Mutational data from human cancer imply that the p53 tumor suppressor gene is crucial for limiting tumorigenesis. p53 is a sequences specific DNA binding protein that is induced by DNA damage or oncogenic stress leading to induction of genes that trigger a series of anti-proliferative responses whose contribution to tumor suppression remains controversial. Additionally, p53 can directly or indirectly repress gene expression, though the impact of p53 repressed genes on tumor progression and maintenance is poorly understood. Adding to this complexity, p53 mutations typically involve a point mutation in one allele and a large deletion targeting the other, with emerging data indicating that both of these events promote cancer beyond p53 loss. Our project previously established that apoptosis and cellular senescence an be major modes of p53 action in tumor suppression, and most recently identified a key role for p53 in limiting aberrant self renewal and restricting cellular plasticity during tumorigenesis. Using key technologies developed in our group, we showed that reactivation of endogenous p53 in advanced tumors produces potent anti-tumor effects, and explored mechanisms whereby p53 lesions promote tumorigenesis independent of their effects on wild-type p53, for example, identifying therapeutically actionable effectors of p53 mutant action in pancreas cancer and additional haploinsufficient tumor suppressors encompassed within 17p deletions that cooperate with p53 suppress tumorigenesis. In the current proposal, Project 4 will continue to use innovative genetic and animal modeling technologies to address significant unanswered questions in the p53 field. For example, it embraces and studies the notion that p53 action depends on context, and combines powerful uses novel mosaic mouse models to interrogate mechanisms of p53 mediated tumor suppression in different tissue and genetic settings. Using potent and inducible shRNA technology optimized in the group, it tests the novel hypothesis that genes normally repressed by p53 and aberrantly increased in mutant tumors contribute to tumor maintenance and may include targets that are synthetically lethal to mutant p53. In doing so, it implements unique inducible shRNA transgenic technology to explore the impact of target inhibition in tumor and normal tissues. Finally, the project will develop a streamlined method for producing p53 mutant alleles in mice, and use this to explore the biology of highly frequent but understudied p53 truncating alleles to determine whether they produce have gain of function properties. Each of our proposed Aims is supported by substantial preliminary data and will benefit from interactions with all other projects and cores. Successful completion of the proposed work will substantially understand how p53 suppresses tumorigenesis in vivo, and may point to therapeutic opportunities relevant to a large fraction of human cancers.

Public Health Relevance

Project 3 uses advanced genetic and genomic tools together novel genetically-engineered mouse models of lymphoma and hepatocellular carcinoma to compare and contrast how wild- type and mutant p53 promote cancer in vivo. It will also explore the role of ferroptosis in this process and how deregulation of p53-mediated gene repression programs contributes to tumor maintenance. The Project will provide new insights into wild-type and mutant p53 action and may identify and validate therapeutic targets for p53 mutant tumors.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Program Projects (P01)
Project #
5P01CA087497-17
Application #
9481810
Study Section
Special Emphasis Panel (ZCA1)
Project Start
Project End
Budget Start
2018-04-01
Budget End
2019-03-31
Support Year
17
Fiscal Year
2018
Total Cost
Indirect Cost
Name
Columbia University (N.Y.)
Department
Type
DUNS #
049179401
City
New York
State
NY
Country
United States
Zip Code
10027
Rokudai, Susumu; Li, Yingchun; Otaka, Yukihiro et al. (2018) STXBP4 regulates APC/C-mediated p63 turnover and drives squamous cell carcinogenesis. Proc Natl Acad Sci U S A 115:E4806-E4814
Rastogi, Chaitanya; Rube, H Tomas; Kribelbauer, Judith F et al. (2018) Accurate and sensitive quantification of protein-DNA binding affinity. Proc Natl Acad Sci U S A 115:E3692-E3701
Baugh, Evan H; Ke, Hua; Levine, Arnold J et al. (2018) Why are there hotspot mutations in the TP53 gene in human cancers? Cell Death Differ 25:154-160
Agmon, Eran; Solon, Jérôme; Bassereau, Patricia et al. (2018) Modeling the effects of lipid peroxidation during ferroptosis on membrane properties. Sci Rep 8:5155
Yozwiak, Carrie E; Hirschhorn, Tal; Stockwell, Brent R (2018) Toward a Microparticle-Based System for Pooled Assays of Small Molecules in Cellular Contexts. ACS Chem Biol 13:761-771
Hirschhorn, Tal; Stockwell, Brent R (2018) The development of the concept of ferroptosis. Free Radic Biol Med :
Liu, Hengrui; Schreiber, Stuart L; Stockwell, Brent R (2018) Targeting Dependency on the GPX4 Lipid Peroxide Repair Pathway for Cancer Therapy. Biochemistry 57:2059-2060
Conrad, Marcus; Kagan, Valerian E; Bayir, Hülya et al. (2018) Regulation of lipid peroxidation and ferroptosis in diverse species. Genes Dev 32:602-619
Zhang, Yan; Larraufie, Marie-Hélène; Musavi, Leila et al. (2018) Design of Small Molecules That Compete with Nucleotide Binding to an Engineered Oncogenic KRAS Allele. Biochemistry 57:1380-1389
Shimada, Kenichi; Reznik, Eduard; Stokes, Michael E et al. (2018) Copper-Binding Small Molecule Induces Oxidative Stress and Cell-Cycle Arrest in Glioblastoma-Patient-Derived Cells. Cell Chem Biol 25:585-594.e7

Showing the most recent 10 out of 159 publications