sox9b Is a Key Regulator of Pancreaticobiliary Ductal System Development

Cholangiocarcinoma (CCA) is an aggressive tumor with a poor prognosis due to its late clinical presentation and the lack of effective non-surgical therapies. Unfortunately, most of the patients are not eligible for curative surgery owing to the presence of metastases at the time of diagnosis. Therefore, it is important to understand the steps leading to cell dissemination in patients with CCA. To metastasize from the primary site, cancer cells must acquire migratory and invasive properties by a cell plasticity-promoting phenomenon known as epithelial-mesenchymal transition (EMT). EMT is a reversible dynamic process by which epithelial cells gradually adopt structural and functional characteristics of mesenchymal cells, and has lately become a center of attention in the field of metastatic dissemination. In the present review, we aim to provide an extensive overview of the current clinical data and the prognostic value of different EMT markers that have been analyzed in CCA. We summarize all the regulatory networks implicated in EMT from the membrane receptors to the main EMT-inducing transcription factors (SNAIL, TWIST and ZEB). Furthermore, since a tumor is a complex structure not exclusively formed by tumor cells, we also address the prominent role of the main cell types of the desmoplastic stroma that characterizes CCA in the regulation of EMT. Finally, we discuss the therapeutic considerations and difficulties faced to develop an effective anti-EMT treatment due to the redundancies and bypasses among the pathways regulating EMT. 4Key Point Box -EMT is an early event of metastasis that endows tumor cells with invasive properties enabling them to spread toward other territories.-EMT contributes to CCA progression and chemoresistance.-The three families of transcription factors that regulate epithelial and mesenchymal marker expression during EMT (SNAIL, TWIST and ZEB) contribute to CCA progression.-Cells of CCA microenvironment, and not only cancer cells, lead to the activation of EMT.

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“…Among Notch signaling target genes, Sox9 plays a fundamental role in biliary pathophysiology [103,104].…”

Section: Development-related Pathways (Figure 2d)mentioning

confidence: 99%

Epithelial-mesenchymal transition in cholangiocarcinoma: From clinical evidence to regulatory networks

Vaquero

Guedj

Clapéron

et al. 2017

Journal of Hepatology

112

117

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“…SOX4 and SOX9 are known regulators of these pathways in cancer and development (Bhattaram et al, 2010;Delous et al, 2012;Kuwahara et al, 2012;Manfroid et al, 2012;Moreno, 2010;Scharer et al, 2009;Song et al, 2013;Vervoort et al, 2013), raising the possibility that SOX factors control biliary development by modulating the response to intercellular signaling. To -14 -address this hypothesis, we investigated the expression of signaling markers in SOX factor-deficient livers.…”

Section: Sox4 and Sox9 Control Signaling Pathways Involved In Biliarymentioning

confidence: 99%

Transcription factors SOX4 and SOX9 cooperatively control development of bile ducts

Poncy

Antoniou

Cordi

et al. 2015

Developmental Biology

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In developing liver, cholangiocytes derive from the hepatoblasts and organize to form the bile ducts. Earlier work has shown that the SRY-related High Mobility Group box transcription factor 9 (SOX9) is transiently required for bile duct development, raising the question of the potential involvement of other SOX family members in biliary morphogenesis. Here we identify SOX4 as a new regulator of cholangiocyte development. Liver-specific inactivation of SOX4, combined or not with inactivation of SOX9, affects cholangiocyte differentiation, apico-basal polarity and bile duct formation. Both factors cooperate to control the expression of mediators of the Transforming Growth Factor-β, Notch, and Hippo-Yap signaling pathways, which are required for normal development of the bile ducts. In addition, SOX4 and SOX9 control formation of primary cilia, which are known signaling regulators. The two factors also stimulate secretion of laminin α5, an extracellular matrix component promoting bile duct maturation. We conclude that SOX4 is a new regulator of liver development and that it exerts a pleiotropic control on bile duct development in cooperation with SOX9.

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“…In zebrafish, the intrahepatic biliary network is formed by small-diameter ductular biliary epithelial cells, which might be analogous to small-diameter ductular biliary epithelial cells in the mammalian liver lobule that transport bile from the canalicular network to the intralobular bile ducts in the portral tract (Kaneko et al, 2015). Indeed, there is remarkable conservation of both genes and gene function across vertebrate biliary system development, and thus many candidate genes responsible for biliary system abnormalities in humans can be screened efficiently and rapidly in the zebrafish model Delous et al, 2012;Hand et al, 2009;Lorent et al, 2015Lorent et al, , 2010Lorent et al, , 2004Matthews et al, 2011Matthews et al, , 2005Sakaguchi et al, 2008;Schaub et al, 2012). The zebrafish transgenic line Tg(Tp1-MmHbb: EGFP) um14 , which is generated by conjugating tandem RBPJκ response element repeats with enhanced green fluorescent protein (EGFP), expresses EGFP specifically in the intrahepatic biliary network in the zebrafish liver (Lorent et al, 2010;Parsons et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Three-dimensional structural analysis reveals a Cdk5-mediated kinase cascade regulating hepatic biliary network branching in zebrafish

et al. 2017

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The intrahepatic biliary network is a highly branched threedimensional network lined by biliary epithelial cells, but how its branching patterns are precisely established is not clear. We designed a new computer-based algorithm that quantitatively computes the structural differences of the three-dimensional networks. Utilizing the algorithm, we showed that inhibition of Cyclin-dependent kinase 5 (Cdk5) led to reduced branching in the intrahepatic biliary network in zebrafish. Further, we identified a previously unappreciated downstream kinase cascade regulated by Cdk5. Pharmacological manipulations of this downstream kinase cascade produced a crowded branching defect in the intrahepatic biliary network and influenced actin dynamics in biliary epithelial cells. We generated larvae carrying a mutation in cdk5 regulatory subunit 1a (cdk5r1a), an essential activator of Cdk5. cdk5r1a mutant larvae show similar branching defects as those observed in Cdk5 inhibitortreated larvae. A small-molecule compound that interferes with the downstream kinase cascade rescued the mutant phenotype. These results provide new insights into branching morphogenesis of the intrahepatic biliary network.

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sox9b Is a Key Regulator of Pancreaticobiliary Ductal System Development

Cited by 109 publications

References 51 publications

Epithelial-mesenchymal transition in cholangiocarcinoma: From clinical evidence to regulatory networks

Epithelial-mesenchymal transition in cholangiocarcinoma: From clinical evidence to regulatory networks

Transcription factors SOX4 and SOX9 cooperatively control development of bile ducts

Three-dimensional structural analysis reveals a Cdk5-mediated kinase cascade regulating hepatic biliary network branching in zebrafish

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