Endothelium-dependent and NO-mediated desensitization to vasopressin in rat aorta

Systemic vasoconstriction modulates the responses of pulmonary vasculature and airway to vasoconstrictors in anesthetized rats

PURPOSE

The physiological responses of the pulmonary vasculature and airway to various vasoconstrictors were studied using isolated perfused lungs and pulmonary arteries, but these responses were not systematically studied in in vivo rats. We determined these responses and modulating effects of systemic circulation in anesthetized rats.

METHODS

We measured directly pulmonary arterial pressure (PAP), left atrial pressure (LAP), aortic blood flow, and airway pressure (AWP) to determine pulmonary vascular resistance (PVR), following injections of angiotensin II (ANG II), endothelin-1 (ET-1), vasopressin, phenylephrine and thromboxane A2 mimetic U46619 in anesthetized SD rats.

RESULTS

ANG II, phenylephrine and vasopressin at high doses caused strong systemic vasoconstriction and left heart overload, resulting in a transient increase in LAP and pulmonary congestion, which consequently decreased PVR. Nonetheless, prior to LAP elevation, PVR was slightly but significantly increased by ANG II and phenylephrine. In contrast, ET-1 and U46619 substantially increased PVR in the absence of LAP elevation, while vasopressin did not increase PVR. In separate experiments, PAP and AWP increased when LAP was forcedly elevated. AWP was increased by U46619 through bronchoconstriction and by the other agents through increased LAP-induced pulmonary congestion.

CONCLUSION

Airway constriction is induced by U46619, and pulmonary vasoconstriction is induced strongly by U46619 and ET-1, and weakly by ANG II and phenylephrine, but not by vasopressin in anesthetized rats. ANG II, vasopressin and phenylephrine exert indirectly a transient pulmonary vasodilatory action due to pulmonary congestion evoked by strong systemic vasoconstriction, which may account for weak pulmonary pressor responses to these agents.

Age dependency of vasopressin pulmonary vasodilatory effect in rats

BACKGROUND

Vasopressin is a systemic vasoconstrictor. Its pulmonary vasodilatory effect is controversial, and limited data are available on its use in neonates with pulmonary hypertension. Hypothesizing that the vasopressin-induced pulmonary vasodilation is developmentally regulated, we evaluated its pulmonary and systemic arterial response in newborn and adult rats.

METHODS

Vessels were mounted on a wire myograph, and the vasopressin-induced changes in vasomotor tone measured. The vessel- and age-dependent differences in vasopressin V1a and V2 receptors' expression were evaluated by western blotting.

RESULTS

Vasopressin induced a dose-dependent increase in mesenteric arterial tone at both ages, but of greater magnitude in adult vessels (P < 0.01). At lower concentrations, vasopressin induced pulmonary vasodilation in adult vessels and vasoconstriction in newborn arteries. The adult vasopressin-induced pulmonary vasodilation was inhibited by ibuprofen, suggesting that the response is prostaglandin mediated. Pulmonary tissue V1a receptor protein expression was higher in adult, when compared with newborn arteries (P < 0.01). The adult vessels V1a expression predominated in the pulmonary arteries, and V2 was only detected in mesenteric arteries.

CONCLUSION

The vasopressin-induced pulmonary vasodilation is absent in newborn rats likely due to the lower tissue V1a expression early in life. These animal data challenge the therapeutic use of vasopressin in neonatal pulmonary hypertension.

Thalidomide attenuates nitric oxide-driven angiogenesis by interacting with soluble guanylyl cyclase

BACKGROUND AND PURPOSE

Nitric oxide (NO) promotes angiogenesis by activating endothelial cells. Thalidomide arrests angiogenesis by interacting with the NO pathway, but its putative targets are not known. Here, we have attempted to identify these targets.

EXPERIMENTAL APPROACH

Cell-based angiogenesis assays (wound healing of monolayers and tube formation in ECV304, EAhy926 and bovine arterial endothelial cells), along with ex vivo and in vivo angiogenesis assays, were used to explore interactions between thalidomide and NO. We also carried out in silico homology modelling and docking studies to elucidate possible molecular interactions of thalidomide and soluble guanylyl cyclase (sGC).

KEY RESULTS

Thalidomide inhibited pro-angiogenic functions in endothelial cell cultures, whereas 8-bromo-cGMP, sildenafil (a phosphodiesterase inhibitor) or a NO donor [sodium nitroprusside (SNP)] increased these functions. The inhibitory effects of thalidomide were reversed by adding 8-bromo-cGMP or sildenafil, but not by SNP. Immunoassays showed a concentration-dependent decrease of cGMP in endothelial cells with thalidomide, without affecting the expression level of sGC protein. These results suggested that thalidomide inhibited the activity of sGC. Molecular modelling and docking experiments revealed that thalidomide could interact with the catalytic domain of sGC, which would explain the inhibitory effects of thalidomide on NO-dependent angiogenesis.

