Crosstalk between c-Jun and TAp73alpha/beta contributes to the apoptosis-survival balance.

The p53-family member p73 plays a role in various cellular signaling pathways during development and growth control and it can have tumor suppressor properties. Several isoforms of p73 exist with considerable differences in their function. Whereas the functions of the N-terminal isoforms (TA and ΔNp73) and their opposing pro- and antiapoptotic roles have become evident, the functional differences of the distinct C-terminal splice forms of TAp73 have remained unclear. Here, we characterized the global genomic binding sites for TAp73α and TAp73ß by chromatin immunoprecipitation sequencing as well as the transcriptional responses by performing RNA sequencing. We identified a specific p73 consensus binding motif and found a strong enrichment of AP1 motifs in close proximity to binding sites for TAp73α. These AP1 motif-containing target genes are selectively upregulated by TAp73α, while their mRNA expression is repressed upon TAp73ß induction. We show that their expression is dependent on endogenous c-Jun and that recruitment of c-Jun to the respective AP1 sites was impaired upon TAp73ß expression, in part due to downregulation of c-Jun. Several of these AP1-site containing TAp73α-induced genes impinge on apoptosis induction, suggesting an underlying molecular mechanism for the observed functional differences between TAp73α and TAp73ß.

Role of p53 serine 46 in p53 target gene regulation.

The tumor suppressor p53 plays a crucial role in cellular growth control inducing a plethora of different response pathways. The molecular mechanisms that discriminate between the distinct p53-responses have remained largely elusive. Here, we have analyzed the p53-regulated pathways induced by Actinomycin D and Etoposide treatment resulting in more growth arrested versus apoptotic cells respectively. We found that the genome-wide p53 DNA-binding patterns are almost identical upon both treatments notwithstanding transcriptional differences that we observed in global transcriptome analysis. To assess the role of post-translational modifications in target gene choice and activation we investigated the genome-wide level of phosphorylation of Serine 46 of p53 bound to DNA (p53-pS46) and of Serine 15 (p53-pS15). Interestingly, the extent of S46 phosphorylation of p53 bound to DNA is considerably higher in cells directed towards apoptosis while the degree of phosphorylation at S15 remains highly similar. Moreover, our data suggest that following different chemotherapeutical treatments, the amount of chromatin-associated p53 phosphorylated at S46 but not at pS15 is higher on certain apoptosis related target genes. Our data provide evidence that cell fate decisions are not made primarily on the level of general p53 DNA-binding and that post-translationally modified p53 can have distinct DNA-binding characteristics.

Genome-wide profiling of p63 DNA-binding sites identifies an element that regulates gene expression during limb development in the 7q21 SHFM1 locus.

Heterozygous mutations in p63 are associated with split hand/foot malformations (SHFM), orofacial clefting, and ectodermal abnormalities. Elucidation of the p63 gene network that includes target genes and regulatory elements may reveal new genes for other malformation disorders. We performed genome-wide DNA-binding profiling by chromatin immunoprecipitation (ChIP), followed by deep sequencing (ChIP-seq) in primary human keratinocytes, and identified potential target genes and regulatory elements controlled by p63. We show that p63 binds to an enhancer element in the SHFM1 locus on chromosome 7q and that this element controls expression of DLX6 and possibly DLX5, both of which are important for limb development. A unique micro-deletion including this enhancer element, but not the DLX5/DLX6 genes, was identified in a patient with SHFM. Our study strongly indicates disruption of a non-coding cis-regulatory element located more than 250 kb from the DLX5/DLX6 genes as a novel disease mechanism in SHFM1. These data provide a proof-of-concept that the catalogue of p63 binding sites identified in this study may be of relevance to the studies of SHFM and other congenital malformations that resemble the p63-associated phenotypes.

Behind the scenes: unravelling the molecular mechanisms of p53 target gene selectivity (Review).

