Joungnam Kim

Roles of heat-shock protein 90 in maintaining and facilitating the neurodegenerative phenotype in tauopathies

Neurodegeneration, a result of multiple dysregulatory events, is a lengthy multistep process manifested by accrual of mutant variants and abnormal expression, posttranslational modification, and processing of certain proteins. Accumulation of these dysregulated processes requires a mechanism that maintains their functional stability and allows the evolution of the neurodegenerative phenotype. In malignant cells, the capacity to buffer transformation has been attributed to heat-shock protein 90 (Hsp90). Although normal proteins seem to require limited assistance from the chaperone, their aberrant counterparts seem to be highly dependent on Hsp90. Whereas enhanced Hsp90 affinity for mutated or functionally deregulated client proteins has been observed for several oncoproteins, it is unknown whether Hsp90 plays a similar role for neuronal proteins and thus maintains and facilitates the transformed phenotype in neurodegenerative diseases. Tauopathies are neurodegenerative diseases characterized by aberrant phosphorylation and/or expression of Tau protein, leading to a time-dependent accumulation of Tau aggregates and subsequent neuronal death. Here, we show that the stability of p35, a neuronal protein that activates cyclin-dependent protein kinase 5 through complex formation leading to aberrant Tau phosphorylation, and that of mutant but not WT Tau protein is maintained in tauopathies by Hsp90. Inhibition of Hsp90 in cellular and mouse models of tauopathies leads to a reduction of the pathogenic activity of these proteins and results in elimination of aggregated Tau. The results identify important roles played by Hsp90 in maintaining and facilitating the degenerative phenotype in these diseases and provide a common principle governing cancer and neurodegenerative diseases.

Hsp90: the vulnerable chaperone

The molecular chaperone Hsp90 has emerged as an important target in cancer treatment because of its roles in maintaining transformation and regulating the function of proteins involved in apoptotic, survival and growth pathways. Many Hsp90 inhibitors function by binding to the N-terminal ATP pocket, but the chaperone has many other vulnerable points. Agents that interact with its C-terminus or modify its post-translational status represent additional ways of interfering with chaperone activity. This review will discuss several emerging classes of Hsp90 inhibitors and their modes of action.

Development of a Fluorescence Polarization Assay for the Molecular Chaperone Hsp90

Heat shock protein 90 (Hsp90) is a molecular chaperone with essential functions in maintaining transformation, and there is increasing interest in developing Hsp90 inhibitors as cancer therapeutics. In this study, the authors describe the development and optimization of a novel assay for the identification of Hsp90 inhibitors using fluorescence polarization. The assay is based on the competition of fluorescently (BODIPY) labeled geldanamycin (GM) for binding to purified recombinant Hsp90α (GM is a natural product that binds to the ATP/ADP pocket in the amino terminal of Hsp90). The authors show that GM-BODIPY binds Hsp90α with high affinity. Even at low Hsp90α concentrations (30 nM), the measured polarization value is close to the maximum assay range of 160 mP, making measurements very sensitive. Its performance, as judged by signal-to-noise ratios (> 10) and Z and Z′ values (> 0.5), suggests that this is a robust and reliable assay. GM, PU24FCl, ADP, and ATP, all known to bind to the Hsp90 pocket, compete with GM-BODIPY for binding to Hsp90α with EC50s in agreement with reported values. These data demonstrate that the Hsp90-FP-based assay can be used for high-throughput screening in aiding the identification of novel Hsp90 inhibitors.

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

Heat shock protein 90 alpha (Hsp90 alpha)/p23 and Hsp90 beta/p23 interactions are crucial for proper folding of proteins involved in cancer and neurodegenerative diseases. Small molecule Hsp90 inhibitors block Hsp90 alpha/p23 and Hsp90 beta/p23 interactions in part by preventing ATP binding to Hsp90. The importance of isoform-selective Hsp90 alpha/p23 and Hsp90 beta/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 Hsp90 alpha/p23 and Hsp90 beta/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 purine-scaffold 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 Hsp90 alpha/p23 and Hsp90 beta/p23 split reporters respectively, relative to carrier control-treated mice. Molecular imaging of isoform-specific Hsp90 alpha/p23 and Hsp90 beta/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 isoform-selective Hsp90 inhibitors.

Design of a Flexible Cell-Based Assay for the Evaluation of Heat Shock Protein 70 Expression Modulators

Heat shock protein 70 (Hsp70) is a chaperone protein that helps protect against cellular stress, a function that may be co-opted to fight human diseases. In particular, the upregulation of Hsp70 can suppress the neurotoxicity of misfolded proteins, suggesting possible therapeutic strategies in neurodegenerative diseases. Alternatively, in cancer cells where high levels of Hsp70 inhibit both intrinsic and extrinsic apoptotic pathways, a reduction in Hsp70 levels may induce apoptosis. To evaluate and identify, in a single assay format, small molecules that induce or inhibit endogenous Hsp70, we have designed and optimized a microtiter assay that relies on whole-cell immunodetection of Hsp70. The assay utilizes a minimal number of neuronal or cancer cells, yet is sufficiently sensitive and reproducible to permit quantitative determinations. We further validated the assay using a panel of Hsp70 modulators. In conclusion, we have developed an assay that is fast, robust, and cost efficient. As such, it can be implemented in most research laboratories. The assay should greatly improve the speed at which novel Hsp70 inducers and inhibitors of expression can be identified and evaluated.