Celastrol regulates multiple nuclear transcription factors belonging to HSP90's clients in a dose- and cell type-dependent way.

Celastrol, a novel HSP90 inhibitor, has recently attracted much attention due to its potential in multiple applications, such as anti-inflammation use, degenerative neuron disease relief, and tumor management. At present, the studies in celastrol's effects on HSP90's clients have focused on the kinase sub-population, while another key sub-population, nuclear transcription factors (TFs), is not being well-explored. In this study, we observe the effects of celastrol on 18 TFs (belonging to HSP90 clients) in three human cell lines: MCF-7 (breast cancer), HepG2 (hepatoma), and THP-1 (monocytic leukemia). The results show that at least half of the detectable TFs were affected by celastrol, though the effect patterns varied with cell type and dosage. Bi-directional regulations of some TFs were identified, a phenomenon not yet seen with other HSP90 inhibitors. Celastrol's capability to affect multiple TFs was consistent with its altering HSP90/TFs interactions and disrupting HSP90/Hop interaction, in addition to the reported damaging HSP90/Cdc37 interaction. This work confirms, for the first time, that celastrol has broad effects on TFs belonging to HSP90's clients, casts new light on understanding these reported actions, and suggests new possible applications for celastrol, such as diabetes management.

HSP90 inhibitor, celastrol, arrests human monocytic leukemia cell U937 at G0/G1 in thiol-containing agents reversible way.

BACKGROUND: Because some of heat shock protein 90's (HSP90) clients are key cell cycle regulators, HSP90 inhibition can affect the cell cycle. Recently, celastrol is identified both as a novel inhibitor of HSP90 and as a potential anti-tumor agent. However, this agent's effects on the cell cycle are rarely investigated. In this study, we observed the effects of celastrol on the human monocytic leukemia cell line U937 cell cycle. RESULTS: Celastrol affected the proliferation of U937 in a dose-dependent way, arresting the cell cycle at G0/G1 with 400 nM doses and triggering cell death with doses above 1000 nM. Cell cycle arrest was accompanied by inhibition of HSP90 ATPase activity and elevation in HSP70 levels (a biochemical hallmark of HSP90 inhibition), a reduction in Cyclin D1, Cdk4 and Cdk6 levels, and a disruption of the HSP90/Cdc37/Cdk4 complex. The observed effects of celastrol on the U937 cell cycle were thiol-related, firstly because the effects could be countered by pre-loading thiol-containing agents and secondly because celastrol and thiol-containing agents could react with each other to form new compounds. CONCLUSIONS: Our results disclose a novel action of celastrol-- causing cell cycle arrest at G0/G1 phase based upon thiol-related HSP90 inhibition. Our work suggests celastrol's potential in tumor and monocyte-related disease management.