Your search keyword '"Günther Pardatscher"' showing total 11 results

1. Long-range movement of large mechanically interlocked DNA nanostructures

Author

Jonathan List, Elisabeth Falgenhauer, Enzo Kopperger, Günther Pardatscher, and Friedrich C. Simmel

Subjects

Science

Abstract

Rotaxanes are interlocked molecules that can undergo sliding and rotational movements and can be used in artificial molecular machines and motors. Here, Simmel and co-workers show a rigid rotaxane structures consisting of DNA origami subunits that can slide over several hundreds of nanometres.

Published

2016

2. Genexpression auf DNA‐Biochips: Strukturierung durch Strangverdrängungs‐Lithographie

Author

Matthaeus Schwarz-Schilling, Friedrich C. Simmel, Günther Pardatscher, Roy Bar-Ziv, and Shirley S. Daube

Subjects

0301 basic medicine, 03 medical and health sciences, 030104 developmental biology, Chemistry, General Medicine, 010402 general chemistry, 01 natural sciences, 0104 chemical sciences

Published

2018

3. DNA condensation in one dimension

Author

Friedrich C. Simmel, Roy Bar-Ziv, Shirley S. Daube, Ohad Vonshak, Günther Pardatscher, and Dan Bracha

Subjects

Nanostructure, Materials science, Static Electricity, Biomedical Engineering, Nanowire, Bioengineering, Nanotechnology, 02 engineering and technology, Microscopy, Atomic Force, 010402 general chemistry, DNA condensation, 01 natural sciences, chemistry.chemical_compound, Monolayer, DNA nanotechnology, General Materials Science, Electrical and Electronic Engineering, Biochip, Electronic circuit, DNA, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Nanostructures, 0104 chemical sciences, chemistry, Microscopy, Electron, Scanning, Nucleic Acid Conformation, 0210 nano-technology

Abstract

DNA can be programmed to assemble into a variety of shapes and patterns on the nanoscale and can act as a template for hybrid nanostructures such as conducting wires, protein arrays and field-effect transistors. Current DNA nanostructures are typically in the sub-micrometre range, limited by the sequence space and length of the assembled strands. Here we show that on a patterned biochip, DNA chains collapse into one-dimensional (1D) fibres that are 20 nm wide and around 70 µm long, each comprising approximately 35 co-aligned chains at its cross-section. Electron beam writing on a photocleavable monolayer was used to immobilize and pattern the DNA molecules, which condense into 1D bundles in the presence of spermidine. DNA condensation can propagate and split at junctions, cross gaps and create domain walls between counterpropagating fronts. This system is inherently adept at solving probabilistic problems and was used to find the possible paths through a maze and to evaluate stochastic switching circuits. This technique could be used to propagate biological or ionic signals in combination with sequence-specific DNA nanotechnology or for gene expression in cell-free DNA compartments.

Published

2016

4. Gene Expression on DNA Biochips Patterned with Strand-Displacement Lithography

Author

Shirley S. Daube, Friedrich C. Simmel, Roy Bar-Ziv, Günther Pardatscher, and Matthaeus Schwarz-Schilling

Subjects

0301 basic medicine, Materials science, Optical Imaging, Gene Expression, Nanotechnology, General Chemistry, DNA, Catalysis, law.invention, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Template, Resist, chemistry, law, Ultraviolet light, Photolithography, Biochip, DNA Probes, Lithography, Electron-beam lithography, Oligonucleotide Array Sequence Analysis

Abstract

Lithographic patterning of DNA molecules enables spatial organization of cell-free genetic circuits under well-controlled experimental conditions. Here, we present a biocompatible, DNA-based resist termed "Bephore", which is based on commercially available components and can be patterned by both photo- and electron-beam lithography. The patterning mechanism is based on cleavage of a chemically modified DNA hairpin by ultraviolet light or electrons, and a subsequent strand-displacement reaction. All steps are performed in aqueous solution and do not require chemical development of the resist, which makes the lithographic process robust and biocompatible. Bephore is well suited for multistep lithographic processes, enabling the immobilization of different types of DNA molecules with micrometer precision. As an application, we demonstrate compartmentalized, on-chip gene expression from three sequentially immobilized DNA templates, leading to three spatially resolved protein-expression gradients.

