Ekaterina Kintsurashvili

Vasoactive Potential of the B1 Bradykinin Receptor in Normotension and Hypertension

Abstract— The B1 type receptor of bradykinin (Bk B1R) is believed to be physiologically inert but highly inducible by inflammatory mediators and tissue damage. To explore the potential participation of the Bk B1R in blood pressure (BP) regulation, we studied mice with deleted Bk B2R gene with induced experimental hypertension, either salt-dependent (subtotal nephrectomy with 0.5% NaCl as drinking water) or renin/angiotensin-dependent (renovascular 2-kidney–1-clip). Compared with the wild-type controls, the B2R gene knockout mice had a higher baseline BP (109.7±1.1 versus 101.1±1.3 mm Hg, P =0.002), developed salt-induced hypertension faster (in 19.3±2.3 versus 27.7±2.4 days, P =0.024), and had a more severe end point BP (148±3.7 versus 133±3.1 mm Hg, P <0.05). On the contrary, renovascular hypertension developed to the same extent (149.7±4.3 versus 148±3.6 mm Hg) and in the same time frame (14±2.2 versus 14±2.1 days). A bolus infusion of a selective B1R antagonist at baseline produced a significant hypertensive response (by 11.4±2 mm Hg) in the knockout mice only. Injection of graded doses of a selective B1R agonist produced a dose-dependent hypotensive response in the knockout mice only. Assessment of tissue expression of B1R and B2R genes by reverse transcription–polymerase chain reaction techniques revealed significantly higher B1R mRNA levels in the B2R knockout mice at all times (normotensive baseline and hypertensive end points). At the hypertensive end points, there was always an increase in B1R gene expression over the baseline values. This increase was significant in cardiac and renal tissues in all hypertensive wild-type mice but only in the clipped kidney of the renovascular knockout mice. The B2R gene expression in the wild-type mice remained unaffected by experimental manipulations. These results confirm the known vasodilatory and natriuretic function of the Bk B2R; they also indicate that in its absence, the B1R can become upregulated and assume some of the hemodynamic properties of the B2R. Furthermore, they indicate that experimental manipulations to produce hypertension also induce upregulation of the B1R, but not the B2R, in cardiac and renal tissues.

Angiotensin-Converting Enzyme Inhibition After Experimental Myocardial Infarct: Role of the Kinin B1 and B2 Receptors

We sought to define the contribution of each of the 2 kinin receptors (bradykinin 1 receptor [B1R] and bradykinin 2 receptor [B2R]) to the cardioprotection of angiotensin-converting enzyme (ACE) inhibition after acute myocardial infarct. Wild-type mice and gene knockout mice missing either B1R or B2R were submitted to coronary ligation with or without concurrent ACE inhibition and had evaluation of left ventricular systolic capacity by assessment of fractional shortening (FS). Baseline FS was similar in all of the animals and remained unchanged in sham-operated ones. At 3 weeks after myocardial infarct, in the wild-type group there was a 27% reduction of FS (P<0.5) without ACE inhibition and 8% with ACE inhibition; in the B1R−/− groups the FS was reduced by 24% and was no different (at 28%) with ACE inhibition; in the B2R−/− groups, however, the FS was decreased by 39% and with ACE inhibition was decreased further by 52%. Analysis of bradykinin receptor gene expression in hearts showed that when one receptor was missing, the other became significantly upregulated; but the B1R remained highly overexpressed in the B2R−/− mice throughout, whereas the overexpressed B2R became significantly suppressed in the B1R−/− mice in a manner quantitatively and directionally similar to that of wild-type mice. We conclude that both bradykinin receptors contribute to the cardioprotective bradykinin-mediated effect of ACE inhibition, not only the B2R as believed previously; but, whereas with potentiated bradykinin in the absence of B1R, the upregulation of B2R is simply insufficient to provide full cardioprotection, in the absence of B2R, the upregulated B1R actually seems to inflict further tissue damage.

