Pathways of angiotensin-(1-7) metabolism in the kidney.

Angiotensin-(1-7) [Ang-(1-7)], which can be formed directly from angiotensin I (Ang I) bypassing the requisite production of Ang II, is a bioactive component of the renin-angiotensin system that may oppose the actions of Ang II. In contrast to the generation of Ang II, angiotensin-converting enzyme (ACE) hydrolyses Ang-(1-7) to inactive fragments. ACE inhibitors substantially augment circulating levels of Ang-(1-7) and increase the peptide's half-life. Thus, this enzymatic pathway constitutes a key regulatory point in the vasculature to balance the actions of Ang II, Ang-(1-7) and bradykinin. In contrast, the renal pathways for the metabolism of Ang-(1-7) appear quite distinct. Characterization of this pathway may shed new light on the potential actions of the peptide in the kidney, as well as the mechanisms of novel vasoactive peptidase therapies. We summarize recent experimental and clinical studies that begin to reveal novel pathways in the formation and degradation of Ang-(1-7) in the kidney.

Pathways for angiotensin-(1---7) metabolism in pulmonary and renal tissues.

Two of the primary sites of actions for angiotensin (ANG)-(1---7) are the vasculature and the kidney. Because little information exists concerning the metabolism of ANG-(1---7) in these tissues, we investigated the hydrolysis of the peptide in rat lung and renal brush-border membrane (BBM) preparations. Radiolabeled ANG-(1---7) was hydrolyzed primarily to ANG-(1---5) by pulmonary membranes. The ANG-converting enzyme (ACE) inhibitor lisinopril abolished the generation of ANG-(1---5), as well as that of smaller metabolites. Kinetic studies of the hydrolysis of ANG-(1---7) to ANG-(1---5) by somatic (pulmonary) and germinal (testes) forms of rat ACE yielded similar values, suggesting that the COOH-domain is responsible for the hydrolysis of ANG-(1---7). Pulmonary metabolism of ANG-(1---5) yielded ANG-(3---5) and was independent of ACE but may involve peptidyl or dipeptidyl aminopeptidases. In renal cortex BBM, ANG-(1---7) was rapidly hydrolyzed to mono- and dipeptide fragments and ANG-(1---4). Aminopeptidase (AP) inhibition attenuated the hydrolysis of ANG-(1---7) and increased ANG-(1---4) formation. Combined treatment with AP and neprilysin (Nep) inhibitors abolished ANG-(1---4) formation and preserved ANG-(1---7). ACE inhibition had no effect on the rate of hydrolysis or the metabolites formed in the BBM. In conclusion, ACE was the major enzymatic activity responsible for the metabolism of ANG-(1---7) in the lung, which is consistent with the ability of ACE inhibitors to increase the half-life of circulating ANG-(1---7) and raise endogenous levels of the peptide. An alternate pathway of metabolism was revealed in the renal cortex, where increased AP and Nep activities, relative to ACE activity, promote conversion of ANG-(1---7) to ANG-(1---4) and smaller fragments.

Differential actions of renal ischemic injury on the intrarenal angiotensin system.

The present study determined the effect of either occlusion of the left renal artery for 60 min (ischemia) or sham operation on angiotensin (ANG) receptors and tissue and urinary levels of ANG peptides between 24 and 72 h recovery in male Sprague-Dawley rats. At 24 h postischemia, urinary concentrations of ANG I and ANG-(1-7) rose by an average of 83 and 64%, respectively (P < 0.05) but had declined to control levels by 72 h. Tissue ANG II rose at 24 h in postischemic kidneys by an average of 63% compared with the contralateral nonischemic kidney (P < 0.05). Whereas the enzymatic activity of angiotensin-converting enzyme and neprilysin was reduced after ischemia, renal renin activity in ischemic kidneys rose by 74% compared with sham-operated kidneys. Receptor autoradiography using (125)I-labeled [Sar(1),Thr(8)]ANG II ((125)I-Sarthran) (0.8 nM) revealed a decreased apparent density of ANG receptors (>80% AT(1)) in ischemic kidneys with a trend for a decrease in the contralateral nonischemic kidneys compared with the kidneys from sham-operated rats. Twenty-four hours after ischemia, ANG II receptors decreased by 68% in glomeruli (P < 0.05), 49% in the outer cortical tubulointerstitial area (P < 0.05), and 48% in the inner cortical-outer medullary area of the vasa recta (P < 0.05). Medullary binding decreased approximately 50% in both the ischemic kidney and the contralateral nonischemic kidney compared with sham. In all regions of the ischemic kidney, receptors recovered by 72 h to levels not different from sham control rats. The marked change in urinary ANG I and ANG-(1-7) at 24 h following occlusion indicates these peptides may be potential urinary markers for acute renal ischemia. The reduction of receptors in vascular and tubular regions of the ischemic kidney provides a mechanism for the loss of vasoconstrictor responses to ANG II following ischemia previously reported by others.

Contribution of angiotensin-(1-7) to blood pressure regulation in salt-depleted hypertensive rats.

We exposed 63 adult spontaneously hypertensive rats (SHR) and 10 (mRen-2)27 transgenic hypertensive rats to a 12-day regimen of either a normal diet (0.5%) or a low-salt diet (0.05%) to evaluate the hypothesis that the vasodepressor heptapeptide, angiotensin-(1-7) [Ang-(1-7)], buffers the pressor effects of angiotensin II during endogenous stimulation of the renin-angiotensin system. Catheters were inserted into a carotid artery and jugular vein under light anesthesia the day before the experiment. Separate groups of conscious instrumented SHR were given short-term infusions of an affinity-purified monoclonal Ang-(1-7) antibody or the neprilysin inhibitor SCH 39370. In addition, SHR and (mRen-2)27 rats were given the Ang-(1-7) receptor antagonist [D-Ala(7)]Ang-(1-7). Exposure to the low-salt diet increased plasma renin activity and elevated plasma levels of angiotensin I and angiotensin II in SHR by 81% and 68%, respectively, above values determined in SHR fed a normal salt diet. Concentrations of angiotensin I and angiotensin II were also higher in the kidney of salt-depleted SHR, whereas plasma and renal tissue levels of Ang-(1-7) were unchanged. Infusion of the Ang-(1-7) antibody produced dose-dependent pressor and tachycardic responses in salt-depleted SHR but no effect in SHR maintained on a normal-salt diet. A comparable cardiovascular response was produced in salt-depleted SHR given either SCH 39370 or [D-Ala(7)]Ang-(1-7). These agents had negligible effects on SHR fed a normal-salt diet. Blockade of Ang-(1-7) receptors produced a similar cardiovascular response in (mRen-2)27 transgenic hypertensive rats fed a low-salt diet. Injections of the heat-inactivated antibody or the subsequent infusion of the antibody to rats given [D-Ala(7)]Ang-(1-7) produced no additional effects. The data support the hypothesis that the hemodynamic effects of neurohormonal activation after salt restriction stimulate a tonic depressor action of Ang-(1-7).