Local Kinin Research Articles

Kinin generation from exogenous kininogens at the surface of retinoic acid-differentiated human neuroblastoma IMR-32 cells after stimulation with interferon-γ

Bradykinin-related peptides, kinins, ubiquitously occur in the nervous system and together with other pro-inflammatory mediators contribute to pathological states of that tissue such as edema and chronic pain. In the current work we characterized the kinin-forming system of neuronal cells obtained by differentiation of human neuroblastoma cell line IMR-32 with retinoic acid. These cells were shown to concentrate exogenous kinin precursors, kininogens, on the surface, release kinins from kininogens and subsequently convert kinins to their des-Arg metabolites. Significantly higher amounts of kinins and des-Arg-kinins were produced after cell stimulation with interferon-γ, a potent pro-inflammatory mediator involved in many neurological disorders. The expression of the major tissue kininogenase (the human kallikrein 1) and the major cell membrane-bound kininase (the carboxypeptidase M) also increased after cell stimulation with interferon-γ, suggesting the involvement of these enzymes in the kinin production and degradation, respectively. Interferon-γ was also able to up-regulate the expression of two known subtypes of kinin receptors. On the protein level, the changes were only observed in the expression of the des-Arg-kinin-specific type 1 receptor which functions in the propagation of the inflammatory state. Taken together, these results suggest a novel way for local kinin and des-Arg-kinin generation in the nervous tissue during pathological states accompanied by interferon-γ release.

Lung cysteine cathepsins: Intruders or unorthodox contributors to the kallikrein–kinin system?

The protease/antiprotease balance is tipped in favor of enhanced proteolysis in inflammatory lung disorders, promoting the spread and severity of inflammation. Cysteine cathepsins participate in the remodeling and/or degradation of the pulmonary extra cellular matrix and in lung homeostasis. There is now good evidence that cathepsins are involved in fibrosis, emphysema, asthma, and in bronchopulmonary dysplasia. Kinins are inflammatory mediators that induce edema, pain and vasodilatation, and participate in vascular homeostasis. Kinins may also contribute to the immune system by acting as danger signals, and activating bradykinin receptors. Kinins are believed to play a role in inflammatory obstructive airway diseases, asthma, and allergic rhinitis. Their release by plasma and tissue kallikreins is severely reduced at inflammatory sites, although local kinin production seems to remain intact. Such conflicting observations suggest that there are alternative mechanisms of kinin metabolism besides the classical pathways. This article reviews the biological and pathophysiological roles of lung cysteine cathepsins, kinins and their receptors, and summarizes the indications that cysteine cathepsins may contribute to kinin liberation and/or degradation.

Kininogen binding to the surfaces of macrophages

Kinin generation may be initiated on the cell surfaces via a primary kininogen docking which has been characterized for endothelial cells, platelets, neutrophils, astrocytes and smooth muscle cells. In this work we describe the adsorption of biotin-labeled human kininogens by murine RAW 264.7 macrophages and human U-937 monocytes/macrophages. Both cell types strongly bound high molecular mass kininogen (HK) in a zinc–ion dependent manner with the dissociation constants of 9.1 nM and 3.3 nM, respectively, and the binding capacities of 46 fmol and 71 fmol per million of respective cells. The HK binding was quenched by 50% by antibodies against Mac-1, gC1qR and uPAR proteins indicating that these macrophage surface receptors are involved in the HK adsorption. A significant increase of HK binding was observed after cell activation with phorbol myristate acetate. Our results suggest that macrophages, similarly to neutrophils, may supply kininogens to the inflammatory foci to support the local kinin production at these sites.

Non-peptide antagonists and agonists of the bradykinin B(2) receptor.

