Small molecule inhibition of tumor necrosis factor gene processing during acute pancreatitis prevents cytokine cascade progression and attenuates pancreatitis severity.

The morbidity and mortality associated with acute pancreatitis are primarily a result of pancreatic parenchymal necrosis and the development of marked pulmonary dysfunction. Recent evidence suggests that both of these conditions are propagated by interleukin (IL)-1 beta and tumor necrosis factor (TNF)-alpha, which are produced in large quantities within these organs. Because the generation of these cytokines occurs in a predictable manner early in the development of acute pancreatitis, we aimed to determine whether cytokine gene processing could be inhibited in vivo and what effects this would have on pancreatitis severity. Mild [caerulein, 50 micrograms/kg/hour intraperitoneally (IP) x 4; n = 40] or severe (choline-deficient diet; n = 40) necrotizing pancreatitis was induced in NIH swiss mice. Animals were randomly given a novel small molecule (CNI-1493; 10 mg/kg IP) known to inhibit macrophage production of TNF and IL-1 in vitro by inhibiting translation of TNF mRNA into protein. Control animals received IP vehicle. All animals with acute pancreatitis showed dramatic up-regulation of the IL-1 beta and TNF-alpha genes. Those animals receiving CNI-1493 demonstrated attenuated production of both species of mRNA in pancreatic as well as pulmonary tissue (P < 0.01). Markers of pancreatitis severity such as serum amylase and lipase, as well as pancreatic necrosis, were decreased in animals treated with CNI-1493 (all P < 0.05). Posttranscriptional blockade of TNF production precludes induction of the proinflammatory cytokine cascade that normally occurs during acute pancreatitis. This lack of cytokine gene processing in the pancreas and lungs results in dramatic reductions in tissue damage and pancreatitis severity, which is not model dependent. This is the first time that a small molecule has been shown to influence this disease.