Published

2018

5. Functional Surface-immobilization of Genes Using Multistep Strand Displacement Lithography

Author

Friedrich C. Simmel, Sandra Sagredo, Günther Pardatscher, and Matthaeus Schwarz-Schilling

Subjects

0301 basic medicine, Materials science, General Chemical Engineering, Microfluidics, Gene Expression, Bioengineering, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, chemistry.chemical_compound, Synthetic biology, Bioreactors, Gene expression, Dimethylpolysiloxanes, Biochip, Gene, Oligonucleotide Array Sequence Analysis, Total internal reflection fluorescence microscope, General Immunology and Microbiology, Polydimethylsiloxane, General Neuroscience, DNA, 030104 developmental biology, chemistry, Printing, Biological system

Abstract

Immobilization of genes on lithographically structured surfaces allows the study of compartmentalized gene expression processes in an open microfluidic bioreactor system. In contrast to other approaches towards artificial cellular systems, such a setup allows for a continuous supply with gene expression reagents and simultaneous draining of waste products. This facilitates the implementation of cell-free gene expression processes over extended periods of time, which is important for the realization of dynamic gene regulatory feedback systems. Here we provide a detailed protocol for the fabrication of genetic biochips using a simple-to-use lithographic technique based on DNA strand displacement reactions, which exclusively uses commercially available components. We also provide a protocol on the integration of compartmentalized genes with a polydimethylsiloxane (PDMS)-based microfluidic system. Furthermore, we show that the system is compatible with total internal reflection fluorescence (TIRF) microscopy, which can be used for the direct observation of molecular interactions between DNA and molecules contained in the expression mix.

Published

2018

6. Single Molecule Characterization of DNA Binding and Strand Displacement Reactions on Lithographic DNA Origami Microarrays

Author

Anton Kuzyk, Max Scheible, Günther Pardatscher, and Friedrich C. Simmel

Subjects

Materials science, Mechanical Engineering, Bioengineering, Nanotechnology, DNA, General Chemistry, Condensed Matter Physics, Single-molecule experiment, chemistry.chemical_compound, Microscopy, Fluorescence, chemistry, DNA nanotechnology, Nucleic Acid Conformation, DNA origami, Molecule, General Materials Science, A-DNA, DNA microarray, Electron-beam lithography, Oligonucleotide Array Sequence Analysis

Abstract

The combination of molecular self-assembly based on the DNA origami technique with lithographic patterning enables the creation of hierarchically ordered nanosystems, in which single molecules are positioned at precise locations on multiple length scales. Based on a hybrid assembly protocol utilizing DNA self-assembly and electron-beam lithography on transparent glass substrates, we here demonstrate a DNA origami microarray, which is compatible with the requirements of single molecule fluorescence and super-resolution microscopy. The spatial arrangement allows for a simple and reliable identification of single molecule events and facilitates automated read-out and data analysis. As a specific application, we utilize the microarray to characterize the performance of DNA strand displacement reactions localized on the DNA origami structures. We find considerable variability within the array, which results both from structural variations and stochastic reaction dynamics prevalent at the single molecule level.

Published

2014

7. Self-Assembled Active Plasmonic Waveguide with a Peptide-Based Thermomechanical Switch

Author

Friedrich C. Simmel, Kilian Vogele, Günther Pardatscher, Jonathan List, Nolan B. Holland, and Tobias Pirzer

Subjects

Fabrication, Materials science, business.industry, General Engineering, Physics::Optics, General Physics and Astronomy, Nanoparticle, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Waveguide (optics), 0104 chemical sciences, Förster resonance energy transfer, DNA nanotechnology, Transmittance, Optoelectronics, General Materials Science, 0210 nano-technology, business, Lithography, Plasmon

