Parlea Lorena, Puri Anu, Kasprzak Wojciech, Bindewald Eckart, Zakrevsky Paul, Satterwhite Emily, Joseph Kenya, Afonin Kirill A, Shapiro Bruce A
Gene Regulation and Chromosome Biology Laboratory, National Cancer Institute , Frederick, Maryland 21702, United States.
Basic Science Program, Leidos Biomedical Research, Inc., Frederick National Laboratory for Cancer Research , Frederick, Maryland 21702, United States.
ACS Comb Sci. 2016 Sep 12;18(9):527-47. doi: 10.1021/acscombsci.6b00073. Epub 2016 Aug 26.
RNA nanostructures can be programmed to exhibit defined sizes, shapes and stoichiometries from naturally occurring or de novo designed RNA motifs. These constructs can be used as scaffolds to attach functional moieties, such as ligand binding motifs or gene expression regulators, for nanobiology applications. This review is focused on four areas of importance to RNA nanotechnology: the types of RNAs of particular interest for nanobiology, the assembly of RNA nanoconstructs, the challenges of cellular delivery of RNAs in vivo, and the delivery carriers that aid in the matter. The available strategies for the design of nucleic acid nanostructures, as well as for formulation of their carriers, make RNA nanotechnology an important tool in both basic research and applied biomedical science.
RNA纳米结构可以通过编程,利用天然存在的或从头设计的RNA基序展现出特定的大小、形状和化学计量比。这些构建体可用作支架,连接功能部分,如配体结合基序或基因表达调节剂,用于纳米生物学应用。本综述聚焦于对RNA纳米技术至关重要的四个领域:纳米生物学特别感兴趣的RNA类型、RNA纳米构建体的组装、RNA在体内细胞递送的挑战以及有助于此的递送载体。核酸纳米结构设计及其载体配方的现有策略,使RNA纳米技术成为基础研究和应用生物医学科学中的重要工具。