Confirmation of direct angiotensin formation by kallikrein.

This study was undertaken to confirm our previous preliminary observation that hog pancreas kallikrein (EC 3.4.21.35) directly liberated an angiotensin-like substance from human plasma protein Cohn fraction IV-4 at an acidic pH of 4.0-5.0. First, the possibility of proangiotensin or des-Asp1-angiotensin being the pressor substance was ruled out by t.l.c. Secondly, the pressor substance was purified by Sephadex G-25 and Bio-Gel P-2 gel filtration, and finally by high-performance liquid chromatography. The amino acid composition of the isolated pressor substance (residues/mol) was: Asp, 1.03; Val, 1.03; Ile, 1.00; Tyr, 0.69; Phe, 1.04; His, 0.91; Arg, 0.86; Pro, 0.86. This composition was identical with that of angiotensin. Since the reaction mixture was not contaminated with common proteolytic enzymes, such as trypsin, chymotrypsin, renin, cathepsin D and proangiotensin-converting enzyme, and other enzymes activated by kallikrein, it is clear that hog kallikrein directly produces angiotensin in vitro.     

Nature of the pressor substance in rabbit placenta

1. The renin-like substance isolated from the placenta of the rabbit produces a prolonged increase of blood pressure in the nephrectomized rat. If incubated with renin substrate from ox serum, it forms a pressor substance that elevates blood pressure in exactly the same way as does angiotensin. 2. This angiotensin-like principle was concentrated by means of ion-exchange chromatography and compared with Val-5-angiotensins I and II in two paper-chromatography systems and in paper electrophoresis. 3. In all the three methods the unknown principle behaved like a mixture of the two reference compounds. 4. It is concluded that incubation of the renin-like substance of placental origin with substrate from ox serum gave a mixture of Val-5-angiotensins I and II. This is evidence that the enzyme isolated from the placenta is either closely related to, or identical with, renin.     

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.     

Intrarenal localization of renin binding substance in rats

Renin binding substance is a protein that reacts with renin (Mw:40,000) to form a high-molecular-weight renin (Mw:60,000). There is evidence that this substance is present in the renal cortex. However, the exact localization has not been determined. We now report that when glomeruli and tubular segments were isolated from the rat kidney cortex and were frozen and thawed to extract proteins, the high-molecular-weight renin was detected by high performance liquid chromatography, when renin was mixed with an extract of tubular segments, but was not detected with an extract of the glomeruli. Thus, the renin binding substance was demonstrated in the cortical tubular cells but not in the glomeruli. Thus, the renin binding substance was demonstrated in the cortical tubular cells but not in the glomeruli, and the renin binding substance probably does not contribute to the process of biosynthesis of renin in juxtaglomerular cells. Rather, this substance may play a role in tubular functions in the kidney.     

Growth stimulation of adult rat hepatocytes in a primary culture by soluble factor(s) secreted from nonparenchymal liver cell

Cocultures of adult rat hepatocytes with nonparenchymal liver cells (NPC) resulted in stimulation of DNA synthesis of hepatocytes and their survival for more than one month. These cells were found capable of synthesizing albumin and 3-methylcholanthrene-inducing cytochrome P-450. A conditioned medium obtained by culturing NPC was effective to the same degree as the coculture with NPC for stimulating DNA synthesis in hepatocytes. The factor(s) responsible for this was inactivated by heating or trypsin treatment, but it was not capable of passing through a cellulose tubing. It is thus evident that soluble proteinaceous substance (s) secreted from NPC stimulates the growth of hepatocytes in a primary culture.     

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.     

Isolation of serum albumin-synthesizing polysomes from rat liver

The procedures for the purification of rat liver polysomes synthesizing serum albumin was developed, employing the quantitative precipitin method with rat serum albumin as a carrier and its antibody, and ribonuclease inhibitor from rat liver. The addition of ribonuclease inhibitor to polysomes during the incubation with antibody was found to prevent their degradation. Under these conditions, about 12 % of the membrane-bound polysomes of rat liver was found in the specific precipitate of serum albumin and its antibody, while a negligible amount of free polysomes was precipitated. It is concluded that polysomes synthesizing serum albumin are isolated by this method.     

