辅分子伴侣调控热休克蛋白HSP90功能的研究

热休克蛋白90(HSP90)是一类ATPase依赖性蛋白,作为分子伴侣,可在辅分子伴侣协助下,通过自身构象改变,参与众多细胞的生物学事件,从而协助新合成蛋白的正确折叠、成功装配、功能稳定及异常蛋白的降解过程。HSP90功能的发挥依赖于辅分子伴侣及氨基末端结合的核苷酸。辅分子伴侣是一类可与分子伴侣(如,HSP90)结合并调节其功能的蛋白,通过参与ATPase循环从而调节HSP90分子伴侣的功能。近年来,辅分子伴侣的研究得到越来越多的关注,本文就辅分子伴侣调控HSP90功能的作用进行综述。     

Hsp90伴侣复合体装配及对类固醇受体调节

真核细胞中近100种蛋白质都受Hsp90的调节。这些蛋白质多与信号转导作用有关,它们与Hsp90一起进入一个以Hsp90/Hsp70为主的伴侣复合体,在复合体内完成信号转导作用。Hsp90除了和蛋白质的伴侣位点结合以外,还在其他位点与辅助因子连接,这是Hsp90能与蛋白质及辅助因子组装成复合体,并进而调节其信号作用的结构基础。类固醇受体等蛋白质的信号转导作用是在Hsp70、Hsp90为基础的5种蛋白质(Hsp90,Hsp70,Hop,Hsp40和p23)组成的复合体中进行的。这个系统可以帮助理解在真核细胞中,Hsp70和Hsp90怎样联合作用,改变底物蛋白构象,以及怎样应答信号作用。     

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．     

Hsp90分子抑制剂拮抗肿瘤耐药的研究进展

Hsp90作为热休克蛋白家族中的重要一员,是一种对细胞生存所必需的分子伴侣,它发挥着稳定顾客蛋白构象、维持其功能的作用。许多顾客蛋白在肿瘤中处于过度表达或持续激活状态,与肿瘤的发生发展有着密切的关系。因此,Hsp90在近年的研究中倍受关注,已经发展为抗肿瘤治疗的良好靶点,目前已经有多个Hsp90抑制剂进入临床实验。近年随着肿瘤分子生物学的研究,肿瘤分子靶向治疗已取得明显成果,针对多种癌症已获得了多个用于靶向治疗的单克隆抗体或小分子化学物质,如用于治疗某些HER2阳性乳腺癌的曲妥珠单抗、用于治疗NSCLC的吉非替尼等。然而随着这些药物的应用,肿瘤耐药性不可避免的产生。多方面研究表明Hsp90抑制剂会引起与耐药相关的多个分子的降解,提示其在拮抗耐药方面具有重要的意义。本文就Hsp90分子抑制剂在拮抗肿瘤耐药方面的研究进行综述。     

FS36作为新型人源Hsp90抑制剂的发现（英文）

热休克蛋白90(Hsp90)通过对几百种蛋白质底物(客户蛋白质)进行合理的折叠、成熟其构象并且激活,在肿瘤细胞的生长和繁殖中发挥重要作用.因此,Hsp90成为非常有吸引力、有前途的抗肿瘤药物靶点,并且超过20种抑制剂已经进入临床实验阶段.我们在这里设计并合成了一个小分子抑制剂:FS36.收集了Hsp90~N-FS36复合物晶体结构的X射线衍射实验数据.高分辨率X射线晶体结构表明,FS36在ATP结合位点上与Hsp90~N相互作用,并且FS36可能替代核苷酸与Hsp90~N结合.FS36和Hsp90~N的复合物晶体结构和相互作用为后期设计和优化新型抗肿瘤药物奠定基础.     

