p53 Gain-of-Function Mutation Induces Metastasis via BRD4-Dependent CSF-1 Expression

TP53 mutations are frequent in esophageal squamous cell carcinoma (ESCC) and other SCCs and are associated with a proclivity for metastasis. Here, we report that colony-stimulating factor-1 (CSF-1) expression is upregulated significantly in a p53-R172H-dependent manner in metastatic lung lesions of ESCC. The p53-R172H-dependent CSF-1 signaling, through its cognate receptor CSF-1R, increases tumor cell invasion and lung metastasis, which in turn is mediated in part through Stat3 phosphorylation and epithelial-to-mesenchymal transition (EMT). In Trp53R172H tumor cells, p53 occupies the Csf-1 promoter. The Csf-1 locus is enriched with histone 3 lysine 27 acetylation (H3K27ac), which is likely permissive for fostering an interaction between bromodomain-containing domain 4 (BRD4) and p53-R172H to regulate Csf-1 transcription. Inhibition of BRD4 not only reduces tumor invasion and lung metastasis but also reduces circulating CSF-1 levels. Overall, our results establish a novel p53-R172H-dependent BRD4-CSF-1 axis that promotes ESCC lung metastasis and suggest avenues for therapeutic strategies for this difficult-to-treat disease.

SIGNIFICANCE

The invasion-metastasis cascade is a recalcitrant barrier to effective cancer therapy. We establish that the p53-R172H-dependent BRD4-CSF-1 axis is a mediator of prometastatic properties, correlates with patient survival and tumor stages, and its inhibition significantly reduces tumor cell invasion and lung metastasis. This axis can be exploited for therapeutic advantage. This article is featured in Selected Articles from This Issue, p. 2489.

Abstract 1289: The role of mutant p53-mediated mechanisms in modulating the tumor microenvironment and promoting lung metastasis

INTRODUCTION/METHODS: The multistep process of the tumor invasion-metastasis cascade is a major barrier to effective therapy. Mutations of the tumor suppressor p53 are frequently detected in esophageal squamous cell carcinoma (ESCC) cases, which in turn correlate with high metastatic rates. To understand the mutant p53-mediated mechanisms in promoting ESCC metastasis, we conducted RNA-Seq, ChIP-Seq and cytokine array on isogenic primary and metastatic tumor cells harvested from our mouse model of esophageal cancer, L2-Cre; LSL-Trp53R172H; Rosa26LSL-YFP, in which we have identified macrophage colony stimulating factor 1 (CSF1) to be a direct gene target of p53-R172H. We have targeted CSF1/CSF1R signaling to assess its pro-tumorigenic roles. In addition to studying tumor intrinsic mechanisms, we have established multiplex immunofluorescence and flow cytometry approaches to characterize the changes in tumor microenvironment (TME). Overall, this study aims to investigate the role and mediators of CSF1 signaling through its cognate receptor CSF1R by which missense p53 mutations can promote lung metastasis.

RESULTS/DISCUSSION: We demonstrate that metastatic ESCC has increased Csf1 expression compared to primary tumors and this is dependent upon p53 mutation status, which is reinforced by TCGA data and patient-derived tissue microarrays (TMAs). The TMA analysis also suggested that CSF1 expression is higher in tumors that are poorly differentiated. Furthermore, through the proximity ligation assay (PLA), we have identified that bromodomain and extra-terminal (BET) protein BRD4, which binds to acetylated histones to regulate transcription interacts with p53-R172H at higher levels compared to wild-type p53 to induce Csf1 expression. We show that the BRD4/CSF1/CSF1R signaling axis fosters tumor invasion, subcutaneous tumor growth and metastatic burden in lungs in a mutant p53 background. In accordance, targeting CSF1/CSF1R signaling reduces phosphorylation of STAT3 in the metastatic tumors, which suggests a mechanism for increased invasiveness and metastasis. In parallel, upon inhibiting this axis, we have identified decreased infiltration of F4/80+CD163+ and F4/80+CD206+ M2-polarized macrophages, as well as CD31+ endothelial cells, and increased number of CD3+CD8+ cytotoxic T-cells at the metastatic tumor sites, indicating that the CSF1/CSF1R pathway plays a critical role in shaping the pro-metastatic and immunosuppressive TME. Finally, analysis of squamous cell carcinoma (SCC) datasets reveals that specific p53 mutations are associated with differential survival rates and CSF1 expression.