Ser84 of human renin contributes to the biphasic pH dependence of the renin-angiotensinogen reaction

The pH dependence of the reaction of various renins was investigated using sheep angiotensinogen as a substrate. Human renin showed two separate peaks, but rat and mouse Ren1 renins showed one peak with a shoulder. A comparison of the predicted subsite residues of human renin with those of rat and mouse Ren1 renins revealed that Arg82, Ser84, Thr85, Ala229, and Thr312 are unique in the human sequence. We examined the possible importance of these residues in the unique pH profile of the human renin reaction by replacing these residues with the corresponding residues of rat renin. The replacement of Ser84 of human renin with Gly changed the pH dependence of the reaction to one peak, similarly to rat and mouse Ren1 renins. Other mutant human renins kept two separate peaks, similarly to wild-type human renin. These results indicate that Ser84 of human renin contributes to the biphasic pH dependence of the renin-angiotensinogen reaction.     

Heterogeneity of renin substrate released from hepatocytes and in brain extracts

Renin substrate was characterized in incubation medium of isolated hepatocytes, plasma, and brain extracts of the rat by isoelectric focusing and polyacrylamide gel electrophoresis. The isoelectric focusing (IEF) profile of renin substrate released into incubation medium of rat hepatocytes demonstrated two peaks with isoelectric points (pI) of 4.1 (minor peak) and 4.6 (major peak). Extracts of normal rat brain also showed two forms (pI 4.6 major form, and pI 5.1 minor form). In contrast, normal rat plasma contained a single broad peak of substrate with pI 4.5. On polyacrylamide gel electrophoresis (PAGE), the hepatocytes medium and brain extracts contained forms of substrate with reduced mobility as compared to the plasma form. Intraperitoneal injection of 17β estradiol (1 mg) or bilateral nephrectomy significantly elevated renin substrate levels in plasma and increased its release from hepatocytes, however, no change in the IEF or PAGE profiles was evident. There was no remarkable change of substrate concentration in the brain following these treatments. Molecular weights of renin substrate were 60,000–65,000 from all preparations. It remains to be established whether the different forms of renin substrate from hepatocytes represent precursor forms of circulating plasma substrate. The presence of distinct forms of brain renin substrate and the lack of an increase in brain renin substrate following nephrectomy or estrogen treatment suggest local synthesis and support the postulate of an independent renin-angiotensin system in the central nervous system.     

Comparative enzymatic studies of human renin acting on pure natural or synthetic substrates

Some of the essential structural requirements for the enzymatic reaction of pure human renin acting on pure human and rat angiotensinogen and on their synthetic tetradecapeptide substrates were investigated. The five carboxy terminal amino acids of synthetic tetradecapeptides played a significant role in substrate recognition and/or hydrolysis by human renin. Kinetic constants Km, Kcat and kcat/Km of the various human renin assays were different according to the substrate used. The presence of either an asparagine or a threonine residue in the S'4 renin subsite did not affect significantly the kinetic constant values. A tyrosine residue, rather than a histidine residue, in the S'3 renin subsite gave the best synthetic substrate studied. When tyrosine residue was present in the S'2 renin subsite an important decrease in kcat was observed. Human angiotensinogen was hydrolysed by human renin with lower Km and kcat values than those measured with human and porcine synthetic substrates, suggesting that the 3-dimensional structure of human angiotensinogen plays a key role in the hydrolysis. This finding was supported by assays performed with rat angiotensinogen, which was cleared by human renin with the same kcat value as rat tetradecapeptide, but with a 49-fold lower Km. Between human and rat angiotensinogen a kcat/Km value of only 2-fold higher has been found in the renin assay using human substrate.     

