Morphology Control of Hairy Nanopores

Peleg, Orit; Tagliazucchi, Mario; Kröger, Martin; Rabin, Yitzhak; Szleifer, Igal

doi:10.1021/nn200702u

Cited by 88 publications

(132 citation statements)

References 41 publications

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“…We attribute this discrepancy to the following: i) Difference in the modeled systems: The MD simulations are for a planar surface grafted with 100-aa-long FG-Nups, whereas we model the sequences of the FG-Nups determined for yeast grafted inside a pore that mimics the experimental size and shape of the yeast NPC. We have shown in previous work (27) that increasing chain length and decreasing the radius of curvature of the pore may disfavor the formation of chain aggregates in comparison to the homogeneous system. ii) MD simulations in the study by Miao and Schulten (22) are initialized in a fully stretched configuration of the 100-aa model FG-Nups and run for a few microseconds.…”

Section: Tagliazucchi Et Almentioning

confidence: 85%

“…We study the translocation of different model particles to elucidate the role of the different interactions in the system and understand their interplay. Our predictions are based on a molecular theory developed to study the structure, thermodynamics, and transport behavior of responsive polymers end-grafted to surfaces of arbitrary geometry (26,27) that is extended here to study the translocation of large particles through a nanopore, the NPC. The theory (Methods) is based on a free energy formulation that explicitly treats the size, shape, conformations, and charge state of all the molecular species and accounts for the nontrivial coupling between molecular organization, physical interactions, and chemical equilibrium.…”

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confidence: 99%

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Effect of charge, hydrophobicity, and sequence of nucleoporins on the translocation of model particles through the nuclear pore complex

Tagliazucchi

Peleg

Kröger

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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Fig. 2. Molecular organization of the yeast NPC. Total amino acid (aa) volume fraction (A and D), volume fraction of hydrophobic segments (B and E), and electrostatic potential (C and F) for the native and homogeneous model sequences (Fig. 1). The plots show that homogenizing the amino acid sequence affects the electrostatic potential but not the density of amino acids or the density of hydrophobic amino acids.

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Section: Tagliazucchi Et Almentioning

confidence: 85%

mentioning

confidence: 99%

Effect of charge, hydrophobicity, and sequence of nucleoporins on the translocation of model particles through the nuclear pore complex

Tagliazucchi

Peleg

Kröger

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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198

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“…At pH 2, the 4PVP chains are charged and therefore adopt rod-like conformations, reaching the center of the channel. At pH 10, the chains are uncharged and they collapse on the channel walls due to the hydrophobic interactions among pyridine segments [43]. Therefore, the polymer is homogeneously distributed inside the nanochannel in the open conductivity state, whereas the axis of the channel is free of polymer segments in the close state.…”

Section: Chemically Gated Ion Channelsmentioning

confidence: 99%

Transport mechanisms in nanopores and nanochannels: can we mimic nature?

2015

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The last few years have witnessed major advancements in the synthesis, modification, characterization and modeling of nanometer-size solid-state channels and pores. Future applications in sensing, energy conversion and purification technologies will critically rely on qualitative improvements in the control over the selectivity, directionality and responsiveness of these nanochannels and nanopores. It is not surprising, therefore, that researchers in the field seek inspiration in biological ion channels and ion pumps, paradigmatic examples of transport selectivity. This work reviews our current fundamental understanding of the mechanisms of transport of ions and larger cargoes through nanopores and nanochannels by examining recent experimental and theoretical work. It is argued that that structure and transport in biological channels and polyelectrolyte-modified synthetic nanopores are strongly coupled: the structure dictates transport and transport affects the structure. We compare synthetic and biological systems throughout this review to conclude that while they present interesting similarities, they also have striking differences.

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“…Still, a number of important applications were newly added in the recent past, including block copolymers and nanocomposites [53]; screening effects in polyelectrolyte brushes [54]; mixed polymer brushes [55]; harvesting cells cultured on thermoresponsive polymer brushes [56,57]; morphology control of hairy nanopores [58]; and the effect of charge, hydrophobicity and sequence of nucleoporins on the translocation of model particles through the nuclear pore complex [59]; to mention a few.…”

Section: Introductionmentioning

confidence: 99%

Challenges in Multiscale Modeling of Polymer Dynamics

et al. 2013

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The mechanical and physical properties of polymeric materials originate from the interplay of phenomena at different spatial and temporal scales. As such, it is necessary to adopt multiscale techniques when modeling polymeric materials in order to account for all important mechanisms. Over the past two decades, a number of different multiscale computational techniques have been developed that can be divided into three categories: (i) coarse-graining methods for generic polymers; (ii) systematic coarse-graining methods and (iii) multiple-scale-bridging methods. In this work, we discuss and compare eleven different multiscale computational techniques falling under these categories and assess them critically according to their ability to provide a rigorous link between polymer chemistry and rheological material properties. For each technique, the fundamental ideas and equations are introduced, and the most important results or predictions are shown and discussed. On the one hand, this review provides a comprehensive tutorial on multiscale computational techniques, which will be of interest to readers newly entering this field; on the other, it presents a critical discussion of the future opportunities and key challenges in the multiscale geometric mapping matrix between all-atomistic and coarse-grained models N number of monomers per chain N e entanglement length, which is the number of monomers between two entanglements n v number of polymer chains per unit volume n ij (n 0 (r ij )) entanglement number (at equilibrium) between particle pairs i and j p r , P R configurational probability distributions in all-atomistic and coarse-grained models, respectively R ee end-to-end distance of polymer chain R G radius of gyration of polymer chain s segment index/contour length variable along primitive chain S(q) single chain coherent dynamic scattering function Z number of entanglements per chain, defined as Z = N/N e α exponent in standard Mittag-Leffler function σ

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Morphology Control of Hairy Nanopores

Cited by 88 publications

References 41 publications

Effect of charge, hydrophobicity, and sequence of nucleoporins on the translocation of model particles through the nuclear pore complex

Effect of charge, hydrophobicity, and sequence of nucleoporins on the translocation of model particles through the nuclear pore complex

Transport mechanisms in nanopores and nanochannels: can we mimic nature?

Challenges in Multiscale Modeling of Polymer Dynamics

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