Reconfiguring DNA Nanotube Architectures <i>via</i> Selective Regulation of Terminating Structures

Schaffter, Samuel W.; Schneider, Joanna; Agrawal, Deepak K.; Pacella, Michael S.; Rothchild, Eric; Murphy, Terence M.; Schulman, Rebecca

doi:10.1021/acsnano.0c05340

Cited by 19 publications

(18 citation statements)

References 51 publications

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“… 43 Recent developments in dynamic nanoassembly also highlight the need to understand the impact of local environment and organization on enzyme activity. 36 , 44 , 45 …”

Section: Introductionmentioning

confidence: 99%

Cascaded Enzyme Reactions over a Three-Dimensional, Wireframe DNA Origami Scaffold

Kahn

Xiong

Huang

et al. 2022

JACS Au

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DNA nanotechnology has increasingly been used as a platform to scaffold enzymes based on its unmatched ability to structure enzymes in a desired format. The capability to organize enzymes has taken many forms from more traditional 2D pairings on individual scaffolds to recent works introducing enzyme organizations in 3D lattices. As the ability to define nanoscale structure has grown, it is critical to fully deconstruct the impact of enzyme organization at the single-scaffold level. Here, we present an open, three-dimensional (3D) DNA wireframe octahedron which is used to create a library of spatially arranged organizations of glucose oxidase and horseradish peroxidase. We explore the contribution of enzyme spacing, arrangement, and location on the 3D scaffold to cascade activity. The experiments provide insight into enzyme scaffold design, including the insignificance of scaffold sequence makeup on activity, an increase in activity at small enzyme spacings of <10 nm, and activity changes that arise from discontinuities in scaffold architecture. Most notably, the experiments allow us to determine that enzyme colocalization itself on the DNA scaffold dominates over any specific enzyme arrangement.

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“… 43 Recent developments in dynamic nanoassembly also highlight the need to understand the impact of local environment and organization on enzyme activity. 36 , 44 , 45 …”

Section: Introductionmentioning

confidence: 99%

Cascaded Enzyme Reactions over a Three-Dimensional, Wireframe DNA Origami Scaffold

Kahn

Xiong

Huang

et al. 2022

JACS Au

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“…The high programmability and the possibility to predict in a straightforward way the thermodynamics of the involved non‐covalent hydrogen bond base pairings, together with the low cost of synthesis, has allowed the self‐assembly of unprecedented precise 2D and 3D structures, hydrogels, nanodevices and polymers from rationally designed synthetic DNA oligonucleotides [39–45] . Recently, the possibility to reconfigure these structures has also been demonstrated enabling dynamic DNA structures with potential adaptive behavior [46–51] …”

Section: Introductionmentioning

confidence: 99%

“…[39][40][41][42][43][44][45] Recently,t he possibility to reconfigure these structures has also been demonstrated enabling dynamic DNAs tructures with potential adaptive behavior. [46][47][48][49][50][51] Motivated by the above arguments and taking advantage of the addressability of DNAw es how here that synthetic nucleic acids are particularly suited for designing self-assembling dynamic polymer-like structures that can be easily reconfigured and reorganized by external inputs.T od ot his we have rationally designed monomer units that can be orthogonally addressed by different DNAr egulator strands and can be used to structurally reorganize the polymers between homopolymers,r andom co-polymers and two-tile and three-tile block co-polymers (Figure 1d). Thev ersatility of the systems presented in this study shows the ease at with DNA-based supramolecular polymers can be controlled using external triggers.…”

Section: Introductionmentioning

confidence: 99%

Reorganization of Self‐Assembled DNA‐Based Polymers using Orthogonally Addressable Building Blocks**

et al. 2021

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Nature uses the breaking and making of non-covalent interactions to achieve the reversible formation and structural reconfiguration of biopolymers, a strategy that permits dynamic adaptation in response to external cues and to changes in the environment. Inspired by this observation and taking advantage of the addressability and programmability of DNA/DNA non-covalent interactions we report here the rational design of orthogonal DNA-based addressable tiles that self-assemble into polymer-like structures that can be reconfigured and reorganized by external inputs. The different tiles share the same 5-nucleotide sticky ends responsible for self-assembly but are rationally designed to contain a specific regulator-binding domain that can be orthogonally targeted by different DNA regulator strands (activators and inhibitors). We show that by sequentially adding specific activators and inhibitors it is possible to re-organize in a dynamic and reversible way the formed polymer-like structures to display well-defined distributions: homopolymers made of a single tile, random polymers in which different tiles are distributed randomly and block structures in which the tiles are organized in segments. The versatility of the systems presented in this study shows the ease with which DNA-based addressable monomers can be designed to create reconfigurable synthetic micron-scale DNA structures offering a new approach to the growing field of supramolecular polymers.

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“…[39][40][41][42][43][44][45] Recently, the possibility to reconfigure these structures has also been demonstrated enabling dynamic DNA structures with potential adaptive behaviour. [46][47][48][49][50][51] Motivated by the above arguments and taking advantage of the addressability of DNA we show here that synthetic nucleic acids are particularly suited for designing selfassembling dynamic polymer-like structures that can be easily reconfigured and reorganized by external inputs. To do this we have rationally designed monomer units that can be orthogonally addressed by different DNA regulator strands and can be used to structurally reorganize the polymers between homopolymers, random co-polymers and diand tri-block co-polymers (Fig.…”

Section: Introductionmentioning

confidence: 99%

Reorganization of Self-Assembled DNA-Based Polymers Using Orthogonally Addressable Building Blocks

Gentile¹,

Grosso²,

Prins³

et al. 2021

Preprint

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Taking advantage of the addressability and programmability of DNA/DNA non-covalent interactions we report here the rational design of orthogonal DNA-based addressable tiles that self-assemble into polymer-like structures that can be reconfigured and reorganized by external inputs. The different tiles share the same 5-nucleotide sticky ends responsible for self-assembly but are rationally designed to contain a specific regulator-binding domain that can be orthogonally targeted by different DNA regulator strands (activators and inhibitors). We show that by sequentially adding specific activators and inhibitors it is possible to re-organize in a dynamic and reversible way the formed polymer-like structures to display well-defined distributions: homopolymers made of a single tile, random polymers in which different tiles are distributed randomly and block structures in which the tiles are organized in segments.

show abstract

Reconfiguring DNA Nanotube Architectures via Selective Regulation of Terminating Structures

Cited by 19 publications

References 51 publications

Cascaded Enzyme Reactions over a Three-Dimensional, Wireframe DNA Origami Scaffold

Cascaded Enzyme Reactions over a Three-Dimensional, Wireframe DNA Origami Scaffold

Reorganization of Self‐Assembled DNA‐Based Polymers using Orthogonally Addressable Building Blocks**

Reorganization of Self-Assembled DNA-Based Polymers Using Orthogonally Addressable Building Blocks

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