High molecular weight renin identified in cytosol fractions of mouse renal cortices

In an attempt to confirm that high molecular weight renin was indeed true renin, we used a specific renin antibody and high performance liquid chromatography to determine characteristics of this protein. In mouse renin granules, renin was stored in a low molecular weight form of 38,000 daltons (LMW renin) and this molecular weight remained unchanged with application 20 mM of sodium tetrathionate. In the cytosol fraction of the renal cortex, LMW renin was partially converted to high molecular weight renin (HMW renin) of 65,000 daltons, as determined using tetrathionate. In both the LMW and HMW renin, enzymatic activity was completely neutralized by application of a specific antiserum of renin and an absolute amount of renin was identified by direct radioimmunoassay. The Km values of HMW and LMW renin were similar. Thus, LMW renin probably binds with renin binding substance and forms HMW renin.     

Renin: structural features of active enzyme and inactive precursor

To determine the structural basis for the unique catalytic mechanism of renin and the mechanism of activation of inactive renin, renin and inactive renin were isolated in pure form. The active site of renin consists of two aspartyl residues, two tyrosyl residues, and one arginyl residue, analogous to pepsin and other acid proteases. The complete amino acid sequence of mouse submaxillary gland renin was determined. Of the amino acids, 43% were identical to those in porcine pepsin. Combination of various chromatographic techniques permitted the separation of inactive renin from active renin in human plasma and kidney. Inactive renin of hog kidney was completely purified. Inactive renin consists of a single polypeptide chain and is activated by proteolysis but not by dissociative reagents such as 4 M NaCl or detergent. Thus it was concluded that the inactive renin in these tissues is renin zymogen rather than a renin-inhibitor complex.     

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.     

Investigation of human and rat inactive renin in plasma and kidney.

Under an initial interval of immobilization stress in rats, reciprocal changes of plasma active and inactive renin were observed, suggesting activation of circulating inactive renin. Molecular weight (MW) studies revealed that this activation might proceed via a MW shift from inactive renin with MW of 50,000 to active renin of MW 43,000. In a later interval of stress, under stimulated renin secretion, a lower MW form (38,000) of active renin was released into the circulation. This MW is close to that of active renin (39,000) found in rat kidney renin granules. In renin granules, equilibrated in fractions of 1.6 and 1.7 mol/L sucrose in discontinuous density gradient, trypsin-activatable renin activity formed 36 and 16% of total activity, respectively. In humans, under acute bicycle exercise, a lower MW form (39,000) of active renin was released into the circulation, while the content of inactive renin with MW in the range of 51,000-58,000 and at 47,000 did not substantially change. There was a slight decrease in circulating inactive renin passing through the kidney. The data suggest that, at least in rats, in vivo pathways for activation of inactive renin might exist, other than that proceeding before secretion from renin granules. Under the conditions of increased renin secretion, a lower MW form of active renin is mainly released into the circulation in both rats and humans.     

Human renin activation by protease from the renin granule fraction of the dog kidney cortex

To clarify the possible conversion of prorenin in renin granules where conversion reportedly occurred, we investigated whether the renin granule fraction of the kidney could activate prorenin to the active form. Renin granules were isolated from the dog kidney cortex by discontinuous sucrose density gradient centrifugation. Human active renin was quantified by immunoradiometric assay which could detect only the human active renin but not the inactive human renin or dog renin. Inactive renin from human amniotic fluid was incubated with the subcellular fraction of the dog kidney cortex. The renin granule fraction that showed the highest renin activity stimulated the inactive renin to become the active form. The membrane preparation obtained from the renin granule fraction by freezing and thawing the fraction in low osmolarity retained the activity of renin activation. Other subcellular fractions showed less renin activation. The optimal pH for renin activation by the membrane was pH 5.0 to 6.0. The activation depended on the time of incubation and concentration. The activation was inhibited by N-ethylmaleimide but not by EDTA or serine protease inhibitors. These results suggest that renin is processed by a membrane bound protease in renin granules.     

