Your search keyword '"Martin Berg Klenow"' showing total 10 results

1. Timescale of hole closure during plasma membrane repair estimated by calcium imaging and numerical modeling

Author

Martin Berg Klenow, Anne Sofie Busk Heitmann, Jesper Nylandsted, and Adam Cohen Simonsen

Subjects

Medicine, Science

Abstract

Abstract Plasma membrane repair is essential for eukaryotic cell life and is triggered by the influx of calcium through membrane wounds. Repair consists of sequential steps, with closure of the membrane hole being the key event that allows the cell to recover, thus identifying the kinetics of hole closure as important for clarifying repair mechanisms and as a quantitative handle on repair efficiency. We implement calcium imaging in MCF7 breast carcinoma cells subject to laser damage, coupled with a model describing the spatio-temporal calcium distribution. The model identifies the time point of hole closure as the time of maximum calcium signal. Analysis of cell data estimates the closure time as: $$\langle t_c \rangle =5.45\pm 2.25$$ ⟨ t c ⟩ = 5.45 ± 2.25 s and $$\langle t_c \rangle =6.81\pm 4.69$$ ⟨ t c ⟩ = 6.81 ± 4.69 s using GCaMP6s-CAAX and GCaMP6s probes respectively. The timescale was confirmed by independent time-lapse imaging of a hole during sealing. Moreover, the analysis estimates the characteristic time scale of calcium removal, the penetration depth of the calcium wave and the diffusion coefficient. Probing of hole closure times emerges as a strong universal tool for quantification of plasma membrane repair

Published

2021

2. Interdisciplinary Synergy to Reveal Mechanisms of Annexin-Mediated Plasma Membrane Shaping and Repair

Author

Poul Martin Bendix, Adam Cohen Simonsen, Christoffer D. Florentsen, Swantje Christin Häger, Anna Mularski, Ali Asghar Hakami Zanjani, Guillermo Moreno-Pescador, Martin Berg Klenow, Stine Lauritzen Sønder, Helena M. Danielsen, Mohammad Reza Arastoo, Anne Sofie Heitmann, Mayank Prakash Pandey, Frederik Wendelboe Lund, Catarina Dias, Himanshu Khandelia, and Jesper Nylandsted

Subjects

annexin, plasma membrane repair, membrane curvature, membrane curvature sensing, membrane shaping, interdisciplinary research, Cytology, QH573-671

Abstract

The plasma membrane surrounds every single cell and essentially shapes cell life by separating the interior from the external environment. Thus, maintenance of cell membrane integrity is essential to prevent death caused by disruption of the plasma membrane. To counteract plasma membrane injuries, eukaryotic cells have developed efficient repair tools that depend on Ca2+- and phospholipid-binding annexin proteins. Upon membrane damage, annexin family members are activated by a Ca2+ influx, enabling them to quickly bind at the damaged membrane and facilitate wound healing. Our recent studies, based on interdisciplinary research synergy across molecular cell biology, experimental membrane physics, and computational simulations show that annexins have additional biophysical functions in the repair response besides enabling membrane fusion. Annexins possess different membrane-shaping properties, allowing for a tailored response that involves rapid bending, constriction, and fusion of membrane edges for resealing. Moreover, some annexins have high affinity for highly curved membranes that appear at free edges near rupture sites, a property that might accelerate their recruitment for rapid repair. Here, we discuss the mechanisms of annexin-mediated membrane shaping and curvature sensing in the light of our interdisciplinary approach to study plasma membrane repair.

Published

2020

3. Human myelin protein P2: From crystallography to time-lapse membrane imaging and neuropathy-associated variants

Author

Matthew P. Blakeley, Adam Cohen Simonsen, Saara Laulumaa, Petri Kursula, Salla Ruskamo, Martin Berg Klenow, and M. Uusitalo

Subjects

Circular dichroism, Protein Folding, Protein Conformation, Charcot–Marie–Tooth disease, Molecular Dynamics Simulation, Crystallography, X-Ray, Myelin P2 Protein, Biochemistry, Time-Lapse Imaging, Fatty acid-binding protein, Myelin, Protein structure, Charcot-Marie-Tooth Disease, Fatty acid binding, medicine, lipid binding, Humans, fatty acid-binding protein, ddc:610, Amino Acid Sequence, protein structure, Lipid bilayer, Molecular Biology, Myelin Sheath, Sequence Homology, Amino Acid, Chemistry, Protein Stability, Vesicle, Circular Dichroism, Cell Membrane, Temperature, Cell Biology, PMP2, Crystallography, medicine.anatomical_structure, Microscopy, Fluorescence, Mutation, fatty acidbinding protein, mutation, myelin protein P2

