Linear aggregation of proteins on the membrane as a prelude to membrane remodeling

Šimunović, Mijo; Srivastava, Anand; Voth, Gregory A.

doi:10.1073/pnas.1309819110

Cited by 146 publications

(204 citation statements)

References 46 publications

(88 reference statements)

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“…Atomic and coarse-grained molecular simulations [40][41][42][43][44][45] have been employed to investigate molecular-scale interactions between BAR proteins and lipids. The scaffold formation [43] and linear assembly [44] of BAR domains have been demonstrated.…”

Section: Introductionmentioning

confidence: 99%

Shape deformation of lipid membranes by banana-shaped protein rods: Comparison with isotropic inclusions and membrane rupture

Noguchi

2016

Phys. Rev. E

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The assembly of curved protein rods on fluid membranes is studied using implicit-solvent meshless membrane simulations. As the rod curvature increases, the rods on a membrane tube assemble along the azimuthal direction first and subsequently along the longitudinal direction. Here, we show that both transition curvatures decrease with increasing rod stiffness. For comparison, curvature-inducing isotropic inclusions are also simulated. When the isotropic inclusions have the same bending rigidity as the other membrane regions, the inclusions are uniformly distributed on the membrane tubes and vesicles even for large spontaneous curvature of the inclusions. However, the isotropic inclusions with much larger bending rigidity induce shape deformation and are concentrated on the region of a preferred curvature. For high rod density, high rod stiffness, and/or low line tension of the membrane edge, the rod assembly induces vesicle rupture, resulting in the formation of a high-genus vesicle. A gradual change in the curvature suppresses this rupture. Hence, large stress, compared to the edge tension, induced by the rod assembly is the key factor determining rupture. For rod curvature with the opposite sign to the vesicle curvature, membrane rupture induces inversion of the membrane, leading to division into multiple vesicles as well as formation of a high-genus vesicle.

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Section: Introductionmentioning

confidence: 99%

Shape deformation of lipid membranes by banana-shaped protein rods: Comparison with isotropic inclusions and membrane rupture

Noguchi

2016

Phys. Rev. E

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“…Remodeling of the biomembrane is achievable by proteins [34] and nanoparticles [35], and it is a vital step in endocytosis and vesiculation [24]. Interestingly, in a system of spherical nano-particles on lipid membranes [35] different aggregation patterns have been induced by varying the membrane rigidity.…”

Section: Discussionmentioning

confidence: 99%

Rigidity of transmembrane proteins determines their cluster shape

2016

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Protein aggregation in cell membrane is vital for the majority of biological functions. Recent experimental results suggest that transmembrane domains of proteins such as α-helices and β-sheets have different structural rigidities. We use molecular dynamics simulation of a coarse-grained model of protein-embedded lipid membranes to investigate the mechanisms of protein clustering. For a variety of protein concentrations, our simulations under thermal equilibrium conditions reveal that the structural rigidity of transmembrane domains dramatically affects interactions and changes the shape of the cluster. We have observed stable large aggregates even in the absence of hydrophobic mismatch, which has been previously proposed as the mechanism of protein aggregation. According to our results, semi-flexible proteins aggregate to form two-dimensional clusters, while rigid proteins, by contrast, form one-dimensional string-like structures. By assuming two probable scenarios for the formation of a two-dimensional triangular structure, we calculate the lipid density around protein clusters and find that the difference in lipid distribution around rigid and semiflexible proteins determines the one-or two-dimensional nature of aggregates. It is found that lipids move faster around semiflexible proteins than rigid ones. The aggregation mechanism suggested in this paper can be tested by current state-of-the-art experimental facilities.

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“…When sufficient chemical information is retained, coarse-grained models can discriminate between different lipids and distinguish protein residues, and thus form a useful bridge between atomistic and macroscopic data. For instance, one can now simulate the collective lipid-mediated selfassembly of membrane proteins (Benjamini and Smit, 2013;Hall et al, 2012;Johnston et al, 2012;Periole et al, 2012;van den Bogaart et al, 2011) and their sorting between different membrane domains (de Jong et al, 2013;Janosi et al, 2012;Schäfer et al, 2011), as well as large-scale protein-induced membrane remodelling -including fusion and fission events (Baoukina and Tieleman, 2010;Braun et al, 2014;Davies et al, 2012;Fuhrmans and Müller, 2015;Kawamoto et al, 2015;Pinot et al, 2014;Risselada et al, 2014;Simunovic et al, 2013).…”

Section: Coarse-grain Resolutionmentioning

confidence: 99%

“…However, when carefully parameterized from higher-resolution models, semi-quantitative predictions can be made (Dama et al, 2013). Recent examples of the supra-coarse-grained approach include simulations of large-scale membrane remodelling by Bin-amphiphysin-Rvs (BAR) domains (Cui et al, 2013;Simunovic et al, 2013;Yu and Schulten, 2013), the membrane-induced formation of peptide fibrils (Morriss-Andrews et al, 2014) and the supra-molecular organization of photosynthetic membranes (Lee et al, 2015). Furthermore, the supra-coarse-grained approach allows for a natural connection to the macroscopic scale using, for instance, field-theory-or fluid-dynamics-based descriptions of cell membranes (Ayton et al, 2009;Camley and Brown, 2014;Fedosov et al, 2014;Yolcu et al, 2014).…”

Section: Supra Coarse-grain Resolutionmentioning

confidence: 99%

Computational ‘microscopy’ of cellular membranes

Ingólfsson

Arnarez²,

Periole³

et al. 2016

Journal of Cell Science

133

120

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Computational 'microscopy' refers to the use of computational resources to simulate the dynamics of a molecular system. Tuned to cell membranes, this computational 'microscopy' technique is able to capture the interplay between lipids and proteins at a spatiotemporal resolution that is unmatched by other methods. Recent advances allow us to zoom out from individual atoms and molecules to supramolecular complexes and subcellular compartments that contain tens of millions of particles, and to capture the complexity of the crowded environment of real cell membranes. This Commentary gives an overview of the main concepts of computational 'microscopy' and describes the state-of-the-art methods used to model cell membrane processes. We illustrate the power of computational modelling approaches by providing a few in-depth examples of largescale simulations that move up from molecular descriptions into the subcellular arena. We end with an outlook towards modelling a complete cell in silico.

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Linear aggregation of proteins on the membrane as a prelude to membrane remodeling

Cited by 146 publications

References 46 publications

Shape deformation of lipid membranes by banana-shaped protein rods: Comparison with isotropic inclusions and membrane rupture

Shape deformation of lipid membranes by banana-shaped protein rods: Comparison with isotropic inclusions and membrane rupture

Rigidity of transmembrane proteins determines their cluster shape

Computational ‘microscopy’ of cellular membranes

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