Emerging Silk Material Trends: Repurposing, Phase Separation and Solution-Based Designs

Silk continues to amaze. This review unravels the most recent progress in silk science, spanning from fundamental insights to medical silks. Key advances in silk flow are examined, with specific reference to the role of metal ions in switching silk from a storage to a spinning state. Orthogonal thermoplastic silk molding is described, as is the transfer of silk flow principles for the triggering of flow-induced crystallization in other non-silk polymers. Other exciting new developments include silk-inspired liquid–liquid phase separation for non-canonical fiber formation and the creation of “silk organelles” in live cells. This review closes by examining the role of silk fabrics in fashioning facemasks in response to the SARS-CoV-2 pandemic.

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Deciphering the Role of π-Interactions in Polyelectrolyte Complexes Using Rationally Designed Peptides

Polymers ◽

10.3390/polym13132074 ◽

2021 ◽

Vol 13 (13) ◽

pp. 2074

Author(s):

Sara Tabandeh ◽

Cristina Elisabeth Lemus ◽

Lorraine Leon

Keyword(s):

Hydrogen Bonding ◽

Phase Separation ◽

Liquid Phase ◽

Charge Density ◽

Secondary Structures ◽

Liquid Phase Separation ◽

Polyelectrolyte Complexes ◽

Π Interactions ◽

Liquid Liquid Phase Separation

Electrostatic interactions, and specifically π-interactions play a significant role in the liquid-liquid phase separation of proteins and formation of membraneless organelles/or biological condensates. Sequence patterning of peptides allows creating protein-like structures and controlling the chemistry and interactions of the mimetic molecules. A library of oppositely charged polypeptides was designed and synthesized to investigate the role of π-interactions on phase separation and secondary structures of polyelectrolyte complexes. Phenylalanine was chosen as the π-containing residue and was used together with lysine or glutamic acid in the design of positively or negatively charged sequences. The effect of charge density and also the substitution of fluorine on the phenylalanine ring, known to disrupt π-interactions, were investigated. Characterization analysis using MALDI-TOF mass spectroscopy, H NMR, and circular dichroism (CD) confirmed the molecular structure and chiral pattern of peptide sequences. Despite an alternating sequence of chirality previously shown to promote liquid-liquid phase separation, complexes appeared as solid precipitates, suggesting strong interactions between the sequence pairs. The secondary structures of sequence pairs showed the formation of hydrogen-bonded structures with a β-sheet signal in FTIR spectroscopy. The presence of fluorine decreased hydrogen bonding due to its inhibitory effect on π-interactions. π-interactions resulted in enhanced stability of complexes against salt, and higher critical salt concentrations for complexes with more π-containing amino acids. Furthermore, UV-vis spectroscopy showed that sequences containing π-interactions and increased charge density encapsulated a small charged molecule with π-bonds with high efficiency. These findings highlight the interplay between ionic, hydrophobic, hydrogen bonding, and π-interactions in polyelectrolyte complex formation and enhance our understanding of phase separation phenomena in protein-like structures.

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Liquid–liquid phase separation in human health and diseases

Signal Transduction and Targeted Therapy ◽

10.1038/s41392-021-00678-1 ◽

2021 ◽

Vol 6 (1) ◽

Author(s):

Bin Wang ◽

Lei Zhang ◽

Tong Dai ◽

Ziran Qin ◽

Huasong Lu ◽

...

Keyword(s):

Phase Separation ◽

Liquid Phase ◽

Human Health ◽

Essential Role ◽

Current Knowledge ◽

Vital Role ◽

Liquid Phase Separation ◽

Eukaryotic Cells ◽

Liquid Liquid Phase Separation

AbstractEmerging evidence suggests that liquid–liquid phase separation (LLPS) represents a vital and ubiquitous phenomenon underlying the formation of membraneless organelles in eukaryotic cells (also known as biomolecular condensates or droplets). Recent studies have revealed evidences that indicate that LLPS plays a vital role in human health and diseases. In this review, we describe our current understanding of LLPS and summarize its physiological functions. We further describe the role of LLPS in the development of human diseases. Additionally, we review the recently developed methods for studying LLPS. Although LLPS research is in its infancy—but is fast-growing—it is clear that LLPS plays an essential role in the development of pathophysiological conditions. This highlights the need for an overview of the recent advances in the field to translate our current knowledge regarding LLPS into therapeutic discoveries.

