Plasma angiotensin in binephrectomised mice.

Plasma renin-angiotensin parameters were measured before and 24h after binephrectomy (BNx) in male Swiss (Ren-1, Ren-2) and BALB/c (Ren-1) female mice (representing the extremes of differences in tissue renin expression), together with in vivo inhibition of residual renin. Plasma Ang II increased from 18.9 +/- 7.3 to 48.1 +/- 16.9 pg/ml after BNx in conscious Swiss mice (+/- sd, p < 0.001, n = 11&12), renin activity (PRA) increased 2.76 times, angiotensinogen (aogen) increased 4.57 times and renin concentration (PRC) fell by 65%. In BALB/c, Ang II+Ang III decreased slightly (56.6 +/- 11 to 37.7 +/- 14.7, p < 0.05, n = 5&6), PRA was unchanged, aogen increased 12 times and PRC fell by 93%. Plasma ACE decreased by 26% and 28% respectively. Aogen did not increase further when post BNx plasma renin was inhibited with antirenin in vivo during 20h. Thus plasma angiotensin is maintained or considerably increased following BNx in mice and the change is consistent with first-order kinetics with respect to renin and aogen in the circulation. Whether the strain carries one or two renin genes, high renal and extrarenal renin production combined with a low plasma aogen phenotype yields resting angiotensin levels similar to other mammals. A kinetic regulation of aogen levels is proposed in mice wherein Ang II production is limited by low substrate concentration thereby ensuring normotension in the face of abundant extrarenal renin secretion.

Effects of thyroid hormones on urinary and renal kallikreins.

The effects of thyroid hormones on the urinary excretion of kallikrein and on renal kallikrein were studied in rats. Total and active urinary kallikrein was decreased after thyroidectomy, but renal kallikrein content remained unchanged. Diuresis increased, and kidney weight and plasma aldosterone concentration decreased. Treatment with 3,5,3'-triiodo-L-thyronine restored the urinary kallikrein in thyroidectomized rats to normal and increased it in intact rats. It also produced increases in kidney weight and plasma aldosterone and a decrease in diuresis. The effect of thyroid hormones on the urinary kallikrein response to mineralocorticoids was also tested. Deoxycorticosterone acetate increased urinary kallikrein more in normal than in thyroidectomized rats. These results suggest that thyroidectomy decreases renal kallikrein synthesis and lowers the turnover rate of the enzyme, changes not detectable by a single measurement of the renal kallikrein content but reflected by an alteration in the urinary excretion of the enzyme. Thyroid hormones participate in the control of urinary kallikrein. This effect, however, is probably indirect and may be mediated by mineralocorticoids since thyroid function affects both the plasma level of aldosterone, which is known to influence renal kallikrein, and the kallikrein response to exogenous mineralocorticoids.

Hypertension in Dahl salt-sensitive rats: biochemical and immunohistochemical studies.

1. The renin-angiotensin and kinin-kallikrein systems of Dahl salt-sensitive and salt-resistant rats fed diets with different salt contents were analysed using biochemical and immunocytochemical techniques. 2. Blood pressure increased by 45% in salt-sensitive rats only, after 4 weeks on a high-salt diet. The plasma renin activity and plasma angiotensin II concentration remained at the same levels in salt-sensitive rats on the high-salt diet as on the normal salt diet, whereas the plasma renin activity and plasma angiotensin II concentration of salt-resistant rats fed the high-salt diet were lower. The plasma renin activity and the plasma angiotensin II concentration were elevated in both salt-resistant and salt-sensitive rats fed the salt-deficient diet but were much more elevated in salt-resistant than in salt-sensitive rats. 3. The kidney immunocytochemical data paralleled the data on plasma parameters. Salt-sensitive rats had fewer renin positive juxtaglomerular apparatuses than salt-resistant rats on the normal diet, and the increase on the sodium-deficient diet was also smaller in salt-sensitive rats. Salt-sensitive rats fed the high-salt diet and the standard diet had almost no angiotensin II immunoreactivity compared with the salt-resistant rats on the same diets. 4. The total renal kallikrein content of salt-sensitive rats was lower than that of salt-resistant rats on all three diets, as was the amount of kallikrein excreted in the urine on the standard and the high-salt diets. The differences resulted from a reduction in active kallikrein. The increase in kallikrein in salt-sensitive and salt-resistant rats on the salt-deficient diet was not significantly different. 5. There were similar changes in immunopositive kallikrein in the kidneys of salt-sensitive and salt-resistant rats with diet, with a large increase in kallikrein biosynthesis on the low-salt diet. The plasma concentration of high-molecular-mass kininogen was not significantly different in salt-sensitive and salt-resistant rats, but there was a significant increase in T-kininogen in salt-sensitive rats fed the high-salt diet. 6. In conclusion, the absence of decreases in the plasma renin activity and the plasma angiotensin II concentration in salt-sensitive rats fed the high-salt diet might partially explain the increase in blood pressure.

