Your search keyword '"Niek van Hilten"' showing total 16 results

1. Atypical cofilin signaling drives dendritic cell migration through the extracellular matrix via nuclear deformation

Author

Harry Warner, Giulia Franciosa, Guus van der Borg, Britt Coenen, Felix Faas, Claire Koenig, Rinse de Boer, René Classens, Sjors Maassen, Maksim V. Baranov, Shweta Mahajan, Deepti Dabral, Frans Bianchi, Niek van Hilten, Herre Jelger Risselada, Wouter H. Roos, Jesper Velgaard Olsen, Laia Querol Cano, and Geert van den Bogaart

Subjects

CP: Cell biology, Biology (General), QH301-705.5

Abstract

Summary: To mount an adaptive immune response, dendritic cells must migrate to lymph nodes to present antigens to T cells. Critical to 3D migration is the nucleus, which is the size-limiting barrier for migration through the extracellular matrix. Here, we show that inflammatory activation of dendritic cells leads to the nucleus becoming spherically deformed and enables dendritic cells to overcome the typical 2- to 3-μm diameter limit for 3D migration through gaps in the extracellular matrix. We show that the nuclear shape change is partially attained through reduced cell adhesion, whereas improved 3D migration is achieved through reprogramming of the actin cytoskeleton. Specifically, our data point to a model whereby the phosphorylation of cofilin-1 at serine 41 drives the assembly of a cofilin-actomyosin ring proximal to the nucleus and enhances migration through 3D collagen gels. In summary, these data describe signaling events through which dendritic cells deform their nucleus and enhance their migratory capacity.

Published

2024

2. Membrane Thinning Induces Sorting of Lipids and the Amphipathic Lipid Packing Sensor (ALPS) Protein Motif

Author

Niek van Hilten, Kai Steffen Stroh, and Herre Jelger Risselada

Subjects

membrane thinning, lipid sorting, protein sorting, membrane deformation, membrane curvature, lipid packing, Physiology, QP1-981

Abstract

Heterogeneities (e.g., membrane proteins and lipid domains) and deformations (e.g., highly curved membrane regions) in biological lipid membranes cause lipid packing defects that may trigger functional sorting of lipids and membrane-associated proteins. To study these phenomena in a controlled and efficient way within molecular simulations, we developed an external field protocol that artificially enhances packing defects in lipid membranes by enforcing local thinning of a flat membrane region. For varying lipid compositions, we observed strong thinning-induced depletion or enrichment, depending on the lipid's intrinsic shape and its effect on a membrane's elastic modulus. In particular, polyunsaturated and lysolipids are strongly attracted to regions high in packing defects, whereas phosphatidylethanolamine (PE) lipids and cholesterol are strongly repelled from it. Our results indicate that externally imposed changes in membrane thickness, area, and curvature are underpinned by shared membrane elastic principles. The observed sorting toward the thinner membrane region is in line with the sorting expected for a positively curved membrane region. Furthermore, we have demonstrated that the amphipathic lipid packing sensor (ALPS) protein motif, a known curvature and packing defect sensor, is effectively attracted to thinner membrane regions. By extracting the force that drives amphipathic molecules toward the thinner region, our thinning protocol can directly quantify and score the lipid packing sensing of different amphipathic molecules. In this way, our protocol paves the way toward high-throughput exploration of potential defect- and curvature-sensing motifs, making it a valuable addition to the molecular simulation toolbox.

Published

2020

3. PMIpred: A physics-informed web server for quantitative Protein-Membrane Interaction prediction

Author

Niek van Hilten, Nino Verwei, Jeroen Methorst, Carsten Nase, Andrius Bernatavicius, and Herre Jelger Risselada

Abstract

MotivationMany membrane peripheral proteins have evolved to transiently interact with the surface of (curved) lipid bilayers. Currently, methods toquantitativelypredict sensing and binding free energies for protein sequences or structures are lacking, and such tools could greatly benefit the discovery of membrane-interacting motifs, as well as theirde novodesign.ResultsHere, we trained a transformer neural network model on molecular dynamics data for>50,000 peptides that is able to accurately predict the (relative) membrane-binding free energy for any given amino acid sequence. Using this information, our physics-informed model is able to classify a peptide’s membrane-associative activity as either non-binding, curvature sensing, or membrane binding. Moreover, this method can be applied to detect membrane-interaction regions in a wide variety of proteins, with comparable predictive performance as state-of-the-art data-driven tools like DREAMM, PPM, and MODA, but with a wider applicability regarding protein diversity, and the added feature to distinguish curvature sensing from general membrane binding.AvailabilityWe made these tools available as a web server, coined Protein-Membrane Interaction predictor (PMIpred), which can be accessed athttps://pmipred.fkt.physik.tu-dortmund.de.

