Strategic deactivation of mRNA COVID-19 vaccines: New applications for siRNA therapy and RIBOTACs

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-08-26 DOI:10.1002/jgm.3733
Nicolas Hulscher, Peter A. McCullough, Diane E. Marotta
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Abstract

The rapid development and authorization of messenger ribonucleic acid (mRNA) vaccines by Pfizer-BioNTech (BNT162b2) and Moderna (mRNA-1273) in 2020 marked a significant milestone in human mRNA product application, overcoming previous obstacles such as mRNA instability and immunogenicity. This paper reviews the strategic modifications incorporated into these vaccines to enhance mRNA stability and translation efficiency, such as the inclusion of nucleoside modifications and optimized mRNA design elements including the 5′ cap and poly(A) tail. We highlight emerging concerns regarding the wide systemic biodistribution of these mRNA vaccines leading to prolonged inflammatory responses and other safety concerns. The regulatory framework guiding the biodistribution studies is pivotal in assessing the safety profiles of new mRNA formulations in use today. The stability of mRNA vaccines, their pervasive distribution, and the longevity of the encapsulated mRNA along with unlimited production of the damaging and potentially lethal spike (S) protein call for strategies to mitigate potential adverse effects. Here, we explore the potential of small interfering RNA (siRNA) and ribonuclease targeting chimeras (RIBOTACs) as promising solutions to target, inactivate, and degrade residual and persistent vaccine mRNA, thereby potentially preventing uncontrolled S protein production and reducing toxicity. The targeted nature of siRNA and RIBOTACs allows for precise intervention, offering a path to prevent and mitigate adverse events of mRNA-based therapies. This review calls for further research into siRNA and RIBOTAC applications as antidotes and detoxication products for mRNA vaccine technology.

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mRNA COVID-19 疫苗的战略性失活:siRNA 疗法和 RIBOTAC 的新应用。
辉瑞-生物技术公司(BNT162b2)和Moderna公司(mRNA-1273)于2020年迅速开发出信使核糖核酸(mRNA)疫苗并获得授权,标志着人类mRNA产品应用领域的一个重要里程碑,克服了以往mRNA不稳定性和免疫原性等障碍。本文回顾了这些疫苗为提高 mRNA 稳定性和翻译效率而进行的战略性修改,如加入核苷修饰和优化的 mRNA 设计元素,包括 5' 帽和 poly(A) 尾。我们强调了新出现的问题,即这些 mRNA 疫苗的广泛全身生物分布会导致长时间的炎症反应和其他安全问题。指导生物分布研究的监管框架对于评估目前使用的新型 mRNA 制剂的安全性至关重要。mRNA 疫苗的稳定性、广泛分布、封装 mRNA 的寿命以及破坏性和潜在致命性尖峰 (S) 蛋白的无限生产,都要求采取策略来减轻潜在的不良影响。在此,我们探讨了小干扰 RNA(siRNA)和核糖核酸酶靶向嵌合体(RIBOTACs)作为靶向、灭活和降解残留和持久性疫苗 mRNA 的潜在解决方案的潜力,从而有可能防止不受控制的 S 蛋白生成并降低毒性。siRNA 和 RIBOTACs 的靶向性允许精确干预,为预防和减轻基于 mRNA 治疗的不良反应提供了途径。本综述呼吁进一步研究 siRNA 和 RIBOTAC 在 mRNA 疫苗技术中作为解毒剂和解毒产品的应用。
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CiteScore
7.20
自引率
4.30%
发文量
567
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