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13 results on '"Eva Bertosin"'

1. A nanoscale reciprocating rotary mechanism with coordinated mobility control

Author

Eva Bertosin, Christopher M. Maffeo, Thomas Drexler, Maximilian N. Honemann, Aleksei Aksimentiev, and Hendrik Dietz

Subjects
Science
Abstract

Biological molecular motors convert chemical energy into mechanical motion by coupling catalytic reactions to large-scale structural transitions. Here, the authors report the design of a rotating DNA nanomechanism that comprises a camshaft whose rotary motion can be transformed into reciprocating large-scale transitions in the structure of the surrounding stator.

Published
2021
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2. Structure and mechanism of the two-component α-helical pore-forming toxin YaxAB

Author

Bastian Bräuning, Eva Bertosin, Florian Praetorius, Christian Ihling, Alexandra Schatt, Agnes Adler, Klaus Richter, Andrea Sinz, Hendrik Dietz, and Michael Groll

Subjects
Science
Abstract

The Yersinia YaxAB system is a pore-forming toxin of so far unknown structure. Here authors present X-ray and cryo-EM to structures of individual subunits and of the YaxAB pore complex, and find that YaxA binds to membranes first and recruits YaxB for subsequent oligomerization.

Published
2018
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3. DNA origami scaffold for studying intrinsically disordered proteins of the nuclear pore complex

Author

Philip Ketterer, Adithya N. Ananth, Diederik S. Laman Trip, Ankur Mishra, Eva Bertosin, Mahipal Ganji, Jaco van der Torre, Patrick Onck, Hendrik Dietz, and Cees Dekker

Subjects
Science
Abstract

FG-Nups are disordered proteins in the nuclear pore complex (NPC) where they selectively control nuclear transport. Here authors build NPC-mimics based on DNA origami rings which attach a certain numbers of Nups to analyse those nanopores by cryoEM and conductance measurements.

Published
2018
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4. Orientation-Locked DNA Origami for Stable Trapping of Small Proteins in the Nanopore Electro-Osmotic Trap

Author

Chenyu Wen, Eva Bertosin, Xin Shi, Cees Dekker, and Sonja Schmid

Subjects
label-free protein trapping, Biofysica, electro-osmotic flow, single-molecule detection, Mechanical Engineering, Biophysics, nanopore electro-osmotic trap (NEOtrap), General Materials Science, Bioengineering, DNA origami, General Chemistry, Condensed Matter Physics
Abstract

Nanopores are versatile single-molecule sensors offering a simple label-free readout with great sensitivity. We recently introduced the nanopore electro-osmotic trap (NEOtrap) which can trap and sense single unmodified proteins for long times. The trapping is achieved by the electro-osmotic flow (EOF) generated from a DNA-origami sphere docked onto the pore, but thermal fluctuations of the origami limited the trapping of small proteins. Here, we use site-specific cholesterol functionalization of the origami sphere to firmly link it to the lipid-coated nanopore. We can lock the origami in either a vertical or horizontal orientation which strongly modulates the EOF. The optimized EOF greatly enhances the trapping capacity, yielding reduced noise, reduced measurement heterogeneity, an increased capture rate, and 100-fold extended observation times. We demonstrate the trapping of a variety of single proteins, including small ones down to 14 kDa. The cholesterol functionalization significantly expands the application range of the NEOtrap technology.

Published
2022

5. Orientation-locked DNA origami for stable trapping of small proteins in the NEOtrap

Author

Chenyu Wen, Eva Bertosin, Xin Shi, Cees Dekker, and Sonja Schmid

Abstract

Nanopores are versatile single-molecule sensors that offer a simple label-free readout with great sensitivity. We recently introduced the Nanopore Electro-Osmotic trap (NEOtrap) which can trap and sense single unmodified proteins for long times. The trapping is achieved by the electro-osmotic flow (EOF) generated from a DNA-origami sphere docked onto the pore, but thermal fluctuations of the origami limited the trapping of small proteins. Here, we use site-specific cholesterol functionalization of the origami sphere to firmly link it to the lipid-coated nanopore. We can lock the origami in either a vertical or horizontal orientation which strongly modulates the EOF. The optimized EOF greatly enhances the trapping capacity, yielding reduced noise, reduced measurement heterogeneity, an increased capture rate, and 100-fold extended observation times. We demonstrate the trapping of a variety of single proteins, including small ones down to a molecular mass of 14 kDa. The cholesterol functionalization significantly expands the application range of the NEOtrap technology.