CONCLUSION AND IMPLICATIONS

Our results showed that thalidomide interacted with sGC, suppressing cGMP levels in endothelial cells, thus exerting its anti-angiogenic effects. These results could lead to the formulation of thalidomide-based drugs to curb angiogenesis by targeting sGC.

Role of nitric oxide and protein kinase C in the tachyphylaxis to vasopressin in rat aortic rings

The contribution of endothelium-derived mediators and protein kinase C in the tachyphylaxis to arginine vasopressin (AVP) was assessed in the rat aorta. Endothelium-intact (E+) and denuded rings (E-) obtained from the rat thoracic aorta were exposed to three administrations of a supramaximal concentration of AVP (100 nM), lasting 20 min and 45 min apart. N-Omega-nitro-L-arginine (NNLA), a non-selective inhibitor of all isoforms of NO synthase, and AMT, a selective inhibitor for the inducible (iNOS) and neuronal (nNOS) isoforms, diminished the tachyphylaxis to AVP significantly in both E+ and in E- rings. No iNOS could be detected by Western blots in freshly isolated rings or in rings exposed to AVP, despite a strong signal in rings isolated from LPS-treated rats, while nNOS could be constitutively detected. Inhibition of prostaglandins or epoxyeicosatrienoic acids (EETs) synthesis by diclofenac or clotrimazole, respectively, had no effect on tachyphylaxis while combination of these agents diminished tachyphylaxis in E+ only. Combination of NNLA, diclofenac and clotrimazole blocked completely the tachyphylaxis. Inhibition of PKC by either chelerythrine or bisindolylmaleimide I-HCl (BisI) led to a significant diminution of AVP tachyphylaxis only in E-. Activation of PKC with phorbol-12-myristate-13-acetate (PMA) simulated tachyphylaxis to AVP in E- only, effect blocked by the NO donor, SNP. In conclusion, NO produced from constitutive nNOS present in vascular smooth muscle cells participates in tachyphylaxis to AVP. PKC is involved in this tachyphylaxis only in E- rings, the presence of NO probably diminishing the effects of this kinase.

Vasopressin-induced vasoconstriction is dependent on MAPKerk1/2 phosphorylation

To investigate the involvement of the mitogen-activated protein kinase (MAPK) family of extracellular signal-regulated kinase (ERK) 1 and 2 (MAPKerk1/2) in the vasopressin-mediated vasoconstriction in the rat aorta. Vasopressin-induced vasoconstriction was measured in isolated rat thoracic aortae in the presence or absence of MAPKerk1/2 kinase (MKKmek1/2) inhibitors. Thereafter the MAPKerk1/2 phosphorylation in the rat aorta was quantified using Western blot analysis. Vasopressin (1-300 nm) induced a concentration-dependent vasoconstriction, which could be inhibited concentration dependently by the selective MKKmek1/2 inhibitors, PD 98059 (10 and 100 microm) and U 0126 (10 and 100 microm). Western blot analysis revealed a 2.7 +/- 0.6-fold increase in the MAPKerk1/2 phosphorylation induced by vasopressin (300 nm). This phosphorylation could be dose dependently prevented by both PD 98059 (100 microm) and U 0126 (10 and 100 microm). These results indicate that vasoconstriction induced by vasopressin is partly regulated by the MAPKerk1/2 pathway.

Endothelium-dependent desensitization to angiotensin II in rabbit aorta: the mechanisms involved

The aim of this study was to characterize the role of the endothelium in angiotensin II-desensitization and its mechanisms of action. Rabbit aortic rings were exposed to increasing doses of angiotensin II (Ang II, 10–9 to 2.5 × 10–6) to generate two cumulative dose-response curves (CDRC I and II). A 50-min interval separated CDRC I and II. Desensitization was observed at all doses in unrubbed aortic tissue and at lower doses in rubbed aortic tissue. Tachyphylaxis was greater in arteries with endothelium. Treatment of intact rings with L-NG-nitroarginine methyl ester (L-NAME, 10–4 M) did not prevent this phenomenon. However, indomethacin (10–5 M) and miconazol (10–6 M) attenuated Ang II-desensitization. Treatment of unrubbed rings with nifedipine (10–6 M) and cromakalim (10–6 M) inhibited the effect of indomethacin. To confirm the involvement of K+ channels, unrubbed and rubbed aortic rings were treated with the KCa2+ blockers apamin (10–7 M), tetraethylammonium (TEA, 10–3 M), and iberiotoxin (10–8 M), and the KATP blocker glibenclamide (10–5 M). In both arteries apamin, TEA, and glibenclamide abolished the tachyphylaxis without changes in the maximal response. Iberiotoxin diminished Ang II-desensitization in rubbed but not unrubbed arteries. Results from this study suggest that Ang II-desensitization involves endothelium-dependent and -independent mechanisms. Endothelium-dependent desensitization could be mediated by a cyclooxygenase-cytochrome P450 product, which could act by increasing KCa2+ channel activity.Key words: angiotensin II, rabbit aorta, desensitization, endothelium, cyclooxygenase products.