Published

2023

4. Physics-based generative model of curvature sensing peptides; distinguishing sensors from binders

Author

Niek van Hilten, Jeroen Methorst, Nino Verwei, and Herre Jelger Risselada

Subjects

Neuronales Netz, Multidisciplinary, Molekulare Biophysik, Molekulardynamik, Biomembran, Simulation, Membranproteine

Abstract

Proteins can specifically bind to curved membranes through curvature-induced hydrophobic lipid packing defects. The chemical diversity among such curvature “sensors” challenges our understanding of how they differ from general membrane “binders” that bind without curvature selectivity. Here, we combine an evolutionary algorithm with coarse-grained molecular dynamics simulations (Evo-MD) to resolve the peptide sequences that optimally recognize the curvature of lipid membranes. We subsequently demonstrate how a synergy between Evo-MD and a neural network (NN) can enhance the identification and discovery of curvature sensing peptides and proteins. To this aim, we benchmark a physics-trained NN model against experimental data and show that we can correctly identify known sensors and binders. We illustrate that sensing and binding are phenomena that lie on the same thermodynamic continuum, with only subtle but explainable differences in membrane binding free energy, consistent with the serendipitous discovery of sensors., Science advances;9(11)

Published

2023

5. Lipase-mediated selective hydrolysis of lipid droplets in phase separated-liposomes

Author

Panagiota Papadopoulou, Rianne van der Pol, Niek van Hilten, Mohammad-Amin Moradi, Maria Ferraz, Johannes aerts, Nico Sommerdijk, Jelger Risselada, agur sevink, and alexander kros

Abstract

The membrane-protein interface in lipid nanoparticles (LNPs) is important for their in vivo behavior. Better understanding may assist to evolve current drug delivery methods to more precise, cell- or tissue-specific nanomedicine. Previously, we demonstrated how phase separation can drive liposomes to cell specific accumulation in vivo, through the selective recognition of phase-separated liposomes by triacylglycerol lipases (TGLs). This exemplified how liposome morphology can determine the preferential interaction of nanoparticles with biologically relevant proteins. Here, we investigate in detail the lipase-induced morphological changes of phase separated liposomes - which bear a lipid droplet in their bilayer - and unravel how lipase recognizes and binds to the particles at a molecular level. We find that phase separated liposomes undergo selective lipolytic degradation of their lipid droplet while overall nanoparticle integrity remains intact. Next, we combined MD simulations and in vitro experiments to identify the Tryptophan-rich loop of the lipase – a region which is involved endogenously in lipoprotein binding – as the region through which the enzyme binds to the particle. We demonstrate that this preferential binding is due to the lipid packing defects induced on the membrane by phase separation. These findings are a significant example of selective LNP – protein communication and interaction, aspects that may further the control of the in vivo behavior of lipid nanoparticles.

Published

2023

6. Cofilin-Driven Nuclear Deformation Drives Dendritic Cell Migration Through the Extracellular Matrix

Author

Harry Marcus Warner, Giulia Franciosa, Guus van der Borg, Felix Faas, Claire Koenig, Rinse de Boer, Rene Classens, Sjors Maassen, Maksim Baranov, Shweta Mahajan, Deepti Dabral, Britt Coenen, Frans Bianchi, Niek van Hilten, Herre Jelger Risselada, Wouter Roos, Jesper Velgaard Olsen, Laia Querol Cano, and Geert van den Bogaart

Published

2023

7. Efficient quantification of lipid packing defect sensing by amphipathic peptides; comparing Martini 2 & 3 with CHARMM36