Abstract

The FEBS journal 288(23), 6716 - 6735 (2021). doi:10.1111/febs.16079, Peripheral myelin protein 2 (P2) is a fatty acid-binding protein expressed in vertebrate peripheral nervous system myelin, as well as in human astrocytes. Suggested functions of P2 include membrane stacking and lipid transport. Mutations in the PMP2 gene, encoding P2, are associated with Charcot���Marie���Tooth disease (CMT). Recent studies have revealed three novel PMP2 mutations in CMT patients. To shed light on the structure and function of these P2 variants, we used X-ray and neutron crystallography, small-angle X-ray scattering, circular dichroism spectroscopy, computer simulations and lipid binding assays. The crystal and solution structures of the I50del, M114T and V115A variants of P2 showed minor differences to the wild-type protein, whereas their thermal stability was reduced. Vesicle aggregation assays revealed no change in membrane stacking characteristics, while the variants showed altered fatty acid binding. Time-lapse imaging of lipid bilayers indicated formation of double-membrane structures induced by P2, which could be related to its function in stacking of two myelin membrane surfaces in vivo. In order to better understand the links between structure, dynamics and function, the crystal structure of perdeuterated P2 was refined from room temperature data using neutrons and X-rays, and the results were compared to simulations and cryocooled crystal structures. Our data indicate similar properties for all known human P2 CMT variants; while crystal structures are nearly identical, thermal stability and function of CMT variants are impaired. Our data provide new insights into the structure���function relationships and dynamics of P2 in health and disease., Published by Wiley-Blackwell, Oxford [u.a.]

Published

2021

4. Phenothiazines alter plasma membrane properties and sensitize cancer cells to injury by inhibiting annexin-mediated repair

Author

Martin Berg Klenow, Jesper Nylandsted, Poul Martin Bendix, Himanshu Khandelia, Anna Mularski, Theresa Louise Boye, Stine Lauritzen Sønder, Adam Cohen Simonsen, Frederik W. Lund, Ali Asghar Hakami Zanjani, Catarina Dias, and Anne Sofie Busk Heitmann

Subjects

Programmed cell death, plasma membrane repair, Annexins, Phosphatidylserines, Molecular Dynamics Simulation, PE, phosphatidylethanolamine, Biochemistry, derivatives of phenothiazine, chemistry.chemical_compound, annexin, ANXA, Annexin, membrane resealing, Annexin, Phenothiazines, Cell Line, Tumor, Neoplasms, Humans, cancer, Molecular Biology, Phospholipids, high intensity focused ultrasound (HIFU), Phosphatidylethanolamine, annexin inhibitor, trifluoperazine (TFP), Cell Membrane, Plasma membrane repair, Cell Biology, Phosphatidylserine, PS, phosphatidylserine, MD, molecular dynamics, Cell biology, AFM, atomic force microscopy, Membrane, chemistry, Membrane curvature, Cancer cell, membrane curvature, PM, plasma membrane, Calcium, TFP, trifluoperazine, membrane injury, Antipsychotic Agents, Research Article

Abstract

Repair of damaged plasma membrane in eukaryotic cells is largely dependent on the binding of annexin repair proteins to phospholipids. Changing the biophysical properties of the plasma membrane may provide means to compromise annexin-mediated repair and sensitize cells to injury. Since, cancer cells experience heightened membrane stress and are more dependent on efficient plasma membrane repair, inhibiting repair may provide approaches to sensitize cancer cells to plasma membrane damage and cell death. Here, we show that derivatives of phenothiazines, which have widespread use in the fields of psychiatry and allergy treatment, strongly sensitize cancer cells to mechanical-, chemical-, and heat-induced injury by inhibiting annexin-mediated plasma membrane repair. Using a combination of cell biology, biophysics, and computer simulations, we show that trifluoperazine acts by thinning the membrane bilayer, making it more fragile and prone to ruptures. Secondly, it decreases annexin binding by compromising the lateral diffusion of phosphatidylserine, inhibiting the ability of annexins to curve and shape membranes, which is essential for their function in plasma membrane repair. Our results reveal a novel avenue to target cancer cells by compromising plasma membrane repair in combination with noninvasive approaches that induce membrane injuries.