Evidence that nitric oxide regulates AT1-receptor agonist and antagonist efficacy in rat injured carotid artery

Vascular injury stimulates AT1-receptor expression and nitric oxide (NO) production in smooth muscle cells (SMCs). We examined the ability of AT1 agonists and antagonists to regulate vascular tone ex vivo in injured arteries and the possible modulation by SMC-derived NO. Rings of rat carotid arteries were isolated at day 7 after endothelial denudation and stimulated with angiotensin (Ang) II in the absence or presence of the AT1 antagonists losartan, L-158,809, or EXP-3174. Freshly denuded contralateral arteries were used as controls. AngII-induced contractions were similar in control and injured arteries. Losartan caused an insurmountable inhibition of AngII-induced contractions in injured but not control arteries. Enhanced inhibition of AngII in injured arteries also was observed in the presence of L-158,809 and EXP-3174. In the presence of the NO synthesis inhibitor nitromonomethyl-L-arginine (L-NMMA), maximal contractions to AngII were greater in injured than in control vessels, and AT1-receptor blockade with losartan was surmountable in all vessels. Mechanical removal of superficial neointimal SMCs attenuated NO production and normalized the efficacy of losartan in injured arteries. These results suggest a role for NO in reducing the biologic effects of AT1-receptor agonists and potentiating the efficacy of AT1 antagonists in vessels undergoing remodeling after injury.

Characterization of receptors mediating contraction of the rat isolated small mesenteric artery and aorta to arginine vasopressin and oxytocin

1. The exact nature of the receptor subtype(s) involved in the action of arg-vasopressin (AVP) on the rat aorta and small mesenteric artery (SMA) is controversial. Therefore, we have studied the effects of the selective V1A receptor antagonists, OPC 21268 and SR 49059, and the oxytocin (OT) receptor antagonist, atosiban, on the AVP- and OT-induced contractions of the two vessels. 2. AVP and OT displayed similar intrinsic activities in the rat aorta and SMA, but AVP was approximately 130 fold and approximately 500 fold more potent than OT, respectively. In the rat aorta, Hill slopes (nH) were similar for OT and AVP. However, in rat SMA, the OT concentration-effect (E/[A]) curve was significantly steeper than the AVP E/[A] curve (nH, = 3.3+/-0.20, 2.3+/-0.15; P<0.001). 3. In the aorta OPC 21268, SR 49059 and atosiban competitively antagonized the AVP and OT E/[A] curves. Except for atosiban and SR 49059 against AVP, competitive antagonism was also observed in the SMA. Atosiban caused concentration-dependent steepening of the AVP E/[A] curve, whereas SR 49059 decreased the upper asymptote. 4. Schild analysis yielded affinities indicative of V1A receptor involvement in both vessels: pKB/ pA2=9.20 9.48, 7.56 7.71 and 6.19 6.48 for SR 49059, OPC 21268 and atosiban, respectively. 5. Neither AVP nor OT relaxed U46619 pre-contracted aorta or SMA in the presence of SR 49059, suggesting no interference of a vasodilatory component. 6. Despite predominant involvement of V1A receptors in both vessels, the different Hill slopes of AVP and OT E/[A] curves as well as the steepening of the AVP E/[A] curves by atosiban are indicative of receptor heterogeneity in the rat SMA.

Physiological mechanisms in regulation of blood pressure fast frequency variations

Spectral analysis of blood pressure fast oscillations (short-term variability), both in humans and animals, reveals three major frequential domains: the very low-, low- and the high-frequency domain. In this paper, experimental data providing evidence for physiological mechanisms involved in the regulation of blood pressure oscillations such as sympathetic nervous system, renin-angiotensin system, NO, respiration, heart function, and circulating blood volume are reviewed. In addition, novel evidence is provided by the author for vasopressin modulation of the low- and high-frequency blood pressure components. This review suggests that the multiplicity of factors involved in the genesis of the blood pressure spectral components imply utmost caution in interpreting spectral results.