Properties of renin substrate in rabbit plasma with a note on its assay

1. Rabbit plasma enzymes that degrade angiotensin I are inhibited completely by the combination of 2,3-dimercaptopropan-1-ol (10mm), EDTA (10mm) and chlorhexidine gluconate (0.005%, w/v). These compounds do not modify the reaction of renin with renin substrate and are termed the selective inhibitors. 2. The renin substrate concentration of plasma can be measured as angiotensin I content by incubating plasma plus the selective inhibitors with renin for a time sufficient to allow complete utilization of renin substrate. 3. This reaction obeys first-order kinetics to substrate concentrations of at least 1000ng. of angiotensin I content/ml. In general, the renin substrate concentrations of normal rabbit plasmas are less than 1000ng. of angiotensin I content/ml. Thus the time required for the complete release of angiotensin I from normal plasma is inversely related to renin activity and is independent of renin substrate concentration. 4. A method for the assay of renin substrate, taking these reaction kinetics into account, is presented.     

Plasma renin activity, active and inactive renin concentrations, and their responses to beta 1-adrenoceptor blockade with metoprolol in hyperthyroidism

Plasma renin activity (PRA), plasma renin concentration (PRC), inactive renin concentration (IRC) and total renin concentration (TRC) were measured in 31 normal controls and in 8 patients with hyperthyroidism. TRC was determined as angiotensin I generated with sheep renin substrate after an acid activation of plasma. The angiotensin I of non-acidified plasma was expressed as PRC. IRC was calculated as TRC minus PRC. The mean values for PRA, PRC, IRC and TRC were significantly (P less than 0.05 to P less than 0.01) higher in the hyperthyroid patients than in the normal or euthyroid controls. The administration of a beta 1-adrenergic blocker, metoprolol (120 mg/day for 14 days), produced a significant (P less than 0.05 to P less than 0.01) fall in levels of T4, PRA and TRC, and reduced the active renin ratio calculated from PRC/TRC significantly (P less than 0.025), as compared to the pretreatment values. Our observations support the idea that the higher PRA in hyperthyroidism is due to an increased secretion of renin. Furthermore, the results may indicate that the conversion of inactive to active renin is accelerated in hyperthyroidism, possibly by an increased sympathetic activity.     

Size of the aliphatic chain of sodium houttuyfonate analogs determines their affinity for renin and angiotensin I converting enzyme

Sodium houttuyfonate analogs (SHAs), CH(3)-(CH(2))(n)-CO-CH(2)-CH(OH)SO(3)Na, (n=6-14) were synthesized and their molecular interactions with renin and angiotensin I converting enzyme (ACE) studied using fluorescence quenching techniques. Unlike renin, inhibition of ACE activity was not directly proportional to the aliphatic chain length of SHAs. Ability of SHAs to inhibit enzyme activities and quench protein fluorescence was greater with renin than with ACE. The presence of an ACE substrate (angiotensin I) did not reduce quenching ability of SHAs, suggesting that enzyme-inhibitor interactions did not involve the active site or the substrate was displaced by inhibitor molecules. The results showed that renin is a more sensitive target than ACE for the potential antihypertensive ability of SHAs.     

An improved method for measuring angiotensin I converting enzyme activity using a highly sensitive angiotensin II radioimmunoassay

A highly sensitive assay for angiotensin I converting enzyme has been developed by using angiotensin I as a substrate. Angiotensin II generated in the reaction mixture was measured by a newly developed specific radioimmunoassay. To protect against angiotensin II destruction, bestatin, an inhibitor of renin, was also used to inhibit plasma renin activity. The reaction was stopped by adding EDTA and MK-521, inhibitors of angiotensin I converting enzyme. The specificity of the antiserum used for the angiotensin II radioimmunoassay was very high. The cross reactivity with angiotensin I was less than 0.5% and none of the proteolytic enzyme inhibitors crossreacted in the assay. The inhibitory effect of pepstatin on plasma renin activity was very high (more than 80%) under the standard assay conditions employed. Serum angiotensinase activity was completely inhibited by the addition of bestatin. An excellent correlation was obtained between this new method and the spectrophotometric method using a synthetic substrate, Hip-His-Leu. The generation of as little as 12 pM of Angiotensin II can be detected. Such low concentration have not been measurable with the usual spectrophotometric method. This new method will facilitate clinical and experimental studies on this unique enzyme, since very low levels of activity can be determined by this highly sensitive radioimmunoassay for angiotensin II.     

