Frontispiz: Reversible Supra‐Folding of User‐Programmed Functional DNA Nanostructures on Fuzzy Cationic Substrates

Immobile Holliday junctions represent not only the most fundamental building block of structural DNA nanotechnology but are also of tremendous importance for the in vitro investigation of genetic recombination and epigenetics. Here, we present a detailed study on the room-temperature assembly of immobile Holliday junctions with the help of the single-strand annealing protein Redβ. Individual DNA single strands are initially coated with protein monomers and subsequently hybridized to form a rigid blunt-ended four-arm junction. We investigate the efficiency of this approach for different DNA/protein ratios, as well as for different DNA sequence lengths. Furthermore, we also evaluate the potential of Redβ to anneal sticky-end modified Holliday junctions into hierarchical assemblies. We demonstrate the Redβ-mediated annealing of Holliday junction dimers, multimers, and extended networks several microns in size. While these hybrid DNA–protein nanostructures may find applications in the crystallization of DNA–protein complexes, our work shows the great potential of Redβ to aid in the synthesis of functional DNA nanostructures under mild reaction conditions.

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Reversible supra‐folding of user‐programmed functional DNA nanostructures on fuzzy cationic substrates

Angewandte Chemie ◽

10.1002/ange.202101909 ◽

2021 ◽

Author(s):

Koyomi Nakazawa ◽

Farah El Fakih ◽

Vincent Jallet ◽

Caroline Rossi–Gendron ◽

Marina Mariconti ◽

...

Keyword(s):

Dna Nanostructures ◽

Functional Dna

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Genetically Encoding Ultra-Stable Virus-like Particles Encapsulating Functional DNA Nanostructures in Living Bacteria

10.21203/rs.3.rs-98920/v1 ◽

2020 ◽

Author(s):

Shai Zilberzwige-Tal ◽

Dan Alon ◽

Danielle Gazit ◽

Shahar Zachariah ◽

Amit Hollander ◽

...

Keyword(s):

Dna Nanotechnology ◽

Nucleic Acid Content ◽

Dna Nanostructures ◽

Loss Of Function ◽

Virus Like Particles ◽

Bio Imaging ◽

Functional Dna ◽

Biological Environment

Abstract DNA nanotechnology is leading the field of in vitro molecular-scale device engineering, accumulating to a dazzling array of applications from zeolite-like catalysts to bio-imaging. However, while DNA nanostructures' function is robust under in vitro settings, their implementation in real-world conditions requires overcoming their rapid degradation and subsequent loss of function. Viruses are incredibly sophisticated supramolecular assemblies, able to protect their nucleic acid content in the relatively inhospitable biological environment. Inspired by this natural ability, we engineered both in vitro and in vivo technologies, enabling the encapsulation and protection of functional DNA nanostructures inside MS2 bacteriophage virus-like particles (VLPs). We demonstrate the ssDNA-VLPs nanocomposites (NCs) abilities to encapsulate single-stranded-DNA (ssDNA) of an unprecedented variety of sizes (200–1500 nucleotides (nt)), sequences, and structures while retaining their functionality. Moreover, by exposing these NCs to hostile biological conditions, such as human blood serum, we exhibit that the VLPs serves as an excellent protective shell. To the best of our knowledge, these engineered NCs pose key properties that are yet unattainable by current fabrication methods.

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