Published
2022

7. A DNA origami rotary ratchet motor

Author

Anna-Katharina Pumm, Wouter Engelen, Enzo Kopperger, Jonas Isensee, Matthias Vogt, Viktorija Kozina, Massimo Kube, Maximilian N. Honemann, Eva Bertosin, Martin Langecker, Ramin Golestanian, Friedrich C. Simmel, and Hendrik Dietz

Subjects
Motion, Proton-Translocating ATPases, Stochastic Processes, Multidisciplinary, Molecular Motor Proteins, Movement, Osmolar Concentration, Temperature, Thermodynamics, DNA, Hydrogen-Ion Concentration, Facilitated Diffusion
Abstract

To impart directionality to the motions of a molecular mechanism, one must overcome the random thermal forces that are ubiquitous on such small scales and in liquid solution at ambient temperature. In equilibrium without energy supply, directional motion cannot be sustained without violating the laws of thermodynamics. Under conditions away from thermodynamic equilibrium, directional motion may be achieved within the framework of Brownian ratchets, which are diffusive mechanisms that have broken inversion symmetry1–5. Ratcheting is thought to underpin the function of many natural biological motors, such as the F1F0-ATPase6–8, and it has been demonstrated experimentally in synthetic microscale systems (for example, to our knowledge, first in ref. 3) and also in artificial molecular motors created by organic chemical synthesis9–12. DNA nanotechnology13 has yielded a variety of nanoscale mechanisms, including pivots, hinges, crank sliders and rotary systems14–17, which can adopt different configurations, for example, triggered by strand-displacement reactions18,19 or by changing environmental parameters such as pH, ionic strength, temperature, external fields and by coupling their motions to those of natural motor proteins20–26. This previous work and considering low-Reynolds-number dynamics and inherent stochasticity27,28 led us to develop a nanoscale rotary motor built from DNA origami that is driven by ratcheting and whose mechanical capabilities approach those of biological motors such as F1F0-ATPase.

Published
2021

8. Tailored Peptide Phenyl Esters Block ClpXP Proteolysis by an Unusual Breakdown into a Heptamer–Hexamer Assembly

Author

Ralf Strasser, Friederike M. Möller, Dóra Balogh, Stephan A. Sieber, Hendrik Dietz, Eva Bertosin, and Markus Lakemeyer

Subjects
Staphylococcus aureus, Serine Proteinase Inhibitors, Protein Conformation, Proteolysis, Peptide, Random hexamer, 010402 general chemistry, 01 natural sciences, Catalysis, Structure-Activity Relationship, Bacterial Proteins, medicine, chemistry.chemical_classification, medicine.diagnostic_test, 010405 organic chemistry, Esters, Stereoisomerism, Endopeptidase Clp, General Chemistry, 0104 chemical sciences, Amino acid, Enzyme, Catalytic cycle, chemistry, Biophysics, Protein Multimerization, Peptides, Molecular probe
Abstract

The proteolytic complex ClpXP is fundamental to bacterial homeostasis and pathogenesis. Because of its conformational flexibility, the development of potent ClpXP inhibitors is challenging, and novel tools to decipher its intricate regulation are urgently needed. Herein, we present amino acid based phenyl esters as molecular probes to study the activity and oligomerization of the ClpXP complex of S. aureus. Systematic screening of (R)- and (S)-amino acids led to compounds showing potent inhibition, as well as stimulation of ClpXP-mediated proteolysis. Substoichiometric binding of probes arrested ClpXP in an unprecedented heptamer-hexamer assembly, in which the two heptameric ClpP rings are dissociated from each other. At the same time, the affinity between ClpX and ClpP increased, leading to inhibition of both enzymes. This conformational arrest is beneficial for the consolidated shutdown of ClpXP, as well as for the study of the oligomeric state during its catalytic cycle.

