Abstract
Hsp90 is an abundant molecular chaperone involved in a variety of cellular processes ranging from signal transduction to viral replication. The function of Hsp90 has been shown to be dependent on its ability to hydrolyze ATP, and in vitro studies suggest that the dimeric nature of Hsp90 is critical for this activity. ATP binding occurs at the N-terminal domains of the Hsp90 dimer, whereas the main dimerization site resides in the very C-terminal domain. ATP hydrolysis is performed in a series of conformational changes. These include the association of the two N-terminal domains, which has been shown to stimulate the hydrolysis reaction. In this study, we set out to identify regions in the N-terminal domain that are important for this interaction. We show that N-terminal deletion variants of Hsp90 are severely impaired in their ability to hydrolyze ATP. However, nucleotide binding of these constructs is similar to that of the wild type protein. Heterodimers of the Hsp90 deletion mutants with wild type protein showed that the first 24 amino acids play a crucial role during the ATPase reaction, because their deletion abolishes the trans-activation between the two N-terminal domains. We propose that the turnover rate of Hsp90 is decisively controlled by intermolecular interactions between the N-terminal domains.
Highlights
Hsp901 is a molecular chaperone that has been linked to the function of several signaling proteins such as Src kinase, steroid hormone receptors, and p53 among others
Previous studies revealed that the ATPase cycle includes significant conformational changes that involve the entire Hsp90 molecule [7]
It was shown that N-terminal dimerization is important for the stimulation of the hydrolysis reaction, because it was found that heterodimers between N-terminally truncated Hsp90 and WT Hsp90 show reduced ATPase activity [11]
Summary
Heat shock protein 90; (P␥)MABA-ATP, adenosinetriphospho-␥-(NЈ-methylanthraniloylaminobutyl)-phosphoramidate; ⌬8-Hsp, deletion mutant lacking the first 8 amino acids; ⌬16-Hsp, deletion mutant lacking the first 16 amino acids; ⌬24-Hsp, deletion mutant lacking the first 24 amino acids; Hsp90-262C, yeast Hsp fragment ranging from amino acid 262 to 709; Hsp90-527C, fragment from amino acid 527 to 709 of Hsp; SEC, size exclusion chromatography; WT, wild type; kon, rate constant for association; koff, rate constant for dissociation. During the ATPase cycle, the N-terminal domains of the dimer associate This seems to be the prerequisite for an efficient hydrolysis reaction. We used the structures of two weakly homologues proteins (GyraseB and MutL) as starting points to design several mutants of Hsp that might influence the dimerization. In these proteins, approximately 30 amino acids interact between the N-terminal subunits to form a dimer [13,14,15]. The results obtained shed light on the mechanism of stimulation in the ATPase cycle of Hsp90 We found that this region is involved in the intermolecular interactions of the N-terminal domains. We conclude that these interactions control the turnover of the overall ATPase cycle
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