Fine-tuning of the Hsc70-based Human Protein Disaggregase Machinery by the Distinctive C-terminal Extension of Apg2.

Apg2, one of the three cytosolic Hsp110 chaperones in humans, supports reactivation of unordered and ordered protein aggregates by Hsc70 (HspA8). Together with DnaJB1, Apg2 serves to nucleate Hsc70 molecules into sites where productive entropic pulling forces can be developed. During aggregate reactivation, Apg2 performs as a specialized nucleotide exchange factor, but the origin of its specialization is poorly defined. Here we report on the role of the distinctive C-terminal extension present in Apg2 and other metazoan homologs. We found that the first part of this Apg2 subdomain, with propensity to adopt α-helical structure, interacts with the nucleotide binding domain of Hsc70 in a nucleotide-dependent manner, contributing significantly to the stability of the Hsc70:Apg2 complex. Moreover, the second intrinsically disordered segment of Apg2 C-terminal extension plays an important role as a downregulator of nucleotide exchange. An NMR analysis showed that the interaction with Hsc70 nucleotide binding domain modifies the chemical environment of residues located in important functional sites such as the interface between lobe I and II and the nucleotide binding site. Our data indicate that Apg2 C-terminal extension is a fine-tuner of human Hsc70 activity that optimizes the substrate remodeling ability of the chaperone system.

Regulation of Human Hsc70 ATPase and Chaperone Activities by Apg2: Role of the Acidic Subdomain.

Protein aggregate reactivation in metazoans is accomplished by the combined activity of Hsp70, Hsp40 and Hsp110 chaperones. Hsp110s support the refolding of aggregated polypeptides acting as specialized nucleotide exchange factors of Hsp70. We have studied how Apg2, one of the three human Hsp110s, regulates the activity of Hsc70 (HspA8), the constitutive Hsp70 in our cells. Apg2 shows a biphasic behavior: at low concentration, it stimulates the ATPase cycle of Hsc70, binding of the chaperone to protein aggregates and the refolding activity of the system, while it inhibits these three processes at high concentration. When the acidic subdomain of Apg2, a characteristic sequence present in the substrate binding domain of all Hsp110s, is deleted, the detrimental effects occur at lower concentration and are more pronounced, which concurs with an increase in the affinity of the Apg2 mutant for Hsc70. Our data support a mechanism in which Apg2 arrests the chaperone cycle through an interaction with Hsc70(ATP) that might lead to premature ATP dissociation before hydrolysis. In this line, the acidic subdomain might serve as a conformational switch to support dissociation of the Hsc70:Apg2 complex.

ClpB dynamics is driven by its ATPase cycle and regulated by the DnaK system and substrate proteins.

The hexameric AAA+ (ATPase associated with various cellular activities) chaperone ClpB reactivates protein aggregates in collaboration with the DnaK system. An intriguing aspect of ClpB function is that the active hexamer is unstable and therefore questions how this chaperone uses multiple rounds of ATP hydrolysis to translocate substrates through its central channel. In the present paper, we report the use of biochemical and fluorescence tools to explore ClpB dynamics under different experimental conditions. The analysis of the chaperone activity and the kinetics of subunit exchange between protein hexamers labelled at different protein domains indicates, in contrast with the current view, that (i) ATP favours assembly and ADP dissociation of the hexameric assembly, (ii) subunit exchange kinetics is at least one order of magnitude slower than the ATP hydrolysis rate, (iii) ClpB dynamics and activity are related processes, and (iv) DnaK and substrate proteins regulate the ATPase activity and dynamics of ClpB. These data suggest that ClpB hexamers remain associated during several ATP hydrolysis events required to partially or completely translocate substrates through the protein central channel, and that ClpB dynamics is tuned by DnaK and substrate proteins.