Functional role,cellular source,and tissue distribution of rat elastase-2, an angiotensin II-forming enzyme

We recently described a chymostatin-sensitive elastase-2 as the major angiotensin (ANG) II-forming enzyme in the perfusate of the rat mesenteric arterial bed (MAB) with the same cDNA sequence as rat pancreatic elastase-2. The role of this enzyme in generating ANG II was examined in the rat isolated and perfused MAB. The vasoconstrictor effect elicited by ANG I and the renin substrate tetradecapeptide was only partially inhibited by captopril but abolished by the combination of captopril and chymostatin or N-acetyl-Ala-Ala-Pro-Leu-chloromethylketone (Ac-AAPL-CK; inhibitor originally developed for human elastase-2). The effect induced by [Pro11,d-Ala12]-ANG I, an ANG I-converting enzyme (ACE)-resistant biologically inactive precursor of ANG II, was blocked by chymostatin or Ac-AAPL-CK. It was also demonstrated that cultured rat mesenteric endothelial cells synthesize elastase-2 and that mRNA for this enzyme can be detected in different rat tissues such as the pancreas, MAB, lung, heart, kidney, liver, and spleen. In conclusion, the demonstration of a functional alternative pathway to ACE for ANG II generation in the rat MAB and the fact that cultured MAB endothelial cells are capable of producing and secreting elastase-2 represent strong evidence of a physiological role for this enzyme in the rat vasculature.     

Generation of xenopsin-related peptides during acid extraction of gastric tissues

Biologically active xenopsin-related peptide(s) were shown by radioimmunoassay to be liberated in nearly micromolar concentrations from substrate(s) with Mr greater than 70,000 during acid extraction of mammalian and avian stomach. The reaction displayed an enzyme-like temperature sensitivity, had a pH optimum of 2, and was fully inhibited in the presence of pepstatin A. Treatment of a stabilized gastric substrate with hog pepsin was found to mimic the reaction, producing immunoreactive xenopsin(s) which behaved similarly during high pressure liquid chromatography. Although some of the generated immunoreactivity co-chromatographed with xenopsin, it differed immunochemically when examined with a battery of region-specific antisera. Highly purified rat gastric immunoreactive xenopsin displayed xenopsin-like biologic effects, producing hypotension in the anesthetized rat and contracting the isolated guinea pig ileum. These findings suggest that there may be a renin/angiotensin-like system for the generation of xenopsin-related peptides in the stomach.     

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.     

Formation of angiotensin II by tonin from partially purified human angiotensinogen

The renin substrate (angiotensinogen) has been purified from outdated human blood bank plasma. A 100-fold purification was achieved by ammonium sulphate protein fractionation and four successive chromatographic procedures. We show that tonin, a serine protease enzyme found in submaxillary glands of the rat, cleaves the human plasma angiotensinogen, devoid of tonin inhibiting factor(s), at a pH optimum of 5--5.5. It generates a pressor substance that was identified as angiotensin (A) II. The rate of cleavage of the human angiotensinogen preparation by 1 nmol of renin or tonin was calculated to be 1320 nmol AI/h for renin and 26 nmol AII/h for tonin.     

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.     

Renin substrate and the renin-angiotensin system in hog tissues

The individual components of the renin-angiotensin system has been identified in numerous tissues. In this study we have examined whether a functional renin-angiotensin system is operative in several hog tissues including brain, aorta, and liver. The contribution of tissue renin substrate to the rate of local angiotensin generation was also assessed. Electrophoretic differences in plasma and tissue renin substrates, indicating structural differences, were employed as an index of independence of the tissue system from that of the peripheral circulation. Our results indicate that all tissues studied had the potential to locally generate angiotensin and that renin substrate limited to rate of the renin reaction in these tissues. Electrophoretic parameters, polyacrylamide gel electrophoresis, and isoelectric focusing suggest that the tissue renin systems are of local origin. The potential magnitude of local angiotensin production is such that tissue renin-angiotensin systems may significantly contribute to the control and regulation of blood pressure and other regulatory mechanisms influenced by angiotensin.     

