Elevated intracellular trypsin exacerbates acute pancreatitis and chronic pancreatitis in mice.

Intra-acinar trypsinogen activation occurs in the earliest stages of pancreatitis and is believed to play important roles in pancreatitis pathogenesis. However, the exact role of intra-acinar trypsin activity in pancreatitis remains elusive. Here, we aimed to examine the specific effects of intra-acinar trypsin activity on the development of pancreatitis using a transgenic mouse model. This transgenic mouse model allowed for the conditional expression of a mutant trypsinogen that can be activated specifically inside pancreatic acinar cells. We found that expression of this active mutated trypsin had no significant effect on triggering spontaneous pancreatitis. Instead, several protective compensatory mechanisms, including SPINK1 and heat shock proteins, were upregulated. Notably, these transgenic mice developed much more severe acute pancreatitis, compared with control mice, when challenged with caerulein. Elevated tissue edema, serum amylase, inflammatory cell infiltration and acinar cell apoptosis were dramatically associated with increased trypsin activity. Furthermore, chronic pathological changes were observed in the pancreas of all transgenic mice, including inflammatory cell infiltration, parenchymal atrophy and cell loss, fibrosis, and fatty replacement. These changes were not observed in control mice treated with caerulein. The alterations in pancreata from transgenic mice mimicked the histological changes common to human chronic pancreatitis. Taken together, we provided in vivo evidence that increased intra-acinar activation of trypsinogen plays an important role in the initiation and progression of both acute and chronic pancreatitis. NEW & NOTEWORTHY Trypsinogen is activated early in pancreatitis. However, the roles of trypsin in the development of pancreatitis have not been fully addressed. Using a genetic approach, we showed trypsin activity is critical for the severity of both acute and chronic pancreatitis.

[1]  G. Klöppel,et al.  Immunocytochemical and morphometric analysis of acinar zymogen granules in human acute pancreatitis , 2004, Virchows Archiv A.

[2]  R. Flavell,et al.  TLR9 and the NLRP3 inflammasome link acinar cell death with inflammation in acute pancreatitis. , 2011, Gastroenterology.

[3]  Huamin Wang,et al.  Activation of nuclear factor-κB in acinar cells increases the severity of pancreatitis in mice. , 2013, Gastroenterology.

[4]  K. Tracey,et al.  Intracellular Hmgb1 inhibits inflammatory nucleosome release and limits acute pancreatitis in mice. , 2014, Gastroenterology.

[5]  M. Peyton,et al.  Transgenic expression of pancreatic secretory trypsin inhibitor-I ameliorates secretagogue-induced pancreatitis in mice. , 2005, Gastroenterology.

[6]  M. Sahin-Tóth,et al.  A preclinical model of chronic pancreatitis driven by trypsinogen autoactivation , 2018, Nature Communications.

[7]  T. Wartmann,et al.  Autoactivation of Mouse Trypsinogens Is Regulated by Chymotrypsin C via Cleavage of the Autolysis Loop* , 2013, The Journal of Biological Chemistry.

[8]  A. Kaiser,et al.  Relationship between severity, necrosis, and apoptosis in five models of experimental acute pancreatitis. , 1995, The American journal of physiology.

[9]  M. Sahin-Tóth,et al.  Mutation That Promotes Activation of Trypsinogen Increases Severity of Secretagogue-Induced Pancreatitis in Mice. , 2019, Gastroenterology.

[10]  Elaina K. Jones,et al.  Acute acinar pancreatitis blocks vesicle-associated membrane protein 8 (VAMP8)-dependent secretion, resulting in intracellular trypsin accumulation , 2017, The Journal of Biological Chemistry.

[11]  H Lippert,et al.  Role of cathepsin B in intracellular trypsinogen activation and the onset of acute pancreatitis. , 2000, The Journal of clinical investigation.

[12]  Jiali Yang,et al.  The Use of Values WNR and GNR to Distinguish between and Diagnose Different Types of Pancreatitis , 2020, Molecular therapy. Methods & clinical development.

[13]  M. Gorry,et al.  Hereditary pancreatitis is caused by a mutation in the cationic trypsinogen gene , 1996, Nature Genetics.

[14]  D. Whitcomb,et al.  Genetics of acute and chronic pancreatitis , 2013, Current opinion in gastroenterology.

[15]  Weihui Zhang,et al.  miR-92a-3p regulates trypsinogen activation via Egr1 in AR42J cells , 2019, Molecular medicine reports.

[16]  Huamin Wang,et al.  Ras activity levels control the development of pancreatic diseases. , 2009, Gastroenterology.

[17]  J. Meldolesi,et al.  Pancreatic duct obstruction in rabbits causes digestive zymogen and lysosomal enzyme colocalization. , 1989, The Journal of clinical investigation.

[18]  A. Saluja,et al.  Development of a new mouse model of acute pancreatitis induced by administration of L-arginine. , 2007, American journal of physiology. Gastrointestinal and liver physiology.

