Understanding and Fine Tuning the Propensity of ATP-Driven Liquid-Liquid Phase Separation with Oligolysine

30 January 2024, Version 2
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

Liquid-Liquid Phase Separation (LLPS) plays pivotal roles in the organization and functionality of living cells. It is imperative to understand the underlying driving forces behind LLPS and to control its occurrence. In this study, we employed coarse-grained (CG) simulations as a research tool to investigate systems comprising oligolysine and adenosine triphosphate (ATP) under conditions of various ionic concentrations and oligolysine lengths. Consistent with experimental observations, our CG simulations captured the formation of LLPS upon the addition of ATP and tendency of dissociating under high ionic concentration. The primary driving force behind this phenomenon is the electrostatic interaction between oligolysine and ATP. An in-depth analysis on the structural properties of LLPS was conducted, where the oligolysine structure remained unchanged with increased ionic concentration and the addition of ATP led to a more pronounced curvature, aligning with the observed enhancement of $\alpha$-helical secondary structure in experiments. In terms of the dynamic properties, the introduction of ATP led to a significant reduction in translational and vibrational degrees of freedom but not rotational degrees of freedom. Through keeping the total number of charged residues constant and varying their entropic effects, we constructed two systems of similar biochemical significance and further validated the entropy effects on the LLPS formation. These findings provide a deeper understanding of LLPS formation and shed lights on the development of novel bioreactor and primitive artificial cells for synthesizing key chemicals for certain diseases.

Keywords

Coarse Grained
Molecular Dynamics
Liquid-Liquid Phase Separation
oligolysine
adenosine triphosphate

Supplementary materials

Title
Description
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Supporting Information
Description
System summary; Radius of gyration under different ionic concentrations; Radial Distribution Function on the effect of ATPs and ionic concentrations; Determination of the threshold distance; Diffusion Coefficient; Solvent Accessible Surface Area; Investigation of the preference for high flexibility; Propensity of LLPS formation when releasing entropy
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