The purification and characterization of recombinant human renin expressed in the human kidney cell line 293

The cDNA encoding human preprorenin has been introduced into the adenovirus-transformed human kidney cell line 293. The recombinant 293 cells expressed and secreted prorenin; trypsin was used to activate the secreted prorenin to renin in vitro. The recombinant protein was purified to homogeneity by a single affinity chromatographic step. Using synthetic tetradecapeptide, the Km was 57.1 +/- 9.3 microM and the kcat was (7.48 +/- 1.57) x 10(3)/hr. Activation with trypsin resulted in a secondary cleavage between Arg53 and Leu54 generating a two chain form held together via a disulfide between Cys51 and Cys58. This secondary cleavage did not affect enzyme activity as determined by the ability of renin to degrade a synthetic tetradecapeptide substrate. Our paper demonstrates the potential for producing large quantities of renin from human kidney cells and also suggests that the use of trypsin, which has been widely used to convert prorenin to renin in vitro, causes a secondary cleavage in the renin peptide chain.     

Comparison of angiotensinogen and tetradecapeptide as substrates for human renin. Substrate dependence of the mode of inhibition of renin by a statine-containing hexapeptide

The kinetic properties of two different substrates for human renin, a synthetic tetradecapeptide and the natural substrate human angiotensinogen, have been compared. While the Vmax was similar for the two substrates, the Km values differed by a factor of 10, i.e., 11.7 +/- 0.7 microM (tetradecapeptide) and 1.0 +/- 0.1 microM (angiotensinogen). The mode of inhibition of renin by a statine (Sta)-containing hexapeptide, BW897C, that is a close structural analog of residues 8-13 of human angiotensinogen (Phe-His-Sta-Val-Ile-His-OMe), was determined for the two substrates. Competitive inhibition was observed when tetradecapeptide was the substrate (Ki = 2.0 +/- 0.2 microM), but a more complex mixed inhibition mode (Ki = 1.7 +/- 0.1 microM, Ki' = 3.0 +/- 0.23 microM) was found with angiotensinogen as substrate. This mixed inhibition probably results from the formation of an enzyme-inhibitor-substrate or enzyme-inhibitor-product complex and reflects the more extensive interactions that the protein angiotensinogen, as opposed to the small tetradecapeptide substrate, can make with renin. We conclude that the mixed inhibition observed when angiotensinogen is used as renin substrate could be important in the clinical application of renin inhibitors because it is less readily reversed by increased concentrations of substrate than is simple competitive inhibition.     

A radiochemical renin assay

1. A synthetic 3-([(14)C]valine)-labelled tetradecapeptide renin substrate was used to measure renin concentration. Renin liberated (14)C-labelled angiotensin I, which was separated from the labelled substrate by paper chromatography. The conversion of substrate into angiotensin I was quantitated by liquid-scintillation counting of radioactivity. 2. The rate of conversion of the substrate into angiotensin I was shown to be linearly related to renin concentration and time under suitable conditions. Angiotensin generation measured in this system agrees well with that measured by bioassay. 3. It is suggested that the use of a pure substrate offers advantages that include the standardization of current units of renin measurement.     

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.     

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.     

Conformations of synthetic tetradecapeptide renin substrate and of angiotensin I in aqueous solution.

The properties of aqueous solutions of synthetic renin substrate tetradecapeptide (Asp-Arg-Val-Tyr-Ile-His-Pro-Phe-His-Leu-Leu-Val-Tyr-Ser) were examined through electrometric titrations, infrared and circular dichroism spectroscopy, and spectrofluorometry. Titration studies of angiotensin I (Asp-Arg-Val-Tyr-Ile-His-Pro-Phe-His-Leu) were also made, whose results indicated a flexible folded conformation similar to that previously proposed for the octapeptide angiotensin II, with a possible additional beta turn at the C terminus. The experimental results of the tetradecapeptide study, associated with Chou and Fasman calculations and with an analysis of structure-activity relationships in renin substrates and competitive inhibitors, led to the proposal of a beta turn involving the His-Pro-Phe-His sequence of the tetradecapeptide. This beta turn would be stabilized by beta-antiparallel interaction between residues 3-4 and 10-12 and by electrostatic attraction between the N-terminal ammonium and C-terminal carboxylate groups and would be destabilized below pH 5 by electrostatic repulsion between His6 and His9. The capacity to assume this conformation is related to structural requirements for renin substrates and competitive inhibitors.     