Physicochemical properties of non-activated and activated renin from human amniotic fluid.

The main physicochemical and enzymic properties of non-activated and activated human amniotic renin (EC 3.4.99.19) were studied in order to clarify the relationships between the two enzymes. Human amniotic renin was activated by dialysis against acidic buffer (pH 3.3), direct acidification or trypsin treatment. All procedures produced similar activation. The physicochemical characteristics of non-activated and activated renin were compared to those of human renal renin. Non-activated renin had a molecular weight of 45,500. A similar molecular weight was obtained by gel eluate activation and by acid treatment of renin prior to gel filtration. Similar isoelectric points were also found for non-activated and activated renin. One major renin peak focused at pH 6.6, whereas no similar renin peak was detected in extracts from normal human kidney. In addition, non-activated and activated renin forms were found to have the same optimal pH, the same Km and the same inhibiting pepstatin concentrations.     

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.     

孕酮对人早孕子宫蜕膜细胞活性肾素分泌的调节

子宫蜕膜是肾素产生的主要部位,肾素包括活性与非活性肾素,活性肾素可使血管紧张素原水解生成血管紧张素Ⅰ,继而调节血管紧张素Ⅱ的表达。实验表明：（１）妊娠早期（孕５～９周）,人子宫蜕膜活性肾素的含量随妊娠周龄增加而升高,孕８周时可达６３３７±１２８４ＡⅠｎｇ／ｇｗｗ·ｈ－１;（２）早孕子宫蜕膜组织活性肾素占总肾素量的１／４;（３）孕酮可调节蜕膜细胞活性肾素的合成与分泌。人早孕子宫蜕膜组织中存在高水平的活性肾素,性类固醇激素可调节蜕膜细胞活性肾素的表达,可以认为,子宫局部肾素血管紧张素系统在妊娠过程中发挥了重要作用。     

Analysis of active renin heterogeneity

Active renin is a heterogeneous enzyme that can be separated into multiple forms with high-resolution isoelectric focusing. The isoelectric heterogeneity may result from differences in glycosylation between the different forms. In order to determine the relationship between active renin heterogeneity and differences in composition or attachment of oligosaccharides, two separate experiments were performed: (i) Tunicamycin, which interferes with normal glycosylation processing, increased the proportion of relatively basic renin forms secreted into the incubation media by rat renal cortical slices. (ii) Endoglycosidase F, which enzymatically removes carbohydrate from some classes of glycoprotein, similarly increased the proportion of relatively basic forms when incubated with active human recombinant renin. In addition, further studies with inhibitors of human renin activity revealed that the heterogeneous renin forms were similarly inhibited by two separate renin inhibitors. These results are consistent with the hypothesis that renin isoelectric heterogeneity is due in part to differences in carbohydrate moiety attachment and that the heterogeneity of renin does not influence access of direct renin inhibitors to the active site of renin.     

Changes of renin isoelectric heterogeneity after acute and chronic stimulation of renin secretion

Changes in the multiple forms of renin secreted or stored in vitro by renal cortical slices were studied in rats made hypertensive with deoxycorticosterone, adrenalectomized rats, and rats fed a high or low salt diet. Renal slices from normal rats were also incubated with angiotensin II, vasopressin, and verapamil. Aliquots of incubation media were subjected to isoelectric focusing, and the six forms of renin were quantified and expressed as a percentage of the total renin activity recovered from the gel. The results showed that chronic and acute stimulation of renin secretion produced a similar modification of the isoelectric focusing profile, consisting of an increased proportion of renin forms with the more acidic isoelectric points. The change in the proportions of the more acidic renin forms was greater with chronic stimulation than that after stimulation with verapamil. However, chronic and acute inhibition or reductions of the rate of renin secretion did not modify the renin profile. We suggest that the progression in the shift of secreted renin forms to those with the more acidic isoelectric points correlates with the intensity or duration of stimulation of renin secretion. These data support the hypothesis that different pools of renin exist and are altered differently by chronic and acute stimulation of renin secretion.     

