Hélène Bachelard

NTPDase1 (CD39) controls nucleotide-dependent vasoconstriction in mouse

AIMS Extracellular nucleotides are vasoactive molecules. The concentrations of these molecules are regulated by ectonucleotidases. In this study, we investigated the role of the blood vessel ectonucleotidase NTPDase1, in the vasoconstrictor effect of nucleotides using Entpd1(-/-) mice. METHODS AND RESULTS Immunofluorescence, enzyme histochemistry, and HPLC analysis were used to evaluate both NTPDase expression and activity in arteries and isolated vascular smooth muscle cells (VSMCs). Vascular reactivity was evaluated in vitro and mean arterial blood pressure was recorded in anesthetized mice after nucleotide i.v. infusion. Expression of nucleotide receptors in VSMCs was determined by RT-PCR. Entpd1(-/-) mice displayed a dramatic deficit of nucleotidase activity in blood vessel wall in situ and in VSMCs in comparison to control mice. In aortic rings from Entpd1(-/-) mice, UDP and UTP induced a potent and long-lasting constriction contrasting with the weak response obtained in wild-type rings. This constriction occurred through activation of P2Y(6) receptor and was independent of other uracil nucleotide-responding receptors (P2Y(2) and P2Y(4)). UDP infusion in vivo increased blood pressure and this effect was potentiated in Entpd1(-/-) mice. In addition, pressurized mesenteric arteries from Entpd1(-/-) mice displayed an enhanced myogenic response, consistent with higher local concentrations of endogenously released nucleotides. This effect was inhibited by the P2 receptor antagonist RB-2. CONCLUSION NTPDase1 is the major enzyme regulating nucleotide metabolism at the surface of VSMCs and thus contributes to the local regulation of vascular tone by nucleotides.

Endothelial and vascular dysfunctions and insulin resistance in rats fed a high-fat, high-sucrose diet

This study was designed to examine the effects of a high-fat, high-sucrose (HFHS) diet on vascular and metabolic actions of insulin. Male rats were randomized to receive an HFHS or regular chow diet for 4 wk. In a first series of experiments, the rats had pulsed Doppler flow probes and intravascular catheters implanted to measure blood pressure, heart rate, and regional blood flows. Insulin sensitivity and vascular responses to insulin were assessed during a euglycemic hyperinsulinemic clamp performed in conscious rats. In a second series of experiments, new groups of rats were used to examine skeletal muscle glucose transport activity and to determine in vitro vascular reactivity, endothelial nitric oxide synthase (eNOS) protein expression in muscle and vascular tissues and endothelin content, nitrotyrosine formation, and NAD(P)H oxidase protein expression in vascular tissues. The HFHS-fed rats displayed insulin resistance, hyperinsulinemia, hypertriglyceridemia, hyperlipidemia, elevated blood pressure, and impaired insulin-mediated renal and skeletal muscle vasodilator responses. A reduction in endothelium-dependent vasorelaxation, accompanied by a decreased eNOS protein expression in muscles and blood vessel endothelium, and increased vascular endothelin-1 protein content were also noted in HFHS-fed rats compared with control rats. Furthermore, the HFHS diet induced a reduced insulin-stimulated glucose transport activity in muscles and increased levels of NAD(P)H oxidase protein and nitrotyrosine formation in vascular tissues. These findings support the importance of eNOS protein in linking metabolic and vascular disease and indicate the ability of a Westernized diet to induce endothelial dysfunction and to alter metabolic and vascular homeostasis.

Fish oil and argan oil intake differently modulate insulin resistance and glucose intolerance in a rat model of dietary-induced obesity