Stimulation of the bradykinin (BK) B(2) receptor by kinins is associated with pathophysiological as well as pronounced beneficial effects. Consequently, interference with BK B(2) receptors by either antagonism or agonism offers promising therapeutic approaches for the development of drugs for the treatment of various human diseases. BK B(2) receptor antagonists may prove useful for the treatment of pathological situations caused by excessively increased local kinin concentrations, such as inflammation, tissue injury and pain. Beneficial effects of peptide BK B(2) receptor antagonists in perennial rhinitis, asthma and brain edema have already been demonstrated in clinical trials. On the other hand, kinins have also been identified as potent vasodilatory and organ-protective peptides. Therefore, BK B(2) receptor agonists may have the potential to become valuable therapeutics in the treatment of cardiovascular diseases such as hypertension, myocardial hypertrophy, myocardial infarction and arrhythmias as well as diabetic disorders. For both approaches, potent, selective and even orally active non-peptide compounds have been discovered recently. Prototypes of these novel third generation classes of compounds are the alkylphosphonium salt WIN-64338, the pseudopeptide NPC-18884, the thiosemicarbazide bradyzide and especially the imidazo[1,2-a]pyridine FR-167344 and the quinolines FR-173657 and LF-16.0687 as non-peptide BK B(2) receptor antagonists, whereas the 4-(2-pyridylmethoxy)-substituted quinoline FR-190997 and the 3-(2-pyridylmethyl)-substituted benzimidazole FR-191413 emerged as non-peptide BK B(2) receptor agonists. These antagonists and agonists of the BK B(2) receptor have already demonstrated efficacy a various animal models of human diseases, which offers promising therapeutic approaches for the development of drugs for the treatment or even prevention of a variety of severe human diseases either via stimulation or via blockade of BK B(2) receptors.

ACE inhibitors improve endothelial function of coronary arterioles from patients with atherosclerosis by influencing local kinin release

ACE inhibitors improve endothelial function of coronary arterioles from patients with atherosclerosis by influencing local kinin release

Expressions of bradykinin B2-receptor, kallikrein and kininogen mRNAs in the heart are altered in pressure-overload cardiac hypertrophy in mice.

Angiotensin-converting enzyme inhibitors prevent cardiac hypertrophy in vivo, and a component of this ameliorative effect has been attributed to accumulation of kinins in cardiac tissues. However, little is known regarding the levels of kallikrein-kinin components in the heart during the development of cardiac hypertrophy. The objectives of the present study were to define the effects of pressure-overload cardiac hypertrophy on cardiac levels of kininogen, kallikrein and bradykinin B2 receptor mRNAs. The pressure-overload induced by aortic constriction produced cardiac hypertrophy in mice after 14 and 28d, assessed from the increased ratios of heart weight to body weight and elevation of brain natriuretic peptide mRNA in the heart. B2 receptor mRNA rapidly decreased in the heart within 7 d after the operation, subsequently returning to those of sham-operated animals. In contrast, levels of both low-molecular-weight kininogen and tissue kallikrein mRNAs were increased 7, 14 and 28 d after aortic constriction. These findings suggest that the mechanical load or stretch in cardiac tissue by pressue-overload rapidly produces the downregulation of B2 receptor expression during the initial stage which may allow the promotion of cardiac hypertrophy induced by a mediation of hypertophic factors such as angiotensin II, while upregulation of kininogen and kallikrein mRNAs during the chronic stage may lead to an enhancement of local kinin generation in the heart, from which further progression of cardiac hypertrophy during later stages may be regulated.

Angiotensin-(1-7)-Stimulated Nitric Oxide and Superoxide Release From Endothelial Cells.

