The distinction between a circulating renin-angiotensin system and a tissue renin-angiotensin system led us to determine tissue angiotensin converting enzyme (ACE) activity. This study establishes the experimental conditions for a good reproducibility of the fluorimetric assay of ACE and describes the use of [3H]ramiprilat to characterize ACE. Angiotensin converting enzyme activity was determined in rat lung, heart, aorta, and kidney (cortex and medulla) and in rabbit kidney (cortex, medulla, tubules, and glomeruli). ACE activity and [3H]ramiprilat binding does not increase in a linear fashion with the protein content of tissue extracts. Linearity limits varied from 1.0 to 2.0 mg of protein/ml (fluorimetry) and from 0.4 to 1.0 mg of protein/ml [( 3H]ramiprilat binding). Comparing ACE activity, measured by fluorimetry, with the amount of [3H]ramiprilat bound shows that the two techniques yield similar results.
On the isolated perfused rat kidney, angiotensin-converting-enzyme activity was evaluated by two approaches: one, biochemical, through the measurements of the enzymatic activity on renal homogenate, the other, pharmacological, through the vasoconstrictor response to angiotensin I. Renal tissue angiotensin-converting-enzyme activity was not modified by setting the kidney under perfusion with a modified Krebs-Henseleit solution but was inhibited after addition of captopril into the perfusion medium (10(-5) M, 100 p. 100 inhibition) or after pretreatment of the animals with ramipril (10 mg/kg/day over 3 weeks, per os, 60 p. 100 inhibition). On the isolated perfused rat kidney, angiotensin I and angiotensin II induced a concentration dependent renal vasoconstriction (EC50 = 1.05 +/- 0.18 X 10(-8) and 0.11 +/- 0.05 X 10(-8) M) which was competitively antagonized by saralasin, an angiotensin II receptor antagonist. Addition of angiotensin-converting-enzyme inhibitors to the perfusion medium (captopril or ramiprilat, 10(-5) M) or pretreatment of the animals with ramipril (50 mg/kg, i.p. the day before or 10 mg/kg/day over 3 weeks, per os) only shifted the angiotensin I concentration-response curve to the right by a factor 3 to 4. The residual vasoconstrictor effect of angiotensin I was abolished by 10(-5) M saralasin and remains linked to a local generation of angiotensin II. Our results suggest that, on the isolated perfused rat kidney, besides the angiotensin-converting-enzyme, an iso-enzyme may also be able to generate angiotensin II.
Summary— Loop diuretics of the benzoic acid and aryloxyacetic acid families inhibit Na+K+Cl − cotransport. The ranking order of potencies measured in the thick ascending limb of Henle's loop and the ranking order of affinities for [ 3 H]piretanide receptors on renal plasma membranes are the same. Potencies and affinities correlate well (correlation coefficient r = 0.959 for the medulla and r = 0.951 for the cortex). Therefore, measurement of [ 1 H]piretanide binding is proposed to facilitate screening for loop diuretic action.
The inhibition of angiotensin converting enzyme by ramipril, ramiprilat, enalapril, enalaprilat, and captopril was studied in the plasma and various tissues (lung, heart, renal cortex, renal medulla) of normotensive rats and spontaneously hypertensive rats. Displacement curves for [3H]ramiprilat were established on each tissue with the converting enzyme inhibitors, and their potencies were expressed as the concentration that inhibited 50% of the specific [3H]ramiprilat binding. In the plasma, lung, and heart, the order of activities was: ramiprilat greater than enalaprilat greater than captopril greater than ramipril greater than enalapril. This order was different in the kidney (cortex and medulla): ramiprilat greater than enalaprilat greater than ramipril greater than captopril greater than enalapril. For ramiprilat, enalaprilat, and captopril, there were no differences in their respective potencies between tissues or between rat strains. However, the two prodrugs ramipril and enalapril were 10-30 times more active in the kidney than in the other tissues in both groups of rats. This was due to the deesterification of the prodrugs: in the presence of an esterase inhibitor (diethyl nitrophenyl phosphate, 10 microM), the potencies of ramipril in the kidney were not different from that obtained in the lung, which was not affected by the presence of the esterase inhibitor. These results suggest that the variations in the tissue activities of an angiotensin converting enzyme inhibitor are probably not due to differences in tissue affinities of the angiotensin converting enzyme inhibitor but depend on the concentration of this angiotensin converting enzyme inhibitor in each tissue.
