Litcius/Paper detail

DNA Sequence and Length Dictate the Assembly of Nucleic Acid Block Copolymers

Felix J. Rizzuto, Michael D. Dore, Muhammad Ghufran Rafique, Xin Luo, Hanadi F. Sleiman

2022Journal of the American Chemical Society37 citationsDOI

Abstract

The self-assembly of block copolymers is often rationalized by structure and microphase separation; pathways that diverge from this parameter space may provide new mechanisms of polymer assembly. Here, we show that the sequence and length of single-stranded DNA directly influence the self-assembly of sequence-defined DNA block copolymers. While increasing the length of DNA led to predictable changes in self-assembly, changing only the sequence of DNA produced three distinct structures: spherical micelles (spherical nucleic acids, SNAs) from flexible poly(thymine) DNA, fibers from semirigid mixed-sequence DNA, and networked superstructures from rigid poly(adenine) DNA. The secondary structure of poly(adenine) DNA strands drives a temperature-dependent polymerization and assembly mechanism: copolymers stored in an SNA reservoir form fibers after thermal activation, which then aggregate upon cooling to form interwoven networks. DNA is often used as a programming code that aids in nanostructure addressability and function. Here, we show that the inherent physical and chemical properties of single-stranded DNA sequences also make them an ideal material to direct self-assembled morphologies and select for new methods of supramolecular polymerization.

Topics & Concepts

CopolymerDNAChemistrySequence (biology)Nucleic acidPolymerizationDNA nanotechnologyPolymerThymineSelf-assemblyBiophysicsA-DNASupramolecular chemistryCrystallographyBiochemistryCrystal structureOrganic chemistryBiologyAdvanced Polymer Synthesis and CharacterizationDNA and Nucleic Acid ChemistryPolymer Surface Interaction Studies