Department of Bioengineering, 501 Rhodes Engineering Research Center, Clemson University, Clemson, SC 29634, United States.
Colloids Surf B Biointerfaces. 2013 Oct 1;110:363-71. doi: 10.1016/j.colsurfb.2013.04.018. Epub 2013 May 13.
While protein-surface interactions have been widely studied, relatively little is understood at this time regarding how protein-surface interaction effects are influenced by protein-protein interactions and how these effects combine with the internal stability of a protein to influence its adsorbed-state structure and bioactivity. The objectives of this study were to develop a method to study these combined effects under widely varying protein-protein interaction conditions using hen egg-white lysozyme (HEWL) adsorbed on silica glass, poly(methyl methacrylate), and polyethylene as our model systems. In order to vary protein-protein interaction effects over a wide range, HEWL was first adsorbed to each surface type under widely varying protein solution concentrations for 2h to saturate the surface, followed by immersion in pure buffer solution for 15h to equilibrate the adsorbed protein layers in the absence of additionally adsorbing protein. Periodic measurements were made at selected time points of the areal density of the adsorbed protein layer as an indicator of the level of protein-protein interaction effects within the layer, and these values were then correlated with measurements of the adsorbed protein's secondary structure and bioactivity. The results from these studies indicate that protein-protein interaction effects help stabilize the structure of HEWL adsorbed on silica glass, have little influence on the structural behavior of HEWL on HDPE, and actually serve to destabilize HEWL's structure on PMMA. The bioactivity of HEWL on silica glass and HDPE was found to decrease in direct proportion to the degree of adsorption-induce protein unfolding. A direct correlation between bioactivity and the conformational state of adsorbed HEWL was less apparent on PMMA, thus suggesting that other factors influenced HEWL's bioactivity on this surface, such as the accessibility of HEWL's bioactive site being blocked by neighboring proteins or the surface itself. The developed methods provide an effective means to characterize the influence of protein-protein interaction effects and provide new molecular-level insights into how protein-protein interaction effects combine with protein-surface interaction and internal protein stability effects to influence the structure and bioactivity of adsorbed protein.
虽然蛋白质-表面相互作用已经得到了广泛的研究,但目前对于蛋白质-表面相互作用的影响如何受到蛋白质-蛋白质相互作用的影响,以及这些影响如何与蛋白质的内部稳定性相结合,从而影响其吸附态结构和生物活性,了解相对较少。本研究的目的是开发一种方法,以研究这些组合效应在广泛变化的蛋白质-蛋白质相互作用条件下,使用在二氧化硅玻璃、聚甲基丙烯酸甲酯和聚乙烯上吸附的鸡卵清溶菌酶(HEWL)作为我们的模型系统。为了在广泛的范围内改变蛋白质-蛋白质相互作用的影响,HEWL 首先在每种表面类型上以广泛变化的蛋白质溶液浓度吸附 2 小时以饱和表面,然后在纯缓冲溶液中浸泡 15 小时以在没有额外吸附蛋白质的情况下平衡吸附蛋白质层。在选定的时间点周期性地测量吸附蛋白质层的面积密度作为层内蛋白质-蛋白质相互作用影响水平的指标,并将这些值与吸附蛋白质的二级结构和生物活性的测量值相关联。这些研究的结果表明,蛋白质-蛋白质相互作用有助于稳定吸附在二氧化硅玻璃上的 HEWL 的结构,对 HEWL 在高密度聚乙烯上的结构行为几乎没有影响,实际上会破坏 PMMA 上 HEWL 结构的稳定性。HEWL 在二氧化硅玻璃和高密度聚乙烯上的生物活性被发现与吸附诱导蛋白质展开的程度成正比地降低。在 PMMA 上,生物活性与吸附 HEWL 的构象状态之间的直接相关性不太明显,这表明其他因素会影响 HEWL 在该表面上的生物活性,例如其生物活性部位的可及性被邻近的蛋白质或表面本身所阻断。所开发的方法提供了一种有效的手段来描述蛋白质-蛋白质相互作用的影响,并提供了新的分子水平的见解,了解蛋白质-蛋白质相互作用的影响如何与蛋白质-表面相互作用和内部蛋白质稳定性的影响相结合,从而影响吸附蛋白质的结构和生物活性。