In biological systems, large and complex structures are often assembled from multiple simpler identical subunits. This strategy—homooligomerization—allows efficient genetic encoding of structures and avoids the need to control the stoichiometry of multiple distinct units. It also allows the minimal number of distinct subunits when designing artificial nucleic acid structures. Here, we present a robust self-assembly system in which homooligomerizable tiles are formed from intramolecularly folded RNA single strands. Tiles are linked through an artificially designed branched kissing-loop motif, involving Watson–Crick base pairing between the single-stranded regions of a bulged helix and a hairpin loop. By adjusting the tile geometry to gain co...
Molecular self-assembly offers a 'bottom-up' route to fabrication with subnanometre precision of com...
Deoxyribonucleic acid (DNA) and Ribonucleic acid (RNA) are molecules that store and transmit genetic...
DNA is used in nature as a biological material of choice to store and transfer genetic information. ...
This study presents a robust homooligomeric self-assembly system based on RNA and DNA tiles that are...
DNA has recently been used as a programmable ‘smart ’ building block for the assembly of a wide rang...
RNA self-assembly has emerged as a powerful building material in nanoconstruction, mainly because of...
Nucleic acid nanotechnology proposes many approaches to construct self-assembled structures using RN...
Programmed self-assembly of strands of nucleic acid has proved highly effective for creating a wide ...
Artificial DNA and RNA structures have been used as scaffolds for a variety of nanoscale devices. In...
Co-transcriptionally folding RNA nanostructures have great potential as biomolecular scaffolds, whic...
RNA can self-assemble into complex structures through base pairing, as well as encode information an...
Three self-assembly strategies were utilized for assembly of novel functional DNA/RNA nanostructures...
RNA nanotechnology has attracted tremendous attention recently and is rapidly developing. The versat...
Nucleic acids have proven to be remarkably versatile as an engineering material for chemical tasks i...
Knots and links are ubiquitous and constantly provide inspiration in all spheres of human endeavor. ...
Molecular self-assembly offers a 'bottom-up' route to fabrication with subnanometre precision of com...
Deoxyribonucleic acid (DNA) and Ribonucleic acid (RNA) are molecules that store and transmit genetic...
DNA is used in nature as a biological material of choice to store and transfer genetic information. ...
This study presents a robust homooligomeric self-assembly system based on RNA and DNA tiles that are...
DNA has recently been used as a programmable ‘smart ’ building block for the assembly of a wide rang...
RNA self-assembly has emerged as a powerful building material in nanoconstruction, mainly because of...
Nucleic acid nanotechnology proposes many approaches to construct self-assembled structures using RN...
Programmed self-assembly of strands of nucleic acid has proved highly effective for creating a wide ...
Artificial DNA and RNA structures have been used as scaffolds for a variety of nanoscale devices. In...
Co-transcriptionally folding RNA nanostructures have great potential as biomolecular scaffolds, whic...
RNA can self-assemble into complex structures through base pairing, as well as encode information an...
Three self-assembly strategies were utilized for assembly of novel functional DNA/RNA nanostructures...
RNA nanotechnology has attracted tremendous attention recently and is rapidly developing. The versat...
Nucleic acids have proven to be remarkably versatile as an engineering material for chemical tasks i...
Knots and links are ubiquitous and constantly provide inspiration in all spheres of human endeavor. ...
Molecular self-assembly offers a 'bottom-up' route to fabrication with subnanometre precision of com...
Deoxyribonucleic acid (DNA) and Ribonucleic acid (RNA) are molecules that store and transmit genetic...
DNA is used in nature as a biological material of choice to store and transfer genetic information. ...