Driver Mutations of Pancreatic Cancer Affect Ca2+ Signaling and ATP Production.

Glandular pancreatic epithelia of the acinar or ductal phenotype may seem terminally differentiated, but they are characterized by remarkable cell plasticity. Stress-induced trans-differentiation of these cells has been implicated in the mechanisms of carcinogenesis. Current consensus links pancreatic ductal adenocarcinoma with onco-transformation of ductal epithelia, but under the presence of driver mutations in Kras and Trp53, also with trans-differentiation of pancreatic acini. However, we do not know when, in the course of cancer progression, physiological functions are lost by mutant acinar cells, nor can we assess their capacity for the production of pancreatic juice components. Here, we investigated whether two mutations-KrasG12D and Trp53R172H-present simultaneously in acinar cells of KPC mice (model of oncogenesis) influence cytosolic Ca2+ signals. Since Ca2+ signals control the cellular handling of digestive hydrolases, any changes that affect intracellular signaling events and cell bioenergetics might have an impact on the physiology of the pancreas. Our results showed that physiological doses of acetylcholine evoked less regular Ca2+ oscillations in KPC acinar cells compared to the control, whereas responses to supramaximal concentrations were markedly reduced. Menadione elicited Ca2+ signals of different frequencies in KPC cells compared to control cells. Finally, Ca2+ extrusion rates were significantly inhibited in KPC cells, likely due to the lower basal respiration and ATP production. Cumulatively, these findings suggest that driver mutations affect the signaling capacity of pancreatic acinar cells even before the changes in the epithelial cell morphology become apparent.

When healing turns into killing - the pathophysiology of pancreatic and hepatic fibrosis.

Disorders such as pancreatic or hepatic fibrosis are a cruel reminder that disruption of the delicate physiological balance could result in severe pathological consequences. Fibrosis is usually associated with chronic diseases and manifests itself as excessive deposition of the extracellular matrix, which gradually leads to the replacement of the cellular components by fibrotic lesions, significantly compromising normal tissue functions. The main cellular mediators of fibrosis are different populations of tissue fibroblasts, predominantly hepatic and pancreatic stellate cells in the liver and pancreas, respectively. These cells undergo a phenotypic switch in response to (bio)chemical or physical stimuli and acquire a myofibroblast-like phenotype characterised by increased contractile and adhesive properties, elevated expression of certain cytoskeletal and membrane proteins, and prominent production of extracellular matrix components. In the past few decades, a substantial scientific effort has been undertaken to investigate the pathogenesis of fibrosis. Here, cellular mechanisms of hepatic and pancreatic fibrosis, their aetiological factors, associated diseases and prospective therapies are discussed. New therapies against fibrosis are likely to be focused on regulation of hepatic/pancreatic stellate cell physiology as well as normalisation of the organ mechanostasis.

Functional iron deficiency in toxic milk mutant mice (tx-J) despite high hepatic ferroportin: a critical role of decreased GPI-ceruloplasmin expression in liver macrophages.

Jackson toxic milk mutant mice (tx-J) carrying a missense mutation in the Atp7b gene are animal models of the Wilson disease. In both the Wilson patients and the tx-J mice, mutations in the ATP7B/Atp7b gene lead to disturbances in copper metabolism. The dysfunction of ATP7B/Atp7b leads to a reduction in the incorporation of copper into apoceruloplasmin; this decreases the ferroxidase activity of ceruloplasmin necessary for the efflux of iron from cells and reduces the release of copper from hepatocytes to the bile; this results in a massive hepatic copper accumulation. A decrease in the ferroxidase activity of ceruloplasmin in the tx-J mice emphasises the practicality of this animal model for the exploration of disturbances in iron balance triggered by dysregulation of copper metabolism. We found that 6-month-old tx-J mutants developed mild anaemia caused by functional iron deficiency. The tx-J mutants showed decreased plasma iron levels with concomitant iron accumulation in hepatocytes and liver macrophages. Hepatic iron retention was accompanied by decreased expression of the membrane form of ceruloplasmin in both liver cell types. Interestingly, in the liver of mutants, we found high levels of ferroportin (an iron exporter) on the surface of liver macrophages despite increased hepatic expression of hepcidin, a peptide inducing internalization and degradation of ferroportin. We conclude that even when the ferroportin expression is high, ceruloplasmin remains a limiting factor in the release of iron to the extracellular environment.