Oncogenic Mutant p53 Sensitizes Non-Small Cell Lung Cancer Cells to Proteasome Inhibition via Oxidative Stress-Dependent Induction of Mitochondrial Apoptosis.

NSCLC is the leading cause of cancer death due, in part, to a lack of active therapies in advanced disease. We demonstrate that combination therapy with a proteasome inhibitor, BH3-mimetic, and chemotherapy is an active precision therapy in NSCLC cells and tumors expressing Onc-p53 alleles.

The oncogenicity of tumor-derived mutant p53 is enhanced by the recruitment of PLK3.

p53 mutations with single amino acid changes in cancer often lead to dominant oncogenic changes. Here, we have developed a mouse model of gain-of-function (GOF) p53-driven lung cancer utilizing conditionally active LSL p53-R172H and LSL K-Ras-G12D knock-in alleles that can be activated by Cre in lung club cells. Mutation of the p53 transactivation domain (TAD) (p53-L25Q/W26S/R172H) eliminating significant transactivation activity resulted in loss of tumorigenicity, demonstrating that transactivation mediated by or dependent on TAD is required for oncogenicity by GOF p53.

DNA replication in progenitor cells and epithelial regeneration after lung injury requires the oncoprotein MDM2.

Depletion of epithelial cells after lung injury prompts proliferation and epithelial mesenchymal transition (EMT) of progenitor cells, and this repopulates the lost epithelial layer. To investigate the cell proliferative function of human oncoprotein MDM2, we generated mouse models targeting human MDM2 expression in either lung Club or alveolar cells after doxycycline treatment. We report that MDM2 expression in lung Club or alveolar cells activates DNA replication specifically in lung progenitor cells only after chemical- or radiation-induced lung injury, irrespective of their p53 status.

Gain-of-function p53 activates multiple signaling pathways to induce oncogenicity in lung cancer cells.

Gain-of-function (GOF) mutants of p53 upregulate genes implicated in cell proliferation and oncogenesis. Here, we report that GOF p53 induces tumorigenicity through simultaneous activation of key oncogenic pathways including those controlling putative tumor-initiating cell functions. We determined that in cells expressing p53-R273H, GOF p53 simultaneously upregulates genes from multiple signaling pathways by recognizing promoters containing distinct transcription factor (TF) binding sites.

Mutant p53 establishes targetable tumor dependency by promoting unscheduled replication.

Gain-of-function (GOF) p53 mutations are observed frequently in most intractable human cancers and establish dependency for tumor maintenance and progression. While some of the genes induced by GOF p53 have been implicated in more rapid cell proliferation compared with p53-null cancer cells, the mechanism for dependency of tumor growth on mutant p53 is unknown. This report reveals a therapeutically targetable mechanism for GOF p53 dependency.

Constitutive Activation of DNA Damage Checkpoint Signaling Contributes to Mutant p53 Accumulation via Modulation of p53 Ubiquitination.

Unlabelled: Many mutant p53 proteins exhibit an abnormally long half-life and overall increased abundance compared with wild-type p53 in tumors, contributing to mutant p53's gain-of-function oncogenic properties. Here, a novel mechanism is revealed for the maintenance of mutant p53 abundance in cancer that is dependent on DNA damage checkpoint activation. High-level mutant p53 expression in lung cancer cells was associated with preferential p53 monoubiquitination versus polyubiquitination, suggesting a role for the ubiquitin/proteasome system in regulation of mutant p53 abundance in cancer cells.

Lung cancer stem cells, p53 mutations and MDM2.

Over the past few decades, advances in cancer research have enabled us to understand the different mechanisms that contribute to the aberrant proliferation of normal cells into abnormal cells that result in tumors. In the pursuit to find cures, researchers have primarily focused on various molecular level changes that are unique to cancerous cells. In humans, about 50 % or more cancers have a mutated tumor suppressor p53 gene thereby resulting in accumulation of p53 protein and losing its function to activate the target genes that regulate cell cycle and apoptosis.

MDM2 overexpression, activation of signaling networks, and cell proliferation.

Frequent overexpression of MDM2 in human cancers suggests that the protein confers a survival advantage to cancer cells. However, overexpression of MDM2 in normal cells seems to restrict cell proliferation. This review discusses the cell growth regulatory functions of MDM2 in normal and genetically defective cells to assess how cancer cells evade the growth-restricting consequence of MDM2 overexpression.

p53: its mutations and their impact on transcription.

p53 is a tumor suppressor protein whose key function is to maintain the integrity of the cell. Mutations in p53 have been found in up to 50 % of all human cancers and cause an increase in oncogenic phenotypes such as proliferation and tumorigenicity. Both wild-type and mutant p53 have been shown to transactivate their target genes, either through directly binding to DNA, or indirectly through protein-protein interactions.

The human oncoprotein MDM2 induces replication stress eliciting early intra-S-phase checkpoint response and inhibition of DNA replication origin firing.

Conventional paradigm ascribes the cell proliferative function of the human oncoprotein mouse double minute2 (MDM2) primarily to its ability to degrade p53. Here we report that in the absence of p53, MDM2 induces replication stress eliciting an early S-phase checkpoint response to inhibit further firing of DNA replication origins. Partially synchronized lung cells cultured from p53-/-:MDM2 transgenic mice enter S phase and induce S-phase checkpoint response earlier than lung cells from p53-/- mice and inhibit firing of DNA replication origins.

Generation of p53 knock-down cell lines.

In order to study the functions of a cell's endogenous mutant p53, the p53 protein levels must be knocked-down. Transient transfection of small interfering RNAs is one way to accomplish this. Another is the stable expression of short hairpin RNAs.

Use of the DNA fiber spreading technique to detect the effects of mutant p53 on DNA replication.