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Taurine suppresses liquid-liquid phase separation of lysozyme protein

10.1101/2021.01.26.428332 ◽

2021 ◽

Author(s):

Kanae Tsubotani ◽

Sayuri Maeyama ◽

Shigeru Murakami ◽

Stephen W Schaffer ◽

Takashi Ito

Keyword(s):

Phase Separation ◽

Polyethylene Glycol ◽

Critical Temperature ◽

Liquid Phase ◽

Liquid Phase Separation ◽

Compatible Osmolyte ◽

Hen Egg ◽

Liquid Liquid Phase Separation ◽

In Cells

AbstractTaurine is a compatible osmolyte that infers stability to proteins. Recent studies have revealed that liquid-liquid phase separation (LLPS) of proteins underlie the formation of membraneless organelles in cells. In the present study, we evaluated the role of taurine on LLPS of hen egg lysozyme. We demonstrated that taurine decreases the turbidity of the polyethylene glycol-induced crowding solution of lysozyme. We also demonstrated that taurine attenuates LLPS-dependent cloudiness of lysozyme solution with 0.5 or 1M NaCl at a critical temperature. Moreover, we observed that taurine inhibits LLPS formation of a heteroprotein mix solution of lysozyme and ovalbumin. These data indicate that taurine can modulate the formation of LLPS of proteins.

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Mechanical frustration of phase separation in the cell nucleus by chromatin

10.1101/2020.12.24.424222 ◽

2020 ◽

Author(s):

Yaojun Zhang ◽

Daniel S.W. Lee ◽

Yigal Meir ◽

Clifford P. Brangwynne ◽

Ned S. Wingreen

Keyword(s):

Phase Separation ◽

Liquid Phase ◽

Cell Nucleus ◽

Mechanical Environment ◽

Coarsening Dynamics ◽

The Impact ◽

Droplet Phase ◽

Liquid Liquid Phase Separation ◽

Fundamental Mechanism

Liquid-liquid phase separation is a fundamental mechanism underlying subcellular organization. Motivated by the striking observation that optogenetically-generated droplets in the nucleus display suppressed coarsening dynamics, we study the impact of chromatin mechanics on droplet phase separation. We combine theory and simulation to show that crosslinked chromatin can mechanically suppress droplets’ coalescence and ripening, as well as quantitatively control their number, size, and placement. Our results highlight the role of the subcellular mechanical environment on condensate regulation.

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Bi-directional protein-protein interactions control liquid-liquid phase separation of PSD-95 and its interaction partners

10.1101/2021.03.03.433781 ◽

2021 ◽

Author(s):

Nikolaj Riis Christensen ◽

Christian Parsbæk Pedersen ◽

Vita Sereikaite ◽

Jannik Nedergaard Pedersen ◽

Maria Vistrup-Parry ◽

...

Keyword(s):

