Institute of Photomedicine, Shanghai Skin Disease Hospital, The Institute for Biomedical Engineering & Nano Science, Tongji University School of Medicine, Shanghai 200443, China.
School of Life Science, Tianjin Engineering Center of Micro-Nano Biomaterials and Detection-Treatment Technology, Tianjin University, Tianjin 300072, China.
Biomaterials. 2018 Apr;161:256-269. doi: 10.1016/j.biomaterials.2018.01.050. Epub 2018 Feb 3.
Protein-mediated biomimetic nanoparticles because of simplicity of their synthesis, subdued nonspecific adsorption, improved pharmacokinetics, and biocompatibility have been receiving increasing attention recently. Nevertheless, only a handful of proteins have been developed for biomimetic synthesis. Worse still, most of them are constrained on single-function usages in chemistry. Exploring new functional proteins, especially those with multi-dentate moieties for multi-role biomimetic chemistry, still remains a substantial challenge. Here, we report on a human endogenous protein, glutathione S-transferase (GST), with favorable amino acid motifs, that has innate talents in incubating high quality gold nanoparticles without adding reducing agents at physiological temperature, and particularly can further anchor gadolinium ions without adding extra chelators. The resultant paramagnetic AuNPs@GST exhibits highly crystallization and uniform size of ca. 10 nm. Compared with clinical contrast agents (Iopamidol, Magnevist), AuNPs@GST shows better imaging performance (e.g. enhanced relaxivity and larger X-ray attenuation efficiency) with clear evidence from Monte Carlo simulation and in vitro experimental results. Further in vivo imaging demonstrates good tumor targeting and clearance of AuNPs@GST without obvious systemic toxicity. Particularly, low immunogenicity of AuNPs@GST is certified by immunological status evaluation of T cells after stimulated with them. This study for the first time demonstrates the manipulation of a human protein for multi-role biomimetic chemistry depending on its unique amino acid motifs and its incorporation into a synthetic agent for potentially addressing some critical issues in cancer nanotheranostics such as synthetic methodology, biocompatibility, function integration, targeting, and immunogenicity.
蛋白质介导的仿生纳米粒子由于其合成简单、非特异性吸附减弱、改善了药代动力学和生物相容性,最近受到了越来越多的关注。然而,只有少数几种蛋白质被开发用于仿生合成。更糟糕的是,它们中的大多数在化学上都受到单一功能的限制。探索新的功能蛋白,特别是那些具有多齿部分的多功能仿生化学蛋白,仍然是一个巨大的挑战。在这里,我们报告了一种人类内源性蛋白,谷胱甘肽 S-转移酶(GST),它具有有利的氨基酸序列,具有在生理温度下孵育高质量金纳米粒子而无需添加还原剂的固有能力,特别是可以进一步固定镧系元素离子而无需添加额外的螯合剂。所得的顺磁 AuNPs@GST 表现出高度结晶和均匀的尺寸约为 10nm。与临床造影剂(碘帕醇、马根维显)相比,AuNPs@GST 具有更好的成像性能(例如增强的弛豫率和更大的 X 射线衰减效率),这一点从蒙特卡罗模拟和体外实验结果中得到了明确的证明。进一步的体内成像表明,AuNPs@GST 具有良好的肿瘤靶向性和清除能力,且没有明显的全身毒性。特别是,AuNPs@GST 的低免疫原性通过用它们刺激后的 T 细胞免疫状态评估得到了证明。本研究首次证明了基于其独特的氨基酸序列对人类蛋白质进行多功能仿生化学的操控,并将其整合到合成试剂中,以潜在地解决癌症纳米治疗学中的一些关键问题,如合成方法、生物相容性、功能整合、靶向和免疫原性。
