Abstract
The homologous hexameric AAA(+) proteins, Hsp104 from yeast and ClpB from bacteria, collaborate with Hsp70 to dissolve disordered protein aggregates but employ distinct mechanisms of intersubunit collaboration. How Hsp104 and ClpB coordinate polypeptide handover with Hsp70 is not understood. Here, we define conserved distal loop residues between middle domain (MD) helix 1 and 2 that are unexpectedly critical for Hsp104 and ClpB collaboration with Hsp70. Surprisingly, the Hsp104 and ClpB MD distal loop does not contact Hsp70 but makes intrasubunit contacts with nucleotide-binding domain 2 (NBD2). Thus, the MD does not invariably project out into solution as in one structural model of Hsp104 and ClpB hexamers. These intrasubunit contacts as well as those between MD helix 2 and NBD1 are different in Hsp104 and ClpB. NBD2-MD contacts dampen disaggregase activity and must separate for protein disaggregation. We demonstrate that ClpB requires DnaK more stringently than Hsp104 requires Hsp70 for protein disaggregation. Thus, we reveal key differences in how Hsp104 and ClpB coordinate polypeptide handover with Hsp70, which likely reflects differential tuning for yeast and bacterial proteostasis.
Highlights
How Hsp104 and ClpB coordinate polypeptide handover with Hsp70 to dissolve disordered protein aggregates is unknown
We demonstrate that ClpB requires DnaK more stringently than Hsp104 requires Hsp70 for protein disaggregation
Here, we establish for the first time that conserved residues in the middle domain (MD) distal loop of Hsp104 and ClpB are critical for collaboration with Hsp70
Summary
How Hsp104 and ClpB coordinate polypeptide handover with Hsp to dissolve disordered protein aggregates is unknown. Hsp104 Distal Loop Enables Collaboration with Hsp analog, ATP␥S, and by mutant subunits defective in ATP hydrolysis and substrate binding [26, 32] These differences confer Hsp104 with the plasticity needed to rapidly disassemble highly stable, cross- amyloid and prion fibrils, as well as their toxic oligomeric precursors, whereas ClpB has limited activity against these substrates [26, 33,34,35,36,37]. We reveal a crucial unanticipated role for the MD distal loop of Hsp104 and ClpB in Hsp collaboration, as well as unexpected differences in how these protein disaggregases dissolve disordered aggregates
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