K B Brosnihan

In vivo metabolism of angiotensin I by neutral endopeptidase (EC 3.4.24.11) in spontaneously hypertensive rats.

We investigated the processing enzymes involved in the formation of circulating angiotensin-(1–7) after intravenous administration of angiotensin I to conscious spontaneously hypertensive and Wistar-Kyoto rats. Immunoreactive products, including angiotensin I, angiotensin II, and angiotensin-(1–7), were measured in arterial blood by three specific radioimmunoassays. Angiotensin I infusion (2 nmol) induced a rapid increase in immunoreactive angiotensin II and angiotensin-(1–7). Pretreatment with the angiotensin converting enzyme inhibitor enalaprilat (2 mg/kg) eliminated angiotensin II formation and augmented circulating levels of angiotensin I and angiotensin-(1–7) in spontaneously hypertensive and Wistar-Kyoto rats. The elevated levels of angiotensin-(1–7) in enalaprilat-treated rats were blocked by concurrent treatment with the neutral endopeptidase (EC 3.4.24.11) inhibitor SCH 39,370 (15 mg/kg) in both strains. Administration of SCH 39,370 alone decreased angiotensin-(1–7) levels in spontaneously hypertensive rats, whereas angiotensin II levels increased in both strains (p < 0.01). Comparisons of the metabolism of angiotensin I in the two rat strains showed increased formation of angiotensin-(1–7) in spontaneously hypertensive rats not given any of the enzyme inhibitors. In addition, levels of angiotensin I were higher after administration of SCH 39,370 in hypertensive rats. These novel findings reveal that neutral endopeptidase EC 3.4.24.11 participates in the conversion of angiotensin I to angiotensin-(1–7) and in the metabolism of angiotensin II in the circulation of both spontaneously hypertensive and Wistar-Kyoto rats. Our results suggest that neutral endopeptidase EC 3.4.24.11 is a major enzymatic constituent of the circulating renin-angiotensin system.

Angiotensin-(1-7). A member of circulating angiotensin peptides.

We measured the concentrations of three principal products of the renin-angiotensin system and seven of their metabolites in the plasma of anesthetized normal dogs and in dogs 24 hours after bilateral nephrectomy. The levels of the angiotensin peptides were measured by high-performance liquid chromatography combined with radioimmunoassay using three specific antibodies that recognized different epitotes in the sequences of angiotensin I, angiotensin II, and angiotensin-(1-7). The analysis revealed that angiotensin-(1-7) is present in the plasma of intact (4.9 +/- 2.2 fmol/ml) and nephrectomized (0.5 +/- 0.5 fmol/ml) dogs. An intravenous injection of purified hog renin (0.01 Goldblatt unit/kg) increased plasma levels of angiotensin I, angiotensin II, and angiotensin-(1-7) both before and after nephrectomy. These changes were associated with parallel increases in the concentrations of fragments of the three parent peptides. Administration of MK-422 led to the disappearance of circulating angiotensin II and its fragments both before and after a second injection of the same dose of renin. In contrast, MK-422 augmented the plasma levels of both angiotensin I and angiotensin-(1-7). The concentrations of these two peptides, but not the blood pressure, were again augmented by a second injection of renin given after blockade of converting enzyme. These effects were observed both before and after bilateral nephrectomy. These findings show that angiotensin-(1-7) circulates in the blood of normal and nephrectomized dogs. In addition, we found that angiotensin-(1-7) is generated in the blood from the cleavage of angiotensin I through a pathway independent of converting enzyme (EC 3.4.15.1).

Immunocytochemical localization of angiotensin-(1–7) in the rat forebrain

Recent findings by this group have led us to reconsider the view that amino (N-) terminal fragments of angiotensin (Ang) II are inactive degradation products of renin-angiotensin system. To further examine this possibility, an antibody to Ang-(1-7), the N-terminal heptapeptide, was produced to demonstrate the neuroanatomical distribution of the rat brain. Ang-(1-7)-immunoreactivity was found in paraventricular, supraoptic, and suprachiasmatic nuclei, bed nucleus of the stria terminalis, substantia innominata, median eminence, and neurohypophysis. This distribution of Ang-(1-7) in the rat forebrain, together with our previous demonstrations of vasopressin secretion in response to this peptide, suggest that Ang-(1-7) functions as a neuromodulator.