FS36作为新型人源Hsp90抑制剂的发现

热休克蛋白90(Hsp90)通过对几百种蛋白质底物(客户蛋白质)进行合理的折叠、成熟其构象并且激活,在肿瘤细胞的生长和繁殖中发挥重要作用．因此,Hsp90成为非常有吸引力、有前途的抗肿瘤药物靶点,并且超过20种抑制剂已经进入临床实验阶段．我们在这里设计并合成了一个小分子抑制剂：FS36．收集了Hsp90^N-FS36复合物晶体结构的X射线衍射实验数据．高分辨率X射线晶体结构表明,FS36在ATP结合位点上与Hsp90^N相互作用,并且FS36可能替代核苷酸与Hsp90^N结合．FS36和Hsp90^N的复合物晶体结构和相互作用为后期设计和优化新型抗肿瘤药物奠定基础．     

组蛋白去乙酰化酶6:异常蛋白降解的关键调控因子

组蛋白去乙酰化酶6(HDAC6)是位于胞浆中的一种去乙酰化酶,参与调控细胞内多种重要的生物活性,可使α-微管蛋白(α-tubulin)、热休克蛋白90(Hsp90)和皮肌动蛋白(cortactin)去乙酰化,并与多种蛋白质缔结形成复合物。在细胞培养中,当产生的错误折叠蛋白超过了分子伴侣再折叠及泛素蛋白酶体系统(UPS)处理能力时,HDAC6可将其特异转运到细胞核周结构——异常蛋白包涵体(aggresome)中,从而使之被自噬有效降解,因此认为HDAC6在异常蛋白降解中发挥了关键的调控功能,是"蛋白构象病"的潜在治疗靶点。     

TPR蛋白对Hsp90功能的调节

热激蛋白Hsp90是一类在进化中形成的高度保守的且可参与多种细胞功能的特异分子伴侣。TPR蛋白通常存在于Hsp90的多蛋白质复合物中,它对Hsp90的功能的多样性起着至关重要的作用,同时Hsp90可能为TPR蛋白提供“泊位”,允许不同的TPR蛋白在Hsp90分子伴侣底物附近有序而特异结合,从而使Hsp90在细胞内环境中以特定的方式完成其各种细胞功能。了解TPR蛋白与Hsp90的相互作用机制为阐明细胞内Hsp90的功能多样性和特异性奠定了基础。     

Hsp90抑制剂的研究进展

热激蛋白90(heat shock protein90,Hsp90)作为分子伴侣在调节细胞生长、分化、凋亡等方面发挥着重要的作用。Hsp90抑制剂能与Hsp90结合,使其功能丧失,造成细胞的多种生理活动缺陷,在Hsp90功能研究和癌症治疗方面具有潜在的价值。综述了不同来源的Hsp90抑制剂及其作用机制,同时对新型Hsp90抑制剂的来源进行了探讨。     

Coordinated ATP hydrolysis by the Hsp90 dimer.

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.     

Stimulation of the weak ATPase activity of human hsp90 by a client protein.

