Translocation, Rejection and Trapping of Polyampholytes

Author:

Kim Yeong-Beom,Chae Min-Kyung,Park Jeong-Man,Johner AlbertORCID,Lee Nam-KyungORCID

Abstract

Polyampholytes (PA) are a special class of polymers comprising both positive and negative monomers along their sequence. Most proteins have positive and negative residues and are PAs. Proteins have a well-defined sequence while synthetic PAs have a random charge sequence. We investigated the translocation behavior of random polyampholyte chains through a pore under the action of an electric field by means of Monte Carlo simulations. The simulations incorporated a realistic translocation potential profile along an extended asymmetric pore and translocation was studied for both directions of engagement. The study was conducted from the perspective of statistics for disordered systems. The translocation behavior (translocation vs. rejection) was recorded for all 220 sequences comprised of N = 20 charged monomers. The results were compared with those for 107 random sequences of N = 40 to better demonstrate asymptotic laws. At early times, rejection was mainly controlled by the charge sequence of the head part, but late translocation/rejection was governed by the escape from a trapped state over an antagonistic barrier built up along the sequence. The probability distribution of translocation times from all successful attempts revealed a power-law tail. At finite times, there was a population of trapped sequences that relaxed very slowly (logarithmically) with time. If a subensemble of sequences with prescribed net charge was considered the power-law decay was steeper for a more favorable net charge. Our findings were rationalized by theoretical arguments developed for long chains. We also provided operational criteria for the translocation behavior of a sequence, explaining the selection by the translocation process. From the perspective of protein translocation, our findings can help rationalize the behavior of intrinsically disordered proteins (IDPs), which can be modeled as polyampholytes. Most IDP sequences have a strong net charge favoring translocation. Even for sequences with those large net charges, the translocation times remained very dispersed and the translocation was highly sequence-selective.

Funder

National Research Foundation of Korea

Publisher

MDPI AG

Subject

Polymers and Plastics,General Chemistry

Cited by 3 articles. 订阅此论文施引文献 订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献

1. Translocation of Hydrophobic Polyelectrolytes under Electrical Field: Molecular Dynamics Study;Polymers;2023-05-31

2. Conformational Behavior of Polyampholytes Grafted onto Spherical Particles;2022 IEEE International Conference on Manipulation, Manufacturing and Measurement on the Nanoscale (3M-NANO);2022-08-08

3. Polymer Dynamics: Bulk and Nanoconfined Polymers;Polymers;2022-03-22

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