Your search keyword '"Pierre Stegemann"' showing total 2 results

1. DNA Origami Voltage Sensors for Transmembrane Potentials with Single-Molecule Sensitivity

Author

Sarah E. Ochmann, Barbara Saccà, Himanshu Joshi, Ulrich F. Keyser, Pierre Stegemann, Henri G. Franquelim, E. Bueber, Philip Tinnefeld, and Aleksei Aksimentiev

Subjects

Membrane potential, Neurons, Materials science, Mechanical Engineering, Bioengineering, General Chemistry, Single-molecule FRET, DNA, Condensed Matter Physics, Transmembrane protein, Membrane Potentials, chemistry.chemical_compound, Molecular dynamics, Membrane, Förster resonance energy transfer, chemistry, Biophysics, Fluorescence Resonance Energy Transfer, DNA origami, Nanotechnology, General Materials Science, A-DNA, Biologie, Fluorescent Dyes

Abstract

Signal transmission in neurons goes along with changes in the transmembrane potential. To report them, different approaches including optical voltage-sensing dyes and genetically encoded voltage indicators have evolved. Here, we present a DNA nanotechnology-based system. Using DNA origami, we incorporate and optimize different properties such as membrane targeting and voltage sensing modularly. As a sensing unit, we use a hydrophobic red dye anchored to the membrane and an anionic green dye at the DNA connecting the DNA origami and the membrane dye anchor. Voltage-induced displacement of the anionic donor unit is read out by changes of Fluorescence Resonance Energy Transfer (FRET) of single sensors attached to liposomes. They show a FRET change of ∼5% for ΔΨ=100 mV and allow adapting the potential range of highest sensitivity. Further, the working mechanism is rationalized by molecular dynamics simulations. Our approach holds potential for the application as non-genetically encoded sensors at membranes.

Published

2021

2. Tailored protein encapsulation into a DNA host using geometrically organized supramolecular interactions

Author

Michael Ehrmann, Daniel Gudnason, Lisa Gamrad, Elisa-Charlott Schöneweiß, Stephan Barcikowski, Melisa Merdanovic, Kenny Bravo-Rodriguez, Barbara Saccà, Pascal Lill, Andreas Sprengel, Victoria Birkedal, Christos Gatsogiannis, Elsa Sanchez-Garcia, Pierre Stegemann, and Mikayel Aznauryan

Subjects

Models, Molecular, 0301 basic medicine, Polymers, Science, Forschungszentren » Zentrum für Medizinische Biotechnologie (ZMB), Supramolecular chemistry, Chemie, General Physics and Astronomy, Nanotechnology, Chemistry Techniques, Synthetic, macromolecular substances, Ligands, 010402 general chemistry, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, chemistry.chemical_compound, Forschungszentren » Center for Nanointegration Duisburg-Essen (CENIDE), Molecular recognition, ddc:570, Molecule, Protein Interaction Domains and Motifs, A-DNA, Binding site, Heat-Shock Proteins, Binding Sites, Multidisciplinary, Molecular Structure, Serine Endopeptidases, Intermolecular force, DNA, General Chemistry, Molecular Imaging, 0104 chemical sciences, 030104 developmental biology, chemistry, Molecular Probes, Periplasmic Proteins, Genetic Engineering, Molecular probe, Biologie

Abstract

The self-organizational properties of DNA have been used to realize synthetic hosts for protein encapsulation. However, current strategies of DNA–protein conjugation still limit true emulation of natural host–guest systems, whose formation relies on non-covalent bonds between geometrically matching interfaces. Here we report one of the largest DNA–protein complexes of semisynthetic origin held in place exclusively by spatially defined supramolecular interactions. Our approach is based on the decoration of the inner surface of a DNA origami hollow structure with multiple ligands converging to their corresponding binding sites on the protein surface with programmable symmetry and range-of-action. Our results demonstrate specific host–guest recognition in a 1:1 stoichiometry and selectivity for the guest whose size guarantees sufficient molecular diffusion preserving short intermolecular distances. DNA nanocontainers can be thus rationally designed to trap single guest molecules in their native form, mimicking natural strategies of molecular recognition and anticipating a new method of protein caging., Current strategies for protein encapsulation in DNA vessels for controlled enzymatic catalysis or therapeutic delivery rely on formation of covalent complexes. Here, the authors design a system that mimics natural reversible non-covalent host–guest interactions between a DNA host and the protein DegP.

Published

2017