Folding of mRNA-DNA origami for controlled translation and viral vector packaging

Abstract

AbstractmRNA is an important molecule in vaccine development and treatment of genetic disorders. Its capability to hybridize with DNA oligonucleotides in a programmable manner facilitates the formation of RNA-DNA origami structures, which can possess a well-defined morphology and serve as rigid supports for mRNA delivery. However, to date, compre- hensive studies on the requirements for efficient folding of mRNA into distinct mRNA-DNA structures while preserving its translation func- tionality remain elusive. Here, we systematically investigate the impact of design parameters on the folding of protein-encoding mRNA into mRNA-DNA origami structures and demonstrate the importance of the availability of ribosome-binding sequences on the translation effi- ciency. Furthermore, these hybrid structures can be encapsulated inside virus capsids for protecting them against nuclease degradation and also for enhancing their cellular uptake. This multicomponent system therefore showcases a modular and versatile nanocarrier. Our work pro- vides valuable insight into the design of mRNA-DNA origami structures contributing to the development of mRNA-based gene delivery platforms.