Processing of angiotensin peptides by NG108-15 neuroblastoma × glioma hybrid cell line

The metabolism of angiotensin (Ang) peptides was studied in NG108-15 neuroblastoma x glioma hybrid cells which express Ang II receptors, renin, dipeptidyl carboxypeptidase A (converting enzyme), as well as Ang I and Ang II. In these experiments, 0.2 nM of either 125I-Ang I or 125I-Ang II was incubated with intact cell monolayers and the medium was analyzed for 125I-products by high performance liquid chromatography. The major product generated from the metabolism of labeled Ang I or Ang II was identified as the amino-terminal heptapeptide Ang-(1-7). N-benzyloxycarbonyl-prolyl-prolinal (ZPP), a specific inhibitor of prolyl endopeptidase, inhibited the formation of Ang-(1-7) from Ang I by 35%. Complete inhibition of Ang-(1-7) generation was attained with p-chloromercuriphenyl-sulfonate, which suggests that a sulfhydryl-containing peptidase other than prolyl endopeptidase is also involved in Ang-(1-7) formation. Ang II was observed to be a minor product resulting from Ang I metabolism. Although the converting enzyme inhibitor enalaprilat (MK-422) significantly reduced Ang II formation, it had no effect on the levels of Ang-(1-7). These findings demonstrate a preferential processing of Ang I into Ang-(1-7) which is not dependent on the prior formation of Ang II.

Tissue renin-angiotensin systems in renal hypertension.

Angiotensinogen messenger RNA (mRNA) levels were measured in the brain (hypothalamus, lower brain stem, cerebellum), liver, kidneys, and adrenal glands of rats made hypertensive by ligation of the aorta between the renal arteries. We also measured renin mRNA in the kidneys of these renal hypertensive rats. The early phase of hypertension (day 6) was associated with significant increases in plasma renin activity and levels of circulating angiotensin II. The circulating renin-angiotensin system was not activated in the later phase of hypertension (day 24). Angiotensinogen mRNA levels were elevated in the lower brain stem of hypertensive rats at both stages of hypertension. In contrast, angiotensinogen mRNA levels in the hypothalamus were increased only at day 6 after aortic ligation. Decreased levels of angiotensinogen mRNA were observed in the cerebellum in both the early and later phases of the hypertension. Angiotensinogen mRNA levels in the adrenal gland below the ligature fell in the early phases but rose in the later phases of hypertension. Renin mRNA levels of the ischemic kidney remained elevated at both the early and later phases, whereas in both ischemic and nonischemic kidneys, levels of angiotensinogen mRNA remained below sham values throughout the period of study. These results indicate differential expression of renin-angiotensin system mRNAs in tissues of renal hypertensive rats. The differential changes in the expression of angiotensinogen mRNA over the course of development and maintenance of renal hypertension suggest that factors in addition to angiotensin II are important in modulating the expression of renin-angiotensin system genes.

Inhibition of angiotensin converting enzyme by the metalloendopeptidase 3.4.24.15 inhibitor c-phenylpropyl-alanyl-alanyl-phenylalanyl-p-aminobenzoate

Inhibitors of metallopeptidases may represent new alternatives in the treatment of cardiovascular disease. Recent investigations have linked the hypotensive properties of the metalloendopeptidase 3.4.24.15 (MEP 24.15) inhibitor c-phenylpropyl-alanyl-alanyl-phenylalanyl-para-aminobenzoate (cFP-A-A-F-pAB) to the attenuation of bradykinin metabolism. However, since angiotensin converting enzyme (ACE) is widely recognized to contribute to the metabolic clearance of bradykinin, we characterized the specificity of cFP-A-A-F-pAB towards ACE. We also determined whether cFP-A-A-F-pAB inhibits the conversion of angiotensin I (Ang I) to Ang II by pulmonary ACE. The ACE activity toward the synthetic substrate hippuryl-histidine-leucine (Hip-His-Leu) was measured in vitro using both a purified lung preparation and pooled rat serum. The ACE activity was inhibited at increasing concentrations of the MEP 24.15 inhibitor. Kinetic analysis revealed that cFP-A-A-F-pAB competitively inhibited pulmonary ACE with a Ki of 0.19 microM. In rat serum, cFP-A-A-F-pAB also competitively inhibited ACE. The hydrolysis of Ang I into Ang II by pulmonary ACE was inhibited to a similar extent by both cFP-A-A-F-pAB and the ACE inhibitor MK 422. These findings are the first to show that the MEP 24.15 inhibitor cFP-A-A-F-pAB also inhibits ACE. We suggest that the reported hypotensive actions of cFP-A-A-F-pAB may be due to the reduction in both bradykinin metabolism and Ang II generation arising from the blockade of ACE.

