Evidence for beta-adrenergic regulation of renal and extrarenal plasma prorenin and renin in dogs

Beta blockade with propranolol for 7 days in healthy normotensive dogs produced a sustained 20-25% drop in heart rate, but only a transient suppression of blood pressure. Plasma renin activity and prorenin were also suppressed transiently, suggesting that both are under beta-receptor regulation. Bilateral nephrectomy (2NX) was followed by rapid clearance of renin from the circulation, at a rate that was minimally influenced by beta blockade. In contrast, the plasma prorenin level rose markedly to a peak within an hour after surgery, leveled off during the next 24 hr, dropped almost toward the pre-2NX baseline by 48 hr, but proceeded to rise again between 48 and 120 hr. Propranolol administration before and during the 2NX period reduced the detectable prorenin, suggesting that its extrarenal source is under beta-adrenergic regulation. The rapid increment of prorenin after 2NX suggests that extrarenal prorenin may have constituted part of the total plasma prorenin before 2NX, and/or had developed sufficiently quickly afterwards to replace and exceed the disappearing renal prorenin. Any fresh increment beyond 48 hr could presumably have been only extrarenal. These observations suggest the existence of a rich beta-regulated extrarenal source of prorenin capable of rapidly supplying the plasma. However, no renin-angiotesin was apparently produced from this prorenin in the nephrectomized state, implying the lack of renal "convertase," without which the prorenin convertase mechanism as a whole was rendered ineffective. The source of the extrarenal prorenin and the identity of the renal convertase remain to be established.     

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

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

Renin 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.     

Extrarenal production and activation of human plasma prorenin: the evidence after venous occlusion

Venous occlusion of the left arm in consenting men was induced for 10 or 20 min to stimulate local fibrinolytic and other proteases, thereby favouring the conversion of prorenin to renin. Using the two techniques cryoactivation and tryptic activation, we found that plasma active renin increased significantly after such occlusion (10 and 20 min) while prorenin rose more convincingly and progressively from 10 to 20 min. The renin increase can be partially attributed to hemoconcentration, but in vivo production and (or) local activation of prorenin to renin cannot be excluded. The prorenin rise can apparently be attributed to local extrarenal production, and not to hemoconcentration or influx, since it was progressive and neither prorenin nor renin levels were raised at all in blood circulating outside the occluded arm. Prekallikrein and plasminogen levels were elevated in occlusion plasmas, but responsibility of these enzyme systems for any enhanced activation of prorenin was not established. The trypsin inhibitory capacity was also elevated, increasing the requirement of trypsin to achieve optimal activation of prorenin, but not changing the prorenin estimate itself. Thus, prorenin appears to be released extrarenally, within the vasculature of an occluded arm, while in vitro evidence suggests that the mechanisms for its activation were stimulated. The importance of such extrarenal production and activation of prorenin for renin production under other physiological or pathophysiological conditions remains to be determined.     

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.     

Correlation of 24-hour fluctuations in renin granules of juxtaglomerular cells and in renin and angiotensinogen in blood plasma of the rat

Summary Subcellular structures of juxtaglomerular (JG) cells in the rat kidney were morphometrically examined at six evenly spaced times over 24 h. Plasma renin activities and angiotensinogen concentrations were also measured at these times. The cell volumes were larger at 20.00 h and 04.00 h than at 00.00 h, whereas the nuclear volumes peaked at 20.00 h and 08.00 h, decreasing at 00.00 h and 16.00 h. The volume and surface densities of renin granules and their individual volumes and surface areas peaked at 16.00 h and 00.00 h, decreasing at 20.00 h and 08.00 h, whereas their numerical densities peaked at 20.00 h, decreasing at 12.00 h. The surface densities of the rough endoplasmic reticulum (rER) peaked at 20.00 h, decreasing at other times, except at 08.00 h, when rER volume and surface density were relatively high. The plasma renin activity was maximal at 20.00 h, whereas it was minimal at 08.00 h. The variation in plasma angiotensinogen concentrations was inversely correlated with that in plasma renin activities. These results suggest that JG cells actively synthesize and release renin during the dark period, especially at 20.00 h, whereas during the light period they gradually synthesize renin and produce the granules, most of which may be stored in the cells during this period.     

