Ulrich Hilgenfeldt

Localization of angiotensinogen in multiple cell types of rat brain

Angiotensinogen was localized in 3 cell types in brain using immunohistochemical methods. These locations included subpopulations of neurons in nuclei that co-stain for angiotensin II, subpopulations of astrocytes that make putative contacts with brain microvessels, and cells of the choroid plexus. These findings are consistent with multiple functions for brain angiotensinogen as a precursor for neuronal angiotensin II and as a potential source for angiotensin II that is locally produced in the brain.

Estrogen action on hepatic synthesis of angiotensinogen and IGF-I: Direct and indirect estrogen effects

In the present study effects of estrogens (natural estradiol and synthetic ethinyl estradiol) on liver derived proteins (angiotensinogen, IGF-I) were investigated in vivo in ovariectomized rats and in vitro in a rat hepatoma cell line (Fe33). The aim of this study was to establish both an animal and an in vitro model for quantification of the hepatic activity of given estrogenic compounds, and to study underlying mechanisms as regards the question of direct or indirect mode of estrogen action. In ovariectomized rats subcutaneous (s.c.)-treatment for 11 days with either estradiol (E2) or ethinyl estradiol (EE) (dose range 0.1-3 micrograms/animal/day) induced a comparable dose-dependent increase in uterine weight indicating a similar estrogenic potency of the two estrogens. Equipotency was also found as regards the effects on IGF-I plasma levels which dose-dependently decreased by about 50% at the highest dose tested (3 micrograms/animal/day). The decrease in IGF-I serum levels was accompanied by a significant 40% decrease in liver IGF-I mRNA. In contrast angiotensinogen plasma levels were affected only by EE (60% increase for the 3 micrograms/animal/day dose) but not by E2. When rats, in addition to ovariectomy, were also hypophysectomized (substituted with human growth hormone and dexamethasone) angiotensinogen again increased by 80% upon administration of 3 micrograms/animal/day EE, whereas IGF-I remained unaffected by EE. In a rat hepatoma cell line (Fe33) which is stably transfected with an estrogen receptor expression plasmid, 10 nmol/l EE for 24 h caused a 2.4-fold increase in angiotensinogen mRNA level. We conclude from our studies that estrogen effects on angiotensinogen serum levels in the rat are direct effects via the hepatic estrogen receptor, whereas estrogen effects on IGF-I serum levels are indirect effects, the primary target of estrogen action being probably the pituitary. The changes in angiotensinogen serum levels in the rat model are comparable to the situation in humans indicating the rat model and the Fe33 model to be useful tools to study the hepatic activity of estrogenic compounds.

Purification and partial characterization of rat brain acid proteinase (isorenin)

1. Isorenin was purified 2000-fold from rat brain by a simple 3-step procedure involving affinity chromatography on pepstatinyl-Sepharose, The preparation appears as a homogenous protein in analytical polyacrylamide gel electrophoresis. Sodium dodecyl sulfate gel electrophoresis indicated an apparent molecular weight of 45 000. Isoelectric focusing separated isoenzymes with isoelectric points at pH 5.45, 5.87, 6.16 and 7.05. 2. The enzyme generates antiotensin I from tetradecapeptide (pH optimum 4.7) and from sheep angiotensinogen (pH optima 3.9 and 5.5). The rate of angiotensin I formation from tetradecapeptide was 30 000 times higher than that from sheep angiotensinogen. The enzyme has acid protease activity at pH 3.2 with hemoglobin as the substrate and pepstatin is a potent inhibitor of the enzyme with a Ki of less than 10(-9) M. 3. The properties of the enzyme strongly suggest that it is identical with cathepsin D.

Local angiotensin formation in hindlimbs of uremic hypertensive and renovascular hypertensive rats

To examine and characterize the vascular renin-angiotensin system in low-renin models of renal hypertension with and without the presence of overt renal insufficiency, we studied the formation and metabolism of angiotensin in isolated perfused rat hindquarter preparations. Rats with 5/6 nephrectomy (5/6NX) and rats with one-kidney, one clip (1K1C) hypertension were compared to sham operated (sham) animals. Angiotensin peptides in plasma or perfusate were characterized by high-performance liquid chromatography and radioimmunoassay (RIA). Plasma angiotensin II was lower, and blood pressure was higher in both experimental groups, compared to sham animals. Plasma angiotensinogen, measured by both direct and indirect RIA, was increased in both experimental groups. The spontaneous release of angiotensin I and angiotensin II from perfused hindquarters did not differ between the groups. Angiotensin I conversion was not different in 5/6NX or 1K1C groups compared with controls. Furthermore, angiotensin conversion was completely inhibited by captopril (1 μmol/l) in all groups. Renin-induced angiotensin release was significantly increased in 5/6NX as compared with sham rats, whereas there was no difference in renin-induced angiotensin release between 1K1C and sham animals. Angiotensin II degradation was significantly attenuated in 5/6NX rats when compared with sham rats (27.6% versus 53.9%, respectively, P < 0.05) but was unaltered in 1K1C rats. Thus, in chronic uremic hypertension, renin-induced angiotensin formation was increased in the face of decreased angiotensin II degradation. These data suggest that vascular angiotensin may contribute to the elevated blood pressure observed in chronic renal failure. In 1K1C rats, vascular angiotensin formation and metabolism was unchanged despite suppressed plasma angiotensin II.