Heat shock protein 90 (Hsp90) is a molecular chaperone involved in the folding and assembly of a limited set of "client" proteins, many of which are involved in signal transduction pathways. In vivo, it is found in complex with additional proteins, including the chaperones Hsp70, Hsp40, Hip and Hop (Hsp-interacting and Hsp-organising proteins, respectively), as well as high molecular mass immunophilins, such as FKBP59, and the small acidic protein p23. The role of these proteins in Hsp90-mediated assembly processes is poorly understood. It is known that ATP binding and hydrolysis are essential for Hsp90 function in vivo and in vitro.Here we show, for the first time, that human Hsp90 has ATPase activity in vitro. The ATPase activity is characterised using a sensitive assay based on a chemically modified form of the phosphate-binding protein from Escherichia coli. Human Hsp90 is a very weak ATPase, its activity is significantly lower than that of the yeast homologue, and it has a half-life of ATP hydrolysis of eight minutes at 37 degrees C. Using a physiological substrate of Hsp90, the ligand-binding domain of the glucocorticoid receptor, we show that this "client" protein can stimulate the ATPase activity up to 200-fold. This effect is highly specific and unfolded or partially folded proteins, which are known to bind to Hsp90, do not affect the ATPase activity. In addition, the peroxisome proliferator-activated receptor, which is related in both sequence and structure to the glucocorticoid receptor but which does not bind Hsp90, has no observable effect on the ATPase activity.We establish the effect of the co-chaperones Hop, FKBP59 and p23 on the basal ATPase activity as well as the client protein-stimulated ATPase activity of human Hsp90. In contrast with the yeast system, human Hop has little effect on the basal rate of ATP hydrolysis but significantly inhibits the client-protein stimulated rate. Similarly, FKBP59 has little effect on the basal rate but stimulates the client-protein stimulated rate further. In contrast, p23 inhibits both the basal and stimulated rates of ATP hydrolysis.Our results show that the ATPase activity of human Hsp90 is highly regulated by both client protein and co-chaperone binding. We suggest that the rate of ATP hydrolysis is critical to the mode of action of Hsp90, consistent with results that have shown that both over and under-active ATPase mutants of yeast Hsp90 have impaired function in vivo. We suggest that the tight regulation of the ATPase activity of Hsp90 is important and allows the client protein to remain bound to Hsp90 for sufficient time for activation to occur.     

Activation of the ATPase activity of hsp90 by the stress-regulated cochaperone aha1

Client protein activation by Hsp90 involves a plethora of cochaperones whose roles are poorly defined. A ubiquitous family of stress-regulated proteins have been identified (Aha1, activator of Hsp90 ATPase) that bind directly to Hsp90 and are required for the in vivo Hsp90-dependent activation of clients such as v-Src, implicating them as cochaperones of the Hsp90 system. In vitro, Aha1 and its shorter homolog, Hch1, stimulate the inherent ATPase activity of yeast and human Hsp90. The identification of these Hsp90 cochaperone activators adds to the complex roles of cochaperones in regulating the ATPase-coupled conformational changes of the Hsp90 chaperone cycle.     

Regulation of Hsp90 ATPase activity by tetratricopeptide repeat (TPR)-domain co-chaperones.

The in vivo function of the heat shock protein 90 (Hsp90) molecular chaperone is dependent on the binding and hydrolysis of ATP, and on interactions with a variety of co-chaperones containing tetratricopeptide repeat (TPR) domains. We have now analysed the interaction of the yeast TPR-domain co-chaperones Sti1 and Cpr6 with yeast Hsp90 by isothermal titration calorimetry, circular dichroism spectroscopy and analytical ultracentrifugation, and determined the effect of their binding on the inherent ATPase activity of Hsp90. Sti1 and Cpr6 both bind with sub-micromolar affinity, with Sti1 binding accompanied by a large conformational change. Two co-chaperone molecules bind per Hsp90 dimer, and Sti1 itself is found to be a dimer in free solution. The inherent ATPase activity of Hsp90 is completely inhibited by binding of Sti1, but is not affected by Cpr6, although Cpr6 can reactivate the ATPase activity by displacing Sti1 from Hsp90. Bound Sti1 makes direct contact with, and blocks access to the ATP-binding site in the N-terminal domain of Hsp90. These results reveal an important role for TPR-domain co-chaperones as regulators of the ATPase activity of Hsp90, showing that the ATP-dependent step in Hsp90-mediated protein folding occurs after the binding of the folding client protein, and suggesting that ATP hydrolysis triggers client-protein release.     

ATP binding and hydrolysis are essential to the function of the Hsp90 molecular chaperone in vivo.

