Human prorenin structure sheds light on a novel mechanism of its autoinhibition and on its non-proteolytic activation by the (pro)renin receptor

Antibodies and prorenin mutants have long been used to structurally characterize prorenin, the inactive proenzyme form of renin. They were designed on the basis of homology models built using other aspartyl protease proenzyme structures since no structure was available for prorenin. Here, we present the first X-ray structure of a prorenin. The current structure of prorenin reveals that, in this zymogene, the active site of renin is blocked by the N-terminal residues of the mature version of the renin molecule, which are, in turn, covered by an Ω-shaped prosegment. This prevents access of substrates to the active site. The departure of the prosegment on activation induces an important global conformational change in the mature renin molecule with respect to prorenin: similar to other related enzymes such as pepsin or gastricsin, the segment that constitutes the N-terminal β-strand in renin is displaced from the renin active site by about 180° straight into the position that corresponds to the N-terminal β-strand of the prorenin prosegment. This way, the renin active site will become completely exposed and capable of carrying out its catalytic functions. A unique inactivation mechanism is also revealed, which does not make use of a lysine against the catalytic aspartates, probably in order to facilitate pH-independent activation [e.g., by the (pro)renin receptor].     

Identification of plasma inactive renin as prorenin with a site-directed antibody

A sequence-specific antibody that recognizes a portion of the prosegment of human renin precursor was raised and used to provide direct evidence that plasma inactive renin contains the prosequence of renal renin and is therefore probably prorenin rather than an inactivated form of previously active renin. The information may help not only to resolve a major controversy concerning the nature of inactive renin in human plasma but also to elucidate its exact physiological role.     

In vitro biosynthesis of human renin and identification of plasma inactive renin as an activation intermediate

The biosynthesis and post-translational modifications, including proteolytic processing and core glycosylation, of the human renin precursor have been studied in vitro in a cell-free system. For this purpose, highly enriched renin mRNA was isolated from a renin-producing juxtaglomerular cell tumor and translated in rabbit reticulocyte lysate containing [35S]methionine in the presence or absence of dog pancreas microsomal membranes. Fluorographic analysis of the radioactive translation products, immunoprecipitated and then resolved on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, revealed that the primary translation product, preprorenin (Mr = 45,000), is initially processed to glycosylated prorenin (Mr = 47,000) during or shortly after its sequestration into the lumen of the microsomal membranes. The vectorial translocation across the membrane was confirmed by the observation that the proform was resistant to digestion with trypsin while preprorenin was sensitive. Radiosequencing and the use of prorenin-specific antibodies established the cleavage points of the pre- and profragment and showed that the in vitro precursor of human renin contains a 23-residue signal peptide and a 43-residue prosegment. The post-translational modification which, despite the removal of signal peptide, resulted in an increase in apparent Mr, reflects the glycosylation as examined using Xenopus oocytes microinjected with renin mRNA in the presence of tunicamycin, an inhibitor of protein glycosylation. Four anti-peptide antibodies which specifically recognize the NH2 terminus (Pro 1), two middle parts (Pro 2A and Pro 2B), and COOH terminus (Pro 3) of the prosegment, respectively, have been raised and used to characterize plasma prorenin. Renin precursors (pre- and prorenin) synthesized in vitro or in the kidney reacted with these antibodies (anti-Pro 1, anti-Pro 2A, anti-Pro 2B, and anti-Pro 3). However, quite unexpectedly, human plasma prorenin was recognized only by anti-Pro 3, indicating that plasma prorenin is a truncated version of intact prorenin, which lacks a large portion of the NH2 terminus of the prosegment and may represent an activation intermediate. This somewhat surprising result may lead to a better understanding of the exact roles and activation mechanisms of plasma prorenin existing in a relatively large amount.     

Efficient Production of Recombinant Human (Pro)renin Utilizing a Decahistidine Tag Attached at the C-Terminus

Human prorenin attached by a decahistidine tag at the C-terminus was produced in Chinese hamster ovary cells. The tagged protein secreted into the culture medium was in the inactive prorenin form, and was activated to mature renin by proteolytic removal of its prosegment by trypsin in the same manner as native prorenin. The tagged (pro)renin was efficiently purified by metal-chelate affinity chromatography. The enzymatic properties of mature renin carrying the tag were similar to native renin. These results indicate that the introduction of a decahistidine tag at the C-terminus does not interfere with either the correct folding of prorenin or the catalytic activity of mature renin.     

