Endothelin-A receptors mediate renal hemodynamic effects of exogenous Angiotensin II in humans.

To investigate whether endothelin-A receptors mediate hemodynamic changes caused by exogenous Angiotensin II in humans, 7 healthy volunteers on a 250-mmol sodium diet underwent 3 separate p-aminohippurate and inulin-based renal hemodynamic studies. In 2 studies, Angiotensin II (increasing rates of 0.625, 1.25, and 2.5 ng/kg per minute, each for 30 minutes) was infused either alone or combined with endothelin-A blocker, BQ123, 0.4 nmol/kg per minute. A third infusion of BQ123 alone was not followed by any change. Angiotensin II infusion alone produced a progressive decrease in renal blood flow (1080+/-94 mL/minx1.73 m2 to 801+/-52, P<0.001, versus baseline) and glomerular filtration rate (115+/-7 mL/minx1.73 m2 to 97+/-7, P<0.001) with increase in filtration fraction (0.188+/-.017 to 0.220+/-.030, P<0.01). Mean arterial pressure and renal vascular resistance increased markedly (86.8+/-3.1 to 97.5+/-4.4 mm Hg, P<0.001 and 83+/-7 to 133+/-20 mm Hg/min per liter, P<0.001, respectively). With Angiotensin II+BQ 123, mean arterial pressure still rose (86.2+/-3.1 to 91.1+/-4.3, P<0.05 versus both baseline and BQ123 alone) but significantly less than with Angiotensin II alone (P<0.05). Renal blood flow (1077+/-76 to 993+/-79, P<0.001) and glomerular filtration rate (115+/-7 to 105+/-7, P<0.05) also changed to a significantly lesser extent than with Angiotensin II alone (P<0.05 for both), whereas filtration fraction remained unchanged (0.185+/-.015 to 0.186+/-.016). Renal vascular resistance rose only by 17% (82+/-5 to 95+/-9, P<0.001 versus baseline as well as versus BQ123 or Angiotensin II alone). The results show that endothelin through Endothelin-A receptors contributes substantially to the systemic and renal vasoconstriction of low-dose exogenous Angiotensin II in healthy humans.

Renal hemodynamic control by endothelin and nitric oxide under angiotensin II blockade in man.

To investigate whether endothelin-A receptors and nitric oxide modulate renal hemodynamics in man under angiotensin II receptor-1 blockade, 6 healthy volunteers, on a 240 mmol Na diet, underwent 4 separate renal hemodynamic measurements, in 3 of which endothelin-A blocker BQ-123 0.2 nmol.kg.min(-1) was infused for 90 minutes after pretreatment with either placebo, telmisartan 1 mg.kg center dot day(-1) for 3 days, or telmisartan as well, but with co-infusion of both BQ-123 and N(G)-nitro-L-arginine methylester 0.5 microg.kg center dot min(-1). A fourth infusion was made with N(G)-nitro-L-arginine methylester alone. No change followed infusion of either N(G)-nitro-L-arginine methylester alone or BQ-123 alone. With BQ-123 after telmisartan, renal blood flow rose from 916 +/- 56 mL center dot min(-1) center dot 1.73 m(2) to 1047 +/- 51.2 (P<0.001), and renal vascular resistances fell from 89 +/- 7 mm Hg center dot min center dot L(-1) to 74 +/-4 (P<0.001). These changes were fully abolished by the co-infused N(G)-nitro-L-arginine methylester. Infusion of BQ-123, devoid of renal hemodynamic effects at baseline, produces significant renal vasodilation when angiotensin II receptors are blocked, indicating an increasing renal hemodynamic role of endothelin-A--receptor activity. Because such a vasodilation is prevented by nonvasoconstricting microdoses of N(G)-nitro-L-arginine methylester, nitric oxide--endothelin balance controls substantially renal hemodynamics under angiotensin II blockade. These findings are consistent with a rationale of the association of endothelin-A blockers with angiotensin II blockers or angiotensin-converting enzyme inhibitors in treating nitric oxide--deficient conditions such as arterial hypertension, heart failure, and chronic renal diseases.

Angiotensin II and prostaglandin interactions on systemic and renal effects of L-NAME in humans.

For investigation of whether interactions between prostaglandins and angiotensin II modulate renal response to acute nitric oxide synthesis inhibition in humans, seven young volunteers who were kept on a 240-mM Na diet underwent four experiments with 90 min of infusion of 3.0 microg/kg.min(-1) NG-nitro-L-arginine methyl ester (L-NAME), each preceded by a 3-d treatment with placebo (PL), 50 mg of losartan (LOS), 75 to 125 mg of indomethacin (IND), or both drugs. Mean arterial pressure (MAP), GFR, effective renal plasma flow (ERPF), and Na excretion rate (UNaV) were measured at baseline and from 0 to 45 min and 45 to 90 min of L-NAME infusion. After PL, L-NAME reduced GFR by 5% at 45 min (P < 0.05) and by 9% at 90 min (P < 0.001), ERPF by 11 to 17% (P < 0.001), and UNaV by 28 to 45% (P < 0.001). MAP, unchanged at 45 min, rose by 5% (P < 0.001) at 90 min. LOS prevented pressor but not renal effects of L-NAME. With L-NAME+IND, MAP rose even at 45 min (+5%; P < 0.001 versus baseline) with a 10% rise at 90 min (P < 0.001). Changes in GFR (-13 to -20%), ERPF (-19 to -26%), and UNaV (-51 to -70%) were greater than those with L-NAME+PL or L-NAME+LOS (P < 0.05 to 0.001). With L-NAME+IND+LOS, MAP did not increase, and GFR, ERPF, and UNaV fell much less than with L-NAME+IND alone (P < 0.02 to 0.001) with no differences versus PL or LOS alone. Angiotensin II blockade does not affect renal changes caused by L-NAME but prevents their potentiation by prostaglandin inhibition. Thus, endogenous prostaglandins counteract renal actions of endogenous angiotensin II in Na-repleted humans even when nitric oxide synthesis is inhibited.