The p53 protein is a tumor suppressor that plays a crucial role in cellular growth regulation inducing a plethora of response pathways. p53 post-translational modifications, p53-binding proteins, co-factors and the p53-family members p63 and p73 have all been described to contribute to p53 target gene regulation and hence cellular outcome. However, the molecular mechanisms that discriminate between the different p53-responses towards stress treatments have remained largely elusive. This review focuses on the topic of the molecular mechanisms behind target gene selectivity of the transcription factor p53 and provides insight into the latest era of p53 research.

Mechanism of interferon-gamma mediated down-regulation of interleukin-10 gene expression.

Expression of the anti-inflammatory cytokine IL-10 is suppressed by the pro-inflammatory interferon gamma but the mechanism of this action is unknown. We analysed activity of IL-10 promoter luciferase reporter constructs in transfected RPMI 8226.1 B cells that were treated at -2 h with IFNgamma (1000 U/ml) followed by stimulation with LPS (100 ng/ml) at 0 h. IFNgamma treatment suppressed LPS-induced IL-10 promoter activity in a construct carrying the -1044 promoter and also one containing the -195 promoter. The suppression was independent of the IRF-motif at -182 but involved the Stat-motif at -120. In gelshift analysis this Stat motif did bind LPS-induced Stat3 and with IFNgamma treatment it did, in addition, bind Stat1. ChIP analysis for detection of transcription factor binding to chromatin in intact cells demonstrated Stat3 binding to the proximal IL-10 promoter when cells are stimulated with LPS only. Treatment with IFNgamma only led to Stat1 binding in ChIP analysis and treatment with IFNgamma plus LPS led to reduced Stat3 binding while Stat1 binding remained high. Finally, LPS-induced activity of the trimeric Stat-motif in front of the luciferase reporter was suppressed by IFNgamma. These data demonstrate that IFNgamma down-regulates expression of the IL-10 gene by a novel mechanism that involves displacement of transactiving Stat3 by IFNgamma-induced Stat1.

The novel p53 target gene IRF2BP2 participates in cell survival during the p53 stress response.

The tumor suppressor p53 contributes to the cellular fate after genotoxic insults, mainly through the regulation of target genes, thereby allowing e.g. repair mechanisms resulting in cell survival or inducing apoptosis. Unresolved so far is the issue, which exact mechanisms lead to one or the other cellular outcome. Here, we describe the interferon regulatory factor-2-binding protein-2 (IRF2BP2) as a new direct target gene of p53, influencing the p53-mediated cellular decision. We show that upregulation of IRF2BP2 after treatment with actinomycin D (Act.D) is dependent on functional p53 in different cell lines. This occurs in parallel with the down-regulation of the interacting partner of IRF2BP2, the interferon regulatory factor-2 (IRF2), which is known to positively influence cell growth. Analyzing the molecular functions of IRF2BP2, it appears to be able to impede on the p53-mediated transactivation of the p21- and the Bax-gene. We show here that overexpressed IRF2BP2 has an impact on the cellular stress response after Act.D treatment and that it diminishes the induction of apoptosis after doxorubicin treatment. Furthermore, the knockdown of IRF2BP2 leads to an upregulation of p21 and faster induction of apoptosis after doxorubicin as well as Act.D treatment.

Characterization of genome-wide p53-binding sites upon stress response.

The tumor suppressor p53 is a sequence-specific transcription factor, which regulates the expression of target genes involved in different stress responses. To understand p53's essential transcriptional functions, unbiased analysis of its DNA-binding repertoire is pivotal. In a genome-wide tiling ChIP-on-chip approach, we have identified and characterized 1546 binding sites of p53 upon Actinomycin D treatment. Among those binding sites were known as well as novel p53 target sites, which included regulatory regions of potentially novel transcripts. Using this collection of genome-wide binding sites, a new high-confidence algorithm was developed, p53scan, to identify the p53 consensus-binding motif. Strikingly, this motif was present in the majority of all bound sequences with 83% of all binding sites containing the motif. In the surrounding sequences of the binding sites, several motifs for potential regulatory cobinders were identified. Finally, we show that the majority of the genome-wide p53 target sites can also be bound by overexpressed p63 and p73 in vivo, suggesting that they can possibly play an important role at p53 binding sites. This emphasizes the possible interplay of p53 and its family members in the context of target gene binding. Our study greatly expands the known, experimentally validated p53 binding site repertoire and serves as a valuable knowledgebase for future research.