Efficient production of recombinant human (pro)renin utilizing a decahistidine tag attached at the C-terminus

Human prorenin attached by a decahistidine tag at the C-terminus was produced in Chinese hamster ovary cells. The tagged protein secreted into the culture medium was in the inactive prorenin form, and was activated to mature renin by proteolytic removal of its prosegment by trypsin in the same manner as native prorenin. The tagged (pro)renin was efficiently purified by metal-chelate affinity chromatography. The enzymatic properties of mature renin carrying the tag were similar to native renin. These results indicate that the introduction of a decahistidine tag at the C-terminus does not interfere with either the correct folding of prorenin or the catalytic activity of mature renin.     

The molecular biology of human renin and its gene

The molecular biology of renin, prorenin, and the renin gene have been studied. A tissue-specific pattern of expression was found in rat and human tissues. In the human placenta, the transfected and endogenous renin promoters are active, and renin mRNA levels and transfected promoter activity are increased by a calcium ionophore plus cAMP. Cultured pituitary AtT-20 cells transfected with a preprorenin expression vector mimick renal renin release by converting prorenin to renin and releasing renin in response to 8Br-cAMP. Studies with mutant renin genes suggest that the body of renin directs renin to the regulated secretory pathway, and renin glycosylation affects its trafficking. Chinese hamster ovary cells were used to produce recombinant prorenin. Infused prorenin was not converted to renin in monkeys. Renin crystals were used to determine its three-dimensional structure. Renin resembles other aspartyl proteases in the active site and core, but it differs in other regions that probably explain renin's unique substrate specificity. Based on structural and mutational analysis, a model for human prorenin was built that suggests lysine -2 of the prosegment interacts with active site aspartate residues, and that the prosegment inactivation of renin is stabilized by binding of an amino terminal beta strand into a groove on renin.     

The fate of prorenin during granulopoiesis in epithelioid cells. Immunocytochemical experiments with antisera against renin and different portions of the renin prosegment

Comparative immunocytochemical experiments with antisera directed against renin and three synthetical peptides (Pro 1, Pro 2A and Pro 3) covering almost the entire span of human renin prosegment were performed on human kidney tissue. With anti-Pro 1, i.e. the antiserum which recognizes the NH2 terminus of human prorenin, no clear immunolabeling of juxtaglomerular epithelioid cell secretory granules could be obtained. It is therefore concluded that the corresponding portion of human prorenin may be cleaved off in the Golgi complex. After application of anti-Pro 3, the antiserum which recognizes the COOH terminus of the prosegment, only the juvenile secretory granules of epithelioid cells were consistently labeled, whereas, in contrast, some of the intermediate and most of the mature secretory granules were anti-Pro 3-negative. As the immunoreactivity of mature renin increased remarkably from protogranules to mature secretory granules, it is suggested that the cleavage of the COOH terminus of the prosegment, i.e. the activation of renin, takes place in juvenile and intermediate granules during condensation of the enzyme. The immunoreactivity of Pro 2A, corresponding to the middle portion of the prosegment, disappeared in a somewhat earlier stage of granulopoiesis than that of Pro 3. It is therefore concluded that the corresponding segmental cleavage, the result of which is a truncated version of intact prorenin, occurs in the protogranules of epithelioid cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Protein modeling of human prorenin using the molecular dynamics method

To study the activation-inactivation mechanism of the renin zymogen, prorenin, a tertiary structural model of human prorenin was constructed using computer graphics and molecular dynamics calculations, based on the pepsinogen structure. This prorenin model shows that the folded prosegment polypeptide can fit into the substrate binding cleft of the renin moiety. The three positively charged residues, Arg 10, Arg 15, and Arg 20, in the prosegment make salt bridges with Asp 225, Glu 331, and Asp 60, respectively, in renin. Arg 43, which is in the processing site, forms salt bridges with the catalytic residues of Asp 81 and Asp 269. These ionic interactions between the prosegment and the renin may contribute to keeping the prorenin structure as an inactive form.     

