N-terminal residues regulate the catalytic efficiency of the Hsp90 ATPase cycle

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.     

The ATPase cycle of the mitochondrial Hsp90 analog Trap1

Hsp90 is an ATP-dependent molecular chaperone whose mechanism is not yet understood in detail. Here, we present the first ATPase cycle for the mitochondrial member of the Hsp90 family called Trap1 (tumor necrosis factor receptor-associated protein 1). Using biochemical, thermodynamic, and rapid kinetic methods we dissected the kinetics of the nucleotide-regulated rearrangements between the open and the closed conformations. Surprisingly, upon ATP binding, Trap1 shifts predominantly to the closed conformation (70%), but, unlike cytosolic Hsp90 from yeast, this process is rather slow at 0.076 s(-1). Because reopening (0.034 s(-1)) is about ten times faster than hydrolysis (k(hyd) = 0.0039 s(-1)), which is the rate-limiting step, Trap1 is not able to commit ATP to hydrolysis. The proposed ATPase cycle was further scrutinized by a global fitting procedure that utilizes all relevant experimental data simultaneously. This analysis corroborates our model of a two-step binding mechanism of ATP followed by irreversible ATP hydrolysis and a one-step product (ADP) release.     

Conserved conformational changes in the ATPase cycle of human Hsp90

The dimeric molecular chaperone Hsp90 is required for the activation and stabilization of hundreds of substrate proteins, many of which participate in signal transduction pathways. The activation process depends on the hydrolysis of ATP by Hsp90. Hsp90 consists of a C-terminal dimerization domain, a middle domain, which may interact with substrate protein, and an N-terminal ATP-binding domain. A complex cycle of conformational changes has been proposed for the ATPase cycle of yeast Hsp90, where a critical step during the reaction requires the transient N-terminal dimerization of the two protomers. The ATPase cycle of human Hsp90 is less well understood, and significant differences have been proposed regarding key mechanistic aspects. ATP hydrolysis by human Hsp90alpha and Hsp90beta is 10-fold slower than that of yeast Hsp90. Despite these differences, our experiments suggest that the underlying enzymatic mechanisms are highly similar. In both cases, a concerted conformational rearrangement involving the N-terminal domains of both subunits is controlling the rate of ATP turnover, and N-terminal cross-talk determines the rate-limiting steps. Furthermore, similar to yeast Hsp90, the slow ATP hydrolysis by human Hsp90s can be stimulated up to over 100-fold by the addition of the co-chaperone Aha1 from either human or yeast origin. Together, our results show that the basic principles of the Hsp90 ATPase reaction are conserved between yeast and humans, including the dimerization of the N-terminal domains and its regulation by the repositioning of the ATP lid from its original position to a catalytically competent one.     

Co-chaperone regulation of conformational switching in the Hsp90 ATPase cycle

ATP hydrolysis by the Hsp90 molecular chaperone requires a connected set of conformational switches triggered by ATP binding to the N-terminal domain in the Hsp90 dimer. Central to this is a segment of the structure, which closes like a "lid" over bound ATP, promoting N-terminal dimerization and assembly of a competent active site. Hsp90 mutants that influence these conformational switches have strong effects on ATPase activity. ATPase activity is specifically regulated by Hsp90 co-chaperones, which directly influence the conformational switches. Here we have analyzed the effect of Hsp90 mutations on binding (using isothermal titration calorimetry and difference circular dichroism) and ATPase regulation by the co-chaperones Aha1, Sti1 (Hop), and Sba1 (p23). The ability of Sti1 to bind Hsp90 and arrest its ATPase activity was not affected by any of the mutants screened. Sba1 bound in the presence of AMPPNP to wild-type and ATPase hyperactive mutants with similar affinity but only very weakly to hypoactive mutants despite their wild-type ATP affinity. Unexpectedly, in all cases Sba1 bound to Hsp90 with a 1:2 molar stoichiometry. Aha1 binding to mutants was similar to wild-type, but the -fold activation of their ATPase varied substantially between mutants. Analysis of complex formation with co-chaperone mixtures showed Aha1 and p50cdc37 able to bind Hsp90 simultaneously but without direct interaction. Sba1 and p50cdc37 bound independently to Hsp90-AMPPNP but not together. These data indicated that Sba1 and Aha1 regulate Hsp90 by influencing the conformational state of the "ATP lid" and consequent N-terminal dimerization, whereas Sti1 does not.     

Synthesis of Hsp90 dimerization modulators

The synthesis and evaluation of several chemical modulators of heat shock protein 90 (Hsp90) dimerization is presented. These agents may represent useful tools to study the importance of N-terminal dimerization and also to determine subunit interface(s) in Hsp90.     

