荧光标记多糖的制备及应用

doi:10.19677/j.issn.1004-7964.2023.01.007

皮革科学与工程 ›› 2023, Vol. 33 ›› Issue (1): 36-45.doi: 10.19677/j.issn.1004-7964.2023.01.007

荧光标记多糖的制备及应用

朱敏¹, 王亚楠^1,2,*

1.四川大学制革清洁技术国家工程实验室,四川成都 610065;
2.四川大学皮革化学与工程教育部重点实验室,四川成都 610065

收稿日期:2022-06-28 出版日期:2023-02-01 上线日期:2023-01-04
通讯作者: *王亚楠（1986-）,男,教授,主要从事制革化学、制革清洁技术研究。E-mail: wangyanan@scu.edu.cn。
作者简介:朱敏（1997-）,女,硕士生。
基金资助:
国家自然科学基金（22278280）; 四川省科技创新人才项目（2022JDRC0029）; 四川省“天府万人计划”天府科技菁英项目

Preparation and Application of Fluorescent Labeling Polysaccharide

ZHU Min¹, WANG Yanan^1,2,*

1. National Engineering Laboratory for Clean Technology of Leather Manufacture, Sichuan University, Chengdu 610065, China;
2. Key Laboratory of Leather Chemistry and Engineering of Ministry of Education, Sichuan University, Chengdu 610065, China

Received:2022-06-28 Online:2023-02-01 Published:2023-01-04

摘要/Abstract

摘要： 多糖是一类来源丰富、可降解和可再生的天然高分子,广泛应用于食品、医药、造纸、皮革等行业。然而,由于多糖结构中缺少可被特异性检测的基团,使得其在应用时的定性/定量分析较为困难。荧光标记技术能赋予多糖可被检测的荧光基团,是实现多糖应用可视化、进而研究多糖功能与作用机理的重要手段。文章综述了常见的荧光标记多糖的方法,包括在多糖的羟基、羧基和醛基引入荧光素的荧光标记法,以及通过化学反应构造共轭结构的自发荧光法,详细阐述了不同荧光标记法的原理、标记条件和应用效果。总结和展望了荧光多糖在荧光示踪、生物成像、食品监测、水质监测和智能包装材料等领域的应用。

关键词: 多糖, 荧光标记, 荧光示踪, 荧光素, 自发荧光

Abstract: Polysaccharide is a kind of abundant, degradable and renewable natural macromolecules, which is widely used in food, medicine, papermaking, leather and other industries. However, the lack of specific detectable groups in molecular structures of polysaccharides results in the difficulty in their qualitative/quantitative analysis. Fluorescent labeling technology can endow polysaccharides with detectable fluorescent groups, which is an important way to achieve the visualization of polysaccharides during their application and further investigate their function and action mechanisms. This paper reviewed the common fluorescent labeling methods of polysaccharides, including the fluorescent labeling methods by introducing fluorescein into the hydroxyl, carboxyl and aldehyde groups of polysaccharides, and the autofluorescence method by constructing conjugated structures through chemical reactions. The principles, labeling conditions and applications of different fluorescent labeling methods were described in detail. The applications of fluorescent polysaccharides in the fields of fluorescent tracing, bioimaging, food monitoring, water quality monitoring and intelligent packaging materials were summarized and prospected.

Key words: polysaccharides, fluorescent labeling, fluorescent tracing, fluorescein, autofluorescence

中图分类号:

Q946

朱敏, 王亚楠. 荧光标记多糖的制备及应用[J]. 皮革科学与工程, 2023, 33(1): 36-45.

ZHU Min, WANG Yanan. Preparation and Application of Fluorescent Labeling Polysaccharide[J]. Leather Science and Engineering, 2023, 33(1): 36-45.