-The stimulation of endothelium-dependent NO release by angiotensin-(1-7) [Ang-(1-7)] has been indirectly shown in terms of vasodilation, which was diminished by NO synthase inhibition or removal of the endothelium. However, direct measurement of endothelium-derived NO has not been analyzed. With a selective porphyrinic microsensor, NO release was directly assessed from single primary cultured bovine aortic endothelial cells. Ang-(1-7) caused a concentration-dependent release of NO of 1 to 10 µmol/L, which was attenuated by NO synthase inhibition. [D-Ala(7)]Ang-(1-7) (5 µmol/L), described as a selective antagonist of Ang-(1-7) receptors, inhibited Ang-(1-7)-induced NO release only by approximately 50%, whereas preincubation of bovine aortic endothelial cells with the angiotensin II subtype 1 and 2 receptor antagonists EXP 3174 and PD 123,177 (both at 0.1 µmol/L) led to an inhibition of 60% and 90%, respectively. A complete blockade of the Ang-(1-7)-induced NO release was observed on preincubation of the cells with 1 µmol/L concentration of the bradykinin subtype 2 receptor antagonist icatibant (HOE 140), suggesting an important role of local kinins in the action of Ang-(1-7). Simultaneous direct measurement of superoxide (O(2)(-)) detected by an O(2)(-)-sensitive microsensor revealed that the moderately Ang-(1-7)-stimulated NO release was accompanied by a very slow concomitant O(2)(-) production with a relative low peak concentration in comparison to the O(2)(-) production of the strong NO releasers bradykinin and, especially, calcium ionophore. Thus, Ang-(1-7) might preserve the vascular system, among others, due to its low formation of cytotoxic peroxynitrite by the reaction between NO and O(2)(-).

Reinforcement of arteriolar myogenic activity by endogenous ANG II: susceptibility to dietary salt.

The purpose of this study was to determine whether endogenous ANG II augments arteriolar myogenic behavior in striated muscle. Because circulating ANG II is decreased during high salt intake, we also investigated whether dietary salt could alter any influence of ANG II on myogenic behavior. Normotensive rats fed low-salt (0.45%, LS) or high-salt (7%, HS) diets were enclosed in a ventilated box with the spinotrapezius muscle exteriorized for intravital microscopy. Dietary salt did not affect resting arteriolar diameters. Microvascular pressure elevation by box pressurization caused greater arteriolar constriction in LS rats (up to 12 microm) than in HS rats (up to 4 microm). The ANG II-receptor antagonists saralasin and losartan attenuated myogenic responsiveness in LS rats but not HS rats. The bradykinin-receptor antagonist HOE-140 had no effect on myogenic responsiveness in LS rats but augmented myogenic responsiveness in HS rats. HOE-140 with the angiotensin-converting enzyme inhibitor captopril attenuated myogenic responsiveness to a greater extent in LS rats than in HS rats. We conclude that endogenous ANG II normally reinforces arteriolar myogenic behavior in striated muscle and that attenuated myogenic behavior associated with high salt intake is due to decreased circulating ANG II and increased local kinin levels.

Amlodipine enhances NO production induced by an ACE inhibitor through a kinin-mediated mechanism in canine coronary microvessels.

Our previous study found that angiotensin-converting enzyme (ACE) inhibitors and amlodipine induce NO release from coronary microvessels through a kinin-dependent mechanism. The goal of this study was to determine whether amlodipine could potentiate NO formation during ACE inhibition. Coronary microvessels were isolated from 16 mongrel dogs. Nitrite, the hydration product of NO, from coronary microvessels was quantified by using the Griess reaction. Bradykinin and kallikrein all significantly increased nitrite release from coronary microvessels in a concentration-dependent manner. The ACE inhibitor, ramiprilat, potentiated these effects. Amlodipine also markedly potentiated nitrite production by ramiprilat. For instance, amlodipine (10(-10) M) enhanced nitrite release induced by ramiprilat (10(-7) M) from 122 +/- 9 to 168 +/- 14 pmol/mg (p < 0.05 vs. ramiprilat). Nitrite release potentiated by ramiprilat and amlodipine was entirely blocked by N(omega)-nitro-L-arginine methyl ester (L-NAME, an inhibitor of NO synthase), HOE 140 (Icatibant, a specific B2-kinin receptor antagonist), and dichloroisocoumarin (DCIC, a serine protease inhibitor that blocks local kinin formation). These results clearly show that there is a synergistic effect on NO formation when amlodipine is combined with ACE inhibition. Our data suggest that kinin-mediated coronary NO production may contribute importantly to the beneficial therapeutic action of ACE inhibitors, especially in combination with amlodipine in the treatment of heart disease.

