Anna Franca Milia

Long-term blood pressure telemetry in AT2 receptor-disrupted mice.

Objectives The hypertension in AT2 receptor knockout mice is imperfectly defined. Therefore, we investigated the influence of dietary salt loading and deoxycorticosterone (DOCA)-salt treatment on blood pressure and diurnal patterns of blood pressure in these mice by radiotelemetry. Methods We used telemetry in AT2 receptor knockout and wild-type mice to measure blood pressure, heart rate, aortic pressure d p/dt, locomotor activity, and circadian rhythms. Salt-related effects were studied by increasing the salt in chow to 4%, adding 1% saline in drinking water, and by DOCA-salt treatment. Results Baseline blood pressures were higher in AT2 receptor knockout than in wild-type mice and were not affected by increasing the salt intake. The blood pressure increase was steeper and greater in AT2 receptor knockout than in wild-type mice after DOCA-salt treatment. A circadian rhythm of blood pressure and heart rate, with higher values during the night, was seen in wild-type, but not in AT2 receptor knockout mice. In AT2 receptor knockout mice, this rhythm was only significant when daily salt intake was increased or when DOCA-salt hypertension was induced. The acrophase of blood pressure and heart rate was found between 2000 and 2400 h and was in accordance with the maximum physical activity. Conclusion These data suggest that AT2 knockout mice display slight hypertension which is not salt-sensitive. On the other hand, the susceptibility to develop DOCA-salt hypertension is increased. The study also illustrates the power of telemetry in monitoring long-term cardiovascular changes and circadian blood pressure and heart rate rhythms in genetically engineered mice.

Cardiovascular Effects of Nociceptin in Unanesthetized Mice

We evaluated the systemic hemodynamic effects induced by nociceptin (NC) and NC-related peptides, including the NC receptor antagonist [Phe1psi(CH2-NH)Gly2]NC(1-13)NH2 ([F/G]NC(1-13)NH2) in unanesthetized normotensive Swiss Morini mice. Bolus intravenous injection of NC decreased mean blood pressure and heart rate. The hypotensive response to 10 nmol/kg NC lasted <10 minutes, whereas a more prolonged hypotension was evoked by 100 nmol/kg (from 114+/-3 to 97+/-2 mm Hg at 10 minutes, P<0.01). The latter dose reduced heart rate from 542+/-43 to 479+/-31 beats/min (P<0.05) and increased aortic blood flow by 41+/-5% (P<0.05). Hypotension and bradycardia were also evoked by NC(1-17)NH2 and NC(1-13)NH2 fragments, whereas NC(1-13)OH and NC(1-9)NH2 were ineffective. Thiorphan, an inhibitor of neutral endopeptidase 24.11, enhanced the hypotension induced by NC(1-13)NH2 and revealed the ability of NC(1-13)OH to decrease mean blood pressure. [F/G]NC(1-13)NH2, a recently synthesized antagonist of the NC receptor, did not alter basal mean blood pressure or heart rate, but it prevented the hypotension, bradycardia, and increase in aortic blood flow evoked by NC. In contrast, [F/G]NC(1-13)NH2 did not alter the hypotension induced by bradykinin or endomorphin-1 (a micro-receptor agonist), and the bradycardia induced by leu-enkephalin (a delta-receptor agonist) or U504885 (a synthetic kappa-receptor agonist). In conclusion, NC and some of its fragments cause hypotension and bradycardia and increase aortic blood flow in mice, with the NC(1-13) sequence being critical for these biological effects. Our results also demonstrate that the compound [F/G]NC(1-13)NH2 is a potent and selective antagonist of the NC receptor in vivo.

Protease-Activated Receptor-2 Stimulates Angiogenesis and Accelerates Hemodynamic Recovery in a Mouse Model of Hindlimb Ischemia