Recent evidence suggests that tissue generation of angiotensins I and II depends on the level of the plasma components of the renin-angiotensin system and on tissue-specific processes. The present study was undertaken to clarify the possible relationship between plasma renin activity (PRA) and tissue angiotensin converting enzyme (ACE) activity in the heart, lung, kidney cortex and kidney medulla of Wistar-Kyoto rats. In the kidney cortex particular attention was focused on renal brush-border ACE.Different experimental models known to have opposite effects on PRA were used: changes in salt intake, deoxycorticosterone acetate (DOCA) with or without salt supplements, and the Goldblatt two-kidney, one clip (2-K,1C) model. Two weeks after the start of the experiments the rats were killed, and PRA, and plasma and tissue ACE activity, were measured.At the end of the study the blood pressure in the treated rats was not significantly different from control. As expected, the PRA were highest in the 2-K,1C and depleted-salt groups and lowest in the DOCA, DOCA-salt and high-salt groups. ACE responses were different in different types of tissue, with no relationship between PRA and plasma or tissue ACE activity. For example, DOCA treatment led to increased ACE activity in the heart and the kidney only if the rats were maintained on a high salt intake. DOCA or salt alone failed to have this effect. In the 2-K,1C model the unclipped kidneys did not show any significant variation in ACE activity, but the clipped kidneys exhibited increased ACE activity compared with sham-operated rats. This increase, coupled with increased renal renin secretion, could play a role in the acceleration of local angiotensin II formation, and could thus initiate and sustain the development of hypertension in this model.The present results show that variations in ACE activity were organ-specific and were not linked either to hypertension or to changes in PRA.
Summary— In order to identify tissue specific regulation of angiotensin converting enzyme (ACE), the effects of dexamethasone (0.04 mg sc per day for 7 days) and triiodothyronine (T3) (0.5 mg/kg sc per day for 10 days) on ACE activity were investigated in different tissues in male Wistar rats. ACE activity was measured by fluorimetry in the plasma, heart, lung and kidney. In the kidney, ACE activity was measured in the medulla, cortex and brush border of proximal tubular cells and 3 H‐ramiprilat binding was used to characterise the changes in brush border ACE activity. Dexamethasone elicited a significant increase in lung ACE activity and a significant decrease in plasma ACE activity, but did not alter enzyme activity in the other tissues studied. T3 produced a significant decrease in lung ACE activity and an increase in ACE activity in the plasma and heart. In the kidney, ACE activity was not modified in the medulla whereas in the cortex and brush border ACE activity was doubled. This increase in ACE activity corresponded to a similar increase in the maximum number of binding sites of 3 H‐ramiprilat, suggesting that the increase in activity corresponded to an increase in the ACE level. The increased heart and kidney ACE activity in response to T3 may contribute to the cardiovascular effects of thyroid hormones through increased local angiotensin II generation. These results show that under dexamethasone or T3, ACE activity can vary from one tissue to another, suggesting that the ACE regulatory mechanism acts differently in each tissue.
The distinction between a circulating renin-angiotensin system and a tissue renin-angiotensin system led us to determine tissue angiotensin converting enzyme (ACE) activity. This study establishes the experimental conditions for a good reproducibility of the fluorimetric assay of ACE and describes the use of [3H]ramiprilat to characterize ACE. Angiotensin converting enzyme activity was determined in rat lung, heart, aorta, and kidney (cortex and medulla) and in rabbit kidney (cortex, medulla, tubules. and glomeruli). ACE activity and [3H]ramiprilat binding does not increase in a linear fashion with the protein content of tissue extracts. Linearity limits varied from 1.0 to 2.0 mg of protein/ml (fluorimetry) and from 0.4 to 1.0 mg of protein/ml ([3H]ramiprilat binding). Comparing ACE activity, measured by fluorimetry, with the amount of [3H]ramiprilat bound shows that the two techniques yield similar results.
