Dimerization and N-terminal domain proximity underlie the function of the molecular chaperone heat shock protein 90

Chadli, Ahmed; Bouhouche, Ilham; Sullivan, William P.; Stensgard, Bridget; McMahon, Nancy; Catelli, Maria-Grazia; Toft, David O.

doi:10.1073/pnas.220430297

Cited by 146 publications

(140 citation statements)

References 50 publications

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“…The specificity of using NRL(M185V)-p23/ Hsp90h-CRL was confirmed using Hsp90h2.2(K107A)-CRL, Hsp90h2.2(K111A)-CRL, and Hsp90h2.2(K107AK111A)-CRL mutant fusion constructs. These mutations are analogous to the K111A mutation in chicken Hsp90a that reduces binding to geldanamycin (29). Figure 3A (Fig.…”

Section: Resultsmentioning

confidence: 92%

Molecular Imaging of the Efficacy of Heat Shock Protein 90 Inhibitors in Living Subjects

et al. 2008

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Heat shock protein 90A (Hsp90A)/p23 and Hsp90B/p23 interactions are crucial for proper folding of proteins involved in cancer and neurodegenerative diseases. Small molecule Hsp90 inhibitors block Hsp90A/p23 and Hsp90B/p23 interactions in part by preventing ATP binding to Hsp90. The importance of isoform-selective Hsp90A/p23 and Hsp90B/p23 interactions in determining the sensitivity to Hsp90 was examined using 293T human kidney cancer cells stably expressing split Renilla luciferase (RL) reporters. Interactions between Hsp90A/p23 and Hsp90B/p23 in the split RL reporters led to complementation of RL activity, which was determined by bioluminescence imaging of intact cells in cell culture and living mice using a cooled charge-coupled device camera. The three geldanamycin-based and seven purinescaffold Hsp90 inhibitors led to different levels of inhibition of complemented RL activities (10-70%). However, there was no isoform selectivity to both classes of Hsp90 inhibitors in cell culture conditions. The most potent Hsp90 inhibitor, PU-H71, however, led to a 60% and 30% decrease in RL activity (14 hr) in 293T xenografts expressing Hsp90A/p23 and Hsp90B/p23 split reporters respectively, relative to carrier control-treated mice. Molecular imaging of isoform-specific Hsp90A/p23 and Hsp90B/p23 interactions and efficacy of different classes of Hsp90 inhibitors in living subjects have been achieved with a novel genetically encoded reporter gene strategy that should help in accelerating development of potent and isoformselective Hsp90 inhibitors. [Cancer Res 2008;68(1):216-26]

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Section: Resultsmentioning

confidence: 92%

Molecular Imaging of the Efficacy of Heat Shock Protein 90 Inhibitors in Living Subjects

et al. 2008

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“…Experimentally, N-domain proximity and nucleotide binding correlate with p23 binding to Hsp90 (44). In addition, fluorescence emission spectra of pyrene-derivatized Hsp90 (21) and electron microscopy of antibody decorated Hsp90 (45) also suggested N-domain proximity in the presence of ATP.…”

Section: Discussionmentioning

confidence: 91%

Ligand-induced Conformational Shift in the N-terminal Domain of GRP94, an Hsp90 Chaperone

