Authors: Sachiko Futakuchi Hiroshi Ishiguro Satoru Naruse Shigeru B H Ko Kotoyo Fujiki Akiko Yamamoto Miyuki Nakakuki Ying Song Martin C Steward Takaharu Kondo Hidemi Goto
Publish Date: 2009/09/15
Volume: 459, Issue: 1, Pages: 215-
Abstract
Cellular mechanisms underlying the impairment of pancreatic fluid and electrolyte secretion in diabetes were examined using interlobular ducts isolated from rat pancreas Fluid secretion was assessed by monitoring changes in luminal volume HCO 3 − uptake across the basolateral membrane was estimated from the recovery of intracellular pH following an acid load Exposure to high glucose concentrations inhibited fluid secretion and reduced the rate of basolateral HCO 3 − uptake in secretinstimulated ducts isolated from normal rats In ducts isolated from streptozotocintreated diabetic rats fluid secretion and basolateral HCO 3 − uptake were also severely impaired but could be largely reversed by incubation in normalglucose solutions Sodiumdependent glucose cotransporter 1 SGLT1 glucose transporter GLUT1 GLUT2 and GLUT8 transcripts were detected by reverse transcriptase polymerase chain reaction in isolated ducts Raising the luminal glucose concentration in microperfused ducts caused a depolarization of the membrane potential consistent with the presence of SGLT1 at the apical membrane Unstimulated ducts filled with highglucose solutions lost luminal fluid by a phlorizinsensitive mechanism indicating that pancreatic ducts are capable of active glucose reabsorption from the lumen via SGLT1 In ducts exposed to high glucose concentrations continuous glucose diffusion to the lumen and active reabsorption via SGLT1 would lead to elevation of intracellular Na+ concentration and sustained depolarization of the apical membrane These two factors would tend to inhibit the basolateral uptake and apical efflux of Cl− and HCO 3 − and could therefore account for the impaired fluid and electrolyte secretion that is observed in diabetes
Keywords: