Ratchet-like polypeptide translocation mechanism of the AAA+ disaggregase Hsp104

Stephanie N. Gates; Adam L. Yokom; JiaBei Lin; Meredith E. Jackrel; Alexandrea N. Rizo; Nathan M. Kendsersky; C.E. Buell; Elizabeth A. Sweeny; Korrie L. Mack; Edward Chuang; Mariana P. Torrente; Min Su; James Shorter; Daniel R. Southworth

doi:10.1126/science.aan1052

Ratchet-like polypeptide translocation mechanism of the AAA+ disaggregase Hsp104

Stephanie N. Gates(University of Michigan), Adam L. Yokom(University of Michigan), JiaBei Lin(University of Pennsylvania), Meredith E. Jackrel(University of Pennsylvania), Alexandrea N. Rizo(University of Michigan), Nathan M. Kendsersky(University of Pennsylvania), C.E. Buell(University of Pennsylvania), Elizabeth A. Sweeny(University of Pennsylvania), Korrie L. Mack(University of Pennsylvania), Edward Chuang(University of Pennsylvania), Mariana P. Torrente(The Graduate Center, CUNY), Min Su(University of Michigan), James Shorter(University of Pennsylvania), Daniel R. Southworth(University of Michigan)

Science

July 20, 2017

10.1126/science.aan1052

Cited by 273Open Access

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Abstract

solubilizes stress-induced amorphous aggregates and amyloids. The structural basis for substrate recognition and translocation is unknown. Using a model substrate (casein), we report cryo-electron microscopy structures at near-atomic resolution of Hsp104 in different translocation states. Substrate interactions are mediated by conserved, pore-loop tyrosines that contact an 80-angstrom-long unfolded polypeptide along the axial channel. Two protomers undergo a ratchet-like conformational change that advances pore loop-substrate interactions by two amino acids. These changes are coupled to activation of specific nucleotide hydrolysis sites and, when transmitted around the hexamer, reveal a processive rotary translocation mechanism and substrate-responsive flexibility during Hsp104-catalyzed disaggregation.

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