Hedgehog signaling regulates epithelial-mesenchymal transition during biliary fibrosis in rodents and humans

Omenetti, Alessia; Porrello, Alessandro; Jung, Youngmi; Yang, Liu; Popov, Yury; Choi, Steve S.; Witek, Rafal P.; Alpini, Gianfranco; Venter, Juliet; VanDongen, Hendrika M.A.; Syn, Wing–Kin; Svegliati‐Baroni, Gianluca; Benedetti, Antonio; Schuppan, Detlef; Diehl, Anna Mae

doi:10.1172/jci35875

Cited by 232 publications

(373 citation statements)

References 89 publications

(132 reference statements)

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“…Upon activation by specific ligands, β-catenin is released from the membrane and promotes transcription of genes involved in mesenchymal phenotype induction [48]. Notch and Hedgehog, acting as morphogens, are also able to activate EMT by regulating the expression of Snail [49,50].…”

Section: The Epithelium To Mesenchymal Transitionmentioning

confidence: 99%

Nucleotides and nucleoside signaling in the regulation of the epithelium to mesenchymal transition (EMT)

Martinez-Ramirez

Dı́az-Muñoz

Butanda-Ochoa

et al. 2016

Purinergic Signalling

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The epithelium-mesenchymal transition (EMT) is an important process of cell plasticity, consisting in the loss of epithelial identity and the gain of mesenchymal characteristics through the coordinated activity of a highly regulated informational program. Although it was originally described in the embryonic development, an important body of information supports its role in pathology, mainly in cancerous and fibrotic processes. The purinergic system of inter-cellular communication, mainly based in ATP and adenosine acting throughout their specific receptors, has emerged as a potent regulator of the EMT in several pathological entities. In this context, cellular signaling associated to purines is opening the understanding of a new element in the complex regulatory network of this phenotypical differentiation process. In this review, we have summarized recent information about the role of ATP and adenosine in EMT, as a growing field with high therapeutic potential.Keywords P2 receptors . P1 receptors . Purinergic signaling . Cell migration . EMTThe purinergic system of intercellular communication General aspects The term purine (from: pure urine) was created more than 130 years ago by Emil Fischer after detailed analytical characterization of the uric acid molecule [1]. Purine molecular structure is the result of fusing pyrimidine and imidazole rings, and it exists as four N-H tautomeric forms [2]. Tautomerism of purine bases in DNA is one of the earliest reasons for mutations [3][4][5]. The interconversion of the different adenine or guanine tautomers produced mispairing with pyrimidines (which also show tautomeric forms) that may lead to changes in DNA sequence [6].Purine molecules appeared very early in the history of our planet, in the period known as Borganic evolution^, before the establishment of living systems. It has been postulated that purines could be formed by a eutectic (denoting a mixture of substances in fixed proportions that melts and freezes at a single temperature that is lower than the melting points of any of the separate constituents) concentration of HCN at extremely low temperature over a period of dozens of years [7]. Purine molecules, such as adenine and guanine, are components of the genetic material (DNA and RNA) of all living beings. Purine and pyrimidine tautomeric equilibria in nucleic acids was postulated to be significant in events such as DNA replication and repair as well as in the occurrence of point mutations [8].As nucleosides and nucleotides, purines play other highly strategic roles, acting as energy intermediates, allosteric regulators of key metabolic activities, redox molecules, and chemical messengers for signal transduction events. The two most important purines serving as extracellular ligands for paracrine and autocrine signaling are ATP and its dephosphorylated form, adenosine (ADO). ATP and ADO act as intracellular intermediate metabolites, and their presence in the

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Section: The Epithelium To Mesenchymal Transitionmentioning

confidence: 99%

Nucleotides and nucleoside signaling in the regulation of the epithelium to mesenchymal transition (EMT)

Martinez-Ramirez

Dı́az-Muñoz

Butanda-Ochoa

et al. 2016

Purinergic Signalling

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“…26 There is evidence that proliferating cholangiocytes have a role in the induction of fibrosis, either directly through epithelial-mesenchymal transition, 27 or indirectly through the activation of hepatic stellate cells. 28 In fact, targeting proliferating biliary epithelia might provide a novel antifibrotic therapy in the liver. 29 Several studies have shown that the induction of iNOS and NO synthesis are also implicated in the promotion of cell growth in cholangiocytes.…”

Section: Protein S-nitrosation During Cholestasismentioning

confidence: 99%

Inhibition of nitric oxide synthesis during induced cholestasis ameliorates hepatocellular injury by facilitating S-nitrosothiol homeostasis

López‐Sánchez

Corrales

Barcos

et al. 2010

Laboratory Investigation

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Cholestatic liver injury following extra-or intrahepatic bile duct obstruction causes nonparenchymal cell proliferation and matrix deposition leading to end-stage liver disease and cirrhosis. In cholestatic conditions, nitric oxide (NO) is mainly produced by a hepatocyte-inducible NO synthase (iNOS) as a result of enhanced inflow of endotoxins to the liver and also by accumulation of bile salts in hepatocytes and subsequent hepatocellular injury. This study was aimed to investigate the role of NO and S-nitrosothiol (SNO) homeostasis in the development of hepatocellular injury during cholestasis induced by bile duct ligation (BDL) in rats. Male Wistar rats (200-250 g) were divided into four groups (n ¼ 10 each), including sham-operated (SO), bile duct-ligated (BDL), tauroursodeoxycholic acid (TUDCA, 50 mg/kg) and S-methylisothiourea (SMT, 25 mg/kg) treated. After 7 days, BDL rats showed elevated serum levels of g-glutamiltranspeptidase, aspartate aminotransferase, alanine aminotransferase, LDH, and bilirubin, bile duct proliferation and fibrosis, compared with the SO group. TUDCA treatment did not significantly alter these parameters, but the iNOS inhibitor SMT ameliorated hepatocellular injury, as shown by lower levels of circulating hepatic enzymes and bilirubin, and a decreased grade of bile duct proliferation and fibrosis. Both TUDCA and SMT treatments reversed Mrp2 canalicular pump expression to control levels. However, only SMT treatment significantly lowered the increased levels of plasma NO and S-nitrosation (S-nitrosylation) of liver proteins in BDL rats. Moreover, BDL resulted in a reduction of the S-nitrosoglutathione reductase (GSNOR/Adh5) enzymatic activity and a downregulation of the GSNOR/Adh5 mRNA expression that was reverted by SMT, but not TUDCA, treatment. A total of 25 liver proteins, including S-adenosyl methionine synthetase, betainehomocysteine S-methyltransferase, Hsp90 and protein disulfide isomerase, were found to be S-nitrosated in BDL rats. In conclusion, the inhibition of NO production during induced cholestasis ameliorates hepatocellular injury. This effect is in part mediated by the improvement of cell proficiency in maintaining SNO homeostasis.

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“…The acquisition of these enhanced properties by reactive cholangiocytes is consistent with our observation that Foxl1 is only expressed in conditions associated with cholangiocyte injury. Diehl and colleagues have recently reported that the sonic hedgehog pathway is reactivated in response to bile duct ligation in rodents [7][8][9] and that hedgehog ligands secreted by hepatic stellate cells enhance cholangiocyte viability and motility. 7 Foxl1 is a downstream target of the sonic hedgehog signaling pathway in the gut 6 and it is reasonable to speculate that Foxl1 may represent an important hedgehog target responsible for the effects of sonic hedgehog on cholangiocyte function during cholestatic liver injury.…”

Section: Discussionmentioning

confidence: 99%

“…Although nothing is known about the function of Foxl1 in the liver, in the gut, Foxl1 is downstream of the hedgehog pathway and is a mediator of the wnt/bcatenin pathway, two signaling pathways that have been linked to cholangiocyte viability and proliferation, respectively. [6][7][8][9][10][11] Taken together, these findings led us to investigate whether Foxl1 is important for cholangiocyte viability and/or proliferation following bile duct injury. Foxl1 À/À mice do not exhibit any baseline liver abnormalities indicating that Foxl1 is dispensable for liver development.…”

mentioning

confidence: 98%

Foxl1 promotes liver repair following cholestatic injury in mice

Sackett

Gao

Shin

et al. 2009

Laboratory Investigation

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Cholangiocyte proliferation is one of the hallmarks of the response to cholestatic injury. We previously reported that the winged helix transcription factor Foxl1 is dramatically induced in cholangiocytes following bile duct ligation. In this study, we investigated the function of Foxl1 in the bile duct ligation model of cholestatic liver injury in Foxl1 À/À and control mice. We found that Foxl1 À/À livers exhibit an increase in parenchymal necrosis, significantly impaired cholangiocyte and hepatocyte proliferation, and failure to expand bile ductular mass. Wnt3a and Wnt7b expression was decreased in the livers of Foxl1 À/À mice along with reduced expression of the b-catenin target gene Cyclin D1 in Foxl1 À/À cholangiocytes. These results show that Foxl1 promotes liver repair after bile-duct-ligation-induced liver injury through activation of the canonical wnt/b-catenin pathway.

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Hedgehog signaling regulates epithelial-mesenchymal transition during biliary fibrosis in rodents and humans

Cited by 232 publications

References 89 publications

Nucleotides and nucleoside signaling in the regulation of the epithelium to mesenchymal transition (EMT)

Nucleotides and nucleoside signaling in the regulation of the epithelium to mesenchymal transition (EMT)

Inhibition of nitric oxide synthesis during induced cholestasis ameliorates hepatocellular injury by facilitating S-nitrosothiol homeostasis

Foxl1 promotes liver repair following cholestatic injury in mice

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