Pancreas transcription factor 1alpha expression is regulated in pancreatitis.

BACKGROUND: Expression of acinar cell-specific genes requires the pancreas transcription factor 1alpha (Ptf1alpha). p48 is the only component of Ptf1alpha that is involved in both acinar gene regulation and pancreatic ontogenesis. MATERIALS AND METHODS: To determine whether Ptf1alpha/p48 expression is regulated during pancreatitis, acute pancreatitis was induced in rats by repeated caerulein injections; early chronic pancreatitis by the combined administration of caerulein and cyclosporin A; and focal pancreas fibrosis by trinitrobenzene sulfonic acid infusion into the pancreatic duct. AR42J cells were used to examine caerulein effects on acinar cells. Ptf1alpha/p48 expression was examined using immunohistochemistry, Western blotting, and qRT-PCR methods. RESULTS: In acute pancreatitis, Ptf1alpha/p48 decreased markedly within 6 h as determined by Western blotting and immunohistochemistry. After 24 h, Ptf1alpha/p48 increased continuously and normalized at day six. In contrast, pancreas amylase reached a nadir at 48 h, when Ptf1alpha/p48 had largely recovered. In the early chronic pancreatitis model Ptf1alpha/p48 levels did not completely recover even at day 14, and this was associated with a failure to restore normal histology and amylase content. qRT-PCR showed that p48 mRNA were reduced after pancreatitis induction and were followed by a decrease in elastase mRNA. In the focal pancreas fibrosis model, Ptf1alpha/p48 expression was undetectable in areas with substantial acinar cell loss and tubular complexes. Caerulein did not affect Ptf1alpha/p48 expression in AR42J cells. CONCLUSIONS: Ptf1alpha/p48 protein and mRNA levels are regulated in acute and chronic experimental pancreatitis. Inability to re-express Ptf1alpha/p48 after injury may preclude acinar cell differentiation and appropriate pancreatic regeneration.

Role of the basic helix-loop-helix transcription factor p48 in the differentiation phenotype of exocrine pancreas cancer cells.

The majority of human pancreatic adenocarcinomas display a ductal phenotype; experimental studies indicate that tumors with this phenotype can arise from both acinar and ductal cells. In normal pancreas acinar cells, the pancreas transcription factor 1 transcriptional complex is required for gene expression. Pancreas transcription factor 1 is a heterooligomer of pancreas-specific (p48) and ubiquitous (p75/E2A and p64/HEB) basic helix-loop-helix proteins. We have examined the role of p48 in the phenotype of azaserine-induced rat DSL6 tumors and cancers of the human exocrine pancreas. Serially transplanted acinar DSL6 tumors express p48 whereas DSL6-derived cell lines, and the tumors induced by them, display a ductal phenotype and lack p48. In human pancreas cancer cell lines and tissues, p48 is present in acinar tumors but not in ductal tumors. Transfection of ductal pancreas cancers with p48 cDNA did not activate the expression of amylase nor a reporter gene under the control of the rat elastase promoter. In some cell lines, p48 was detected in the nucleus whereas in others it was cytoplasmic, as in one human acinar tumor. Together with prior work, our findings indicate that p48 is associated with the acinar phenotype of exocrine pancreas cancers and it is necessary, but not sufficient, for the expression of the acinar phenotype.

Expressed sequence tag (EST) phenotyping of HT-29 cells: cloning of ser/thr protein kinase EMK1, kinesin KIF3B, and of transcripts that include Alu repeated elements.

To study the mechanisms that control epithelial commitment and differentiation we have used undifferentiated HT-29 colon cancer cells and a subpopulation of mucus secreting cells obtained by selection of HT-29 cells in 10-6 M methotrexate (M6 cells) as experimental models. We isolated cDNAs encoding transcripts overexpressed in early confluent M6 cells regarding steady-state levels in HT-29 cells by subtractive hybridisation. Fifty-one cDNA clones, corresponding to 34 independent transcripts, were isolated, partially sequenced by their 5' end, and classified into four groups according to their identity: transcripts that included a repeated sequence of the Alu family (10 clones, among them those encoding ribonucleoprotein RNP-L and E-cadherin), transcripts encoded by the mitochondrial genome (nine clones), transcripts encoding components of the protein synthesis machinery (23 clones, including the human ribosomal protein L38 not previously cloned in humans) and nine additional cDNAs that could not be classified in the previous groups. These last included ferritin, cytokeratin 18, translationally controlled human tumour protein (TCHTP), mt-aldehyde dehydrogenase, as well as unknown transcripts (three clones), and the human homologues of the molecular motor kinesin KIF3B and of the ser/thr protein kinase EMK1. Spot dot and Northern blot analyses showed that ser/thr protein kinase EMK1 was differentially expressed in M6 cells when compared with parental HT-29 cells. Steady-state levels of EMK1 were higher in proliferating, preconfluent, M6 and HT-29 cells than in 2 days post confluence (dpc) and 8dpc M6 and HT-29 cells. Transcripts that included an Alu repeat were also shown to be differentially expressed and accumulated in differentiating M6 cells when analysed by Northern blot. The significance of the transcripts cloned is discussed in the context of the commitment and differentiation of the M6 cells to the mucus secreting lineage of epithelial cells.

Activation of the urokinase plasminogen activator/urokinase plasminogen activator receptor system and redistribution of E-cadherin are associated with hepatocyte growth factor-induced motility of pancreas tumor cells overexpressing Met.

Because hepatocyte growth factor (HGF) is a potent mitogen for normal human exocrine pancreas cells (NPCs) in vitro, we have analyzed the expression of HGF and its receptor, Met, in NPC and pancreas cancer cells and studied its effects in vitro. Using immunohistochemistry, Northern blotting, and reverse transcription-polymerase chain reaction, we examined the expression of HGF and Met in normal pancreas and pancreas cancer. Scatter assays, wound-healing assays, and migration through transwell filters were used to study HGF-stimulated motility of IMIM-PC-2 cancer cells. In tumors, HGF is mainly detected in stromal cells, whereas Met is overexpressed in cancer cells with an unpolarized distribution. In vitro, HGF stimulates motogenesis but not proliferation in cancer cells. Cell motility is accompanied by a rapid decrease in the cytoskeleton-bound E-cadherin, an acceleration of cellular adhesion to the substrate, an up-regulation of urokinase plasminogen activator (u-PA) RNA and protein, and a change in the solubility and proteolysis of the u-PA receptor. Cell motility is significantly reduced by inhibitors of u-PA proteolytic activity such as antibodies neutralizing u-PA activity, plasminogen activator inhibitor 1, and amiloride. These results show that a paracrine loop of HGF activation may participate in the development or progression of pancreas cancer. In vitro, the HGF-stimulated motogenesis of pancreas cancer cells involves the activation of the u-PA/u-PA receptor proteolytic system, suggesting its role in the invasive stages of tumor progression.