Abstract

Nanoscale plasmonic waveguides composed of metallic nanoparticles are capable of guiding electromagnetic energy below the optical diffraction limit. Signal feed-in and readout typically require the utilization of electronic effects or near-field optical techniques, whereas for their fabrication mainly lithographic methods are employed. Here we developed a switchable plasmonic waveguide assembled from gold nanoparticles (AuNPs) on a DNA origami structure that facilitates a simple spectroscopic excitation and readout. The waveguide is specifically excited at one end by a fluorescent dye, and energy transfer is detected at the other end via the fluorescence of a second dye. The transfer distance is beyond the multicolor FRET range and below the Abbé limit. The transmittance of the waveguide can also be reversibly switched by changing the position of a AuNP within the waveguide, which is tethered to the origami platform by a thermoresponsive peptide. High-yield fabrication of the plasmonic waveguides in bulk was achieved using silica particles as solid supports. Our findings enable bulk solution applications for plasmonic waveguides as light-focusing and light-polarizing elements below the diffraction limit.

Published

2016

8. Long-range movement of large mechanically interlocked DNA nanostructures

Author

Enzo Kopperger, Elisabeth Falgenhauer, Jonathan List, Friedrich C. Simmel, and Günther Pardatscher

Subjects

Rotaxane, Materials science, Rotaxanes, Science, Catenane, Supramolecular chemistry, General Physics and Astronomy, Metal Nanoparticles, Nanotechnology, 02 engineering and technology, 010402 general chemistry, Microscopy, Atomic Force, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Fluorescence, Article, Motion, DNA origami, Multidisciplinary, fungi, food and beverages, General Chemistry, DNA, 021001 nanoscience & nanotechnology, Mechanically interlocked molecular architectures, Molecular machine, ddc, 0104 chemical sciences, Nanostructures, Mechanism (engineering), Axle, Gold, 0210 nano-technology

Abstract

Interlocked molecules such as catenanes and rotaxanes, connected only via mechanical bonds have the ability to perform large-scale sliding and rotational movements, making them attractive components for the construction of artificial molecular machines and motors. We here demonstrate the realization of large, rigid rotaxane structures composed of DNA origami subunits. The structures can be easily modified to carry a molecular cargo or nanoparticles. By using multiple axle modules, rotaxane constructs are realized with axle lengths of up to 355 nm and a fuel/anti-fuel mechanism is employed to switch the rotaxanes between a mobile and a fixed state. We also create extended pseudo-rotaxanes, in which origami rings can slide along supramolecular DNA filaments over several hundreds of nanometres. The rings can be actively moved and tracked using atomic force microscopy., Rotaxanes are interlocked molecules that can undergo sliding and rotational movements and can be used in artificial molecular machines and motors. Here, Simmel and co-workers show a rigid rotaxane structures consisting of DNA origami subunits that can slide over several hundreds of nanometres.

Published

2016

9. DNA-based Self-Assembly of Chiral Plasmonic Nanostructures with Tailored Optical Response

Author

Friedrich C. Simmel, Alexander Högele, Anton Kuzyk, Alexander O. Govorov, Eva-Maria Roller, Zhiyuan Fan, Tim Liedl, Robert D. Schreiber, and Günther Pardatscher

Subjects

Circular dichroism, Materials science, Optical Phenomena, ta221, Physics::Optics, Nanoparticle, Metal Nanoparticles, Plamonics, FOS: Physical sciences, Nanotechnology, Condensed Matter - Soft Condensed Matter, Microscopy, Electron, Transmission, DNA nanotechnology, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), DNA origami, Physics - Biological Physics, Optical rotatory dispersion, Plasmon, ta218, Condensed Matter - Materials Science, Multidisciplinary, ta214, Condensed Matter - Mesoscale and Nanoscale Physics, ta114, business.industry, Circular Dichroism, Surface plasmon, Materials Science (cond-mat.mtrl-sci), DNA, Self-assembly, Optical phenomena, Biological Physics (physics.bio-ph), Optoelectronics, Soft Condensed Matter (cond-mat.soft), Gold, business, Physics - Optics, Optics (physics.optics)