参考文献

[1] Yu Y,Shen M,Song Q,et al.Biological activities and pharmaceutical applications of polysaccharide from natural resources:A review[J].Carbohydrate Polymers,2018,183:91-101.
[2] Dwek R A.Glycobiology:toward understanding the function of sugars[J].Chemical reviews,1996,96(2):683-720.
[3] Nasrollahzadeh M,Sajjadi M,Iravani S,et al.Starch,cellulose,pectin,gum,alginate,chitin and chitosan derived(nano)materials for sustainable water treatment:A review[J].Carbohydrate Polymers,2021,251:116986.
[4] Giepmans,B N G.The fluorescent toolbox for assessing protein location and function[J].Science,2006,312(5771):217-224.
[5] Waggoner A.Fluorescent labels for proteomics and genomics[J].Current Opinion in Chemical Biology,2006,10(1):62-66.
[6] Lavis L D,Raines R T.Bright ideas for chemical biology[J].ACS Chemical Biology,2008,3(3):142-155.
[7] Kristiansen K A.Potthast B E.Periodate oxidation of polysaccharides for modification of chemical and physical propertiest[J].Carbohydrate Research,2010, 345(10):1264-1271.
[8] De H P,Gamez P,Driessen W L,et al.New polydentate and polynucleating N-donor ligands from amines and 2,4,6-trichloro-1,3,5-triazine[J].Tetrahedron Letter,2002,43(38):6783-6783.
[9] Abitbol T,Palermo A,Moran-Mirabal J M.Fluorescent labeling and characterization of cellulose nanocrystals with varying charge contents[J].Biomacromolecules,2013,14(9):3278-3284.
[10] Helbert W,Chanzy H,Husum T L,et al.Fluorescent cellulose microfibrils as substrate for the detection of cellulase activity[J].Macromolecules,2003,4(3):481-487.
[11] Reid M S,Karlsson M,Abitbol T.Fluorescently labeled cellulose nanofibrils for detection and loss analysis[J].Carbohydrate Polymers,2020,250:116943.
[12] Norton A B,Hancocks R D,Spyropoulos F,et al.Development of 5-(4,6-dichlorotriazinyl)aminofluorescein(DTAF)staining for the characterisation of low acyl gellan microstructures[J].Food Hydrocolloids,2016,53(1-2):93-97.
[13] Khin M N,Ahammed S,Zhong F.Development of(5-(4, 6- dichlorotriazinyl)aminofluorescein) DTAF-labelled polysaccharides for characterization of microstructure and phase distribution of composite hydrogel Visualization of hydrogels using CLSM[J].Food Bioscience,2021,41:100909.
[14] Hoffmann C,Leroy-Dudal J,Patel S,et al.Fluorescein isothiocyanate-labeled human plasma fibronectin in extracellular matrix remodeling[J].Analytical Biochemistry,2008,372(1):62-71.
[15] Eyley S,Thielemans W.Surface modification of cellulose nanocrystals[J].Nanoscale,2014,6(14):7764-7779.
[16] Dong S,Roman M.Fluorescently labeled cellulose nanocrystals for bioimaging applications[J].Journal of the American Chemical Society,2007,129(45):13810-13811.
[17] Roman M,Dong S,Hirani A,et al.Cellulose nanocrystals for drug delivery[M].Polysaccharide Materials:Performance by Design,2009,1071:81-91.
[18] Fan X M,Yu H Y,Wang D C,et al.Designing highly luminescent cellulose nanocrystals with modulated morphology for multifunctional bioimaging materials[J].ACS Applied Materials&Interfaces,2019,11(51):48192-48201.
[19] Mahmoud K A,Mena J A,Male K B,et al.Effect of surface charge on the cellular uptake and cytotoxicity of fluorescent labeled cellulose nanocrystals[J].ACS Applied Materials&Interfaces,2010,2(10):2924-2932.
[20] Purington E,Bousfield D,Gramlich W M.Fluorescent dye adsorption in aqueous suspension to produce tagged cellulose nanofibers for visualization on paper[J].Cellulose,2019,26(8):5117-5131.
