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3. Complex nanoemulsion for vitamin delivery

Author

Siewert J. Marrink, Bart M H Bruininks, Paulo C. T. Souza, Laurita dos Santos, Odivania Kruger, Neila Machado, Gustavo De Campos Dieamant, Priyanka Singh, P. P. Favero, Carine Dal Pizzol, Airton Abrahão Martin, and Molecular Dynamics

Subjects
food.ingredient, integumentary system, Chemistry, Skin Absorption, Supramolecular chemistry, Rational design, Absorption (skin), Vitamins, Lecithin, Nanomaterials, Membrane, medicine.anatomical_structure, food, Drug Delivery Systems, Drug delivery, Stratum corneum, medicine, Biophysics, General Materials Science, Emulsions, Skin
Abstract

Lipid nanoemulsions are promising nanomaterials for drug delivery applications in food, pharmaceutical and cosmetic industries. Despite the noteworthy commercial interest, little is known about their supramolecular organization, especially about how such multicomponent formulations interact with cell membranes. In the present work, coarse-grained molecular dynamics simulations have been employed to study the self-assembly of a 15-component lipid nanoemulsion droplet containing vitamins A and E for skin delivery. Our results display aspects of the unique "onion-like" agglomeration between the chemical constituents in the different layers of the lipid nanodroplet. Vitamin E molecules are more concentrated in the center of the droplet together with other hydrophobic constituents such as the triglycerides with long tails. On the other hand, vitamin A occupies an intermediate layer between the core and the co-emulsifier surface of the nanodroplet, together with lecithin phospholipids. Coarse-grained molecular dynamics simulations were also performed to provide insight into the first steps involved in absorption and penetration of the nanodroplet through skin membrane models, representing an intracellular (hair follicle infundibulum) and intercellular pathway (stratum corneum) through the skin. Our data provide a first view on the complex organization of commercial nanoemulsion and its interaction with skin membranes. We expect our results to open the way towards the rational design of such nanomaterials.

Published
2022

4. Synthetic Membrane Shaper for Controlled Liposome Deformation

Author

Nicola De Franceschi, Weria Pezeshkian, Alessio Fragasso, Bart M. H. Bruininks, Sean Tsai, Siewert J. Marrink, Cees Dekker, and Molecular Dynamics

Subjects
General Engineering, General Physics and Astronomy, General Materials Science
Abstract

Shape defines the structure and function of cellular membranes. In cell division, the cell membrane deforms into a "dumbbell" shape, while organelles such as the autophagosome exhibit "stomatocyte" shapes. Bottom-up in vitro reconstitution of protein machineries that stabilize or resolve the membrane necks in such deformed liposome structures is of considerable interest to characterize their function. Here we develop a DNA-nanotechnology-based approach that we call the synthetic membrane shaper (SMS), where cholesterol-linked DNA structures attach to the liposome membrane to reproducibly generate high yields of stomatocytes and dumbbells. In silico simulations confirm the shape-stabilizing role of the SMS. We show that the SMS is fully compatible with protein reconstitution by assembling bacterial divisome proteins (DynaminA, FtsZ:ZipA) at the catenoidal neck of these membrane structures. The SMS approach provides a general tool for studying protein binding to complex membrane geometries that will greatly benefit synthetic cell research.

Published
2022
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5. Martini 3

Author

Vincent Nieto, Valentina Corradi, Siewert J. Marrink, Matti Javanainen, Peter C. Kroon, Ilpo Vattulainen, Hector Martinez-Seara, D. Peter Tieleman, Alex H. de Vries, Jan Domański, Hanif M. Khan, Robert B. Best, Ilias Patmanidis, Sebastian Thallmair, Ignacio Faustino, Xavier Periole, Jonathan Barnoud, Tsjerk A. Wassenaar, Josef Melcr, Nathalie Reuter, Haleh Abdizadeh, Bart M H Bruininks, Paulo C. T. Souza, Fabian Grünewald, Riccardo Alessandri, Luca Monticelli, Department of Physics, and Molecular Dynamics

