Statistical mechanics of aggregation and crystallization for semiflexible polymers

Junghans, Christoph; Bachmann, Michael; Janke, Wolfhard

doi:10.1209/0295-5075/87/40002

Cited by 38 publications

(44 citation statements)

References 18 publications

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“…The influence of density on the aggregation a) zierenberg@itp.uni-leipzig.de b) mueller@itp.uni-leipzig.de c) schierz@itp.uni-leipzig.de d) marenz@itp.uni-leipzig.de e) janke@itp.uni-leipzig.de transition of two lattice proteins has been noticed recently 18 to be similar to that on an ideal gas. In this study we will extend this observation by investigating an off-lattice polymer model that has been successfully applied to peptide 19 and polymer aggregation 20,21 before. Focusing on the case of flexible homopolymers, we will provide entropic arguments for the density dependence and energetic arguments for finite-size effects which leads to a reasonable description of the density dependence in a spherical confinement.…”

Section: Introductionmentioning

confidence: 87%

Aggregation of theta-polymers in spherical confinement

Zierenberg

Mueller

Schierz

et al. 2014

The Journal of Chemical Physics

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We investigate the aggregation transition of theta polymers in spherical confinement with multicanonical simulations. This allows for a systematic study of the effect of density on the aggregation transition temperature for up to 24 monodisperse polymers. Our results for solutions in the dilute regime show that polymers can be considered isolated for all temperatures larger than the aggregation temperature, which is shown to be a function of the density. The resulting competition between single-polymer collapse and aggregation yields the lower temperature bound of the isolated chain approximation. We provide entropic and energetic arguments to describe the density dependence and finite-size effects of the aggregation transition for monodisperse solutions in finite systems. This allows us to estimate the aggregation transition temperature of dilute systems in a spherical cavity, using a few simulations of small, sufficiently dilute polymer systems.

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Section: Introductionmentioning

confidence: 87%

Aggregation of theta-polymers in spherical confinement

Zierenberg

Mueller

Schierz

et al. 2014

The Journal of Chemical Physics

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“…This is in contrast to the directed or semiflexible approaches to study binding and allows one to compare to the uncorrelated motifs that originate within aggregation of flexible polymers [15]. We notice that there has been a somewhat equivalent use of the terms aggregation [23,24,25] and binding [7,8]. Here, we refer to binding as the process of two polymers attaching to each other, in our case even flexible polymers.…”

Section: Introductionmentioning

confidence: 99%

Effect of grafting on the binding transition of two flexible polymers

Zierenberg

Tholen

Janke

2017

Eur. Phys. J. Spec. Top.

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We investigate the binding transition of two flexible polymers grafted to a steric surface with closeby end points. While free polymers show a discontinuous transition, grafting to a steric flat surface leads to a continuous binding transition. This is supported by results from Metropolis and parallel multicanonical simulations. A combination of canonical and microcanonical analyses reveals that the change in transition order can be understood in terms of the reduced translational entropy of the unbound high-temperature phase upon grafting. a

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“…Compared to the canonical runs, we find that the tunneling frequency, on average, is a factor 2.8 higher in the 1/γ -ensemble simulations, where intermediate energies are not statistically suppressed. The tunneling frequency is a key figure when studying surface effects 16,42 and properties that strongly depend on the relative population of the coexisting states, such as the heat capacity.…”

Section: Resultsmentioning

confidence: 99%

Accelerating atomic-level protein simulations by flat-histogram techniques

Jónsson

Mohanty

Irbäck

2011

The Journal of Chemical Physics

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Flat-histogram techniques provide a powerful approach to the simulation of first-order-like phase transitions and are potentially very useful for protein studies. Here, we test this approach by implicit solvent all-atom Monte Carlo (MC) simulations of peptide aggregation, for a 7-residue fragment (GIIFNEQ) of the Cu/Zn superoxide dismutase 1 protein (SOD1). In simulations with 8 chains, we observe two distinct aggregated/non-aggregated phases. At the midpoint temperature, these phases coexist, separated by a free-energy barrier of height 2.7 k B T . We show that this system can be successfully studied by carefully implemented flat-histogram techniques. The frequency of barrier crossing, which is low in conventional canonical simulations, can be increased by turning to a two-step procedure based on the Wang-Landau and multicanonical algorithms.

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Statistical mechanics of aggregation and crystallization for semiflexible polymers

Cited by 38 publications

References 18 publications

Aggregation of theta-polymers in spherical confinement

Aggregation of theta-polymers in spherical confinement

Effect of grafting on the binding transition of two flexible polymers

Accelerating atomic-level protein simulations by flat-histogram techniques

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