We investigated the potential metabolic benefits of fish oil (FO) or vegetable argan oil (AO) intake in a dietary model of obesity-linked insulin resistance. Rats were fed a standard chow diet (controls), a high-fat/high-sucrose (HFHS) diet, or an HFHS diet in which 6% of the fat was replaced by either FO or AO feeding, respectively. The HFHS diet increased adipose tissue weight and insulin resistance as revealed by increased fasting glucose and exaggerated glycemic and insulin responses to a glucose tolerance test (intraperitoneal glucose tolerance test). Fish oil feeding prevented fat accretion, reduced fasting glycemia, and normalized glycemic or insulin responses to intraperitoneal glucose tolerance test as compared with HFHS diet. Unlike FO consumption, AO intake failed to prevent obesity, yet restored fasting glycemia back to chow-fed control values. Insulin-induced phosphorylation of Akt and Erk in adipose tissues, skeletal muscles, and liver was greatly attenuated in HFHS rats as compared with chow-fed controls. High-fat/high-sucrose diet-induced insulin resistance was also confirmed in isolated hepatocytes. Fish oil intake prevented insulin resistance by improving or fully restoring insulin signaling responses in all tissues and isolated hepatocytes. Argan oil intake also improved insulin-dependent phosphorylations of Akt and Erk; and in adipose tissue, these responses were increased even beyond values observed in chow-fed controls. Taken together, these results strongly support the beneficial action of FO on diet-induced insulin resistance and glucose intolerance, an effect likely explained by the ability of FO to prevent HFHS-induced adiposity. Our data also show for the first time that AO can improve some of the metabolic and insulin signaling abnormalities associated with HFHS feeding.

Induction of insulin resistance by high-sucrose feeding does not raise mean arterial blood pressure but impairs haemodynamic responses to insulin in rats

This study was undertaken to further investigate the effects of a sucrose‐enriched diet on vascular function and insulin sensitivity in rats. Male Sprague‐Dawley rats were randomized to receive a sucrose‐ or regular rat chow‐diet for 4 weeks. A first group of sucrose‐ and chow‐fed rats was instrumented with pulsed Doppler flow probes and intravascular catheters to determine blood pressure, heart rate, regional blood flows and insulin sensitivity in conscious rats. Insulin sensitivity was assessed by the euglycemic hyperinsulinemic clamp technique. Glucose transport activity was examined in isolated muscles by using the glucose analogue [3H]‐2‐deoxy‐D‐glucose. A second group of sucrose‐ and chow‐fed rats was used to obtain information regarding nitric oxide synthase (NOS) isozymes protein expression in muscles, and determine endothelin content in vascular tissues isolated from both dietary groups. Sucrose feeding was found to induce insulin resistance, but had no effect on resting blood pressure, heart rate, or regional haemodynamics. This insulin resistance was accompanied by alteration in the vascular responses to insulin. Insulin‐mediated skeletal muscle vasodilation was impaired, whereas the mesenteric vasoconstrictor response was potentiated in sucrose‐fed rats. A reduction in eNOS protein content in muscle and an increase in vascular endothelin peptide were noted in these animals. Moreover, a reduction in insulin‐simulated glucose transport activity was also noted in muscles isolated from sucrose‐fed rats. Together these data suggest that a cluster of metabolic and haemodynamic abnormalities occur in response to the intake of simple sugars in rats.

Regional haemodynamic effects of μ‐, δ‐, and κ‐opioid agonists microinjected into the hypothalamic paraventricular nuclei of conscious, unrestrained rats

1 The cardiovascular effects of bilateral injection into the hypothalamic paraventricular nuclei of selective μ‐, δ‐, and κ‐opioid receptor agonists were investigated in conscious, unrestrained Wistar Kyoto rats, chronically instrumented with pulsed Doppler flow probes for measurement of regional haemodynamics. 2 The selective μ‐agonist [D‐Ala2, MePhe4, Gly5ol]enkephalin (DAMGO), injected bilaterally into the hypothalamic paraventricular nuclei (0.01‐1.0 nmol), caused increases in blood pressure, tachycardias, vasoconstriction in renal and superior mesenteric vascular beds and substantial vasodilatation in the hindquarter vascular bed. 3 The administration of increasing doses (0.01–5.0 nmol) of the selective δ‐agonist [D‐Phe2,5]enkephalin (DPDPE) or the selective κ‐agonist, U50488H into the paraventricular nuclei (PVN) had no significant effect on blood pressure, heart rate, or regional haemodynamics. 4 Together, the present results are further evidence of a role for opioid peptides, especially acting at μ‐receptors in the PVN, in the central regulation of the cardiovascular system, whereas a role for opioid peptides, acting at δ‐ and κ‐receptors in the PVN, seems less obvious from the present results.

