Abstract
A notable feature of complex cellular environments is protein-rich compartments that are formed via liquid–liquid phase separation. Recent studies have shown that these biomolecular condensates can play both promoting and inhibitory roles in fibrillar protein self-assembly, a process that is linked to Alzheimer's, Parkinson's, Huntington's, and various prion diseases. Yet, the exact regulatory role of these condensates in protein aggregation remains unknown. By employing microfluidics to create artificial protein compartments, the self-assembly behavior of the fibrillar protein lysozyme within them can be characterized. It is observed that the volumetric parameters of protein-rich compartments can change the kinetics of protein self-assembly. Depending on the change in compartment parameters, the lysozyme fibrillation process either accelerated or decelerated. Furthermore, the results confirm that the volumetric parameters govern not only the nucleation and growth phases of the fibrillar aggregates but also affect the crosstalk between the protein-rich and protein-poor phases. The appearance of phase-separated compartments in the vicinity of natively folded protein complexes triggers their abrupt percolation into the compartments' core and further accelerates protein aggregation. Overall, the results of the study shed more light on the complex behavior and functions of protein-rich phases and, importantly, on their interaction with the surrounding environment.
Original language | English |
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Article number | 2308069 |
Journal | Small |
Volume | 20 |
Issue number | 22 |
Early online date | 26 Dec 2023 |
DOIs | |
State | Published - 29 May 2024 |
Externally published | Yes |
Bibliographical note
Publisher Copyright:© 2023 The Authors. Small published by Wiley-VCH GmbH.
Funding
S.K. and M.E.M. contributed equally to this work. U.S. acknowledges financial support from the Nella and Leon Benoziyo Center for Neurological Diseases. In addition, U.S. thanks the Perlman family for funding the Shimanovich Lab at the Weizmann Institute of Science: This research was made possible in part by the generosity of the Harold Perlman Family. The work was also supported by a research grant from the Perlman Family Foundation Founded by Anita and Louis Perlman C‐AIM Young Scientist Fund. The authors would like to acknowledge partial support from the GMJ Schmidt Minerva Center of Supramolecular Architectures at the Weizmann Institute, the Mondry Family Fund for the University of Michigan/Weizmann collaboration, the Gerald Schwartz, and Heather Reisman Foundation, and the WIS Sustainability and Energy Research Initiative (SAERI). This research was supported by a research grant from the Tom and Mary Beck Center for Advanced and Intelligent Materials at the Weizmann Institute of Science. S.K. acknowledges The Swiss Society of Friends of the Weizmann Institute for their financial support. M.E.M. thanks the Sergio Lombroso Fellowship (for Cancer Research) for financial support. All the EM studies were conducted at the Irving and Cherna Moskowitz Center for Nano and Bio‐Nano Imaging at the Weizmann Institute of Science. The authors thank Steve Manch for editing the English of this manuscript.
Funders | Funder number |
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Heather Reisman Foundation | |
Mondry Family Fund for the University of Michigan/Weizmann | |
Perlman family for funding the Shimanovich Lab | |
SAERI | |
Swiss Society of Friends of the Weizmann Institute | |
Tom and Mary Beck Center for Advanced and Intelligent Materials at the Weizmann Institute of Science | |
WIS Sustainability and Energy Research Initiative | |
Weizmann Institute | |
Perlman Family Foundation | |
Cancer Research UK |
Keywords
- amyloid fibrillation
- liquid-liquid phase separation
- lysozyme protein
- microfluidics
- self-assembly