CONCLUSION: We have demonstrated novel roles and mechanisms of mutant p53-dependent CSF1-CSF1R signaling pathway in fostering ESCC tumor invasion and lung metastasis that may be applicable to other SCCs. We believe this can open up new avenues for therapeutic applications.

Citation Format: Gizem Efe, Katherine M. Cunningham, Qiaosi Tang, Kensuke Sugiura, Karen Dunbar, Kensuke Suzuki, Lois Resnick-Silverman, Alison M. Taylor, James J. Manfredi, Carol L. Prives, Anil K. Rustgi. The role of mutant p53-mediated mechanisms in modulating the tumor microenvironment and promoting lung metastasis [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 1289.

In vivo RNA-seq and ChIP-seq analyses show an obligatory role for the C terminus of p53 in conferring tissue-specific radiation sensitivity

Thymus and spleen, in contrast to liver, are radiosensitive tissues in which p53-dependent apoptosis is triggered after whole-body radiation in vivo. Combined RNA sequencing (RNA-seq) and chromatin immunoprecipitation sequencing (ChIP-seq) analyses of radiation-treated mouse organs identifies both shared and tissue-specific p53 transcriptional responses. As expected, the p53 targets shared among thymus and spleen are enriched in apoptotic targets. The inability to upregulate these genes in the liver is not due to reduced gene occupancy. Use of an engineered mouse model shows that deletion of the C terminus of p53 can confer radiation-induced expression of p53 apoptotic targets in the liver with concomitant increased cell death. Global RNA-seq analysis reveals that an additional role of the C terminus is also needed for transcriptional activation of liver-specific p53 targets. It is hypothesized that both suppression of apoptotic gene expression combined with enhanced activation of liver-specific targets confers tissue-specific radio-resistance.

Abstract B014: Mutant p53-mediated CSF1/CSF1R signaling promotes tumor invasion and lung metastasis in esophageal squamous cell carcinoma

Introduction: Mutations of the tumor suppressor p53 are detected up to 80% of esophageal squamous cell carcinoma (ESCC) cases, which in turn correlate with high metastatic rates and poor prognosis. To understand the mutant p53-mediated mechanisms in promoting ESCC metastasis, we conducted RNA-Seq and cytokine array on isogenic primary and metastatic tumor cells harvested from our mouse model of esophageal cancer harboring Trp53R172H/-, in which we have identified Colony stimulating factor 1 (Csf1) to be upregulated. Our goal is to investigate the role and mediators of CSF1 signaling through its cognate receptor CSF1R by which missense p53 mutations can promote tumor invasion and lung metastasis in ESCC. Methods: We have utilized novel L2-Cre; LSL-Trp53R172H; Rosa26LSL-YFP mice and isolated tumor cells to model metastatic ESCC. We conducted ChIP-Seq analysis for p53 on tumor cells derived from lung metastases in our mouse models. Furthermore, we have genetically and pharmacologically targeted CSF1/CSF1R signaling axis to assess its role in ESCC tumor invasion and lung metastasis. In addition to studying tumor intrinsic mechanisms, we have established quantitative multiplex immunofluorescence (qmIF) and flow cytometry approaches to characterize the changes in tumor microenvironment (TME). Results And Discussion: We demonstrate that metastatic ESCC has increased Csf1 expression compared to primary tumors, and this is dependent upon p53 mutation status, which is reinforced by the TCGA data and patient-derived tissue microarrays (TMAs). The overlay of the RNA-Seq with the ChIP-Seq analysis indicates that Csf1 is a direct gene target of p53-R172H with enriched binding motifs. Furthermore, based on the proximity ligation assay (PLA) with murine ESCC tumor cells, bromodomain and extra-terminal motif (BET) protein BRD4 interacts with p53-R172H to induce Csf1 expression. We show that the BRD4-CSF1 axis fosters tumor invasion, subcutaneous tumor growth and metastatic burden in a mutant p53 background. In accordance, upon inhibiting this signaling pathway in the tail-vein injection lung metastasis models, we have identified reduced expression of CD31+ cells and decreased infiltration of F4/80+CD163+ and F4/80+CD206+ M2-polarized macrophages at the metastatic tumor sites, indicating that the CSF1/CSF1R pathway plays a critical role in shaping the pro-metastatic and immunosuppressive TME. Finally, analysis of the esophageal cancer datasets reveals that specific p53 mutations are associated with markedly differential overall survival rates and Csf1 expression. Based upon these results, we are generating human and murine esophageal cells with distinct DNA contact and conformational p53 mutations via base editing. Conclusion: We have demonstrated novel roles and mechanisms of mutant p53-dependent CSF1/CSF1R signaling pathway in fostering ESCC tumor invasion and lung metastasis that may be applicable to other squamous cell cancers. We believe this can open up new avenues for therapeutic applications.

