Tuning Formation of Protein–DNA Coacervates by Sequence and Environment

Lebold, Kathryn M.; Best, Robert B.

doi:10.1021/acs.jpcb.2c00424

Cited by 15 publications

(17 citation statements)

References 104 publications

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“…No condensates were observed for polyA5 for peptides as long as [RGRGG]15, also suggesting a minimal RNA length, but the peptide length was not extended beyond 75 amino acids. These simulations are generally in agreement with previous computational works on RNA [21][22][23] and DNA 24 showing LLPS is enhanced with longer nucleic acids lengths.…”

Section: Introductionsupporting

confidence: 92%

The Effect of Polymer Length in Phase Separation

Valdés-García

Gamage

Smith

et al. 2022

Preprint

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Understanding the thermodynamics that drives liquid-liquid phase separation (LLPS) is quite important given the many numbers of diverse biomolecular systems undergoing this phenomenon. Regardless of the diversity, the processes underlying the formation of condensates exhibit physical similarities. Many studies have focused on condensates of long polymers, but very few systems of short polymer condensates have been observed and yet studied. Here we study a short polymer system of various lengths of poly-Adenine RNA and peptide formed by the RGRGG sequence repeats to understand the underlying thermodynamics of LLPS. We carried out MD simulations using the recently developed COCOMO coarse-grained (CG) model which revealed the possibility of condensates for lengths as short as 5-10 residues, which was then confirmed by experiment, making this one of the smallest LLPS systems yet observed. Condensation depends on polymer length and concentration, and phase boundaries were identified. A free energy model was also developed. Results show that the length dependent condensation is driven solely by entropy of confinement and identifies a negative free energy (-ΔG) of phase separation, indicating the stability of the condensates. The simplicity of this system will provide the basis for understanding more biologically realistic systems.

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Section: Introductionsupporting

confidence: 92%

The Effect of Polymer Length in Phase Separation

Valdés-García

Gamage

Smith

et al. 2022

Preprint

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“… This approach made it possible to determine critical temperatures and dense and dilute phase protein concentrations, which showed agreement with theoretical descriptions of polymer phase transitions from Flory–Huggins theory. − Since the development of this coarse-graining framework, additional experimental data and atomistic simulations have been used to develop alternative residue-resolution coarse-grained models that aim to achieve quantitative agreement with experimental phase diagrams. ,,− The improved coarse-grained models can now quantitatively determine saturation concentrations ,, and account for the effects of a range of temperatures and salt concentrations . These models have been used in a variety of investigations of phase separated systems, including to identify the interactions driving and sustaining phase separation of the FUS low-complexity domain, to understand salt-dependence in interactions driving phase separation, and to look at the effect of condensate aging on material properties and dense phase interactions. , Coarse-grained models of nucleic acids have also made it possible to use simulations to look at protein–DNA interactions, including interactions between highly charged proteins and DNA in condensates, the interplay of H1, HP1 and DNA, to investigate the interactions driving phase separation of chromatin-associated proteins and its role in chromatin organization, and as part of a multiscale model of chromatin (Figure ). …”

Section: Simulationsmentioning

confidence: 99%

Section: Simulationsmentioning

confidence: 99%

“…120 These models have been used in a variety of investigations of phase separated systems, including to identify the interactions driving and sustaining phase separation of the FUS low-complexity domain, 124 to understand salt-dependence in interactions driving phase separation, 99 and to look at the effect of condensate aging on material properties and dense phase interactions. 102,103 Coarse-grained models of nucleic acids have also made it possible to use simulations to look at protein− DNA interactions, including interactions between highly charged proteins and DNA in condensates, 125 the interplay of H1, HP1 and DNA, 126 to investigate the interactions driving phase separation of chromatin-associated proteins and its role in chromatin organization, and as part of a multiscale model of chromatin (Figure 5). 127 Coarse-grained models also can be made more computationally efficient by confining molecular movements to a lattice as implemented in the LASSI model.…”

Section: Detailed Models Limit Simulationmentioning

confidence: 99%

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Theoretical and Data-Driven Approaches for Biomolecular Condensates

Saar

Qian

et al. 2023

Chem. Rev.

