Your search keyword '"Koenderink, Gijsje H."' showing total 10 results

1. Elucidating the role of water in collagen self-assembly by isotopically modulating collagen hydration.

Author

Giubertoni, Giulia, Liru Feng, Klein, Kevin, Giannetti, Guido, Rutten, Luco, Yeji Choi, Anouk van der Net, Castro-Linares, Gerard, Caporaletti, Federico, Micha, Dimitra, Hunger, Johannes, Deblais, Antoine, Bonn, Daniel, Sommerdijk, Nico, Šarić, Anđela, Ilie, Ioana M., Koenderink, Gijsje H., and Woutersen, Sander

Subjects

COLLAGEN, CYTOSKELETAL proteins, RATE of nucleation, HYDRATION, STRUCTURAL dynamics

Abstract

Water is known to play an important role in collagen self-assembly, but it is still largely unclear how water--collagen interactions influence the assembly process and determine the fibril network properties. Here, we use the H2O/D2O isotope effect on the hydrogen-bond strength in water to investigate the role of hydration in collagen self-assembly. We dissolve collagen in H2O and D2O and compare the growth kinetics and the structure of the collagen assemblies formed in these water isotopomers. Surprisingly, collagen assembly occurs ten times faster in D2O than in H2O, and collagen in D2O self-assembles into much thinner fibrils, that form a more inhomogeneous and softer network, with a fourfold reduction in elastic modulus when compared to H2O. Combining spectroscopic measurements with atomistic simulations, we show that collagen in D2O is less hydrated than in H2O. This partial dehydration lowers the enthalpic penalty for water removal and reorganization at the collagen--water interface, increasing the self-assembly rate and the number of nucleation centers, leading to thinner fibrils and a softer network. Coarse-grained simulations show that the acceleration in the initial nucleation rate can be reproduced by the enhancement of electrostatic interactions. These results show that water acts as a mediator between collagen monomers, by modulating their interactions so as to optimize the assembly process and, thus, the final network properties. We believe that isotopically modulating the hydration of proteins can be a valuable method to investigate the role of water in protein structural dynamics and protein self-assembly. [ABSTRACT FROM AUTHOR]

Published

2024

2. Cross-linkers at growing microtubule ends generate forces that drive actin transport

Author

Celbiologie, Sub Cell Biology, Alkemade, Celine, Wierenga, Harmen, Volkov, Vladimir A., López, Magdalena Preciado, Akhmanova, Anna, ten Wolde, Pieter Rein, Dogterom, Marileen, Koenderink, Gijsje H., Celbiologie, Sub Cell Biology, Alkemade, Celine, Wierenga, Harmen, Volkov, Vladimir A., López, Magdalena Preciado, Akhmanova, Anna, ten Wolde, Pieter Rein, Dogterom, Marileen, and Koenderink, Gijsje H.

Published

2022

3. Cross-linkers at growing microtubule ends generate forces that drive actin transport

Author

Cell Biology, Neurobiology and Biophysics, Sub Cell Biology, Alkemade, Celine, Wierenga, Harmen, Volkov, Vladimir A., López, Magdalena Preciado, Akhmanova, Anna, ten Wolde, Pieter Rein, Dogterom, Marileen, Koenderink, Gijsje H., Cell Biology, Neurobiology and Biophysics, Sub Cell Biology, Alkemade, Celine, Wierenga, Harmen, Volkov, Vladimir A., López, Magdalena Preciado, Akhmanova, Anna, ten Wolde, Pieter Rein, Dogterom, Marileen, and Koenderink, Gijsje H.

Published

2022

4. An active biopolymer network controlled by molecular motors

Author

Koenderink, Gijsje H., Dogic, Zvonimir, Nakamura, Fumihiko, Bendix, Poul M., MacKintosh, Frederick C., Hartwig, John H., Stossel, Thomas P., and Weitz, David A.

Subjects

Myosin -- Properties, Actin -- Properties, Cytoskeleton -- Properties, Muscle proteins -- Properties, Polymers -- Rheology, Polymers -- Research, Science and technology

Abstract

We describe an active polymer network in which processive molecular motors control network elasticity. This system consists of actin filaments cross-linked by filamin A (FLNa) and contracted by bipolar filaments of muscle myosin II. The myosin motors stiffen the network by more than two orders of magnitude by pulling on actin filaments anchored in the network by FLNa cross-links, thereby generating internal stress. The stiffening response closely mimics the effects of external stress applied by mechanical shear. Both internal and external stresses can drive the network into a highly nonlinear, stiffened regime. The active stress reaches values that are equivalent to an external stress of 14 Pa, consistent with a 1-pN force per myosin head. This active network mimics many mechanical properties of cells and suggests that adherent cells exert mechanical control by operating in a nonlinear regime where cell stiffness is sensitive to changes in motor activity. This design principle may be applicable to engineering novel biologically inspired, active materials that adjust their own stiffness by internal catalytic control. active soft matter | cytoskeleton | filamin A | rheology | myosin II

Published

2009

5. Cross-linkers at growing microtubule ends generate forces that drive actin transport.

Author

Alkemade, Celine, Wierenga, Harmen, Volkov, Vladimir A., L'opez, Magdalena Preciado, Akhmanova, Anna, ten Wolde, Pieter Rein, Dogterom, Marileen, and Koenderink, Gijsje H.

