Hypoxia-induced p53 modulates both apoptosis and radiosensitivity via AKT
Katarzyna B. Leszczynska, … , Francesca M. Buffa, Ester M. Hammond
Katarzyna B. Leszczynska, … , Francesca M. Buffa, Ester M. Hammond
Published May 11, 2015
Citation Information: J Clin Invest. 2015;125(6):2385-2398. https://doi.org/10.1172/JCI80402.
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Hypoxia-induced p53 modulates both apoptosis and radiosensitivity via AKT

Abstract

Restoration of hypoxia-induced apoptosis in tumors harboring p53 mutations has been proposed as a potential therapeutic strategy; however, the transcriptional targets that mediate hypoxia-induced p53-dependent apoptosis remain elusive. Here, we demonstrated that hypoxia-induced p53-dependent apoptosis is reliant on the DNA-binding and transactivation domains of p53 but not on the acetylation sites K120 and K164, which, in contrast, are essential for DNA damage–induced, p53-dependent apoptosis. Evaluation of hypoxia-induced transcripts in multiple cell lines identified a group of genes that are hypoxia-inducible proapoptotic targets of p53, including inositol polyphosphate-5-phosphatase (INPP5D), pleckstrin domain–containing A3 (PHLDA3), sulfatase 2 (SULF2), B cell translocation gene 2 (BTG2), cytoplasmic FMR1-interacting protein 2 (CYFIP2), and KN motif and ankyrin repeat domains 3 (KANK3). These targets were also regulated by p53 in human cancers, including breast, brain, colorectal, kidney, bladder, and melanoma cancers. Downregulation of these hypoxia-inducible targets associated with poor prognosis, suggesting that hypoxia-induced apoptosis contributes to p53-mediated tumor suppression and treatment response. Induction of p53 targets, PHLDA3, and a specific INPP5D transcript mediated apoptosis in response to hypoxia through AKT inhibition. Moreover, pharmacological inhibition of AKT led to apoptosis in the hypoxic regions of p53-deficient tumors and consequently increased radiosensitivity. Together, these results identify mediators of hypoxia-induced p53-dependent apoptosis and suggest AKT inhibition may improve radiotherapy response in p53-deficient tumors.

Authors

Katarzyna B. Leszczynska, Iosifina P. Foskolou, Aswin G. Abraham, Selvakumar Anbalagan, Céline Tellier, Syed Haider, Paul N. Span, Eric E. O’Neill, Francesca M. Buffa, Ester M. Hammond

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Figure 2

Transcriptional activity of p53 is required to induce expression of a specific group of genes in hypoxia.

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Transcriptional activity of p53 is required to induce expression of a sp...
(A) Validation of p53 targets by qPCR in p53+/+ and p53–/– HCT116 cells exposed to hypoxia. The bar graph shows mean ± SEM (combined n = 3, 2-way ANOVA test [*P < 0.05; **P < 0.01; ***P < 0.001]). (B) qPCR for p53 ChIP in HCT116 cells exposed to 8 hours of normoxia or hypoxia for the genes indicated. The bar graph shows mean ± SEM (combined n = 3, 2-way ANOVA test [P < 0.0001] followed by 2-tailed Student’s t test [*P < 0.05]). (C) PCR for the INPP5D transcripts using a combination of primers (marked as arrows in Supplemental Figure 2A) specifically detecting the short INPP5D transcript (F4+R4 or F4+R1), all INPP5D transcripts (F1+R1), or the full-length INPP5D transcript (F4a+R4 or F5+R4) on the cDNA from HCT116 or RKO cells exposed to 16 hours of hypoxia. THP-1 cDNA was used as a control for the expression of the full-length INPP5D. RPS29 is shown as a control gene. (D) Alignment of the putative p53 RE of the short INPP5D in human, mouse, and rat. A consensus p53 RE is shown below the alignment. (E) qPCR for p53 ChIP at the putative p53 RE in the short INPP5D promoter in HCT116 cells exposed to 8 hours of normoxia or hypoxia. The bar graph shows mean ± SEM (combined n = 3, 2-tailed Student’s t test [*P < 0.05]).