TIA1 potentiates tau phase separation and promotes generation of toxic oligomeric tau

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Significance

Phase separation of proteins is increasingly thought to play a fundamental role in biological processes. Recent studies show that tau protein phase separates, but the biological significance is unknown since artificial crowding agents are typically used and the resulting tau is not toxic. We now demonstrate that TIA1 potentiates RNA-mediated phase separation of tau, thereby enabling a process that occurs at physiological concentrations and also directs the formation of biologically active, highly neurotoxic oligomeric tau. Coordinated phase separation of functionally related proteins provides a general mechanism through which membraneless organelles can direct biological activities.

Abstract

Tau protein plays an important role in the biology of stress granules and in the stress response of neurons, but the nature of these biochemical interactions is not known. Here we show that the interaction of tau with RNA and the RNA binding protein TIA1 is sufficient to drive phase separation of tau at physiological concentrations, without the requirement for artificial crowding agents such as polyethylene glycol (PEG). We further show that phase separation of tau in the presence of RNA and TIA1 generates abundant tau oligomers. Prior studies indicate that recombinant tau readily forms oligomers and fibrils in vitro in the presence of polyanionic agents, including RNA, but the resulting tau aggregates are not particularly toxic. We discover that tau oligomers generated during copartitioning with TIA1 are significantly more toxic than tau aggregates generated by incubation with RNA alone or phase-separated tau complexes generated by incubation with artificial crowding agents. This pathway identifies a potentially important source for generation of toxic tau oligomers in tau-related neurodegenerative diseases. Our results also reveal a general principle that phase-separated RBP droplets provide a vehicle for coassortment of selected proteins. Tau selectively copartitions with TIA1 under physiological conditions, emphasizing the importance of TIA1 for tau biology. Other RBPs, such as G3BP1, are able to copartition with tau, but this happens only in the presence of crowding agents. This type of selective mixing might provide a basis through which membraneless organelles bring together functionally relevant proteins to promote particular biological activities.

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The abbreviated name, 'mfold web server', describes a number of closely related software applications available on the World Wide Web (WWW) for the prediction of the secondary structure of single stranded nucleic acids. The objective of this web server is to provide easy access to RNA and DNA folding and hybridization software to the scientific community at large. By making use of universally available web GUIs (Graphical User Interfaces), the server circumvents the problem of portability of this software. Detailed output, in the form of structure plots with or without reliability information, single strand frequency plots and 'energy dot plots', are available for the folding of single sequences. A variety of 'bulk' servers give less information, but in a shorter time and for up to hundreds of sequences at once. The portal for the mfold web server is http://www.bioinfo.rpi.edu/applications/mfold. This URL will be referred to as 'MFOLDROOT'.

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Liquid phase condensation in cell physiology and disease.

Yongdae Shin, Clifford Brangwynne (2017)

Phase transitions are ubiquitous in nonliving matter, and recent discoveries have shown that they also play a key role within living cells. Intracellular liquid-liquid phase separation is thought to drive the formation of condensed liquid-like droplets of protein, RNA, and other biomolecules, which form in the absence of a delimiting membrane. Recent studies have elucidated many aspects of the molecular interactions underlying the formation of these remarkable and ubiquitous droplets and the way in which such interactions dictate their material properties, composition, and phase behavior. Here, we review these exciting developments and highlight key remaining challenges, particularly the ability of liquid condensates to both facilitate and respond to biological function and how their metastability may underlie devastating protein aggregation diseases.

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Phase separation by low complexity domains promotes stress granule assembly and drives pathological fibrillization.

Amandine Molliex, Jamshid Temirov, Jihun Lee … (2015)

Stress granules are membrane-less organelles composed of RNA-binding proteins (RBPs) and RNA. Functional impairment of stress granules has been implicated in amyotrophic lateral sclerosis, frontotemporal dementia, and multisystem proteinopathy-diseases that are characterized by fibrillar inclusions of RBPs. Genetic evidence suggests a link between persistent stress granules and the accumulation of pathological inclusions. Here, we demonstrate that the disease-related RBP hnRNPA1 undergoes liquid-liquid phase separation (LLPS) into protein-rich droplets mediated by a low complexity sequence domain (LCD). While the LCD of hnRNPA1 is sufficient to mediate LLPS, the RNA recognition motifs contribute to LLPS in the presence of RNA, giving rise to several mechanisms for regulating assembly. Importantly, while not required for LLPS, fibrillization is enhanced in protein-rich droplets. We suggest that LCD-mediated LLPS contributes to the assembly of stress granules and their liquid properties and provides a mechanistic link between persistent stress granules and fibrillar protein pathology in disease.

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Author and article information

Journal

Journal ID (nlm-ta): Proc Natl Acad Sci U S A

Journal ID (iso-abbrev): Proc Natl Acad Sci U S A

Journal ID (hwp): pnas

Journal ID (pmc): pnas

Journal ID (publisher-id): PNAS

Title: Proceedings of the National Academy of Sciences of the United States of America

Publisher: National Academy of Sciences

ISSN (Print): 0027-8424

ISSN (Electronic): 1091-6490

Publication date (Print): 02 March 2021

Publication date (Electronic): 22 February 2021

Publication date PMC-release: 22 February 2021

Volume: 118

Issue: 9

Electronic Location Identifier: e2014188118

Affiliations

[1] ^aDepartment of Pharmacology and Experimental Therapeutics, Boston University School of Medicine , Boston, MA 02118;

[2] ^bDepartment of Neuroscience, Mayo Clinic Florida , Jacksonville, FL 32224;

[3] ^cDepartment of Anatomy and Neurobiology, Boston University School of Medicine , Boston, MA 02118;

[4] ^dDepartment of Neurology, Boston University School of Medicine , Boston, MA 02118;

[5] ^eDivision of Rheumatology, Immunology, and Allergy, Brigham and Women’s Hospital, Harvard Medical School , Boston, MA 02115;

[6] ^fGerman Center for Neurodegenerative Diseases , DZNE, Berlin, 10117, Germany;

[7] ^gDepartment of Translational Neuroscience, Grand Rapids Research Center, Michigan State University , Grand Rapids, MI 49503;

[8] ^hCenter for Systems Neuroscience, Boston University School of Medicine , Boston, MA 02118;

[9] ⁱNeurophotonics Center, Boston University School of Medicine , Boston, MA 02118

Author notes

²To whom correspondence may be addressed. Email: bwolozin@ 123456bu.edu .

Edited by Gregory A. Petsko, Brigham and Women’s Hospital, Boston, Massachusetts, and approved January 19, 2021 (received for review July 7, 2020)

Author contributions: P.E.A.A. and B.W. designed research; P.E.A.A., S.L., J.S., S.B., M.M., B.L.M., G.S., L.F.A.A.-M., L.J., M.M.Ö., and P.I. performed research; P.E.A.A., S.L., J.S., Y.C., P.I., L.P., S.W., N.M.K., and B.W. contributed new reagents/analytic tools; P.E.A.A., S.L., M.K., and B.W. analyzed data; and P.E.A.A. and B.W. wrote the paper.

¹P.E.A.A. and S.L. contributed equally to this work.