The influence of plasma renin substrate on the relationship between plasma renin activity and plasma renin concentration. An experimental study in hyper- and hypothyroid rats

The effects of endogenous Plasma Renin Substrate (PRS) on the relationship between Plasma Renin Activity (PRA) and the Plasma Renin Concentration (PRC) have been studied in hyperthyroid rats, by I-triiodothyronine (T3) administration and in hypothyroid rats, by propylthiouracil (PTU) treatment, to clarify if PRA changes are an adequate index for evaluating the renin-angiotensin changes during the alterations in the thyroid function. Although in experimental situations studied the induced variation on PRC explains a 62 per cent of the changes in PRA, finding a good lineal correlation between both parameters (r = 0.79, P less than 0.001). Not only does PRS play an important role on the kinetic of the enzymatic reaction but also explains jointly with PRC up to a 85 per cent of PRA alterations. PRS changes become more important during thyrotoxicosis where they limit in a higher degree the velocity of reaction due to inverse relationship between PRC and PRS (r = 0.74, P less than 0.001).     

Binding of renin and angiotensinogen to macromolecules in plasma studied by sedimentation equilibrium centrifugation

Plasma from normal and aggressive mice was subjected to sedimentation equilibrium centrifugation in an air-driven centrifuge. The aim was to study the apparent molecular weight of renin and angiotensinogen in undiluted plasma. Both renin and angiotensinogen appeared heterogeneous with respect to molecular size, suggesting binding to plasma macromolecules. Subsequent high pressure liquid chromatography, using a size exclusion column, demonstrated molecular homogeneity and molecular weights as found in noncentrifuged plasma, indicating that the binding is easily reversible. It is concluded that renin and angiotensinogen in undiluted and unfractionated plasma are weakly bound to plasma macromolecules. This may reduce their activity and to some extent explain the previously observed apparent inhibition of the enzymatic activity.     

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].     

Control of renal and extrarenal salt and water excretion by plasma angiotensin II in the kelp gull (Larus dominicanus)

Summary The osmoregulatory effects of intravenously (i.v.) administered angiotensin II (AII) at dose rates of 5, 15 and 45 ng · kg^–1 · min^–1 were examined in kelp gulls utilizing salt glands and/or kidneys as excretory organs.In birds given i.v. infusion of 1200 mOsmolal NaCl at 0.3 ml · min^–1 and utilizing only the salt glands to excrete the load, infusion of AII for 30 min consistently inhibited salt gland function in a dose-dependent manner.In birds given i.v. infusion of 500 mOsmolal NaCl at 0.72 ml · min^–1 and utilizing both salt glands and kidneys to excrete the load, each dose of AII given for 2 h inhibited salt gland function but stimulated the kidney, so that the overall outputs of salt and water were enhanced and showed significant (2P<0.01) positive correlations with plasma AII.In birds given i.v. infusion of 200 mOsmolal glucose at 0.5 ml · min^–1 and utilizing only the kidneys to excrete the load, low doses of AII (5 and 15 ng · kg^–1 · min^–1) caused renal salt and water retention, whereas a high dose (45 ng · kg^–1 · min^–1) stimulated salt and water output.The actions of plasma AII in kelp gulls support the concept that this hormone plays a vital role in avian osmoregulation, having effects on both salt gland and kidney function. Elevation of plasma AII consistently inhibits actively secreting salt glands, but its effects upon renal excretion depend primarily on the osmotic status as well as on the plasma AII concentration. In conditions of salt and volume loading doses of AII stimulate sodium and water excretion. With salt and volume depletion, the action of AII is bi-phasic with low doses promoting renal sodium and water retention but high circulating levels causing natriuresis and diuresis.     

Bovine ovarian cells have (pro)renin receptors and prorenin induces resumption of meiosis in vitro

The discovery of a receptor that binds prorenin and renin in human endothelial and mesangial cells highlights the possible effect of renin-independent prorenin in the resumption of meiosis in oocytes that was postulated in the 1980s.This study aimed to identify the (pro)renin receptor in the ovary and to assess the effect of prorenin on meiotic resumption. The (pro)renin receptor protein was detected in bovine cumulus-oocyte complexes, theca cells, granulosa cells, and in the corpus luteum. Abundant (pro)renin receptor messenger ribonucleic acid (mRNA) was detected in the oocytes and cumulus cells, while prorenin mRNA was identified in the cumulus cells only. Prorenin at concentrations of 10⁻¹⁰, 10⁻⁹, and 10⁻⁸ M incubated with oocytes co-cultured with follicular hemisections for 15 h caused the resumption of oocyte meiosis. Aliskiren, which inhibits free renin and receptor-bound renin/prorenin, at concentrations of 10⁻⁷, 10⁻⁵, and 10⁻³ M blocked this effect (P < 0.05). To determine the involvement of angiotensin II in prorenin-induced meiosis resumption, cumulus-oocyte complexes and follicular hemisections were treated with prorenin and with angiotensin II or saralasin (angiotensin II antagonist). Prorenin induced the resumption of meiosis independently of angiotensin II. Furthermore, cumulus-oocyte complexes cultured with forskolin (200 μM) and treated with prorenin and aliskiren did not exhibit a prorenin-induced resumption of meiosis (P < 0.05). Only the oocytes’ cyclic adenosine monophosphate levels seemed to be regulated by prorenin and/or forskolin treatment after incubation for 6 h. To the best of our knowledge, this is the first study to identify the (pro)renin receptor in ovarian cells and to demonstrate the independent role of prorenin in the resumption of oocyte meiosis in cattle.     