Subjects
STRUCTURAL BASIS, Materials science, Lipid Bilayers, TRANSITIONS, Molecular Dynamics Simulation, SOLUBILITY, Molecular systems, Biochemistry, Miscibility, Force field (chemistry), PROTEIN-PROTEIN INTERACTIONS, 03 medical and health sciences, Molecular dynamics, Polarizability, Molecular Biology, 030304 developmental biology, 0303 health sciences, Computational model, Hydrogen Bonding, ASSOCIATION, Cell Biology, TRANSMEMBRANE DOMAIN, SIMULATIONS, TRANSMEMBRANE DOMAIN DIMERIZATION, MODEL, General purpose, Chemical physics, Thermodynamics, 1182 Biochemistry, cell and molecular biology, Computational biophysics, HELIX INTERACTIONS, EXTENSION, Biotechnology
Abstract

The coarse-grained Martini force field is widely used in biomolecular simulations. Here we present the refined model, Martini 3 (http://cgmartini.nl), with an improved interaction balance, new bead types and expanded ability to include specific interactions representing, for example, hydrogen bonding and electronic polarizability. The updated model allows more accurate predictions of molecular packing and interactions in general, which is exemplified with a vast and diverse set of applications, ranging from oil/water partitioning and miscibility data to complex molecular systems, involving protein-protein and protein-lipid interactions and material science applications as ionic liquids and aedamers.

Published
2021
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6. Sequential Voxel-Based Leaflet Segmentation of Complex Lipid Morphologies

Author

Tsjerk A. Wassenaar, Albert S. Thie, Siewert J. Marrink, Shirin Faraji, Bart M H Bruininks, Paulo C. T. Souza, Molecular Dynamics, and Theoretical Chemistry

Subjects
Fusion, Computer science, Vesicle, computer.software_genre, Micelle, Article, Computer Science Applications, Molecular dynamics, Membrane, Voxel, Particle, Segmentation, Physical and Theoretical Chemistry, Biological system, computer
Abstract

As molecular dynamics simulations increase in complexity, new analysis tools are necessary to facilitate interpreting the results. Lipids, for instance, are known to form many complicated morphologies, because of their amphipathic nature, becoming more intricate as the particle count increases. A few lipids might form a micelle, where aggregation of tens of thousands could lead to vesicle formation. Millions of lipids comprise a cell and its organelle membranes, and are involved in processes such as neurotransmission and transfection. To study such phenomena, it is useful to have analysis tools that understand what is meant by emerging entities such as micelles and vesicles. Studying such systems at the particle level only becomes extremely tedious, counterintuitive, and computationally expensive. To address this issue, we developed a method to track all the individual lipid leaflets, allowing for easy and quick detection of topological changes at the mesoscale. By using a voxel-based approach and focusing on locality, we forego costly geometrical operations without losing important details and chronologically identify the lipid segments using the Jaccard index. Thus, we achieve a consistent sequential segmentation on a wide variety of (lipid) systems, including monolayers, bilayers, vesicles, inverted hexagonal phases, up to the membranes of a full mitochondrion. It also discriminates between adhesion and fusion of leaflets. We show that our method produces consistent results without the need for prefitting parameters, and segmentation of millions of particles can be achieved on a desktop machine.

Published
2021

7. On the road to simulating life with molecular detail

Author

Bart M H Bruininks, Marrink, Siewert, Telles de Souza, Paulo, de Vries, Alex, and Molecular Dynamics

Abstract

We start off with a full chapter dedicated to high school students focussing on the basic of what it means to make a (toy) model of moving particles. After this introduction to the molecular dynamics way of thinking we move on to a full-fledged force field (Martini). The other chapters will cover different apspects of modelling. These aspects are initial state building, two case studies (lipid-DNA nanoparticles and a nanodroplet on skin) and advanced analysis.