Author

Niek van Hilten, Kai Steffen Stroh, and Herre Jelger Risselada

Abstract

In biological systems, proteins can be attracted to curved or stretched regions of lipid bilayers by sensing hydrophobic defects in the lipid packing on the membrane surface. Here, we present an efficient end-state free energy calculation method to quantify such sensing in molecular dynamics simulations. We illustrate that lipid packing defect sensing can be defined as the difference in mechanical work required to stretch a membrane with and without a peptide bound to the surface. We also demonstrate that a peptide’s ability to concurrently induce excess leaflet area (tension) and elastic softening – a property we call the ‘characteristic area of sensing’ (CHAOS) – and lipid packing sensing behavior are in fact two sides of the same coin. In essence, defect sensing displays a peptide’s propensity to generate tension. The here-proposed mechanical pathway is equally accurate yet, computationally, about 40 times less costly than the commonly used alchemical pathway (thermodynamic integration), allowing for more feasible free energy calculations in atomistic simulations. This enabled us to directly compare the Martini 2 and 3 coarse-grained and the CHARMM36 atomistic force-fields in terms of relative binding free energies for six representative peptides including the curvature sensor ALPS and two antiviral amphipathic helices (AH). We observed that Martini 3 qualitatively reproduces experimental trends, whilst producing substantially lower (relative) binding free energies and shallower membrane insertion depths compared to atomistic simulations. In contrast, Martini 2 tends to overestimate (relative) binding free energies. Finally, we offer a glimpse into how our end-state based free energy method can enable the inverse design of optimal lipid packing defect sensing peptides when used in conjunction with our recently developed Evolutionary Molecular Dynamics (Evo-MD) method. We argue that these optimized defect sensors – aside from their biomedical and biophysical relevance – can provide valuable targets for the development of lipid force-fields.TOC Graphic

Published

2022

8. Physics-based inverse design of curvature sensing antiviral peptides

Author

Niek van Hilten and Herre Jelger Risselada

Subjects

Biophysics

Published

2023

9. Physics-based inverse design of cholesterol attracting transmembrane helices reveals a paradoxical role of hydrophobic length

Author

Jeroen Methorst, Nino Verwei, Christian Hoffmann, Paweł Chodnicki, Roberto Sansevrino, Han Wang, Niek van Hilten, Dennis Aschmann, Alexander Kros, Loren Andreas, Jacek Czub, Dragomir Milovanovic, and Herre Jelger Risselada

Subjects

chemistry.chemical_classification, 0303 health sciences, 010304 chemical physics, Cholesterol, Sequence (biology), 01 natural sciences, Attraction, Amino acid, 03 medical and health sciences, Transmembrane domain, Molecular dynamics, chemistry.chemical_compound, Membrane, chemistry, Membrane protein, 0103 physical sciences, Biophysics, 030304 developmental biology

Abstract

The occurrence of linear cholesterol-recognition motifs in alpha-helical transmembrane domains has long been debated. Here, we demonstrate the ability of a genetic algorithm guided by coarse-grained molecular dynamics simulations—a method coined evolutionary molecular dynamics (Evo-MD)—to directly resolve the sequence which maximally attracts cholesterol for single-pass alpha-helical transmembrane domains (TMDs). We illustrate that the evolutionary landscape of cholesterol attraction in membrane proteins is characterized by a sharp, well-defined global optimum. Surprisingly, this optimal solution features an unusual short hydrophobic block, consisting of typically only eight small hydrophobic amino acids, surrounded by three successive lysines. Owing to the membrane thickening effect of cholesterol, cholesterol-enriched ordered phases favor TMDs characterized by a long rather than a too short hydrophobic length (a negative hydrophobic mismatch). However, this short hydrophobic pattern evidently offers a pronounced net advantage for the attraction of free cholesterol in both coarse-grained and atomistic simulations. We illustrate that optimal cholesterol attraction is in fact based on the superposition of two distinct thermodynamic attraction mechanisms. In addition, we explore the evolutionary occurrence and feasibility of these two mechanisms by analyzing existing databases of membrane proteins and through the direct expression of analogous short hydrophobic sequences in live cell assays. The puzzling sequence variability of proposed linear cholesterol-recognition motifs is indicative of a sub-optimal membrane-mediated attraction of cholesterol which markedly differs from ligand binding based on shape compatibility.Significance StatementOur work demonstrates how a synergy between evolutionary algorithms and high-throughput coarse-grained molecular dynamics can yield fundamentally new insights into the evolutionary fingerprints of protein-mediated lipid sorting. We illustrate that the evolutionary landscape of cholesterol attraction in isolated transmembrane domains is characterized by a well-defined global optimum. In contrast, sub-optimal attraction of cholesterol is associated with a diverse solution space and features a high sequence variability despite acting on the same unique molecule. The contrasting physicochemical nature of the resolved attraction optimum suggests that cholesterol attraction via linear motifs does not pose a dominant pressure on the evolution of transmembrane proteins.