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Biomolecular condensation processes are increasingly recognized as a fundamental mechanism that living cells use to organize biomolecules in time and space. These processes can lead to the formation of membraneless organelles that enable cells to perform distinct biochemical processes in controlled local environments, thereby supplying them with an additional degree of spatial control relative to that achieved by membranebound organelles. This fundamental importance of biomolecular condensation has motivated a quest to discover and understand the molecular mechanisms and determinants that drive and control this process. Within this molecular viewpoint, computational methods can provide a unique angle to studying biomolecular condensation processes by contributing the resolution and scale that are challenging to reach with experimental techniques alone. In this Review, we focus on three types of dry-lab approaches: theoretical methods, physicsdriven simulations and data-driven machine learning methods. We review recent progress in using these tools for probing biomolecular condensation across all three fields and outline the key advantages and limitations of each of the approaches. We further discuss some of the key outstanding challenges that we foresee the community addressing next in order to develop a more complete picture of the molecular driving forces behind biomolecular condensation processes and their biological roles in health and disease.

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“…27,32 There are ongoing efforts to develop and evaluate a nucleic acid (DNA/RNA) CG model to study protein-nucleic acid interactions and the role DNA plays in LLPS. [57][58][59][60] Here, we use a model that separates the nucleotide into two beads; one bead represents the sugar-phosphate backbone, carrying an overall -1 charge, and the other represents the base but differentiates between bases ADE, THY, CYT, and GUA in their respective stacking and hydrogen bonding interactions. Using our CG nucleic acid model, we studied the effects of DNA addition on the LLPS of HP1α by conducting CG coexistence simulations of HP1α homodimers containing a small mole fraction of 205 bp dsDNA, 0.02 and 0.038, at 320 K. This system can be reasonably compared to an experimental system containing 50µM/100 µM of HP1α with 1.5µM of the same 205 bp dsDNA.…”

Section: Computational Studies Of Hp1α Llps In the Presence Of Dnamentioning

confidence: 99%

Molecular interactions underlying the phase separation of HP1α: Role of phosphorylation, ligand and nucleic acid binding

Her

Phan

Jovic

et al. 2022

Preprint

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Heterochromatin protein 1α (HP1α) is a crucial component for the proper maintenance of chromatin structure and function. It has been proposed that HP1α functions through liquid-liquid phase separation (LLPS), which allows it to sequester and compact chromatin into transcriptionally repressed heterochromatin regions. In vitro, HP1α can form phase separated liquid droplets upon phosphorylation of its N-terminus extension (NTE) and/or through interactions with DNA and chromatin. While it is known that LLPS requires homodimerization of HP1α and that it involves interactions between the positively charged hinge region of HP1α and the negatively charged phosphorylated NTE or nucleic acid, the precise molecular details of this process and its regulation are still unclear. Here, we combine computational modeling and experimental approaches to elucidate the phase separation properties of HP1α under phosphorylation-driven and DNA-driven LLPS conditions. We also tune these properties using peptides from four HP1α binding partners (Sgo1, CAF-1, LBR, and H3). In phosphorylation-driven LLPS, HP1α can exchange intradimer hinge-NTE interactions with interdimer contacts, which also leads to a structural change from a compacted to an extended HP1α dimer conformation. This process can be enhanced by the presence of positively charged peptide ligands such as Sgo1 and H3 and disrupted by the addition of negatively charged or neutral peptides such as LBR and CAF-1. In DNA-driven LLPS, both positively and negatively charged peptide ligands can perturb phase separation. Our findings demonstrate the importance of electrostatic interactions in the LLPS of HP1α where binding partners can modulate the overall charge of the droplets and screen or enhance hinge region interactions through specific and non-specific effects. Our study illuminates the complex molecular framework that can fine tune the properties of HP1α and that can contribute to heterochromatin regulation and function.

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Tuning Formation of Protein–DNA Coacervates by Sequence and Environment

Cited by 15 publications

References 104 publications

The Effect of Polymer Length in Phase Separation

The Effect of Polymer Length in Phase Separation

Theoretical and Data-Driven Approaches for Biomolecular Condensates

Molecular interactions underlying the phase separation of HP1α: Role of phosphorylation, ligand and nucleic acid binding

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