Cardioprotective Effects of a Selective B2 Receptor Agonist of Bradykinin Post-Acute Myocardial Infarct

BACKGROUND The cardioprotective benefits of bradykinin are attributable to activation of its B(2) receptor (B(2)R)-mediated actions and abolished by B(2)R antagonists. The current experiments evaluated the cardioprotective potential of a potent, long-acting B(2)R-selective agonist peptide analogue of bradykinin, the compound NG291. METHODS We compared the extent of cardiac tissue damage and remodeling and expression pattern of selected genes in mice submitted to acute myocardial infarct (MI) and treated for 1 week with either NG291 [Hyp(3),Thi(5),(N)Chg(7),Thi(8)]-bradykinin or with saline delivered via osmotic minipump. RESULTS Active treatment resulted in better ejection fraction (EF) 69 +/- 1% vs. 61 +/- 3.1% (P = 0.01), (vs. 85 +/- 1.3% in sham-operated controls), fractional shortening (FS) 38 +/- 4% vs. 32 +/- 8% (NS) (vs. 53 +/- 1.2 in sham-operated controls), and fewer markers of myocyte apoptosis (TUNEL-positive nuclei 4.9 +/- 1.1% vs. 9.7 +/- 0.03%, P = 0.03). Systolic blood pressure (SBP) at end point was normal at 110 +/- 4.2 in actively treated mice, but tended to be lower at 104 +/- 4.7 mm Hg in saline controls with decreased cardiac systolic capacity. Expression patterns of selected genes to factors related to tissue injury, inflammation, and metabolism (i.e., the B(1)R, B(2)R, endothelial nitric oxide synthase (eNOS), TNF-alpha, cardiomyopathy-associated 3 (Cmya3), and pyruvate dehydrogenase kinase isoenzyme 4 (PDK4)) showed that acute MI induced significant upregulation of these genes, and active treatment prevented or attenuated this upregulation, whereas the B(2)R agonist itself produced no difference in the myocardium of sham-operated mice. CONCLUSIONS Treatment with a selective B(2)R agonist initiated at the time of induction of acute MI in mice had a beneficial effect on cardiac function, tissue remodeling, and inflammation-related tissue gene expression, which may explain its structural and functional benefits.

Mechanisms Mediating the Vasoactive Effects of the B1 Receptors of Bradykinin

Abstract—Bradykinin normally exerts its vasodilatory effect via the B2 receptor (B2R), but in this receptor’s absence, the B1 receptor becomes expressed and activated. To explore the mechanism of B1R-mediated vasodilation, 8 groups of B2R gene–knockout mice received a 2-week infusion of a B1R antagonist (300 &mgr;g · kg−1 · d−1) or vehicle (groups 1 and 2), B1R antagonist or vehicle plus NO inhibition with N&ohgr;-nitro-l-arginine methyl ester (groups 3 and 4), B1R antagonist or vehicle plus cyclooxygenase inhibition with indomethacin (groups 5 and 6), or B1R antagonist or vehicle plus blockade of vasoconstricting prostaglandin (PG) H2 and thromboxane A2 (TxA2) with SQ29548 (groups 7 and 8). The B1R antagonist produced significant (P <0.05) blood pressure increases of 17.7±3.1 mm Hg in group 1 and 10.4±3 mm Hg in group 3, whereas their vehicle-treated respective control groups 2 and 4 had no significant blood pressure changes. Indomethacin abolished the capacity of the B1R antagonist to raise blood pressure, as did blockade of the receptors of PGH2 and TxA2. Injection with the B1R agonist produced a hypotensive response (12±1.3 mm Hg), which was further accentuated by TxA2 blockade (21.7±4.1 mm Hg). Analysis of B1R gene expression by reverse transcription–polymerase chain reaction (PCR) in cardiac and renal tissues revealed marked expression at baseline, with further upregulation by 1.5- to 2-fold after various manipulations. Expression of the TxA2 receptor gene in renal tissue by quantitative real-time PCR was significantly lower in mice treated with the B1R antagonist, consistent with increased levels of agonist for this receptor. The data confirm that the B1R becomes markedly expressed in the absence of B2R and suggest that it contributes to vasodilation by inhibiting a vasoconstricting product of the arachidonic acid cascade acting via the PGH2/TxA2 receptor.

Cell Signaling, Internalization, and Nuclear Localization of the Angiotensin Converting Enzyme in Smooth Muscle and Endothelial Cells

