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Differential roles for DNAJ isoforms in HTT-polyQ and FUS aggregation modulation revealed by chaperone screens

Kinneret Rozales, Amal Younis, Naseeb Saida, Anatoly Meller, Hodaya Goldman, Lior Kellerman, Ronit Heinrich, Shai Berlin, Reut Shalgi

2022Nature Communications37 citationsDOIOpen Access PDF

Abstract

Protein aggregation is a hallmark of neurodegeneration. Here, we find that Huntington's disease-related HTT-polyQ aggregation induces a cellular proteotoxic stress response, while ALS-related mutant FUS (mutFUS) aggregation leads to deteriorated proteostasis. Further exploring chaperone function as potential modifiers of pathological aggregation in these contexts, we reveal divergent effects of naturally-occurring chaperone isoforms on different aggregate types. We identify a complex of the full-length (FL) DNAJB14 and DNAJB12, that substantially protects from mutFUS aggregation, in an HSP70-dependent manner. Their naturally-occurring short isoforms, however, do not form a complex, and lose their ability to preclude mutFUS aggregation. In contrast, DNAJB12-short alleviates, while DNAJB12-FL aggravates, HTT-polyQ aggregation. DNAJB14-FL expression increases the mobility of mutFUS aggregates, and restores the deteriorated proteostasis in mutFUS aggregate-containing cells and primary neurons. Our results highlight a maladaptive cellular response to pathological aggregation, and reveal a layer of chaperone network complexity conferred by DNAJ isoforms, in regulation of different aggregate types.

Topics & Concepts

Gene isoformChaperone (clinical)Cell biologyModulation (music)Differential (mechanical device)BiologyEscherichia coli ProteinsHsp90Computational biologyGeneticsGeneBacterial proteinHeat shock proteinPhysicsMedicinePathologyAcousticsThermodynamicsRNA Research and SplicingHeat shock proteins researchGenomics and Chromatin Dynamics
Differential roles for DNAJ isoforms in HTT-polyQ and FUS aggregation modulation revealed by chaperone screens | Litcius