Renin substrate in plasma of various mammalian species: electrophoresis on polyacrylamide gel.

The plasma of eight different species was subjected to electrophoresis on polyacrylamide gel, and the position of renin substrate was determined. There are considerable differences in the electrophoretic mobility of the renin substrates tested. Sheep substrate shows the slowest migration and mouse substrate the most rapid. The species tested appear to fall into two groups: slow-moving substrates occuring in the plasmas of sheep, cow, pig, and rabbit and fast moving substrates in man, dog, rat, and mouse. In most species only a single peak of renin substrate appeared, but in man and dog a minor peak was often observed in addition to the prominent major one. The classification of human renin substrate as an alpha-2-globulin is questioned.     

Isolation of completely inactive plasma prorenin and its activation by kallikreins. A possible new link between renin and kallikrein.

Existing views on prorenin are conflicting and its physiological activation mechanism is not clear. In an attempt to obtain clearcut views on the molecular properties of prorenin in human plasma, the renin zymogen (prorenin) was separated from active renin by two steps of affinity chromatography and it was demonstrated that prorenin is a completely inactivate zymogen contrary to the existing information. Inactive prorenin has an apparent molecular of 56,000 contrary to 46,000-43,000 of partially active prorenin. Isolated and acid-treated human prorenin was shown to be activated by kallikreins from human urine and plasma. This activation was completely blocked by Trasylol. Hog pancreatic kallikrein also activated human prorenin. The kallikrein mediated activation of prorenin indicates the existence of a new link between the vasoconstricting renin-angiotensin system and the vasodilating kallikreinkinin system.     

Changes of plasma renin and renal renin concentration in HgCl2 induced acute renal failure in rats.

Acute renal failure (ARF) was produced by the single intraperitoneal injection of 3 mg/kg mercuric chloride (HgCl2) in male Wistar rats. Immediately after, and in the 1st, 3rd, 6th, 24th and 48th hour after HgCl2 administration the following variables were monitored: plasma renin concentration (PRC), renal renin concentration (RRC) blood-urea nitrogen (BUN), plasma sodium (PNa), plasma creatinine (PCr) concentrations and haematocrit (Ht). Haematocrit and PNa increased during the first hour and returned to the control value in the 3rd hour. Thereafter, their level remained unchanged. Plasma renin concentration increased threefold during the first six hours after the HgCl2 injection, however, by the 48th hour it returned to the control value. In the first 24 hours of ARF, RRC remained unchanged. However, by the 48th hour its level increased four times the control value. After mercury injection BUN and PCr increased progressively. We were not able to establish any significant correlation between the changes of PRC and BUN. A gradual increase of RRC was observed in the course of ARF.     

Expression of renin and angiotensinogen genes in the human placental tissues

The expression of renin and angiotensinogen genes in the human placenta and related tissues has been examined by RNA blot hybridization analysis with specific human complementary DNA (cDNA) probes. Renin mRNA was detectable in the chorion throughout pregnancy and in the hydatidiform moles, but not in the decidua, amnion or myometrium. The relative concentration of renin mRNA in the chorion was at the highest level in early pregnancy and decreased thereafter, while the total amount contained in the whole placenta was at the lowest level in early pregnancy, and increased thereafter, reaching at term about one-sixth of the total renin mRNA in the kidney. Hydatidiform moles had an even higher concentration of renin mRNA than the early chorion. There was no significant difference in either the relative concentration or the total renin mRNA content in the placentae from 4 normal and 4 toxemic pregnancies. Angiotensinogen mRNA was undetectable in any of the placental tissues, hydatidiform moles or myometrium. These results show that renin is synthesized in the placenta, possibly to play some physiological role locally by utilizing angiotensinogen which is abundantly present in the maternal systemic circulation.