Project description:We sequenced AR42J cell exposed to CCK or insulin in different concentrations. This enable us to uncover the possible effect of the different hormones on acinar cells in pathlogy.

Project description:Investigation of differential microRNAs in the exosomes of caerulein-induced AR42J pancreatic acinar cells

Project description:Acute pancreatitis (AP) is a common digestive disorder with high morbidity and mortality. At present, the pathogenic mechanisms of AP remain unclear. Pancreatic acinar intracellular trypsinogen activation is considered to be an important cause of AP and is an important event in the early stages of AP. The activation of trypsinogen is a key factor for the pancreas to maintain normal function and that the abnormal activation of trypsinogen in pancreatic acinar cells is an initiating factor for the occurrence of AP. In the past decade, microRNA-related research results suggest that small non-coding RNAs play an important role in AP. Recently, endogenous transfer RNA-derived small RNA (tsRNA), a newly identified non-coding small RNA, is reported to be associated with multiple diseases. tsRNAs can be broadly classified into two main groups: tiRNAs (tRNA halves) and tRFs (tRNA-derived fragments). tiRNAs are produced by specific cleavage in the anticodon loop under various stress conditions (29-50 nucleotides). tRFs are separated to 4 subtypes by their sites of origin in pre-tRNA or mature tRNA, and generally shorter than tiRNAs (16-28 nucleotides). Similar to the function of microRNA, tsRNA can inhibit their functions by binding to target genes. However, the role of tsRNA in regulating AP pathogenesis has not been investigated. In this experiment, sodium taurocholate was used to treat the rat pancreatic acinar cell (AR42J) to establish the AP-related intracellular activation of trypsinogen model. Then we used RNA sequencing to identify the differentially expressed non-coding small RNAs including microRNA and tsRNA in the cell model.

Project description:Pancreatic acinar cells can dedifferentiate upon tissue injury and acquire ductal characteristics. This acquisition of duct cell features is critical in tumor development. Nevertheless, duct cells themselves are less prone for development of PDAC (pancreatic ductal adenocarcinoma) than dedifferentiated acini. We aimed to clarify which genes are unique for dedifferentiated acini. Mixed exocrine preparations of acinar and duct cells were obtained from human pancreatic donor organs and cultured to induce dedifferentiation. We lineage-labeled and FACS-purified these human dedifferentiated acinar cells and compared them to duct cells from the same donor (n=5).

Project description:Non-coding small RNA expression analysis of rat pancreatic acinar cells(AR42J) treated with sodium taurocholate

Project description:Phosphoproteomic analysis to elucidate whether high-fat diet induced hyperinsulinemia contributes to pancreatic cancer directly through insulin receptor (INSR) signaling in KrasG12D-expressing pancreatic acinar cells.

Project description:This experiment used RNA-Seq technology to explore gene expression in mouse FACS-purified pancreatic P60 Acinar cells, P60 Beta-cells, 1 day 3TF (MafA/Neurog3/Pdx1)-induced Acinar cells and 7 days 3TF-induced Acinar cells.ďż˝

Project description:Epigenetic profile of tissues is reprogrammed under diseased conditions. H3K4Me3 and H3K27Me3 represent active and repressive epigenetic marks, respectively. ChIP-seq is an effective tool to study global protein-DNA interactions. To study global epigenetic differences, we used H3K4Me3 antibody to evaluate its enrichment in pancreatic acinar cells of WT and Mist1-/- mice followed by next generation sequencing. We found specific hotspots that showed differential enrichment for H3K4Me3 both in WT and Mist1-/- mice. The data show that pancreatic acinar cells are epigenetically reprogrammed under stressed cellular conditions. Global H3K4Me3 profiling of WT and Mist1-/- pancreatic acinar cells using ChIP-seq.

Project description:Acinar ductal metaplasia (ADM), is believed to be one of the earliest precursor lesions towards the development of pancreatic ductal adenocarcinoma, and maintaining the pancreatic acinar cell phenotype suppresses tumor formation. We report that pStat3 and HDAC inhibition can attenuate ADM in vitro and TSA treatment reverses the dedifferentiated phenotype to one that is more acinar. Our findings suggest that pharmacological inhibition or reversal of pancreatic ADM represents a potential therapeutic strategy for blocking ductal reprogramming of acinar cells.

Project description:The apical-basal polarity of pancreatic acinar cells is essential for maintaining tissue architecture. However, the mechanisms by which polarity proteins regulate acinar pancreas tissue homeostasis are poorly understood. Here, we evaluate the role of Par3 in acinar pancreas injury and homeostasis. While Par3 loss in the mouse pancreas disrupts tight junctions, Par3 loss is dispensable for pancreatogenesis. However, with aging, Par3 loss results in low-grade inflammation, acinar degeneration, and pancreatic lipomatosis. Par3 loss also exacerbates pancreatitis-induced acinar cell loss, resulting in pronounced pancreatic lipomatosis and failure to regenerate. Moreover, Par3 loss in mice harboring mutant Kras causes extensive pancreatic intraepithelial neoplastic (PanIN) lesions and large pancreatic cysts. We also show that Par3 loss restricts injury-induced primary ciliogenesis. Significantly, targeting BET proteins enhances primary ciliogenesis during pancreatitis-induced injury and, in mice with Par3 loss, limits pancreatitis-induced acinar loss and facilitates acinar cell regeneration. Combined, this study demonstrates how Par3 restrains pancreatitis- and Kras-induced changes in the pancreas and identifies a potential role for BET inhibitors to attenuate pancreas injury and facilitate pancreas tissue regeneration.