File(s) not publicly available
Mutant p53 drives multinucleation and invasion through a process that is suppressed by ANKRD11
journal contribution
posted on 2018-11-21, 00:00 authored by JE Noll, J Jeffery, F Al-Ejeh, R Kumar, KK Khanna, DF Callen, Paul NeilsenPaul NeilsenMutations of p53 in cancer can result in a gain of function associated with tumour progression and metastasis. We show that inducible expression of several p53 hotspot mutants promote a range of centrosome abnormalities, including centrosome amplification, increased centrosome size and loss of cohesion, which lead to mitotic defects and multinucleation. These mutant p53-expressing cells also show a change in morphology and enhanced invasive capabilities. Consequently, we sought for a means to specifically target the function of mutant p53 in cancer cells. This study has identified ANKRD11 as a key regulator of the oncogenic potential of mutant p53. Loss of ANKRD11 expression with p53 mutation defines breast cancer patients with poor prognosis. ANKRD11 alleviates the mitotic defects driven by mutant p53 and suppresses mutant p53-mediated mesenchymal-like transformation and invasion. Mechanistically, we show that ANKRD11 restores a native conformation to the mutant p53 protein and causes dissociation of the mutant p53-p63 complex. This represents the first evidence of an endogenous protein with the capacity to suppress the oncogenic properties of mutant p53. © 2012 Macmillan Publishers Limited All rights reserved.
Funding
Category 2 - Other Public Sector Grants Category
History
Volume
31Issue
23Start Page
2836End Page
2848Number of Pages
13eISSN
1476-5594ISSN
0950-9232Publisher
Nature Publishing GroupPublisher DOI
Full Text URL
Peer Reviewed
- Yes
Open Access
- No
External Author Affiliations
University of Adelaide; Signal Transduction Laboratory; University of Adelaide & Hanson InstituteEra Eligible
- Yes
Journal
OncogeneUsage metrics
Categories
Keywords
Licence
Exports
RefWorksRefWorks
BibTeXBibTeX
Ref. managerRef. manager
EndnoteEndnote
DataCiteDataCite
NLMNLM
DCDC