Neutral endopeptidase and angiotensin-converting enzyme inhibitors increase nitric oxide production in isolated canine coronary microvessels by a kinin-dependent mechanism.

Bradykinin is a substrate for both neutral endopeptidase 24.11 (NEP) and angiotensin-converting enzyme (ACE). Our previous studies showed that ACE inhibitors can stimulate nitric oxide production in coronary microvessels, which is mediated by local kinins. Whether inhibition of NEP also can affect local vascular NO production has not been established. To determine the role of NEP in the control of NO production, coronary microvessels were isolated from seven mongrel dogs. Two NEP inhibitors, phosphoramidon and thiorphan, and an ACE inhibitor, ramiprilat, were used. Nitrite, the metabolite of NO in aqueous solution, was measured by using the Griess reaction. Phosphoramidon and thiorphan (10(-6) M) increased nitrite production from 80 +/- 6 to 136 +/- 6 and 144 +/- 7 pmol/mg, respectively. Ramiprilat (10(-8) M) increased nitrite production from 78 +/- 6 to 155 +/- 7 pmol/mg wet weight. The effect of these agents on nitrite release was blocked by L-NAME, which inhibits NO synthase, HOE-140, which blocks bradykinin B2-receptor, and dichloroisocoumarin, which blocks kinin-forming enzymes. These results clearly indicate that inhibition of kinin metabolism by using neutral endopeptidase inhibitors increases NO production from coronary microvessels. Thus neutral endopeptidase plays an important role in local kinin-modulated NO production in the coronary microcirculation and NEP inhibitors may be useful clinical tools in treatment of cardiovascular disease.

Bradykinin B 2 -Receptor Activation Augments Norepinephrine Exocytosis From Cardiac Sympathetic Nerve Endings

We determined whether local bradykinin production modulates cardiac adrenergic activity. Depolarization of guinea pig heart sympathetic nerve endings (synaptosomes) with 1 to 100 mmol/L K+ caused the release of endogenous norepinephrine (10% to 50% above basal level). This release was exocytotic, because it depended on extracellular Ca2+, was inhibited by the N-type Ca(2+)-channel blocker omega-conotoxin and the protein kinase C inhibitor Ro31-8220, and was potentiated by the neuronal uptake-1 inhibitor desipramine. Typical of adrenergic terminals, norepinephrine exocytosis was enhanced by activation of prejunctional angiotensin AT1-receptors and attenuated by adrenergic alpha 2-receptors, adenosine A1-receptors, and histamine H3-receptors. Exogenous bradykinin enhanced norepinephrine exocytosis by 7% to 35% (EC50, 17 nmol/L), without inhibiting uptake 1. B2-receptor, but not B1-receptor, blockade antagonized this effect. The kininase II/angiotensin-converting enzyme inhibitor enalaprilat and the addition of kininogen or kallikrein enhanced norepinephrine exocytosis by approximately equal to 6% to 40% (EC50, 20 nmol/L) and approximately equal to 25% to 60%, respectively. This potentiation was prevented by serine protease inhibitors and was antagonized by B2-receptor blockade. Therefore, norepinephrine exocytosis is augmented when bradykinin synthesis is increased or when its breakdown is inhibited. This is the first report of a local kallikrein-kinin system in adrenergic nerve endings capable of generating enough bradykinin to activate B2-receptors in an autocrine/paracrine fashion and thus enhance norepinephrine exocytosis. This amplification process may operate in disease states, such as myocardial ischemia, associated with severalfold increases in local kinin concentrations.