Citation Format: Gizem Efe, Qiaosi Tang, Katherine M. Cunningham, Kensuke Sugiura, Karen Dunbar, Kausik Regunath, Kensuke Suzuki, Andres J. Klein-Szanto, Lois Resnick-Silverman, James J. Manfredi, Carol L. Prives, Anil K. Rustgi. Mutant p53-mediated CSF1/CSF1R signaling promotes tumor invasion and lung metastasis in esophageal squamous cell carcinoma [abstract]. In: Proceedings of the AACR Special Conference: Cancer Metastasis; 2022 Nov 14-17; Portland, OR. Philadelphia (PA): AACR; Cancer Res 2022;83(2 Suppl_2):Abstract nr B014.

Distinct mechanisms control genome recognition by p53 at its target genes linked to different cell fates

The tumor suppressor p53 integrates stress response pathways by selectively engaging one of several potential transcriptomes, thereby triggering cell fate decisions (e.g., cell cycle arrest, apoptosis). Foundational to this process is the binding of tetrameric p53 to 20-bp response elements (REs) in the genome (RRRCWWGYYYN_0-13RRRCWWGYYY). In general, REs at cell cycle arrest targets (e.g. p21) are of higher affinity than those at apoptosis targets (e.g., BAX). However, the RE sequence code underlying selectivity remains undeciphered. Here, we identify molecular mechanisms mediating p53 binding to high- and low-affinity REs by showing that key determinants of the code are embedded in the DNA shape. We further demonstrate that differences in minor/major groove widths, encoded by G/C or A/T bp content at positions 3, 8, 13, and 18 in the RE, determine distinct p53 DNA-binding modes by inducing different Arg248 and Lys120 conformations and interactions. The predictive capacity of this code was confirmed in vivo using genome editing at the BAX RE to interconvert the DNA-binding modes, transcription pattern, and cell fate outcome.

Mdm2 promotes Cdc25C protein degradation and delays cell cycle progression through the G2/M phase

Upon different types of stress, the gene encoding the mitosis-promoting phosphatase Cdc25C is transcriptionally repressed by p53, contributing to p53's enforcement of a G2 cell cycle arrest. In addition, Cdc25C protein stability is also decreased following DNA damage. Mdm2, another p53 target gene, encodes a ubiquitin ligase that negatively regulates p53 levels by ubiquitination. Ablation of Mdm2 by siRNA led to an increase in p53 protein and repression of Cdc25C gene expression. However, Cdc25C protein levels were actually increased following Mdm2 depletion. Mdm2 is shown to negatively regulate Cdc25C protein levels by reducing its half-life independently of the presence of p53. Further, Mdm2 physically interacts with Cdc25C and promotes its degradation through the proteasome in a ubiquitin-independent manner. Either Mdm2 overexpression or Cdc25C downregulation delays cell cycle progression through the G2/M phase. Thus, the repression of the Cdc25C promoter by p53, together with p53-dependent induction of Mdm2 and subsequent degradation of Cdc25C, could provide a dual mechanism by which p53 can enforce and maintain a G2/M cell cycle arrest.

