Your search keyword '"Anna E C, Meijering"' showing total 5 results

1. Implementation of 3D Multi-Color Fluorescence Microscopy in a Quadruple Trap Optical Tweezers System

Author

Anna E C, Meijering, Julia A M, Bakx, Tianlong, Man, Iddo, Heller, Gijs J L, Wuite, and Erwin J G, Peterman

Subjects

Microscopy, Fluorescence, Optical Tweezers, Nanotechnology, Optical Devices, DNA

Abstract

Recent advances in the design and measurement capabilities of optical tweezers instruments, and especially the combination with multi-color fluorescence detection, have accommodated a dramatic increase in the versatility of optical trapping. Quadruple (Q)-trap optical tweezers are an excellent example of such an advance, by providing three-dimensional control over two constructs and thereby enabling for example DNA-DNA braiding. However, the implementation of fluorescence detection in such a Q-trapping system poses several challenges: (1) since typical samples span a distance in the order of tens of micrometers, it requires imaging of a large field of view, (2) in order to capture fast molecular dynamics, fast imaging with single-molecule sensitivity is desired, (3) in order to study three-dimensional objects, it could be needed to detect emission light at different axial heights while keeping the objective lens and thus the optically trapped microspheres in a fixed position. In this chapter, we describe design guidelines for a fluorescence imaging module on a Q-trap system that overcomes these challenges and provide a step-by-step description for construction and alignment of such a system. Finally, we present detailed instructions for proof-of-concept experiments that can be used to validate and highlight the capabilities of the instruments.

Published

2022

2. Nonlinear mechanics of human mitotic chromosomes

Author

Anna E C, Meijering, Kata, Sarlós, Christian F, Nielsen, Hannes, Witt, Janni, Harju, Emma, Kerklingh, Guus H, Haasnoot, Anna H, Bizard, Iddo, Heller, Chase P, Broedersz, Ying, Liu, Erwin J G, Peterman, Ian D, Hickson, and Gijs J L, Wuite

Subjects

Optics and Photonics, DNA Topoisomerases, Type II, Chromosomes, Human, Humans, Mitosis, DNA, Chromosomes

Abstract

In preparation for mitotic cell division, the nuclear DNA of human cells is compacted into individualized, X-shaped chromosomes

Published

2021

3. Imaging unlabeled proteins on DNA with super-resolution

Author

Ineke Brouwer, Anna E. C. Meijering, Andreas S. Biebricher, Gijs J.L. Wuite, Iddo Heller, Erwin J.G. Peterman, Gerrit Sitters, Physics of Living Systems, and LaserLaB - Molecular Biophysics

Subjects

AcademicSubjects/SCI00010, Inverse, 02 engineering and technology, Biology, Narese/16, 03 medical and health sciences, chemistry.chemical_compound, Imaging, Three-Dimensional, Microscopy, Genetics, Fluorescence microscope, Medical imaging, Humans, Computer Simulation, 030304 developmental biology, 0303 health sciences, DNA, 021001 nanoscience & nanotechnology, Photobleaching, Superresolution, DNA-Binding Proteins, Microscopy, Fluorescence, chemistry, Temporal resolution, Methods Online, 0210 nano-technology, Biological system, Monte Carlo Method, Protein Binding

Abstract

Fluorescence microscopy is invaluable to a range of biomolecular analysis approaches. The required labeling of proteins of interest, however, can be challenging and potentially perturb biomolecular functionality as well as cause imaging artefacts and photo bleaching issues. Here, we introduce inverse (super-resolution) imaging of unlabeled proteins bound to DNA. In this new method, we use DNA-binding fluorophores that transiently label bare DNA but not protein-bound DNA. In addition to demonstrating diffraction-limited inverse imaging, we show that inverse Binding-Activated Localization Microscopy or ‘iBALM’ can resolve biomolecular features smaller than the diffraction limit. The current detection limit is estimated to lie at features between 5 and 15 nm in size. Although the current image-acquisition times preclude super-resolving fast dynamics, we show that diffraction-limited inverse imaging can reveal molecular mobility at ∼0.2 s temporal resolution and that the method works both with DNA-intercalating and non-intercalating dyes. Our experiments show that such inverse imaging approaches are valuable additions to the single-molecule toolkit that relieve potential limitations posed by labeling.

Published

2020

4. Super-Resolution Imaging of Unlabeled Proteins on DNA

Author

Iddo Heller, Erwin J.G. Peterman, Anna E. C. Meijering, Andreas S. Biebricher, Gijs J.L. Wuite, Physics of Living Systems, LaserLaB - Molecular Biophysics, and Physics and Astronomy

Subjects

Molecular interactions, chemistry.chemical_compound, chemistry, Proof of concept, Temporal resolution, Microscopy, Biophysics, Nanotechnology, Biology, Biological system, Superresolution, DNA, Visualization

Abstract

Direct visualization of DNA-protein interactions at the single-molecule level is of ever increasing importance to unravel the salient details of a wide range of DNA-associated processes. Recent emergence of super-resolution imaging has the potential to further boost the impact of such investigations. However, current imaging methods heavily rely on (fluorescent) labeling strategies, which can be challenging and potentially even interfere with the molecular interactions under scrutiny. Here, we introduce a new label-free method to image the presence and location of DNA-bound proteins with super-resolution on optically manipulated DNA. The method is based on localization microscopy of DNA-intercalating dyes that locally bind to bare DNA but not to protein-bound DNA sections, yielding an inverted image that reveals the ‘shadows’ of the proteins on the DNA: inverse binding-activated localization microscopy (iBALM). We present the proof of principle of iBALM as well as of functional variations to this method and provide experimental and theoretical data that describe the spatial and temporal resolution that can be obtained. iBALM has the potential to become a valuable addition to the single-molecule toolkit and enable direct visualization of processes that were previously not possible due to limitations posed by labeling.

Published

2017

5. DNA-Tile Structures Induce Ionic Currents through Lipid Membranes

Author

Kerstin Göpfrich, Ulrich F. Keyser, Thomas Zettl, Samet Kocabey, Anna E. C. Meijering, Tim Liedl, and Silvia Hernández-Ainsa

Subjects

Materials science, Membrane lipids, Lipid Bilayers, Bioengineering, Nanotechnology, 02 engineering and technology, Gating, Biosensing Techniques, 010402 general chemistry, 01 natural sciences, Membrane Lipids, DNA nanotechnology, General Materials Science, Lipid bilayer, Ion channel, Transmembrane channels, Mechanical Engineering, General Chemistry, DNA, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 0104 chemical sciences, Nanostructures, Membrane, Biophysics, Nucleic Acid Conformation, Self-assembly, 0210 nano-technology

Abstract

Self-assembled DNA nanostructures have been used to create man-made transmembrane channels in lipid bilayers. Here, we present a DNA-tile structure with a nominal subnanometer channel and cholesterol-tags for membrane anchoring. With an outer diameter of 5 nm and a molecular weight of 45 kDa, the dimensions of our synthetic nanostructure are comparable to biological ion channels. Because of its simple design, the structure self-assembles within a minute, making its creation scalable for applications in biology. Ionic current recordings demonstrate that the tile structures enable ion conduction through lipid bilayers and show gating and voltage-switching behavior. By demonstrating the design of DNA-based membrane channels with openings much smaller than that of the archetypical six-helix bundle, our work showcases their versatility inspired by the rich diversity of natural membrane components.

Published

2015