β-catenin blocks Kras-dependent reprogramming of acini into pancreatic cancer precursor lesions in mice
John P. Morris IV, … , Sam C. Wang, Matthias Hebrok
John P. Morris IV, … , Sam C. Wang, Matthias Hebrok
Published January 11, 2010
Citation Information: J Clin Invest. 2010;120(2):508-520. https://doi.org/10.1172/JCI40045.
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Research Article Oncology

β-catenin blocks Kras-dependent reprogramming of acini into pancreatic cancer precursor lesions in mice

Abstract

Cellular plasticity in adult organs is involved in both regeneration and carcinogenesis. WT mouse acinar cells rapidly regenerate following injury that mimics acute pancreatitis, a process characterized by transient reactivation of pathways involved in embryonic pancreatic development. In contrast, such injury promotes the development of pancreatic ductal adenocarcinoma (PDA) precursor lesions in mice expressing a constitutively active form of the GTPase, Kras, in the exocrine pancreas. The molecular environment that mediates acinar regeneration versus the development of PDA precursor lesions is poorly understood. Here, we used genetically engineered mice to demonstrate that mutant Kras promotes acinar-to-ductal metaplasia (ADM) and pancreatic cancer precursor lesion formation by blocking acinar regeneration following acute pancreatitis. Our results indicate that β-catenin is required for efficient acinar regeneration. In addition, canonical β-catenin signaling, a pathway known to regulate embryonic acinar development, is activated following acute pancreatitis. This regeneration-associated activation of β-catenin signaling was not observed during the initiation of Kras-induced acinar-to-ductal reprogramming. Furthermore, stabilized β-catenin signaling antagonized the ability of Kras to reprogram acini into PDA preneoplastic precursors. Therefore, these results suggest that β-catenin signaling is a critical determinant of acinar plasticity and that it is inhibited during Kras-induced fate decisions that specify PDA precursors, highlighting the importance of temporal regulation of embryonic signaling pathways in the development of neoplastic cell fates.

Authors

John P. Morris IV, David A. Cano, Shigeki Sekine, Sam C. Wang, Matthias Hebrok

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Figure 1

Mutant Kras blocks acinar regeneration and promotes ADM/PanIN formation.

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Mutant Kras blocks acinar regeneration and promotes ADM/PanIN formation....
(AH) H&E staining of regeneration time course in Pdx1-CreEarly (AD) and Pdx1-CreEarly;LSL-KrasG12D (EH) mice. (E and M) Asterisks indicate spontaneous PanIN lesions in PBS-treated Pdx1-CreEarly;LSL-KrasG12D animals. Insets in B and F show morphologically similar duct-like cells 2 days after induction of acute pancreatitis. (IP) Amylase (red)/CK19 (green) immunofluorescent labeling. Note CK19 expression in spontaneous PanIN lesions in Pdx1-CreEarly;LSL-KrasG12D mice (asterisk, M). (J and N) Amylase is downregulated and CK19 is weakly expressed in transient duct-like cells in Pdx1-CreEarly mice (inset, J) while strongly expressed in duct-like cells in Pdx1-CreEarly;LSL-KrasG12D mice (inset, N). Rare amylase-positive cells are found in metaplastic epithelium (arrowheads, O). (QT) Amylase (red), CK19 (blue), YFP (green) immunofluorescent labeling in Elastase-CreERT;LSL-KrasG12D;R26R-EYFP mice. Without caerulein treatment, YFP expression is restricted to amylase-positive cells and restricted from CK19-positive cells. Arrowheads indicate autofluorescent erythrocytes (Q). Double-CK19/YFP–positive cells (cyan, indicating blue/green overlap) persist following caerulein treatment (RT). Original magnification, ×400 (AP; insets). Scale bars: 50 μm (QT).