[19]  M. Sahin-Tóth,et al.  Human cationic trypsinogen (PRSS1) variants and chronic pancreatitis. , 2014, American journal of physiology. Gastrointestinal and liver physiology.

[20]  M. Sahin-Tóth Biochemical models of hereditary pancreatitis. , 2006, Endocrinology and metabolism clinics of North America.

[21]  M. Lotze,et al.  Cell Death and DAMPs in Acute Pancreatitis , 2014, Molecular medicine.

[22]  S. Vege,et al.  Drug Therapy for Acute Pancreatitis , 2015, Current Treatment Options in Gastroenterology.

[23]  M. Sahin-Tóth,et al.  Natural single-nucleotide deletion in chymotrypsinogen C gene increases severity of secretagogue-induced pancreatitis in C57BL/6 mice. , 2019, JCI insight.

[24]  B. Ji,et al.  Intracellular Trypsin Induces Pancreatic Acinar Cell Death but Not NF-κB Activation* , 2009, The Journal of Biological Chemistry.

[25]  K. Lee,et al.  Spontaneous Activation of Pancreas Trypsinogen in Heat Shock Protein 70.1 Knock-out Mice , 2005, Pancreas.

[26]  I. Velasco,et al.  Acute Pancreatitis: Hypertonic Saline Increases Heat Shock Proteins 70 and 90 and Reduces Neutrophil Infiltration in Lung Injury , 2009, Pancreas.

[27]  B. Ji,et al.  The role of protein synthesis and digestive enzymes in acinar cell injury , 2013, Nature Reviews Gastroenterology &Hepatology.

[28]  J. Drenth,et al.  Mutations in serine protease inhibitor Kazal type 1 are strongly associated with chronic pancreatitis , 2002 .

[29]  L. Cantley,et al.  Phosphatidylinositol 3-kinase-dependent activation of trypsinogen modulates the severity of acute pancreatitis. , 2001, The Journal of clinical investigation.

[30]  B. Ji,et al.  Robust acinar cell transgene expression of CreErT via BAC recombineering , 2008, Genesis.

[31]  M. Ohmuraya,et al.  Transgenic expression of pancreatic secretory trypsin inhibitor-1 rescues SPINK3-deficient mice and restores a normal pancreatic phenotype. , 2010, American Journal of Physiology - Gastrointestinal and Liver Physiology.

[32]  A. Saluja,et al.  Cerulein-induced chronic pancreatitis does not require intra-acinar activation of trypsinogen in mice. , 2013, Gastroenterology.

[33]  H. Witt,et al.  Chronic pancreatitis: challenges and advances in pathogenesis, genetics, diagnosis, and therapy. , 2007, Gastroenterology.

[34]  M. Tóth,et al.  Mutations of human cationic trypsinogen (PRSS1) and chronic pancreatitis , 2006, Human mutation.

[35]  R A Knight,et al.  Molecular definitions of cell death subroutines: recommendations of the Nomenclature Committee on Cell Death 2012 , 2011, Cell Death and Differentiation.

[36]  A. Habtezion,et al.  Inflammation in acute and chronic pancreatitis , 2015, Current opinion in gastroenterology.

[37]  P. Garg,et al.  Intra-acinar trypsinogen activation mediates early stages of pancreatic injury but not inflammation in mice with acute pancreatitis. , 2011, Gastroenterology.

[38]  G. Klöppel,et al.  Human acute pancreatitis: Its pathogenesis in the light of immunocytochemical and ultrastructural findings in acinar cells , 2004, Virchows Archiv A.

[39]  K. Søreide,et al.  Is There a Trojan Horse to Aggressive Pancreatic Cancer Biology? A Review of the Trypsin-PAR2 Axis to Proliferation, Early Invasion, and Metastasis , 2020, Journal of pancreatic cancer.

[40]  B. Han,et al.  NF-κB activation in pancreas induces pancreatic and systemic inflammatory response , 2002 .

[41]  E. Thrower,et al.  Molecular and cellular mechanisms of pancreatic injury , 2010, Current opinion in gastroenterology.

[42]  Vijay P. Singh,et al.  Bile Acids Induce Pancreatic Acinar Cell Injury and Pancreatitis by Activating Calcineurin* , 2012, The Journal of Biological Chemistry.

[43]  B. Ji,et al.  Species Differences between Rat and Mouse CCKAReceptors Determine the Divergent Acinar Cell Response to the Cholecystokinin Analog JMV-180* , 2000, The Journal of Biological Chemistry.

[44]  B. Ji,et al.  Intracellular activation of trypsinogen in transgenic mice induces acute but not chronic pancreatitis , 2011, Gut.

[45]  M. Bhatia Apoptosis versus necrosis in acute pancreatitis. , 2004, American journal of physiology. Gastrointestinal and liver physiology.

[46]  Fan Wang,et al.  Animal models of gastrointestinal and liver diseases. Animal models of acute and chronic pancreatitis. , 2016, American journal of physiology. Gastrointestinal and liver physiology.