A novel "patient-like" model of cholangiocarcinoma progression based on bile duct inoculation of tumorigenic rat cholangiocyte cell lines.

UNLABELLED: Intrahepatic cholangiocarcinoma typically presents in an advanced stage in which treatment options are limited. In an effort to recapitulate key biological and clinical features of the progressive disease, we established a novel rat model based on bile duct inoculation of rat cholangiocyte cell lines in different stages of tumor progression. Our BDEneu cell line, which is highly tumorigenic, originated from an immortalized rat cholangiocyte cell line (BDE1 cells) that was stably transfected to constitutively overexpress mutationally activated rat neu oncogene. Our less aggressive tumorigenic BDEsp cholangiocyte cell line was derived from the spontaneous in vitro neoplastic transformation of the same parent BDE1 cell line. Unlike BDEneu cells, BDEsp cells expressed wild-type c-neu and exhibited in vitro growth rates intermediate between those of BDEneu and BDE1 cholangiocytes. Cyclooxygenase-2 and activated Akt were significantly overexpressed in BDEsp cells over those of BDE1 cells, and at higher levels than those expressed in BDEneu cells. Only BDEneu cells overexpressed activated p185(neu), which was associated with a significant increase in phospho-p44/42 mitogen-activated protein kinase (MAPK). Mucin 1 (MUC1) messenger RNA (mRNA), an indicator of cholangiocarcinoma cell progression, was also significantly overexpressed in BDEneu cells over that of BDEsp cells. BDEneu cells inoculated into the bile duct of isogenic rats resulted over a 21- to 26-day period in rapid exponential cholangiocarcinoma tumor growth within liver, paralleled by increases in bile duct obstruction and gross peritoneal metastases. Under comparable conditions, BDEsp cells yielded only small nonmetastatic intrahepatic cholangiocarcinomas without bile duct obstruction. CONCLUSIONS: A novel model of cholangiocarcinoma progression mimicking progressive development of the advanced human disease has been established, which may serve as a powerful preclinical platform to study cholangiocarcinoma progression and for rapidly testing treatment approaches.

erbB-2/neu transformed rat cholangiocytes recapitulate key cellular and molecular features of human bile duct cancer.

BACKGROUND & AIMS: Cholangiocarcinomas appear to arise from the malignant transformation of cholangiocytes lining the biliary tract. Because the development of an in vitro model of malignant transformation can provide a powerful new tool for establishing critical events governing the molecular pathogenesis of cholangiocarcinoma, we investigated the potential of achieving malignant transformation of cultured rat cholangiocytes in relation to aberrant overexpression of mutationally activated erbB-2/neu. METHODS: Malignant neoplastic transformation was achieved after infection of the rat cholangiocyte cell line, designated BDE1, with the retrovirus Glu664-neu, containing the transforming rat erbB-2/neu oncogene. RESULTS: Compared with untransformed control cells, malignant transformants carrying the activating erbB-2/neu mutation prominently overexpressed p185neu receptor protein, which was phosphorylated strongly at its major autophosphorylation site at tyrosine 1248. Moreover, erbB-2/neu transformation of BDE1 cells resulted in increased telomerase activity, up-regulation of cyclooxygenase-2 with overproduction of prostaglandin E(2), enhanced phosphorylation of mitogen-activated protein kinase and of serine/threonine kinase Akt/PKB, overexpression of vascular endothelial growth factor, and increased mucin 1 messenger RNA expression. Only erbB-2/neu transformants were tumorigenic when transplanted into isogeneic rats, yielding a 100% incidence of tumors closely resembling human desmoplastic ductal cholangiocarcinomas in their morphology. Malignant cholangiocytes in the tumors were strongly immunoreactive for biliary cytokeratin 19, p185neu, and cyclooxygenase-2. CONCLUSIONS: This unique malignant transformation model recapitulates key molecular features of the human disease and appears to be well suited for testing novel molecular therapeutic strategies against cholangiocarcinoma.