Altered Renal Expression of Aquaporin Water Channels and Sodium Transporters in Rats with Two-Kidney, One-Clip Hypertension

Water channel aquaporin-1 (AQP1) is strongly expressed in kidney in proximal tubule and descending limb of Henle epithelia and in vasa recta endothelia. The grossly normal phenotype in human subjects deficient in AQP1 (Colton null blood group) and in AQP4 knockout mice has suggested that aquaporins (other than the vasopressin-regulated water channel AQP2) may not be important in mammalian physiology. We have generated transgenic mice lacking detectable AQP1 by targeted gene disruption. In kidney proximal tubule membrane vesicles from knockout mice, osmotic water permeability was reduced 8-fold compared with vesicles from wild-type mice. Although the knockout mice were grossly normal in terms of survival, physical appearance, and organ morphology, they became severely dehydrated and lethargic after water deprivation for 36 h. Body weight decreased by 35 +/- 2%, serum osmolality increased to >500 mOsm, and urinary osmolality (657 +/- 59 mOsm) did not change from that before water deprivation. In contrast, wild-type and heterozygous mice remained active after water deprivation, body weight decreased by 20-22%, serum osmolality remained normal (310-330 mOsm), and urine osmolality rose to >2500 mOsm. Urine [Na+] in water-deprived knockout mice was <10 mM, and urine osmolality was not increased by the V2 agonist DDAVP. The results suggest that AQP1 knockout mice are unable to create a hypertonic medullary interstitium by countercurrent multiplication. AQP1 is thus required for the formation of a concentrated urine by the kidney.

Angiotensin II (AngII) helps to regulate overall renal tubular reabsorption of salt and water, yet its effects in the distal nephron have not been well studied. The purpose of these studies was to determine whether AngII stimulates luminal Na(+) transport in the cortical collecting duct (CCD). Intracellular Na(+) concentration ([Na(+)](i)), as a reflection of Na(+) transport across the apical membrane, was measured with fluorescence microscopy using sodium-binding benzofuran isophthalate (SBFI) in isolated, perfused CCD segments dissected from rabbit kidneys. Control [Na(+)](i), during perfusion with 25 mM NaCl and a Na(+)-free solution in the bath containing the Na(+)-ionophore monensin (10 microM, to eliminate basolateral membrane Na(+) transport) averaged 19.3 +/- 5.2 mM (n = 16). Increasing luminal [NaCl] to 150 mM elevated [Na(+)](i) by 9.87 +/- 1.5 mM (n = 7; P < 0.05). AngII (10(-9) M) added to the lumen significantly elevated baseline [Na(+)](i) by 6.3 +/- 1.0 mM and increased the magnitude (Delta = 25.2 +/- 3.7 mM) and initial rate ( approximately 5 fold) of change in [Na(+)](i) to increased luminal [NaCl]. AngII when added to the bath had similar stimulatory effects; however, AngII was much more effective from the lumen. Thus, AngII significantly increased the apical entry of Na(+) in the CCD. To determine if this apical entry step occurred via the epithelial Na(+) channel (ENaC), studies were performed using the specific ENaC blocker, benzamil hydrochloride (10(-6) M). When added to the perfusate, benzamil almost completely inhibited the elevations in [Na(+)](i) to increased luminal [NaCl] in both the presence and absence of AngII. These results suggest that AngII directly stimulates Na(+) channel activity in the CCD. AT(1) receptor blockade with candesartan or losartan (10(-6) M) prevented the stimulatory effects of AngII. Regulation of ENaC activity by AngII may play an important role in distal Na(+) reabsorption in health and disease.