Activation of Hsp70 reduces neurotoxicity by promoting polyglutamine protein degradation
We sought novel strategies to reduce levels of the polyglutamine androgen receptor (polyQ AR) and achieve therapeutic benefits in models of spinobulbar muscular atrophy (SBMA), a protein aggregation neurodegenerative disorder. Proteostasis of the polyQ AR is controlled by the Hsp90/Hsp70-based chaperone machinery, but mechanisms regulating the protein’s turnover are incompletely understood. We demonstrate that overexpression of Hip, a co-chaperone that enhances binding of Hsp70 to its substrates, promotes client protein ubiquitination and polyQ AR clearance. Furthermore, we identify a small molecule that acts similarly to Hip by allosterically promoting Hsp70 binding to unfolded substrates. Like Hip, this synthetic co-chaperone enhances client protein ubiquitination and polyQ AR degradation. Both genetic and pharmacologic approaches targeting Hsp70 alleviate toxicity in a Drosophila model of SBMA. These findings highlight the therapeutic potential of allosteric regulators of Hsp70, and provide new insights into the role of the chaperone machinery in protein quality control.
The Hsp90/Hsp70-based chaperone machinery plays a well established role in signaling protein function, trafficking and turnover. A number of recent observations also support the notion that Hsp90 and Hsp70 play key roles in the triage of damaged and aberrant proteins for degradation via the ubiquitin-proteasome pathway. In the mid 1990s, it was discovered that Hsp70 is required for ubiquitin-dependent degradation of short lived and abnormal proteins, and it became clear that inhibition of Hsp90 uniformly leads to the proteasomal degradation of Hsp90 client proteins. Subsequently, CHIP and parkin were shown to be Hsp70-binding ubiquitin E3 ligases that direct ubiquitin-charged E2 enzymes to the Hsp70-bound client protein. The stabilizing effect of Hsp90 reflects the interaction of the chaperone with the ligand binding cleft of the client protein. These hydrophobic clefts must be open to allow passage of ligands to binding sites in the protein interior, and they are inherent sites of conformational instability. Hsp90 stabilizes the open state of the cleft and prevents Hsp70-dependent ubiquitination. In the model we present here, progressive oxidative events result in cleft opening as the initial step in protein unfolding, and as long as Hsp90 can interact to stabilize the cleft, it will buffer the effect of oxidative damage. When cleft opening is such that Hsp90 can no longer interact, Hsp70-dependent ubiquitination occurs. We summarize evidence that Hsp90 interacts very dynamically with a variety of proteins that are not classic Hsp90 clients, and we show that this dynamic cycling with Hsp90 protects against CHIP-mediated ubiquitination. Scientific interest to date has focused on stringent regulation of the classic client proteins, which have metastable clefts and are inherently short lived. But, the recognition that Hsp90 cycles dynamically with longer lived proteins with more stable clefts permits extension of the triage model to the quality control of damaged proteins in general.
It is established that neuronal nitric-oxide synthase (nNOS) is ubiquitylated and proteasomally degraded. The proteasomal degradation of nNOS is enhanced by suicide inactivation of nNOS or by the inhibition of hsp90, which is a chaperone found in a native complex with nNOS. In the current study, we have examined whether CHIP, a chaperone-dependent E3 ubiquitinprotein isopeptide ligase that is known to ubiquitylate other hsp90-chaperoned proteins, could act as an ubiquitin ligase for nNOS. We found with the use of HEK293T or COS-7 cells and transient transfection methods that CHIP overexpression causes a decrease in immunodetectable levels of nNOS. The extent of the loss of nNOS is dependent on the amount of CHIP cDNA used for transfection. Lactacystin (10 M), a selective proteasome inhibitor, attenuates the loss of nNOS in part by causing the nNOS to be found in a detergent-insoluble form. Immunoprecipitation of the nNOS and subsequent Western blotting with an anti-ubiquitin IgG shows an increase in nNOS-ubiquitin conjugates because of CHIP. Moreover, incubation of nNOS with a purified system containing an E1 ubiquitin-activating enzyme, an E2 ubiquitin carrier protein conjugating enzyme (UbcH5a), CHIP, glutathione S-transferase-tagged ubiquitin, and an ATP-generating system leads to the ubiquitylation of nNOS. The addition of purified hsp70 and hsp40 to this in vitro system greatly enhances the amount of nNOSubiquitin conjugates, suggesting that CHIP is an E3 ligase for nNOS whose action is facilitated by (and possibly requires) its interaction with nNOS-bound hsp70. Nitric-oxide synthases (NOSs)1 are cytochrome P450-like hemoprotein enzymes that catalyze the conversion of L-arginine to citrulline and nitric oxide by a process that requires NADPH and molecular oxygen. NOS is bidomain in structure with an oxygenase domain, which contains the cysteine residue that is coordinated to the prosthetic heme as well as the tetrahydrobiopterin binding site, and a reductase domain, which contains the binding sites for FMN, FAD, and NADPH. The NOS is a highly regulated enzyme requiring homodimerization and association with Ca 2ϩ -calmodulin for activity. Another mechanism for regulation involves the selective ubiquitin-dependent proteasomal degradation of dysfunctional NOS (1). This is evident, for example, when metabolism-based or suicide inactivators cause the covalent alteration and inactivation of neuronal NOS (nNOS) and trigger enhanced proteasomal degradation of the enzyme (2). The nature of the factor(s) that selectively recognize dysfunctional nNOS is unknown; however, inhibition of hsp90 leads to enhanced proteasomal degradation of nNOS, implicating the hsp90-based chaperone machinery as a potential regulator of nNOS protein levels (3).Hundreds, perhaps thousands, of cellular proteins are chaperoned by the hsp90/hsp70-based chaperone machinery (4), and it has been proposed that these chaperones play a key role in protein triage decisions that maintain quality control of cellular proteins. CHIP is a U-box-containin...