[21] Cai C,Wei B,Jin Z,et al.Facile method for fluorescent labeling of starch nanocrystal[J].ACS Sustainable Chemistry&Engineering,2017,5(5):3751-3761.
[22] Ghosh S K,Abdullah F,Mukherjee A.Fabrication and fluorescent labeling of guar gum nanoparticles in a surfactant free aqueous environment[J].Materials Science&Engineering C,2015,46(46):521-529.
[23] Hu Q,Chen Q,Yan X,et al.Chondrocyte affinity peptide modified PAMAM conjugate as a nanoplatform for targeting and retention in cartilage[J].Nanomedicine,2018,13(7):749-767.
[24] Mahmoud K A,Mena J A,Male K B,et al.Effect of surface charge on the cellular uptake and cytotoxicity of fluorescent labeled cellulose nanocrystals[J].ACS Applied Materials&Interfaces,2010,2(10):2924-2932.
[25] Ding Q,Zeng J,Wang B,et al.Influence of binding mechanism on labeling efficiency and luminous properties of fluorescent cellulose nanocrystals[J].Carbohydrate Polymers,2017,175:105-112.
[26] Ding Q,Zeng J,Wang B,et al.Effect of retention rate of fluorescent cellulose nanofibrils on paper properties and structure[J].Carbohydrate Polymers,2018,186:73-81.
[27] Hobisch M A,Bossu J,Mandlez D,et al.Localization of cellulosic fines in paper via fluorescent labeling[J].Cellulose,2019,26(11):6933-6942.
[28] Hobisch M,Zabler S,Bardet S M,et al.How cellulose nanofibrils and cellulose microparticles impact paper strength-a visualization approach[J].Carbohydrate Polymers,2020,254:117406.
[29] Nielsen L J,Eyley S,Thielemans W,et al.Dual fluorescent labelling of cellulose nanocrystals for pH sensing[J].Chemical Communications,2010,46(47):8929-8931.
[30] Ursuegui S,Chivot N,Moutin S,et al.Biotin-conjugated N-methylisatoic anhydride:a chemical tool for nucleic acid separation by selective 2prime-hydroxyl acylation of RNA[J].Chemical Communications Royal Society of Chemistry,2014,50:5748.
[31] Coppola G M.A convenient preparation of 1,4-dihydro-1-methyl-4-oxo-2-quinolinecarboxaldehyde from N- methylisatoic anhydride[J].Journal of Heterocyclic Chemistry,1986,23(6):1717-1719.
[32] Steen K A,Rice G M,Weeks K M.Fingerprinting noncanonical and tertiary RNA structures by differential shape reactivity[J].Journal of the American Chemical Society,2012,134(32):13160.
[33] Deangelis P L.Polysaccharide labeling with N-methylisatoic anhydride:Generation of ultraviolet chromophores and blue fluorophores[J].Analytical Biochemistry,2000,284(1):167-169.
[34] 涂宗财,李如一,石燕,等.一种N-甲基靛红酸酐快速标记多糖的制备方法[P].CN201410748956.X,2015-04-22.
[35] 齐猛. N-甲基靛红酸酐标记杠柳新苷P分离粘虫中肠结合蛋白的研究[D].西安:西北农林科技大学,2015.
[36] Kibler M,Bachmann K.New derivatization method for carboxylic acids in aqueous solution for analysis by capillary electrophoresis and laser-induced fluorescence detection[J].Journal of Chromatography A,1999,836(2):325-331.
[37] Zeng Y,Song Y,Li J,et al.Visualization and quantification of penetration/mass transfer of acrylic resin retanning agent in leather using fluorescent tracing technique[J].Journal of the American Leather Chemists Association,2016,111(11):398-405.
[38] Nakajima N,Ikada Y.Mechanism of amide formation by carbodiimide for bioconjugation in aqueous media[J].Bioconjugate chemistry,1995,6(1):123-130.
[39] Hu T Q,Hayek A.A green technology for fibre modification,part I:Attaching a fluorescent molecule to cellulose fibres and their potential highvalue applications[J].Journal of Science&Technology for Forest Products and Processes,2013,3(3):34-40.