Biochemical and physiological studies on two T-kininogen species using monoclonal antibodies.

Rat T-kininogens were characterized in plasma, urine and liver slice incubation medium in different physiological conditions using monoclonal antibodies that allow to distinguish between the two forms of T-kininogen. T-kininogen purified from the plasma of both normal and inflamed Wistar and Sprague-Dawley rats was found to contain the two forms of T-kininogen, TI and TII, separated by non-denaturing polyacrylamide gel electrophoresis. The two forms were also found in the plasma of several strains of normal and inflamed rats, except in the plasma of the Buffalo rat which contained only TII-kininogen. The two forms of T-kininogen were also found in the media in which liver slices from inflamed and non-inflamed wistar rats had been incubated. The urine T-kininogen of normal rats was chiefly TI-kininogen, but both forms were found in the urine of inflamed rats. T-kininogen in the plasma of normal and inflamed rats was further characterized by chromatography on Con A-Ultrogel. In normal plasma, we observed a ratio of non-retained to retained T-kininogen of 0.41. The retained T-kininogen was eluted as two peaks, one eluted with 45 mM and the other with 120 mM alpha-methyl-D-glucoside. The ratio of non-adsorbed to adsorbed T-kininogen in inflamed Wistar rat plasma was 1.40 and the retained material was almost exclusively in a single peak, which eluted with 50 mM alpha-methyl-D-glucoside. The non-adsorbed and adsorbed fractions contained both forms of T-kininogen, but the protein bands in the non-retained fraction had greater mobilities on non-denaturing PAGE. SDS-PAGE analysis of T-kininogen deglycosylated by N-glycosidase F showed a major band with a molecular mass of 50 kDa, whereas the molecular mass of the native form was 66 kDa. We concluded that both forms of T-kininogen exist in the non-inflamed and the inflamed rat plasma, except for the Buffalo rat, and that T-kininogen displays a different chromatographic pattern on Con A-Ultrogel after inflammation suggesting altered glycosylation.

Protein products of the rat kallikrein gene family. Substrate specificities of kallikrein rK2 (tonin) and kallikrein rK9.

Two closely related kallikrein-like proteinases having little activity toward the standard synthetic amide substrates of tissue kallikreins were isolated from the rat submandibular gland. They were found to be the protein products of the rKlk2 (tonin) and the rKlk9 genes by amino acid sequence analysis (nomenclature of the genes and proteins of the kallikrein family is according to the proposal of the discussion panel from the participants of the KININ '91 meeting held Sept. 8-14, 1991, in Munich, Germany). These two proteinases of similar structure also had very similar physicochemical properties. They differed from other kallikrein-related proteinases in having high pHi values of 6.20 (rK2) and 6.85 (rK9). Kallikrein rK2 was purified as a single peptide chain, whereas rK9 appeared as a two-chain protein after reduction. Their enzymatic properties were also very similar and differed significantly from those of other rat kallikrein-related proteinases. Unlike the five other kallikrein-related proteinases we have purified so far, kallikrein rK9 was not inhibited by aprotinin. rK9 also differed from rK2 by its tissue localization. The prostate gland contained only rK9 where it was the major kallikrein-like component. The amino acids preferentially accommodated by the proteinase S3 to S2' subsites were identified using synthetic amide and protein substrates. Unlike other kallikrein-related proteinases, rK2 had a prevalent chymotrypsin-like specificity, whereas rK9 had both chymotrypsin-like and trypsin-like properties. Both rK2 and rK9 preferred a prolyl residue in position P2 of the substrate and did not accommodate bulky and hydrophobic residues at that position, as did most of the other kallikrein-related proteinases. This P2-proline-directed specificity is necessary for processing the precursors of several biologically active peptides. Subsites accommodating residues COOH-terminal to the scissile bond were also important in determining the overall substrate specificity of these proteinases. rK2 and rK9 both showed a preference for hydrophobic residues in P2'. Other subsites upstream of the S3 subsite were found to intervene in substrate binding and hydrolysis. The restricted specificity of rK2 and rK9 is consistent with the presence of an extended substrate binding site, and hence with a processing enzyme function. Their P1 specificities enabled both proteinases to release angiotensin II from angiotensinogen and from angiotensinogen I, but rK9 was at least 100 times less active than rK2 on both substrates. The substrate specificities of rK2 and rK9 were correlated with key amino acids defining their substrate binding site.(ABSTRACT TRUNCATED AT 400 WORDS)