Abstract— Proteinase-activated receptors (PAR-2) are expressed by the cardiovascular system and mediate vasodilation, plasma protein extravasation, and endothelial cell proliferation, all regarded as essential steps for neovascularization. We investigated the angiogenic action of PAR-2 signaling in vivo. The effect of the PAR-2 activating peptide (PAR-2AP, SLIGRL-NH2) was assessed in the absence of ischemia, and the therapeutic potential of PAR-2AP and the PAR-2 agonist trypsin (at 300 and 1.5 nmol IM daily for 21 days, respectively) was also tested in mice subjected to unilateral limb ischemia. PAR-2AP increased capillarity in normoperfused adductor skeletal muscles, whereas neither the vehicle of the PAR2-AP nor the PAR-2 reverse peptide (PAR-2RP, LRGILS-NH2) did produce any effect. In addition, both PAR-2AP and trypsin enhanced reparative angiogenic response to limb ischemia, an effect that was not produced by PAR-2RP or the vehicle of PAR-2 agonists. Potentiation of reparative angiogenesis by PAR-2AP or trypsin resulted in an accelerated hemodynamic recovery and enhanced limb salvage. In conclusions, our study is the first to demonstrate the angiogenic potential of PAR-2 stimulation in vivo. If similar effects occur in humans, PAR-2AP agonists could have some therapeutic potential for the treatment of tissue ischemia.

Prevention of Diabetes-Induced Microangiopathy by Human Tissue Kallikrein Gene Transfer

Background—Microvascular insufficiency represents a major cause of end-organ failure among diabetics. Methods and Results—In streptozotocin-induced diabetic mice, we evaluated the potential of human tissue kallikrein (hTK) gene as a sole therapy against peripheral microangiopathy. Local delivery of hTK gene halted the progression of microvascular rarefaction in hindlimb skeletal muscle by inhibiting apoptosis, thus ensuring an improved hemodynamic recovery in case of supervening vascular occlusion. The curative action of hTK did not necessitate insulin supplementation. Application of gene therapy at a stage of established microangiopathy stimulated vascular regeneration. Conclusions—Our studies indicate that hTK may represent a useful tool for the treatment of microvascular complications in diabetics.

Cardiac hypertrophy and microvascular deficit in kinin B2 receptor knockout mice.

Abstract—Experimental and clinical evidence suggests kinin involvement in adaptive myocardial growth. Kinins are growth-inhibitory to cardiomyocytes. Knockout of kinin B2 receptor (B2R) signaling causes dilated and failing cardiomyopathy in 129/J mice, and a 9-bp deletion polymorphism of human B2R is associated with reduced receptor expression and exaggerated left ventricular growth response to physical stress. We reasoned that genetic background and aging may significantly influence the impact of B2R mutation on cardiac phenotype. The theory was challenged in C57BL/6 mice, a strain that naturally differs from the 129/J strain, carrying 1 instead of 2 renin genes. C57BL/6 B2R knockouts (B2R-KO) showed higher blood pressure and heart rate levels (P <0.05) compared with wild-type controls (WT) at all ages examined. At 12 months, left ventricular contractility and diastolic function were mildly altered (P <0.05) and histological and morphological analyses revealed ventricular hypertrophy and cardiomyocyte enlargement in B2R-KO (P <0.01). Reparative fibrosis was enhanced by 208% and capillary density reduced by 38% (P <0.01). Functional and structural alterations induced by B2R deletion in C57BL/6 mice were less severe than those reported previously in the 129/J strain. We conclude that interaction of B2R signaling with other genetic determinants influences aging-related changes in myocardial structure and function. These findings may help us understand the role of kinins in the development of cardiac failure.

