Reconfigurable pH-Responsive DNA Origami Lattices

Julin, Sofia; Linko, Veikko; Kostiainen, Mauri A.

doi:10.1021/acsnano.3c03438

Cited by 20 publications

(11 citation statements)

References 60 publications

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“…Such origami unit can be further assembled into one-dimensional and two-dimensional lattices which still possess pH responsiveness. 25 Moreover, several groups recently 26 , 27 have explored using triplex formation to fold duplex scaffold into defined nanostructures. In comparison to standard Watson-Crick-mediated duplex origami, triplex origami is based on Hoogsteen binding to align neighboring duplex.…”

Section: Intermolecular Dna Interactionsmentioning

confidence: 99%

The motive forces in DNA-enabled nanomachinery

Zhang,

Liu

2024

iScience

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Section: Intermolecular Dna Interactionsmentioning

confidence: 99%

The motive forces in DNA-enabled nanomachinery

Zhang,

Liu

2024

iScience

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“…pH-responsive nucleic acid sequences are found throughout natural DNA structuresthe i -motif may bind proteins during transcription, and triplex DNA regulates nucleic acid metabolism and gene function . The predictability and sensitivity of these structures have underscored their use in dynamic nanotechnology applications, − for example, in molecular machinery, − synthetic biology, , switchable structures, − and plasmonic DNA devices . In contrast, the use of the A-motif (self-associated adenines that are protonated at the N7 position) has lagged, potentially due to the low pH at which it is activated for assembly as well as the limited/contradictory knowledge of its scope and applicability. − Recently, we demonstrated the use of this protonated adenine motif in the reversible fibrillization of DNA origami .…”

Section: Introductionmentioning

confidence: 99%

Divergent Polymer Superstructures from Protonated Poly(adenine) DNA and RNA

Cox,

Bai,

Platnich

et al. 2024

Biomacromolecules

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Studies have shown that poly(adenine) DNA and RNA strands protonate at a low pH to form self-associating duplexes; however, the nanoscopic morphology of these structures is unclear. Here, we use Transition Electron Microscopy (TEM), Atomic Force Microscopy (AFM), dynamic light scattering (DLS), and fluorescence spectroscopy to show that both ribose identity (DNA or RNA) and assembly conditions (thermal or roomtemperature annealing) dictate unique hierarchical structures for poly(adenine) sequences at a low pH. We show that while the thermodynamic product of protonating poly(adenine) DNA is a discrete dimer of two DNA strands, the kinetic product is a supramolecular polymer that branches and aggregates to form microndiameter superstructures. In contrast, we find that protonated poly(A) RNA polymerizes into micrometer-length, twisted fibers under the same conditions. These divergent hierarchical morphologies highlight the amplification of subtle chemical differences between RNA and DNA into unique nanoscale behaviors. With the use of poly(adenine) strands spanning vaccine technologies, sensing, and dynamic biotechnology, understanding and controlling the underlying assembly pathways of these structures are critical to developing robust, programmable nanotechnologies.

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“…More specifically, the DOCs can be polymerized into reconfigurable 1D filament-like chains or 2D lattices by DNA hybridization. 20,21 The reconfiguration of the microscale DNA architectures is driven by strand displacement reactions. 22−24 1a), we show that their polymerization can result in membrane deformation to different extents depending on the degree of polymerization of the DOC networks.…”

mentioning

confidence: 99%

“…In this work, we demonstrate a membrane-bound DNA origami cross (DOC) chiral structure that is capable of both polymerization and reconfiguration to engineer the membrane morphology of giant unilamellar vesicles (GUVs). More specifically, the DOCs can be polymerized into reconfigurable 1D filament-like chains or 2D lattices by DNA hybridization. , The reconfiguration of the microscale DNA architectures is driven by strand displacement reactions. − After anchoring the DOCs onto GUVs (Figure a), we show that their polymerization can result in membrane deformation to different extents depending on the degree of polymerization of the DOC networks.…”

mentioning

confidence: 99%

Modulating Lipid Membrane Morphology by Dynamic DNA Origami Networks

et al. 2023

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Membrane morphology and its dynamic adaptation regulate many cellular functions, which are often mediated by membrane proteins. Advances in DNA nanotechnology have enabled the realization of various protein-inspired structures and functions with precise control at the nanometer level, suggesting a viable tool to artificially engineer membrane morphology. In this work, we demonstrate a DNA origami cross (DOC) structure that can be anchored onto giant unilamellar vesicles (GUVs) and subsequently polymerized into micrometer-scale reconfigurable one-dimensional (1D) chains or two-dimensional (2D) lattices. Such DNA origami-based networks can be switched between lefthanded (LH) and right-handed (RH) conformations by DNA fuels and exhibit potent efficacy in remodeling the membrane curvatures of GUVs. This work sheds light on designing hierarchically assembled dynamic DNA systems for the programmable modulation of synthetic cells for useful applications.

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Reconfigurable pH-Responsive DNA Origami Lattices

Cited by 20 publications

References 60 publications

The motive forces in DNA-enabled nanomachinery

The motive forces in DNA-enabled nanomachinery

Divergent Polymer Superstructures from Protonated Poly(adenine) DNA and RNA

Modulating Lipid Membrane Morphology by Dynamic DNA Origami Networks

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