Hsp90 is an abundant molecular chaperone essential to the establishment of many cellular regulation and signal transduction systems, but remains one of the least well described chaperones. The biochemical mechanism of protein folding by Hsp90 is poorly understood, and the direct involvement of ATP has been particularly contentious. Here we demonstrate in vitro an inherent ATPase activity in both yeast Hsp90 and the Escherichia coli homologue HtpG, which is sensitive to inhibition by the Hsp90-specific antibiotic geldanamycin. Mutations of residues implicated in ATP binding and hydrolysis by structural studies abolish this ATPase activity in vitro and disrupt Hsp90 function in vivo. These results show that Hsp90 is directly ATP dependent in vivo, and suggest an ATP-coupled chaperone cycle for Hsp90-mediated protein folding.     

Virtual prototyping study shows increased ATPase activity of Hsp90 to be the key determinant of cancer phenotype

Hsp90 is an ATP-dependent molecular chaperone that regulates key signaling proteins and thereby impacts cell growth and development. Chaperone cycle of Hsp90 is regulated by ATP binding and hydrolysis through its intrinsic ATPase activities, which is in turn modulated by interaction with its co-chaperones. Hsp90 ATPase activity varies in different organisms and is known to be increased in tumor cells. In this study we have quantitatively analyzed the impact of increasing Hsp90 ATPase activity on the activities of its clients through a virtual prototyping technology, which comprises a dynamic model of Hsp90 interaction with clients involved in proliferation pathways. Our studies highlight the importance of increased ATPase activity of Hsp90 in cancer cells as the key modulator for increased proliferation and survival. A tenfold increase in ATPase activity of Hsp90 often seen in cancer cells increases the levels of active client proteins such as Akt-1, Raf-1 and Cyclin D1 amongst others to about 12-, 8- and 186-folds respectively. Additionally we studied the effect of a competitive inhibitor of Hsp90 activity on the reduction in the client protein levels. Virtual prototyping experiments corroborate with findings that the drug has almost 10- to 100-fold higher affinity as indicated by a lower IC₅₀ value (30–100 nM) in tumor cells with higher ATPase activity. The results also indicate a 15- to 25-fold higher efficacy of the inhibitor in reducing client levels in tumor cells. This analysis provides mechanistic insights into the links between increased Hsp90 ATPase activity, tumor phenotype and the hypersensitivity of tumor Hsp90 to inhibition by ATP analogs.     

Dynamic Aha1 co‐chaperone binding to human Hsp90

Hsp90 is an essential chaperone that requires large allosteric changes to determine its ATPase activity and client binding. The co‐chaperone Aha1, which is the major ATPase stimulator in eukaryotes, is important for regulation of Hsp90's allosteric timing. Little is known, however, about the structure of the Hsp90/Aha1 complex. Here, we characterize the solution structure of unmodified human Hsp90/Aha1 complex using NMR spectroscopy. We show that the 214‐kDa complex forms by a two‐step binding mechanism and adopts multiple conformations in the absence of nucleotide. Aha1 induces structural changes near Hsp90's nucleotide‐binding site, providing a basis for its ATPase‐enhancing activity. Our data reveal important aspects of this pivotal chaperone/co‐chaperone interaction and emphasize the relevance of characterizing dynamic chaperone structures in solution.     

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.     

Evolution and function of diverse Hsp90 homologs and cochaperone proteins

Members of the Hsp90 molecular chaperone family are found in the cytosol, ER, mitochondria and chloroplasts of eukaryotic cells, as well as in bacteria. These diverse family members cooperate with other proteins, such as the molecular chaperone Hsp70, to mediate protein folding, activation and assembly into multiprotein complexes. All examined Hsp90 homologs exhibit similar ATPase rates and undergo similar conformational changes. One of the key differences is that cytosolic Hsp90 interacts with a large number of cochaperones that regulate the ATPase activity of Hsp90 or have other functions, such as targeting clients to Hsp90. Diverse Hsp90 homologs appear to chaperone different types of client proteins. This difference may reflect either the pool of clients requiring Hsp90 function or the requirement for cochaperones to target clients to Hsp90. This review discusses known functions, similarities and differences between Hsp90 family members and how cochaperones are known to affect these functions. This article is part of a Special Issue entitled: Heat Shock Protein 90 (HSP90).