Renovascular Hypertension in Bradykinin B2-Receptor Knockout Mice

We evaluated whether kinins exert a protective action against the development of two-kidney, one clip (2K1C) hypertension, a model characterized by an activated renin-angiotensin system in the ischemic kidney and increased expression of the bradykinin (BK) B2 receptor in the contralateral kidney. BK B2-receptor knockout (B2-/-), wild-type (B2+/+), and heterozygous (B2+/-) mice underwent clipping of the left renal artery, with the other kidney remaining untouched. Basal systolic blood pressure (SBP, via tail-cuff plethysmography) was higher in B2-/- mice than in B2+/- or B2+/+ mice (121+/-2 versus 113+/-2 and 109+/-1 mm Hg; P<0.05 for both comparisons). SBP did not change from basal values after sham operation, but it increased in mice that underwent clipping. The increase in SBP was greater in 2K1C B2-/- mice than in B2+/- or B2+/+ mice (28+/-2 versus 14+/-2 and 14+/-2 mm Hg, respectively, at 2 weeks; P<0.05 for both comparisons). Blockade of the BK B2 receptor by Icatibant enhanced the pressure response to clipping in B2+/+ mice (29+/-2 mm Hg at 2 weeks). Intra-arterial mean blood pressure (MBP) was higher in 2K1C than in respective sham-operated mice, with the MBP difference being higher in B2-/- mice (32 and 38 mm Hg, at 2 and 4 weeks, respectively), and higher in B2+/+ mice given Icatibant (30 and 32 mm Hg) than in B2+/+ mice without Icatibant (17 and 18 mm Hg). At 4 weeks, acute injection of an angiotensin type 1 receptor antagonist normalized the MBP of 2K1C hypertensive mice. A tachycardic response was observed 1 week after clipping in B2-/- and B2+/- mice, but this effect was delayed in B2+/+ mice. However, the HR response to clipping in B2+/+ mice was enhanced by Icatibant. Within each strain, heart weight to body weight ratio was greater in 2K1C hypertensive mice than in sham-operated control animals (B2-/-: 5.7+/-0.1 versus 5.2+/-0.1; B2+/+: 5.1+/-0.1 versus 4.5+/-0.1; P<0.01 for both comparisons). The clipped kidney weight to nonclipped kidney weight ratio was consistently reduced in mice with 2K1C hypertension. Our results indicate that kinins acting on the BK B2 receptor exert a protective action against excessive blood pressure elevation during early phases of 2K1C hypertension.

Normal blood pressure and renal function in mice lacking the bradykinin B(2) receptor.

Telemetric blood pressure determinations, heart rate measurements, and pressure-natriuresis-diuresis experiments were used to characterize cardiovascular and renal function in bradykinin B2 receptor knockout mice fed mouse chow containing 0.25% NaCl or mouse chow containing 4% NaCl. In B2 receptor knockout mice fed usual mouse chow, the mean arterial blood pressure leveled between 108±1 and 110±3 mm Hg, and the heart rate leveled between 520±26 and 525±29 bpm, values that were not different from those measured in B1 receptor knockout mice or 129Sv/J control mice. Increasing dietary salt intake did not affect mean arterial blood pressure and heart rate. Accordingly, pressure-natriuresis curves, pressure-diuresis curves, renal blood flow, and glomerular filtration rate were not different between B2 receptor knockout and 129Sv/J mice. Increasing dietary salt intake to 4% increased renal blood flow to levels between 8.41 and 9.50 mL/min per gram kidney wet weight in 129Sv/J mice, whereas in B2 receptor-deficient mice, renal blood flow was not affected and ranged between 6.85 and 7.88 mL/min per gram kidney wet weight. Other renal function parameters were not affected. Absence of B2 receptor function was verified in B2 receptor knockout mice with bradykinin infusion. These data suggest that the absence of B2 receptor function does not necessarily make B2 receptor knockout mice hypertensive or induce salt sensitivity. Presumably, differences in the genetic background or an adaptation to the loss of B2 receptor function may account for these results, in contrast with earlier reports involving B2 receptor knockout mice. We hold the latter possibility to be more likely and to be a fruitful possibility for future research.

Cytochrome P450–Dependent Renal Arachidonic Acid Metabolism in Desoxycorticosterone Acetate–Salt Hypertensive Mice

Cytochrome P450 (P450)-dependent arachidonic acid metabolites may act as mediators in the regulation of vascular tone and renal function. We studied arachidonic acid hydroxylase activities in renal microsomes from normotensive NMRI mice, desoxycorticosterone acetate (DOCA)-salt hypertensive mice, and DOCA-salt mice treated with either lovastatin or bezafibrate, both of which improve hemodynamics in this model. Control renal microsomes had arachidonic acid hydroxylase activities of 175±12 pmol · min−1 · mg−1. The metabolites formed were 20- and 19-hydroxyarachidonic acid, representing ≈80% and ≈20% of the total hydroxylation. Treatment with DOCA-salt resulted in significantly decreased hydroxylase activities (to 84±4 pmol · min−1 · mg−1) of the total microsomal P450 content and a decrease in immunodetectable Cyp4a proteins. Lovastatin had no effect on these variables, whereas bezafibrate increased arachidonic acid hydroxylase activities to 163±12 pmol · min−1 · mg−1. In situ hybridization with probes for Cyp4a-10, 12, and 14 revealed that Cyp4a-14 was the P450 isoform most strongly induced by bezafibrate. The expression was concentrated in the cortical medullary junction and was localized predominantly in the proximal tubules. In conclusion, these results suggest that the capacity to produce 20-hydroxyarachidonic acid is impaired in the kidneys of DOCA-salt hypertensive mice. Furthermore, bezafibrate may ameliorate hemodynamics in this model by restoring P450-dependent arachidonic acid hydroxylase activities. Lovastatin, on the other hand, exerts its effects via P450-independent mechanisms.