[40] Wang C,Gao M,Huang Z,et al.Characterization of saccharide using high fluorescent 5-(((2-(carbohydrazino)methyl)thio)acetyl)-aminofluorescein tag by Capillary-HPLC-LIF and MALDI-TOF-MS[J].Talanta,2013,117:229-234.
[41] Han Z,Wang Y,Liu X,et al.Fluorescent labeling of several gycosaminoglycans and their interaction with anti-chondroitin sulfate antibody[J].Chinese Journal of Analytical Chemistry,2011,39(9):1352-1357.
[42] 焦广玲. 几种大西洋来源海藻多糖及其衍生物抗2型糖尿病活性的比较研究[D].青岛:中国海洋大学,2011.
[43] 赵小亮. 利用糖芯片研究海洋多糖及其衍生物与蛋白质的相互作用[D].青岛:中国海洋大学,2013.
[44] Ruhaak L R,Zauner G,Huhn C,et al.Glycan labeling strategies and their use in identification and quantification[J].Analytical and Bioanalytical Chemistry,2010,397(8):3457-3481.
[45] O’Shea M G,Samuel M S,Konik C M,et al.Fluorophore-assisted carbohydrate electrophoresis(FACE)of oligosaccharides:efficiency of labelling and high- resolution separation[J].Carbohydrate Research,1998,105(1-2):1-12.
[46] Zoltan S,András G,Tomas R,et al.Improved sample preparation method for glycan analysis of glycoproteins by CE-LIF and CE-MS[J].Electrophoresis,2010,31(8):1389-1395.
[47] Bui A,Kocsis B,Kilár F.Methodology to label mixed carbohydrate components by APTS[J].Journal of biochemical and biophysical methods,2008,70(6):1313-1316.
[48] Bunz S C,Cutillo F.Analysis of native and APTS-labeled N-glycans by capillary electrophoresis/time-of-flight mass spectrometry[J].Analytical and Bioanalytical Chemistry,2013,405(25):8277-8284.
[49] Evangelista R A,Guttman A,Chen F.Acid-catalyzed reductive amination of aldoses with 8-aminopyrene- 1,3,6-trisulfonate[J].Electrophoresis,1996,17(2):347-351.
[50] Mitra I,Snyder C M,Zhou X,et al.Structural characterization of serum N-glycans by methylamidation,fluorescent labeling,and analysis by microchip electrophoresis[J].Analytical Chemistry,2016:88(18):8965-8971.
[51] Che F Y,Song J F,Rong Z,et al.Analysis of 8-aminonaphthalene-1,3,6-trisulfonate-derivatized oligosaccharides by capillary electrophoresis-electrospray ionization quadrupole ion trap mass spectrometry[J].Journal of Chromatography A,1999,858(2):229-238.
[52] Jackson P.The use of polyacrylamide-gel electrophoresis for the high-resolution separation of reducing saccharides labelled with the fluorophore 8-aminonaphthalene-1,3,6-trisulphonic acid.Detection of picomolar quantities by an imaging system based on a cooled char[J].Biochemical Journal,1990,270(3):705-13.
[53] Roger O,Colliec-Jouault S,Ratiskol J,et al.Polysaccharide labelling:impact on structural and biological properties[J].Carbohydrate Polymers,2002,50(3):273-278.
[54] Gennaro L A,Delaney J,Vouros P,et al.Capillary electrophoresis/electrospray ion trap mass spectrometry for the analysis of negatively charged derivatized and underivatized glycans[J].Rapid Communications in Mass Spectrom,2002,16(3):192-200.
[55] Gennaro L A,Harvey D J,Vouros P.Reversed-phase ion-pairing liquid chromatography/ion trap mass spectrometry for the analysis of negatively charged,derivatized glycans[J].Rapid Communications in Mass Spectrometry,2003,17(14):1528-1534.
[56] Oonuki Y,Yoshida Y,Uchiyama Y,et al.Application of fluorophore-assisted carbohydrate electrophoresis to analysis of disaccharides and oligosaccharides derived from glycosaminoglycans[J].Analytical Biochemistry,2005,343(2):212-222.
[57] Hardman R.A toxicologic review of quantum dots:toxicity depends on physicochemical and environmental factors[J].Environmental Health Perspectives,2006,114(2):165-172.
[58] Choi H S,Liu W,Misra,et al.Renal clearance of quantum dots[J].Nature Biotechnology,2007,25:1165-1170.