Isradipine and insulin sensitivity in hypertensive rats

The present study was designed to investigate the effect of a reduction in blood pressure, by using the calcium channel antagonist isradipine, on insulin sensitivity and vascular responses to insulin in conscious spontaneously hypertensive male rats (SHR). The rats were instrumented with intravascular catheters and pulsed Doppler flow probes to measure blood pressure, heart rate, and blood flows. Insulin sensitivity was assessed by the euglycemic-hyperinsulinemic clamp technique. Two groups of rats received isradipine at a dose of 0.05 or 0.15 mg ⋅ kg-1 ⋅ h-1, whereas a third group received a continuous infusion of vehicle (15% DMSO). Both doses of isradipine were found to decrease mean blood pressure (-25 ± 4 mmHg at the dose of 0.05 mg ⋅ kg-1 ⋅ h-1and -20 ± 2 mmHg at the dose of 0.15 mg ⋅ kg-1 ⋅ h-1) and to improve insulin sensitivity. Moreover, in the rats treated with the low dose of isradipine, we observed vasodilations in renal, superior mesenteric, and hindquarter vascular beds. In the untreated group, the euglycemic infusion of insulin (4 mU ⋅ kg-1 ⋅ min-1) was found to cause vasoconstrictions in superior mesenteric and hindquarter vascular beds, but no changes in mean blood pressure, heart rate, or renal vascular conductance were found. In contrast, in the isradipine-treated groups, the same dose of insulin was found to produce vasodilations in the renal vascular bed and to abolish the vasoconstrictor responses previously observed. We concluded that short-term treatment with isradipine in SHR can lower blood pressure and improve insulin sensitivity, mainly through hemodynamic factors, as supported by experiments with hydralazine as a positive vasodilator control.The present study was designed to investigate the effect of a reduction in blood pressure, by using the calcium channel antagonist isradipine, on insulin sensitivity and vascular responses to insulin in conscious spontaneously hypertensive male rats (SHR). The rats were instrumented with intravascular catheters and pulsed Doppler flow probes to measure blood pressure, heart rate, and blood flows. Insulin sensitivity was assessed by the euglycemic-hyperinsulinemic clamp technique. Two groups of rats received isradipine at a dose of 0.05 or 0.15 mg. kg-1. h-1, whereas a third group received a continuous infusion of vehicle (15% DMSO). Both doses of isradipine were found to decrease mean blood pressure (-25 +/- 4 mmHg at the dose of 0.05 mg. kg-1. h-1 and -20 +/- 2 mmHg at the dose of 0.15 mg. kg-1. h-1) and to improve insulin sensitivity. Moreover, in the rats treated with the low dose of isradipine, we observed vasodilations in renal, superior mesenteric, and hindquarter vascular beds. In the untreated group, the euglycemic infusion of insulin (4 mU. kg-1. min-1) was found to cause vasoconstrictions in superior mesenteric and hindquarter vascular beds, but no changes in mean blood pressure, heart rate, or renal vascular conductance were found. In contrast, in the isradipine-treated groups, the same dose of insulin was found to produce vasodilations in the renal vascular bed and to abolish the vasoconstrictor responses previously observed. We concluded that short-term treatment with isradipine in SHR can lower blood pressure and improve insulin sensitivity, mainly through hemodynamic factors, as supported by experiments with hydralazine as a positive vasodilator control.

Epicardial application of bradykinin elicits pressor effects and tachycardia in guinea pigs. Possible mechanisms

Topical application of bradykinin (BK) to the surface of the left ventricle (epicardial application) of anesthetized guinea pigs elicited dose-dependent pressor effects and tachycardia. The pressor effect of epicardial BK was reduced by prior systemic treatment of animals with pentolinium or a combination of phentolamine and propranolol, but it was not affected by acute bilateral vagotomy or systemic administration of atropine, indomethacin, naloxone or a combination of mepyramine and cimetidine. The tachycardia caused by epicardial BK was not affected by any of the aforementioned drugs or by section of the vagi. Both the pressor effect and tachycardia evoked by epicardial BK were abolished by prior epicardial application of lidocaine, a local anesthetic, or by chronic systemic capsaicin treatment. These results suggest that the pressor effect of epicardial BK is partially reflex in nature and likely to result from the stimulation by BK of cardiac sympathetic, capsaicin-sensitive primary afferents, whereas the tachycardia caused by epicardial BK could be mediated by an intracardiac release of (a) cardioaccelerating substance(s) from cardiac, capsaicin-sensitive sensory nerve fibers and/or terminals.