Kinetic comparisons of amniotic fluid inactive renin and renal renin using synthetic and human renin substrates

Inactive renin has been isolated from pooled amniotic fluid and purified approximately 642-fold. Prior to activation the isolates had approximately 4% of the activity found after activation. The observation is similar to that reported for inactive renin from chorionic cell culture and suggests a placental origin of amniotic fluid inactive renin. Using plasma from an estrogen-treated woman, renin substrate was recovered free of renin and inactive renin and a portion was separated into NMW and HMW components. The NMW form constituted approximately 93% and the HMW form approximately 7% of the renin substrate. Amniotic fluid inactive renin was used for determinations of enzyme-substrate kinetics with the pooled, NMW, and HMW plasma substrate and tetradecapeptide synthetic substrate, and the results were compared to similar determinations using standard renal renin. Using synthetic substrate, the kinetics of renal renin and amniotic fluid inactive renin before and after activation were similar. The kinetics of renal renin with pooled, NMW, and HMW plasma substrate were also similar. Amniotic fluid inactive renin had a lower Km with pooled than with NMW substrate, however, which resulted from a significantly smaller Km with HMW component. Although the affinity constants with pooled substrate were not different for renin and inactive renin, the Km of inactive renin was significantly less with the HMW component of plasma renin substrate. The observations are compatible with a role for placental inactive renin in normal pregnancy and suggest the possibility of a further role in hypertensive pregnancy.     

Immunochemical studies on biosynthesis of rat plasma angiotensinogen and its regulation by cortisol

Glucocorticosteroid hormones increase the level of rat plasma angiotensinogen by increasing its rate of synthesis. Two forms of plasma angiotensinogen have been purified differing with respect to molecular weight and affinity to concanavalin A. Immunochemical studies using antibodies raised against the separated forms of angiotensinogen revealed cross-reactivity with both antigens. Both antibodies were able to quantitatively precipitate the angiotensinogen activity present in rat serum samples. Cortisol increased the total amount of plasma renin substrate without changing the relative amounts of both angiotensinogen forms. mRNA coding for plasma angiotensinogen was determined by in vitro translation of poly(A)-containing RNA and immunochemical analysis of translation products. Angiotensinogen mRNA could be detected in total poly(A)-containing RNA isolated from rat liver, but not in mRNA isolated from brain, although angiotensinogen has been reported to be present in the latter organ. The level of hepatic mRNA coding for plasma angiotensinogen was high in rats treated with cortisol, but not detectable in animals depleted from endogenous glucocorticosteroids by bilateral adrenalectomy.     

Isorenin, pseudorenin, cathepsin D and renin. A comparative enzymatic study of angiotensin-forming enzymes

1. Renin was purified 30 000-fold from rat kidneys by chromatography on DEAE-cellulose and SP-Sephadex, and by affinity chromatography on pepstatinyl-Sepharose. 2. The enzymatic properties of isorenin from rat brain, pseudorenin from hog spleen, cathepsin D from bovine spleen, and renin from rat kidneys were compared: Isorenin, pseudorenin and cathepsin D generate angiotensin from tetradecapeptide renin substrate with pH optima around 4.9, renin at 6.0. With sheep angiotensinogen as substrate, isorenin, pseudorenin and cathepsin D have similar pH profiles (pH optima at 3.9 and 5.5), in contrast to renin (pH optimum at 6.8). 3. The angiotensin-formation from tetradecapeptide by isorenin, pseudorenin and cathepsin D was inhibited by albumin, alpha-and beta-globulins. These 3 enzymes have acid protease activity at pH 3.2 with hemoglobin as the substrate. Renin is not inhibited by proteins and has no acid protease activity. 4. Renin generates angiotensin I from various angiotensinogens at least 100 000 times faster than isorenin, pseudorenin or cathepsin D, and 3000 000 times faster than isorenin when compared at pH 7.2 with rat angiotensinogen as substrate. 5. The 3 'non-renin' enzymes exhibit a high sensitivity to inhibition by pepstatin (Ki less than 5.10(-10) M), in contrast to renin (Ki approximately 6-10(-7) M), at pH 5.5. 6. It is concluded from the data that isorenin from rat brain and pseudorenin from hog spleen are closely related to, or identical with cathepsin D.