Your search keyword '"Ulrich Rant"' showing total 3 results

1. Electrical Actuation of a DNA Origami Nanolever on an Electrode

Author

Wolfgang Kaiser, Michael Mertig, Ulrich Rant, Felix Kroener, and Andreas Heerwig

Subjects

business.product_category, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Biochemistry, Catalysis, Colloid and Surface Chemistry, Electricity, Electric field, DNA origami, Electronics, Electrodes, Lever, Chemistry, Response time, General Chemistry, DNA, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Nanostructures, Interfacing, Electrode, 0210 nano-technology, business, Voltage

Abstract

Development of electrically powered DNA origami nanomachines requires effective means to actuate moving origami parts by externally applied electric fields. We demonstrate how origami nanolevers on an electrode can be manipulated (switched) at high frequency by alternating voltages. Orientation switching is long-time stable and can be induced by applying low voltages of 200 mV. The mechanical response time of a 100 nm long origami lever to an applied voltage step is less than 100 μs, allowing dynamic control of the induced motion. Moreover, through voltage assisted capture, origamis can be immobilized from folding solution without purification, even in the presence of excess staple strands. The results establish a way for interfacing and controlling DNA origamis with standard electronics, and enable their use as moving parts in electro-mechanical nanodevices.

Published

2017

2. Quantitation of Affinity, Avidity, and Binding Kinetics of Protein Analytes with a Dynamically Switchable Biosurface

Author

Jelena Knezevic, Ralf Strasser, Ulrich Rant, Paul A. Hampel, Wolfgang Kaiser, and Andreas Langer

Subjects

Analyte, Chromatography, Surface Properties, Chemistry, Proteins, General Chemistry, Ligands, Biochemistry, Fluorescence, Catalysis, Receptor–ligand kinetics, Orders of magnitude (mass), Dissociation constant, Kinetics, Colloid and Surface Chemistry, Reaction rate constant, Biophysics, Avidity, Binding site, Protein Binding

Abstract

A label-free method for the analysis of interactions of proteins with surface-tethered ligands is introduced. Short DNA levers are electrically actuated on microelectrodes by ac potentials, and their switching dynamics are measured in real-time by fluorescence energy transfer. Binding of proteins to ligands attached to the top of the DNA levers is detected by time-resolved measurements of the levers' dynamic motion. We demonstrate the quantitation of binding kinetics (k(on), k(off) rate constants), dissociation constants (K(D) in the pM regime), and the influence of competitive binders (EC(50) values). Moreover, the "switchSENSE" method reveals avidity effects and allows discriminating between analytes with one or more binding sites. In a comparative study, interactions of six hexa-histidine-tagged proteins with tris-nitrilotriacetic acid (NTA(3)) ligands are quantitated. Their binding kinetics and affinities are found to vary over up to 2 orders of magnitude, evidencing that the proteins' individual chemical environments significantly influence the His(6)-NTA(3) interaction.

Published

2012

3. Conformations of end-tethered DNA molecules on gold surfaces: influences of applied electric potential, electrolyte screening, and temperature

Author

Wolfgang Kaiser and Ulrich Rant

Subjects

Models, Molecular, Surface Properties, Static Electricity, Analytical chemistry, DNA, Single-Stranded, Electrolyte, Sodium Chloride, Nucleic Acid Denaturation, Biochemistry, Catalysis, Electrolytes, Colloid and Surface Chemistry, Electricity, Electric field, Molecule, Transition Temperature, Base Sequence, Oligonucleotide, Chemistry, Temperature, General Chemistry, DNA, Ionic strength, Electrode, Nucleic Acid Conformation, Electric potential, Gold, Electrode potential

Abstract

We describe the behavior of 72mer oligonucleotides that are end-tethered to gold surfaces under the influence of applied electric fields. The DNA extension is measured by fluorescence energy transfer as a function of the DNA hybridization state (single- and double-stranded), the concentration of monovalent salt in solution (100 microM to 1 M NaCl), the applied electrode potential (-0.6 to +0.1 V vs Pt), and the temperature (1 to 50 degrees C). At high ionic strength, the DNA conformations are very robust and independent of the applied electrode potential and temperature variations. In solutions of medium ionic strength, the DNA conformation can be manipulated efficiently by applying bias potentials to the Au electrodes. The molecules are repelled at negative potentials and attracted to the surface at positive potentials. The conformation transition occurs abruptly when the electrode bias is swept by merely 0.1 V across the transition potential, which shifts negatively when the salinity is decreased. The behavior can be understood by electrostatic screening arguments and, in the case of single-stranded DNA, when secondary structures are taken into account. At low ionic strength, the experiments reveal an intriguing temperature-dependent stiffening of single-stranded DNA, which can be rationalized by combining counterion condensation theory with the Odjik-Skolnick-Fixman description of the electrostatic persistence length and the unstacking of bases at elevated temperatures.

Published

2010