Cystic fibrosis: model of pathogenesis based on the apical membrane potential

• Main Authors: Beatrica Kurbel, Saša Rapan, Sven Kurbel
• Format: Article
• Language: English
• Published: Medical Association of Zenica-Doboj Canton 2015-02-01
• Series: Medicinski Glasnik
• Subjects: membrane potential; cystic fibrosis; pNBC1; AE1
• Online Access: http://www.ljkzedo.ba/sites/default/files/Glasnik/12-01-feb2015/01%20Kurbel.pdf

A simple model of cystic fibrosis (CF) is proposed, based on the apical membrane (ApM) potential. The ApM of epithelial cells is highly permeable to sodium and activation of CFTRs makes it permeable to chloride. Calculated ApM potentials of cells with activated cystic fibrosis transmembrane conductance regulators (CFTRs) are between the sodium and chloride Nernst values and thus allow rapid absorption of both ions in exocrine glands. In CF patients the potential is near the sodium Nernst value and thus more salt is left in the ducts. Simulation predicts that the sodium driving force increases more than 3.5 times if the ApM permeability for Cl- increases from 5-94% of the sodium permeability. In pancreatic ductal cells basolateral sodium bicarbonate cotransporters (pNBC1) allows influx of bicarbonates with sodium. Bicarbonates are exchanged for intraductal chloride by anion exchanger 1 (AE1) in the ApM. Activated CFTRs let some chloride to leak back to ducts, followed by water that dilutes ductal proteins. Replenished intraductal chloride allows more bicarbonate secretion. In CF patients, pancreatic water and bicarbonate secretion is limited by the intraductal chloride pool.