Molecular Characterization of Zoledronic acid Induced Growth Inhibition in Cancer

Zoledronic acid is a nitrogen-containing bisphosphonate widely used in the treatment of bone metastasis secondary to breast cancer. In addition, current clinical trials suggest direct antitumor effects, which may reduce the risk of overall disease progression in breast cancer patients. Consisten...

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Bibliographic Details
Main Author: Singh, Shiv Kishor
Contributors: Ellenrieder, Volker (Prof. Dr.) (Thesis advisor)
Format: Doctoral Thesis
Language:English
Published: Philipps-Universität Marburg 2010
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Summary:Zoledronic acid is a nitrogen-containing bisphosphonate widely used in the treatment of bone metastasis secondary to breast cancer. In addition, current clinical trials suggest direct antitumor effects, which may reduce the risk of overall disease progression in breast cancer patients. Consistently, recent experimental approaches have demonstrated strong antiproliferative and apoptotic effects in various human cancer cells, although the molecular mechanisms remained elusive. This study was conducted to identify key mechanisms underlying the growth suppressor activity of zoledronic acid in epithelial cancer. For this purpose, we employed an extensive series of cellular, molecular as well as biochemical studies and uncovered the existence of a nuclear GSK3β- NFATc2 stabilization pathway that is target for inactivation by zoledronic acid during growth suppression. GSK3β labels nuclear NFAT through phosphorylation of three phosphoserines (Ser 215, Ser 219 and Ser 223) residues located within the N-terminal SP2 motif of the factor, and this post-translational modification protects the factor from ubiquitination and degradation. The phosphoserine sequences are highly conserved among species and are identical to the previously reported “phospho-degron” elements through which GSK3β labels other key cell cycle regulators for subsequent ubiquitination and proteasomal degradation. Here, we show that GSK3β can make use of the “phospho-degron” elements to stabilize rather than proteolyse mitogenic transcription factors, and thus GSK3β exerts pro-proliferative functions through stabilization of NFATc2 levels in cancer. Treatment with zoledronic acid, however, inhibits GSK3β kinase activity, thus disrupts NFATc2 phosphorylation and stabilization in the nucleus, and finally allows the 26S proteasomal machinery to target NFATc2 for degradation. Mechanistically, HDM2, the human homologue of the E3-ligase MDM2, accumulates in the nucleus upon treatment binds to NFATc2 and transfers ubiquitin to lysines K-684 and K-897. Ubiquitination of K-684 and K-897 requires an unphosphorylated status of NFATc2 in the nucleus and is key for the subsequent recognition and degradation by the 26S proteasome. The net cellular outcome of GSK3β -NFATc2 pathway disruption and degradation of the transcription factor is a progredient halt of cancer cells at the G1 cell cycle phase. Together, this study uncovers a key pathway in cancer growth control that is aimed for inactivation by zoledronic acid. From the medical point of view, we believe that these findings significantly contribute to a better understanding of the biochemical basis underlying one of the most promising and exciting new treatment for malignant disease.
DOI:10.17192/z2010.0675