Hemodynamic and Neurohormonal Changes in the Development of DOC Hypertension in the Dog

In this article we summarize studies of the hemodynamic and endocrine effects of desoxycorticosterone (DOC)-induced hypertension in dogs and also review new data of the action of this steroid on baroreceptors. The hemodynamic effect of subcutaneous injections of DOC to dogs, without supplementation of salt in their diet, consisted of increases in arterial pressure that were sustained for a 28-day observation period and associated with augmented cardiac output. At the early stage of the hypertensive response there was a rise in plasma Na+ concentration accompanied by increases in the plasma and cerebrospinal fluid (CSF) levels of vasopressin. The activity of the peripheral renin angiotensin system, as evaluated by the longitudinal changes in plasma renin activity and plasma immunoreactive angiotensin II (irAng-II), was markedly depressed in the hypertensive dogs. In contrast, the concentration of irAngII in the CSF did not change. Additional studies of the carotid occlusion reflex in anesthetized dogs revealed an enhanced buffering baroreceptor capacity in the early (less than day 10), but not the late (greater than day 28), stages of the hypertension. The abnormality in baroreflex function may be mediated by an effect of the steroid on an activity of brain angiotensin II that influences the inhibitory interaction between high and low pressure baroreceptors. The data acquired in these studies agree with the notion that excess mineralocorticoid production causes hypertension by mechanisms that influence the neurohormonal control of blood pressure by the central nervous system.

Cardiovascular actions of intrahypothalamic injections of atrial natriuretic peptide.

Accumulating evidence implicates atrial natriuretic polypeptide (ANP) as a neurotransmitter in brain. The presence and distribution of ANP, its high affinity binding sites, and the messenger RNA of its precursor have been described in the central nervous system. However, the function(s) of ANP in specific brain areas is largely unknown. We have now determined the cardiovascular effects elicited by microinjection of atriopeptin-III (ANP-III) in hypothalamic and preoptic areas in rats. ANP-III (40 pmol) increased heart rate when injected into the anteromedial preoptic nucleus (AMPO), the medial preoptic area (MPA), the periventricular area, and in two regions of the dorsal hypothalamus. Other nuclei within the hypothalamus were unresponsive. The tachycardic effects elicited by AMPO-MPA injection of ANP-III were abolished by adrenalectomy. These data indicate that ANP-III acts at discrete sites to elicit tachycardia and the mechanism of action for at least one brain site appears to be through central pathways which selectively activate the adrenal gland.

Differential Regulation of Angiotensinogen Transcripts After Renin Infusion

To investigate angiotensinogen regulation in high-renin hypertension, we infused porcine renin intravenously at either a low (4 mU/kg per hour, n = 6) or high (20 mU/kg per hour, n = 9) dose into male Sprague-Dawley rats (225 to 250 g) for 5 days using osmotic minipumps. Control rats received 0.9% NaCl. In renin-infused rats, mean arterial pressure and plasma renin activity were significantly elevated. Both low- and high-renin infusions lowered plasma angiotensinogen levels. Plasma angiotension II was elevated in rats given renin but reached statistical significance only at the higher dose. Angiotensinogen mRNA isolated from the liver, adrenal gland, kidney, and brain was measured by slot blot analysis. Both renin doses were associated with significant decreases in the levels of liver and hypothalamic angiotensinogen mRNA. In the medulla oblongata, angiotensinogen mRNA was reduced only by the higher renin dose. The lower dose increased angiotensinogen mRNA in the adrenal gland, and in kidney, angiotensinogen mRNA level was unchanged by renin infusion. Angiotensinogen mRNA visualized on Northern blots showed that the number of mRNA species in liver decreased from three in control rats to a single mRNA species after renin infusion. Tissue differences in the size of the major angiotensinogen mRNA species were also apparent. This, together with changes in the total hybridization signal of angiotensinogen mRNA in tissues, suggests that renin differentially affects the different angiotensinogen mRNA transcripts. Results of this study indicate that angiotensinogen gene expression is regulated not only by alterations in levels of circulating angiotensin II but also by other mechanisms, presently unidentified, that are activated by renin infusions.