TY - JOUR
T1 - Rescue of embryonic stem cells from cellular transformation by proteomic stabilization of mutant p53 and conversion into WT conformation
AU - Rivlin, Noa
AU - Katz, Shir
AU - Doody, Maayan
AU - Sheffer, Michal
AU - Horesh, Stav
AU - Molchadsky, Alina
AU - Koifman, Gabriela
AU - Shetzer, Yoav
AU - Goldfinger, Naomi
AU - Rotter, Varda
AU - Geiger, Tamar
N1 - Israel Cancer Research Fund; Israel Science Foundation [1617/12]; Israel Centers of Research Excellence (I-CORE, Gene Regulation in Complex Human Disease Center) [41/11]; Center of Excellence Grant from the Israel Science Foundation; Center of Excellence Grant from the Flight Attendant Medical Research InstituteWe thank Dr. Elena Ainbinder and Dr. Yael Fried for spectral karyotype analysis analyses and technical assistance. We also thank Dr. Rebecca Haffner and Dr. Ori Brenner for their help with ESCs establishment and pathological analyses, respectively. In addition, we thank Noa Bossel for her help with RNA sequencing data analysis and Yoach Rais for his help with the ChIP. The work by T. G. was supported by the Israel Cancer Research Fund, by the Israel Science Foundation (Grant 1617/12), and by the Israel Centers of Research Excellence (I-CORE, Gene Regulation in Complex Human Disease Center 41/11). The work by V. R. was supported by a Center of Excellence Grant from the Israel Science Foundation and a Center of Excellence Grant from the Flight Attendant Medical Research Institute. V. R. is the incumbent of the Norman and Helen Asher Professorial Chair of Cancer Research at The Weizmann Institute.
PY - 2014/5/13
Y1 - 2014/5/13
N2 - p53 is a well-known tumor suppressor that is mutated in over 50% of human cancers. These mutations were shown to exhibit gain of oncogenic function compared with the deletion of the gene. Additionally, p53 has fundamental roles in differentiation and development; nevertheless, mutant p53 mice are viable and develop malignant tumors only on adulthood. We set out to reveal the mechanisms by which embryos are protected from mutant p53-induced transformation using ES cells (ESCs) that express a conformational mutant of p53. We found that, despite harboring mutant p53, the ESCs remain pluripotent and benign and have relatively normal karyotype compared with ESCs knocked out for p53. Additionally, using high-content RNA sequencing, we show that p53 is transcriptionally active in response to DNA damage in mutant ESCs and elevates p53 target genes, such as p21 and btg2. We also show that the conformation of mutant p53 protein in ESCs is stabilized to a WT conformation. Through MS-based interactome analyses, we identified a network of proteins, including the CCT complex, USP7, Aurora kinase, Nedd4, and Trim24, that bind mutant p53 and may shift its conformation to a WT form. We propose this conformational shift as a novel mechanism of maintenance of genomic integrity, despite p53 mutation. Harnessing the ability of these protein interactors to transform the oncogenic mutant p53 to the tumor suppressor WT form can be the basis for future development of p53-targeted cancer therapy.
AB - p53 is a well-known tumor suppressor that is mutated in over 50% of human cancers. These mutations were shown to exhibit gain of oncogenic function compared with the deletion of the gene. Additionally, p53 has fundamental roles in differentiation and development; nevertheless, mutant p53 mice are viable and develop malignant tumors only on adulthood. We set out to reveal the mechanisms by which embryos are protected from mutant p53-induced transformation using ES cells (ESCs) that express a conformational mutant of p53. We found that, despite harboring mutant p53, the ESCs remain pluripotent and benign and have relatively normal karyotype compared with ESCs knocked out for p53. Additionally, using high-content RNA sequencing, we show that p53 is transcriptionally active in response to DNA damage in mutant ESCs and elevates p53 target genes, such as p21 and btg2. We also show that the conformation of mutant p53 protein in ESCs is stabilized to a WT conformation. Through MS-based interactome analyses, we identified a network of proteins, including the CCT complex, USP7, Aurora kinase, Nedd4, and Trim24, that bind mutant p53 and may shift its conformation to a WT form. We propose this conformational shift as a novel mechanism of maintenance of genomic integrity, despite p53 mutation. Harnessing the ability of these protein interactors to transform the oncogenic mutant p53 to the tumor suppressor WT form can be the basis for future development of p53-targeted cancer therapy.
UR - http://www.scopus.com/inward/record.url?scp=84900470310&partnerID=8YFLogxK
U2 - https://doi.org/10.1073/pnas.1320428111
DO - https://doi.org/10.1073/pnas.1320428111
M3 - مقالة
C2 - 24778235
SN - 0027-8424
VL - 111
SP - 7006
EP - 7011
JO - Proceedings of the National Academy of Sciences of the United States of America
JF - Proceedings of the National Academy of Sciences of the United States of America
IS - 19
ER -