Phase Separation ◽

Liquid Phase ◽

Protein Interactions ◽

Postsynaptic Density ◽

Specific Protein ◽

Liquid Phase Separation ◽

Protein Protein Interactions ◽

New Perspective ◽

Liquid Liquid Phase Separation

SUMMARYThe organization of the postsynaptic density (PSD), a protein-dense semi-membraneless organelle, is mediated by numerous specific protein-protein interactions (PPIs) which constitute a functional post-synapse. Postsynaptic density protein 95 (PSD-95) interacts with a manifold of proteins, including the C-terminal of transmembrane AMPA receptor (AMAPR) regulatory proteins (TARPs). Here, we uncover the minimal essential peptide responsible for the stargazin (TARP-γ2) mediated liquid-liquid phase separation (LLPS) formation of PSD-95 and other key protein constituents of the PSD. Furthermore, we find that pharmacological inhibitors of PSD-95 can facilitate formation of LLPS. We found that in some cases LLPS formation is dependent on multivalent interactions while in other cases short peptides carrying a high charge are sufficient to promote LLPS in complex systems. This study offers a new perspective on PSD-95 interactions and their role in LLPS formation, while also considering the role of affinity over multivalency in LLPS systems.

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Liquid–liquid phase separation of tau protein: The crucial role of electrostatic interactions

Journal of Biological Chemistry ◽

10.1074/jbc.ac119.009198 ◽

2019 ◽

Vol 294 (29) ◽

pp. 11054-11059 ◽

Cited By ~ 35

Author(s):

Solomiia Boyko ◽

Xu Qi ◽

Tien-Hao Chen ◽

Krystyna Surewicz ◽

Witold K. Surewicz

Keyword(s):

Phase Separation ◽

Liquid Phase ◽

Tau Protein ◽

Crucial Role ◽

Electrostatic Interactions ◽

Liquid Phase Separation ◽

Liquid Liquid Phase Separation

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Liquid–Liquid Phase Separation in Crowded Environments

International Journal of Molecular Sciences ◽

10.3390/ijms21165908 ◽

2020 ◽

Vol 21 (16) ◽

pp. 5908 ◽

Cited By ~ 4

Author(s):

Alain A. M. André ◽

Evan Spruijt

Keyword(s):

Phase Separation ◽

Liquid Phase ◽

Macromolecular Crowding ◽

Liquid Phase Separation ◽

The Impact ◽

Crowded Environments ◽

Liquid Liquid Phase Separation ◽

In Cells

Biomolecular condensates play a key role in organizing cellular fluids such as the cytoplasm and nucleoplasm. Most of these non-membranous organelles show liquid-like properties both in cells and when studied in vitro through liquid–liquid phase separation (LLPS) of purified proteins. In general, LLPS of proteins is known to be sensitive to variations in pH, temperature and ionic strength, but the role of crowding remains underappreciated. Several decades of research have shown that macromolecular crowding can have profound effects on protein interactions, folding and aggregation, and it must, by extension, also impact LLPS. However, the precise role of crowding in LLPS is far from trivial, as most condensate components have a disordered nature and exhibit multiple weak attractive interactions. Here, we discuss which factors determine the scope of LLPS in crowded environments, and we review the evidence for the impact of macromolecular crowding on phase boundaries, partitioning behavior and condensate properties. Based on a comparison of both in vivo and in vitro LLPS studies, we propose that phase separation in cells does not solely rely on attractive interactions, but shows important similarities to segregative phase separation.

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Charge-Driven Condensation of RNA and Proteins Suggests Broad Role of Phase Separation in Cytoplasmic Environments

10.1101/2020.04.23.057901 ◽

2020 ◽

Author(s):

Bercem Dutagaci ◽

Grzegorz Nawrocki ◽

Joyce Goodluck ◽

Ali Akbar Ashkarran ◽

Charles G. Hoogstraten ◽

...