Enhanced Blood Pressure Sensitivity to Deoxycorticosterone in Mice With Disruption of Bradykinin B2 Receptor Gene

The renal kallikrein-kinin system is activated under conditions of mineralocorticoid excess. To evaluate whether endogenous kinins exert a protective role against the development of mineralocorticoid-induced hypertension, we studied the cardiovascular effects induced by long-term administration of deoxycorticosterone (DOC; 0.3 micromol/g body wt s.c. once per week for 6 weeks) or vehicle in transgenic mice (Bk2r-/-) lacking the bradykinin B2 receptor gene and in wild-type controls (Bk2r+/+). Under basal conditions, Bk2r-/- mice showed higher systolic blood pressure (tail-cuff plethysmography) than wild-type Bk2r+/+ and heterozygous Bk2r+/- mice (121+/-2 versus 114+/-2 and 115+/-2 mm Hg, respectively; P<0.05 for both comparisons). Heart rate was higher in Bk2r-/- and Bk2r+/- than in Bk2r+/+ (459+/-12 and 418+/-7 versus 390+/-7 bpm; P<0.05 for both comparisons). Systolic blood pressure was increased by DOC in transgenic as well as in wild-type mice, whereas no change was induced by the vehicle. The pressor response to DOC was more rapid and pronounced in Bk2r-/- than in Bk2r+/+ and Bk2r+/- (30+/-5 versus 15+/-4 and 6+/-3 mm Hg, respectively, at 3 weeks; P<0.01 for both comparisons). The difference in systolic blood pressure was consistent with that detected by direct intra-arterial measurements of mean blood pressure. Neither DOC nor its vehicle altered heart rate or gain in body weight over time. Under basal conditions, urinary sodium excretion did not differ between strains. During DOC administration, cumulative urinary sodium excretion was lower in Bk2r-/- than in Bk2r+/+ (2.59+/-0.15 versus 3.31+/-0.22 mmol, respectively, during the first week; P<0.05). Urinary kinin excretion was increased by DOC in both Bk2r-/- (from 0.65+/-0.17 to 4.27+/-0.80 pmol/24 h; P<0.01) and Bk2r+/+ (from 0.55+/-0.09 to 6.27+/-1.48 pmol/24 h; P<0.05). The increase in urinary kinin excretion was similar between strains. These results show that integrity of the bradykinin B2 receptor is essential for regulation of blood pressure and heart rate under basal conditions. In addition, they indicate that activation of the kallikrein-kinin system represents a compensatory response against the development of hypertension induced by mineralocorticoid excess.

Role of the bradykinin B2 receptor in the maturation of blood pressure phenotype: lesson from transgenic and knockout mice.

The binding of bradykinin (BK) to its B2 receptor results in a wide spectrum of biological effects including vasodilation, smooth muscle contraction and relaxation, pain, and inflammation. In order to gain a better insight into the physiological function of this potent vasoactive peptide, murine models have been created by the use of gene insertion or deletion. The results of studies using these strategies are revisited in the present article. In transgenic mice harboring the human BK B2 receptor cDNA (cHBKR), expression of the transgene was identified in the aorta, brain, heart, lung, liver, kidney, uterus and prostate gland by RT-PCR Southern blot analysis. These mice displayed an exaggerated hypotensive response to intra-aortic injection of BK, whereas the blood pressure of knockout mice, homozygous for targeted disruption of the endogenous gene, was insensitive to BK. Two transgenic mouse lines expressing the human BK B2 receptor showed a significant reduction of systolic tail-cuff blood pressure (84 +/- 1 mm Hg, n = 28; 80 +/- 1 mm Hg, n = 24; P < 0.001) compared with the control littermates (97 +/- 1 mm Hg, n = 52). Systolic blood pressure was elevated in BK B2 receptor knockout mice (124 +/- 1 mm Hg, n = 38). In heterozygous mice, systolic blood pressure was similar to that of controls until 5 month-old, then it raised to the elevated levels of knockout mice at 7 months of age. Together these data indicate that kinins acting through the B2 receptor play a role in the development of the blood pressure phenotype.