p53 Maintains Baseline Expression of Multiple Tumor Suppressor Genes

TP53 is the most commonly mutated tumor suppressor gene and its mutation drives tumorigenesis. Using ChIP-seq for p53 in the absence of acute cell stress, we found that wild-type but not mutant p53 binds and activates numerous tumor suppressor genes, including PTEN, STK11(LKB1), miR-34a, KDM6A(UTX), FOXO1, PHLDA3, and TNFRSF10B through consensus binding sites in enhancers and promoters. Depletion of p53 reduced expression of these target genes, and analysis across 18 tumor types showed that mutation of TP53 associated with reduced expression of many of these genes. Regarding PTEN, p53 activated expression of a luciferase reporter gene containing the p53-consensus site in the PTEN enhancer, and homozygous deletion of this region in cells decreased PTEN expression and increased growth and transformation. These findings show that p53 maintains expression of a team of tumor suppressor genes that may together with the stress-induced targets mediate the ability of p53 to suppress cancer development. p53 mutations selected during tumor initiation and progression, thus, inactivate multiple tumor suppressor genes in parallel, which could account for the high frequency of p53 mutations in cancer.Implications: In this study, we investigate the activities of p53 under normal low-stress conditions and discover that p53 is capable of maintaining the expression of a group of important tumor suppressor genes at baseline, many of which are haploinsufficient, which could contribute to p53-mediated tumor suppression. Mol Cancer Res; 15(8); 1051-62. ©2017 AACR.

A rare DNA contact mutation in cancer confers p53 gain-of-function and tumor cell survival via TNFAIP8 induction

The p53 tumor suppressor gene encodes a sequence-specific transcription factor. Mutations in the coding sequence of p53 occur frequently in human cancer and often result in single amino acid substitutions (missense mutations) in the DNA binding domain (DBD), blocking normal tumor suppressive functions. In addition to the loss of canonical functions, some missense mutations in p53 confer gain-of-function (GOF) activities to tumor cells. While many missense mutations in p53 cluster at six "hotspot" amino acids, the majority of mutations in human cancer occur elsewhere in the DBD and at a much lower frequency. We report here that mutations at K120, a non-hotspot DNA contact residue, confer p53 with the previously unrecognized ability to bind and activate the transcription of the pro-survival TNFAIP8 gene. Mutant K120 p53 binds the TNFAIP8 locus at a cryptic p53 response element that is not occupied by wild-type p53. Furthermore, induction of TNFAIP8 is critical for the evasion of apoptosis by tumor cells expressing the K120R variant of p53. These findings identify induction of pro-survival targets as a mechanism of gain-of-function activity for mutant p53 and will likely broaden our understanding of this phenomenon beyond the limited number of GOF activities currently reported for hotspot mutants.

Two Faces of SIVA

In non-small cell lung cancer cells that contain a mutated KRAS gene, SIVA, a p53 target gene that is critical for apoptosis, is overexpressed in a p53-independent manner and promotes tumorigenesis through the stimulation of mTOR signaling. The ablation of Siva in conditional knockout mice results in an inhibition of tumor development that makes SIVA an interesting new candidate therapeutic target for the treatment of a carcinoma with few therapeutic options.

p53 Promotes cell survival due to the reversibility of its cell-cycle checkpoints

The tumor suppressor p53 (TP53) has a well-studied role in triggering cell-cycle checkpoint in response to DNA damage. Previous studies have suggested that functional p53 enhances chemosensitivity. In contrast, data are presented to show that p53 can be required for cell survival following DNA damage due to activation of reversible cell-cycle checkpoints. The cellular outcome to DNA damage is determined by the duration and extent of the stimulus in a p53-dependent manner. In response to transient or low levels of DNA damage, p53 triggers a reversible G2 arrest, whereas a sustained p53-dependent cell-cycle arrest and senescence follows prolonged or high levels of DNA damage. Regardless of the length of treatment, p53-null cells arrest in G2, but ultimately adapt and proceed into mitosis. Interestingly, they fail to undergo cytokinesis, become multinucleated, and then die from apoptosis. Upon transient treatment with DNA-damaging agents, wild-type p53 cells reversibly arrest and repair the damage, whereas p53-null cells fail to do so and die. These data indicate that p53 can promote cell survival by inducing reversible cell-cycle arrest, thereby allowing for DNA repair. Thus, transient treatments may exploit differences between wild-type p53 and p53-null cells.

