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SummaryProteostasis is maintained by optimum expression, folding, transport, and clearance of proteins. Deregulation of any of these processes triggers widespread protein aggregation and loss of function. Here, we perturbed proteostasis by blocking proteasome-mediated protein degradation and investigated proteome partitioning from soluble to insoluble fraction.Aggregation of Respiratory Chain Complex (RCC) subunits highlights the early destabilization event as revealed by proteome redistribution. Sequence analyses followed by microscopy suggest that low complexity regions at the N-terminus are capable to facilitate aggregation of RCC subunits. As a result, respiratory complex assembly process is impaired due to destabilization of sub-complexes marking the onset of mitochondrial dysfunction and ROS accumulation. Redistribution of Histone proteins and their modifications indicated reprogramming of transcription as adaptive response. Together, we demonstrate susceptibility of RCC subunits to aggregation under multiple proteotoxic stresses providing an explanation for the simultaneous deregulation of proteostasis and bioenergetics in age-related degenerative conditions.

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Improved Supra-Organization Is A Conformational And Functional Adaptation Of Respiratory Complexes

Rawat

Ghosh

Mondal

et al. 2020

Preprint

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Multiple surveillance mechanisms accelerate proteasome mediated degradation of misfolded proteins to prevent protein aggregation inside and outside mitochondria. But how cells safeguard mitochondrial function despite increased protein aggregation during proteasome inactivation? Here, using two-dimensional complexome profiling, we extensively characterize the dynamic states of respiratory complexes (RCs) in proteasome-inhibited cells.We report that RC-subunits are increasingly integrated into supra-organizations to optimize catalytic activity simultaneous to their aggregation inside mitochondria. Complex-II (CII) and CV are incorporated into oligomers. CI, CIII, and CIV subcomplexes are associated into holocomplexes followed by integration into supercomplexes. Time-course experiments reveal that the core (CI+CIII 2 ) stoichiometry of supercomplex (I+III 2 +IV) is preserved during earlystress while CIV composition varies. Simultaneously, increased CI-activity suggests conformational optimization of supercomplexes for better function. Re-establishment of steady-state stoichiometry and relative increase in supercomplex-quantity consolidates functional adaptation during prolonged proteasome-inhibition. Together, we name this preemptive adaptive mechanism as 'improved Supra-organization of Respiratory Complexes' (iSRC). We find that iSRC is active in multiple protein-unfolding stresses, in multiple celltypes that differ in proteostatic and metabolic demands, and reversible upon stresswithdrawal.

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Anusha

Proteostasis perturbation destabilizes respiratory complex assembly-intermediates via aggregation of subunits

Improved Supra-Organization Is A Conformational And Functional Adaptation Of Respiratory Complexes

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