Functional, biochemical, and molecular investigations of renal kallikrein-kinin system in diabetic rats.

A reduction of renal kallikrein has been found in non-insulin-treated diabetic individuals, suggesting that an impaired renal kallikrein-kinin system (KKS) contributes to the development of diabetic nephropathy. We analyzed relevant components of the renal KKS in non-insulin-treated streptozotocin (STZ)-induced diabetic rats. Twelve weeks after a single injection of STZ, rats were normotensive and displayed hyperglycemia, polyuria, proteinuria, and reduced glomerular filtration rate. Blood bradykinin (BK) levels and prekallikrein activity were significantly increased compared with controls. Renal kallikrein activity was reduced by 70%, whereas urinary BK levels were increased up to threefold. Renal kininases were decreased as indicated by a 3-fold reduction in renal angiotensin-converting enzyme activity and a 1.8-fold reduction in renal expression of neutral endopeptidase 24.11. Renal cortical expression of kininogen and B2receptors was enhanced to 1.4 and 1.8-fold, respectively. Our data suggest that increased urinary BK levels found in severely hyperglycemic STZ-diabetic rats are related to increased filtration of components of the plasma KKS and/or renal kininogen synthesis in combination with decreased renal kinin-degrading activity. Thus, despite reduced renal kallikrein synthesis, renal KKS is activated in the advanced stage of diabetic nephropathy.A reduction of renal kallikrein has been found in non-insulin-treated diabetic individuals, suggesting that an impaired renal kallikrein-kinin system (KKS) contributes to the development of diabetic nephropathy. We analyzed relevant components of the renal KKS in non-insulin-treated streptozotocin (STZ)-induced diabetic rats. Twelve weeks after a single injection of STZ, rats were normotensive and displayed hyperglycemia, polyuria, proteinuria, and reduced glomerular filtration rate. Blood bradykinin (BK) levels and prekallikrein activity were significantly increased compared with controls. Renal kallikrein activity was reduced by 70%, whereas urinary BK levels were increased up to threefold. Renal kininases were decreased as indicated by a 3-fold reduction in renal angiotensin-converting enzyme activity and a 1.8-fold reduction in renal expression of neutral endopeptidase 24.11. Renal cortical expression of kininogen and B2 receptors was enhanced to 1.4 and 1. 8-fold, respectively. Our data suggest that increased urinary BK levels found in severely hyperglycemic STZ-diabetic rats are related to increased filtration of components of the plasma KKS and/or renal kininogen synthesis in combination with decreased renal kinin-degrading activity. Thus, despite reduced renal kallikrein synthesis, renal KKS is activated in the advanced stage of diabetic nephropathy.

Bradykinin and kallidin levels in the trapezius muscle in patients with work-related trapezius myalgia, in patients with whiplash associated pain, and in healthy controls - A microdialysis study of women.

Abstract The origins of chronic muscle pain development and maintenance are debated regarding the relative contributions of peripheral nociception and central pain processing. Bradykinin (BKN) and kallidin (KAL) have been suggested to be algesic kinins involved in muscle pain. This in vivo study investigates whether there were significant differences in interstitial muscle concentrations of BKN and KAL between chronic work‐related trapezius myalgia (TM), chronic whiplash associated disorders (WAD), and healthy controls (CON). These subjects were studied at rest, during a 20‐min repetitive low‐force exercise and recovery. The interstitial concentrations of BKN and KAL of trapezius were determined using the microdialysis technique. The interstitial concentration of KAL was overall significantly higher in TM than in CON. [KAL] and [BKN] increased significantly during the brief exercise in all groups. The increase in [BKN] during exercise was significantly higher in TM than in the other two groups, whereas the increase in [KAL] during exercise was highest in WAD. In chronic pain, positive correlations existed between the two kinins and the difference in pain intensity between recovery and baseline. In this in vivo study of two groups of patients with chronic pain clinically involving the trapezius muscle, we found alterations – most prominent in TM – in the interstitial concentrations of BKN and KAL. The results indicated that the two kinins were involved in aspects of hyperalgesia.

Activation of the tissue kallikrein–kinin system in stroke

Edema formation is a major problem in large ischemic infarcts, and the underlying breakdown of the blood-brain barrier is only incompletely understood. Here, we report that the tissue kallikrein-kinin system, which influences the permeability of the blood-brain barrier, is activated in stroke. In 22 patients with large infarcts in the territory of the middle cerebral artery, we found elevated plasma concentrations of the tissue kinin kallidin. The data suggest that further studies on a possible role of kinin receptor antagonists on edema after stroke are warranted.

Kinins are involved in the antiproteinuric effect of angiotensin-converting enzyme inhibition in experimental diabetic nephropathy.