Reversible cryoactivation of recombinant human prorenin.

Cleavage of prorenin's prosegment causes irreversible formation of renin. In contrast, renin activity is reversibly exposed when prorenin is acidified to pH 3.3. Nonetheless, acidification of plasma results in irreversible activation of prorenin, because endogenous proteases cleave the prosegment of acid-activated prorenin. Chilling of plasma results in irreversible cryoactivation of prorenin. In this study we investigated whether cryoactivation of purified prorenin is reversible. The intrinsic renin activity of recombinant human prorenin was measured by an enzyme kinetic assay using partially purified human angiotensinogen as substrate. Results are expressed as a percent (mean +/- S.E.) of the maximal activity exposed after limited proteolysis by trypsin. The intrinsic renin activity of two pools (0.3 and 0.06 Goldblatt units/ml) was 1.5% +/- 0.3 and 1.2% +/- 0.6 at 37 degrees C. Activity increased to 19% +/- 0.3 and 26% +/- 0.5 after incubation at 0 degrees C and to 5.4% +/- 0.5 and 2.1% +/- 1.2 at room temperature. Cryoactivation did not occur in buffers containing more than 1 M NaCl. It took 8 min at 37 degrees C or 180 min at room temperature for cryoactivated prorenin to lose half of its intrinsic renin activity. It took 48 and 26 h, respectively, at 0 degree C for the two pools of prorenin at 37 degrees C to regain half of their maximum intrinsic activity at 0 degrees C. A direct immunoradiometric assay that detects active renin but not prorenin was able to detect cryoactivated prorenin. These results show that human prorenin can be reversibly cryoactivated in buffers of low ionic strength and has greater intrinsic activity at room temperature than at 37 degrees C.     

The dominant role of the prosegment of prorenin in determining the rate of activation by acid or trypsin: studies with molecular chimeras

Human prorenin activation by acid or trypsin is faster than rat prorenin by two orders of magnitude. No plausible mechanism exists to explain the difference. Two chimeric mutant prorenins were produced in CHO cells. A chimera, hPro/rRen, composed of human prorenin prosegment and rat active renin segment, was activated as fast as wild-type human prorenin at pH 3.3 and 25 degrees C or by trypsin (1 microg/ml). The other chimera, rPro/hRen, composed of rat prorenin prosegment and human active renin segment, was activated as slowly as wild-type rat prorenin at pH 3.3 and 25 degrees C or by trypsin (50 microg/ml). These results indicate that the rate of activation of prorenin is predominantly determined by the N-terminal pro-sequence. Plausible mechanisms are discussed.     

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.     

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.     

Purification and characterization of human truncated prorenin.

Posttranslational processing of enzymatically inactive prorenin to an active form participates in the control of the activity of a key system involved in blood pressure regulation, growth, and other important functions. The issue is complicated because renin can be produced by a number of tissues throughout the body, in addition to the kidney, but the mechanism by which they process prorenin to renin is unknown and difficult to determine because of the small amounts of renin present. In the juxtaglomerular cell of the kidney, a 43 amino acid prosegment is cleaved from the amino terminus of prorenin to generate renin of molecular weight 44,000 [Do, Y. S., Shinagawa, T., Tam, H., Inagami, T., & Hsueh, W. A. (1987) J. Biol. Chem. 262, 1037-1043]. Using human uterine lining or a recombinant human prorenin system, we employed the same approach as that used in kidney, ammonium sulfate precipitation at pH 3.1 followed by pepstatin and H-77 affinity chromatography or gel filtration, to purify to homogeneity a 45,500-MW totally active renin. The specific activity of the active truncated prorenin was 850 Goldblatt units (GU)/mg of protein for chorion-decidua renin and 946 GU/mg of protein for recombinant renin, both similar to that reported for pure human renal renin. Both forms of renin cross-reacted with an antibody generated against 44,00-MW pure human renal renin and with an antibody generated against a peptide identical to the carboxy-terminal one-third of the prosegment.(ABSTRACT TRUNCATED AT 250 WORDS)     

