Acetylation of carboxyl-terminal domain selectively regulates p53-mediated gene transcriptionn

Abstract

Abstract: Objective To explore whether carboxyl-terminal domain (CTD) acetylation contributes to selectively regulating p53-mediated transcription of a subset of genes. Methods Based on p53-null lung cancer cell line H1299, a pair of inducible cell strains expressing the wildtype p53 (p53-WT) and the CTD acetylation-mimicking p53 (p53-6KQ) were constructal, respectively, and a response to doxycycline (Doxy) treatment was generated. RNA-sequencing was applied to analyze the changes of the transcriptional profiles regulated by p53-WT or p53-6KQ. Bio-informatic analysis was performed to annotate p53-6KQ-specific candidates, and their potential biological functions. Results The p53-inducible cell strains were successfully established. 306 differentially expressed genes that were specifically regulated by p53-6KQ were identified. These genes were functionally enriched in the biological processes involving in cell fate determination, transcription, neuron development and tumor necrosis factor signaling pathway. Conclusions The CTD acetylation may selectively and functionally regulate a subset of p53 target genes.

Key words: p53, acetylation, gene transcriptional regulation, tumor, bioinformatic analysis

CLC Number:

R394.3

YAN Xiao-jun, XU Wen-bin, WANG Dong-lai. Acetylation of carboxyl-terminal domain selectively regulates p53-mediated gene transcriptionn[J]. Basic & Clinical Medicine, 2021, 41(11): 1577-1582.

References

[1]Vousden KH, Prives C. Blinded by the light: the growing complexity of p53[J]. Cell, 2009, 137: 413-431.
[2]Lane DP. Cancer. p53, guardian of the genome[J]. Nature, 1992, 358: 15-16.[3]Olivier M, Hollstein M, Hainaut P. TP53 mutations in human cancers: origins, consequences, and clinical use[J]. Cold Spring Harb Perspect Biol, 2010, 2: a001008. doi: 10.1101/cshperspect.a001008.
[4]谌芳, 吴意, 林雪迟. P53功能的多效性[J]. 基础医学与临床, 2015, 35: 1672-1676.
[5]Liu Y, Tavana O, Gu W. p53 modifications: exquisite decorations of the powerful guardian[J]. J Mol Cell Biol, 2019, 11: 564-577.
[6]Wen J, Wang D. Deciphering the PTM codes of the tumor suppressor p53[J]. J Mol Cell Biol. 2021, mjab047. doi: 10.1093/jmcb/mjab047.
[7]Reed SM, Quelle DE. p53 acetylation: regulation and consequences[J]. Cancers (Basel), 2014, 7: 30-69.
[8]Krummel KA, Lee CJ, Toledo F, et al. The C-terminal lysines fine-tune p53 stress responses in a mouse model but are not required for stability control or transactivation[J]. Proc Natl Acad Sci U S A, 2005, 10: 10188-10193.
[9]Wang D, Kon N, Lasso G, et al. Acetylation-regulated interaction between p53 and SET reveals a widespread regulatory mode[J]. Nature, 2016, 538: 118-122.
[10]Kon N, Churchill M, Li H, et al. Robust p53 stabilization is dispensable for its activation and tumor suppressor function[J]. Cancer Res, 2021, 81: 935-944.
[11]Tsai FY, Orkin SH. Transcription factor GATA-2 is required for proliferation/survival of early hematopoietic cells and mast cell formation, but not for erythroid and myeloid terminal differentiation[J]. Blood, 1997, 89: 3636-3643.
[12]Yaguchi T, Nakano T, Gotoh A, et al. Adenosine promotes GATA-2-regulated p53 gene transcription to induce HepG2 cell apoptosis[J]. Cell Physiol Biochem, 2011, 28: 761-770.
[13]Brady OA, Jeong E, Martina JA, et al. The transcription factors TFE3 and TFEB amplify p53 dependent transcriptional programs in response to DNA damage[J]. Elife, 2018, 7: e40856. doi: 10.7554/eLife.40856.

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