IMPLICATIONS

Although p53 status has been suggested as a clinical predictor of chemotherapeutic efficacy, studies to date have not always supported this. This study demonstrates that p53 is still an important determinant of cell fate in response to chemotherapy, under the appropriate treatment conditions.

Multiple breast cancer cell-lines derived from a single tumor differ in their molecular characteristics and tumorigenic potential

BACKGROUND

Breast cancer cell lines are widely used tools to investigate breast cancer biology and to develop new therapies. Breast cancer tissue contains molecularly heterogeneous cell populations. Thus, it is important to understand which cell lines best represent the primary tumor and have similarly diverse phenotype. Here, we describe the development of five breast cancer cell lines from a single patient's breast cancer tissue. We characterize the molecular profiles, tumorigenicity and metastatic ability in vivo of all five cell lines and compare their responsiveness to 4-hydroxytamoxifen (4-OHT) treatment.

METHODS

Five breast cancer cell lines were derived from a single patient's primary breast cancer tissue. Expression of different antigens including HER2, estrogen receptor (ER), CK8/18, CD44 and CD24 was determined by flow cytometry, western blotting and immunohistochemistry (IHC). In addition, a Fluorescent In Situ Hybridization (FISH) assay for HER2 gene amplification and p53 genotyping was performed on all cell lines. A xenograft model in nude mice was utilized to assess the tumorigenic and metastatic abilities of the breast cancer cells.

RESULTS

We have isolated, cloned and established five new breast cancer cell lines with different tumorigenicity and metastatic abilities from a single primary breast cancer. Although all the cell lines expressed low levels of ER, their growth was estrogen-independent and all had high-levels of expression of mutated non-functional p53. The HER2 gene was rearranged in all cell lines. Low doses of 4-OHT induced proliferation of these breast cancer cell lines.

CONCLUSIONS

All five breast cancer cell lines have different antigenic expression profiles, tumorigenicity and organ specific metastatic abilities although they derive from a single tumor. None of the studied markers correlated with tumorigenic potential. These new cell lines could serve as a model for detailed genomic and proteomic analyses to identify mechanisms of organ-specific metastasis of breast cancer.

Analyzing p53 regulated DNA damage checkpoints by flow cytometry

The most critical feature of the cellular response to DNA damage is the ability of the cell to pause and repair the damage so that detrimental mutations will not be passed along to future generations of cells. The cell cycle of mammalian cells is equipped with checkpoints that can prevent cell cycle progression. Cells can either be arrested before replication of the DNA when the cells have a 2 N amount of DNA or after replication and prior to cell mitosis when the cells have a 4 N amount of DNA. Flow cytometry is a standard technique that is used to 'sort' cells based on their DNA content. It uses the principles of light scattering, light excitation, and emission of fluorochrome molecules to generate data about individual cells. The cells are fixed and permeabilized so that the DNA can be stained with a fluorescent dye. Cells that have a 2 N amount of DNA can be separated from cells with a 4 N amount of DNA. Using this technique, changes in the profile of the G1, S, and G2/M phases of the cell cycle are readily seen after DNA damage.

Skp2B overexpression alters a prohibitin-p53 axis and the transcription of PAPP-A, the protease of insulin-like growth factor binding protein 4

Background

We previously reported that the degradation of prohibitin by the SCF^Skp2B ubiquitin ligase results in a defect in the activity of p53. We also reported that MMTV-Skp2B transgenic mice develop mammary gland tumors that are characterized by an increased proteolytic cleavage of the insulin-like growth factor binding protein 4 (IGFBP-4), an inhibitor of IGF signaling. However, whether a link exists between a defect in p53 activity and proteolysis of IGFBP-4 was not established.

Methods and Results

We analyzed the levels of pregnancy-associated plasma protein A (PAPP-A), the protease of IGFBP-4, in MMTV-Skp2B transgenic mice and found that PAPP-A levels are elevated. Further, we found a p53 binding site in intron 1 of the PAPP-A gene and that both wild type and mutant p53 bind to this site. However, binding of wild type p53 results in the transcriptional repression of PAPP-A, while binding of mutant p53 results in the transcriptional activation of PAPP-A. Since MMTV-Skp2B mice express wild type p53 and yet show elevated levels of PAPP-A, at first, these observations appeared contradictory. However, further analysis revealed that the defect in p53 activity in Skp2B overexpressing cells does not only abolish the activity of wild type of p53 but actually mimics that of mutant p53. Our results suggest that in absence of prohibitin, the half-life of p53 is increased and like mutant p53, the conformation of p53 is denatured.