Published

2021

10. Structure-Based Discovery of Novel Ligands for the Orexin 2 Receptor

Author

Peter Kolb, Jakub Gunera, Daniel M. Rosenbaum, Jillian G. Baker, and Niek van Hilten

Subjects

Agonist, Stereochemistry, medicine.drug_class, Plasma protein binding, CHO Cells, Ligands, 01 natural sciences, 03 medical and health sciences, Structure-Activity Relationship, Cricetulus, Orexin Receptors, Drug Discovery, medicine, Structure–activity relationship, Animals, Humans, Receptor, 030304 developmental biology, 0303 health sciences, biology, Molecular Structure, Chemistry, Chinese hamster ovary cell, biology.organism_classification, Orexin receptor, 0104 chemical sciences, 010404 medicinal & biomolecular chemistry, Docking (molecular), Area Under Curve, Drug Design, Molecular Medicine, Orexin Receptor Antagonists, Protein Binding

Abstract

The orexin receptors are peptide-sensing G protein-coupled receptors that are intimately linked with regulation of the sleep/wake cycle. We used a recently solved X-ray structure of the orexin receptor subtype 2 in computational docking calculations with the aim to identify additional ligands with unprecedented chemotypes. We found validated ligands with a high hit rate of 29% out of those tested, none of them showing selectivity with respect to the orexin receptor subtype 1. Furthermore, of the higher-affinity compounds examined, none showed any agonist activity. While novel chemical structures can thus be found, selectivity is a challenge owing to the largely identical binding pockets.

Published

2020

11. Membrane Thinning Induces Sorting of Lipids and the Amphipathic Lipid Packing Sensor (ALPS) Protein Motif

Author

Herre Jelger Risselada, Kai Steffen Stroh, and Niek van Hilten

Subjects

0301 basic medicine, Physiology, protein sorting, membrane thinning, curvature sensing, medicine.disease_cause, 01 natural sciences, lcsh:Physiology, 03 medical and health sciences, chemistry.chemical_compound, Membrane region, Physiology (medical), 0103 physical sciences, Amphiphile, Protein targeting, medicine, lipid packing, Structural motif, Original Research, Phosphatidylethanolamine, 010304 chemical physics, lcsh:QP1-981, lipid sorting, 030104 developmental biology, Membrane, chemistry, Membrane protein, Membrane curvature, membrane curvature, Biophysics, membrane deformation

Abstract

Heterogeneities (e.g., membrane proteins and lipid domains) and deformations (e.g., highly curved membrane regions) in biological lipid membranes cause lipid packing defects that may trigger functional sorting of lipids and membrane-associated proteins. To study these phenomena in a controlled and efficient way within molecular simulations, we developed an external field protocol that artificially enhances packing defects in lipid membranes by enforcing local thinning of a flat membrane region. For varying lipid compositions, we observed strong thinning-induced depletion or enrichment, depending on the lipid's intrinsic shape and its effect on a membrane's elastic modulus. In particular, polyunsaturated and lysolipids are strongly attracted to regions high in packing defects, whereas phosphatidylethanolamine (PE) lipids and cholesterol are strongly repelled from it. Our results indicate that externally imposed changes in membrane thickness, area, and curvature are underpinned by shared membrane elastic principles. The observed sorting toward the thinner membrane region is in line with the sorting expected for a positively curved membrane region. Furthermore, we have demonstrated that the amphipathic lipid packing sensor (ALPS) protein motif, a known curvature and packing defect sensor, is effectively attracted to thinner membrane regions. By extracting the force that drives amphipathic molecules toward the thinner region, our thinning protocol can directly quantify and score the lipid packing sensing of different amphipathic molecules. In this way, our protocol paves the way toward high-throughput exploration of potential defect- and curvature-sensing motifs, making it a valuable addition to the molecular simulation toolbox.

Published

2020

12. Inverse design of membrane curvature and defect sensing peptides by evolutionary molecular dynamics simulations (evoMD)

Author

Niek van Hilten and Herre Jelger Risselada

Subjects

Biophysics

Published

2022

13. Binding-Site Compatible Fragment Growing Applied to the Design of β2-Adrenergic Receptor Ligands

Author

Els Pardon, Florent Chevillard, Cecilia Betti, Steven Ballet, Niek van Hilten, Peter Kolb, Wibke E. Diederich, Helena Rimmer, and Jan Steyaert

Subjects

0301 basic medicine, Chemistry, Drug discovery, In silico, Computational biology, 01 natural sciences, 0104 chemical sciences, β2 adrenergic receptor, 010404 medicinal & biomolecular chemistry, 03 medical and health sciences, 030104 developmental biology, Protein structure, Fragment (logic), Drug Discovery, Molecular Medicine, Structure–activity relationship, Binding site

Abstract

Fragment-based drug discovery is intimately linked to fragment extension approaches that can be accelerated using software for de novo design. Although computers allow for the facile generation of millions of suggestions, synthetic feasibility is however often neglected. In this study we computationally extended, chemically synthesized, and experimentally assayed new ligands for the β2-adrenergic receptor (β2AR) by growing fragment-sized ligands. In order to address the synthetic tractability issue, our in silico workflow aims at derivatized products based on robust organic reactions. The study started from the predicted binding modes of five fragments. We suggested a total of eight diverse extensions that were easily synthesized, and further assays showed that four products had an improved affinity (up to 40-fold) compared to their respective initial fragment. The described workflow, which we call “growing via merging” and for which the key tools are available online, can improve early fragment-based dru...

