Controlling Liquid–Liquid Phase Separation of Cold-Adapted Crystallin Proteins from the Antarctic Toothfish

Bierma, Jan C.; Roskamp, Kyle; Ledray, Aaron P.; Kiss, Andor J.; Cheng, C.‐H. Christina; Martin, Rachel W.

doi:10.1016/j.jmb.2018.10.023

Cited by 18 publications

(23 citation statements)

References 81 publications

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“…These observations suggest that, in the microstructured RLP hydrogels (see below), it is only the higher concentration RLP phase that comprises a cross-linked, percolated polymer network. As expected, the phase diagram (Figure A) has the typical shape of a polymer with UCST transition and is consistent with other proteins that undergo LLPS upon cooling, as is in the case of γ-crystallins , or other RLP constructs. , Interestingly, in such proteins, the LLPS transition is enhanced with increasing the content of both arginine and aromatic amino acids, as we have shown here in our atomistic simulations (Figure A). The transition temperatures shown in the coexistence curve suggest conditions suitable for cell culture applications, as the solutions phase separate close to physiological conditions and at concentrations required for effective cross-linking as detailed above.…”

Section: Resultssupporting

confidence: 89%

Alteration of Microstructure in Biopolymeric Hydrogels via Compositional Modification of Resilin-Like Polypeptides

Garcia

Patkar

Jovic

et al. 2021

ACS Biomater. Sci. Eng.

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Heterogeneities in hydrogel scaffolds are known to impact the performance of cells in cell-laden materials constructs, and we have employed the phase separation of resilin-like polypeptides (RLPs) as a means to generate such materials.Here, we study the compositional features of resilin-like polypeptides (RLPs) that further enable our control of their liquid−liquid phase separation (LLPS) and how such control impacts the formation of microstructured hydrogels. The evaluation of the phase separation of RLPs in solutions of ammonium sulfate offers insights into the sequence-dependent LLPS of the RLP solutions, and atomistic simulations, along with 2D-nuclear Overhauser effect spectroscopy (NOESY) and correlated spectroscopy (COSY) 1 H NMR, suggest specific amino acid interactions that may mediate this phase behavior. The acrylamide functionalization of RLPs enables their photo-cross-linking into hydrogels and also enhances the phase separation of the polypeptides. A heating−cooling protocol promotes the formation of stable emulsions that yield different microstructured morphologies with tunable rheological properties. These findings offer approaches for choosing RLP compositions with phase behaviors that can be easily tuned with differences in temperature to control the resulting morphology and mechanical behavior of the heterogeneous hydrogels in regimes useful for biological applications.

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Section: Resultssupporting

confidence: 89%

Alteration of Microstructure in Biopolymeric Hydrogels via Compositional Modification of Resilin-Like Polypeptides

Garcia

Patkar

Jovic

et al. 2021

ACS Biomater. Sci. Eng.

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“…[234] Although the whole lens of D. mawsoni resists cold cataract down to at least À 12°C, below which it freezes solid, [235] the individual γ- crystallins vary greatly in cold-cataract resistance despite their high sequence identity. [236] Wild-type toothfish γM8b phase separates at À 4.8°C, but mutating only three Arg residues on the surface to Lys makes it more resistant to cold cataract than any of the wild-type proteins tested, with an onset temperature of À 13.7°C, illustrating the importance of specific proteinprotein interactions. Conversely, mutating three Lys residues to Arg raises the onset temperature of LLPS by an equivalent amount, to 3.5°C, [236] thereby demonstrating that LLPS can be controlled by making subtle changes to protein surface properties, even in well-folded proteins.…”

Section: Llpsmentioning

confidence: 97%

“…The Antarctic toothfish, Dissostichus mawsoni , has at least 13 expressed γ‐crystallin paralogues [234] . Although the whole lens of D. mawsoni resists cold cataract down to at least −12 °C, below which it freezes solid, [235] the individual γ‐crystallins vary greatly in cold‐cataract resistance despite their high sequence identity [236] . Wild‐type toothfish γM8b phase separates at −4.8 °C, but mutating only three Arg residues on the surface to Lys makes it more resistant to cold cataract than any of the wild‐type proteins tested, with an onset temperature of −13.7 °C, illustrating the importance of specific protein‐protein interactions.…”

