将壳聚糖衍生纳米载体用于向外周和中枢神经元高效递送 siRNA

Ana P Spencer, Adriana Vilaca, Miguel Xavier, Rafael Santos, Ariel Ionescu, Maria Lazaro, Victoria Leiro, Eran Perlson, Sofia C Guimaraes, Ben M Maoz, Ana P Pego
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引用次数: 0

摘要

使用小干扰 RNA(siRNA)的基因疗法通过沉默特定基因,如限制轴突生长的磷酸酶和天丝蛋白同源物(PTEN)基因,有望治疗神经系统疾病。然而,由于过早降解和非特异性递送,将 siRNA 有效递送到神经元具有挑战性。基于壳聚糖的递送系统因其良好的生物相容性而显示出巨大的潜力。然而,它们有限的转染效率和缺乏神经元滋养性需要进一步改造。在我们之前利用壳聚糖成功实现神经元靶向 DNA 递送的基础上,我们提出了一种旨在下调 PTEN 的 siRNA 递送新方法。这包括使用硫醇化的三甲基壳聚糖(TMCSH)为基础的 siRNA 纳米颗粒,这种纳米颗粒具有破伤风神经毒素重链(HC)的神经刺激性 C 端片段的功能,可有效地向外周和中枢神经元递送 siRNA。这些多聚物具有合适的理化特性和生物相容性,对神经元电生理学无不良影响。包括三维体外培养和微流控在内的多种神经元模型证实了多聚物的效率和神经特异性。HC靶向大大增强了纳米粒子与神经元的结合,活细胞成像显示沿轴突逆向运输的速度提高了五倍。此外,靶向 PTEN 的 siRNA 递送促进了胚胎皮质神经元的轴突生长。因此,这些多聚物是一种很有前景的 siRNA 运送平台,具有临床转化和治疗应用的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Engineered chitosan-derived nanocarrier for efficient siRNA delivery to peripheral and central neurons
Gene therapy using small interfering RNA (siRNA) holds promise for treating neurological disorders by silencing specific genes, such as the phosphatase and tensin homolog (PTEN) gene, which restricts axonal growth. Yet, delivering siRNA to neurons efficiently is challenging due to premature degradation and unspecific delivery. Chitosan-based delivery systems have shown great potential due to their well-established biocompatibility. However, their limited transfection efficiency and lack of neuronal tropism require further modification. Building on our previous successes with neuron-targeted DNA delivery using chitosan, a novel approach for siRNA delivery aimed at PTEN downregulation is proposed. This involves using thiolated trimethyl chitosan (TMCSH)-based siRNA nanoparticles functionalized with the neurotropic C-terminal fragment of the tetanus neurotoxin heavy chain (HC) for efficient delivery to both peripheral and central neurons. These polyplexes demonstrated suitable physicochemical properties, biocompatibility, and no adverse effects on neuronal electrophysiology. Diverse neuronal models, including 3D ex vivo cultures and microfluidics, confirmed polyplexes efficiency and neurospecificity. HC targeting significantly enhanced nanoparticle neuronal binding, and live cell imaging revealed five times faster retrograde transport along axons. Furthermore, siRNA delivery targeting PTEN promoted axonal outgrowth in embryonic cortical neurons. Thus, these polyplexes represent a promising platform for siRNA delivery, offering potential for clinical translation and therapeutic applications.
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