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pH和盐浓度影响磺酸基团吸附乳铁蛋白的机理 被引量:6

Mechanistic analysis of effects of pH and salt concentration on lactoferrin adsorption onto adsorbents with sulfonic ligand
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摘要 磺酸基团是用来分离乳铁蛋白普遍被认可的配基,因此含有磺酸基团的层析剂是被用得最广泛的分离介质。通过对三种接有磺酸基团的层析介质,在不同pH和盐浓度时的静态吸附研究,得到了吸附的基本规律:随着pH或盐浓度的增大,吸附容量降低。利用分子模拟技术,比较了乳铁蛋白分子表面电势在不同条件时的变化,推测pH影响吸附的机理在于改变了蛋白表面氨基酸残基的质子化状态和分子表面电势,而盐浓度主要是屏蔽了蛋白和配基之间的相互作用,改变蛋白分子表面整体电势强弱,对电势分布没有明显影响。通过计算蛋白和配基之间的结合能,量化不同条件下的吸附能力,表征pH和盐浓度的影响。 Sulfonate group is the most common ligand used for purifying lactoferrin. The isotherm adsorption curves of lactoferrin on three adsorbents with sulfonic ligand at different pHs and salt concentrations showed that adsorption capacity decreased with the increase of pH or salt concentration. Further molecular simulation was performed to compare the electrostatic potential of lactoferrin under different conditions. It could be presumed that the mechanism of pH effect was the change of protonation of amino acid residues on the surface of protein and the change of electrostatic potential consequently, while the mechanism of salt effect could be the shield of electrostatic interaction between protein and ligand with no impact on electrostatic potential distribution obviously. Finally, the binding energy between protein and ligand under different conditions was calculated to quantify adsorption capacity and characterize the effects of pH and salt concentration.
作者 杜巧燕 林东强 王荣柱 姚善泾
机构地区 浙江大学生物质化工教育部重点实验室、化学工程与生物工程学系
出处 《化工学报》 EI CAS CSCD 北大核心 2014年第2期593-598,共6页 CIESC Journal
基金 国家自然科学基金项目(21036005)~~
关键词 乳铁蛋白 静态吸附 盐浓度 分子模拟 表面电势 结合能 pH lactoferrin adsorption isotherms pH salt concentration molecular simulation electrostatic potential binding energy
分类号 TQ028.8 [化学工程]
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参考文献18

  • 1Levay Peter Ferenc,Viljoen Margaretha. Lactoferrin:a general review[J].{H}HAEMATOLOGICA,1995.252-267.
  • 2Brock Jeremy H. The physiology of lactoferrin[J].{H}Biochemistry and Cell Biology,2002.1-6.
  • 3L?nnerdal B,Iyer S. Lactoferrin:molecular structure and biological function[J].{H}Annual Review of Nutrition,1995.93-110.
  • 4Moore Stanley A,Anderson Bryan F,Groom Colin R,Haridas M, Baker Edward N. Three-dimensional structure of diferric bovine lactoferrin at 2.8 ? resolution[J].{H}Journal of Molecular Biology,1997.222-236.
  • 5Sánchez Lourdes,Calvo Miguel,Brock Jeremy H. Biological role of lactoferrin[J].{H}ARCHIVES OF DISEASE IN CHILDHOOD,1992.657.
  • 6Ward P P,Paz E,Conneely O M. Multifunctional roles of lactoferrin:a critical overview[J].{H}Cellular and Molecular Life Sciences,2005.2540-2548.
  • 7Du Qiaoyan,Lin Dongqiang,Xiong Zhansen,Yao Shanjing. One step purification of lactoferrin from crude sweet whey using cation-exchange expanded bed adsorption[J].Industrial &Engineering Chemistry Research,2013.2693-2699.
  • 8Lu Rongrong,Xu Shiying,Wang Zhang,Yang Ruijin. Isolation of lactoferrin from bovine colostrum by ultrafiltration coupled with strong cation exchange chromatography on a production scale[J].{H}Journal of Membrane Science,2007.152-161.
  • 9Fee Conan J,Chand Amita. Capture of lactoferrin and lactoperoxidase from raw whole milk by cation exchange chromatography[J].{H}Separation and purification technology,2006.143-149.
  • 10Gao Dong,Lin Dongqiang,Yao Shanjing. Mechanistic analysis on the effects of salt concentration and pH on protein adsorption onto a mixed-mode adsorbent with cation ligand[J].{H}Journal of Chromatography B,2007.16-23.

二级参考文献27

  • 1[1]Lenhoff AM.A natural interaction:chemical engineering and molecular biophysics[J].AIChE Joumal,2003,49:806-812.
  • 2[2]Okada T.Interpretation of chromatographic retention based on electrostatic theories[J].Anal Sci,1998,14:469-477.
  • 3[3]Roush DJ,Gill DS,Willson RC.Electrostatic potential and electrostatic interaction energies of rat cytochrome b5 and a simulated anion-exchange adsorbent surface[J].Biophys J,1994,66:1290-1300.
  • 4[4]Mazza CB,Sukumar M,Breneman CM,et al.Prediction of protein retention in ion-exchange system using molecular descriptors obtained from crystal structure[J].Anal Chem,2001,73:5457-5461.
  • 5[5]Yao Y,Lenhoff AM.Electrostatic contribution to protein retention in ion-exchange chromatography.1.cytochrome c variants[J].Anal Chem,2001,76:6743-6752.
  • 6[6]Yao Y,Lenhoff AM.Electrostatic contribution to protein retention in ion-exchange chromatography.2.proteins with various degrees of structural difference[J].Anal Chem,2005,77:2157-2165.
  • 7[7]Kurinov I,Harrison RW.The influence of temperature on lysozyme crystals-structure and dynamics of protein and water[J].Biological Crystallography,1995,51:98-109.
  • 8[8]Wang D,Bode W,Huber R.Bovine chymotrypsinogen a X-ray crystal structure analysis and refinement of a new crystal form at 1.8 A resolution[J].J Mol Biol,1985,185:595-624.
  • 9[9]Sharp K,Honig B.Electrostatic interactions in macromolecules:theory and applications[J].Ann Rev Biophys Chem,1990,19:301-302.
  • 10[10]Sharp K,Honig B.Lattice models of electrostatic interactions:the finite difference Poisson-Boltzmann method[J].Chemica Scripta,1989,29A:71.

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二级引证文献94

化工学报
2014年 第2期

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