Immunological characterization of rat kininogens with monoclonal antibodies to T-kininogen. Distinction between the different domains of T-kininogen and the multiple rat kininogens.

A panel of 16 monoclonal antibodies (mAb) were produced against rat T-kininogen to characterize this family of proteins. These mAbs bound 125I-T-kininogen by radioimmunoassay as well as reacting strongly with immobilized T-kininogen in an enzyme-linked immunosorbent assay (ELISA). The reactivity of these antibodies with proteolytic fragments of T-kininogen demonstrated the recognition of several different epitopes. One antibody was specific for the domain 1 of the heavy chain and/or the light chain, twelve antibodies were specific for domain 2 and three antibodies were specific for domain 3. All monoclonal antibodies recognized the two forms of T-kininogen encoded by the two different T-kininogen genes, TI and TII kininogen, except antibody TK 16-3.1 which uniquely reacted with TII kininogen. Two antibodies recognizing domain 2 cross-reacted with the high-molecular-mass kininogen (H-kininogen), whereas all the other monoclonal antibodies were specific to T-kininogen and did not recognize the heavy chain of H-kininogen. None of the antibodies tested altered the thiol protease inhibitory activity of T-kininogen, its partial proteolysis by rat mast cell chymase or the hydrolysis of H-kininogen by rat urinary kallikrein. The use of these antibodies in the development of sensitive ELISA to measure T-kininogen levels in plasma, urine, liver microsomes and hepatocytes is described. Two different forms of T-kininogen were distinguished by these monoclonal antibodies in Western blotting using rat plasma. The localization of T-kininogen was defined using these monoclonal antibodies by immunohistochemistry in rat liver hepatocytes and rat kidney.

Immunolocalization of high molecular weight kininogen (HKg) and T kininogen (TKg) in the rat hypothalamus.

Specific HKg immunostaining detected with antiserum against the light chain (LC) of HKg was restricted to SRIF neurons of the hypothalamic periventricular area projecting to median eminence (ME). Heavy chain (HC) immunoreactivity related to HKg and/or low molecular weight kininogen (LKg) was found in some other hypothalamic territories. Specific TKg was mainly associated with vasopressin in neurons of suprachiasmatic (SCN), supraoptic (SON) and paraventricular (PVN) nuclei. By direct RIA, hypothalamus was found to contain the highest level of TKg (10ng/mg protein) and after trypsin hydrolysis and HPLC separation of kinins, 10.3 pg BK and 7.3 pg T-kinin/mg protein.

Effects of growth hormone and estrogen on rat angiotensinogen quantified by an enzyme linked immunosorbent assay.

An enzyme linked immunosorbent assay for rat angiotensinogen was developed based on one monoclonal antibody with high affinity for angiotensinogen and des-angiotensin 1-angiotensinogen and rabbit polyclonal antibodies for angiotensinogen was developed. Serum levels of angiotensinogen were lower in female than in male rats but increased significantly after hypophysectomy. Estrogen substitution after hypophysectomy had no further stimulatory or inhibitory influence. In hypophysectomized animals continuous and intermittent growth hormone administration had clearly different effects. The results indicate that the sexually dimorphic secretion of growth hormone is involved in the regulation of circulating angiotensinogen concentrations in the rat.

Immunocytochemical localization of albumin, transferrin, angiotensinogen and kininogens during the initial stages of the rat liver differentiation.