Angiotensin-Converting Enzyme Inhibitors Promote Nitric Oxide Production in Coronary Microvessels from Failing Explanted Human Hearts

We have previously shown that nitric oxide (NO) release by the coronary circulation in the failing and nonfailing human heart is, in part, regulated by local kinin production in coronary microvessels. Angiotensin-converting enzyme (ACE) also known as kininase II, inactivates kinins. ACE inhibitors prevent kinin breakdown by ACE, thereby increasing the concentration of bradykinin (BK) and related kinins. The goal of this study was to determine if kinins contribute to the therapeutic action of ACE inhibitors. Six hearts from end-stage heart failure patients were harvested at the time of orthotopic cardiac transplantation. Microvessels were prepared as previously described, and nitrite production, a metabolic product of NO in vitro, was determined by the Griess reaction. Microvessels were incubated in the presence of kininogen and bradykinin, and with the ACE inhibitors ramiprilat, enalaprilat, or captopril. All caused dose-dependent increases in nitrite. For instance, ramiprilat increased nitrite from 76 ± 5.6 to 155 ± 15 pmol/min per mg wet weight. Nitrite production in response to ACE inhibition was blocked by N-nitro-l-arginine methyl ester (l-NAME), a NO synthase inhibitor, and icatibant (HOE 140), a B2-kinin receptor-specific antagonist. Furthermore, NO production was prevented by 3 different serine protease inhibitors, which block kallikrein, the enzyme responsible for conversion of kininogen to kinins. Our results indicate that ACE/kininase inhibitors increase NO production by the coronary microvasculature in the failing human heart, through increased available active kinins. The therapeutic action of ACE inhibition in the failing human heart may result in part from increased NO production by coronary microvessels.

Improvement of Alveolar–Capillary Membrane Diffusing Capacity With Enalapril in Chronic Heart Failure and Counteracting Effect of Aspirin

KII ACE, the enzyme that converts angiotensin I and inactivates bradykinin, is highly concentrated in the lungs; its blockade reduces exposure to angiotensin II and enhances exposure to prostaglandins generated by local kinin hyperconcentration. Our hypothesis is that ACE inhibitors improve pulmonary function in chronic heart failure (CHF) by readjusting lung vessel tone and permeability or alveolar-capillary membrane diffusion. In 16 CHF patients and 16 normal volunteers or mild untreated hypertensives, pulmonary function and exercise tests with respiratory gas analysis were assessed on placebo, enalapril (10 mg BID), enalapril plus aspirin (325 mg/d), or aspirin, in random order and double blind, for 15 days each. In CHF, enalapril increased pulmonary carbon monoxide diffusion (DLCO), oxygen consumption (VO2), and exercise tolerance and reduced the ratio of dead space to tidal volume (VD/VT) and the ventilatory equivalent for carbon dioxide production (VE/VCO2). On enalapril, VO2 (r = .80, P < .0001) and VD/VT (r = -.69, P = .003) changes from placebo correlated with those in DLCO. These effects were inhibited by aspirin and were absent in control subjects. In 8 additional patients, hydralazine-isosorbide dinitrate, as an alternative treatment for reducing pulmonary capillary wedge pressure (PCWP) and increasing exercise capacity, were more effective than enalapril for the PCWP but did not affect DLCO and VE/VCO2; amelioration in VO2 and VD/VT was unrelated to DLCO and was not modified by aspirin. ACE inhibition improved pulmonary diffusion in CHF. Hydralazine-isosorbide dinitrate failed to provide this result. Counteraction by aspirin, a prostaglandin inhibitor, bespeaks prostaglandin participation while on enalapril that might readjust capillary permeability or alveolar-capillary membrane diffusion.

A23 Cardioprotection of converting enzyme inhibitors and local kinin formation

A23 Cardioprotection of converting enzyme inhibitors and local kinin formation

ACE inhibitors promote nitric oxide accumulation to modulate myocardial oxygen consumption.

