Your search keyword '"Nijenhuis, Minke A. D."' showing total 15 results

1. DNA origami

Author

Dey, Swarup, Fan, Chunhai, Gothelf, Kurt V., Li, Jiang, Lin, Chenxiang, Liu, Longfei, Liu, Na, Nijenhuis, Minke A. D., Sacca, Barbara, Simmel, Friedrich C., Yan, Hao, and Zhan, Pengfei

Subjects

Physics - Biological Physics, Condensed Matter - Soft Condensed Matter

Abstract

Biological materials are self-assembled with near-atomic precision in living cells, whereas synthetic 3D structures generally lack such precision and controllability. Recently, DNA nanotechnology, especially DNA origami technology, has been useful in the bottom-up fabrication of well-defined nanostructures ranging from tens of nanometres to sub-micrometres. In this Primer, we summarize the methodologies of DNA origami technology, including origami design, synthesis, functionalization and characterization. We highlight applications of origami structures in nanofabrication, nanophotonics and nanoelectronics, catalysis, computation, molecular machines, bioimaging, drug delivery and biophysics. We identify challenges for the field, including size limits, stability issues and the scale of production, and discuss their possible solutions. We further provide an outlook on next-generation DNA origami techniques that will allow in vivo synthesis and multiscale manufacturing.

Published

2021

2. Self-Assembly of Ultrasmall 3D Architectures of (l)-Acyclic Threoninol Nucleic Acids with High Thermal and Serum Stability.

Author

Skaanning, Mads K., Bønnelykke, Jonas, Nijenhuis, Minke A. D., Samanta, Anirban, Smidt, Jakob Melgaard, and Gothelf, Kurt V.

Published

2024

3. Folding Double‐Stranded DNA into Designed Shapes with Triplex‐Forming Oligonucleotides (Adv. Mater. 40/2023)

Author

Ng, Cindy, primary, Samanta, Anirban, additional, Mandrup, Ole Aalund, additional, Tsang, Emily, additional, Youssef, Sarah, additional, Klausen, Lasse Hyldgaard, additional, Dong, Mingdong, additional, Nijenhuis, Minke A. D., additional, and Gothelf, Kurt V., additional

Published

2023

4. Protein‐Templated Reactions Using DNA‐Antibody Conjugates

Author

Baranda Pellejero, Lorena, primary, Nijenhuis, Minke A. D., additional, Ricci, Francesco, additional, and Gothelf, Kurt V., additional

Published

2022

5. Protein-Induced Fluorescence Enhancement and Quenching in a Homogeneous DNA-Based Assay for Rapid Detection of Small-Molecule Drugs in Human Plasma

Author

Nielsen, Line D. F., primary, Hansen-Bruhn, Malthe, additional, Nijenhuis, Minke A. D., additional, and Gothelf, Kurt V., additional

Published

2022

6. Protein‐Templated Reactions Using DNA‐Antibody Conjugates.

Author

Baranda Pellejero, Lorena, Nijenhuis, Minke A. D., Ricci, Francesco, and Gothelf, Kurt V.

Published

2023

7. A Wireframe DNA Cube: Antibody Conjugate for Targeted Delivery of Multiple Copies of Monomethyl Auristatin E

Author

Märcher, Anders, primary, Nijenhuis, Minke A. D., additional, and Gothelf, Kurt V., additional

Published

2021

8. DNA origami

Author

Dey, Swarup, primary, Fan, Chunhai, additional, Gothelf, Kurt V., additional, Li, Jiang, additional, Lin, Chenxiang, additional, Liu, Longfei, additional, Liu, Na, additional, Nijenhuis, Minke A. D., additional, Saccà, Barbara, additional, Simmel, Friedrich C., additional, Yan, Hao, additional, and Zhan, Pengfei, additional

Published

2021

9. Entropy-Based Rational Modulation of the pKa of a Synthetic pH-Dependent Nanoswitch

Author

Mariottini, Davide, primary, Idili, Andrea, additional, Nijenhuis, Minke A. D., additional, Ercolani, Gianfranco, additional, and Ricci, Francesco, additional

Published

2019

10. DNA-Based Nanodevices Controlled by Purely Entropic Linker Domains

Author

Mariottini, Davide, primary, Idili, Andrea, additional, Nijenhuis, Minke A. D., additional, de Greef, Tom F. A., additional, and Ricci, Francesco, additional

Published

2018

11. Entropy-Based Rational Modulation of the pKa of a Synthetic pH-Dependent Nanoswitch.

Author

Mariottini, Davide, Idili, Andrea, Nijenhuis, Minke A. D., Ercolani, Gianfranco, and Ricci, Francesco

Published

2019

12. Small-Molecule-Induced and Cooperative Enzyme Assembly on a 14-3-3 Scaffold

Author

den Hamer, Anniek, primary, Lemmens, Lenne J. M., additional, Nijenhuis, Minke A. D., additional, Ottmann, Christian, additional, Merkx, Maarten, additional, de Greef, Tom F. A., additional, and Brunsveld, Luc, additional

Published

2016

13. Entropy-Based Rational Modulation of the pKaof a Synthetic pH-Dependent Nanoswitch

Author

Mariottini, Davide, Idili, Andrea, Nijenhuis, Minke A. D., Ercolani, Gianfranco, and Ricci, Francesco

Abstract

The rational regulation of the pKaof an ionizable group in a synthetic device could be achieved by controlling the entropy of the linker connecting the hydrogen bond forming domains. We demonstrate this by designing a set of pH-responsive synthetic DNA-based nanoswitches that share the same hydrogen bond forming domains but differ in the length of the linker. The observed acidic constant (pKa) of these pH-dependent nanoswitches is linearly dependent on the entropic cost associated with loop formation and is gradually shifted to more basic pH values when the length of the linker domain is reduced. Through mathematical modeling and thermodynamic characterization we demonstrate that the modulation of the observed pKais due to a purely entropic contribution. This approach represents a very versatile strategy to rationally modulate the pKaof synthetic devices in a highly predictable and accurate way.

Published

2019

14. Small-Molecule-Induced and Cooperative Enzyme Assembly on a 14-3-3 Scaffold.

Author

den Hamer, Anniek, Lemmens, Lenne J. M., Nijenhuis, Minke A. D., Ottmann, Christian, Merkx, Maarten, de Greef, Tom F. A., and Brunsveld, Luc

Published

2017

15. Entropy-Based Rational Modulation of the p K a of a Synthetic pH-Dependent Nanoswitch.

Author

Mariottini D, Idili A, Nijenhuis MAD, Ercolani G, and Ricci F

Abstract

The rational regulation of the p K of an ionizable group in a synthetic device could be achieved by controlling the entropy of the linker connecting the hydrogen bond forming domains. We demonstrate this by designing a set of pH-responsive synthetic DNA-based nanoswitches that share the same hydrogen bond forming domains but differ in the length of the linker. The observed acidic constant (p a of an ionizable group in a synthetic device could be achieved by controlling the entropy of the linker connecting the hydrogen bond forming domains. We demonstrate this by designing a set of pH-responsive synthetic DNA-based nanoswitches that share the same hydrogen bond forming domains but differ in the length of the linker. The observed acidic constant (p K is due to a purely entropic contribution. This approach represents a very versatile strategy to rationally modulate the p a of synthetic devices in a highly predictable and accurate way.K a is due to a purely entropic contribution. This approach represents a very versatile strategy to rationally modulate the p K a of synthetic devices in a highly predictable and accurate way.

Published

2019