Low molecular weight renin as a storage form in renin granules of the dog

The molecular weight of renin extracted from isolated renin granules of the dog was estimated by gel filtration, using tetradecapeptide as substrate, and was approximately 43,000 daltons. Neither big renin nor big big renin was demonstrable. On the other hand, crude extract of kidney cortex showed angiotensin I generating enzymes other than 43,000 dalton form of renin, whose molecular weight were over 100,000 and around 70,000 daltons. They seemed nonspecific proteases, since they hydrolyzed tetradecapeptide but not plasma angiotensinogen. Therefore renin is stored in the renin granules as a low molecular weight form.     

Purification and characterization of human kidney renin

By means of a new rapid and small scale purification method, human kidney renin has been purified from a single kidney in a homogeneous state, as judged on SDS-PAGE. The kidney which showed unusually high renin activity was from a patient with cardiomyopathy. 8,000-fold purification was attained by means of only pepstatin-aminohexyl-Sepharose chromatography and FPLC on a Mono Q column, and the yield was 34%. The specific activity was 5.63 mg angiotensin I per mg protein per h at 37 degrees C and pH 6.5 with porcine angiotensinogen as the substrate. The molecular weight was estimated to be 37,000 by SDS-PAGE and 38,000 by HPLC on a TSK G-3000 SW column. The preparation showed three bands on isoelectric focusing. The molecular weight and the profile on isoelectric focusing of the purified renin agreed with those found for the extracts of both the patient's kidney and a kidney with the usual low renin activity.     

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.     

Interaction of mouse submaxillary gland renin with a statine-containing, subnanomolar, competitive inhibitor

The interaction between mouse submaxillary gland renin and a statine-containing, iodinated substrate analog inhibitor was studied. The compound, 1 (Boc-His-Pro-Phe-(4-iodo)-Phe-Sta-Leu-Phe-NH2, Sta = (3S,4S)-4-amino-3-hydroxy-6-methyl-heptanoic acid), a statine-containing analog of the renin substrate octapeptide, was a competitive inhibitor of cleavage of synthetic tetradecapeptide renin substrate by mouse submaxillary gland renin, with a Ki of 6.2 x 10(-10) M (pH 7.2, 37 degrees C). Titration of the partial quenching of the tryptophan fluorescence of the enzyme by 1 revealed tight binding with a dissociation constant less than 3 nM and a binding stoichiometry of one mole 1 per mole enzyme. The time course of tight binding of 1 to mouse renin appeared to be fast, with kON greater than or equal to 1.3 x 10(6) s-1 M-1. The UV difference spectrum generated upon binding of 1 to mouse renin had two prominent features: a strong, broad band that had a minimum at 242 nm with delta epsilon (242) = -19,500 cm-1 M-1, and a triplet of enhanced bands centered at 286 nm with delta epsilon (286) about +1100 cm-1 M-1. The strong, broad, negative band was similar to the difference between the UV absorbance of 1 in methanol and in 0.1 M citrate phosphate pH 7.2. A structure-activity correlation for analogs of 1 showed some moieties of 1 that are important for potent inhibition of mouse renin. The inhibition data for these compounds versus human kidney renin suggested that the solution of the crystal structure of 1 bound to mouse renin will provide useful information for the design of inhibitors of human kidney renin.     

Inhibition of human renin by synthetic peptides derived from its prosegment

The primary structure of human preprorenin has recently been determined from its cDNA sequence. It includes a 46-amino acid NH2-terminal prosegment. Six peptides corresponding to the entire prosegment (9-40), except for the NH2-terminal (1-8) and COOH-terminal (41-46) ends have been synthesized. These peptides were tested for their inhibitory effect on human plasma renin activity. Boc-Tyr-Thr-Thr-Phe-Lys-Arg-Ile-Phe-Leu-Lys-Arg-Met-Pro-OMe (where Boc represents t-butoxycarbonyl and OMe represents methoxy) (h Y(9-20) and its fragment Boc-Leu-Lys-Arg-Met-Pro-OMe h (16-20) were the most potent inhibitors with IC50 values of 2 X 10(-4) and 3 X 10(-4)M, respectively. Peptides located near the COOH-terminus were less inhibitory. The inhibitory capacity of h (16-20) was studied further on highly purified human renin acting on either pure human angiotensinogen or a synthetic human tetradecapeptide substrate. In both of these assays its inhibitory potency was about 10-fold greater than that found on plasma renin activity. Peptide h (16-20) was 3-6 times less potent in inhibiting human renin than its mouse counterpart m (15-19) was in inhibiting mouse renin. Kinetic studies carried out with h (16-20) showed a mixed type of inhibition. When human angiotensinogen was used as substrate, Ki and K'i values were 17.7 +/- 3.9 and 2.9 +/- 0.9 microM, respectively. These studies showed that human renin, like mouse renin and pepsin, can be inhibited by peptides derived from its prosegment. In addition, as in the case of pepsin, they suggest that the NH2-terminal part of the prosegment interacts more strongly with the active enzyme.     