Conclusions

These observations revealed a novel function of prohibitin as a chaperone of p53. Further, they suggest that binding of denatured p53 in intron 1 causes an enhancer effect and increases the transcription of PAPP-A. Therefore, these findings indicate that the defect in p53 function and the increased proteolysis of IGFBP-4, we had observed, represent two components of the same pathway, which contributes to the oncogenic function of Skp2B.

Skp2B attenuates p53 function by inhibiting prohibitin

The F-box protein Skp2 and its isoform Skp2B are both overexpressed in breast cancers. Skp2 alters the activity of p53 by inhibiting its interaction with p300 and by promoting p300 degradation. Here, we report that Skp2B also attenuates the activity of p53; however, this effect is independent of p300, suggesting that another mechanism might be involved. Prohibitin, a protein reported to activate p53, was isolated in a two-hybrid screen with the carboxy-terminal domain unique to Skp2B. We observed that prohibitin is a new substrate of Skp2B and that the degradation of prohibitin is responsible for the attenuated activity of p53 in cells overexpressing Skp2B. Furthermore, we show that the activity of p53 is reduced in the mammary glands of Skp2B transgenic mice. This study indicates that both Skp2 and Skp2B attenuate p53 activity through different pathways, suggesting that amplification of the Skp2 locus represents a powerful mechanism to attenuate p53 function in cancer.

Gene-specific mechanisms of p53 transcriptional control and prospects for cancer therapy

The regulation of gene-specific activation is critical to the tumor suppressor function by p53. p53 is a well-characterized transcription factor that responds to DNA damage and other genotoxic stresses by the activation of downstream targets that are involved with repair, differentiation, senescence, growth arrest, and apoptosis. Sequence-specific binding to DNA, conformation, post-translational modifications, cofactor binding, stability, and subcellular localization all influence the performance of p53. The purpose of this review is to define features that play a key role in gene-specific activation and to show that these are often incapacitated in cancer cells. Using such knowledge to design selective strategies for the restoration of p53 wild-type function in cancer cells represents a promising cancer therapy.

Target structure-based discovery of small molecules that block human p53 and CREB binding protein association

Lysine acetylation of human tumor suppressor p53 in response to cellular stress signals is required for its function as a transcription factor that regulates cell cycle arrest, senescence, or apoptosis. Here, we report small molecules that block lysine 382-acetylated p53 association with the bromodomain of the coactivator CBP, an interaction essential for p53-induced transcription of the cell cycle inhibitor p21 in response to DNA damage. These chemicals were discovered in target structure-guided nuclear magnetic resonance spectroscopy screening of a focused chemical library constructed based on the structural knowledge of CBP bromodomain/p53-AcK382 binding. Structural characterization shows that these chemicals inhibit CBP/p53 association by binding to the acetyl-lysine binding site of the bromodomain. Cell-based functional assays demonstrate that the lead chemicals can modulate p53 stability and function in response to DNA damage.

Evidence against a role for SV40 in human mesothelioma

SV40 has been implicated in the etiology of 40% to 60% of human mesotheliomas. These studies could have important medical implications concerning possible sources of human infection and potential therapies if human tumors are induced by this agent. We did PCR-based analysis to detect SV40 large T antigen DNA in human mesotheliomas. None of 69 tumors in which a single copy gene was readily amplified contained detectable SV40 large T antigen sequences. Under these conditions, it was possible to detect one copy of integrated SV40 DNA per cell in a mixture containing a 5,000-fold excess of normal cells using formalin-fixed preparations. Kidney, a known reservoir of SV40 in monkeys, from some of these individuals were also negative for SV40 large T antigen sequences. A subset of mesotheliomas was analyzed for SV40 large T antigen expression by immunostaining with a highly specific SV40 antibody. These tumors as well as several human mesothelioma cell lines previously reported to contain SV40 large T antigen were negative for detection of the virally encoded oncoprotein. Moreover, mesothelioma cell lines with wild-type p53 showed normal p53 function in response to genotoxic stress, findings inconsistent with p53 inactivation by the putative presence of SV40 large T antigen. Taken together, these findings strongly argue against a role of SV40 by any known transformation mechanism in the etiology of the majority of human malignant mesotheliomas.

