Triggering RNAi with multifunctional RNA nanoparticles and their delivery.

DNA and RNA nanotechnology Pub Date : 2015-01-01 Epub Date: 2015-07-27 DOI:10.1515/rnan-2015-0001
Bich Ngoc Dao, Mathias Viard, Angelica N Martins, Wojciech K Kasprzak, Bruce A Shapiro, Kirill A Afonin
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Abstract

Proteins are considered to be the key players in structure, function, and metabolic regulation of our bodies. The mechanisms used in conventional therapies often rely on inhibition of proteins with small molecules, but another promising method to treat disease is by targeting the corresponding mRNAs. In 1998, Craig Mellow and Andrew Fire discovered dsRNA-mediated gene silencing via RNA interference or RNAi. This discovery introduced almost unlimited possibilities for new gene silencing methods, thus opening new doors to clinical medicine. RNAi is a biological process that inhibits gene expression by targeting the mRNA. RNAi-based therapeutics have several potential advantages (i) a priori ability to target any gene, (ii) relatively simple design process, (iii) site-specificity, (iv) potency, and (v) a potentially safe and selective knockdown of the targeted cells. However, the problem lies within the formulation and delivery of RNAi therapeutics including rapid excretion, instability in the bloodstream, poor cellular uptake, and inefficient intracellular release. In an attempt to solve these issues, different types of RNAi therapeutic delivery strategies including multifunctional RNA nanoparticles are being developed. In this mini-review, we will briefly describe some of the current approaches.

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利用多功能 RNA 纳米粒子及其传输技术触发 RNAi。
蛋白质被认为是人体结构、功能和代谢调节的关键因素。传统疗法中使用的机制通常依赖于用小分子抑制蛋白质,但另一种有希望治疗疾病的方法是靶向相应的 mRNA。1998 年,克雷格-梅洛(Craig Mellow)和安德鲁-费尔(Andrew Fire)发现了通过 RNA 干扰或 RNAi 来介导的 dsRNA 基因沉默。这一发现为新的基因沉默方法带来了几乎无限的可能性,从而为临床医学打开了新的大门。RNAi 是一种通过靶向 mRNA 抑制基因表达的生物过程。基于 RNAi 的疗法有几个潜在的优势:(i) 可以先验地靶向任何基因;(ii) 设计过程相对简单;(iii) 位点特异性;(iv) 效力;(v) 可以安全、选择性地敲除靶细胞。然而,RNAi 疗法的配方和给药存在问题,包括排泄快、在血液中不稳定、细胞吸收差以及细胞内释放效率低。为了解决这些问题,人们正在开发不同类型的 RNAi 治疗递送策略,包括多功能 RNA 纳米颗粒。在这篇小型综述中,我们将简要介绍目前的一些方法。
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