Alwani Saniya, Kaur Randeep, Michel Deborah, Chitanda Jackson M, Verrall Ronald E, Karunakaran Chithra, Badea Ildiko
Drug Design and Discovery Research Group, College of Pharmacy and Nutrition, University of Saskatchewan, Saskatoon, SK, Canada.
Department of Chemical & Biological Engineering, University of Saskatchewan, Saskatoon, SK, Canada.
Int J Nanomedicine. 2016 Feb 19;11:687-702. doi: 10.2147/IJN.S92218. eCollection 2016.
Nanodiamonds (NDs) are emerging as an attractive tool for gene therapeutics. To reach their full potential for biological application, NDs should maintain their colloidal stability in biological milieu. This study describes the behavior of lysine-functionalized ND (lys-ND) in various dispersion media, with an aim to limit aggregation and improve the colloidal stability of ND-gene complexes called diamoplexes. Furthermore, cellular and macromolecular interactions of lys-NDs are also analyzed in vitro to establish the understanding of ND-mediated gene transfer in cells.
lys-NDs were synthesized earlier through covalent conjugation of lysine amino acid to carboxylated NDs surface generated through re-oxidation in strong oxidizing acids. In this study, dispersions of lys-NDs were prepared in various media, and the degree of sedimentation was monitored for 72 hours. Particle size distributions and zeta potential measurements were performed for a period of 25 days to characterize the physicochemical stability of lys-NDs in the medium. The interaction profile of lys-NDs with fetal bovine serum showed formation of a protein corona, which was evaluated by size and charge distribution measurements. Uptake of lys-NDs in cervical cancer cells was analyzed by scanning transmission X-ray microscopy, flow cytometry, and confocal microscopy. Cellular uptake of diamoplexes (complex of lys-NDs with small interfering RNA) was also analyzed using flow cytometry.
Aqueous dispersion of lys-NDs showed minimum sedimentation and remained stable over a period of 25 days. Size distributions showed good stability, remaining under 100 nm throughout the testing period. A positive zeta potential of >+20 mV indicated a preservation of surface charges. Size distribution and zeta potential changed for lys-NDs after incubation with blood serum, suggesting an interaction with biomolecules, mainly proteins, and a possible formation of a protein corona. Cellular internalization of lys-NDs was confirmed by various techniques such as confocal microscopy, soft X-ray spectroscopy, and flow cytometry.
This study establishes that dispersion of lys-NDs in aqueous medium maintains long-term stability and also provides evidence that lysine functionalization enables NDs to interact effectively with the biological system to be used for RNAi therapeutics.
纳米金刚石(NDs)正成为基因治疗中一种有吸引力的工具。为充分发挥其在生物应用中的潜力,NDs应在生物环境中保持其胶体稳定性。本研究描述了赖氨酸功能化纳米金刚石(lys-ND)在各种分散介质中的行为,旨在限制聚集并提高称为纳米金刚石基因复合物(diamoplexes)的胶体稳定性。此外,还在体外分析了lys-NDs与细胞和大分子的相互作用,以深入了解ND介导的细胞基因转移。
赖氨酸功能化纳米金刚石(lys-NDs)先前是通过将赖氨酸氨基酸共价连接到在强氧化性酸中再氧化产生的羧化纳米金刚石表面而合成的。在本研究中,在各种介质中制备了lys-NDs的分散液,并监测了72小时的沉降程度。在25天内进行粒度分布和zeta电位测量,以表征lys-NDs在介质中的物理化学稳定性。lys-NDs与胎牛血清的相互作用情况显示形成了蛋白冠,通过尺寸和电荷分布测量对其进行了评估。通过扫描透射X射线显微镜、流式细胞术和共聚焦显微镜分析了lys-NDs在宫颈癌细胞中的摄取情况。还使用流式细胞术分析了纳米金刚石基因复合物(lys-NDs与小干扰RNA的复合物)的细胞摄取情况。
lys-NDs 的水分散液沉降最少,在25天内保持稳定。粒度分布显示出良好的稳定性,在整个测试期间均保持在100 nm以下。大于 +20 mV 的正zeta电位表明表面电荷得以保留。与血清孵育后,lys-NDs 的粒度分布和zeta电位发生了变化,这表明其与生物分子(主要是蛋白质)发生了相互作用,并可能形成了蛋白冠。通过共聚焦显微镜、软X射线光谱和流式细胞术等多种技术证实了lys-NDs的细胞内化。
本研究证实lys-NDs在水性介质中的分散液保持长期稳定性,并且还提供了证据表明赖氨酸功能化使NDs能够与生物系统有效相互作用,从而用于RNAi治疗。