DNA damage-induced downregulation of Cdc25C is mediated by p53 via two independent mechanisms: one involves direct binding to the cdc25C promoter

The Cdc25C phosphatase mediates cellular entry into mitosis. The cdc25C gene is a target for transcriptional downregulation by the tumor suppressor protein p53, and this repression can be shown to contribute to p53-dependent cell cycle arrest. Two independent mechanisms have been identified. One involves the direct binding of p53 to a site in the cdc25C promoter, and the second involves a CDE/CHR element. Both of these mediate p53-dependent repression at levels of p53 comparable to those produced by DNA damage. Three CCAAT elements in the cdc25C promoter that were previously implicated in p53-dependent repression fail to do so at physiologically relevant levels of p53. Repression of Cdc25C by p53 represents an additional mechanism for p53-dependent cell cycle arrest in response to DNA damage. Importantly, this is a clear demonstration of p53-mediated transcriptional downregulation that is dependent on sequence-specific DNA binding by p53.

Stabilization and activation of p53 by the coactivator protein TAFII31

Regulation of the stability of p53 is key to its tumor-suppressing activities. mdm2 directly binds to the amino-terminal region of p53 and targets it for degradation through the ubiquitin-proteasome pathway. The coactivator protein TAF(II)31 binds to p53 at the amino-terminal region that is also required for interaction with mdm2. In this report, we demonstrate that expression of TAF(II)31 inhibits mdm2-mediated ubiquitination of p53 and increases p53 levels. TAF(II)31-mediated p53 stabilization results in activation of p53-mediated transcriptional activity and leads to p53-dependent growth arrest in fibroblasts. UV-induced stabilization of p53 coincides with an increase in p53-associated TAF(II)31 and a corresponding decrease in mdm2-p53 interaction. Non-p53 binding mutant of TAF(II)31 fails to stabilize p53. Our results suggest that direct interaction of TAF(II)31 and p53 not only mediates p53 transcriptional activation but also protects p53 from mdm2-mediated degradation, thereby resulting in activation of p53 functions.

Identification of a novel class of genomic DNA-binding sites suggests a mechanism for selectivity in target gene activation by the tumor suppressor protein p53

There are two response elements for p53 in the promoter of the gene for the cyclin-dependent kinase inhibitor p21. The binding of p53 to the 5' site was enhanced by incubation with monoclonal antibody 421, whereas the binding of p53 to the 3' site was inhibited. Mutational analysis showed that a single-base change caused one element to behave like the other. A response element in the human cdc25C promoter is bound by p53 with properties similar to the 3' site. These results identify two classes of p53-binding sites and suggest a mechanism for target gene selectivity by p53.

Retinoblastoma protein and simian virus 40-dependent immortalization of human fibroblasts

Transformation and immortalization of human diploid fibroblasts by simian virus 40 (SV40) is at least a two-stage process, since transformants have a limited lifespan in culture. We have isolated immortalized derivatives (AR5 and HAL) from transformants generated with an origin-defective SV40 genome encoding a heat-labile large T protein (T antigen) and reported that both preimmortal and immortal transformants are continuously dependent on T antigen function for growth as determined by temperature shift experiments. In this study, we demonstrate complex formation between T antigen and the retinoblastoma susceptibility gene product (Rb) at 35 degrees C and observed a reduction in complexes under conditions of loss of T antigen function and growth inhibition at 39 degrees C. Viral oncogenes (polyomavirus large T protein and adenovirus E1A 12S protein) known to bind Rb were introduced into AR5 and HAL cells, both stably by gene transfer and transiently by virus vectors. Such double transformants are still unable to proliferate at 39 degrees C, although complex formation with the newly introduced oncogenes was demonstrated. We suggest that T antigen interacts with other cellular processes in addition to Rb to transform and immortalize human cells in culture. Our finding that p53-T antigen complexes are also temperature dependent in AR5 and HAL cells could provide such an additional mechanism.