Published

2018

14. Virtual Compound Libraries in Computer-Assisted Drug Discovery

Author

Peter Kolb, Niek van Hilten, and Florent Chevillard

Subjects

Parsing, 010304 chemical physics, Computer science, Drug discovery, General Chemical Engineering, Cheminformatics, General Chemistry, Library and Information Sciences, computer.software_genre, 01 natural sciences, Popularity, Chemical space, 0104 chemical sciences, Computer Science Applications, World Wide Web, Small Molecule Libraries, 010404 medicinal & biomolecular chemistry, User-Computer Interface, 0103 physical sciences, Drug Discovery, Key (cryptography), computer

Abstract

The use of virtual compound libraries in computer-assisted drug discovery has gained in popularity and has already lead to numerous successes. Here, we examine key static and dynamic virtual library concepts that have been developed over the past decade. To facilitate the search for new drugs in the vastness of chemical space, there are still several hurdles to overcome, including the current difficulties in screening and parsing efficiency and the need for more reliable vendors and accurate synthesis prediction tools. These challenges should be tackled by both the developers of virtual libraries and by their users, in order for the exploration of chemical space to live up to its potential.

Published

2019

15. Binding-Site Compatible Fragment Growing Applied to the Design of β

Author

Florent, Chevillard, Helena, Rimmer, Cecilia, Betti, Els, Pardon, Steven, Ballet, Niek, van Hilten, Jan, Steyaert, Wibke E, Diederich, and Peter, Kolb

Subjects

Models, Molecular, Structure-Activity Relationship, Binding Sites, Protein Conformation, Drug Design, Computer Simulation, Receptors, Adrenergic, beta-2, Ligands, Amination

Abstract

Fragment-based drug discovery is intimately linked to fragment extension approaches that can be accelerated using software for de novo design. Although computers allow for the facile generation of millions of suggestions, synthetic feasibility is however often neglected. In this study we computationally extended, chemically synthesized, and experimentally assayed new ligands for the β

Published

2018

16. Potent Metabolic Sialylation Inhibitors Based on C-5-Modified Fluorinated Sialic Acids

Author

Johan F. A. Pijnenborg, Niek van Hilten, Thomas J. Boltje, Natasja Balneger, Torben Heise, Hidde Elferink, Christian Büll, Esther D. Kers-Rebel, and Gosse J. Adema

Subjects

Cytidine monophosphate, Halogenation, Sialyltransferase, Cancer development and immune defence Radboud Institute for Molecular Life Sciences [Radboudumc 2], Synthetic Organic Chemistry, Inhibitory postsynaptic potential, 01 natural sciences, Article, Cell Line, Mice, 03 medical and health sciences, chemistry.chemical_compound, All institutes and research themes of the Radboud University Medical Center, Biosynthesis, Drug Discovery, Cytidine Monophosphate, medicine, Animals, Humans, 030304 developmental biology, 0303 health sciences, biology, Cancer, Human cell, medicine.disease, Amides, Carbon, Sialyltransferases, 3. Good health, 0104 chemical sciences, Sialic acid, carbohydrates (lipids), 010404 medicinal & biomolecular chemistry, chemistry, Biochemistry, Cell culture, Sialic Acids, biology.protein, Molecular Medicine, Carbamates

Abstract

Sialic acid sugars on mammalian cells regulate numerous biological processes, while aberrant expression of sialic acid is associated with diseases such as cancer and pathogenic infection. Inhibition of the sialic acid biosynthesis may therefore hold considerable therapeutic potential. To effectively decrease the sialic acid expression, we synthesized C-5-modified 3-fluoro sialic acid sialyltransferase inhibitors. We found that C-5 carbamates significantly enhanced and prolonged the inhibitory activity in multiple mouse and human cell lines. As an underlying mechanism, we have identified that carbamate-modified 3-fluoro sialic acid inhibitors are more efficiently metabolized to their active cytidine monophosphate analogues, reaching higher effective inhibitor concentrations inside cells.