Rat albumin, transferrin, angiotensinogen, T kininogen (TKg) and high molecular weight kininogen (HKg) gene expression was examined immunocytochemically in embryonic and fetal livers. All these plasmatic proteins, angiotensinogen excepted, are detected as early as day 11 of gestation in intestine epithelial cells and embryonic hepatocytes. Angiotensinogen becomes expressible only at day 13 of gestation. During the early fetal period, the protein immunostaining increases strikingly in parallel with the hepatocyte differentiation. Albumin and transferrin are highly expressed comparatively to kininogens and angiotensinogen. For the first time, specific HKg is demonstrated in the rat liver.

Thyroid hormone receptors and stimulation of angiotensinogen production in HepG2 cells.

Binding characteristics and effects of 3,5,-3'-triiodo-L-thyronine (T3) on angiotensinogen production in HepG2 were studied in serum-free medium. Binding was performed on intact cells and on partially purified isolated nuclei using [125I]T3. Scatchard plots revealed one class of high affinity binding sites with a Kd of approximately 80 pmol/liter. Calculation of maximum binding showed that HepG2 possess approximately 1000 binding sites per cell. Unlabeled T3 and T4 competed for binding sites on intact HepG2 with 50% inhibition of [125I] T3 binding at approximately 3.0 and 38.0 pmol/liter, respectively. The HepG2 showed a dose-dependent increase in angiotensinogen production in serum-free medium which was maximal at 10(-5) mol/liter (two-fold increase/10(6) cells/24 h) and had an EC50 of approximately 5.0 x 10(-8) mol/liter. T3 also produced after 24 h a dose-dependent increase in DNA highly correlated with T3 applied (r = 0.88, P less than 0.01). In conclusion, this study shows that HepG2 possess specific high affinity binding sites for T3 and that T3 stimulates angiotensinogen production and DNA synthesis in these cells.

The kallikrein-kinin system in the rat hypothalamus. Immunohistochemical localization of high molecular weight kininogen and T kininogen in different neuronal systems.

High molecular weight kininogen (HKg) and T kininogen (TKg) were detected and localized by immunocytochemistry in adult rat hypothalamus. In addition, kininogens were measured by their direct radioimmunoassay (RIA) or by indirect estimation of kinins released after trypsin hydrolysis and high pressure liquid chromatography (HPLC) separation of bradykinin (BK) and T kinin. A specific HKg immunoreactivity demonstrated with antibodies directed against the light chain (LC) of HKg was colocated with SRIF in neurons of hypothalamic periventricular area (PVA) projecting to external zone (ZE) of median eminence (ME). Heavy chain (HC) immunoreactivity which could be related to HKg or to low molecular weight kininogen (LKg) was detected in some other systems: i) parvocellular neurons of suprachiasmatic (SCN) and arcuate nuclei containing SRIF, ii) magnocellular neurons (mostly oxytocinergic) of paraventricular (PVN) and supraoptic (SON) nuclei, iii) neurons of dorsomedian and lateral hypothalamic areas. TKg immunostaining was restricted to magnocellular neurons of PVN, SON, accessory nuclei (mostly vasopressinergic) and to parvocellular neurons of SCN (vasopressinergic). TKg projections are directed towards the internal zone (ZI) of ME, but very few immunoreactive terminals are detectable in neurohypophysis. TKg staining parallels with vasopressin during water deprivation, and is undetectable in homozygous Brattleboro rats. In some magnocellular neurons, TKg and HC (related to HKg or LKg) are coexpressed. TKg, was also detected in hypothalamus and cerebellum extracts by direct RIA, and BK and T kinin were identified after trypsin hydrolysis. HKg and LKg can act as precursor of BK which can play a physiological role as releasing factor, neuromodulator--neurotransmitter,--or modulator of local microcirculation in hypothalamus. The three kininogens are also potent thiolprotease inhibitors which could modulate both the maturation processes of peptidic hormones and their inactivation and catabolism.

Differential distribution of immunoreactive angiotensinogen in the hind-brain and spinal cord of neonatal and adult rats.

