Widespread nuclear lamina injuries defeat proteostatic purposes of α-synuclein amyloid inclusions.

Biogenesis of inclusion bodies (IBs) facilitates protein quality control (PQC). Canonical aggresomes execute degradation of misfolded proteins while non-degradable amyloids sequester into insoluble protein deposits. Lewy bodies (LBs) are filamentous amyloid inclusions of α-synuclein, but PQC benefits and drawbacks associated with LB-like IBs remain underexplored. Here, we report that crosstalk between filamentous LB-like IBs and aggresome-like IBs of α-synuclein (Syn-aggresomes) buffer the load, aggregation state, and turnover of the amyloidogenic protein in mouse primary neurons and HEK293T cells. Filamentous LB-like IBs possess unorthodox PQC capacities of self-quarantining α-synuclein amyloids and being degradable upon receding fresh amyloidogenesis. Syn-aggresomes equilibrate biogenesis of filamentous LB-like IBs by facilitating spontaneous degradation of α-synuclein and conditional turnover of disintegrated α-synuclein amyloids. Thus, both types of IB primarily contribute to PQC. Incidentally, the overgrown perinuclear LB-like IBs become degenerative once these are misidentified by BICD2, a cargo-adapter for the cytosolic motor-protein dynein. Microscopy indicates that microtubules surrounding the perinuclear filamentous inclusions are also distorted, misbalancing the cytoskeleton-nucleoskeleton tension leading to widespread lamina injuries. Together, nucleocytoplasmic mixing, DNA damage, and deregulated transcription of stress chaperones defeat the proteostatic purposes of the filamentous amyloids of α-synuclein.

Increased supraorganization of respiratory complexes is a dynamic multistep remodelling in response to proteostasis stress.

Proteasome-mediated degradation of misfolded proteins prevents aggregation inside and outside mitochondria. But how do cells safeguard the mitochondrial proteome and mitochondrial functions despite increased aggregation during proteasome inactivation? Here, using a novel two-dimensional complexome profiling strategy, we report increased supraorganization of respiratory complexes (RCs) in proteasome-inhibited cells that occurs simultaneously with increased pelletable aggregation of RC subunits inside mitochondria. Complex II (CII) and complex V (CV) subunits are increasingly incorporated into oligomers. Complex I (CI), complex III (CIII) and complex IV (CIV) subunits are engaged in supercomplex formation. We unravel unique quinary states of supercomplexes during early proteostatic stress that exhibit plasticity and inequivalence of constituent RCs. The core stoichiometry of CI and CIII is preserved, whereas the composition of CIV varies. These partially disintegrated supercomplexes remain functionally competent via conformational optimization. Subsequently, increased stepwise integration of RC subunits into holocomplexes and supercomplexes re-establishes steady-state stoichiometry. Overall, the mechanism of increased supraorganization of RCs mimics the cooperative unfolding and folding pathways for protein folding, but is restricted to RCs and is not observed for any other mitochondrial protein complexes.This article has an associated First Person interview with the first author of the paper.