Subjects

ACTIN, MICROTUBULES, MOLECULAR motor proteins, CELL motility, CELL division

Abstract

The actin and microtubule cytoskeletons form active networks in the cell that can contract and remodel, resulting in vital cellular processes such as cell division and motility. Motor proteins play an important role in generating the forces required for these processes, but more recently the concept of passive cross-linkers being able to generate forces has emerged. So far, these passive cross-linkers have been studied in the context of separate actin and microtubule systems. Here, we show that cross-linkers also allow actin and microtubules to exert forces on each other. More specifically, we study single actin filaments that are cross-linked to growing microtubule ends, using in vitro reconstitution, computer simulations, and a minimal theoretical model. We show that microtubules can transport actin filaments over large (micrometer-range) distances and find that this transport results from two antagonistic forces arising from the binding of cross-linkers to the overlap between the actin and microtubule filaments. The cross-linkers attempt to maximize the overlap between the actin and the tip of the growing microtubules, creating an affinity-driven forward condensation force, and simultaneously create a competing friction force along themicrotubule lattice. We predict and verify experimentally how the average transport time depends on the actin filament length and the microtubule growth velocity, confirming the competition between a forward condensation force and a backward friction force. In addition, we theoretically predict and experimentally verify that the condensation force is of the order of 0.1 pN. Thus, our results reveal an active mechanism for local actin remodeling by growing microtubules that relies on passive cross-linkers. [ABSTRACT FROM AUTHOR]

Published

2022

6. Connectivity and plasticity determine collagen network fracture.

Author

Burla, Federica, Dussi, Simone, Martinez-Torres, Cristina, Tauber, Justin, van der Gucht, Jasper, and Koenderink, Gijsje H.

Subjects

COLLAGEN, CONNECTIVE tissues, DEFORMATIONS (Mechanics), COMPUTER networks, TISSUES

Abstract

Collagen forms the structural scaffold of connective tissues in all mammals. Tissues are remarkably resistant against mechanical deformations because collagen molecules hierarchically selfassemble in fibrous networks that stiffen with increasing strain. Nevertheless, collagen networks do fracture when tissues are overloaded or subject to pathological conditions such as aneurysms. Prior studies of the role of collagen in tissue fracture have mainly focused on tendons, which contain highly aligned bundles of collagen. By contrast, little is known about fracture of the orientationally more disordered collagen networks present in many other tissues such as skin and cartilage. Here, we combine shear rheology of reconstituted collagen networks with computer simulations to investigate the primary determinants of fracture in disordered collagen networks. We show that the fracture strain is controlled by the coordination number of the network junctions, with less connected networks fracturing at larger strains. The hierarchical structure of collagen fine-tunes the fracture strain by providing structural plasticity at the network and fiber level. Our findings imply that low connectivity and plasticity provide protective mechanisms against network fracture that can optimize the strength of biological tissues. [ABSTRACT FROM AUTHOR]

Published

2020

7. Charge-dependent interactions of monomeric and filamentous actin with lipid bilayers.

Author

Schroer, Carsten F. E., Baldauf, Lucia, Buren, Lennard van, Wassenaar, Tsjerk A., Meloe, Manuel N., Koenderink, Gijsje H., and Marrink, Siewert J.

Subjects

BILAYER lipid membranes, ACTIN, CYTOSKELETAL proteins, MOLECULAR dynamics, CELL membranes

Abstract

The cytoskeletal protein actin polymerizes into filaments that are essential for the mechanical stability of mammalian cells. In vitro experiments showed that direct interactions between actin filaments and lipid bilayers are possible and that the net charge of the bilayer as well as the presence of divalent ions in the buffer play an important role. In vivo, colocalization of actin filaments and divalent ions are suppressed, and cells rely on linker proteins to connect the plasma membrane to the actin network. Little is known, however, about why this is the case and what microscopic interactions are important. A deeper understanding is highly beneficial, first, to obtain understanding in the biological design of cells and, second, as a possible basis for the building of artificial cortices for the stabilization of synthetic cells. Here, we report the results of coarse-grained molecular dynamics simulations of monomeric and filamentous actin in the vicinity of differently charged lipid bilayers. We observe that charges on the lipid head groups strongly determine the ability of actin to adsorb to the bilayer. The inclusion of divalent ions leads to a reversal of the binding affinity. Our in silico results are validated experimentally by reconstitution assays with actin on lipid bilayer membranes and provide a molecular-level understanding of the actin-membrane interaction. [ABSTRACT FROM AUTHOR]

