Abstract
AIMS: The epithelial sodium channel ENaC consists of the subunits α, β, and γ and is activated at an individual channel level by proteolytic processing. Murine γENaC contains a distal polybasic tract 186(RKRK) mediating proteolytic ENaC activation by serine proteases in vitro. The relevance of ENaC activation at this cleavage site for sodium homeostasis in vivo is unknown. METHODS: Mice were generated carrying a mutation of the distal polybasic tract (RKRK186QQQQ or γENaC(ki/ki)) using CRISP/Cas9. Sodium homeostasis and proteolytic processing of γENaC were investigated under a low sodium diet, pharmacological ENaC blockade, and induction of nephrotic syndrome. RESULTS: Under control conditions, the response to bolus amiloride was reduced in γENaC(ki/ki) mice compared to γENaC(wt/wt) mice. Under a low sodium diet for 4 days, urinary sodium excretion was similarly lowered in both genotypes; however, γENaC(ki/ki) mice required significantly higher plasma aldosterone concentrations. Both genotypes were similarly tolerant to amiloride exposure for 4 days and developed similar sodium retention and body weight gain after induction of nephrotic syndrome. Proteolytic processing of γENaC leading to increased expression of distally cleaved γENaC at ~54 kDa was stimulated in both γENaC(wt/wt) and γENaC(ki/ki) mice under all interventions without an appreciable difference in the migration pattern. CONCLUSION: Mice harboring the RKRK186QQQQ mutation of the distal polybasic tract develop hyperaldosteronism under a low sodium diet, pointing to the relevance of this tract for sodium preservation. However, proteolytical processing of γENaC in these mice appears to be compensated for by the involvement of other adjacent cleavage sites.