Project description:Extrahepatic bile ducts were isolated from mouse pups at days 0-3 and primary cholangiocytes were isolated. Cholangiocytes were treated with DMSO, bilatresone (TOX4), betavulgarin (TOX2), and isoflavanone (TOX3), as per Lorent et al, Science Translationa Medicine 2015;286:286ra67 (Fig. 1), all in DMSO. Treatment concentrations were 2.0 micrograms/ml, for 6 hours.

Project description:Effects of C3 toxin on RNA profiles in neonatal rat ventricular cardiac myocytes exposed to endothelin-1 (1 h)

Project description:Global Gene expression changes in cholangiocytes with TGF beta treatment

Project description:Growth factor, TGF beta can have profound effect on global gene expression changes. Since TGF beta signalling is not well studied in liver epithelia , we decided to do Next gen RNA-seq analysis to look at TGF beta signaling in cholangiocytes

Project description:Alcoholic hepatitis (AH) is a life-threatening disease with limited treatment options. The presence of cholestasis worsens prognosis but the responsible mechanism is unknown. AH results in infiltration of polymorphonuclear neutrophils (PMNs) in the liver, and cholestasis often reflects bile duct pathology, so we investigated whether and how PMNs interact with cholangiocytes in AH.

Project description:The present study used microarray approach to identify the genomewide response to cholera toxin in the presence of nitrate. Considering that fact that the possibility of the existence of multiple Gα genes/proteins in plants has not been conclusively ruled out, analysis of the genomewide impact of RGA1 mutation in rice and GPA1 mutation in Arabidopsis reveal only those genes that are under their direct control. On the other hand, assuming that all those different Gα subunits in any given plant are regulated by cholera toxin, analysis of the genomwide response to cholera toxin could capture the entire G-protein responsive transcriptome, beyond what can be revealed by the mutant approach. This could reveal even those genes that respond to other, as yet unidentified Gα subunits, as well as reveal some genes that are non-specifically regulated by cholera toxin, independent of any G-proteins.

Project description:cholangiocytes treated with TGFbeta

Project description:Transcriptional profiling of log and stationary phases of S. Typhimurium, comparing untreated controls with T2 toxin-treated samples. Each array used labelled cDNA against a common genomic DNA reference. Trplicate arrays were carried out for each of the 4 conditions: untreated log phase, untreated stationary phase, T2 toxin treated log phase and T2 toxin treated stationary phase.

Project description:Despite the impact of bile duct disorders, treatment options remain very limited. Poor access to biliary tissue and restrictions in long-term culture or significant expansion of primary cholangiocytes have posed major challenges for research in the field. These limitations have so far precluded large scale experiments such as transcriptomic and genome-wide analyses which are urgently needed to better understand biliary physiology and pathophysiology. To address this issue, we have developed a novel system for the isolation and propagation of primary cholangiocytes from the extrahepatic bile ducts. The resulting Extrahepatic Cholangiocyte Organoids (ECOs) maintain their genetic stability, transcriptomic profile and function over long term culture and are compatible with regenerative medicine applications such as biliary reconstruction. We established a novel protocol for the isolation and propagation of primary cholangiocytes from the extrahepatic biliary tree in the form of extrahepatic cholangiocyte organoids (ECOs). The aim of this experiment was to provide in depth characterisation of the transcriptome of ECOs during long term culture. We compare the transcriptome of ECOs cultured for 1 passage (P1), 10 passages (P10) and 20 passages (P20) with freshly isolated primary cholangiocytes from the common bile duct. Embryonic Stem Cells (ES) cells are used as a negative control=

Project description:Purpose: The aim of this study is to propose a computational model which can help in unravelling the mechanisms of initial bile duct lumen formation. Guided by the quantification of morphological features and expression of genes in developing bile ducts (cholangiocytes) from embryonic mouse liver, hypotheses for the mechanisms of biliary lumen formation were generated and tested with the model. Here, the RNA-sequencing data were collected from purified embryonic cholangiocytes at two developmental stages (E16 and E18).