A rapid simple method for the assay of renin in rabbit plasma

1. EDTA (10mm), 2,3-dimercaptopropan-1-ol (10mm) and chlorhexidine gluconate (0.005%, w/v) cause complete inactivation of plasma enzymes that degrade angiotensin I, but have no effect on the reaction of renin with its substrate. The reagents were termed the selective inhibitors. 2. Thus it is possible to measure renin in plasma by its ability to catalyse the release of angiotensin I. 3. Sterile plasma, treated with the selective inhibitors, is incubated with renin substrate (500-1000ng. of angiotensin content/ml.) at pH6 at 42 degrees for 6hr. 4. Under these conditions the reaction obeys first-order kinetics. Renin activity is calculated in terms of the percentage release of the angiotensin content/hr. 5. As described, the assay is sufficiently sensitive to measure renin in the plasma of all normal rabbits. By extending the length of the incubation, much lower activities can be measured.     

Purification, properties and kinetics of sheep and human renin substrates.

Sheep plasma renin substrate was purified 1,200-fold by using nephrectomised sheep plasma, followed by DEAE-Sephadex chromatography and gel filtration. The purified substrate contained 8 mu-g angiotensin II/mg protein and had an estimated molecular weight of 52,000. The kinetic characteristics of the purified substrate were identical both to those of unpurified nephrectomised sheep plasma and to normal sheep plasma substrates. At pH 7.5, K-m of the human renin-sheep substrate reaction was 0.29 mu-M and for sheep renin-sheep substrate, 2.0 mu-M. Sheep substrate was susceptible to peptic digestion with generation of pepsitensin. Human renin substrate was less readily purified. DEAE-Sephadex chromatography of plasma from pregnant women at 36-40 weeks' gestation produced a 70-fold increase in purity (0.9 mu-g angiotensin II/mg protein). No further increase was achieved with gel filtration. Human renin substrate behaved as a larger (mol. wt. 82,000) more anionic protein than sheep substrate and was resistant to the proteolytic actions of both pepsin and sheep renin. K-m for the human renin-human substrate reaction was high and could not be accurately determined (range 3-8 mu-M, mean 5.7 mu-M). The presence of human substrate in a human renin-sheep substrate system did not alter the measured initial velocity. In both sheep and man, the normal concentration of renin substrate is considerably less than K-m and must therefore be considered a determinant of angiotensin production rate in vivo.     

Renin cleavage of a human kidney renin substrate analogous to human angiotensinogen, H-Asp-Arg-Val-Tyr-Ile-His-Pro-Phe-His-Leu-Val-Ile-His-Ser-OH, that is human renin specific and is resistant to cathepsin D

A synthetic tetradecapeptide, H-Asp-Arg-Val-Tyr-Ile-His-Pro-Phe-His-Leu-Val-Ile-His-Ser-OH, which corresponds to the 13 amino terminal residues of human angiotensinogen plus a carboxy terminal serine to replace a suggested site of carbohydrate attachment, has been shown to be a good substrate for human kidney renin. At pH 7.2 and 37 degrees C the KM or Michaelis constant was 8.4 +/- 2.9 microM, and the VM or velocity at infinite tetradecapeptide concentration was 11.3 +/- 2.4 mumol angiotensin I made per hour per milligram renin. The tetradecapeptide was highly resistant to cleavage by mouse submaxillary renin. The tetradecapeptide was also slowly cleaved by human liver cathepsin D, by rabbit lung angiotensin-converting enzyme, and by reconstituted human serum, but did not yield angiotensin I. Thus, this synthetic renin substrate should permit more specific measurement of human kidney renin activity.     

Renin substrate in granules from rat kidney cortex.