The present communication deals with the cytochemical localization of angiotensinogen (ATG) immunoactivity in the hind-brain and spinal cord of neonatal (1-day-old) and adult (3-month-old pregnant) female rats. In the neonatal hind-brain, the immunoreactive cells were more numerous than in that of adult rats. In the adult rat hind-brain, the number of ATG-positive cells was quite limited in each nucleus. Further, in some nuclei, only neurons or neuroglia were positive, while in others the immunoactivity was observed in both the components. Spinal cords of neonatal rats showed a few undifferentiated ATG-positive cells in the grey matter. Contrary to this, the spinal cord of adult animals contained numerous immunoreactive glial cells in the grey matter, fasciculus cuneatus and fasciculus gracilis. Immunoactivity in the neurons was localized in the Nissl bodies.

Angiotensinogen in the developing rat fetal hindbrain and spinal cord from 18th to 20th day of gestation: an immunocytochemical study.

We have detected angiotensinogen immunoreactivity in the hindbrain and in the spinal cord of rat fetuses during the 18th to 20th day of gestation. In the 18th-day fetus, a few immunoreactive angiotensinogen cells are localized in precise brain areas. Their number sharply increase during the 19th and 20th day gestation period when there is an active cell differentiation and cell growth. These observations suggest a role of the renin-angiotensinogen system during cell growth and cell differentiation.

Effect of sex hormones on plasma T-kininogen in the rat.

The influence of sex hormones on rat plasma T-kininogen concentration was examined. The level of T-kininogen in the post-pubertal female rat is about 3-times that of the male animal. Female rats castrated as adults or 15 days after birth, had low T-kininogen concentrations, near those of male rats. In contrast, castration of mature or immature male animals induced no change in T-kininogen. Treatment of castrated female or male rats with 17 alpha-ethinylestradiol significantly increased the T-kininogen level, whereas administration of testosterone or progesterone had no effect. The influence of estrogen was specific for T-kininogen, since plasma HMW kininogen concentration was the same in male and female rats and was not affected by castration or sex hormone treatment. T-kininogen concentration was not significantly changed in pregnant rat between the 12th and the 20th day of pregnancy, but increased after parturition. It was high in the newborn rat at birth and then decreased similarly over the next 3 weeks in males and females. It continued to decrease in the males, reaching the level of the adult rat, but it increased in the female from 3-4 weeks of age and reached the adult level at about 6-8 weeks. These data indicate that natural estrogens have a physiological influence on the plasma level of T-kininogen in female rats whereas testosterone had no effect on either male or castrated female rats. HMW kininogen is not physiologically dependent on sex hormones.

Effect of thyroidectomy on rat T-kininogen.

The thyroid state affects the inflammatory reaction; in general, thyroid hormones increase and hypothyroidism decreases the inflammatory response. T-kininogen is an acute phase protein that inhibits cysteine proteases. The influence of thyroidectomy and 3,5,3'-triiodothyronine (T3)-treatment of thyroidectomized animals was examined on rat plasma T-kininogen concentration. Thyroidectomy increased the T-kininogen level three- to fourfold. A single administration of 10 micrograms T3/100 g body wt in 7-wk postthyroidectomy rats decreased it by approximately 50%. Daily treatment with 0.5 micrograms T3/100 g body wt prevented the increases in T-kininogen. The modifications in plasma T-kininogen concentration were confirmed by high-performance liquid chromatography analysis of the plasma kinins released by trypsin. They demonstrated that T-kinin was greatly and bradykinin slightly increased after thyroidectomy and that T-kinin concentration in T3-treated thyroidectomized animals was almost restored to the control level. The ability of thyroidectomized animals to produce a higher plasma T-kininogen compared with euthyroid animals was further documented when T-kininogen production was stimulated by laparotomy. This procedure resulted in a fourfold increase in T-kininogen in thyroidectomized animals compared with controls. The increase of plasma T-kininogen level after thyroidectomy results from a more active synthesis of the protein, since liver slices from thyroidectomized rats synthesized T-kininogen at a rate about two times higher than normal rats. These data may account at least in part for the diminution of the inflammatory response observed after thyroidectomy.

Effect of dexamethasone on kininogen production by a rat hepatoma cell line.