Effect of troglitazone on vascular and glucose metabolic actions of insulin in high—sucrose-fed rats

In rats, diets high in simple sugar induce insulin resistance and alter vascular reactivity. The present study was designed to evaluate the effects of 5 weeks treatment with troglitazone on insulin sensitivity, regional hemodynamics, and vascular responses to insulin in chow-fed and high-sucrose-fed rats. Male rats were randomly divided in 4 groups to receive a regular chow diet in the absence (group 1) or presence of troglitazone (0.2% in food; group 2), or a sucrose-enriched diet in the absence (group 3) or presence of troglitazone (group 4) for 5 weeks. The rats were instrumented with Doppler flow probes and intravascular catheters to determine blood pressure, heart rate, and regional blood flows. Insulin sensitivity was assessed by the euglycemic hyperinsulinemic clamp technique. Glucose transport activity was examined in isolated muscles. Sucrose feeding was found to induce insulin resistance and to impair the insulin-mediated skeletal muscle vasodilation. Treatment with troglitazone was found to increase whole-body insulin sensitivity in sucrose- and chow-fed rats, but had no effect on skeletal muscle glucose transport activity measured in isolated muscles from both dietary groups. Changes in regional hemodynamics were observed in both dietary cohorts treated with troglitazone, and the hindquarter vasoconstrictor response to insulin noted in sucrose-fed rats was abolished by the treatment. The vascular effects of troglitazone, and its insulin-related attenuating effects on contractile tone, could have contributed, in part, to improve insulin action on peripheral glucose disposal, presumably by improving blood flow distribution and glucose delivery.

Altered cardiac bradykinin metabolism in experimental diabetes caused by the variations of angiotensin-converting enzyme and other peptidases

The peptidases angiotensin-converting enzyme (ACE) and neutral endopeptidase 24.11 (NEP) mediate most of the kinin catabolism in normal cardiac tissue and are the molecular targets of inhibitory drugs that favorably influence diabetic complications. We studied the variations of those kininases in the myocardium of rats in experimental diabetes. ACE and NEP activities were significantly decreased in heart membranes 4-8weeks post-streptozotocin (STZ) injection. However, insulin-dependent diabetes did not modify significantly bradykinin (BK) half-life (t(1/2)) while the effect of both ACE (enalaprilat) and ACE and NEP (omapatrilat) inhibitors on BK degradation progressively decreased, which may be explained by the upregulation of other unidentified metallopeptidase(s). In vivo insulin treatment restored the activities of both ACE and NEP. ACE and NEP activities were significantly higher in hearts of young Zucker rats than in those of Sprague-Dawley rats. BK t(1/2) and the effects of peptidase inhibitors on t(1/2) varied accordingly. It is concluded that kininase activities are subjected to large and opposite variations in rat cardiac tissue in type I and II diabetes models. A number of tissue or molecular factors may determine these variations, such as remodeling of cardiac tissue, ectoenzyme shedding to the extracellular fluid and the pathologic regulation of peptidase gene expression.

Capsaicin-sensitive structures as potential target sites for neurotensin and bradykinin in guinea pig atria☆

We tested the influence of capsaicin (CAP) desensitization on the positive chronotropic and inotropic effects of neurotensin (NT), bradykinin (BK), calcitonin gene-related peptide (CGRP) and noradrenaline (NA) in guinea pig isolated atria. The positive chronotropic and inotropic effects of NT and BK were completely inhibited, whereas those elicited by CGRP and NA were either slightly reduced (CGRP) or unaffected (NA), in CAP-desensitized compared to control atria. Cross-desensitization studies using CAP, NT and BK showed that the positive chronotropic and inotropic effects of CAP are slightly affected, whereas those evoked by BK are markedly reduced in NT-desensitized atria. On the other hand, the positive chronotropic and inotropic effects of CAP and NT were similar in BK-desensitized and control atria. The results were interpreted as an indication that NT, BK and CAP produce their excitatory effects in guinea pig atria by interacting with a common population of CAP-sensitive sensory nerve fibers (presumably substance P (SP)- and CGRP-containing nerve fibers). The absence of cross-desensitization between NT or BK and CAP, or between NT and BK, suggests that the activation and desensitization of atrial, CAP-sensitive sensory nerve fibers by the latter agents involve different receptors and/or mechanisms.