Spectroscopic study of the interaction between PEG/a-cyclodextrin pseudopolyrotaxane hydrogel with BSA

doi:10.16085/j.issn.1000-6613.2016.11.031

Chemical Industry and Engineering Progress ›› 2016, Vol. 35 ›› Issue (11): 3590-3594.DOI: 10.16085/j.issn.1000-6613.2016.11.031

Previous Articles Next Articles

Spectroscopic study of the interaction between PEG/a-cyclodextrin pseudopolyrotaxane hydrogel with BSA

LIN Jiduan¹, ZHAO Jun^1,2

1. Department of Bioengineering and Biotechnology, College of Chemical Engineering, Huaqiao University, Xiamen 361021, Fujian, China;
2. Institute of Oil and Natural Products, Huaqiao University, Xiamen 361021, Fujian, China

Received:2016-01-28 Revised:2016-06-15 Online:2016-11-05 Published:2016-11-05

PEG/a-环糊精准聚轮烷水凝胶与BSA相互作用的光谱学研究

林集端¹, 赵珺^1,2

1. 华侨大学化工学院生物工程与技术系, 福建厦门 361021;
2. 华侨大学油脂及天然产物研究所, 福建厦门 361021

通讯作者: 赵珺,博士,讲师。E-mail:zhaojun@hqu.edu.cn。
作者简介:林集端(1990-),男,硕士研究生,研究方向为环糊精水凝胶。
基金资助:
福建省自然科学基金（2013J05028）、华侨大学引进人才科研启动项目（11BS408）及华侨大学研究生科研创新能力培育计划项目。

Abstract

Abstract: Self-assembled pseudopolyrotaxane hydrogel formed by polyethylene glycol (PEG) and cyclodextrin (CD) can be used as a slow-release carrier for proteins. In this ternary system, there may be certain interactions between PEG, CD and proteins. With bovine serum albumin (BSA) as the model protein, the structure changes of BSA in the PEG/a-CD pseudopolyrotaxane hydrogel was studied by ultraviolet-visible absorption spectrum, fluorescence spectrum, powder X-ray diffraction (XRD) techniques, and NOESY spectra. The results showed that BSA had a significant effect on the formation rate of the hydrogel. The fluorescence and synchronous fluorescence spectrum analysis showed that the ternary structure of BSA had minor changes in the hydrogel, which led to red-shift of the maximum fluorescence emission wavelength, and the microenvironment of Trp and Tyr residues also changed slightly in the hydrogel. These changes became more significant with the increasing of BSA concentration. Moreover, when BSA was added, the diffraction angles in XRD spectra at 2q = 6.56°, 11.54°, 12.06°, 20.56°, 22.04°and 26.04°showed remarkable changes compared with those of the pure pseudopolyrotaxane, demonstrating that the crystalline pattern of PEG/a-CD pseudopolyrotaxane was changed in the presence of BSA. The results reflected that BSA was not simply physically mixed with the PEG/a-CD pseudopolyrotaxane hydrogel, but that it might prefer to form complexes with the hydrogel. 2D NOESY spectra also showed that the presence of mutual coupling of hydrogen atoms between BSA and PEG/a-CD, demonstrated the interaction between them.

Key words: pseudopolyrotaxane hydrogel, bovine serum albumin, cyclodextrin, polyethylene glycol, spectroscopy, powder X-ray diffraction

摘要： 聚乙二醇（PEG）与环糊精（CD）自组装形成的准聚轮烷水凝胶可作为蛋白缓释载体。在此三元体系中，PEG、CD和蛋白质之间可能存在一定的相互作用。本文以牛血清白蛋白（BSA）为模型蛋白，通过紫外-可见吸收光谱，荧光光谱，X射线粉末衍射（XRD）和NOESY谱分析等技术，研究BSA在PEG/a-CD准聚轮烷水凝胶中结构的变化。结果表明BSA对水凝胶的生成速率具有显著的影响。通过荧光光谱和同步荧光光谱分析可知，BSA在水凝胶中其三级结构发生轻微变化，致使最大荧光发射波长发生红移，而Trp和Tyr残基在水凝胶中其微环境发生了微小变化。这些变化随着BSA浓度的提高而趋于显著。对比XRD谱图发现，水凝胶在加入BSA前后，2q = 6.56°、11.54°、12.06°、20.56°、22.04°、26.04°这些衍射角位置的谱峰发生明显变化，说明BSA对PEG/a-CD准聚轮烷的晶型有一定的改变，反映了BSA与水凝胶不只是单纯的混合，而且存在形成复合物而改变蛋白质结构的可能性。2D NOESY谱图也表明BSA与PEG/a-CD准聚轮烷之间存在氢原子的相互耦合作用，证明了两者之间的相互作用。

