Potassium diet as a determinant for the renal response to systemic potassium channel modulation in anesthetized rats.

The role of potassium intake in the response of kidney function and plasma renin activity (PRA) to systemic application of U37883A (4-morpholinecarboximidine-N-1-adamantyl-N'-cyclohexyl-hydro chloride), a putative blocker of ATP-sensitive potassium channels (K(ATP)), and P1075 (N-cyano-N'-(1,1-dimethylpropyl)-N"-pyridylguanidine), an opener of K(ATP) channels, was studied in the anesthetized rat. It was found that under normal potassium diet (0.7% K), U37883A (15 mg/kg, i.v.) increased urinary flow rate (UV) and sodium excretion (UNaV), decreased urinary potassium excretion (UKV), and significantly diminished heart rate (HR) without affecting mean arterial blood pressure (MAP) or glomerular filtration rate (GFR). P1075 (10 microg/kg, i.v.) lowered UV, UNaV and UKV, at least in part due to the fall in MAP and GFR. PRA was diminished by U37883A and increased by P1075. Variation in potassium diet (0.04 or 2% K) left the response in MAP, HR or GFR to both potassium channel modulators essentially unchanged. The reduction in renal excretion rates to P1075 also appeared unaffected, further supporting a predominant role of the change in MAP and GFR in this response. Variation in potassium diet, however, elicited the following alterations: (1) under both low and high potassium diet U37883A did no longer cause a significant natriuresis; (2) U37883A elicited a significant kaliuresis under high potassium diet, whereas potassium excretion remained essentially unchanged on very low levels under low potassium diet; (3) the increase in PRA to P1075 was blunted under low potassium diet. Additional experiments provided evidence that P1075 releases renin from freshly isolated juxtaglomerular cells of rats on normal but not on low potassium diet. In summary, systemic potassium channel modulation employing U37883A or P1075, respectively, exerts distinct effects on blood pressure and heart rate independent of potassium diet. In contrast, potassium diet appears to be a determinant for the concomitant responses in plasma renin activity and renal sodium and potassium excretion.

Effect of chronic salt loading on kidney function in early and established diabetes mellitus in rats.

Glomerular hyperfiltration and renal hypertrophy are among the events that characterize the early course of diabetes mellitus in rats and human patients. Previous studies from this laboratory demonstrated that salt restriction paradoxically reduces total renal vascular resistance (RVR) and increases glomerular filtration rate (GFR) in diabetic rats (J Am Soc Nephrol 1995;5:1761-7). In the present study we examined the converse condition by testing the effects of chronic salt loading on kidney function in moderately hyperglycemic insulin-treated rats with early and established streptozotocin diabetes. Salt loading was accomplished by adding 1% NaCl to the drinking water 1 day or 35 days after diabetes was induced. The high-salt diet appropriately increased salt excretion in diabetic rats and nondiabetic controls. GFR and renal plasma flow were determined by inulin and para-amino hippuric acid (PAH) clearance 7 days after salt loading was started. Diabetic rats receiving tap water exhibited hyperfiltration with no change in renal blood flow (RBF). In nondiabetic rats, salt loading caused a reduction in total RVR and proportional increases in RBF, GFR, and kidney weight (KW). Salt loading in early diabetes did not affect RVR, RBF, or KW and caused a paradoxical reduction in GFR. In established diabetes, salt loading reduced RVR and increased RBF, similar to results in nondiabetic rats, but as in rats with early diabetes, it did not increase GFR or KW. In summary, although the response in RVR and RBF to chronic salt loading depends on the duration of diabetes, the increase in GFR and KW as seen in nondiabetic rats is blunted in the early and established state of insulin-treated diabetes in rats. These findings further support the notion that the renal response to variation in salt intake is altered in insulin-treated diabetes in rats.