Transient body fluid accumulation and enhanced NKCC2 expression in gerbils with brain infarction.

BACKGROUND: Enhanced expression of a kidney-specific sodium co-transporter (NKCC2: Na-K-2Cl co-transporter) in the thick ascending limb of Henle has been identified in rat models of congestive heart failure and liver cirrhosis, suggesting that high NKCC2 expression underlies edema formation. An increased abundance of NKCC2, however, has also been noted in rats with the syndrome of inappropriate secretion of antidiuretic hormone; hyponatremia without edema. In the present study, we examined NKCC2 expression in non-edematous disease, such as a brain infarction, and investigated the physiological and/or pathological characterization of NKCC2 expression. METHODS: We initially examined NKCC2 expression in an animal model of brain infarction. Mongolian gerbils (around 60 g body weight) underwent bilateral clamping of the common carotid arteries for 5 min for the induction of brain infarction. NKCC2 and apical water channel (AQP2) protein levels in the collecting duct were examined by Western blotting in kidney tissues 2, 7, and 14 days after the brain infarction. Gerbils with brain infarction were then fed either a normal low-sodium diet (0.3 g/kg/day) or a high-sodium diet (3.0 g/kg/day), and body weight, urine volume and urinary osmolality were examined daily. Blood parameters were measured on day 14 after the brain infarction. RESULTS: Histochemical examination of the brain confirmed the presence of brain infarction, as manifested by altered cresyl violet staining in the hippocampus. Protein levels of NKCC2 were significantly increased in gerbils with brain infarction on days 2 and 7 after brain infarction, whereas AQP2 protein signals remained unaltered. However, the increased NKCC2 intensity disappeared on day 14. Body weight gain was slightly, but significantly greater in gerbils with brain infarction than in sham-operated gerbils up to 7 days after the brain infarction. The high-sodium diet resulted in significant urinary concentration and enhanced weight gain in infarcted gerbils. CONCLUSION: We noted increased NKCC2 abundance in non-edematous disease, which enhanced body fluid accumulation, likely via the sodium loading-dependent concentration of the urine. These results suggest that the physiological process of edema formation is based on specific NKCC2 expression. The transient duration of these findings in the present animal model suggests two different characteristics of specific NKCC2 expression, an immediate, transient appearance as a common response in serious conditions and more chronic expression that leads to edema formation.

Urinary concentration defect and limited expression of sodium cotransporter, rBSC1, in a rat model of chronic renal failure.

BACKGROUND: Renal urinary concentration is associated with enhanced expression of sodium cotransporter (rBSC1) in thick ascending limb of Henle. Overexpression of rBSC1 was reported recently in hypertrophied nephrons after unilateral nephrectomy (UNX) and in kidney isografts. Since urinary concentration defect and hypertrophy of residual nephrons are major manifestations of chronic renal failure (CRF), we investigated the rBSC1 signals for RNA and protein in a rat model of CRF. METHODS: Rats underwent 5/6 nephrectomy and examined 8 weeks after operation. rBSC1 mRNA was examined by competitive PCR and in situ hybridization, and rBSC1 protein signals by western blotting and immunohistochemistry. Rats that underwent sham-operation, UNX, or 5/6 nephrectomy followed by a 3-week recovery period (acute renal failure), were used as control. Water intake was restricted for 24 h in subgroups of control and CRF rats. RESULTS: Microscopic examination showed hypertrophy of residual nephrons in both UNX and CRF rats. Signals for rBSC1 mRNA and protein were enhanced at basal condition only in rats with UNX. Under basal conditions, CRF rats demonstrated low urinary osmolality in spite of high plasma arginine vasopressin levels. Water restriction resulted in increased signals for rBSC1 mRNA and protein and concentration of urine in sham-operated rats, but such increases were absent and urinary concentration was incomplete in CRF rats. CONCLUSIONS: Compensatory overexpression and upregulation of rBSC1 expression in response to dehydration are both absent in CRF rats. These limitations are thought to be the underlying mechanisms of urinary concentrating defect seen in CRF.

Vasopressin-independent renal urinary concentration: increased rBSC1 and enhanced countercurrent multiplication.

BACKGROUND: A close association between the expression of the sodium transporter, rat bumetanide sensitive cotransporter (rBSC), in thick ascending limb of Henle and urinary concentration has been reported. However, direct evidence for this association and the mechanism of rBSC1 expression are still to be elucidated. METHODS: Brattleboro (BB) rats weighing approximately 200 g were dehydrated by water restriction for 4 hours, which induced around a 5% body weight reduction. Although plasma arginine vasopressin (AVP) was undetectable even after the water restriction, BB rats concentrated urine from 182 +/- 23 (mean +/- SD) at baseline to 404 +/- 65 mOsm/kg. H2O. RESULTS: Urinary volume was reduced from 5.8 +/- 1.8 to 1.4 +/- 0.6 mL/h. This treatment significantly increased sodium and urea accumulation in the renal medulla and reduced urinary sodium excretion. rBSC1 signals for both mRNA and protein were increased in dehydrated rats, although aquaporin type 2 (AQP2) expression was not enhanced in dehydrated BB rats. Subcutaneous infusion of desmopressin acetate (DDAVP) intensified rBSC1 signals of BB rats more than those in dehydrated condition. CONCLUSION: Dehydration increased rBSC1 expression and enhanced countercurrent multiplication even in AVP deficiency. These results supply strong evidence for the association between rBSC1 expression and urinary concentration, and indicate the presence of an AVP-independent mechanism for urine concentration.