1. Subcellular fractions of rat kidney cortex generated angiotensin I continuously over 2h when incubated at 37degreesC with rat renin, indicating the presence of renin substrate within cells in the renal cortex. 2. Renin substrate was located in highest specific concentration in particulate fractions. The particles containing renin substrate had a sedimentation velocity slightly lower than mitochondria and renin granules but greater than the microsomal fraction. 3. Isopycnic gradient centrifugation indicated a density of 1.190g/ml for the particles containing renin substrate, compared with 1.201 for renin granules, 1.177 for mitochondria, and 1.170 and 1.230 for lysosomes in the heavy-granule fraction. 4. In the liver, renin substrate was also found in particles, but these had a lower sedimentation rate than those from the kidney. 5. The molecular weights of renin substrate in kidney and liver granules and rat plasma were similar, namely 61000-62000. 6. On the basis of these biochemical findings, a mechanism for the intrarenal production of angiotensin, incorporating a subcellular reaction scheme, is proposed.     

Inhibition of renin secretion in the isolated rat kidney by angiotensin I.

The effect of angiotensin I on renal perfusion pressure, and on basal and isoprenaline stimulated renin secretion, was examined in the isolated perfused rat kidney. The increase in prefusion pressure associated with intrarenal infusion of angiotensin I suggested conversion of the peptide to angiotensin II within the kidney. Basal renin secretion and the stimulatory response to isoprenaline were significantly suppressed by angiotensin I. The converting enzyme inhibitor SQ 20,881, infused at 1,600 X dose of angiotensin I, partially reversed the vasoconstrictor effect of angiotensin I without altering the degree of suppression of renin secretion.     

Measurement of renin and substrate concentrations in human serum.

Methods for the measurement of renin and renin substrate by radioimmunoassay have been described. One method of measuring renin is based on the zero-order reaction velocity of angiotensin I formation when serum is incubated with an excess of hog substrate. This method was compared with a bioassay which has been described previously (A. B. Gould, L. T. Skeggs, and J. R. Kahn, 1966, Lab. Invest.15, 1802–1813) and with another radioimmunoassay which determines renin concentration from the rate of angiotensin I formation with endogenous substrate by using the integrated form of the Michaelis-Menten equation and the kinetic constants. Similar results were obtained by these three methods when 30 samples of serum from 15 normotensive people were assayed. No evidence was found to suggest any interference by activators or inhibitors in human serum. The mean recovery of human renin added to serum in 27 experiments was 93.5 ± 10.7% (SD). In addition, the kinetic analysis of human serum showed no difference in the rate of angiotensin formation, at comparable substrate levels, in sera from normotensive people (including women taking oral contraceptives) and patients with essential hypertension.     

Marathon run: effects on plasma renin activity, renin substrate, angiotensin converting enzyme, and cortisol

Altogether 33 Finnish amateur runners were studied before and after a non-competitive Marathon run over the classical itinerary in Athens in 1976 (n = 8), 1977 (n = 14) and 1978 (n = 11). Plasma renin activity (PRA) rose 3-fold in all runs, whereas plasma renin substrate (RS) concentration did not change significantly. Serum angiotensin converting enzyme (ACE) activity was not changed. Serum cortisol concentration was increased 2-3 fold. The unchanged plasma RS concentration, in spite of increasing PRA, indicates that plasma RS is kept within normal limits during prolonged strenuous physical exercise. One contributing mechanism may be stimulation of RS biosynthesis by cortisol. Low PRA levels in two old runners, 65 and 83 years old, may indicate a decreased ability to respond with renin release to the stimuli of physical exercise.     

A comparison of the substrate specificities of cathepsin D and pseudorenin

Cathepsin D, purified from hog spleen, releases angiotensin I from tetradecapeptide renin substrate and from protein renin substrates purified from hog and human plasma. However, the enzyme does not act on the naturally occurring renin substrate as it exists in plasma nor on purified substrate in the presence of plasma. Cathepsin D releases angiotensin I quantitatively from tetradecapeptide renin substrate and does not further degrade the angiotensin I on prolonged incubation. The pH optimum for cathepsin D prolonged incubation. The pH optimum for cathepsin D acting on tetradecapeptide renin substrate is 4.5, and there is very low activity above pH 7. These properties are very similar to those of pseudorenin, an angiotensin-forming enzyme originally isolated from human kidney, indicating that cathepsin D and pseudorenin may be identical.     