关键词: 准聚轮烷水凝胶, 牛血清白蛋白, 环糊精, 聚乙二醇, 光谱, X射线粉末衍射

CLC Number:

O636.1

LIN Jiduan, ZHAO Jun. Spectroscopic study of the interaction between PEG/a-cyclodextrin pseudopolyrotaxane hydrogel with BSA[J]. Chemical Industry and Engineering Progress, 2016, 35(11): 3590-3594.

林集端, 赵珺. PEG/a-环糊精准聚轮烷水凝胶与BSA相互作用的光谱学研究[J]. 化工进展, 2016, 35(11): 3590-3594.

References

[1] HARADA A,KAMACHI M. Complex formation between poly(ethylene glycol) and a-cyclodextrin[J]. Macromolecules,1990,23(10):2821-2823.
[2] HARADA A,LI J,KAMACHI M. The molecular necklace:a rotaxane containing many threaded a-cyclodextrins[J]. Nature,1992,356(6367):325-327.
[3] HARADA A. Cyclodextrin-based molecular machines[J]. Acc. Chem. Res.,2001,34(6):456-464.
[4] WENZ G,HAN B H,MULLER A. Cyclodextrin rotaxanes and polyrotaxanes[J]. Chem. Rev.,2006,106(3):782-817.
[5] GIBSON H W,BHEDA M C,ENGEN P T. Rotaxanes,catenanes,polyrotaxanes,polycatenanes and related materials[J]. Prog. Polym. Sci.,1994,19(5):843-945.
[6] HIGASHI T,HIRAYAMA F,MISUMI S,et al. Polypseudorotaxane formation of randomly-pegylated insulin with cyclodextrins:slow release and resistance to enzymatic degradation[J]. Chem. Pharm. Bull.,2009,57(5):541-544.
[7] HIGASHI T,HIRAYAMA F,YAMASHITA S,et al. Slow-release system of pegylated lysozyme utilizing formation of polypseudorotaxanes with cyclodextrins[J]. Int. J. Pharm.,2009,374(1/2):26-32.
[8] HIGASHI T,TAJIMA A,OHSHITA N,et al. Design and evaluation of the highly concentrated human IgG formulation using cyclodextrin polypseudorotaxane hydrogels[J]. AAPS Pharm. Sci. Tech.,2015,16(6):1290-1298.
[9] ROGOZEA A,MATEI I,TURCU I M,et al. EPR and circular dichroism solution studies on the interactions of bovine serum albumin with ionic surfactants and beta-cyclodextrin[J]. J. Phys. Chem. B,2012,116(49):14245-14253.
[10] LIU Y,LIU Y,GUO R. Insights into cyclodextrin-modulated interactions between protein and surfactant at specific and nonspecific binding stages[J]. J. Colloid Interface Sci.,2010,351(1):180-189.
[11] WU J,ZHAO C,LIN W,et al. Binding characteristics between polyethylene glycol(PEG)and proteins in aqueous solution[J]. J. Colloid Interface Sci.,2014,2(20):2983-2992.
[12] HIGASHI T,HIRAYAMA F,MISUMI S,et al. Design and evaluation of polypseudorotaxanes of pegylated insulin with cyclodextrins as sustained release system[J]. Biomaterials,2008,29(28):3866-3871.
[13] RAWAT S,RAMAN S C,SAHOO D K. Molecular mechanism of polyethylene glycol mediated stabilization of protein[J]. Biochem. Biophys. Res. Commun.,2010,392(4):561-566.
[14] OI W,ISOBE M,HASHIDZUME A,et al. Macromolecular recognition:discrimination between human and bovine serum albumins by cyclodextrins[J]. Macromol. Rapid Comm.,2011,32:501-505.