[59] Thomas S W I,Joly G D,Swager T M.Chemical sensors based on amplifying fluorescent conjugated polymers[J].Chemical Reviews,2007,107:1339-1386.
[60] Fernando L P,Kandel P K,Yu J,et al.Mechanism of cellular uptake of highly fluorescent conjugated polymer nanoparticles[J].Biomacromolecules,2010,11(10):2675-2682.
[61] Dan D,Jing L,Shi H,et al.Light-up bioprobe with aggregation-induced emission characteristics for real-time apoptosis imaging in target cancer cells[J].Journal of Materials Chemistry B,2013,2(2):231-238.
[62] Cui K,Lu X,Cui W,et al.Fluorescent nanoparticles assembled from a poly(ionic liquid)for selective sensing of copper ions[J].Chemical Communications,2011,47(3):920-922.
[63] Osakada Y,Hanson L,Cui B.Diarylethene doped biocompatible polymer dots for fluorescence switching[J].Chemical Communications,2012,48(27):3285-3287.
[64] Wu C,Schneider T,Zeigler M,et al.Bioconjugation of ultrabright semiconducting polymer dots for specific cellular targeting[J].Journal of the American Chemical Society,2010,132(43):15410-15417.
[65] Zhang X,Wang S,Xu L,et al.Biocompatible polydopamine fluorescent organic nanoparticles:facile preparation and cell imaging[J].Nanoscale,2012,4(18):5581-5584.
[66] Liu M,Ji J,Zhang X,et al.Self-polymerization of dopamine and polyethyleneimine:novel fluorescent organic nanoprobes for biological imaging applications[J].Journal of Materials Chemistry B Materials for Biology&Medicine,2015,3(17):3476-3482.
[67] Shi Y,Xu D,Liu M,et al.Room temperature preparation of fluorescent starch nanoparticles from starch-dopamine conjugates and their biological applications[J].Materials Science&Engineering C,2018,82:204-209.
[68] Zhu Y,Wang J,Li X,et al.Self-assembly and emulsification of dopamine-modified hyaluronan[J].Carbohydrate Polymers,2015,123:72-79.
[69] Ryu J H,Hong S,Lee H.Bio-inspired adhesive catechol-conjugated chitosan for biomedical applications:A mini review[J].Acta Biomaterialia,2015,27:101-115.
[70] Cassano R,Trapani A,Gioia M L D,et al.Synthesis and characterization of novel chitosan-dopamine or chitosan-tyrosine conjugates for potential nose-to-brain delivery[J].International Journal of Pharmaceutics,2020,589:119829.
[71] Wei W,Yuan L,Hu G,et al.Monodisperse chitosan microspheres with interesting structures for protein drug delivery[J].Advanced Materials,2008,20(12):2292-2296.
[72] Wei W,Wang L,Yuan L,et al.Preparation and application of novel microspheres possessing autofluorescent properties[J].Advanced Functional Materials,2007,17(16):3153-3158.
[73] Hwang Y J,Larsen J,Krasieva T B,et al.Effect of genipin crosslinking on the optical spectral properties and structures of collagen hydrogels[J].ACS Applied Materials&Interfaces,2011,3(7):2579-2584.
[74] Yao F,Li X,Yu X,et al.Crosslinking reaction of chitosan and gelatin with genipin[J].Journal of Tianjin University,2007,40(12):1485-1489.
[75] Nickerson M T,Patel J,Heyd D V,et al.Kinetic and mechanistic considerations in the gelation of genipin-crosslinked gelatin[J].International Journal of Biological Macromolecules,2006,39(4-5):298-302.
[76] Yuan L,Li X,Ge L,et al.Emulsion template method for the fabrication of gelatin-based scaffold with a controllable pore structure[J].ACS Applied Materials&Interfaces,2018,11(1):269-277.
[77] Song Y,Wu S,Wang Y N,et al.Visualization of penetration and reaction of aldehyde tanning agent in leather using fluorescence technique[J].Journal of the American Leather Chemists Association,2020,115(7):248-254.