Published
2021

8. A molecular view on the escape of lipoplexed DNA from the endosome

Author

Siewert-Jan Marrink, Helgi I. Ingólfsson, Bart M H Bruininks, Paulo C. T. Souza, and Molecular Dynamics

Subjects
0301 basic medicine, DYNAMICS, 01 natural sciences, ENERGETICS, non-viral vector, GENE DELIVERY, Molecular dynamics, chemistry.chemical_compound, HEMIFUSION, Cationic liposome, Biology (General), Fusion, 010304 chemical physics, General Neuroscience, Gene Transfer Techniques, General Medicine, Transfection, Medicine, martini, lipids (amino acids, peptides, and proteins), Computational and Systems Biology, LIPIDS, QH301-705.5, Endosome, Science, Genetic Vectors, Short Report, Gene delivery, Molecular Dynamics Simulation, MEMBRANE-FUSION, DOTAP/DOPE, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0103 physical sciences, None, General Immunology and Microbiology, TRANSFECTION EFFICIENCY, Lipid bilayer fusion, dotap, molecular dynamics, SIMULATIONS, 030104 developmental biology, chemistry, Liposomes, Biophysics, FORCE-FIELD, lipoplex, DNA
Abstract

The use of non-viral vectors for in vivo gene therapy could drastically increase safety, whilst reducing the cost of preparing the vectors. A promising approach to non-viral vectors makes use of DNA/cationic liposome complexes (lipoplexes) to deliver the genetic material. Here we use coarse-grained molecular dynamics simulations to investigate the molecular mechanism underlying efficient DNA transfer from lipoplexes. Our computational fusion experiments of lipoplexes with endosomal membrane models show two distinct modes of transfection: parallel and perpendicular. In the parallel fusion pathway, DNA aligns with the membrane surface, showing very quick release of genetic material shortly after the initial fusion pore is formed. The perpendicular pathway also leads to transfection, but release is slower. We further show that the composition and size of the lipoplex, as well as the lipid composition of the endosomal membrane, have a significant impact on fusion efficiency in our models.

Published
2020

9. Bottom-up fabrication of a proteasome-nanopore that unravels and processes single proteins

Author

Siewert-Jan Marrink, Giovanni Maglia, Roderick Corstiaan Abraham Versloot, Shengli Zhang, Gang Huang, Bart M H Bruininks, Paulo C. T. Souza, Chemical Biology 1, and Molecular Dynamics

Subjects
chemistry.chemical_classification, Nanopore, Multiprotein complex, chemistry, Proteasome, Activator (genetics), General Chemical Engineering, Biomolecule, Biophysics, General Chemistry, Threading (protein sequence), 20s proteasome, Molecular machine
Abstract

The precise assembly and engineering of molecular machines capable of handling biomolecules play crucial roles in most single-molecule methods. In this work we use components from all three domains of life to fabricate an integrated multiprotein complex that controls the unfolding and threading of individual proteins across a nanopore. This 900 kDa multicomponent device was made in two steps. First, we designed a stable and low-noise β-barrel nanopore sensor by linking the transmembrane region of bacterial protective antigen to a mammalian proteasome activator. An archaeal 20S proteasome was then built into the artificial nanopore to control the unfolding and linearized transport of proteins across the nanopore. This multicomponent molecular machine opens the door to two approaches in single-molecule protein analysis, in which selected substrate proteins are unfolded, fed to into the proteasomal chamber and then addressed either as fragmented peptides or intact polypeptides. An integrated multiprotein nanopore has been fabricated using components from all three domains of life. This molecular machine opens the door to two approaches in single-molecule protein analysis, in which selected substrate proteins are unfolded, fed to into the proteasomal chamber and then processed either as fragmented peptides or intact polypeptides.

Published
2021

10. A Practical View of the Martini Force Field

Author

Bart M H, Bruininks, Paulo C T, Souza, and Siewert J, Marrink

Subjects
Models, Molecular, Lipid Bilayers, Thermodynamics, Water, Guidelines as Topic, DNA, Molecular Dynamics Simulation
Abstract

Martini is a coarse-grained (CG) force field suitable for molecular dynamics (MD) simulations of (bio)molecular systems. It is based on mapping of two to four heavy atoms to one CG particle. The effective interactions between the CG particles are parametrized to reproduce partitioning free energies of small chemical compounds between polar and apolar phases. In this chapter, a summary of the key elements of this CG force field is presented, followed by an example of practical application: a lipoplex-membrane fusion experiment. Formulated as hands-on practice, this chapter contains guidelines to build CG models of important biological systems, such as asymmetric bilayers and double-stranded DNA. Finally, a series of notes containing useful information, limitations, and tips are described in the last section.

Published
2019

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