The co-chaperone p23 arrests the Hsp90 ATPase cycle to trap client proteins

The action of the molecular chaperone Hsp90 is essential for the activation and assembly of an increasing number of client proteins. This function of Hsp90 has been proposed to be governed by conformational changes driven by ATP binding and hydrolysis. Association of co-chaperones and client proteins regulate the ATPase activity of Hsp90. Here, we have examined the inhibition of the ATPase activity of human Hsp90beta by one such co-chaperone, human p23. We demonstrate that human p23 interacts with Hsp90 in both the absence and presence of nucleotide with a higher affinity in the presence of the ATP analogue AMP-PNP. This is consistent with an analysis of the effect of p23 on the steady-state kinetics that revealed a mixed mechanism of inhibition. Mass spectrometry of the intact Hsp90.p23 complex determined the stoichiometry of binding to be one p23 to each subunit of the Hsp90 dimer. p23 was also shown to interact with a monomeric, truncated fragment of Hsp90, lacking the C-terminal homodimerisation domain, indicating dimerisation of Hsp90 is not a prerequisite for association with p23. Complex formation between Hsp90 and p23 increased the apparent affinity of Hsp90 for AMP-PNP and completely inhibited the ATPase activity. We propose a model where the role of p23 is to lock individual subunits of Hsp90 in an ATP-dependent conformational state that has a high affinity for client proteins.     

Dissection of the contribution of individual domains to the ATPase mechanism of Hsp90

Hsp90 is a dimeric, ATP-regulated molecular chaperone. Its ATPase cycle involves the N-terminal ATP binding domain (amino acids (aa) 1-272) and, in addition, to some extent the middle domain (aa 273-528) and the C-terminal dimerization domain (aa 529-709). To analyze the contribution of the different domains and the oligomeric state on the progression of the ATPase cycle of yeast Hsp90, we created deletion constructs lacking either the C-terminal or both the C-terminal and the middle domain. To test the effect of dimerization on the ATPase activity of the different constructs, we introduced a Cys residue at the C-terminal ends of the constructs, which allowed covalent dimerization. We show that all monomeric constructs tested exhibit reduced ATPase activity and a decreased affinity for ATP in comparison with wild type Hsp90. The covalently linked dimers lacking only the C-terminal domain hydrolyze ATP as efficiently as the wild type protein. Furthermore, this construct is able to trap the ATP molecule similar to the full-length protein. This demonstrates that in the ATPase cycle, the C-terminal domain can be replaced by a cystine bridge. In contrast, the ATPase activity of the artificially linked N-terminal domains remains very low and bound ATP is not trapped. Taken together, we show that both the dimerization of the N-terminal domains and the association of the N-terminal with the middle domain are important for the efficiency of the ATPase cycle. These reactions are synergistic and require Hsp90 to be in the dimeric state.     

Substrate binding drives large-scale conformational changes in the Hsp90 molecular chaperone

Hsp90 is a ubiquitous molecular chaperone. Previous structural analysis demonstrated that Hsp90 can adopt a large number of structurally distinct conformations; however, the functional role of this flexibility is not understood. Here we investigate the structural consequences of substrate binding with a model system in which Hsp90 interacts with a partially folded protein (Δ131Δ), a well-studied fragment of staphylococcal nuclease. SAXS measurements reveal that under apo conditions, Hsp90 partially closes around Δ131Δ, and in the presence of AMPPNP, Δ131Δ binds with increased affinity to Hsp90's fully closed state. FRET measurements show that Δ131Δ accelerates the nucleotide-driven open/closed transition and stimulates ATP hydrolysis by Hsp90. NMR measurements reveal that Hsp90 binds to a specific, highly structured region of Δ131Δ. These results suggest that Hsp90 preferentially binds a locally structured region in a globally unfolded protein, and this binding drives functional changes in the chaperone by lowering a rate-limiting conformational barrier.     

Intrinsic inhibition of the Hsp90 ATPase activity

The molecular chaperone Hsp90 is required for the folding and activation of a large number of substrate proteins. These are involved in essential cellular processes ranging from signal transduction to viral replication. For the activation of its substrates, Hsp90 binds and hydrolyzes ATP, which is the key driving force for conformational conversions within the dimeric chaperone. Dimerization of Hsp90 is mediated by a C-terminal dimerization site. In addition, there is a transient ATP-induced dimerization of the two N-terminal ATP-binding domains. The resulting ring-like structure is thought to be the ATPase-active conformation. Hsp90 is a slow ATPase with a turnover number of 1 ATP/min for the yeast protein. A key question for understanding the molecular mechanism of Hsp90 is how ATP hydrolysis is regulated and linked to conformational changes. In this study, we analyzed the activation process structurally and biochemically with a view to identify the conformational limitations of the ATPase reaction cycle. We showed that the first 24 amino acids stabilize the N-terminal domain in a rigid state. Their removal confers flexibility specifically to the region between amino acids 98 and 120. Most surprisingly, the deletion of this structure results in the complete loss of ATPase activity and in increased N-terminal dimerization. Complementation assays using heterodimeric Hsp90 show that this rigid lid acts as an intrinsic kinetic inhibitor of the Hsp90 ATPase cycle preventing N-terminal dimerization in the ground state. On the other hand, this structure acts, in concert with the 24 N-terminal amino acids of the other N-terminal domain, to form an activated ATPase and thus regulates the turnover number of Hsp90.     