[78] Zhang R,Zhang X X,Tang Y X,et al.Composition,isolation,purification and biological activities of Sargassum fusiforme polysaccharides:A review[J].Carbohydrate Polymers,2019, 228:115381.
[79] Sun M M,Su F C,Yang J X,et al.Fluorescent labeling of polysaccharides from masson pine pollen and its effect on raw264.7 macrophages[J].Polymers,2018,10(4):372.
[80] Wang K,Cheng F,Pan X,et al.Investigation of the transport and absorption of Angelica sinensis polysaccharide through gastrointestinal tract both in vitro and in vivo[J].Drug Delivery,2017,24(1):1360-1371.
[81] 丁雷. 天然多糖基高分子染料的构建与应用研究[D].上海:东华大学,2021.
[82] Ding L,Li X,Hu L,et al.A naked-eye detection polyvinyl alcohol/cellulose-based pH sensor for intelligent packaging[J].Carbohydrate Polymers,2020,233:115859.
[83] Chauhan P,Hadad C,López A H,et al.A nanocellulose-dye conjugate for multi-format optical pH-sensing[J].Chemical Communications,2014,50(67):9493-9496.
[84] Ferreira L V,Cabral P V,Almeida P,et al.Ultraviolet visible absorption,luminescence,and X-ray photoelectron spectroscopic studies of a rhodamine dye covalently bound to microcrystalline cellulose[J].Macromolecules,1998,31(12):3936-3944.
[85] Zen,K.Second messengers regulate endosomal acidification in Swiss 3T3 fibroblasts[J].The Journal of Cell Biology,1992,119(1):99-110.
[86] 刘俊,夏传杰,王康龙,等.基于海藻酸钠电沉积技术制备ZnO量子点及其复合膜的检测应用研究[J].高分子学报,2022,53(2):145-152.
[87] Chen W,Lei J,Wang Y,et al.Direct generation of Mn-doped ZnS quantum dots/alginate nanocomposite beads based on gelation and in situ synthesis of quantum dots[J].Macromolecular Materials and Engineering,2019,304(4):1800681.
[88] Park S,Lee M R,Shin I.Carbohydrate microarrays as powerful tools in studies of carbohydrate-mediated biological processes[J].Chemical Communications,2008,(37):4389-4399.
[89] 薛彦峰,王秀奎,侯信,等.糖芯片研究[J].化学进展,2008,20(1):148-154.
[90] 黄河,贾红英,侯信.糖芯片的检测及应用[J].化学通报,2009,72(5):401-406.
[91] Baum A,Dominiak M,Vidal-Melgosa S,et al.Prediction of pectin yield and quality by FTIR and carbohydrate microarray analysis[J].Food and Bioprocess Technology,2017,10(1):143-154.
[92] 沈一鸣,马建中,范倩倩.天然多糖与纳米材料在皮革无铬鞣制中的研究进展[J].精细化工,2022,39(5):865-872.
[93] Ding W,Zhou J,Zeng Y,et al.Preparation of oxidized sodium alginate with different molecular weights and its application for crosslinking collagen fiber[J].Carbohydrate Polymers,2017,157:1650-1656.
[94] Ding W,Yi Y,Wang Y N,et al.Preparation of a highly effective organic tanning agent with wide molecular weight distribution from bio-renewable sodium alginate[J].Chemistryselect,2018,3(43):12330-12335.
[95] Ding W,Wang Y N,Zhou J F,et al.Effect of structure features of polysaccharides on properties of dialdehyde polysaccharide tanning agent[J].Carbohydrate Polymers,2018,201:549-556.
[96] Ding W,Pang X Y,Ding Z W,et al.Constructing a robust chrome-free leather tanned by biomass-derived polyaldehyde via crosslinking with chitosan derivatives[J].Journal of Hazardous Materials,2020,396:122771.
[97] 黄婉丽,杨紫涵,王亚楠,等.双醛壳聚糖的制备及其对皮胶原纤维的交联作用[J].皮革科学与工程,2021,31(2):1-5.
[98] Ding W,Yi Y D,Wang Y N,et al.Peroxide-periodate co-modification of carboxymethylcellulose to prepare polysaccharide-based tanning agent with high solid content[J].Carbohydrate Polymers,2019,224:115169.

荧光标记多糖的制备及应用

Preparation and Application of Fluorescent Labeling Polysaccharide

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