Kinetics of renin reaction in rat plasma (author's transl)]

Important kinetic aspects of renin reaction were studied in order to evaluate the parameters that regulate the formation rate of angiotensin I. This rate decreased throughout the incubation period of normal rat plasma and it showed a linear increase when plasma was incubated with renin-substrate. When renin was added to normal rat plasma a plateau in the angiotensin I formation rate occurred after 4-6 hours. When plasma samples containing increasing amounts of renin-substrate were incubated, the velocity of their reaction increased in proportion to the renin-substrate concentration. Under these incubation conditions, the reaction between endogenous renin and renin-substrate in normal rat plasma, proved to be a first kinetic order with respect to the substrate.     

Subcellular Localization in Rat Brain of Angiotensin I-Generating Endopeptidase Activity Distinct from Cathepsin D

Abstract: The generation of angiotensin I from the artificial renin substrate tetradecapeptide by proteolytic enzymes in rat brain tissue was studied. The involvement of endopeptidase activity in the enzymatical cleavage of the renin substrate was inferred from the simultaneous accumulation of both angiotensin I and the complementary tetrapeptide Leu-Val-Tyr-Ser on incubation of tetradecapeptide with rat brain tissue. This endopeptidase activity was active over a pH range of 3.5–7.5. In contrast, cathepsin D released angiotensin I from tetradecapeptide only at acidic pH. The angiotensin I accumulation on incubation of tetradecapeptide with brain endopeptidase activity was only partly inhibited in the presence of an excess of the carboxyl protease inhibitor N -acetyl pepstatin. Further, the brain endopeptidase activity displayed a subcellular localization different from that of acid protease activity. It is concluded that angiotensin I can be generated in the brain by soluble endopeptidases, which are distinct from cathepsin D.     

Peptide inhibitors of converting enzyme.

Human plasma and atypical lung converting enzyme, and porcine plasma converting enzyme are substantially inhibited by other components of the renin-angiotensin system, and by angiotensin II and its analogues. Des-Asp¹ angiotensin II (angiotensin III) 0.1 mM and tridecapeptide renin substrate 0.1 mM are both effective inhibitors of human lung, plasma and porcine plasma converting enzymes. Des-Asp¹-Arg² angiotensin II also was an effective inhibitor of plasma enzymes. Bradykininase activity (kininase II) of the converting enzymes was also inhibited by angiotensin I, angiotensin III, tetradecapeptide renin substrate and tridecapeptide renin substrate. The substantial kininase and converting enzyme inhibitory effects of components of the renin-angiotensin system, suggest a potential close physiologic relationship between the kallikrein-kinin system and the renin-angiotensin system.     

Trypsin activation of inactive renin: plasma blanks and angiotensin I radioimmunoassay.

Divergent conclusions exist as to whether inactive renin is present in nephrectomized rat plasma. A major factor contributing to this conflict may be related to significant changes in the "plasma blank" when trypsin-treated plasma is subjected to angiotensin I (AI) radioimmunoassay (RIA). In normal, but not nephrectomized rat plasma, AI-like substances are present in direct proportion to active renin. These substances are destroyed by trypsin. However, trypsin generates additional AI-like material, in both normal and nephrectomized rat plasma. This material, which is present in proportion to the renin substrate concentration, does not appear to be tetradecapeptide (TDP). In normal plasma, however, exogenous TDP is converted to AI in proportion to the active renin concentration and AI generation from TDP is increased by activation of inactive renin. However, in nephrectomized rat plasma, no AI generation from TDP was evident either before or after trypsin treatment. The coincident tryptic generation of a substance that quenches the levels of AI detected by RIA, combined with significant changes in the levels of endogenous and trypsin generated AI-like substances, may have significant bearing on the measured levels of inactive renin.     