Immormino¹,

Dollins²,

Shaffer

et al. 2004

Journal of Biological Chemistry

129

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The hsp90 1 family of molecular chaperones is required for the activation of a large number of proteins, including those involved in eukaryotic cell cycle regulation, signal transduction, immune response, and transcription (1, 2). GRP94 (also known as gp96), the endoplasmic reticulum paralog of cytoplasmic Hsp90, participates in the maturation of proteins that are transported to the cell surface, including Toll-like receptors and certain integrins (3), or secreted, such as IgGs (4, 5). The activity of the hsp90 family chaperones is regulated by ATP (6). Fungally derived ansamycin antibiotics such as geldanamycin and radicicol (7) compete for the ATP binding site (8 -11) and exhibit potent anti-tumor activity by acting as pan-hsp90 inhibitors (12-17). Given their central importance in the biology of protein folding and in cellular stress response, and their potential as targets in a variety of therapeutic strategies, the mechanism by which hsp90 chaperone activity is regulated and the chemistry of their interactions with client substrates are under intensive investigation.GRP94 and Hsp90 exist as obligate homodimers, with each subunit consisting of an N-terminal regulatory and ligand binding domain, a charged region, a middle domain, and a C-terminal dimerization domain. This organization and the structural similarity of their N-terminal ATP binding domains characterize the GHKL family of proteins (18), whose members in addition to Hsp90s also include DNA gyrase, histidine kinases, DNA topoisomerase II, and MutL. By analogy to DNA gyrase (19) and MutL (20), it has been proposed that Hsp90 chaperone activity is linked to an N-domain conformational change that is coupled to ATP binding and hydrolysis and that results in the dimerization of the N-domains (21, 22). Mechanistic explanations of how ATP binding and hydrolysis are coupled to Hsp90 activity have been hindered, however, by the lack of any observed change in the conformation of the Ndomain in response to ligands. The complete protein, rather than just the isolated N-domain, is required for ATP hydrolysis (6, 23), suggesting that conformational rearrangements resulting in a close interaction between the N-and middle domains are important for Hsp90 activity. Interactions with co-chaperones may also be important catalysts for ATP hydrolysis in human Hsp90 as well (24).GRP94 and Hsp90 are greater than 50% identical in their N-domains, yet the biochemical hallmarks of Hsp90 chaperone activity are largely missing for this paralog. ATP hydrolysis above background levels has not been detected for GRP94 (25), nor have co-chaperones or partner proteins been identified. In addition, although Hsp90 binds ADP/ATP with micromolar affinity (11), the binding constant for adenosine nucleotides to GRP94 is estimated to be of several millimolar units (25). These differences suggest that the structure of GRP94 may reveal an alternative regulatory mechanism for GRP94. The structure of the N-domain of GRP94 in complex with a series of inhibitory ligands was reported recently and...

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“…The functional consequences of these changes are still largely unclear. One of the few functional correlations of these rearrangements is that binding of the cofactor p23 requires ATP bound to Hsp90 (28) and the dimeric form of the N-terminal domains (22,29).…”

Section: Discussionmentioning

confidence: 99%

“…Here, cross-linking data indicate that the N-terminal domains associate in the presence of AMP-PNP, which had been suggested previously based on electron microscopic data (26). This seems to be a prerequisite for the association of Hsp90 with the co-chaperone p23, which is known to occur after ATP-binding (27,28,29). In the studies of Weikl et al (22) and Prodromou et al (25), fragments of Hsp90 lacking C-terminal domains were found to be considerably less active than wild-type Hsp90.…”

Section: Hsp90mentioning

confidence: 99%

Coordinated ATP Hydrolysis by the Hsp90 Dimer

Richter

Muschler

Hainzl

et al. 2001

Journal of Biological Chemistry

190

236

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The Hsp90 dimer is a molecular chaperone with an unusual N-terminal ATP binding site. The structure of the ATP binding site makes it a member of a new class of ATP-hydrolyzing enzymes, known as the GHKL family. While for some of the family members structural data on conformational changes occurring after ATP binding are available, these are still lacking for Hsp90. Here we set out to investigate the correlation between dimerization and ATP hydrolysis by Hsp90. The dimerization constant of wild type (WT) Hsp90 was determined to be 60 nM. Heterodimers of WT Hsp90 with fragments lacking the ATP binding domain form readily and exhibit dimerization constants similar to full-length Hsp90. However, the ATPase activity of these heterodimers was significantly lower than that of the wild type protein, indicating cooperative interactions in the N-terminal part of the protein that lead to the activation of the ATPase activity. To further address the contribution of the N-terminal domains to the ATPase activity, we used an Hsp90 point mutant that is unable to bind ATP. Since heterodimers between the WT protein and this mutant showed WT ATPase activity, this mutant, although unable to bind ATP, still has the ability to stimulate the activity in its WT partner domain. Thus, contact formation between the N-terminal domains might not depend on ATP bound to both domains. Together, these results suggest a mechanism for coupling the hydrolysis of ATP to the opening-closing movement of the Hsp90 molecular chaperone.

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Dimerization and N-terminal domain proximity underlie the function of the molecular chaperone heat shock protein 90

Cited by 146 publications

References 50 publications

Molecular Imaging of the Efficacy of Heat Shock Protein 90 Inhibitors in Living Subjects

Molecular Imaging of the Efficacy of Heat Shock Protein 90 Inhibitors in Living Subjects

Ligand-induced Conformational Shift in the N-terminal Domain of GRP94, an Hsp90 Chaperone

Coordinated ATP Hydrolysis by the Hsp90 Dimer

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