Published

2021

5. Author response for 'Human myelin protein P2: From crystallography to time-lapse membrane imaging and neuropathy-associated variants'

Author

Matthew P. Blakeley, Petri Kursula, Saara Laulumaa, Adam Cohen Simonsen, Salla Ruskamo, Martin Berg Klenow, and M. Uusitalo

Subjects

Myelin, Membrane, medicine.anatomical_structure, Chemistry, medicine, Biophysics

Published

2021

6. Human myelin protein P2: From crystallography to time-lapse membrane imaging and neuropathy-associated variants

Author

Petri Kursula, M. Uusitalo, Saara Laulumaa, Matthew P. Blakeley, Adam Cohen Simonsen, Salla Ruskamo, and Martin Berg Klenow

Subjects

Crystallography, Circular dichroism, Myelin, Membrane, medicine.anatomical_structure, Chemistry, Fatty acid binding, medicine, Stacking, PMP2, Lipid bilayer, Lipid Transport

Abstract

Peripheral myelin protein 2 (P2) is a fatty acid-binding protein expressed in vertebrate peripheral nervous system myelin, as well as in human astrocytes. Suggested functions of P2 include membrane stacking and lipid transport. Mutations in the PMP2 gene, encoding P2, are associated with Charcot-Marie-Tooth disease (CMT). Recent studies have revealed three novel PMP2 mutations in CMT patient families. To shed light on the structure and function of the corresponding P2 variants, we used X-ray and neutron crystallography, small-angle X-ray scattering, circular dichroism spectroscopy, computer simulations, and lipid binding assays. The crystal and solution structures of the I50del, M114T, and V115A variants of P2 showed only minor differences to the wild-type protein, whereas the thermal stability of the disease variants was reduced. Lipid vesicle aggregation assays revealed no change in membrane stacking characteristics, while the variants showed slightly altered fatty acid binding. Time-lapse imaging of lipid bilayers indicated membrane blebbing induced by P2, which could be related to its function in stacking of two curved membrane surfaces in myelin in vivo. All variants caused blebbing of membranes on similar timescales. In order to better understand the links between structure, dynamics, and function, the crystal structure of perdeuterated P2 was refined from room temperature data collected using both neutrons and X-rays, and the results were compared to molecular dynamics simulations and cryocooled crystal structures. Taken together, our data indicate similar properties of all known CMT variants of human P2; while crystal structures are nearly identical, stability and function of the disease variants are impaired compared to the wild-type protein. Our data provide new insights into the structure-function relationships and dynamics of P2 in health and disease.

Published

2021

7. Timescale of hole closure during plasma membrane repair estimated by calcium imaging and numerical modeling

Author

Jesper Nylandsted, Martin Berg Klenow, Anne Sofie Busk Heitmann, and Adam Cohen Simonsen

Subjects

Data Analysis, Cell Membrane Permeability, Time Factors, Materials science, Ultraviolet Rays, Science, Biophysics, Closure (topology), chemistry.chemical_element, Calcium, Models, Biological, Signal, Article, Calcium imaging, Cell Line, Tumor, Humans, Calcium Signaling, Diffusion (business), Penetration depth, Multidisciplinary, Cell Membrane, Plasma membrane repair, Mechanics, Molecular Imaging, Membrane, Microscopy, Fluorescence, chemistry, Medicine, Systems biology

Abstract

Plasma membrane repair is essential for eukaryotic cell life and is triggered by the influx of calcium through membrane wounds. Repair consists of sequential steps, with closure of the membrane hole being the key event that allows the cell to recover, thus identifying the kinetics of hole closure as important for clarifying repair mechanisms and as a quantitative handle on repair efficiency. We implement calcium imaging in MCF7 breast carcinoma cells subject to laser damage, coupled with a model describing the spatio-temporal calcium distribution. The model identifies the time point of hole closure as the time of maximum calcium signal. Analysis of cell data estimates the closure time as: $$\langle t_c \rangle =5.45\pm 2.25$$ ⟨ t c ⟩ = 5.45 ± 2.25 s and $$\langle t_c \rangle =6.81\pm 4.69$$ ⟨ t c ⟩ = 6.81 ± 4.69 s using GCaMP6s-CAAX and GCaMP6s probes respectively. The timescale was confirmed by independent time-lapse imaging of a hole during sealing. Moreover, the analysis estimates the characteristic time scale of calcium removal, the penetration depth of the calcium wave and the diffusion coefficient. Probing of hole closure times emerges as a strong universal tool for quantification of plasma membrane repair

