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Truncated tetrahedral RNA nanostructures exhibit enhanced features for delivery of RNAi substrates.

Paul ZakrevskyWojciech K KasprzakWilliam F HeinzWeimin WuHtet KhantEckart BindewaldNomongo DorjsurenEric A FieldsNatalia De ValLuc JaegerBruce A Shapiro
Published in: Nanoscale (2020)
Using RNA as a material for nanoparticle construction provides control over particle size and shape at the nano-scale. RNA nano-architectures have shown promise as delivery vehicles for RNA interference (RNAi) substrates, allowing multiple functional entities to be combined on a single particle in a programmable fashion. Rather than employing a completely bottom-up approach to scaffold design, here multiple copies of an existing synthetic supramolecular RNA nano-architecture serve as building blocks along with additional motifs for the design of a novel truncated tetrahedral RNA scaffold, demonstrating that rationally designed RNA assemblies can themselves serve as modular pieces in the construction of larger rationally designed structures. The resulting tetrahedral scaffold displays enhanced characteristics for RNAi-substrate delivery in comparison to similar RNA-based scaffolds, as evidenced by its increased functional capacity, increased cellular uptake and ultimately an increased RNAi efficacy of its adorned Dicer substrate siRNAs. The unique truncated tetrahedral shape of the nanoparticle core appears to contribute to this particle's enhanced function, indicating the physical characteristics of RNA scaffolds merit significant consideration when designing platforms for delivery of functional RNAs via RNA nanoparticles.
Keyphrases
  • nucleic acid
  • tissue engineering
  • high resolution
  • machine learning
  • amino acid
  • energy transfer