DNA replication involves a coordinated progression through S phase, and disruption of these regulated steps may cause gene abnormalities, which may lead to cancer. Different stages of DNA replication can be detected immunofluorescently that would indicate how replication is progressing in a cell population or under specific conditions. We describe a method for labeling replicating DNA with two nucleotide analogs, and then detecting the sequential patterns of incorporation using fluorescently labeled antibodies on DNA spread onto a glass slide.

Measurement of chemosensitivity and growth rate in p53 expressing cells.

Chemoresistance and increased growth rate are two gain-of-function functions that mutant p53 is thought to possess. Here, we describe two methods for measuring the sensitiveness of cells to chemotherapeutic drugs and the rate of cell growth. Both of which can be used with a wide range of cell types.

Human Oncoprotein MDM2 Up-regulates Expression of NF-κB2 Precursor p100 Conferring a Survival Advantage to Lung Cells.

The current model predicts that MDM2 is primarily overexpressed in cancers with wild-type (WT) p53 and contributes to oncogenesis by degrading p53. Following a correlated expression of MDM2 and NF-κB2 transcripts in human lung tumors, we have identified a novel transactivation function of MDM2. Here, we report that in human lung tumors, overexpression of MDM2 was found in approximately 30% of cases irrespective of their p53 status, and expression of MDM2 and NF-κB2 transcripts showed a highly significant statistical correlation in tumors with WT p53.

Gain-of-function mutant p53 upregulates CXC chemokines and enhances cell migration.

The role of dominant transforming p53 in carcinogenesis is poorly understood. Our previous data suggested that aberrant p53 proteins can enhance tumorigenesis and metastasis. Here, we examined potential mechanisms through which gain-of-function (GOF) p53 proteins can induce motility.

MDM2 controls the timely expression of cyclin A to regulate the cell cycle.

Overexpression of MDM2 has been related to oncogenesis. In this communication, we present evidence to show that MDM2 controls the cell cycle-dependent expression of cyclin A by using a pathway that ensures its timely expression. MDM2 does not inhibit cyclin D or E expression.

Tumor-derived p53 mutants induce NF-kappaB2 gene expression.

Overexpression of mutant p53 is a common theme in tumors, suggesting a selective pressure for p53 mutation in cancer development and progression. To determine how mutant p53 expression may lead to survival advantage in human cancer cells, we generated stable cell lines expressing p53 mutants p53-R175H, -R273H, and -D281G by use of p53-null human H1299 (lung carcinoma) cells. Compared to vector-transfected cells, H1299 cells expressing mutant p53 showed a survival advantage when treated with etoposide, a common chemotherapeutic agent; however, cells expressing the transactivation-deficient triple mutant p53-D281G (L22Q/W23S) had significantly lower resistance to etoposide.

Modulation of gene expression by tumor-derived p53 mutants.

p53 mutants with a single amino acid substitution are overexpressed in a majority of human cancers containing a p53 mutation. Overexpression of the mutant protein suggests that there is a selection pressure on the cell indicative of an active functional role for mutant p53. Indeed, H1299 cells expressing mutant p53-R175H, p53-R273H or p53-D281G grow at a faster rate compared with a control cell line.

Tumor-derived p53 mutants induce oncogenesis by transactivating growth-promoting genes.

We have studied the mechanism of mutant p53-mediated oncogenesis using several tumor-derived mutants. Using a colony formation assay, we found that the majority of the mutants increased the number of colonies formed compared to the vector. Expression of tumor-derived p53 mutants increases the rate of cell growth, suggesting that the p53 mutants have 'gain of function' properties.

Cell cycle regulatory functions of the human oncoprotein MDM2.

The protein (MDM2) coded by the mouse double minute-2 (mdm2) gene or its human homologue is well known as an oncoprotein. Malignant human tumors particularly breast tumors and soft tissue sarcomas frequently overexpress MDM2. Artificial amplification of mdm2 gene derived from a transformed murine cell line enhances tumorigenic potential of murine cells.

Flow cytometric analysis of MDM2-mediated growth arrest.

Although MDM2, the product of mouse double minute-2 (mdm2) gene, or its human homologue possesses the potential to confer tumorigenic properties, it induces G1/S arrest in nontransformed cells. Flow cytometry provides a way to determine the effects of MDM2 on the cell cycle by expressing the protein ectopically, immunostaining cells expressing MDM2 and analyzing their DNA content. The DNA histograms of MDM2-transfected and untransfected cells can then be used to visualize the effect of ectopically expressed MDM2 on the cell cycle.

Transactivation and transrepression studies with p53.

The methods outlined in this chapter are designed to facilitate the study of the transactivation and transrepression properties of p53 (as well as p63 and p73). Once a gene of interest is identified, its presumptive promoter region can be cloned upstream of a luciferase gene in a plasmid. The most common reason for transfection experiments is to study gene expression patterns in the presence or absence of a particular gene product (e.

Hetero-oligomerization does not compromise 'gain of function' of tumor-derived p53 mutants.

Tumor-derived p53 mutants activate transcription from promoters of various growth-related genes. We tested whether this transactivation function of the mutant protein is sufficient to induce tumorigenesis ('gain of function'). Tumor-derived mutant p53-281G transactivates the promoters of human epidermal growth factor receptor (EGFR) and human multiple drug resistance gene (MDR-1).

Function and dysfunction of the human oncoprotein MDM2.

The protein MDM2 coded by the human homologue of mouse double minute-2 (mdm2) gene frequently overexpresses in malignant human breast and other tumors. Artificial amplification of mouse mdm2 gene derived from a transformed murine cell line enhances tumorigenic potential of murine cells. These evidences suggest oncogenic properties of human or mouse MDM2.