A targeting sequence for dense secretory granules resides in the active renin protein moiety of human preprorenin

Human renin plays an important role in blood pressure homeostasis and is secreted in a regulated manner from the juxtaglomerular apparatus of the kidney in response to various physiological stimuli. Many aspects of the regulated release of renin (including accurate processing of prorenin to renin, subcellular targeting of renin to dense secretory granules, and regulated release of active renin) can be reproduced in mouse pituitary AtT-20 cells transfected with a human preprorenin expression vector. Using protein engineering, we have attempted to define the roles of various structures in prorenin that affect its production and trafficking to dense core secretory granules, resulting in its activation and regulated secretion. Replacement of the native signal peptide of human preprorenin with that of a constitutively secreted protein (immunoglobulin M) had no apparent effect on either the constitutive secretion of prorenin or the regulated secretion of active renin in transfected AtT-20 cells. Removal of the pro segment resulted in a marked reduction in total renin secretion, but did not prevent renin from entering the regulated secretory pathway. Single or combined mutations in the two glycosylation sites of human renin did not prevent its regulated secretion; however, the complete elimination of glycosylation resulted in a significant increase in the ratio of renin/prorenin secreted by the transfected cells. Thus, these results suggest that 1) at least one of the sequences that target human renin to dense secretory granules lies within the protein moiety of active renin; 2) the presence of the pro segment is important for efficient prorenin and renin production; and 3) glycosylation can quantitatively affect the proportion of active renin secreted.     

Molecular cloning and nucleotide sequence of a human renin cDNA fragment.

We have studied human renin messenger RNA by hybridization with the mouse submaxillary gland (SMG) renin cDNA probe. The human kidney messenger RNA is about 1.6 kilobase (kb) long, similarly to the mouse SMG renin mRNA. A kidney renin cDNA clone of 1.1 kb length was obtained. A comparison of nucleotide sequences of mouse and human cDNA clones reveals conservation of residues involved in catalytic mechanisms and a potential glycosylation site. The human renin molecular probe allowed us to study renin expression in human chorionic tissue. The chorionic and kidney renin messenger RNAs are similar in length. The Southern blot analysis reveals the presence of a single renin gene in human DNA.     

Plasma inactive renin in patients with diabetes mellitus: effects of standing and the relation to serum protease inhibitor

In order to investigate the mechanisms of increased plasma inactive renin in diabetics with microvascular complications, changes in active and inactive renin with the progress of diabetes mellitus were studied, and effects of standing on inactive renin release and the relationship between plasma inactive renin and serum trypsin or protease inhibitors wee also studied. Inactive renin increased with the aggravation of diabetes mellitus, but active renin didn't show significant changes with the aggravation of diabetes mellitus. Active renin was significantly increased both in the healthy subjects and in the diabetic patients when they were in an upright position, but no significant change was observed in inactive renin. Serum trypsin in diabetics with retinopathy and nephropathy was lower than that in those with no clinical sign of microangiopathy, but the correlation between plasma inactive renin and serum trypsin was not significant. There was a significant correlation between plasma inactive renin and serum alpha 2-globulin (r = 0.52, p less than 0.01). Although plasma inactive renin was not significantly correlated with serum alpha 1-antitrypsin, there was a significant correlation between plasma inactive renin and serum alpha 2-macroglobulin (r = 0.61, p less than 0.01). These results show that the increased levels of plasma inactive renin observed with the development of diabetic microangiopathy are probably related to the altered plasma protein metabolism observed in patients with diabetes mellitus. However, it is not clear whether this altered protein metabolism is related to the conversion from inactive to active renin.     

Observations on the renal processing and sorting of prorenin.