The present study examined non-insulin-treated streptozotocin (STZ)-induced diabetic rats to determine the role of kinins in diabetic nephropathy. Their involvement in the renoprotective effect of the angiotensin-converting enzyme inhibitor (ACEI) ramipril was investigated using the bradykinin (BK) B(2)-receptor antagonist, icatibant (HOE 140), or a combination of the two drugs.Although, none of the treatments prevented the decline of the glomerular filtration rate (GFR) in diabetic rats, ramipril (3 mg/kg/day), but not icatibant (HOE 140; 500 microg/kg/day), prevented proteinuria in these animals. However, the antiproteinuric effect of ramipril was reduced by 45% when combined with icatibant. To explore whether the renal kallikrein-kinin system (KKS) belongs to the underlying mechanisms of these findings, we also determined urinary BK levels, renal kallikrein (KLK) and angiotensin-converting enzyme (ACE) activity as well as renal cortical mRNA levels of neutral endopeptidase 24.11 (NEP) and low-molecular weight (LMW) kininogen. STZ led to a reduction of renal KLK and ACE activity and NEP expression and to a three-fold increase of urinary BK excretion and renal kininogen expression. Icatibant given alone had no effect on these parameters. In contrast, ramipril treatment normalized urinary protein and BK excretion as well as kininogen mRNA expression without affecting NEP mRNA expression or KLK and ACE activity. Our data demonstrate that renal BK is increased in severe STZ-induced diabetes mellitus, but may affect glomerular regulation only to a minor degree under this condition. However, kinins are partly involved in the antiproteinuric action of ACEI at this stage of diabetic nephropathy.

Separation and characterization of two different species of rat angiotensinogen

Two distinct species of rat angiotensinogen (A-1 and A-2) were purified from plasma of nephrectomized rats by combining ammonium sulfate fractionation, chromatography on Blue Sepharose and SP-Sephadex, gel filtration and preparative polyacrylamide gel electrophoresis. Separation of the two species was accomplished in the SP-Sephadex chromatography step, A-1 eluting before A-2. The two angiotensinogen species had identical electrophoretic mobilities on analytical polyacrylamide gel electrophoresis, but differed in their apparent molecular weights as obtained by SDS-gel electrophoresis (A-1, Mr 60 000; A-2, Mr 56 400). In analytical isoelectric focusing each species displayed a characteristic double band with isoelectric points of 4.54 and 4.60 for A-1, and 4.69 and 4.76 for A-2. These physicochemical differences can be accounted for by the difference in carbohydrate content: A-1, when compared to A-2, had a higher content of sialic acid (5.0 and 2.1 mol/mol), neutral hexoses (10.2 and 5.9 mol/mol) and aminohexoses (10.5 and 7.0 mol/mol, respectively). Antiserum raised against rat angiotensinogen crossreacted completely with both angiotensinogens. Both species could also be isolated from plasma of non-nephrectomized rats, which indicates that they may be present under physiological conditions. The physiological significance of the occurrence of these species of angiotensinogen is still unknown.

Ca2+ signalling of kinins in cells expressing rat, mouse and human B1/B2-receptor

With respect to functional aspects, the kallikrein-kinin-system can be divided into a plasma kallikrein-kinin-system and a tissue kallikrein-kinin-system. At least four functional kinin peptides act via two different G-protein-coupled receptors, an inducible B1-receptor and a constitutively expressed B2-receptor. B1R and B2R couple to G(q/11) and lead via phospholipase C to Ca2+ mobilization. In humans both, bradykinin and kallidin are agonists on the B2-receptor. In contrast, bradykinin is believed to be the only kinin acting on the B2R in rats and mice. However, recently we have isolated a kallidin-like-peptide from plasma and urine of rats. Until now the kinin ligand-receptor interactions were mainly characterized in binding studies. However, receptor affinity does not inevitably correspond with the intrinsic activity of an agonist. The aim of the present study was to investigate intracellular calcium mobilization to quantify mouse, rat and human B1- and B2-receptor activation by bradykinin, kallidin, des-Arg9-bradykinin, des-Arg10-kallidin, and of the two novel rat kinins, kallidin-like-peptide and des-Arg10-kallidin-like-peptide. In cells stably expressing the human, rat, and mouse B2-receptor, respectively, bradykinin, kallidin, and kallidin-like-peptide were nearly equipotent (EC50, 10(-12)M) at eliciting Ca2+-transients. Their des-Arg-derivatives were 10(3)-fold less potent. In cells expressing B1-receptor the des-Arg derivatives elicited Ca2+-signals at an EC50 in the order of 10(-9)M. Major differences between these peptides could not be observed. Bradykinin, kallidin, and kallidin-like-peptide caused a Ca2+-signal at substantially higher concentrations in the order of 10(-7)M. The data show that des-Arg9-bradykinin, des-Arg10-kallidin, and des-Arg10-kallidin-like-peptide are equipotent agonists at the B1-receptor. Bradykinin, kallidin and kallidin-like-peptide are equipotent agonists at the B2-receptor.