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Reciprocal repression between P53 and TCTP

Abstract

Screening for genes that reprogram cancer cells for the tumor reversion switch identified TCTP (encoding translationally controlled tumor protein) as a crucial regulator of apoptosis. Here we report a negative feedback loop between P53 and TCTP. TCTP promotes P53 degradation by competing with NUMB for binding to P53-MDM2–containing complexes. TCTP inhibits MDM2 auto-ubiquitination and promotes MDM2-mediated ubiquitination and degradation of P53. Notably, Tctp haploinsufficient mice are sensitized to P53-dependent apoptosis. In addition, P53 directly represses TCTP transcription. In 508 breast cancers, high-TCTP status associates with poorly differentiated, aggressive G3-grade tumors, predicting poor prognosis (P < 0.0005). Tctp knockdown in primary mammary tumor cells from ErbB2 transgenic mice results in increased P53 expression and a decreased number of stem-like cancer cells. The pharmacological compounds sertraline and thioridazine increase the amount of P53 by neutralizing TCTP's action on the MDM2-P53 axis. This study links TCTP and P53 in a previously unidentified regulatory circuitry that may underlie the relevance of TCTP in cancer.

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Figure 1: Transcriptional repression of TCTP by P53.
Figure 2: Repression of the P53 protein by TCTP.
Figure 3: TCTP forms a complex with P53, MDM2 and NUMB and inhibits the auto-ubiquitination of MDM2.
Figure 4: Tctp haploinsufficiency increases the amount of P53 and enhances susceptibility to P53-dependent apoptosis.
Figure 5: Clinical relevance of TCTP in breast cancer and its expression in mammary stem cells.
Figure 6: Sertraline and thioridazine increase the amount of P53.

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Acknowledgements

A.T. and R.A. dedicate this work to G. Schnek for his sustained care. We thank C. Auclair for constant support; D. Galvagno for technical assistance; G. D'Ario and S. Confalonieri for statistical analyses; and B. Vogelstein (Johns Hopkins University), M. Oren (Weizmann Institute of Science) and B. Wasilyk and C. Wasilyk (IGBMC Illkirch) for HCT116, H1299 Trp53-null, temperature-sensitive P53 Val138 mutant cells, and P53 protein and plasmids, respectively. This work was supported by grants from the Agence Nationale de la Recherche Programme Blanc (ANR- 09-BLAN-0292-01), the European Union Network of Excellence CONTICANET and the Association Sclérose Tubéreuse de Bourneville to A.T. and R.A., the Associazione Italiana per la Ricerca sul Cancro and the Italian Ministries of Education University Research (MIUR) and the Italian Ministry of Health to S.P. and P.P.D.F., the European Community (FP6 and FP7), the European Research Council, the Ferrari Foundation, the Monzino Foundation and the Cassa Risparmio Provincie Lombarde (CARIPLO) Foundation to P.P.D.F. and the G. Vollaro Foundation to S.P. J.W. received support from Agency for Innovation by Science and Technology (IWT).

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A.T. and R.A. conceptualized, designed and directed the study and wrote the article as part of a teamwork with P.P.D.F., S.P. and J.-C.M. The P53-RE was characterized by A.L. The initial observation of increased P53 in Tctp heterozygous mice was made by A.L. The IHC analysis on the affected subjects was performed by G.M. and G.V. D.T. and I.C. performed the studies on the stem cells. R.V., A.L., D.T., I.C., S.R.-F., J.W. and O.C. carried out experiments and analyzed data. J.H. suggested and interpreted the surface plasmon resonance experiments.

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Correspondence to Adam Telerman.

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Amson, R., Pece, S., Lespagnol, A. et al. Reciprocal repression between P53 and TCTP. Nat Med 18, 91–99 (2012). https://doi.org/10.1038/nm.2546

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