Protein kinase C-alpha regulation of gallbladder Na+ transport becomes progressively more dysfunctional during gallstone formation.

Gallbladder Na+ absorption and biliary Ca2+ are both increased during gallstone formation and may promote cholesterol nucleation. Na+/H+ exchange (NHE) is a major pathway for gallbladder Na+ transport. Ca2+-dependent second messengers, including protein kinase C (PKC), inhibit basal gallbladder Na+ transport. Multiple PKC isoforms with species- and tissue-specific expression have been reported. In this study we sought to characterize Ca2+-dependent PKC isoforms in gallbladder and to examine their roles in Na+ transport during gallstone formation. Gallbladders were harvested from prairie dogs fed either nonlithogenic chow or 1.2% cholesterol-enriched diet for varying periods to induce various stages of gallstone formation. PKC was activated with the use of phorboldibutyrate, and we assessed gallbladder NHE regulation by measuring unidirectional Na+ flux and dimethylamiloride-inhibitable 22Na+ uptake. We measured gallbladder PKC activity with the use of histone III-S phosphorylation and used Gö 6976 to determine PKC-alpha contributions. Gallbladder PKC isoform messenger RNA and protein expression were examined with the use of Northern- and Western-blot analysis, respectively. Prairie dog and human gallbladder expresses PKC-alpha, betaII, and delta isoforms. The PKC activation significantly decreased gallbladder J(Na)(ms) and reduced baseline 22Na+ uptake by inhibiting NHE. PKC-alpha mediated roughly 42% of total PKC activity under basal conditions. PKC-alpha regulates basal gallbladder Na+ transport by way of stimulation of NHE isoform NHE-2 and inhibition of isoform NHE-3. PKC-alpha blockade reversed PKC-induced inhibition of J(Na)(ms) and 22Na+ uptake by about 45% in controls but was progressively less effective during gallstone formation. PKC-alpha contribution to total PKC activity is progressively reduced, whereas expression of PKC-alpha mRNA, and protein increases significantly during gallstone formation. We conclude that PKC-alpha regulation of gallbladder NHE becomes progressively more dysfunctional and may in part account for the increased Na+ absorption observed during gallstone formation.

Lovastatin alters biliary lipid composition and dissolves gallstones: a long-term study in prairie dogs.

Lovastatin, an inhibitor of the rate-limiting enzyme in cholesterol biosynthesis, is widely used to treat hypercholesterolemia. We investigated the long-term effects of lovastatin alone and in combination with ursodeoxycholic acid on biliary lipid composition and gallstone dissolution. Forty-two prairie dogs were fed 1.2% cholesterol diet for 5 weeks, and cholecystectomy was performed on 6 animals to confirm gallstones. The remaining animals were maintained on a 0.4% cholesterol diet and were randomized to receive placebo, lovastatin (3.3 mg/g diet), ursodeoxycholic acid (10 mg/g), or combination of both drugs. After 10 weeks, animals underwent cholecystectomy. Dissolution response to therapy was determined, and serum and biliary lipids were measured. All treatment groups had significant reductions in serum cholesterol. Lovastatin treatment reduced both hepatic and gallbladder bile cholesterol, altered bile acid composition, and induced a 79% total response compared to placebo. Although ursodeoxycholic treatment induced a 44% response, long-term combination treatment elevated both gallbladder bile cholesterol and calcium and failed to produce an augmented response. These data suggest that lovastatin therapy alone may promote gallstone dissolution in humans.