We studied the isolated blood-free perfused nonclipped kidneys from the 2-kidney Goldblatt hypertensive rat model (GHR) to evaluate intrinsic excretory responses to changes in perfusion pressure. We examined kidneys from 10 control rats (in vivo systolic BP 110 +/- 3.6 mm Hg), from 9 rats with nonmalignant hypertension (HBP) (in vivo systolic BP 158 +/- 6.5 mm Hg), and from 5 rats with malignant HBP (in vivo systolic BP 183 +/- 6.4 mm Hg). We found that at all levels of perfusion pressure, the renal vascular resistances were significantly higher and glomerular filtration rate (GFR) lower in kidneys from hypertensive rats than in kidneys from control rats. Kidneys from hypertensive rats had lower urinary excretion of sodium (UNaV) and urine flow than kidneys from control rats at all levels of pressure above 100 mm Hg. The most striking differences in all functional parameters were noted in kidneys from rats with malignant HBP. Kidneys from both hypertensive and control rats failed to show changes in vascular resistance in response to Saralasin. We conclude that the nonclipped kidney in GHR exhibits a blunted natriuresis in response to elevated perfusion pressure which occurs in the absence of angiotensin II (AII) and renin substrate. This diminished pressure natriuresis may be caused partly by the lower GFR and by reduced pressure transmission due to greater renal vascular resistance and thus may be partially responsible for the maintenance of the hypertensive state.
We studied the effects of insulin and of anti-insulin serum (AIS) on sodium excretion in isolated diabetic and normal, fed, rat kidneys perfused at a constant pressure of 100 mm Hg with Krebs-Ringer bicarbonate buffer containing 7.5% bovine serum albumin and 5 mM glucose and gassed with 95% O2 and 5% CO2. The addition of insulin produced antinatriuresis in kidneys from diabetic rats but not in those from normal rats. Moreover, before the addition of insulin, the baseline rate of sodium excretion was greater in the diabetic rat kidney than in the normal rat kidney, while no differences in glomerular filtration rate (GFR) were observed. The addition of AIS (enough to bind 1.4 mU of insulin per milliliter of perfusate) produced a brisk natriuresis in kidneys from normal rats, and this natriuresis could be reversed by the addition of saturating amounts of insulin. By contrast, the addition of normal guinea pig serum to the perfusate of normal kidneys or AIS to the perfusate of diabetic kidneys was unassociated with natriuresis. We conclude that (a) insulin promoted antinatriuresis in diabetic but not in normal rat kidneys, (b) AIS promoted natriuresis in normal kidneys, and (c) this natriuresis was a specific effect of AIS and was reversed by the addition of insulin. Our data support the view that insulin-induced antinatriuresis depends on endogenous levels of circulating insulin and on the availability of insulin-binding sites in the kidney.
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