吸附诱导的重肌球蛋白在聚合物表面的失活对滑动的肌动蛋白丝施加有效的阻力

K. Hanson, G. Solana, V. Vaidyanathan, D. Nicolau
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引用次数: 0

摘要

肌动蛋白和肌球蛋白是工程纳米器件中潜在的力产生元件。这种应用要求表面涂层既具有生物相容性又适合纳米光刻加工,但表面调节运动蛋白功能的方式尚未得到严格研究。在这里,我们研究了运动蛋白在各种聚合物表面的表面密度和生物活性,并将结果与体外肌动球蛋白的运动特性进行了比较。研究发现,纤维速度是由活性重肌球蛋白(HMM)的比例而不是密度控制的,这与由于肌动蛋白结合相互作用较弱而失活的HMM施加有效阻力是一致的。对先前模型结果的解释表明,不活跃的HMM馏分没有产生力的能力,并且施加在聚苯乙烯上的有效阻力低于甲基丙烯酸酯聚合物和硝化纤维,这与芳香族表面结构上更高程度的蛋白质变性一致
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Adsorption-induced inactivation of heavy meromyosin on polymer surfaces imposes effective drag force on sliding actin filaments in vitro
Actin and myosin are of interest as potential force-generating elements in engineered nanodevices. Such applications require surface coatings which are both biocompatible and amenable to nanolithographic processing, but the manner in which surfaces modulate motor protein function has not been rigorously studied. Here we examine motor protein surface density and bioactivity on a variety of polymer surfaces, and compare the results to in vitro actomyosin motility characteristics. Filament velocities were found to be controlled by the proportion, rather than density, of active heavy meromyosin (HMM), consistent with the imposition of an effective drag force by inactivated HMM due to weak actin-binding interactions. Interpretation of the results with respect to previous models suggests that the inactive HMM fraction has no force-generating ability, and that the effective drag imposed on polystyrene is lower than that on methacrylate polymers and nitrocellulose, consistent with a higher degree of protein denaturation on aromatic surface structures
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