T Kininogen and High Molecular Weight Kininogen were characterized in the cell culture medium of Fao cells, a highly differentiated cell line derived from the Reuber H35 rat hepatoma. Immunoreactive T Kininogen and High Molecular Weight Kininogen identified by direct and specific RIAs were indistinguishable from standard kininogens. Immunoreactive T Kininogen was further identified by HPLC analysis of T kinin released after trypsin hydrolysis of the cell culture medium. The basal release rate of T kininogen was ten-fold higher than that of High Molecular Weight Kininogen. T Kininogen was not stored within the cells contrary to High Molecular Weight Kininogen. The production of the two kininogens in the cell medium was stimulated by dexamethasone up to five times in a dose-dependent manner. The specific antiglucocorticoid compound RU 38486 did not alter the basal rate of kininogen release by Fao cells, but abolished the stimulation by dexamethasone, indicating that dexamethasone exerts a true glucocorticoid type effect.

Differential effects of nephrectomy and surgery on plasma kininogens and angiotensinogen in the rat.

The effects of bilateral nephrectomy or a sham operation on plasma angiotensinogen and on the different kininogens were studied in the rat. Total plasma kininogen was measured by RIA of kinins after trypsin hydrolysis. In addition, the high molecular weight (HMW) kininogen and the low molecular weight (T)-kininogen were specifically quantified by using direct RIAs. Angiotensinogen was measured by RIA of angiotensin I after exhaustion by renin. Three groups of control, nonoperated, bilaterally nephrectomized and sham-operated rats were studied in each experiment. Twenty-four hours after either a bilateral nephrectomy or a sham operation total plasma kininogen was elevated approximately 5 times when compared to control rats. Time course measurements from 0 to 48 h in 3 other groups of control, bilaterally nephrectomized and sham-operated rats demonstrated that kininogen gradually increased at 12, 24, and 48 h after the surgery and that the elevation observed in plasma kininogen appeared to be entirely due to an increase in T-kininogen levels. There was no difference in T-kininogen levels between bilaterally nephrectomized and sham-operated animals. By contrast HMW kininogen was neither influenced by surgery nor by nephrectomy. Angiotensinogen increased more than 8 times in bilaterally nephrectomized rats but displayed only little changes in sham-operated animals. During the course of this experiment it was observed that also in control animals submitted to repeated skin incision and venipuncture for blood sampling at the jugular vein, T-kininogen increased dramatically in plasma, but reached values lower than in sham-operated or bilaterally nephrectomized rats. In a third experiment performed in normal rats it was found that T-kininogen levels were more than 3 times elevated over initial values 24 h after a single blood sampling at the jugular vein. These results indicate that T-kininogen but not HMW kininogen is very sensitive to surgery, perhaps as a result of increased T-kininogen synthesis due to an inflammatory reaction. The T-kininogen might participate in the inflammatory reaction that occurs at the site of tissue injury and in the healing process. As there was no difference in T-kininogen, and in HMW kininogen levels between bilaterally nephrectomized and sham-operated rats, the kidneys do not seem to play an important role in the regulation of plasma kininogens. Angiotensinogen, HMW kininogen, and T-kininogen are therefore regulated separately after nephrectomy or surgery.

[Production and characterization of human antirenin antibodies prepared with synthetic immunogens]. / Production et caractérisation d'anticorps antirénine humaine préparés avec des immunogènes de synthèse.

Specific blockade of renin angiotensin system can be obtained both by enzymatic inhibitors and by passive and active immunization against renin. Recent studies have shown that synthetic peptides mimicking a protein segment can be used as immunogens to elicit antibodies which react with the parent molecule. In order to develop synthetic antirenin antigens we have selected peptidic sequences from human active renin and synthesized the corresponding peptides to produce antibodies able to recognize the entire human molecule and to inhibit its enzymatic activity. Three dimensional models of human renin were used to predict 17 putative epitopes. Then 18 peptides related to 13 potential antigenic determinants were synthesized by solid or liquid phase technic and 11 were shown to be antigenic when tested by their binding to several polyclonal and monoclonal human renin antibodies. The peptides were injected into rabbits and antisera tested by radio-immunoassay (RIA) and enzyme linked immunosorbent assay (ELISA) showed that nine peptides were immunogenic. Mainly, antiserum raised against the peptide mimicking the beta-hairpin 81-50 of active human renin which lies across the catalytic cleft, produced a 25 p. 100 inhibition of plasma renin activity at a 1: 50 dilution. Immunoglobulins, purified from antibodies raised against this epitopes, bound labelled renin and inhibited enzymatic activity of pure human renin on its synthetic tetradecapeptide substrate, in a dose dependent manner.