Published

2020

8. Cell-sized liposomes reveal how actomyosin cortical tension drives shape change.

Author

Carvalho, Kevin, Tsai, Feng C., Lees, Edouard, Voituriez, Raphaël, Koenderink, Gijsje H., and Sykes, Cecile

Subjects

LIPOSOMES, CELL size, ACTIN, MOLECULAR motor proteins, ORGAN rupture, CHEMICAL energy

Abstract

Animal cells actively generate contractile stress in the actin cortex, a thin actin network beneath the cell membrane, to facilitate shape changes during processes like cytokinesis and motility. On the microscopic scale, this stress is generated by myosin molecular motors, which bind to actin cytoskeletal filaments and use chemical energy to exert pulling forces. To decipher the physical basis for the regulation of cell shape changes, here, we use a cell-like system with a cortex anchored to the outside or inside of a liposome membrane. This system enables us to dissect the interplay between motor pulling forces, cortex-membrane anchoring, and network connectivity. We show that cortices on the outside of liposomes either spontaneously rupture and relax built-up mechanical stress by peeling away around the liposome or actively compress and crush the liposome. The decision between peeling and crushing depends on the cortical tension determined by the amount of motors and also on the connectivity of the cortex and its attachment to the membrane. Membrane anchoring strongly affects the morphology of cortex contraction inside liposomes: cortices contract inward when weakly attached, whereas they contract toward the membrane when strongly attached. We propose a physical model based on a balance of active tension and mechanical resistance to rupture. Our findings show how membrane attachment and network connectivity are able to regulate actin cortex remodeling and membrane-shape changes for cell polarization. [ABSTRACT FROM AUTHOR]

Published

2013

9. Active multistage coarsening of actin networks driven by myosin motors.

Author

e Silva, Marina Soares, Depken, Martin, Stuhrmann, Björn, Korsten, Marijn, MacKintosh, Fred C., and Koenderink, Gijsje H.

Subjects

MYOSIN, MUSCLE motility, ACTIN, CYTOSKELETON, ACTOMYOSIN

Abstract

In cells, many vital processes involve myosin-driven motility that actively remodels the actin cytoskeleton and changes cell shape. Here we study how the collective action of myosin motors organizes actin filaments into contractile structures in a simplified model system devoid of biochemical regulation. We show that this self-organization occurs through an active multistage coarsening process. First, motors form dense foci by moving along the actin network structure followed by coalescence. Then the foci accumulate actin filaments in a shell around them. These actomyosin condensates eventually cluster due to motor-driven coalescence. We propose that the physical origin of this multistage aggregation is the highly asymmetric load response of actin filaments: they can support large tensions but buckle easily under piconewton compressive loads. Because the motor-generated forces well exceed this threshold, buckling is induced on the connected actin network that resists motor-driven filament sliding. We show how this buckling can give rise to the accumulation of actin shells around myosin foci and subsequent coalescence of foci into superaggregates. This new physical mechanism provides an explanation for the formation and contractile dynamics of disordered condensed actomyosin states observed in vivo. [ABSTRACT FROM AUTHOR]

Published

2011

10. Active multistage coarsening of actin networks driven by myosin motors.

Author

Soares e Silva M, Depken M, Stuhrmann B, Korsten M, MacKintosh FC, and Koenderink GH

Subjects

Actin Cytoskeleton physiology, Actins physiology, Actomyosin physiology, Algorithms, Animals, Cell Movement physiology, Humans, Microscopy, Confocal, Microscopy, Fluorescence, Models, Biological, Models, Chemical, Muscle Contraction physiology, Myosins physiology, Actin Cytoskeleton chemistry, Actins chemistry, Actomyosin chemistry, Myosins chemistry

Abstract

In cells, many vital processes involve myosin-driven motility that actively remodels the actin cytoskeleton and changes cell shape. Here we study how the collective action of myosin motors organizes actin filaments into contractile structures in a simplified model system devoid of biochemical regulation. We show that this self-organization occurs through an active multistage coarsening process. First, motors form dense foci by moving along the actin network structure followed by coalescence. Then the foci accumulate actin filaments in a shell around them. These actomyosin condensates eventually cluster due to motor-driven coalescence. We propose that the physical origin of this multistage aggregation is the highly asymmetric load response of actin filaments: they can support large tensions but buckle easily under piconewton compressive loads. Because the motor-generated forces well exceed this threshold, buckling is induced on the connected actin network that resists motor-driven filament sliding. We show how this buckling can give rise to the accumulation of actin shells around myosin foci and subsequent coalescence of foci into superaggregates. This new physical mechanism provides an explanation for the formation and contractile dynamics of disordered condensed actomyosin states observed in vivo.

Published

2011