Substrate analog competitive inhibitors of human renin

Replacement with D-amino acids at the site of cleavage in the native sequence of tetradecapeptide renin substrate yields effective competitive inhibitors of renin. The present communication reports the solid phase synthesis and the kinetic parameters of analogs of des-Asp-tetradecapeptide renin substrate, in which L-Leu at position 10 and/or 11 has been replaced with D-Leu. The dissociation constant (K_i) for renin of the three inhibitors described here is about 10^?6 M. These synthetic substrate analogs are not significantly hydrolyzed by renin.     

The amino-acid residues on the C-terminal side of the cleavage site of angiotensinogen influence the species specificity of reaction with renin

The N-terminal sequences of human and canine angiotensinogen and two hybrid sequences were synthesized and used to determine whether the species specificity of renin is influenced by amino-acid residues adjacent to the cleavage site. kcat/Km for the generation of angiotensin I from the N-terminal tridecapeptide of human angiotensinogen by canine renin is 0.37% of that observed when the N-terminal tetradecapeptide from canine angiotensinogen is used as a substrate. Replacement of the valine residue at P'1 in the human tridecapeptide with the leucine residue from the canine sequence triples kcat and improves Km 4-fold. Replacement of isoleucine residue at P'2 with the valine residue from the canine sequence enhances Km 8-fold. Substitution of the histidine residue at P'3 with the tyrosine serine sequence of canine angiotensinogen increases kcat an order of magnitude. Results obtained with the synthetic substrate are similar to those observed with the protein substrates. Canine renin does not cleave human angiotensinogen. Also, kcat/Km of canine renin for its homologous substrate is about 6-times greater than the kcat/Km value for human renin acting on human angiotensinogen.     

A study on renin binding protein (RnBP) in the human kidney

We purified, from human kidney, a protein that reacts with rabbit anti-porcine kidney renin binding protein (RnBP) antiserum by trapping with porcine kidney renin. The purified preparation showed a single protein peak on gel filtration by high performance liquid chromatography (HPLC) and two protein bands on sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). The latter two kinds of protein were identified as the porcine renin and human kidney protein from their electrophoretic mobilities and reactivity toward rabbit anti-porcine kidney renin and RnBP antisera. The molecular weights of the purified preparation and the human kidney protein were estimated to be 56,000 by HPLC and 43,000 by SDS-PAGE, respectively. The specific activity of porcine renin in the purified preparation was 8.6 mg angiotensin I per mg of protein per h at 37 degrees C and pH 6.5. This specific activity was about one-fifth that of free porcine renin. Therefore, it is suggested from the reactivity toward the anti-porcine RnBP antiserum and inhibitory action toward porcine renin that the human kidney protein is RnBP and that the human RnBP is purified as a complex with porcine renin.     

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.     

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.     

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.     

Measurement of inactive renin in normal, nephrectomized, and adrenalectomized rats.

In a new method for measurement of inactive rat plasma renin, the trypsin generated angiotensin I immunoreactive material, which was HPLC characterized as similar to tetradecapeptide renin substrate, is removed by a cation exchange resin before the renin incubation step. The method also corrects for trypsin destruction of endogenous angiotensinogen by the addition of exogenous angiotensinogen. When measured with this method inactive renin in rat plasma decreased after nephrectomy and increased after adrenalectomy. This is in accordance with findings in humans. A sexual dimorphism of prorenin (inactive renin) in rat plasma, similar to that reported in humans and mice, was demonstrated. Thus, inactive renin in the rat is no exception among species, and the rat might be a suitable animal model for further studies dealing with the physiology of prorenin in plasma and tissues.     

Biochemical evidence for existence of immunoreactive renin in human prolactinoma tissue

High activity of renin was demonstrated in human prolactinoma tissue. This activity was almost completely inhibited by specific antibody raised against human renal renin, indicating that it was not due to the nonspecific action of proteases. The specific activity of renin was 5.04 ng of angiotensin I generated/mg of protein per h, comparable to that of the pituitary tissue prepared from postmortem human subjects. The biochemical properties of the prolactinoma renin were generally similar to those of well-known kidney enzyme, such as molecular mass (Mr = 46,000), optimum pH (6.0), and glycoprotein nature. However, the isoelectric points (pI) of the prolactinoma renin (pI = 4.90, 5.04, 5.24 and 5.41) differed somewhat from those of plasma and kidney renins reported hitherto. These results indicate that true renin can be produced in human prolactinoma tissue.     

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.