Abstract

Surface plasmon resonances generated in metallic nanostructures can be utilized to tailor electromagnetic fields. The precise spatial arrangement of such structures can result in surprising optical properties that are not found in any naturally occurring material. Here, the designed activity emerges from collective effects of singular components equipped with limited individual functionality. Top-down fabrication of plasmonic materials with a predesigned optical response in the visible range by conventional lithographic methods has remained challenging due to their limited resolution, the complexity of scaling, and the difficulty to extend these techniques to three-dimensional architectures. Molecular self-assembly provides an alternative route to create such materials which is not bound by the above limitations. We demonstrate how the DNA origami method can be used to produce plasmonic materials with a tailored optical response at visible wavelengths. Harnessing the assembly power of 3D DNA origami, we arranged metal nanoparticles with a spatial accuracy of 2 nm into nanoscale helices. The helical structures assemble in solution in a massively parallel fashion and with near quantitative yields. As a designed optical response, we generated giant circular dichroism and optical rotary dispersion in the visible range that originates from the collective plasmon-plasmon interactions within the nanohelices. We also show that the optical response can be tuned through the visible spectrum by changing the composition of the metal nanoparticles. The observed effects are independent of the direction of the incident light and can be switched by design between left- and right-handed orientation. Our work demonstrates the production of complex bulk materials from precisely designed nanoscopic assemblies and highlights the potential of DNA self-assembly for the fabrication of plasmonic nanostructures., Comment: 5 pages, 4 figures

Published

2011

10. 144 Sculpting light with DNA origami

Author

Günther Pardatscher, Robert D. Schreiber, Alexander Högele, Friedrich C. Simmel, Zhiyuan Fan, Alexander O. Govorov, Tim Liedl, Eva-Maria Roller, and Anton Kuzyk

Subjects

Plasmonic nanoparticles, Materials science, Nanostructure, Structural Biology, Oligonucleotide, Particle, Nanoparticle, DNA origami, Nanotechnology, General Medicine, Molecular Biology, Nanoscopic scale, Plasmon

Abstract

We used the DNA origami method (Rothemund, 2006) for the fabrication of self-assembled nanoscopic materials (Seeman, 2010). In DNA origami, a virus-based 8 kilobase-long DNA single-strand is folded into shape with the help of ∼ 200 synthetic oligonucleotides. The resulting DNA nanostructures can be designed to adopt any three-dimensional shape and can be addressed through DNA hybridization or chemical modification with nanometer precision. We have realized that complex assemblies of nanoparticles, including magnetic, fluorescent, and plasmonic nanoparticles. Such nanoconstructs may exhibit striking optical properties such as strong optical activity in the visible range (Kuzyk et al., 2012). To this end, plasmonic particles were assembled in solution to form helices of controlled handedness. We achieved spatial control over particle placement better than 2 nm and attachment yields of 97% and above. As a collective optical response emerging from our dispersed nanostructures, we detected pronounced circular ...

Published

2013

11. DNA origami-based nanoribbons: assembly, length distribution, and twist

Author

Anton Kuzyk, Friedrich C. Simmel, Carlos E. Castro, Max Scheible, Ralf Jungmann, and Günther Pardatscher

Subjects

Fabrication, Materials science, Nanotubes, Carbon, Oligonucleotide, Mechanical Engineering, Intermolecular force, Bioengineering, Nanotechnology, DNA, General Chemistry, Microscopy, Atomic Force, Polymerization, Biopolymers, Mechanics of Materials, Helix, Nucleic Acid Conformation, DNA origami, General Materials Science, Length distribution, Electrical and Electronic Engineering, Twist

Abstract

A variety of polymerization methods for the assembly of elongated nanoribbons from rectangular DNA origami structures are investigated. The most efficient method utilizes single-stranded DNA oligonucleotides to bridge an intermolecular scaffold seam between origami monomers. This approach allows the fabrication of origami ribbons with lengths of several micrometers, which can be used for long-range ordered arrangement of proteins. It is quantitatively shown that the length distribution of origami ribbons obtained with this technique follows the theoretical prediction for a simple linear polymerization reaction. The design of flat single layer origami structures with constant crossover spacing inevitably results in local underwinding of the DNA helix, which leads to a global twist of the origami structures that also translates to the nanoribbons.

Published

2011