Section: Protein‐protein Interactionsmentioning

confidence: 99%

“…Wild‐type toothfish γM8b phase separates at −4.8 °C, but mutating only three Arg residues on the surface to Lys makes it more resistant to cold cataract than any of the wild‐type proteins tested, with an onset temperature of −13.7 °C, illustrating the importance of specific protein‐protein interactions. Conversely, mutating three Lys residues to Arg raises the onset temperature of LLPS by an equivalent amount, to 3.5 °C, [236] thereby demonstrating that LLPS can be controlled by making subtle changes to protein surface properties, even in well‐folded proteins. The importance of specific surface interactions were hinted at in early studies, for example the finding that phase separation induces major changes to the Raman spectrum of tyrosine in lens proteins [237] .…”

Section: Protein‐protein Interactionsmentioning

confidence: 99%

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Chemical Properties Determine Solubility and Stability in βγ‐Crystallins of the Eye Lens

et al. 2021

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βγ-Crystallins are the primary structural and refractive proteins found in the vertebrate eye lens. Because crystallins are not replaced after early eye development, their solubility and stability must be maintained for a lifetime, which is even more remarkable given the high protein concentration in the lens. Aggregation of crystallins caused by mutations or post-translational modifications can reduce crystallin protein stability and alter intermolecular interactions. Common post-translational modifications that can cause age-related cataracts include deamidation, oxidation, and tryptophan derivatization. Metal ion binding can also trigger reduced crystallin solubility through a variety of mechanisms. Interprotein interactions are critical to maintaining lens transparency: crystallins can undergo domain swapping, disulfide bonding, and liquid-liquid phase separation, all of which can cause opacity depending on the context. Important experimental techniques for assessing crystallin conformation in the absence of a high-resolution structure include dye-binding assays, circular dichroism, fluorescence, light scattering, and transition metal FRET.

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“…The majority of these publications are focused on the analysis of macromolecules (proteins and RNA/DNA) enriched in membrane-less organelles and their structural features [7,9,10,11,12,13,14,15,16,17], as well as on the analysis of model systems capable to isolate protein-rich phases under certain conditions in vitro as well as in vivo. Typically, the model systems used in such studies include different phase-separating proteins, such as tau-protein [18], elastin-like polypeptides [19], fused in sarcoma (FUS) [20], transactive response element (TAR) DNA-binding protein of 43 kDa (TDP-43) [21], structural γ-crystallins [22], polyQ-protein Whi3 [23], proteasomal shuttle factor UBQLN2 [24], nucleophosmin (NPM1) [25], Numb/Pon complex from Drosophila neuroblast [26], C9orf72 dipeptide repeat proteins [27], multivalent signaling proteins [28], and many others. There are several reports [29,30] indicating that the solvent properties of membrane-less organelles and protein-rich phases are different from those of the environment from which these phases originate.…”

mentioning

confidence: 99%

Driving Forces of Liquid–Liquid Phase Separation in Biological Systems

Zaslavsky¹,

Ferreira²,

Uversky

2019

Biomolecules

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Analysis of liquid–liquid phase separation in biological systems shows that this process is similar to the phase separation observed in aqueous two-phase systems formed by nonionic polymers, proteins, and polysaccharides. The emergence of interfacial tension is a necessary condition of phase separation. The situation in this regard is similar to that of phase separation in mixtures of partially miscible solvents. It is suggested that the evaluation of the effects of biological macromolecules on the solvent properties of aqueous media and the measurement of the interfacial tension as a function of these solvent properties may be more productive for gaining insights into the mechanism of liquid–liquid phase separation than the study of structural details of proteins and RNAs engaged in the process.

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Controlling Liquid–Liquid Phase Separation of Cold-Adapted Crystallin Proteins from the Antarctic Toothfish

Cited by 18 publications

References 81 publications

Alteration of Microstructure in Biopolymeric Hydrogels via Compositional Modification of Resilin-Like Polypeptides

Alteration of Microstructure in Biopolymeric Hydrogels via Compositional Modification of Resilin-Like Polypeptides

Chemical Properties Determine Solubility and Stability in βγ‐Crystallins of the Eye Lens

Driving Forces of Liquid–Liquid Phase Separation in Biological Systems

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