Changes of Blood Pressure,Renin, and Angiotensin after Bilateral Nephrectomy in Patients with Chronic Renal Failure

Circulating levels of renin, angiotensin I, and angiotensin II were increased in six patients with chronic renal failure and hypertension uncontrolled by dialysis and hypotensive drugs. Lower and often normal levels were found in 10 patients whose blood pressure was controlled by dialysis treatment. For a variety of reasons all patients were subjected to bilateral nephrectomy. The logarithm of the decrease in plasma concentrations of renin and angiotensin II was significantly related to the fall of blood pressure after operation. Plasma renin concentration correlated significantly with blood angiotensin I concentration and with plasma angiotensin II in samples taken before and after nephrectomy. Renin, angiotensin I, and angiotensin II were measurable in samples of blood taken 48 hours or more after the operation.     

An increase in high-molecular weight renin substrate associated with estrogenic hypertension

We have previously reported that estrogens have the potential to induce new forms of renin substrate in addition to elevating the major circulating form of this protein. One of these estrogen-induced forms had a molecular weight in excess of 150,000. In this study we have compared the plasma concentration of the high-molecular-weight renin substrate in normotensive women receiving estrogen therapy and women with estrogenic hypertension. A statistically significant elevation of this protein was associated with estrogenic hypertension and normotensive pregnant women at term. This form of renin substrate differed from the major form with respect to electrophoretic mobility, isoelectric point, and immunologic cross-reactivity. In addition, kinetic analysis indicated that this high-molecular-weight substrate has a significantly higher affinity for the enzyme renin than the major circulating form (Km = 1800 +/- 290 versus 3520 +/- 260 ng angiotensin I equivalents/ml). These results suggest that in addition to renin substrate concentration, substrate composition may play an important role in blood pressure regulation.     

Resolution of rat renin substrates by isoelectric focusing.

Pooled plasmas from normal or binephrectomized rats and perfusates of isolated livers were used as sources of renin substrate for isoelectric focusing. After desalting, preliminary fractionation (plasma only), and concentration, the preparations were focused in a pH 3--10 gradient on 20-cm glass plates layered with Sephadex slurry. The pH 4--6 region, containing all the substrate, was scraped from this plate and refocused in a pH 4--6 gradient. Substrate content of 1-cm strips of slurry from half of the plate was determined by both radioimmunoassay and bioassay of angiotensin resulting from incubation with added renin. Corresponding strips from the other half of the plate were incubated without renin as a control for any preformed angiotensin. The asymmetry and broad distribution (pH 4--5) of substrate from different sources suggested the existence of more than one form. Higher resolution achieved by using the high substrate concentration of postnephrectomy plasma and 0.5-cm strips of slurry on 20-cm or 40-cm plates revealed peaks and shoulders of substrate activity. Our data suggest that multiple forms of substrate are synthesized by the liver and circulate in plasma. Postnephrectomy rat plasma appears to contain relatively more substrate(s) with higher isoelectric points than in normal plasma, possibly an accumulation of forms ordinarily degraded by endogenous renal renin.     

Effect in vivo of beta-adrenergic stimulation, angiotensin II, dibutyryl cyclic AMP, and theophylline on tonin concentration in rat saliva and submaxillary gland.

Tonin (an enzyme present in rat submaxillary gland and saliva) has previously been shown to be able, unlike renin and reninlike substances, to release angiotensin II either directly by acting on an appropriate substrate or from angiotensin I. The administration of a beta-adrenergic drug, isoproterenol, produces a rise of tonin concentration in saliva without affecting its concentration in the submaxillary gland. Prior administration of a beta blocker, propranolol, partially prevents this effect. The administration of theophylline increases the tonin concentration in both saliva and the submaxillary gland, whereas dibutyryl cyclic AMP increases tonin concentration in the former. These results suggest that beta-adrenergic stimulation enhances both tonin release into the saliva and tonin synthesis in the submaxillary gland, and that these effects might be mediated by cyclic AMP. Infusion of angiotensin II blocked the stimulatory effect of isoproterenol on salivary tonin. 1Sar-8Ile-angiotensin II is both a weak antagonist of angiotensin II in this respect and a strong agonist in terms of blocking the effect of isoproterenol another role mirrored in other physiological mechanisms of derivatives of angiotensin II.