High-affinity prorenin binding to cardiac man-6-P/IGF-II receptors precedes proteolytic activation to renin

Mannose-6-phosphate (man-6-P)/insulin-like growth factor-II (man-6-P/IgF-II) receptors are involved in the activation of recombinant human prorenin by cardiomyocytes. To investigate the kinetics of this process, the nature of activation, the existence of other prorenin receptors, and binding of native prorenin, neonatal rat cardiomyocytes were incubated with recombinant, renal, or amniotic fluid prorenin with or without man-6-P. Intact and activated prorenin were measured in cell lysates with prosegment- and renin-specific antibodies, respectively. The dissociation constant (K(d)) and maximum number of binding sites (B(max)) for prorenin binding to man-6-P/IGF-II receptors were 0.6 +/- 0.1 nM and 3,840 +/- 510 receptors/myocyte, respectively. The capacity for prorenin internalization was greater than 10 times B(max). Levels of internalized intact prorenin decreased rapidly (half-life = 5 +/- 3 min) indicating proteolytic prosegment removal. Prorenin subdivision into man-6-P-free and man-6-P-containing fractions revealed that only the latter was bound. Cells also bound and activated renal but not amniotic fluid prorenin. We concluded that cardiomyocytes display high-affinity binding of renal but not extrarenal prorenin exclusively via man-6-P/IGF-II receptors. Binding precedes internalization and proteolytic activation to renin thereby supporting the concept of cardiac angiotensin formation by renal prorenin.     

Nonproteolytic "activation" of prorenin by active site-directed renin inhibitors as demonstrated by renin-specific monoclonal antibody.

Incubation of human plasma prorenin (PR), the enzymatically inactive precursor of renin (EC 3.4.23.15), with a number of nonpeptide high-affinity active site-directed renin inhibitors induces a conformational change in PR, which was detected by a monoclonal antibody that reacts with active renin but not with native inactive PR. This conformational change also occurred when inactive PR was activated during exposure to low pH. Nonproteolytically acid-activated PR, and inhibitor-"activated" PR, as well as native PR, were retained on a blue Sepharose column, in contrast to proteolytically activated PR. Kinetic analysis of the activation of plasma prorenin by renin inhibitor (INH) indicated that native plasma contains an open intermediary form of prorenin, PRoi, in which the active site is exposed and which is in rapid equilibrium with the inactive closed form, PRc. PRoi reacts with inhibitor to form a reversible complex, PRoi.INH, which undergoes a conformational change resulting in a tight complex of a modified open form of prorenin, PRo, and the inhibitor, PRoi.INH-->PRo.INH. The PRoi-to-PRo conversion leads to the expression of an epitope on the renin part of the molecule that is recognized by a renin-specific monoclonal antibody. Presumably, PRo corresponds to the enzymatically active form of PR that is formed during exposure to low pH. Thus, it seems that the propeptide of PR interacts with the renin part of the molecule not only at or near the enzyme's active site but also at some distance from the active site. Interference with the first interaction by renin inhibitor leads to destabilization of the propeptide, by which the second interaction is disrupted and the enzyme assumes its active conformation. The results of this study may provide a model for substrate-mediated prorenin activation and increase the likelihood that enzymatically active prorenin is formed in vivo.     

Expression of a deletion mutant of the prosegment of human prorenin in Chinese hamster ovary cells

Expression plasmids encoding native human preporenin and a mutant deleted in its entire prosegment were transfected into Chinese hamster ovary cells. The cells transfected with the expression plasmid of native preporenin secreted exclusively inactive prorenin, while the cells transfected with the mutant secreted the active enzyme. The secreted amount of renin from the latter cells was much lower than that of prorenin from the former ones, although these two enzymes had little difference in specific activity after trypsin activation. These results suggest that the prosegment plays an important role in the secretory process of renin, although the fully active enzyme can be formed in its absence.     

Biochemical and immunological differences between plasma inactive renin from normal and nephrectomized rats.