ACE inhibitors potentiate kinin-nitric oxide (NO)-dependent coronary vascular dilation, and NO can modulate myocardial oxygen consumption. Whether ACE inhibitors also affect myocardial O2 consumption has not been established. Production of nitrite, a metabolite of NO in aqueous solution, in coronary microvessels and O2 consumption in myocardium were quantified with the use of in vitro tissue preparations, the Greiss reaction, and a Clark-type O2 electrode. In coronary microvessels, kininogen (the precursor of kinin; 10 micrograms/mL) and three ACE inhibitors (captopril, enalaprilat, or ramiprilat; 10(-8) mol/L) increased nitrite production from 76 +/- 6 to 173 +/- 15, 123 +/- 12, 125 +/- 12, and 153 +/- 12 pmol/mg, respectively (all P < .05). In myocardium, kininogen (10 micrograms/mL) and captopril, enalaprilat, or ramiprilat (10(-4) mol/L) reduced cardiac O2 consumption by 41 +/- 2%, 19 +/- 3%, 25 +/- 2%, and 35 +/- 2%, respectively. The changes in both nitrite release and O2 consumption in vitro were blocked by N omega-nitro-L-arginine methyl ester or N omega-nitro-L-arginine, inhibitors of endogenous NO formation. The effects were also blocked by HOE 140, which blocks the bradykinin B2-kinin receptor, and serine protease inhibitors, which inhibit local kinin formation. Our data indicate that stimulation of local kinin formation by use of a precursor for kinin formation or inhibition of kinin degradation by use of ACE inhibitors increases NO formation and is important in the control of cardiac O2 consumption. Vasodilation and control of myocardial O2 consumption by NO may contribute importantly to the therapeutic actions of ACE inhibitors in cardiac disease states.

Regulation of nitric oxide production in human coronary microvessels and the contribution of local kinin formation.

The goal of this study was to define the regulation of nitric oxide release by coronary microvessels from the failing and nonfailing human heart and to determine the role of local kinin production in the elaboration of nitric oxide by human coronary microvascular endothelium. Ten hearts from humans with end-stage heart failure and two hearts from patients without heart failure were harvested at the time of orthotopic cardiac transplantation. Microvessels were sieved and the production of nitrite was determined by the Griess reaction. Microvessels were incubated in the presence of agonists for nitric oxide production (acetylcholine and bradykinin), which caused dose-dependent increases in nitrite, a response that was blocked by NG-nitro-L-arginine methyl ester and receptor-specific antagonists (atropine and HOE 140, respectively). In addition, the production of nitrite by microvessels from the failing heart appeared to be less than that produced by microvessels from the nonfailing heart. Incubation with norepinephrine or the alpha2-adrenergic agonist BHT 920 also caused dose-dependent increases in nitrite production, which were blocked by the B2-receptor antagonist HOE 140. This implicated local kinin synthesis as an intermediate step in the production of nitric oxide in response to alpha2-adrenoceptor stimulation. The production of nitric oxide was also prevented by the addition of serine protease inhibitors, which blocked the action of local kallikrein, again suggesting a role for local kinin synthesis. Our results indicate that nitric oxide is produced by human coronary microvessels, that nitric oxide production may be reduced but certainly not increased in microvessels from the failing human heart, and that there is active local kinin generation in these blood vessels.

Hypertensive effect of tissue kallikrein in rostral ventrolateral medulla is mediated by brain kinins

Microinjections of kallikrein, 0.5–2.0 units, in the rostral ventrolateral medulla (RVLM) of brain increased arterial pressure in Wistar-Kyoto (WKY) and spontaneously hypertensive rats (SHR). This effect was significantly greater in SHR. The kinin B 2 receptor antagonist icatibant (Hoe 140) blocked the hypertensive responses to kallikrein in both groups and caused greater hypotension and bradycardia in SHR. These results suggest that local kinins in the RVLM act to alter cardiovascular function and may be involved in the maintenance of blood pressure in the SHR.