Keyword(s):

Phase Separation ◽

Liquid Phase ◽

Molecular Size ◽

Liquid Phase Separation ◽

Coarse Grained ◽

Biological Macromolecules ◽

Separation Processes ◽

Cellular Environment ◽

Liquid Liquid Phase Separation

ABSTRACTPhase separation processes are increasingly being recognized as important organizing mechanisms of biological macromolecules in cellular environments. Well established drivers of liquid-liquid phase separation are multi-valency and intrinsic disorder. Here, we show that globular macromolecules may condense simply based on electrostatic complementarity. More specifically, phase separation of mixtures between RNA and positively charged proteins is described from a combination of multiscale computer simulations with microscopy and spectroscopy experiments. Condensates retain liquid character and phase diagrams are mapped out as a function of molecular concentrations in experiment and as a function of molecular size and temperature via simulations. The results suggest a more general principle for phase separation that is based primarily on electrostatic complementarity without invoking polymer properties as in most previous studies. Simulation results furthermore suggest that such phase separation may occur widely in heterogenous cellular environment between nucleic acid and protein components.STATEMENT OF SIGNIFICANCELiquid-liquid phase separation has been recognized as a key mechanism for forming membrane-less organelles in cells. Commonly discussed mechanisms invoke a role of disordered peptides and specific multi-valent interactions. We report here phase separation of RNA and proteins based on a more universal principle of charge complementarity that does not require disorder or specific interactions. The findings are supported by coarse-grained simulations, theory, and experimental validation via microscopy and spectroscopy. The broad implication of this work is that condensate formation may be a universal phenomenon in biological systems.

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The Role of Methionine Residues in the Regulation of Liquid-Liquid Phase Separation

Biomolecules ◽

10.3390/biom11081248 ◽

2021 ◽

Vol 11 (8) ◽

pp. 1248

Author(s):

Juan Carlos Aledo

Keyword(s):

Phase Separation ◽

Liquid Phase ◽

Low Complexity ◽

Liquid Phase Separation ◽

Modular Architecture ◽

Residue Interaction ◽

Methionine Residues ◽

Molecular Forces ◽

Liquid Liquid Phase Separation

Membraneless organelles are non-stoichiometric supramolecular structures in the micron scale. These structures can be quickly assembled/disassembled in a regulated fashion in response to specific stimuli. Membraneless organelles contribute to the spatiotemporal compartmentalization of the cell, and they are involved in diverse cellular processes often, but not exclusively, related to RNA metabolism. Liquid-liquid phase separation, a reversible event involving demixing into two distinct liquid phases, provides a physical framework to gain insights concerning the molecular forces underlying the process and how they can be tuned according to the cellular needs. Proteins able to undergo phase separation usually present a modular architecture, which favors a multivalency-driven demixing. We discuss the role of low complexity regions in establishing networks of intra- and intermolecular interactions that collectively control the phase regime. Post-translational modifications of the residues present in these domains provide a convenient strategy to reshape the residue–residue interaction networks that determine the dynamics of phase separation. Focus will be placed on those proteins with low complexity domains exhibiting a biased composition towards the amino acid methionine and the prominent role that reversible methionine sulfoxidation plays in the assembly/disassembly of biomolecular condensates.

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Granule regulation by phase separation during Drosophila oogenesis

Emerging Topics in Life Sciences ◽

10.1042/etls20190155 ◽

2020 ◽

Vol 4 (3) ◽

pp. 355-364

Author(s):

M. Sankaranarayanan ◽

Timothy T. Weil

Keyword(s):

Phase Separation ◽

Translational Control ◽

Protein Complexes ◽

Physiological Role ◽

Drosophila Oogenesis ◽

And Function ◽

Rna Protein Complexes ◽

Liquid Liquid Phase Separation

Drosophila eggs are highly polarised cells that use RNA–protein complexes to regulate storage and translational control of maternal RNAs. Ribonucleoprotein granules are a class of biological condensates that form predominantly by intracellular phase separation. Despite extensive in vitro studies testing the physical principles regulating condensates, how phase separation translates to biological function remains largely unanswered. In this perspective, we discuss granules in Drosophila oogenesis as a model system for investigating the physiological role of phase separation. We review key maternal granules and their properties while highlighting ribonucleoprotein phase separation behaviours observed during development. Finally, we discuss how concepts and models from liquid–liquid phase separation could be used to test mechanisms underlying granule assembly, regulation and function in Drosophila oogenesis.

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