Using immunological techniques, we have demonstrated that about half the trypsin-activatable renin in normal rat plasma is prorenin, while the other is not, and that inactive renin in nephrectomized rat plasma is not prorenin. In the present study, the trypsin-induced angiotensin I generating activity not related to prorenin from normal rat plasma disappeared after HPLC on G3000SW. HPLC analysis of trypsin-treated plasma showed the generation of active renin by trypsin for normal rat plasma, while it did not for nephrectomized rat plasma. These results indicate that trypsin treatment of crude plasma results in the generation of angiotensin I generating activity not due to prorenin, as well as activation of prorenin. HPLC on G3000SW is a useful tool for the determination of plasma prorenin.     

Renin processing studied by immunogold localization of prorenin and renin in granular juxtaglomerular cells in mice treated with enalapril

Summary Immunogold techniques were used to investigate renin processing within granular juxtaglomerular cells following short-term (6 h and 1 day) and long-term (4 weeks) enalapril treatment in female BALB/c mice. In control animals, renin protein labelling was localized to all types of granules (proto-, polymorphous, intermediate and mature) and to transport vesicles, whilst prorenin labelling was found in all these sites except mature granules, confirming that active renin is localized to mature granules only. Following short-term enalapril treatment, the exocytosis of renin protein from mature granules was increased. Long-term enalapril treatment resulted in increased numbers of transport vesicles and all types of granules, consistent with increased synthesis and storage of renin. More large intermediate granules contained discrete regions labelled for prorenin. Renin protein was exocytosed from individual and multiple granules, whilst prorenin was exocytosed from protoand intermediate granules. It is concluded that under normal conditions prorenin is secreted constitutively by bulk flow from transport vesicles. On the other hand, active renin is secreted regulatively from mature granules. In conditions of intense stimulation (angiotensin-converting enzyme inhibition treatment), increased synthesis of prorenin leads to enhanced secretion of prorenin by both constitutive and regulative pathways. Under these conditions, the conversion of prorenin to active renin is increased, with increased secretion of active renin occurring in a regulative manner. Furthermore, the localization of prorenin to one discrete region of large intermediate granules leads us to conclude, that cleavage of the prosegment of renin occurs with the transition of intermediate to mature granules.     

Immunological evidence that inactive renin is prorenin

Antibody raised to a synthetic dodecapeptide, corresponding to the C-terminal portion of the human renin pro-segment, was tested for its ability to recognize highly purified human inactive or active (mature) renins; immune complexes were detected by precipitation with protein A-Sepharose. Serial antibody dilutions caused identical binding of renal or plasma inactive renins but failed to bind active renin. In contrast, antibody to active renin recognized both active and inactive forms. Reversible acid activation of inactive renin enhanced its binding to the anti-prorenin antibody, whereas irreversible trypsin activation significantly reduced binding. Binding was abolished following prolonged exposure to trypsin or if inactive renin was acidified prior to trypsin treatment. These results indicate that inactive renin shares immunochemical determinants with prorenin; they suggest that acidification alters the conformation of the pro-segment and that trypsin can convert the molecule both to fully mature renin and to intermediate form(s).     

Immunocytochemical localization of prorenin, renin, and cathepsins B, H, and L in juxtaglomerular cells of rat kidney

To examine the correlation of localization of prorenin, renin, and cathepsins B, H, and L, immunocytochemistry was applied to rat renal tissue, using a sequence-specific anti-body (anti-prorenin) that recognizes the COOH terminus of the rat renin prosegment. In serial semi-thin sections, immunodeposits for prorenin, renin, and cathepsins B, H, and L were localized in the same juxtaglomerular (JG) cells. Immunodeposits for renin were detected throughout the cytoplasm of the cells, whereas those for prorenin were detected in the perinuclear region. Immunoreactivity for cathepsin B was stronger than that for cathepsins H and L. By electron microscopy, prorenin was localized in small (immature) granules but not in large mature granules, whereas renin was localized mainly in mature granules. In serial thin sections, prorenin, renin, and cathepsin B were colocalized in the same immature granules containing heterogeneously dense material (intermediate granules). By double immunostaining, co-localization of renin with cathepsins B, H, or L was demonstrated in mature granules. The results suggest the possibility that processing of prorenin to renin occurs in immature granules of rat JG cells, and cathepsin B detected in JG cells may be a major candidate for the maturation of renin.