C-terminal regions of Hsp90 are important for trapping the nucleotide during the ATPase cycle

Hsp90 is an abundant molecular chaperone that functions in an ATP-dependent manner in vivo. The ATP-binding site is located in the N-terminal domain of Hsp90. Here, we dissect the ATPase cycle of Hsp90 kinetically. We find that Hsp90 binds ATP with a two-step mechanism. The rate-limiting step of the ATPase cycle is the hydrolysis of ATP. Importantly, ATP becomes trapped and committed to hydrolyze during the cycle. In the isolated ATP-binding domain of Hsp90, however, the bound ATP was not committed and the turnover numbers were markedly reduced. Analysis of a series of truncation mutants of Hsp90 showed that C-terminal regions far apart in sequence from the ATP-binding domain are essential for trapping the bound ATP and for maximum hydrolysis rates. Our results suggest that ATP binding and hydrolysis drive conformational changes that involve the entire molecule and lead to repositioning of the N and C-terminal domains of Hsp90.     

Conformational switching of the molecular chaperone Hsp90 via regulated phosphorylation

Hsp90 is an essential molecular chaperone in the eukaryotic cytosol. Its function is modulated by cochaperones and posttranslational modifications. Importantly, the phosphatase Ppt1 is a dedicated regulator of the Hsp90 chaperone system. Little is known about Ppt1-dependent phosphorylation sites and how these affect Hsp90 activity. Here, we identified the major phosphorylation sites of yeast Hsp90 in its middle or the C-terminal domain and determined the subset regulated by Ppt1. In general, phosphorylation decelerates the Hsp90 machinery, reduces chaperone function in vivo, sensitizes yeast cells to Hsp90 inhibition and affects DNA repair processes. Modification of one particular site (S485) is lethal, whereas others modulate Hsp90 activity via distinct mechanisms affecting the ATPase activity, cochaperone binding and manipulating conformational transitions in Hsp90. Our mechanistic analysis reveals that phosphorylation of Hsp90 permits a regulation of the conformational cycle at distinct steps by targeting switch points for the communication of remote regions within Hsp90.     

The Co-chaperone Sba1 connects the ATPase reaction of Hsp90 to the progression of the chaperone cycle

The molecular chaperone Hsp90 mediates the ATP-dependent activation of a large number of proteins involved in signal transduction. During this process, Hsp90 was found to associate transiently with several accessory factors, such as p23/Sba1, Hop/Sti1, and prolyl isomerases. It has been shown that ATP hydrolysis triggers conformational changes within Hsp90, which in turn are thought to mediate conformational changes in the substrate proteins, thereby causing their activation. The specific role of the partner proteins in this process is unknown. Using proteins from Saccharomyces cerevisiae, we characterized the interaction of Hsp90 with its partner protein p23/Sba1. Our results show that the nucleotide-dependent N-terminal dimerization of Hsp90 is necessary for the binding of Sba1 to Hsp90 with an affinity in the nanomolar range. Two Sba1 molecules were found to bind per Hsp90 dimer. Sba1 binding to Hsp90 resulted in a decreased ATPase activity, presumably by trapping the hydrolysis state of Hsp90ATP. Ternary complexes of Hsp90Sba1 could be formed with the prolyl isomerase Cpr6, but not with Sti1. Based on these findings, we propose a model that correlates the ordered assembly of the Hsp90 co-chaperones with distinct steps of the ATP hydrolysis reaction during the chaperone cycle.     

热休克蛋白90三磷酸腺苷酶的调控机制研究

热休克蛋白90（heat shock protein90,Hsp90）是一类在生物进化中高度保守的蛋白,与细胞凋亡密切相关,作为抗癌新靶标已经得到了广泛的关注。相关研究表明,Hsp90可以通过多种方式调控ATPase的活性,如自身构象改变、与辅伴侣分子形成复合物以及转录后修饰等。在Hsp90基本构象改变的基础上,综述了不同因素对ATPase的调控作用,着重阐述近几年的研究进展,为进一步研究Hsp90调控ATPase的机制提供一定的参考。     

Tamoxifen Enhances the Hsp90 Molecular Chaperone ATPase Activity

Background

Hsp90 is an essential molecular chaperone that is also a novel anti-cancer drug target. There is growing interest in developing new drugs that modulate Hsp90 activity.

