Molecular dynamics simulation on regulation of liquid–liquid phase separation of repetitive peptides

Understanding the intricate interactions governing protein and peptide behavior in liquid–liquid phase separation (LLPS) is crucial for unraveling biological functions and dysfunctions. This study employs a residue-leveled coarse-grained molecular dynamics approach to simulate the phase separation o...

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Vydáno v:	Scientific reports Ročník 14; číslo 1; s. 13382 - 10
Hlavní autoři:	Yang, Xiaojun, Wang, Yanwei, Yang, Guangcan
Médium:	Journal Article
Jazyk:	angličtina
Vydáno:	London Nature Publishing Group UK 11.06.2024 Nature Publishing Group Nature Portfolio
Témata:	631/57/2266 631/57/2269 631/57/2272 Dielectric constant DNA - chemistry DNA - metabolism Electrostatic interaction Electrostatic properties GENESIS Humanities and Social Sciences Hydrophobic and Hydrophilic Interactions Hydrophobicity Liquid–liquid phase separation Molecular dynamics Molecular Dynamics Simulation multidisciplinary Peptides Peptides - chemistry Phase Separation Phase Transition Polypeptides Polyproline Salts Science Science (multidisciplinary) Temperature Temperature effects Liquid–liquid phase separation Molecular dynamics Polypeptides Hydrophobicity GENESIS Electrostatic interaction
ISSN:	2045-2322, 2045-2322
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Shrnutí:	Understanding the intricate interactions governing protein and peptide behavior in liquid–liquid phase separation (LLPS) is crucial for unraveling biological functions and dysfunctions. This study employs a residue-leveled coarse-grained molecular dynamics approach to simulate the phase separation of repetitive polyproline and polyarginine peptides (poly PR) with varying lengths and sequences in solution, considering different concentrations and temperatures. Our findings highlight the crucial role of sequence order in promoting LLPS in peptides with identical lengths of repetitive sequences. Interestingly, repetitive peptides containing fewer than 10 polyarginine repeats exhibit no LLPS, even at salt concentrations up to 3 M. Notably, our simulations align with experimental observations, pinpointing a salt concentration of 2.7 M for PR25-induced LLPS. Utilizing the same methodology, we predict the required salt concentrations for LLPS induction as 1.2 M, 1.5 M, and 2.7 M for PR12, PR15, and PR35, respectively. These predictions demonstrate good agreement with experimental results. Extending our investigation to include the peptide glutamine and arginine (GR15) in DNA solution, our simulations mirror experimental observations of phase separation. To unveil the molecular forces steering peptide phase separation, we introduce a dielectric constant modifier and hydrophobicity disruptor into poly PR systems. Our coarse-grained analysis includes an examination of temperature effects, leading to the inference that both hydrophobic and electrostatic interactions drive phase separation in peptide systems.
Bibliografie:	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 14 content type line 23
ISSN:	2045-2322 2045-2322
DOI:	10.1038/s41598-024-64327-7