Structural Fuzziness of the RNA-Organizing Protein SERF Determines a Toxic Gain-of-interaction

The mechanisms by which protein complexes convert from functional to pathogenic are the subject of intensive research. Here, we report how functionally unfavorable protein interactions can be induced by structural fuzziness, i.e., by persisting conformational disorder in protein complexes. We show t...

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Published in:Journal of molecular biology 2020-02, Vol.432 (4), p.930-951
Main Authors: Meyer, N. Helge, Dellago, Hanna, Tam-Amersdorfer, Carmen, Merle, David A., Parlato, Rosanna, Gesslbauer, Bernd, Almer, Johannes, Gschwandtner, Martha, Leon, A., Franzmann, Titus M., Grillari, Johannes, Kungl, Andreas J., Zangger, Klaus, Falsone, S. Fabio
Format: Article
Language:English
Subjects:
Alpha synuclein
Intrinsically disordered proteins
MOAG-4/SERF
RNA-binding
Structural fuzziness
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Summary:The mechanisms by which protein complexes convert from functional to pathogenic are the subject of intensive research. Here, we report how functionally unfavorable protein interactions can be induced by structural fuzziness, i.e., by persisting conformational disorder in protein complexes. We show that extreme disorder in the bound state transforms the intrinsically disordered protein SERF1a from an RNA-organizing factor into a pathogenic enhancer of alpha-synuclein (aSyn) amyloid toxicity. We demonstrate that SERF1a promotes the incorporation of RNA into nucleoli and liquid-like artificial RNA-organelles by retaining an unusually high degree of conformational disorder in the RNA-bound state. However, this type of structural fuzziness also determines an undifferentiated interaction with aSyn. RNA and aSyn both bind to one identical, positively charged site of SERF1a by an analogous electrostatic binding mode, with similar binding affinities, and without any observable disorder-to-order transition. The absence of primary or secondary structure discriminants results in SERF1a being unable to select between nucleic acid and amyloidogenic protein, leading the pro-amyloid aSyn:SERF1a interaction to prevail in the cytosol under conditions of cellular stress. We suggest that fuzzy disorder in SERF1a complexes accounts for an adverse gain-of-interaction which favors toxic binding to aSyn at the expense of nontoxic RNA binding, thereby leading to a functionally distorted and pathogenic process. Thus, structural fuzziness constitutes a direct link between extreme conformational flexibility, amyloid aggregation, and the malfunctioning of RNA-associated cellular processes, three signatures of neurodegenerative proteinopathies. [Display omitted] •SERF1a is a novel nucleocytosolic RNA-binding protein without any homology to canonical RNA binding sequences.•SERF1a favors the integration of RNA into phase separated liquid droplets and into subnuclear RNA-processing structures.•Under conditions of cellular stress, SERF1a binds alpha synuclein in the cytosol, favoring neurotoxic amyloid aggregation.•SERF1a binds to RNA and alpha synuclein by an identical, fully disordered binding mode.•SERF1a is unable to distinguish between the physiologic and the pathogenic binding partner.
ISSN:0022-2836
1089-8638
DOI:10.1016/j.jmb.2019.11.014