Published
2019

10. Cryo-Electron Microscopy and Mass Analysis of Oligolysine-Coated DNA Nanostructures

Author

Hendrik Dietz, Elija Feigl, Maximilian N. Honemann, Pierre Stömmer, Maximilian Wenig, and Eva Bertosin

Subjects
Materials science, Cryo-electron microscopy, Stacking, General Physics and Astronomy, 02 engineering and technology, engineering.material, 010402 general chemistry, 01 natural sciences, PEG-oligolysine, Article, pseudoatomic model fitting, Coating, DNA nanotechnology, Microscopy, mass photometry, DNA origami, Nanotechnology, General Materials Science, Composite material, Cryoelectron Microscopy, General Engineering, DNA, self-assembly, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Nanostructures, Ionic strength, engineering, Nucleic Acid Conformation, cryo-EM, Self-assembly, 0210 nano-technology
Abstract

Cationic coatings can enhance the stability of synthetic DNA objects in low ionic strength environments such as physiological fluids. Here, we used single-particle cryo-electron microscopy (cryo-EM), pseudoatomic model fitting, and single-molecule mass photometry to study oligolysine and polyethylene glycol (PEG)-oligolysine-coated multilayer DNA origami objects. The coatings preserve coarse structural features well on a resolution of multiple nanometers but can also induce deformations such as twisting and bending. Higher-density coatings also led to internal structural deformations in the DNA origami test objects, in which a designed honeycomb-type helical lattice was deformed into a more square-lattice-like pattern. Under physiological ionic strength, where the uncoated objects disassembled, the coated objects remained intact but they shrunk in the helical direction and expanded in the direction perpendicular to the helical axis. Helical details like major/minor grooves and crossover locations were not discernible in cryo-EM maps that we determined of DNA origami coated with oligolysine and PEG-oligolysine, whereas these features were visible in cryo-EM maps determined from the uncoated reference objects. Blunt-ended double-helical interfaces remained accessible underneath the coating and may be used for the formation of multimeric DNA origami assemblies that rely on stacking interactions between blunt-ended helices. The ionic strength requirements for forming multimers from coated DNA origami differed from those needed for uncoated objects. Using single-molecule mass photometry, we found that the mass of coated DNA origami objects prior to and after incubation in low ionic strength physiological conditions remained unchanged. This finding indicated that the coating effectively prevented strand dissociation but also that the coating itself remained stable in place. Our results validate oligolysine coatings as a powerful stabilization method for DNA origami but also reveal several potential points of failure that experimenters should watch to avoid working with false premises.

Published
2021

11. DNA origami scaffold for studying intrinsically disordered proteins of the nuclear pore complex

Author

Adithya N. Ananth, Cees Dekker, Mahipal Ganji, Philip Ketterer, Diederik S. Laman Trip, Hendrik Dietz, Ankur Mishra, Patrick Onck, Jaco van der Torre, Eva Bertosin, and Micromechanics

Subjects
0301 basic medicine, MECHANISM, Nanostructure, Science, viruses, Mutant, General Physics and Astronomy, Molecular Dynamics Simulation, Intrinsically disordered proteins, FOLDING DNA, NANOSTRUCTURES, Article, General Biochemistry, Genetics and Molecular Biology, Nanopores, 03 medical and health sciences, Molecular dynamics, ACCESS RESISTANCE, otorhinolaryngologic diseases, Journal Article, DNA origami, PERMEABILITY, Nuclear pore, lcsh:Science, Ions, SOLID-STATE NANOPORES, ARCHITECTURE, Multidisciplinary, Chemistry, SELECTIVE TRANSPORT, Gatekeepers, virus diseases, DNA, General Chemistry, ddc, Intrinsically Disordered Proteins, Nanopore, stomatognathic diseases, 030104 developmental biology, Nuclear Pore, Biophysics, Nucleic Acid Conformation, lcsh:Q, Nuclear transport, NANOSCALE SHAPES
Abstract

