TAp63gamma can substitute for p53 in inducing expression of the maspin tumor suppressor.

Maspin is a Class II tumor suppressor protein and plays a role in tumor growth by inhibiting cellular invasion and motility. It is a member of the serpin family of protease inhibitors and has been shown to reduce angiogenesis. Maspin gene expression can be upregulated by the tumor suppressor p53. We tested 7 p53-related proteins of the p63 and p73 families for their ability to induce maspin expression. The p63 splice form TAp63gamma can substitute for p53 in activating the maspin promoter. TAp63gamma activates the promoter through the same consensus site as p53. In the DLD-1 colorectal adenocarcinoma cell line, harboring a tet-off regulated transgene, induction of TAp63gamma leads to an upregulation of maspin mRNA from the chromosomal gene. With a short lag phase also maspin protein levels are elevated after induced TAp63gamma expression. To assess a potential function of p63-dependent maspin upregulation in tumors we followed expression of p53, p63 and maspin by immunohistochemistry in hepatocellular carcinomas. Two types of tumors with wild-type or mutant p53 were assayed. Interestingly, the majority of tumors expressing only a mutated and inactive p53 protein nonetheless stain positive for maspin, whereas these tumors were positive for p63 protein expression. In summary, we show that TAp63gamma can substitute for p53 in transcriptional activation of the maspin tumor suppressor gene. TAp63gamma employs the same DNA recognition site for this activation as p53. We observe expression patterns of p53, p63 and maspin proteins in tumor tissue that may indicate also a function of maspin induction by p63 in tumors.

Identification of Tcf-4 as a transcriptional target of p53 signalling.

T-cell factor (Tcf)-4 is a main transcription factor to pass on Wnt/beta-catenin signalling. The tumour suppressor protein p53 contributes as a transcription factor to cell-cycle arrest and apoptosis induction. Mutations of components in p53 and Wnt/beta-catenin signalling networks play a part in tumour formation. Here, we identify the Tcf-4 gene as a downstream effector of p53. Induction of wild-type p53 in a tet-off regulated human colon cell system leads to the reduction of Tcf-4 mRNA and protein levels. Also, mRNA of the Tcf-4 target gene uPAR is downregulated after p53 induction. Expression of a luciferase reporter controlled by the Tcf-4 promoter is repressed by wild-type p53, but not by a p53 mutant deficient in DNA binding. Such a regulation is seen in cell lines of different origin. These findings directly link Wnt/beta-catenin signalling and p53 tumour suppressor function and may provide a mechanism by which loss of p53 function contributes to progression in the adenoma/carcinoma sequence in colon tumours. Furthermore, since Tcf-4 is expressed in many tissues and downregulation of Tcf-4 by p53 is seen in several different cell types, this regulation likely plays a role in proliferation control of all tissues that can express p53 and Tcf-4.

Three CCAAT-boxes and a single cell cycle genes homology region (CHR) are the major regulating sites for transcription from the human cyclin B2 promoter.

Cyclins are essential regulators of the cell division cycle. Cyclin B associates with the cyclin-dependent kinase 1 (cdc2) to form a complex which is required for cells to undergo mitosis. In mammalian cells three B-type cyclins have been characterised, cyclin B1, B2 and B3. The cell cycle-dependent synthesis of cyclin B1 and B2 has been investigated in detail displaying maximum expression in G2 which is mainly regulated on the transcriptional level. We have previously shown that this regulation of the mouse cyclin B2 promoter is controlled by a cell cycle-dependent element (CDE) and the cell cycle genes homology region (CHR). Also in a number of other genes CDE/CHR elements repress transcription in G0 and G1 and lead to relief of repression later during the cell cycle. Here, we compare human and mouse cyclin B2 promoters. Both promoters share only nine regions with nucleotide identities. Three of these sites are CCAAT-boxes spaced 33 bp apart which can bind the NF-Y transcriptional activator. NF-Y binding to the human cyclin B2 promoter could be shown by chromatin immunoprecipitation (ChIP) assays. Activation by NF-Y is responsible for more than 93% of the total promoter activity as measured by cotransfecting a plasmid coding for a dominant-negative form of NF-YA. Cell cycle-dependent repression is regulated solely through a CHR. Surprisingly, in contrast to the mouse promoter the CHR in the human cyclin B2 promoter does not rely on a CDE site in tandem with it. Together with the recently described mouse cdc25C promoter, human cyclin B2 is the second identified gene which solely requires a CHR for its cell cycle regulation.

Cyclin B1 transcription is enhanced by the p300 coactivator and regulated during the cell cycle by a CHR-dependent repression mechanism.

Cyclin B is a central regulator of transition from the G(2) phase of the cell cycle to mitosis. In mammalian cells two B-type cyclins have been characterised, cyclin B1 and B2. Both are expressed with a maximum in G(2) and their synthesis is mainly regulated on the transcriptional level. We show that a single cell cycle genes homology region, lacking a functional cell cycle-dependent element in tandem with it, contributes most of the cell cycle-dependent transcription from the cyclin B1 promoter. The coactivator p300 binds to the cyclin B1 promoter and synergises with the transcription factor NF-Y in activating transcription of cyclin B1.

A single cell cycle genes homology region (CHR) controls cell cycle-dependent transcription of the cdc25C phosphatase gene and is able to cooperate with E2F or Sp1/3 sites.

The cdc25C phosphatase participates in regulating transition from the G2 phase of the cell cycle to mitosis by dephosphorylating cyclin-dependent kinase 1. The tumor suppressor p53 down-regulates expression of cdc25C as part of G2/M checkpoint control. Transcription of cdc25C oscillates during the cell cycle with no expression in resting cells and maximum transcription in G2. We had identified earlier a new mechanism of cell cycle-dependent transcription that is regulated by a cell cycle-dependent element (CDE) in conjunction with a cell cycle genes homology region (CHR). The human cdc25C gene was the first example. CDE/CHR tandem elements have since been found in promoters of many cell cycle genes. Here we show that the mouse cdc25C gene is regulated by a CHR but does not hold a CDE. Therefore, it is the first identified gene with CHR-dependent transcriptional regulation during the cell cycle not relying on a CDE located upstream of it. The CHR leads to repression of cdc25C transcription early in the cell cycle and directs a release of this repression in G2. Furthermore, we find that this CHR can cooperate in cell cycle-dependent transcription with elements placed directly upstream of it binding E2F, Sp1 or Sp3 transcription factors.