Published

2021

8. Membrane rolling induced by bacterial toxins

Author

Adam Cohen Simonsen, Jonas Camillus Jeppesen, and Martin Berg Klenow

Subjects

0303 health sciences, Microbial toxins, Cholera Toxin, Tubular membrane, Chemistry, Protein subunit, Cell Membrane, 02 engineering and technology, General Chemistry, Adhesion, Molecular Dynamics Simulation, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Curvature, Shiga Toxin, 03 medical and health sciences, Membrane, Membrane curvature, Biophysics, Negative curvature, 0210 nano-technology, Unilamellar Liposomes, 030304 developmental biology

Abstract

Membrane curvature effects are important in numerous cellular processes and many membrane interacting proteins induce spontaneous curvature upon membrane binding. Shiga and cholera toxins both belong to the AB 5 family of toxins and consist of a toxic A subunit and a membrane-binding pentameric B subunit. Shiga and cholera toxins induce tubular membrane invaginations in cells and GUVs due to curvature effects and the toxins are known from MD simulations to induce curvature. Membrane invaginations have been linked to uptake of the toxins into cells. As a novel model system to experimentally characterize curvature-inducing proteins, we study the morphology induced in planar membrane patches. It was previously shown that annexins induce distinct morphologies in membrane patches including membrane rolling. In this study we show that the B subunits of Shiga and cholera toxins (STxB, CTxB) both induce roll-up of cell-sized membrane patches. Rolling starts from the free membrane edges of the patch and is completed within a few seconds. We characterize the branched roll morphology and find experimental estimates for the spontaneous curvature of the toxins based on the topography of rolls. The estimates are in agreement with previous MD simulations. We quantify the dynamics of rolling as induced by the toxins and demonstrate agreement with a theoretical model of the rolling dynamics. The model solves the equation of motion for a membrane roll and includes viscous drag and adhesion to the support. The results suggest that membrane rolling may be a general phenomenon displayed by many proteins that induce negative curvature in membranes with free edges.

Published

2020

9. Interdisciplinary Synergy to Reveal Mechanisms of Annexin-Mediated Plasma Membrane Shaping and Repair

Author

Mohammad Reza Arastoo, Catarina Dias, Helena Maria D. Danielsen, Mayank Prakash Pandey, Jesper Nylandsted, Ali Asghar Hakami Zanjani, Anne Sofie Busk Heitmann, Anna Mularski, Himanshu Khandelia, Christoffer D. Florentsen, Swantje Christin Häger, Stine Lauritzen Sønder, Guillermo Moreno-Pescador, Poul Martin Bendix, Frederik W. Lund, Adam Cohen Simonsen, and Martin Berg Klenow

Subjects

0301 basic medicine, cell rupture, plasma membrane repair, Annexins, Cell, Review, 02 engineering and technology, Molecular Dynamics Simulation, Membrane Lipids, annexin, 03 medical and health sciences, Annexin, medicine, Animals, Humans, membrane shaping, lcsh:QH301-705.5, Molecular cell biology, Nanotubes, Cell Membrane, Plasma membrane repair, Lipid bilayer fusion, General Medicine, 021001 nanoscience & nanotechnology, 030104 developmental biology, Membrane, medicine.anatomical_structure, lcsh:Biology (General), membrane damage, Membrane curvature, membrane curvature, interdisciplinary research, Biophysics, membrane curvature sensing, 0210 nano-technology, Wound healing

Abstract

The plasma membrane surrounds every single cell and essentially shapes cell life by separating the interior from the external environment. Thus, maintenance of cell membrane integrity is essential to prevent death caused by disruption of the plasma membrane. To counteract plasma membrane injuries, eukaryotic cells have developed efficient repair tools that depend on Ca2+- and phospholipid-binding annexin proteins. Upon membrane damage, annexin family members are activated by a Ca2+ influx, enabling them to quickly bind at the damaged membrane and facilitate wound healing. Our recent studies, based on interdisciplinary research synergy across molecular cell biology, experimental membrane physics, and computational simulations show that annexins have additional biophysical functions in the repair response besides enabling membrane fusion. Annexins possess different membrane-shaping properties, allowing for a tailored response that involves rapid bending, constriction, and fusion of membrane edges for resealing. Moreover, some annexins have high affinity for highly curved membranes that appear at free edges near rupture sites, a property that might accelerate their recruitment for rapid repair. Here, we discuss the mechanisms of annexin-mediated membrane shaping and curvature sensing in the light of our interdisciplinary approach to study plasma membrane repair.

Published

2020

10. Kræftceller overlever ved at bøje cellemembranen

Author

Theresa Louise Boye, Martin Berg Klenow, Jesper Nylandsted, and Adam Cohen Simonsen