Coronary Kinin Generation Mediates Nitric Oxide Release After Angiotensin Receptor Stimulation

Our goal was to determine whether angiotensin II (Ang II) and its metabolic fragments release nitric oxide and the mechanisms by which this occurs in blood vessels from the canine heart. We incubated 20 mg of microvessels or large coronary arteries in phosphate-buffered saline for 20 minutes and measured nitrite release. Nitrite release increased from 27 +/- 2 up to 103 +/- 5, 145 +/- 17, 84 +/- 4, 107 +/- 16, and 54 +/- 4 pmol/mg (P < .05) in response to 10(-5) mol/L of Ang I, II, III, IV, and Ang-(1-7), respectively. The effects of all angiotensins were blocked by N omega-nitro-L-arginine methyl ester (100 mumol/L), indicating that nitrite was a product of nitric oxide metabolism, and by Hoe 140 (10 mumol/L), a specific bradykinin B2 receptor antagonist, indicating a potential role for local kinin formation. The protease inhibitors aprotinin (10 mumol/L) and soybean trypsin inhibitor, which block local kinin formation, inhibited nitrite release by all of the angiotensins. Angiotensin nonselective (saralasin), type 1-specific (losartan), and type 2-specific (PD 123319) receptor antagonists abolished the nitrite released in response to all the fragments. Angiotensin type 1 and type 2 and receptors mediate nitrite release after Ang I, II, III, and Ang-(1-7), whereas only type 2 receptors mediate nitrite release after Ang IV. Similar results were obtained in large coronary arteries. In summary, formation of nitrite from coronary microvessels and large arteries in the normal dog heart in response to angiotensin peptides is due to the activation of local kinin production in the coronary vessel wall.

Stimulation of Renal Interstitial Bradykinin by Sodium Depletion

The ability to measure and detect change in renal bradykinin in situ would allow study of relations between local kinin production and renal function in hypertensive or diabetic disorders. A new renal interstitial microdialysis technique allowed collections of renal subcapsular interstitial fluid 2 weeks after microdialysis probe placement in conscious dogs (n = 5) on a normal sodium diet (50 mEq/day) and for 5 subsequent days on low sodium intake (10 mEq/day). Although interstitial bradykinin measured by radioimmunoassay (RIA) was undetectable (< 0.08 pg/min) during normal sodium intake, it was detectable (0.34 +/- 0.02 pg/min) after 1 day of low sodium. The kinin level at the end of the 5 subsequent days on low sodium was 1.94 +/- 0.09 pg/min (P < .01). The data show that renal interstitial kinin can be measured in situ. Further, a low sodium diet can rapidly increase interstitial kinin in the conscious dog.

Kinins mediate kallikrein-induced endothelium-dependent relaxations in isolated canine coronary arteries

ACE inhibitors elicit the release of endothelium-derived relaxing factors in perfused isolated canine arteries (Mombouli and Vanhoutte, J.Cardiovasc.Pharmacol.1991, 18: 926–927); this action is antagonized by bradykinin-receptor antagonists suggesting that it is mediated by local kinin generation. The effects of exogenous tissular kallikrein (porcine) were examined in vitro in the isolated canine coronary artery. Isometric tension was measured in blood vessel rings (with and without endothelium) contracted with prostaglandin F 2α. The kallikrein elicited relaxations in rings with, but not in those without, endothelium. This response was augmented by the angiotensin converting enzyme inhibitor perindoprilat, and it was antagonized by the selective B 2-kinin receptor antagonist HOE 140 and aprotinin, an inhibitor of tissular kallikrein. These data suggest that in the canine coronary artery, kallikrein causes relaxations that may be mediated by kinins generated from endogenous kininogens present in the vascular wall.