Routing of individual polymers in designed patterns

A proximity effect has been invoked to explain the enhanced activity of enzyme cascades on DNA scaffolds. Using the cascade reaction carried out by glucose oxidase and horseradish peroxidase as a model system, here we study the kinetics of the cascade reaction when the enzymes are free in solution, when they are conjugated to each other and when a competing enzyme is present. No proximity effect is found, which is in agreement with models predicting that the rapidly diffusing hydrogen peroxide intermediate is well mixed. We suggest that the reason for the activity enhancement of enzymes localized by DNA scaffolds is that the pH near the surface of the negatively charged DNA nanostructures is lower than that in the bulk solution, creating a more optimal pH environment for the anchored enzymes. Our findings challenge the notion of a proximity effect and provide new insights into the role of DNA scaffolds.

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“…Knudsen et al 40. measured the surface potential of a single-stranded DNA-grafted brush polymer by atomic force microscopy to be −130 mV.…”

Section: Resultsmentioning

confidence: 99%

Proximity does not contribute to activity enhancement in the glucose oxidase–horseradish peroxidase cascade

2016

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“…[22][23][24][25][26][27][28][29][30] DNA conjugates often combine multiple self-assembly motifs enabling selective and orthogonal noncovalent interactions. [31][32][33][34][35][36][37] To date, little is known about materials from DNA conjugates, in which the interactions between the non-DNA parts are central for the hierarchical organization. Therefore, the study of the mechanistic details of self-assembly in such systems is important.…”

Section: Introductionmentioning

confidence: 99%

Pathway Diversity in the Self-Assembly of DNA-Derived Bioconjugates

Vyborna

Vybornyi²,

Häner

2016

Bioconjugate Chem.

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The pathway diversity of the self-assembly of amphiphilic DNA-pyrene conjugates is described.The hydrophobic pyrene units drive the self-assembly of the anionic oligomers in an aqueous environment into ribbon-shaped, DNA-grafted supramolecular polymers. Isothermal mixing of two types of sorted ribbons, each of which contains only one kind of two complementary oligonucleotides, results in the formation of tight networks. Thermal disassembly of these kinetically trapped networks and subsequent re-assembly of the liberated components leads to mixed supramolecular polymers, which now contain both types of oligonucleotides. The scrambling of the oligonucleotides prevents the interaction between ribbons and, thus, network formation. The results show that a high local density of DNA strands in linear arrays favors hybridization among sorted polymers, whereas hybridization among mixed arrays is prevented. The lack of DNA hybridization among mixed ribbons is ascribed to the electrostatic repulsion between identical, hence non-complementary, oligonucleotides. The findings highlight the importance of kinetically trapped states on the structural and functional properties of supramolecular polymers containing orthogonal self-assembly motifs.

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“…[10][11][12] The computational tools [11][12][13] for designing such objects have emerged along with these techniques, and this progress has opened up new possibilities for the researchers to effortlessly build their own nanostructures for tailored uses. [14] Recently demonstrated applications based on customized DNA nanostructures include artificial ion channels, [15] optical (plasmonic and photonic) structures, [16,17] high-precision molecular positioning devices, [18] modifiable templates for arranging, e.g., proteins, [19][20][21] polymers, [22] and nanotubes, [23] as well as DNA-assisted techniques for creating arbitrarily shaped metal nanoparticles. [24][25][26] Fully addressable DNA nanostructures, especially DNA origami, possess huge potential to serve as inherently biocompatible and versatile molecular platforms.…”

mentioning

confidence: 99%

Protein Coating of DNA Nanostructures for Enhanced Stability and Immunocompatibility

Auvinen

Zhang

Nonappa

et al. 2017

Adv Healthcare Materials

174

144

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DNA nanotechnology has taken a giant leap toward real-life applications during the recent years. [1,2] After the invention of DNA origami in 2006, [3] the whole research field has grown exponentially. [2,4] Today there are numerous ways to build discrete user-defined, accurate, and fully addressable DNA nanostructures, such as scaffolded 2D and 3D origami [3,5,6] with twists, curves, and bends, [7,8] Lego-like objects formed from molecular canvases, [9] and wireframe-based meshed constructions. [10][11][12] The computational tools [11][12][13] for designing such objects have emerged along with these techniques, and this progress has opened up new possibilities for the researchers to effortlessly build their own nanostructures for tailored uses. [14] Recently demonstrated applications based on customized DNA nanostructures include artificial ion channels, [15] optical (plasmonic and photonic) structures, [16,17] high-precision molecular positioning devices, [18] modifiable templates for arranging, e.g., proteins, [19][20][21] polymers, [22] and nanotubes, [23] as well as DNA-assisted techniques for creating arbitrarily shaped metal nanoparticles. [24][25][26] Fully addressable DNA nanostructures, especially DNA origami, possess huge potential to serve as inherently biocompatible and versatile molecular platforms. However, their use as delivery vehicles in therapeutics is compromised by their low stability and poor transfection rates. This study shows that DNA origami can be coated by precisely defined oneto-one protein-dendron conjugates to tackle the aforementioned issues. The dendron part of the conjugate serves as a cationic binding domain that attaches to the negatively charged DNA origami surface via electrostatic interactions. The protein is attached to dendron through cysteinemaleimide bond, making the modular approach highly versatile. This work demonstrates the coating using two different proteins: bovine serum albumin (BSA) and class II hydrophobin (HFBI). The results reveal that BSA-coating significantly improves the origami stability against endonucleases (DNase I) and enhances the transfection into human embryonic kidney (HEK293) cells. Importantly, it is observed that BSA-coating attenuates the activation of immune response in mouse primary splenocytes. Serum albumin is the most abundant protein in the blood with a long circulation half-life and has already found clinically approved applications in drug delivery. It is therefore envisioned that the proposed system can open up further opportunities to tune the properties of DNA nanostructures in biological environment, and enable their use in various delivery applications.

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Routing of individual polymers in designed patterns

Cited by 196 publications

References 45 publications

Proximity does not contribute to activity enhancement in the glucose oxidase–horseradish peroxidase cascade

Proximity does not contribute to activity enhancement in the glucose oxidase–horseradish peroxidase cascade

Pathway Diversity in the Self-Assembly of DNA-Derived Bioconjugates

Protein Coating of DNA Nanostructures for Enhanced Stability and Immunocompatibility

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