Acquired chemoresistance in pancreatic carcinoma cells: induced secretion of IL-1beta and NO lead to inactivation of caspases.

Pancreatic cancer exhibits profound chemoresistance resulting either from pre-existing (intrinsic) mechanisms, or from anticancer drug treatment itself (acquired chemoresistance). To identify molecular alterations leading to acquired chemoresistance, the chemosensitive pancreatic carcinoma cell line PT45-P1 was exposed to low-dose treatment with etoposide for 6 weeks. Afterwards, these cells (PT45-P1res) were much more resistant to high-dose treatment with anticancer drugs than parental cells. Among several differentially expressed genes in PT45-P1res cells, IL-1beta was most significantly upregulated, a finding in line with our previous observation that IL-1beta accounts for intrinsic chemoresistance of pancreatic carcinoma cells. Elevated IL-1beta expression in PT45-P1res cells was confirmed by real-time PCR and ELISA, and treatment with the IL-1 receptor antagonist restored drug-induced apoptosis. The increased IL-1beta secretion was accompanied by an elevated formation of nitric oxide (NO) and a NO-dependent inhibition of the etoposide-induced caspase-3/-7/-8/-9 activity. Caspase activation was restored either by the iNOS inhibitor 1400W, the reducing agent dithiothreitol or the IL-1 receptor antagonist, resulting in greater sensitivity towards anticancer drug treatment. Conversely, IL-1beta or the NO-donor SNAP decreased caspase activation and apoptosis in etoposide-treated PT45-P1 cells. These data confirm IL-1beta and NO as determinants of chemoresistance in pancreatic cancer, and indicate that the intrinsic and acquired chemoresistance rely to some extent on common molecular targets beneficial for improved therapeutical strategies.

The proliferation-associated early response gene p22/PRG1 is a novel p53 target gene.

The novel early response gene p22/PRG1 is linked to cell cycle entry and the induction of proliferation in various cell types although its exact function is still unknown. The p22/PRG1 promoter region contains a 20 bp sequence matching the consensus binding motif for the tumor suppressor protein p53. Gel shift assays demonstrated that p53 specifically binds to an oligonucleotide derived from the p53 binding site of the p22/PRG1 promoter. Chloramphenicol acetyltransferase (CAT) reporter gene assays confirmed that this site confers p53-dependent transcriptional activity to the p22/PRG1 promoter. In Hela cells, p22/PRG1 promoter constructs induced CAT expression only when cotransfected with an expression plasmid for wild-type, but not for mutant p53. Similarly, CAT expression was inducible at the permissive (31 degrees C) but not at the non-permissive temperature (39 degrees C) in the rat embryo fibroblast-derived cell line clone-6 that expresses a temperature-sensitive mutant p53. Conversion of this mutant p53 to a functional p53 at the permissive temperature was accompanied by a significant increase of endogenous p22/PRG1 mRNA level in this cell line. Gamma-irradiation of rat splenocytes or doxorubicin-treatment of Hela cells increased p53 levels followed by transcriptional activation of p22/PRG1 and p21/Waf1 in parallel. Our data demonstrate that p22/PRG1 transcription is induced by p53 during p53-dependent cell cycle arrest and apoptosis. Therefore, p22/PRG1 represents a novel target for transcriptional activation by p53.

p22/PACAP response gene 1 (PRG1): a putative target gene for the tumor suppressor p53.

In this study we describe a novel putative p53-responsive gene, designated p22/PACAP response gene 1 (PRG1), recently identified as a proliferation-associated early-response gene in rats. By means of electrophoretic mobility shift assay and CAT-reporter gene assay, we could demonstrate that the p53 binding site residing in the promoter of p22/PRG1 is functional in vitro. Furthermore, in clone 6 cells expression of p22/PRG1 is induced in parallel to p21/Waf1 under conditions permitting mutant p53 to adopt wild-type configuration. An increase of p22/PRG1 transcription was also observed in gamma-irradiated rat splenocytes, which undergo p53-dependent apoptosis. Our findings demonstrate that p22/PRG1 fulfills all essential criteria as a p53 target gene and might be implicated in p53-dependent apoptosis.

Allogeneic mouse T cell lines distinguish three Balb/c leukemias from each other and from non-leukemic lymphocytes.

In order to separate graft-versus-leukemia (GVL) effect from graft-versus-host (GVH) reactions in allogeneic cell therapy, we established cytotoxic T cell lines (CTL) against irradiated A20, WEHI-3 and PU cells, ie cells from 3 hematopoietic tumors of Balb/c origin. Immunization with these cell lines did not lead to prolonged survival in Balb/c mice. The cytotoxic activity of the CTL was tested against the 3 leukemias. In all 9 combinations the highest specific lysis was achieved against the stimulating tumor. Cold target inhibition experiments showed that the activity against 51Cr-labelled leukemia cells could be almost completely inhibited by adding a sufficient amount of unlabelled target cells. On the other hand, when unlabelled concanavalin A-induced Balb/c blast cells were added, the inhibition was incomplete. By means of flow cytometry it was excluded that the different susceptibilities and inhibitory potentials of tumor cells and nonmalignant blasts are caused solely by differences in the MHC expression of the target cells. These findings confirm that allogeneic CTL are capable of discriminating malignant from nonmalignant cells, even if the tumor is nonimmunogenic in syngeneic animals.