Molecular Dynamic Simulation Study on Soy Protein As Drug Delivery Vehicle

Zhuoyuan Zheng, Akash Singh, Yumeng Li
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Abstract

Protein-based drug carriers are promising candidates for efficient drug delivery among the available potential colloidal carrier systems, due to their low cytotoxicity, abundance, renewability, diverse functional groups and interactions, and high drug loading capacity, etc. In this study, molecular dynamics (MD) simulations are performed to study the mechanisms of 11S molecule of soy protein as drug delivery vehicle to attach allyl isothiocyanate (AITC) and doxorubicin (DOX) drugs. The intermolecular interactions between protein and drugs are investigated; and the loading capacities of the protein molecules are calculated and compared with experiments. It is found that, for the AITC system, both nonpolar and polar residues of protein have the ability to adsorb AITCs; particularly, the polar residues serve as the primary active sites for the stable attachment of the drug molecules through the electrostatic (dipole-dipole) interactions. For the DOX system, however, the main driving force become the π-π stacking (the van der Waals interactions) among the aromatic rings of DOX and protein. In addition to pristine protein, different denaturation processes are found to be able to increase the exposure of active sites, therefore, enhance the loading efficiency of the protein carriers.
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大豆蛋白作为药物传递载体的分子动力学模拟研究
蛋白基药物载体具有细胞毒性低、丰度高、可再生、功能基团和相互作用多样、载药能力强等特点,是潜在的胶体载体系统中高效给药的重要候选药物。本研究通过分子动力学(MD)模拟研究了大豆蛋白11S分子作为药物递送载体附着异硫氰酸烯丙酯(AITC)和阿霉素(DOX)药物的机制。研究了蛋白质与药物的分子间相互作用;计算了蛋白质分子的负载能力,并与实验进行了比较。研究发现,对于AITC体系,蛋白质的非极性残基和极性残基都具有吸附AITC的能力;特别是,极性残基作为药物分子通过静电(偶极-偶极)相互作用稳定附着的主要活性位点。然而,对于DOX体系,主要驱动力是DOX与蛋白质芳香环之间的π-π堆叠(范德华相互作用)。除了原始蛋白外,不同的变性过程可以增加活性位点的暴露,从而提高蛋白质载体的装载效率。
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