Abstract
The isolation of ribonucleic acid (RNA) suitable for gene expression studies is challenging in the pancreas, due to its high ribonuclease activity. This is even more complicated during pancreatitis, a condition associated with inflammation and fibrosis. Our aim was to implement a time-effective and reproducible protocol to isolate high quality RNA from specific pancreatic cell subtypes, in normal and inflammatory conditions. We used two genetically engineered mouse models (GEMM), Ela-CreER/YFP and Sox9-CreER/YFP, to isolate acinar and ductal cells, respectively. To induce pancreatitis, mice received a caerulein treatment (125 μg/kg) for 8 and 72 h. We alternatively used EGTA and calcium buffers that contain collagenase P (0.6 mg/mL) to rapidly digest the pancreas into individual cells. Most of the cells from normal and injured pancreas were single-dissociated, exhibited a round morphology and did not incorporate trypan blue dye. Cell suspensions from Ela- and Sox9-CreER/YFP pancreas were then sorted by flow cytometry to isolate the YFP-positive acinar and ductal cells, respectively. Sorted cells kept a round shape and emitted fluorescence detected by the 38 HE green fluorescence filter. RNA was isolated by column-based purification approach. The RNA integrity number (RIN) was high in sorted acinar cell fractions treated with or without caerulein (8.6 ± 0.17 and 8.4 ± 0.09, respectively), compared to the whole pancreas fraction (4.8 ± 1.1). Given the low number of sorted ductal cells, the RIN value was slightly lower compared to acini (7.4 ± 0.4). Quantitative-PCR experiments indicated that sorted acinar and ductal cells express the specific acinar and ductal markers, respectively. Additionally, RNA preparations from caerulein-treated acinar cells were free from significant contamination with immune cell RNA. We thus validated the DIE (Digestion, Isolation, and Extraction)-RNA tool as a reproducible and efficient protocol to isolate pure acinar and ductal cells in vivo and to extract high quality RNA from these cells.
Highlights
Acute pancreatitis is among the most prevalent diseases that affect the pancreas and is a main driver for pancreatic cancer development (Yadav and Lowenfels, 2013)
Significant advances could be made by profiling gene expression and applying deep molecular biology approaches on purely isolated acinar cells from injured pancreas
We fully describe a protocol that allows a rapid dissociation of adult pancreas, isolation of acinar or ductal cells and extraction of high quality ribonucleic acid (RNA) suitable for deep and sensitive molecular biology approaches
Summary
Acute pancreatitis is among the most prevalent diseases that affect the pancreas and is a main driver for pancreatic cancer development (Yadav and Lowenfels, 2013). Acinar cells, which represent 80% of the pancreas, are mainly affected by pancreatitis (Reichert et al, 2016). In the presence of inflammation, acinar cells undergo acinar-to-ductal metaplasia, a pre-requisite for the development of pancreatic neoplasia and, possibly, pancreatic cancer in a later stage (Strobel et al, 2007; Fendrich et al, 2008; Prévot et al, 2012). The pathophysiology of metaplasia initiation is still incompletely understood. In this context, preclinical models of pancreatitis are of particular interest to get more insights into the underlying molecular mechanisms. Significant advances could be made by profiling gene expression and applying deep molecular biology approaches on purely isolated acinar cells from injured pancreas
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