pathways[J]. Biochimica et Biophysica Acta(BBA)-General Subjects, 2024, 1868(1):130503.
[49] NAWROT R, BARYLSKI J, NOWICKI G, et al. Plant antimicrobial peptides[J]. Folia Microbiologica, 2014, 59(3):181-196.
基本信息:
DOI:10.20099/j.issn.1000-4475.2024.0411
中图分类号:TQ658
引用信息:
[1]邵浩凡,孙晓曼,李淼,等.植物源肽类原料在化妆品中的应用与研究进展[J].香料香精化妆品,2026,No.214(01):23-28+63.DOI:10.20099/j.issn.1000-4475.2024.0411.
2026-02-28
2026-02-28