Role of STAT3 in glucocorticoid-induced expression of the human IL-10 gene.

In the present report we have determined the molecular mechanisms, which govern the expression of the human IL-10 gene when induced by the glucocorticoid Methyl-Prednisolone (MP). Treatment of cells with MP at 10(-6) M will readily induce IL-10 in CD19+ primary B cells and in a human B cell line. Analysis of the IL-10 promoter showed a robust 18-fold induction and demonstrated that a potential GRE motif was not required, while mutation of the -120 STAT-motif strongly reduced MP-induced trans-activation. A strong induction was also seen with a trimeric STAT-motif and over-expression of dominant-negative STAT3 could block MP induction of IL-10 mRNA. Finally, MP treatment induced binding of STAT3 to the promoter as shown by gelshift, supershift and by chromatin-immunoprecipitation. These data show that glucocorticoid-induced expression of the IL-10 gene is mediated by the transcription factor STAT3.

The new frontier in cancer research: deciphering cancer epigenetics.

Cancer has long been known to be a disease caused by alterations in the genetic blueprint of cells. In the past decade it has become apparent that epigenetic alterations also underlie the etiology of cancer. Since epigenetic changes may be more facile to reverse than genetic lesions, much research has been invested in their characterization. Success has indeed been booked in the clinic with drugs that erase DNA methylation imprints or that target histone post-translational modifications such as lysine acetylation. However, the actual consequences of current epigenetic pharmacological intervention protocols are still poorly characterized and may be rather pleiotropic in nature. The challenge we face is therefore to define the cellular enzymes responsible for epigenetic modifications at given genes under specific conditions, so as to develop pharmacological agents that target tumorigenic epigenetic lesions while eliciting minimal unwanted side effects. Application of genome-wide analytical tools has begun to provide spatio-temporally resolved data that will be crucial to achieve this goal. Finally, the molecular mode of action of epigenetic drugs may be more intricate than initially thought, involving more than DNA and histones, since it has been reported that transcription (co)factors are themselves also targeted by histone modifying enzymes.

Targeted discovery tools: proteomics and chromatin immunoprecipitation-on-chip.

Despite the availability of several completely sequenced genomes, we are still, for the most part, ignorant about how genes interact and regulate each other within a given cell type to specify identity, function and cellular memory. A realistic model of cellular regulation based on current knowledge indicates that many interacting networks operate at the epigenetic, transcriptional, translational and post-translational levels, with feedback between the various levels. Protein-protein and protein-DNA interactions help to define which genes may be activated in a particular cell, and determine whether external cues cause activation or repression. New technologies, e.g. proteomics using mass spectrometry, high-density DNA or oligonucleotide microarrays (chips), and chromatin immunoprecipitation (ChIP), provide new and exciting tools for deciphering the pathways and proteins controlling gene expression. Analysis of these pathways offers new insight that aids targeted drug development.

Regulation of HDM2 activity by the ribosomal protein L11.

The HDM2 protein plays an important role in regulating the stability and function of the p53 tumor suppressor protein. In this report, we show that the ribosomal protein L11 can interact with HDM2 and inhibit HDM2 function, thus leading to the stabilization and activation of p53. The inhibition of HDM2 activity by L11 shows some similarity to the previously described activity of ARF, and expression of either ARF or L11 can induce a p53 response. Enhancement of the interaction between endogenous L11 and HDM2 following treatment of cells with low levels of actinomycin-D suggests that the HDM2/L11 interaction represents a novel pathway for p53 stabilization in response to perturbations in ribosome biogenesis.