Shannon M. Doyle scite author profile

Two members of the AAA+ superfamily, ClpB and Hsp104, collaborate with Hsp70 and Hsp40 to rescue aggregated proteins. However, the mechanisms that elicit and underlie their proteinremodeling activities remain unclear. We report that for both Hsp104 and ClpB, mixtures of ATP and ATPγS unexpectedly unleash activation, disaggregation, and unfolding activities independent of co-chaperones. Mutations reveal how remodeling activities are elicited by impaired hydrolysis at individual nucleotide binding domains. However, for some substrates, mixtures of ATP and ATPγS abolish remodeling, while for others ATP binding without hydrolysis is sufficient. Remodeling of different substrates necessitates a diverse balance of polypeptide holding (which requires ATP binding but not hydrolysis) and unfolding (which requires ATP hydrolysis). We suggest that this versatility in reaction mechanism enables ClpB and Hsp104 to reactivate the entire aggregated proteome after stress, and enables Hsp104 to control prion inheritance.Life demands that members of the AAA+ ATPase superfamily (ATPases associated with various cellular activities) couple energy from ATP hydrolysis to the remodeling of a bewildering array of macromolecular structures, that range from protein to DNA and RNA 1, 2 . Typically, eukaryotic genomes encode 50-80 family members 1 , each of which occupies specific niches that require specialized modes of substrate selection and regulation. The extraordinary adaptive radiation of AAA+ proteins to function in a multitude of cellular reactions illustrates the versatility of their structurally conserved AAA+ domain. Subunits containing AAA+ domains assemble into oligomeric rings, and ATP binds at the interface between adjacent protomers 1, 2 . AAA+ oligomers undergo considerable conformational changes during ATP binding and hydrolysis, although how these events are regulated and transduced into productive substrate remodeling remains largely enigmatic. Furthermore, it remains unanswered whether individual AAA+ family members rely on a common reaction mechanism to remodel various macromolecular clients. It is also unclear whether different AAA+ members have evolved distinct methods to engage and restructure substrates, or if individual proteins can switch between distinct reaction mechanisms for different substrates.Two members of the AAA+ superfamily separated by ~2 billion years of evolution 3 , yeast Hsp104, and its E. coli homolog, ClpB, allow cell survival after exposure to extreme environmental stress 4-7 . They function to dissolve and renature thousands of diverse 5 Correspondence: Sue Wickner,

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Hsp104 and ClpB: protein disaggregating machines

Doyle

Wickner

2009

Trends in Biochemical Sciences

258

225

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Protein rescue from aggregates by powerful molecular chaperone machines

Doyle

Genest

Wickner

2013

Nat Rev Mol Cell Biol

227

201

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Protein quality control within the cell requires the interplay of many molecular chaperones and proteases. When this quality control system is disrupted, polypeptides follow pathways leading to misfolding, inactivity and aggregation. Among the repertoire of molecular chaperones are remarkable proteins that forcibly untangle protein aggregates, called disaggregases. Structural and biochemical studies have led to new insights into how these proteins collaborate with co-chaperones and utilize ATP to power protein disaggregation. Understanding how energy-dependent protein disaggregating machines function is universally important and clinically relevant, as protein aggregation is linked to medical conditions such as Alzheimer's disease, Parkinson's disease, amyloidosis and prion diseases.

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Shannon M. Doyle

Asymmetric deceleration of ClpB or Hsp104 ATPase activity unleashes protein-remodeling activity

Hsp104 and ClpB: protein disaggregating machines

Protein rescue from aggregates by powerful molecular chaperone machines

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