The molecular chaperone hsp90 has emerged as an important therapeutic target in cancer and neurodegenerative diseases, including the polyglutamine expansion disorders, because of its ability to regulate the activity, turnover and trafficking of many proteins. For neurodegenerative disorders associated with protein aggregation, the rationale has been that inhibition of hsp90 by geldanamycin and related compounds activates heat shock factor 1 (HSF1) to induce the production of the chaperones hsp70 and hsp40 that promote disaggregation and protein degradation. However, we show here that geldanamycin blocks the development of aggregates of the expanded glutamine androgen receptor (AR112Q) of Kennedy disease in Hsf1(-/-) mouse embryonic fibroblasts where these chaperones are not induced. Geldanamycin is additionally known to inhibit hsp90-dependent protein trafficking and to promote proteasomal degradation of client proteins. Overexpression of the hsp90 cochaperone p23 also promotes AR112Q degradation, and inhibits both AR trafficking and AR112Q aggregation without altering levels of hsp70 or hsp40. The hsp90-dependent trafficking mechanism has been defined, and it is shown that key immunophilin (IMM) components of the trafficking machinery are present in polyglutamine aggregates in cell and mouse models of Kennedy disease. Our results indicate that inhibition of the hsp90-dependent trafficking mechanism prevents aggregation of the expanded glutamine androgen receptor, thereby opening a variety of novel therapeutic approaches to these neurodegenerative disorders.
NO production by neuronal nitric oxide synthase (nNOS) requires calmodulin and is enhanced by the chaperone Hsp90, which cycles dynamically with the enzyme. The proteasomal degradation of nNOS is enhanced by suicide inactivation and by treatment with Hsp90 inhibitors, the latter suggesting that dynamic cycling with Hsp90 stabilizes nNOS. Here, we use a purified ubiquitinating system containing CHIP (carboxyl terminus of Hsp70-interacting protein) as the E3 ligase to show that Hsp90 inhibits CHIP-dependent nNOS ubiquitination. Like the established Hsp90 enhancement of NO synthesis, Hsp90 inhibition of nNOS ubiquitination is Ca 2+ /calmodulin-dependent, suggesting that the same interaction of Hsp90 with the enzyme is responsible for both enhancement of nNOS activity and inhibition of ubiquitination. It is established that CHIP binds to Hsp90 as well as to Hsp70, but we show here the two chaperones have opposing actions on nNOS ubiquitination, with Hsp70 stimulating and Hsp90 inhibiting. We have used two mechanism-based inactivators, guanabenz and N G -amino-L-arginine, to alter the heme/substrate binding cleft and promote nNOS ubiquitination that can be inhibited by Hsp90. We envision that as nNOS undergoes toxic damage, the heme/substrate binding cleft opens exposing hydrophobic residues as the initial step in unfolding. As long as Hsp90 can form even transient complexes with the opening cleft, ubiquitination by Hsp70-dependent ubiquitin E3 ligases, like CHIP, is inhibited. When unfolding of the cleft progresses to a state that cannot cycle with Hsp90, Hsp70-dependent ubiquitination is unopposed. In this way, the Hsp70/Hsp90 machinery makes the quality control decision for stabilization versus degradation of nNOS.Both the function and turnover of a wide variety of signaling proteins, such as steroid receptors and protein kinases, are regulated by Hsp90 1 (reviewed in Ref. 1). These Hsp90 'client' proteins are assembled into complexes with the chaperone by a multichaperone machinery in which Hsp90 and Hsp70 function together as essential components (1). Formation of heterocomplexes with Hsp90 stabilizes client proteins, and treatment with an Hsp90 inhibitor such as geldanamycin uniformly triggers their degradation (2). Degradation of the Hsp90-regulated signaling proteins occurs via the ubiquitin-proteasome pathway, which in this case is initiated by Hsp70-dependent E3 ubiquitin ligases, such as CHIP (3) and parkin (4).
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