Transient receptor potential ankyrin 1 mediates chronic pancreatitis pain in mice.

Chronic pancreatitis (CP) is a devastating disease characterized by persistent and uncontrolled abdominal pain. Our lack of understanding is partially due to the lack of experimental models that mimic the human disease and also to the lack of validated behavioral measures of visceral pain. The ligand-gated cation channel transient receptor potential ankyrin 1 (TRPA1) mediates inflammation and pain in early experimental pancreatitis. It is unknown if TRPA1 causes fibrosis and sustained pancreatic pain. We induced CP by injecting the chemical agent trinitrobenzene sulfonic acid (TNBS), which causes severe acute pancreatitis, into the pancreatic duct of C57BL/6 trpa1(+/+) and trpa1(-/-) mice. Chronic inflammatory changes and pain behaviors were assessed after 2-3 wk. TNBS injection caused marked pancreatic fibrosis with increased collagen-staining intensity, atrophy, fatty replacement, monocyte infiltration, and pancreatic stellate cell activation, and these changes were reflected by increased histological damage scores. TNBS-injected animals showed mechanical hypersensitivity during von Frey filament probing of the abdomen, decreased daily voluntary wheel-running activity, and increased immobility scores during open-field testing. Pancreatic TNBS also reduced the threshold to hindpaw withdrawal to von Frey filament probing, suggesting central sensitization. Inflammatory changes and pain indexes were significantly reduced in trpa1(-/-) mice. In conclusion, we have characterized in mice a model of CP that resembles the human condition, with marked histological changes and behavioral measures of pain. We have demonstrated, using novel and objective pain measurements, that TRPA1 mediates inflammation and visceral hypersensitivity in CP and could be a therapeutic target for the treatment of sustained inflammatory abdominal pain.

Protein phosphatase 2A mediates resensitization of the neurokinin 1 receptor.

Activated G protein-coupled receptors (GPCRs) are phosphorylated and interact with ß-arrestins, which mediate desensitization and endocytosis. Endothelin-converting enzyme-1 (ECE-1) degrades neuropeptides in endosomes and can promote recycling. Although endocytosis, dephosphorylation, and recycling are accepted mechanisms of receptor resensitization, a large proportion of desensitized receptors can remain at the cell surface. We investigated whether reactivation of noninternalized, desensitized (phosphorylated) receptors mediates resensitization of the substance P (SP) neurokinin 1 receptor (NK(1)R). Herein, we report a novel mechanism of resensitization by which protein phosphatase 2A (PP2A) is recruited to dephosphorylate noninternalized NK(1)R. A desensitizing concentration of SP reduced cell-surface SP binding sites by only 25%, and SP-induced Ca(2+) signals were fully resensitized before cell-surface binding sites started to recover, suggesting resensitization of cell-surface-retained NK(1)R. SP induced association of ß-arrestin1 and PP2A with noninternalized NK(1)R. ß-Arrestin1 small interfering RNA knockdown prevented SP-induced association of cell-surface NK(1)R with PP2A, indicating that ß-arrestin1 mediates this interaction. ECE-1 inhibition, by trapping ß-arrestin1 in endosomes, also impeded SP-induced association of cell-surface NK(1)R with PP2A. Resensitization of NK(1)R signaling required both PP2A and ECE-1 activity. Thus, after stimulation with SP, PP2A interacts with noninternalized NK(1)R and mediates resensitization. PP2A interaction with NK(1)R requires ß-arrestin1. ECE-1 promotes this process by releasing ß-arrestin1 from NK(1)R in endosomes. These findings represent a novel mechanism of PP2A- and ECE-1-dependent resensitization of GPCRs.

The tissue factor pathway mediates both activation of coagulation and coagulopathy after injury.

BACKGROUND: The initiation of coagulation in trauma is thought to originate from exposed tissue factor (TF); recent data have led to the alternative hypothesis that damage-associated molecular patterns may contribute to postinjury coagulation. In acute traumatic coagulopathy, aberrant coagulation is mediated via the activated protein C (aPC) pathway; the upstream regulators of this process and its relation to TF remain uncharacterized. To examine the role of the TF pathway in mediating acute traumatic coagulopathy, we used specific antibody blockades in an established murine model of traumatic hemorrhagic shock, hypothesizing that both coagulation activation after injury and aPC-mediated coagulopathy are driven by TF via thrombin. METHODS: Mice underwent an established model of trauma and hemorrhage and were subjected to either sham (vascular cannulation) or trauma-hemorrhage (cannulation, laparotomy, shock to mean arterial pressure of 35 mm Hg); they were monitored for 60 minutes before sacrifice. Mice in each group were pretreated with either targeted anti-TF antibody to block the TF pathway or hirudin for specific blockade of thrombin. Plasma was assayed for thrombin-antithrombin (TAT) and aPC by enzyme-linked immunosorbent assay. RESULTS: Compared with controls, trauma-hemorrhage mice treated with anti-TF antibody had significantly reduced levels of TAT (2.3 ng/mL vs. 5.7 ng/mL, p = 0.016) and corresponding decreases in aPC (16.3 ng/mL vs. 31.6 ng/mL, p = 0.034), with reductions to levels seen in sham mice. Direct inhibition of thrombin yielded similar results, with reduction in aPC to levels below those seen in sham mice. CONCLUSION: In this study, blockade of the TF pathway led to the attenuation of both thrombin production and aPC activation observed in traumatic shock. Specific thrombin inhibition achieved similar results, indicating that aPC-related coagulopathy is mediated via thrombin activated by the TF pathway. The near-complete blockade of TAT and aPC observed in this model argues for a dominant role of the TF-thrombin pathway in both coagulation activation after injury and traumatic coagulopathy.