UNLABELLED: Cholangiocarcinoma (CCA) cells paradoxically express the death ligand, tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) and, therefore, are dependent upon potent survival signals to circumvent TRAIL cytotoxicity. CCAs are also highly desmoplastic cancers with a tumor microenvironment rich in myofibroblasts (MFBs). Herein, we examine a role for MFB-derived CCA survival signals. We employed human KMCH-1, KMBC, HuCCT-1, TFK-1, and Mz-ChA-1 CCA cells, as well as human primary hepatic stellate and myofibroblastic LX-2 cells, for these studies. In vivo experiments were conducted using a syngeneic rat orthotopic CCA model. Coculturing CCA cells with myofibroblastic human primary hepatic stellate cells or LX-2 cells significantly decreased TRAIL-induced apoptosis in CCA cells, a cytoprotective effect abrogated by neutralizing platelet-derived growth factor (PDGF)-BB antiserum. Cytoprotection by PDGF-BB was dependent upon Hedgehog (Hh) signaling, because it was abolished by the smoothened (SMO; the transducer of Hh signaling) inhibitor, cyclopamine. PDGF-BB induced cyclic adenosine monophosphate-dependent protein kinase-dependent trafficking of SMO to the plasma membrane, resulting in glioma-associated oncogene (GLI)2 nuclear translocation and activation of a consensus GLI reporter gene-based luciferase assay. A genome-wide messenger RNA expression analysis identified 67 target genes to be commonly up- (50 genes) or down-regulated (17 genes) by both Sonic hedgehog and PDGF-BB in a cyclopamine-dependent manner in CCA cells. Finally, in a rodent CCA in vivo model, cyclopamine administration increased apoptosis in CCA cells, resulting in tumor suppression. CONCLUSIONS: MFB-derived PDGF-BB protects CCA cells from TRAIL cytotoxicity by a Hh-signaling-dependent process. These results have therapeutical implications for the treatment of human CCA.
UNLABELLED: Cholangiocarcinoma (CCA) cells paradoxically express the death ligand, tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) and, therefore, are dependent upon potent survival signals to circumvent TRAILcytotoxicity. CCAs are also highly desmoplastic cancers with a tumor microenvironment rich in myofibroblasts (MFBs). Herein, we examine a role for MFB-derived CCA survival signals. We employed humanKMCH-1, KMBC, HuCCT-1, TFK-1, and Mz-ChA-1 CCA cells, as well as human primary hepatic stellate and myofibroblastic LX-2 cells, for these studies. In vivo experiments were conducted using a syngeneic rat orthotopic CCA model. Coculturing CCA cells with myofibroblastic human primary hepatic stellate cells or LX-2 cells significantly decreased TRAIL-induced apoptosis in CCA cells, a cytoprotective effect abrogated by neutralizing platelet-derived growth factor (PDGF)-BB antiserum. Cytoprotection by PDGF-BB was dependent upon Hedgehog (Hh) signaling, because it was abolished by the smoothened (SMO; the transducer of Hh signaling) inhibitor, cyclopamine. PDGF-BB induced cyclic adenosine monophosphate-dependent protein kinase-dependent trafficking of SMO to the plasma membrane, resulting in glioma-associated oncogene (GLI)2 nuclear translocation and activation of a consensus GLI reporter gene-based luciferase assay. A genome-wide messenger RNA expression analysis identified 67 target genes to be commonly up- (50 genes) or down-regulated (17 genes) by both Sonic hedgehog and PDGF-BB in a cyclopamine-dependent manner in CCA cells. Finally, in a rodent CCA in vivo model, cyclopamine administration increased apoptosis in CCA cells, resulting in tumor suppression. CONCLUSIONS: MFB-derived PDGF-BB protects CCA cells from TRAILcytotoxicity by a Hh-signaling-dependent process. These results have therapeutical implications for the treatment of human CCA.
Authors: Samer Singh; Zhiqiang Wang; Dennis Liang Fei; Kendall E Black; John A Goetz; Robert Tokhunts; Camilla Giambelli; Jezabel Rodriguez-Blanco; Jun Long; Ethan Lee; Karoline J Briegel; Pablo A Bejarano; Ethan Dmitrovsky; Anthony J Capobianco; David J Robbins Journal: Cancer Res Date: 2011-05-12 Impact factor: 12.701
Authors: Akira Anan; Edwina S Baskin-Bey; Steven F Bronk; Nathan W Werneburg; Vijay H Shah; Gregory J Gores Journal: Hepatology Date: 2006-02 Impact factor: 17.425
Authors: Boris R A Blechacz; Rory L Smoot; Steven F Bronk; Nathan W Werneburg; Alphonse E Sirica; Gregory J Gores Journal: Hepatology Date: 2009-12 Impact factor: 17.425
Authors: Robert L Yauch; Stephen E Gould; Suzie J Scales; Tracy Tang; Hua Tian; Christina P Ahn; Derek Marshall; Ling Fu; Thomas Januario; Dara Kallop; Michelle Nannini-Pepe; Karen Kotkow; James C Marsters; Lee L Rubin; Frederic J de Sauvage Journal: Nature Date: 2008-08-27 Impact factor: 49.962
Authors: David M Berman; Sunil S Karhadkar; Anirban Maitra; Rocio Montes De Oca; Meg R Gerstenblith; Kimberly Briggs; Antony R Parker; Yutaka Shimada; James R Eshleman; D Neil Watkins; Philip A Beachy Journal: Nature Date: 2003-09-14 Impact factor: 49.962
Authors: Christian D Fingas; Joachim C Mertens; Nataliya Razumilava; Steven F Bronk; Alphonse E Sirica; Gregory J Gores Journal: Liver Int Date: 2011-12-02 Impact factor: 5.828
Authors: Tobias Kiesslich; Christian Mayr; Julia Wachter; Doris Bach; Julia Fuereder; Andrej Wagner; Beate Alinger; Martin Pichler; Pietro Di Fazio; Matthias Ocker; Frieder Berr; Daniel Neureiter Journal: Mol Cell Biochem Date: 2014-07-27 Impact factor: 3.396
Authors: Rory L Smoot; Nathan W Werneburg; Takaaki Sugihara; Matthew C Hernandez; Lin Yang; Christine Mehner; Rondell P Graham; Steven F Bronk; Mark J Truty; Gregory J Gores Journal: J Cell Biochem Date: 2017-08-03 Impact factor: 4.429
Authors: Joachim C Mertens; Christian D Fingas; John D Christensen; Rory L Smoot; Steven F Bronk; Nathan W Werneburg; Michael P Gustafson; Allan B Dietz; Lewis R Roberts; Alphonse E Sirica; Gregory J Gores Journal: Cancer Res Date: 2012-12-05 Impact factor: 12.701