Abstract
Hsp90 is a homodimeric ATP-dependent molecular chaperone that remodels its substrate 'client' proteins, facilitating their folding and activating them for biological function. Despite decades of research, the mechanism connecting ATP hydrolysis and chaperone function remains elusive. Particularly puzzling has been the apparent lack of cooperativity in hydrolysis of the ATP in each protomer. A crystal structure of the mitochondrial Hsp90, TRAP1, revealed that the catalytically active state is closed in a highly strained asymmetric conformation. This asymmetry, unobserved in other Hsp90 homologs, is due to buckling of one of the protomers and is most pronounced at the broadly conserved client-binding region. Here, we show that rather than being cooperative or independent, ATP hydrolysis on the two protomers is sequential and deterministic. Moreover, dimer asymmetry sets up differential hydrolysis rates for each protomer, such that the buckled conformation favors ATP hydrolysis. Remarkably, after the first hydrolysis, the dimer undergoes a flip in the asymmetry while remaining in a closed state for the second hydrolysis. From these results, we propose a model where direct coupling of ATP hydrolysis and conformational flipping rearranges client-binding sites, providing a paradigm of how energy from ATP hydrolysis can be used for client remodeling.
Highlights
Heat-shock protein 90 (Hsp90) is a highly conserved ATP-dependent molecular chaperone
Using TRAP1 as a model system for Hsp90, here we investigate how ATP hydrolysis is coupled to its conformational asymmetry and propose a model connecting it to client remodeling
We examine whether ATP hydrolysis in TRAP1 is sequential, what the order of hydrolysis events is, and how the asymmetry is coupled to the nucleotide states along the ATPase cycle
Summary
Heat-shock protein 90 (Hsp90) is a highly conserved ATP-dependent molecular chaperone. Hsp can function as a canonical chaperone and promote protein folding by suppressing aggregation (Krukenberg et al, 2009; Wiech et al, 1992), it is unique in that it plays an active role in regulating the activities of a large subset of the proteome, including many proteins involved in signal transduction such as kinases and hormone receptors, supporting normal cellular functions This essential function of Hsp is intimately tied to its ATPase activity, and mutations that either enhance or suppress this activity compromise cell viability (Nathan and Lindquist, 1995; Panaretou et al, 1998). Deregulation of cellular Hsp levels helps support uncontrolled growth in many human cancers making Hsp an important pharmacological target (Whitesell and Lindquist, 2005)
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