[1]	LAI Huaidong, CHENG Deshu, WANG Jian, LUO Juxiang. Preparation and application of α-methyl styrene maleic anhydride copolymer microspheres immobilized β-cyclodextrin [J]. Chemical Industry and Engineering Progress, 2023, 42(4): 2038-2046.
[2]	WANG Yan, QIN Zhenping, LIU Yue, ZHANG Wenhai, GUO Hongxia. Preparation and properties of β-cyclodextrin in-situ modified MoS₂ tubular ceramic composite membrane [J]. Chemical Industry and Engineering Progress, 2023, 42(10): 5373-5380.
[3]	NIE Fan, TONG Kun, SHAO Zhiguo, LIU Guangquan, LI Shusen, LI Xingchun. Volatile generation during pyrolysis of heavy organic matters and the development of the evolution gas analysis [J]. Chemical Industry and Engineering Progress, 2022, 41(5): 2322-2331.
[4]	QIAN Ke, DENG Miao, QIAO Zhijun, FANG Zhimei, TU Jianfei, RUAN Dianbo. Preparation and electrochemical properties of cyclodextrin based activated carbon [J]. Chemical Industry and Engineering Progress, 2022, 41(4): 2000-2006.
[5]	FAN Xiangru, YANG Yijin, GUO Xujing, ZHANG Quanbi. Study on the adsorption characteristics of methylene blue by soft manganese ore-oil sludge-based activated carbon [J]. Chemical Industry and Engineering Progress, 2022, 41(12): 6664-6671.
[6]	QIN Li, LI Dongdong, TIAN Jingsheng, HAN Junhua, ZHANG Yin, LI Jianwen, GAO Wenhui. Preparation of leuco malachite green imprinting sensor based on multiple technologies and its application [J]. Chemical Industry and Engineering Progress, 2022, 41(11): 6018-6028.
[7]	CUI Kun, HUANG Jin, ZHAO Qiaoling, MA Zhi. New progress in analysis and characterization of long chain branched structure in high melt strength polypropylene [J]. Chemical Industry and Engineering Progress, 2022, 41(10): 5425-5440.
[8]	CHEN Shaoyun, TIAN Du, LI Qi, ZHONG Min, HU Chenglong, JI Hongbing. Study on the phase structure of polystyrene/poly(methyl methacrylate) blend film by Raman Mapping imaging [J]. Chemical Industry and Engineering Progress, 2021, 40(7): 3900-3908.
[9]	WEN Jiaxin, ZHANG Xin, LIU Yunxia, HE Zhiqiang, QU Qichao. Preparation and performance of smart anti-corrosion coating based on nanocontainers of BTA@MSNs-PAA [J]. Chemical Industry and Engineering Progress, 2021, 40(5): 2685-2694.
[10]	Junjie HAO, Chunxiang LYU, Denghua LI. Characterization of the microstructure of carbon fibers: Raman spectroscopy [J]. Chemical Industry and Engineering Progress, 2020, 39(S2): 227-233.
[11]	Liping HU, Shengquan HUANG, Shuhua TIAN, Yansheng HUANG, Liuyun HU, FALOLA Akinola A, Xuan LI, Yidan SHU, Xue Zhong WANG. Model building and transfer between spectrometers in the application of near infrared spectroscopy to online quality control of Chinese herbal liquid tonic [J]. Chemical Industry and Engineering Progress, 2020, 39(8): 3263-3272.
[12]	Entian LI,Yang XU,Pei YAO,Yuanyuan ZHU,Yihan ZHANG,Xiashi ZHU. Remove naphthalene from solvent oil by vinyl imidazole ionic liquid and β-cyclodextrin [J]. Chemical Industry and Engineering Progress, 2020, 39(4): 1321-1328.
[13]	Cuizhong CHEN, Junfeng LI, Mingju LAN, EREAIHAN, Kefei XIE, Weilong XU, Yaru LIU, Hongwei SUN. Effect of C/N ratio on the performance of nitrification and three-dimensional fluorescence excitation-emission matrix (EEM) spectroscopy characterization of extracellular polymeric substances from sequencing batch reactors [J]. Chemical Industry and Engineering Progress, 2020, 39(12): 5275-5282.
[14]	Tong LI,Zhaoping ZHONG,Bo ZHANG. The synergistic effect of co-pyrolysis of cellulose andhydrogen-enriched feedstock [J]. Chemical Industry and Engineering Progress, 2019, 38(9): 4044-4051.
[15]	Shouyi LI,Xiongchao LIN,Beibei LU,Yonggang WANG,Dengyue ZHANG,Yunhui ZHOU. Effects of minerals on pyrolysis characteristics of maceralin high-alkali coal [J]. Chemical Industry and Engineering Progress, 2019, 38(08): 3650-3657.

Spectroscopic study of the interaction between PEG/a-cyclodextrin pseudopolyrotaxane hydrogel with BSA

PEG/a-环糊精准聚轮烷水凝胶与BSA相互作用的光谱学研究

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments