Your search keyword '"Dian Spakman"' showing total 4 results

1. Constructing arrays of nucleosome positioning sequences using Gibson Assembly for single-molecule studies

Author

Gijs J.L. Wuite, Erwin J.G. Peterman, Graeme A. King, Dian Spakman, LaserLaB - Molecular Biophysics, and Physics of Living Systems

Subjects

0301 basic medicine, Gibson assembly, Optical Tweezers, lcsh:Medicine, Sequence (biology), Computational biology, Article, Histones, 03 medical and health sciences, chemistry.chemical_compound, Histone H3, 0302 clinical medicine, Single-molecule biophysics, Nucleosome, lcsh:Science, Physics, Biophysical methods, Multidisciplinary, Microscopy, Confocal, biology, lcsh:R, DNA, Chromatin Assembly and Disassembly, Chromatin, Nucleosomes, 030104 developmental biology, Histone, chemistry, biology.protein, lcsh:Q, Linker, 030217 neurology & neurosurgery, Plasmids

Abstract

As the basic building blocks of chromatin, nucleosomes play a key role in dictating the accessibility of the eukaryotic genome. Consequently, nucleosomes are involved in essential genomic transactions such as DNA transcription, replication and repair. In order to unravel the mechanisms by which nucleosomes can influence, or be altered by, DNA-binding proteins, single-molecule techniques are increasingly employed. To this end, DNA molecules containing a defined series of nucleosome positioning sequences are often used to reconstitute arrays of nucleosomes in vitro. Here, we describe a novel method to prepare DNA molecules containing defined arrays of the ‘601’ nucleosome positioning sequence by exploiting Gibson Assembly cloning. The approaches presented here provide a more accessible and efficient means to generate arrays of nucleosome positioning motifs, and facilitate a high degree of control over the linker sequences between these motifs. Nucleosomes reconstituted on such arrays are ideal for interrogation with single-molecule techniques. To demonstrate this, we use dual-trap optical tweezers, in combination with fluorescence microscopy, to monitor nucleosome unwrapping and histone localisation as a function of tension. We reveal that, although nucleosomes unwrap at ~20 pN, histones (at least histone H3) remain bound to the DNA, even at tensions beyond 60 pN.

Published

2020

2. Cellular dynamics of the SecA ATPase at the single molecule level

Author

Antoine M. van Oijen, Anne Bart Seinen, Arnold J. M. Driessen, Dian Spakman, and Molecular Microbiology

Subjects

0301 basic medicine, Science, ATPase, Cellular imaging, environment and public health, Article, Cell membrane, 03 medical and health sciences, medicine, Molecule, SecYEG Translocon, SecA Proteins, Multidisciplinary, Escherichia coli K12, 030102 biochemistry & molecular biology, biology, Chemistry, Escherichia coli Proteins, Cell Membrane, Translocon, Molecular Imaging, Protein Transport, 030104 developmental biology, Secretory protein, Membrane, medicine.anatomical_structure, Cytoplasm, biology.protein, Biophysics, Medicine, bacteria, Protein Multimerization

Abstract

In bacteria, the SecA ATPase provides the driving force for protein secretion via the SecYEG translocon. While the dynamic interplay between SecA and SecYEG in translocation is widely appreciated, it is not clear how SecA associates with the translocon in the crowded cellular environment. We use super-resolution microscopy to directly visualize the dynamics of SecA in Escherichia coli at the single-molecule level. We find that SecA is predominantly associated with and evenly distributed along the cytoplasmic membrane as a homodimer, with only a minor cytosolic fraction. SecA moves along the cell membrane as three distinct but interconvertible diffusional populations: (1) A state loosely associated with the membrane, (2) an integral membrane form, and (3) a temporarily immobile form. Disruption of the proton-motive-force, which is essential for protein secretion, re-localizes a significant portion of SecA to the cytoplasm and results in the transient location of SecA at specific locations at the membrane. The data support a model in which SecA diffuses along the membrane surface to gain access to the SecYEG translocon.

Published

2021

3. Method for immobilization of living and synthetic cells for high-resolution imaging and single-particle tracking

Author

Bert Poolman, Dian Spakman, Christiaan M. Punter, Łukasz Syga, Enzymology, and Groningen Biomolecular Sciences and Biotechnology

Subjects

0301 basic medicine, Materials science, Surface Properties, Fluorescence Recovery After Photobleaching (FRAP), Science, Saccharomyces cerevisiae, Total Internal Reflection Fluorescence (TIRF), engineering.material, 010402 general chemistry, Tracking (particle physics), 01 natural sciences, Article, 03 medical and health sciences, Coating, Microscopy, Concanavalin A, Escherichia coli, Single Particle Tracking (SPT), Immobilized Cells, single molecule analysis, Unilamellar Liposomes, Multidisciplinary, Total internal reflection fluorescence microscope, biology, Vesicle, Resolution (electron density), Optical Imaging, Fluorescence recovery after photobleaching, super resolution imaging, synthetic cells, biology.organism_classification, 0104 chemical sciences, 030104 developmental biology, Microscopy, Fluorescence, Glutaral, engineering, Biophysics, Super-resolution Imaging, Medicine, Artificial Cells

Abstract

Super-resolution imaging and single-particle tracking require cells to be immobile as any movement reduces the resolution of the measurements. Here, we present a method based on APTES-glutaraldehyde coating of glass surfaces to immobilize cells without compromising their growth. Our method of immobilization is compatible with Saccharomyces cerevisiae, Escherichia coli, and synthetic cells (here, giant-unilamellar vesicles). The method introduces minimal background fluorescence and is suitable for imaging of single particles at high resolution. With S. cerevisiae we benchmarked the method against the commonly used concanavalin A approach. We show by total internal reflection fluorescence microscopy that modifying surfaces with ConA introduces artifacts close to the glass surface, which are not present when immobilizing with the APTES-glutaraldehyde method. We demonstrate validity of the method by measuring the diffusion of membrane proteins in yeast with single-particle tracking and of lipids in giant-unilamellar vesicles with fluorescence recovery after photobleaching. Importantly, the physical properties and shape of the fragile GUVs are not affected upon binding to APTES-glutaraldehyde coated glass. The APTES-glutaraldehyde is a generic method of immobilization that should work with any cell or synthetic system that has primary amines on the surface.

Published

2018

4. Steric exclusion and protein conformation determine the localization of plasma membrane transporters

Author

Łukasz Syga, Anne-Bart Seinen, Antoine M. van Oijen, Andrew Robinson, Paul E. Schavemaker, Bert Poolman, Dian Spakman, Christiaan M. Punter, Frans Bianchi, Gemma Moiset, Enzymology, Zernike Institute for Advanced Materials, Groningen Biomolecular Sciences and Biotechnology, and Molecular Biophysics

Subjects

0301 basic medicine, endocrine system, Saccharomyces cerevisiae Proteins, MCC/eisosomes, Protein Conformation, Cancer development and immune defence Radboud Institute for Molecular Life Sciences [Radboudumc 2], Science, Saccharomyces cerevisiae, General Physics and Astronomy, S. cerevisiae, transporters, plasma membrane, General Biochemistry, Genetics and Molecular Biology, Article, localization, high-resolution microscopy, Diffusion, 03 medical and health sciences, Protein structure, Membrane Microdomains, lcsh:Science, Integral membrane protein, Multidisciplinary, biology, Chemistry, Cell Membrane, Fluorescence recovery after photobleaching, General Chemistry, biology.organism_classification, Transport protein, Kinetics, Protein Transport, Proton-Translocating ATPases, 030104 developmental biology, Membrane, Membrane protein, Cytoplasm, MCPs, Biophysics, Amino Acid Transport Systems, Basic, lcsh:Q, Fluorescence Recovery After Photobleaching

Abstract

The plasma membrane (PM) of Saccharomyces cerevisiae contains membrane compartments, MCC/eisosomes and MCPs, named after the protein residents Can1 and Pma1, respectively. Using high-resolution fluorescence microscopy techniques we show that Can1 and the homologous transporter Lyp1 are able to diffuse into the MCC/eisosomes, where a limited number of proteins are conditionally trapped at the (outer) edge of the compartment. Upon addition of substrate, the immobilized proteins diffuse away from the MCC/eisosomes, presumably after taking a different conformation in the substrate-bound state. Our data indicate that the mobile fraction of all integral plasma membrane proteins tested shows extremely slow Brownian diffusion through most of the PM. We also show that proteins with large cytoplasmic domains, such as Pma1 and synthetic chimera of Can1 and Lyp1, are excluded from the MCC/eisosomes. We hypothesize that the distinct localization patterns found for these integral membrane proteins in S. cerevisiae arises from a combination of slow lateral diffusion, steric exclusion, and conditional trapping in membrane compartments., The yeast plasma membrane consists of membrane microdomains with distinct protein composition. Here the authors use high-resolution single molecule imaging to observe diffusion of specific transmembrane proteins in and out of these microdomains, and propose features that dictate their inclusion/exclusion from these structures.

Published

2018