Human prorenin is the biosynthetic precursor of renin. In general, prorenin is enzymatically inactive until it is converted to renin. The kidney is the major source of renin in the circulation, and is also an important source of circulating prorenin. The mechanisms of prorenin sorting and processing to renin in the juxtaglomerular cell may be a determinant of renal renin production. Therefore, our studies have focused on renal enzymes involved in "limited proteolysis" of prorenin to renin and on the morphology of prorenin sorting in the human juxtaglomerular cell.     

Purification of high molecular weight (HMW) renin from porcine kidney and direct evidence that the HMW renin is a complex of renin with renin binding protein (RnBP)

The high molecular weight (HMW) renin was purified from porcine kidney by a procedure involving extraction with a buffer system containing protease inhibitors, ammonium sulfate fractionation, pepstatin-aminohexyl-Sepharose 4B column chromatography, gel filtration on Ultrogel AcA 44 and aminohexyl-Sepharose 4B column chromatography. The resulting preparation showed a single band on isoelectric focusing, exhibiting an isoelectric point at pH 5.25, and was stable on storage at -80 degrees C for 4 months. The specific activity was 3.97 mg of angiotensin I formed/mg of protein per h at 37 degrees C and at pH 6.5 with porcine angiotensinogen as the substrate. When the HMW renin was exposed to acid, renin activity increased by about 5-fold and the free form of fully active renin was recovered from the acidified HMW renin, leaving an insoluble aggregate of protein. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the HMW renin showed two protein bands, of which one was identified as renin from the electrophoretic mobility and the other was the protein, assigned as renin binding protein (RnBP), that was insolubilized by acidification. The purified HMW renin is a complex of renin with RnBP, and the molecular weights of RnBP and renin in the HMW renin were estimated to be 39,000 and 32,000, respectively, by gel permeation liquid chromatography in 6 M guanidine-HCl. A modified rapid method for purification of renin is also presented.     

The mouse Rn locus: S allele of the renin regulator gene results from a single structural gene duplication.

Inbred strains of mice have been divided into two distinct phenotypic groups having different levels of renin activity regulated by androgen in the submaxillary gland (SMG). Strains carrying the Rnrs allele of the renin gene regulator, located on chromosome 1, have a high level of renin activity; strains carrying the Rnrb allele have a low level of renin activity. The level of SMG renin activity correlates with the level of renin mRNA. We have analyzed, by Southern blot hybridization, the organization of renin genes in both strains. Strains carrying the Rnrb allele, such as BALB/c or C57 Bl/6, or CH3 mice, have one renin structural gene per haploid genome, while those having the Rnrs allele, such as AKR or Swiss mice, have two renin genes. We have also identified renin genes in mice belonging to different biochemical groups: Mus spretus has one renin gene while M. vrania and M. musculus brevirostris have two renin genes.     

Correlation between juxtaglomerular index, kidney renin content and plasma renin concentration in the rat.

The correlation between juxtaglomerular index, kidney renin content, and plasma renin concentration has been investigated in rats. The results indicate that renin exists in two forms. When determining the renin content of the kidney, the renin actually present in the modified smooth muscle cells of the juxtaglomerular apparatus is measured; this is called bound renin. The amount of bound renin is derived from the total of granular and subgranular renin in the modified smooth muscle cells. Since JGI and KRCont show a significant positive correlation in untreated adult rats, it is assumed that in such animals the ratio of granular and subgranular renin is constant. Since no correlation could be demonstrated between kidney renin content and PRC in untreated adult rats, and JGI and KRCont did not change parallel with the increase of PRC in numerous experimental conditions, it is assumed that part of the renin synthetized in the JG cells is secreted directly, without passing the process of condensation into membrane bound granules. This mobile renin does not significantly affect the renin content and the JGI of the kidney. Under physiological circumstances, most of the produced renin seems to mature to granules in the modified smooth muscle cells before being secreted. When renin production and release increased, maturation to granules may be inhibited, a significant part of the produced renin released by direct secretion, and the subgranular, immature renin may also be secreted.