The angiotensin converting enzyme (ACE) catalyzes the extracellular formation of angiotensin II, and degradation of bradykinin, thus regulating blood pressure and renal handling of electrolytes. We have previously shown that exogenously added ACE elicited transcriptional regulation independent of its enzymatic activity. Because transcriptional regulation generates from protein-DNA interactions within the cell nucleus we have investigated the initial cellular response to exogenous ACE and the putative internalization of the enzyme in smooth muscle cells (SMC) and endothelial cells (EC). The following phenomena were observed when ACE was added to cells in culture: 1) it bound to SMC and EC with high affinity (Kd = 361.5 ± 60.5 pm) and with a low binding occupancy (Bmax = 335.0 ± 14.0 molecules/cell); 2) it triggered cellular signaling resulting in late activation of focal adhesion kinase and SHP2; 3) it modulated platelet-derived growth factor receptor-β signaling; 4) it was endocytosed by SMC and EC; and 5) it transited through the early endosome, partially occupied the late endosome and the lysosome, and was localized to the nuclei. The incorporation of ACE or a fragment of it into the nuclei reached saturation at 120 min, and was preceded by a lag time of 40 min. Internalized ACE was partially cleaved into small fragments. These results revealed that extracellular ACE modulated cell signaling properties, and that SMC and EC have a pathway for delivery of extracellular ACE to the nucleus, most likely involving cell surface receptor(s) and requiring transit through late endosome/lysosome compartments.

Blockade of platelet alpha2B-adrenergic receptors: a novel antiaggregant mechanism.

BACKGROUND Platelets play a vital role in hemostasis and thrombosis. Catecholamines have a profound effect on platelet aggregation and atherothrombosis but the exact mechanism involved is insufficiently understood. In this report, we demonstrate the existence and role of alpha2B-adrenergic receptors (α2B-ARs) in normal human platelets. METHODS Sixteen healthy individuals were recruited as donors of normal blood from which platelets were isolated. The presence of α2B-ARs in platelets was proven by Western blot analysis. In order to investigate their function, we performed light transmittance aggregometry and platelet function activity tests by examining the inhibitory effects of specific α2B-AR antibodies and of the selective α2B-AR antagonist ARC 239. RESULTS Pretreatment of human platelets with agents that selectively block α2B-ARs showed a substantial inhibition in platelet aggregation that had been induced by adenosine diphosphate (ADP), by epinephrine and by arachidonic acid. The percent aggregation decreased from 81.5 ± 1.7% to 35.8 ± 5% and to 24 ± 4.6% for ADP with α2B-Abs and ARC 239 respectively, from 72.2 ± 1.9% to 25.5 ± 4.3% and to 8.8 ± 1.7% for epinephrine with α2B-Abs and ARC 239 respectively, and from 87 ± 2.1% to 47.9 ± 6.2% and to 61.2 ± 5.7% for arachidonic acid with α2B-Abs and ARC 239 respectively, p<0.05 for all. Additionally, collagen/epinephrine closure time increased from 120.8 ± 6.1s to 189.5 ± 39.5s (p=0.001). CONCLUSIONS Our results reveal that contrary to previous knowledge, the α2B-AR subtype does exist in platelets and is an important regulator of aggregation. Inhibition of α2B-ARs in platelets may offer a novel therapeutic opportunity in the prevention of atherothrombotic events.

Hypertension in Transgenic Mice With Brain-Selective Overexpression of the α2B-Adrenoceptor

BACKGROUND Previous studies have shown that the presynaptic alpha(2B)-adrenoceptor subtype in the central nervous system has a sympathoexcitatory function and its activation leads to a hyperadrenergic hypertensive state. The purpose of this project was to develop a novel hyperadrenergic model, a transgenic (TG) mouse model with brain-selective overexpression of the alpha(2B)-adrenergic receptor (alpha(2B)-AR). METHODS We used Southern blot analysis to confirm transgene, real-time PCR to assess gene expression, western Blot analysis and immunohistology to assess protein expression and localization in brain areas. Indirect blood pressure (BP) and heart rate were recorded. RESULTS In TG mice there was a 1.8-fold increase in alpha(2B)-AR protein expression compared to wild-type (WT) mice. Immunostaining of brain sections revealed that concentration of alpha(2B)-AR was much more pronounced in TG than in WT mice. Systolic BP at 8 weeks of age was significantly elevated in TG 130 +/- 6 mm Hg, compared with WT control nontransgenic littermates of the same age 107 +/- 7 mm Hg, (P < 0.05), indicating that the TG mice had indeed developed hypertension. CONCLUSIONS We have therefore documented that overexpression of the alpha(2B)-AR gene leads to increased production of alpha(2B)-AR protein in brain regions known to regulate central sympathetic outflow, thus resulting in sustained BP elevation. This is a unique model of experimental hypertension driven purely by overexpression of the alpha(2B)-AR that would result in an overactive sympathetic system and would be suitable for testing the pharmacologic properties of potential therapeutic agents.