The nuclear pore complex (NPC) is the gatekeeper for nuclear transport in eukaryotic cells. A key component of the NPC is the central shaft lined with intrinsically disordered proteins (IDPs) known as FG-Nups, which control the selective molecular traffic. Here, we present an approach to realize artificial NPC mimics that allows controlling the type and copy number of FG-Nups. We constructed 34 nm-wide 3D DNA origami rings and attached different numbers of NSP1, a model yeast FG-Nup, or NSP1-S, a hydrophilic mutant. Using (cryo) electron microscopy, we find that NSP1 forms denser cohesive networks inside the ring compared to NSP1-S. Consistent with this, the measured ionic conductance is lower for NSP1 than for NSP1-S. Molecular dynamics simulations reveal spatially varying protein densities and conductances in good agreement with the experiments. Our technique provides an experimental platform for deciphering the collective behavior of IDPs with full control of their type and position., FG-Nups are disordered proteins in the nuclear pore complex (NPC) where they selectively control nuclear transport. Here authors build NPC-mimics based on DNA origami rings which attach a certain numbers of Nups to analyse those nanopores by cryoEM and conductance measurements.

Published
2018
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12. Structure and mechanism of the two-component α-helical pore-forming toxin YaxAB

Author

Florian Praetorius, Hendrik Dietz, Alexandra Schatt, Michael Groll, Christian Ihling, Andrea Sinz, Bastian Bräuning, Klaus Richter, Eva Bertosin, and Agnes Adler

Subjects
0301 basic medicine, Models, Molecular, Pore Forming Cytotoxic Proteins, Protein Conformation, alpha-Helical, Yersinia Infections, Science, Bacterial Toxins, General Physics and Astronomy, Virulence, Yersinia, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, 0302 clinical medicine, Protein structure, Animals, Humans, lcsh:Science, Pore-forming toxin, Multidisciplinary, biology, Chemistry, Cryoelectron Microscopy, General Chemistry, biology.organism_classification, ddc, Transmembrane domain, 030104 developmental biology, Membrane, Lytic cycle, Membrane protein, Multiprotein Complexes, Biophysics, lcsh:Q, Protein Multimerization, 030217 neurology & neurosurgery
Abstract

Pore-forming toxins (PFT) are virulence factors that transform from soluble to membrane-bound states. The Yersinia YaxAB system represents a family of binary α-PFTs with orthologues in human, insect, and plant pathogens, with unknown structures. YaxAB was shown to be cytotoxic and likely involved in pathogenesis, though the molecular basis for its two-component lytic mechanism remains elusive. Here, we present crystal structures of YaxA and YaxB, together with a cryo-electron microscopy map of the YaxAB complex. Our structures reveal a pore predominantly composed of decamers of YaxA–YaxB heterodimers. Both subunits bear membrane-active moieties, but only YaxA is capable of binding to membranes by itself. YaxB can subsequently be recruited to membrane-associated YaxA and induced to present its lytic transmembrane helices. Pore formation can progress by further oligomerization of YaxA–YaxB dimers. Our results allow for a comparison between pore assemblies belonging to the wider ClyA-like family of α-PFTs, highlighting diverse pore architectures., The Yersinia YaxAB system is a pore-forming toxin of so far unknown structure. Here authors present X-ray and cryo-EM to structures of individual subunits and of the YaxAB pore complex, and find that YaxA binds to membranes first and recruits YaxB for subsequent oligomerization.

Published
2017

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