Soliman Bangly, Wen Ming Ming, Kandil Eman, El-Agamy Basma, Gamal-Eldeen Amira M, ElHefnawi Mahmoud
Department of Biochemistry, Faculty of Science, Ain Shams University, Cairo 11566, Egypt.
Biomedical Informatics and Chemo-Informatics Group, Informatics and Systems Department, National Research Centre, Cairo 12622, Egypt.
Pharmaceutics. 2024 Apr 3;16(4):494. doi: 10.3390/pharmaceutics16040494.
Currently, there is still a lack of effective carriers with minimal side effects to deliver therapeutic miRNA. Thus, it is crucial to optimize novel drug delivery systems. MiR-375 has proven superior therapeutic potency in Hepatocellular carcinoma (HCC). The purpose of this study was to fabricate 2 novel and smart nano-carriers for the transportation efficiency of miR-375 in HCC cells and enhance its anti-tumor effects. We established the miR-375 construct through the pEGP- miR expression vector. Two nano-carriers of solid/liquid lipids and chitosan (CS) were strategically selected, prepared by high-speed homogenization, and optimized by varying nano-formulation factors. Thus, the two best nano-formulations were designated as F1 (0.5% CS) and F2 (1.5% CS) and were evaluated for miR-375 conjugation efficiency by gel electrophoresis and nanodrop assessment. Then, physio-chemical characteristics and stability tests for the miR-375 nano-plexes were all studied. Next, its efficiencies as replacement therapy in HepG2 cells have been assessed by fluorescence microscopy, flow cytometry, and cytotoxicity assay. The obtained data showed that two cationic nanostructured solid/liquid lipid carriers (NSLCs); F1 and F2 typically had the best physio-chemical parameters and long-term stability. Moreover, both F1 and F2 could form nano-plexes with the anionic miR-375 construct at weight ratios 250/1 and 50/1 via electrostatic interactions. In addition, these nano-plexes exhibited physical stability after three months and protected miR-375 from degradation in the presence of 50% fetal bovine serum (FBS). Furthermore, both nano-plexes could simultaneously deliver miR-375 into HepG2 cells and they ensure miR re-expression even in the presence of 50% FBS compared to free miR-375 (-value < 0.001). Moreover, both F1 and F2 alone significantly exhibited minimal cytotoxicity in treated cells. In contrast, the nano-plexes significantly inhibited cell growth compared to free miR-375 or doxorubicin (DOX), respectively. More importantly, F2/miR-375 nano-plex exhibited more anti-proliferative activity in treated cells although its IC50 value was 55 times lower than DOX (-value < 0.001). Collectively, our findings clearly emphasized the multifunctionality of the two CS-coated NSLCs in terms of their enhanced biocompatibility, biostability, conjugation, and transfection efficiency of therapeutic miR-375. Therefore, the NSLCs/miR-375 nano-plexes could serve as a novel and promising therapeutic strategy for HCC.
目前,仍然缺乏副作用最小的有效载体来递送治疗性miRNA。因此,优化新型药物递送系统至关重要。miR-375已被证明在肝细胞癌(HCC)中具有卓越的治疗效力。本研究的目的是制备两种新型智能纳米载体,以提高miR-375在肝癌细胞中的运输效率并增强其抗肿瘤作用。我们通过pEGP-miR表达载体构建了miR-375构建体。策略性地选择了固体/液体脂质和壳聚糖(CS)这两种纳米载体,通过高速匀浆法制备,并通过改变纳米制剂因素进行优化。因此,将两种最佳纳米制剂命名为F1(0.5% CS)和F2(1.5% CS),并通过凝胶电泳和微量核酸蛋白测定仪评估其对miR-375的缀合效率。然后,对miR-375纳米复合物的物理化学特性和稳定性进行了研究。接下来,通过荧光显微镜、流式细胞术和细胞毒性测定评估了其在HepG2细胞中作为替代疗法的效率。获得的数据表明,两种阳离子纳米结构固体/液体脂质载体(NSLCs);F1和F2通常具有最佳的物理化学参数和长期稳定性。此外,F1和F2都可以通过静电相互作用以250/1和50/1的重量比与阴离子miR-375构建体形成纳米复合物。此外,这些纳米复合物在三个月后表现出物理稳定性,并在50%胎牛血清(FBS)存在的情况下保护miR-375不被降解。此外,与游离miR-375相比,两种纳米复合物都可以同时将miR-375递送至HepG2细胞,并且即使在存在50% FBS的情况下也能确保miR重新表达(P值<0.001)。此外,单独的F1和F2在处理的细胞中均显示出最小的细胞毒性。相比之下,与游离miR-375或阿霉素(DOX)相比,纳米复合物分别显著抑制细胞生长。更重要的是,F2/miR-375纳米复合物在处理的细胞中表现出更强的抗增殖活性,尽管其IC50值比DOX低55倍(P值<0.001)。总体而言,我们的研究结果清楚地强调了两种CS包被的NSLCs在增强治疗性miR-375的生物相容性、生物稳定性、缀合和转染效率方面的多功能性。因此,NSLCs/miR-375纳米复合物可作为一种新型且有前景的肝癌治疗策略。