Methodology/Principal Findings

Using a virtual screening approach, 4-hydroxytamoxifen, the active metabolite of the anti-estrogen drug tamoxifen, was identified as a putative Hsp90 ligand. Surprisingly, while all drugs targeting Hsp90 inhibit the chaperone ATPase activity, it was found experimentally that 4-hydroxytamoxifen and tamoxifen enhance rather than inhibit Hsp90 ATPase.

Conclusions/Significance

Hence, tamoxifen and its metabolite are the first members of a new pharmacological class of Hsp90 activators.     

热休克蛋白90的N端与ATP类似物的晶体结构揭示其功能调控

分子伴侣热休克蛋白90(Hsp90)对于许多涉及细胞周期调控、信号转导以及细胞生长调控蛋白质的折叠、成熟及稳定是必需的．Hsp90的N端结构高度保守,包含一个ATP结合口袋并具有ATP酶活性,Hsp90的功能依赖于ATP与Hsp90结合后诱导的构象重排及之后的ATP水解．为了深入研究ATP与Hsp90结合后N端的结构及其功能状态,使用悬滴法共结晶了Hsp90的N端与ATP类似物AMPPNP及ATPγS的复合物,并利用分子置换法对其结构进行了解析．两个复合物晶体结构都捕获到了核苷酸的电子密度,尤其是γ-磷酸的电子密度,从而观察到γ-磷酸与蛋白质之间的相互作用．ATPγS中γ-磷酸的捕获证实了之前报道的结构中没有捕获到γ-磷酸是其处于无序状态而非被水解．单体状态下的人源Hsp90^N- AMPPNP与处于二聚体化的酵母Hsp90-AMPPNP结构对比可见S1和ATP lid的位置有明显区别,结构分析表明,E18-K100和N40-D127之间形成的氢键相互作用,在一定程度上阻碍了S1和ATP lid的摆动,很可能阻止了二聚体的形成．     

Domain-mediated dimerization of the Hsp90 cochaperones Harc and Cdc37

Hsp90 is a highly conserved molecular chaperone that acts in concert with Hsp70 and a cohort of cochaperones to mediate the folding of client proteins into functional conformations. The novel Hsp90 cochaperone Harc was identified previously on the basis of its amino acid sequence similarity to Cdc37. Although the biochemical role of Harc has not been established, the structural similarities between Harc and Cdc37 suggest that it too may function to regulate the binding of client proteins to Hsp90. We report here that Harc forms dimers in vitro. Functional dissection of Harc revealed that both the N-terminal and middle domains contributed to its dimerization. Notably, dimerization of the middle domain of Harc was required for the binding of Hsp90, suggesting that dimerized Harc binds to Hsp90 dimers. The N-terminal domain of Harc made an important contribution to the dimerization of Harc by facilitating the interaction of Hsp70 with Harc-Hsp90 heterocomplexes. Harc was also found to heterodimerize with Cdc37 in vitro. Titration experiments revealed that Harc homodimerization was favored over heterodimerization with Cdc37 when both cochaperones were at similar levels. However, formation of Harc homodimers and heterodimers of Harc and Cdc37 was comparable when the level of Cdc37 was approximately 10-fold above that of Harc. Furthermore, homo- and heterodimerization of Harc and Cdc37 was a dynamic process. Thus Harc could potentially contribute to the regulation of the Hsp90-mediated folding of Cdc37-dependent protein kinases into functional conformations via dimerization with Cdc37.     

Structural studies of the Hsp70/Hsp90 organizing protein of Plasmodium falciparum and its modulation of Hsp70 and Hsp90 ATPase activities

HOP is a cochaperone belonging to the foldosome, a system formed by the cytoplasmic Hsp70 and Hsp90 chaperones. HOP acts as an adapter protein capable of transferring client proteins from the first to the second molecular chaperone. HOP is a modular protein that regulates the ATPase activity of Hsp70 and Hsp90 to perform its function. To obtain more detailed information on the structure and function of this protein, we produced the recombinant HOP of Plasmodium falciparum (PfHOP). The protein was obtained in a folded form, with a high content of α-helix secondary structure. Unfolding experiments showed that PfHOP unfolds through two transitions, suggesting the presence of at least two domains with different stabilities. In addition, PfHOP primarily behaved as an elongated dimer in equilibrium with the monomer. Small-angle X-ray scattering data corroborated this interpretation and led to the reconstruction of a PfHOP ab initio model as a dimer. Finally, the PfHOP protein was able to inhibit and to stimulate the ATPase activity of the recombinant Hsp90 and Hsp70–1, respectively, of P. falciparum. Our results deepened the knowledge of the structure and function of PfHOP and further clarified its participation in the P. falciparum foldosome.