A Monte Carlo simulation of a protein (CoVE) in a matrix of random barriers

Monte Carlo simulations are performed to study structure and dynamics of a protein CoVE in random media generated by a random distribution of barriers at concentration c with a coarse-grained model in its native (low temperature) and denatured (high temperature) phase. The stochastic dynamics of the...

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Bibliographic Details
Published in:Physica A 2021-06, Vol.572, p.125896, Article 125896
Main Author: Pandey, R.B.
Format: Article
Language:English
Subjects:
Coarse-grained model
Corona virus envelope protein
Globular
Monte Carlo simulation
Protein
Random coil
Random media
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Summary:Monte Carlo simulations are performed to study structure and dynamics of a protein CoVE in random media generated by a random distribution of barriers at concentration c with a coarse-grained model in its native (low temperature) and denatured (high temperature) phase. The stochastic dynamics of the protein is diffusive in denature phase at low c, it slows down on increasing c and stops moving beyond a threshold (cth≈ 0.10). In native phase, the protein moves extremely slow at low c but speeds up on further increasing c in a characteristic range (c =0.10–0.20) before getting trapped at high c (cth≈ 0.30). The radius of gyration (Rg) of CoVE shows different non-monotonic dependence on c (increase followed by decay) in native and denature phase with a higher and sharper rate of change in former. Effective dimension (D) of CoVE is estimated from the scaling of structure factor: in denatured phase, D≈2 (a random coil conformation) at low c (= 0.01–0.10) with appearance of some globularization i.e. D≈2.3, 2.5 at higher c (= 0.2, 0.3). Increasing c seems to reduce the globularity (D≈3) of CoVE in native phase. •Effect of barriers (with concentration c) on CoVE protein is critical in COVID.•Conformational response is non-monotonic, different in native and denature phase.•Native and denature structures have different thresholds for global transport.•Barriers enhance dynamics of native structures in a characteristic range of c.•Barriers enforce globularization in denature phase in a characteristic range of c.
ISSN:0378-4371
1873-2119
DOI:10.1016/j.physa.2021.125896