Molecular crowding facilitates assembly of spidroin-like proteins through phase separation

[Display omitted] •The effect of a crowding agent on the self-coacervation of a silk-like protein was characterized.•The thermodynamics of coacervation was studied.•Driving forces and mechanisms of phase separation are discussed. Gaining insights into the processes that transform dispersed biopolyme...

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Veröffentlicht in:European polymer journal 2019-03, Vol.112, p.539-546
Hauptverfasser: Lemetti, Laura, Hirvonen, Sami-Pekka, Fedorov, Dmitrii, Batys, Piotr, Sammalkorpi, Maria, Tenhu, Heikki, Linder, Markus B., Aranko, A. Sesilja
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Sprache:eng
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Zusammenfassung:[Display omitted] •The effect of a crowding agent on the self-coacervation of a silk-like protein was characterized.•The thermodynamics of coacervation was studied.•Driving forces and mechanisms of phase separation are discussed. Gaining insights into the processes that transform dispersed biopolymers into well-ordered structures, such as soluble spidroin-proteins to spider silk threads, is essential for attempts to understand their biological function and to mimic their unique properties. One of these processes is liquid-liquid phase separation, which can act as an intermediate step for molecular assembly. We have shown that a self-coacervation step that occurs at a very high protein concentration (>200 gl−1) is crucial for the fiber assembly of an engineered triblock silk-like molecule. In this study, we demonstrate that the addition of a crowding agent lowers the concentration at which coacervation occurs by almost two orders of magnitude. Coacervates induced by addition of a crowding agent are functional in terms of fiber formation, and the crowding agent appears to affect the process solely by increasing the effective concentration of the protein. Furthermore, induction at lower concentrations allows us to study the thermodynamics of the system, which provides insights into the coacervation mechanism. We suggest that this approach will be valuable for studies of biological coacervating systems in general.
ISSN:0014-3057
1873-1945
DOI:10.1016/j.eurpolymj.2018.10.010