溶菌酶蛋白与聚合物防污膜相互作用的分子动力学模拟

张恒; 胡立梅; 蔺存国; 王利; 苑世领

doi:10.3724/SP.J.1105.2014.13164

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溶菌酶蛋白与聚合物防污膜相互作用的分子动力学模拟

研究论文 | 更新时间：2021-03-19

- 溶菌酶蛋白与聚合物防污膜相互作用的分子动力学模拟
- Molecular Dynamics Simulation of Interaction between Lysozyme and Non-fouling Polymer Membranes
- 高分子学报 2014年第1期页码：99-106
- 作者机构：
  
  1. 山东大学化学与化工学院,济南,250100
  2. 海洋腐蚀与防护国防科技重点实验室中国船舶重工集团公司第七二五研究所,青岛,266101
- 作者简介：
- 基金信息：
- DOI：10.3724/SP.J.1105.2014.13164
  中图分类号：
- 纸质出版日期：2014-1-20，
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张恒, 胡立梅, 蔺存国, 王利, 苑世领. 溶菌酶蛋白与聚合物防污膜相互作用的分子动力学模拟[J]. 高分子学报, 2014,(1):99-106.

Heng Zhang, Li-mei Hu, Cun-guo Lin, Li Wang, Shi-ling Yuan. Molecular Dynamics Simulation of Interaction between Lysozyme and Non-fouling Polymer Membranes[J]. Acta Polymerica Sinica, 2014,(1):99-106.
张恒, 胡立梅, 蔺存国, 王利, 苑世领. 溶菌酶蛋白与聚合物防污膜相互作用的分子动力学模拟[J]. 高分子学报, 2014,(1):99-106. DOI： 10.3724/SP.J.1105.2014.13164.

Heng Zhang, Li-mei Hu, Cun-guo Lin, Li Wang, Shi-ling Yuan. Molecular Dynamics Simulation of Interaction between Lysozyme and Non-fouling Polymer Membranes[J]. Acta Polymerica Sinica, 2014,(1):99-106. DOI： 10.3724/SP.J.1105.2014.13164.

摘要

采用分子动力学方法研究了溶菌酶蛋白分子（Lysozyme）在2种典型聚合物防污材料（有机硅弹性体聚二甲基硅氧烷PDMS和两性离子类聚磺酸基甜菜碱甲基丙烯酸甲酯SBMA）表面的吸附行为，进一步从微观角度阐释了防污材料的防污机理.通过比较蛋白质与聚合物膜间的作用力和结合能，防污膜表面水化层的动力学性质，以及蛋白质与基底结合位点附近的结构分析表明SBMA有着更优异的防污能力：（1）蛋白质的吸附须要克服两者表面水化层引起的物理障碍和能量势垒，SBMA通过表面氢键、静电作用和笼效应束缚了一层紧密结合的水化层，表面结合水难于脱附，水化层分子的去溶剂化需要克服的能垒高.（2）蛋白质与PDMS的结合能量上更具优势，相比SBMA与蛋白质间的结合更加稳定，不利于蛋白质的脱附.

Abstract

A series of molecular dynamics simulations were conducted to investigate the interaction between protein (lysozyme) and two typical non-fouling membranes (PDMS and SBMA). Lysozymes were initially put on the surfaces of two non-fouling membranes with a minimal separation distance 0.5 nm

1.0 nm and 1.5 nm. Centroids of proteins were fixed during the first 15 ns simulation to determine the forces that membranes extended on proteins. Then the fix was cancelled in the following 20 ns simulations. At the end of simulations

both the proteins were adsorbed on membranes. By analyzing the types of residues near adsorption sites

contact areas

hydrogen bonds

VDW contacts between protein and membranes

we concluded that PDMS has a better combination with lysozyme than SBMA. This closely adsorption makes the protein not easy to leave from membranes. To fully understand the molecular mechanism of non-fouling materials

the simulation results were analyzed from two aspects: interaction between protein and membrane

interaction between surface hydration layer and membrane. Combined with our previous work which concentrated on properties of surface hydration layers it is concluded: (1) PDMS has a larger attractive force on protein than SBMA at the whole distance range. Both the interactions between protein and membranes were energetically favorable

but Lysozyme interacted much more strongly with PDMS than SBMA. (2) SBMA has plenty of hydrogen bonds

electrostatic interactions

and cage effects with surface waters that lead to a stable surface hydration layer. The hydration layers were believed to form a physical and energetic barrier to prevent protein adsorption on the surface. At last we proposed a possible mechanism of protein adsorption or anti-fouling: the first obligatory step of protein adsorption was the dehydration of both protein and the membrane. After that

protein induced a series of conformation changes to change its surface hydrophobic/hydrophilic properties

charge distributions etc. Then it came to the final stable adsorption state by forming hydrogen bonds

VDW contacts and electrostatic interactions between protein and substrates.

关键词

生物污损防污材料溶菌酶蛋白分子动力学

Keywords

Bio-foulingNon-fouling materialLysozymeMolecular dynamics

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