Endothelial modulation and tolerance development in the vasorelaxant responses to nitrate of rabbit aorta

We investigated the endothelial modulations in nitrate tolerance in isolated rabbit aorta. Nitrate tolerance was induced by a 72-h treatment with transdermal nitroglycerin (NTG, 0.4 mg/h) in conscious rabbits, which was verified by a 20-fold increase in the EC50 values [NTG tolerance (6.1 +/- 0.8) x 10(-7) M vs control (3.0 +/- 0.6) x 10(-8) M]. The relaxations to NTG in tolerant and nontolerant aortic strips were enhanced when their endothelia were denuded [E(-)]. In the presence of endothelium [E(+)], NTG-tolerant vessels were not tolerant to acetylcholine (ACh), which can release endothelial nitric oxide (NO), exogenous NO or 8-bromo (Br)-cGMP. In NTG-tolerant and nontolerant vessels with endothelium, concentration-response curves for NO were the same as those in endothelium-absent tolerant vessels. In both NTG-tolerant and nontolerant vessels, treatment with superoxide dismutase (SOD, 20 units/ml), an O2-. scavenger, unaffected the responses to NTG reduced in the presence of endothelium, but treatment with NG-nitro-L-arginine methyl ester (L-NAME, 10(-4) M), an NO synthase (NOS) inhibitor, reversed these reductions. Thus, our data did not indicate that an increased endothelial superoxide O2-. production contributes to nitrate tolerance. Our study suggested that (i) an impaired biotransformation process from NTG to NO is responsible for the occurrence of nitrate tolerance and (ii) vascular response to NTG enhanced by endothelial removal is related to blocked endothelial NO release.     

Organic nitrate tolerance is induced by degradation of some cytochrome P450 isoforms

The mechanism of nitrate tolerance is poorly defined. We studied the rat P450 (CYP)-catalyzed conversion of organic nitrate to nitric oxide (NO) by purified CYP isoforms and the relationship between P450 expression and nitrate tolerance following continuous infusion of organic nitrates in rats. CYP1A2 effectively formed NO from isosorbide dinitrate and nitroglycerine (NTG). The hypotensive effect of an NTG bolus injection was abolished in rats which had been previously given a continuous 48 h infusion of NTG. Nitrate tolerance was reversible to control levels 2 days after cessation of the continuous infusion. At 48 h after infusion, NTG-induced NO generation of the vessels increased in acetone (a P450 inducer)-pretreated rats, and nitrite and nitrate levels were markedly greater than in normal rats. The appearance and disappearance of P450 isoforms paralleled the conversion of organic nitrates to NO as assessed by immunohistochemistry and Western blotting. Our observations indicate that nitrate tolerance is in large part the result of decreased P450 expression and activity. Interventions that maintain or increase P450 activity may be a useful strategy to provide sustained relief from ischemic conditions in humans.     

Continuous treatment with organic nitrate affects hepatic cytochrome P450

We previously reported that cytochrome P450 (P450) is a key enzyme of organic nitrate biotransformation and that P450 levels of the heart and its vessels markedly decreased at the development of nitrate tolerance. Escape from tolerance of organic nitrate by induction of cytochrome P450. Most organic nitrates, including nitroglycerin (NTG), are metabolized in the liver, where nitric oxide (NO) is concomitantly produced from the organic nitrates. Therefore, organic nitrate administration may also affect hepatic P450 levels, since the liver is the major organ of P450-related metabolism. Male Wistar rats were intravenously administrated NTG or isosorbide dinitrate (ISDN) for 24-96 h. Hepatic P450 was drastically decreased after 48 h or 72 h of continuous NTG or ISDN infusion, when nitrate tolerance was observed, but it recovered 48 h after cessation of the drug administration. hemeoxygenase-1 (HO-1) was induced within 24 h of continuous NTG infusion, but it returned to normal levels 48 h after cessation of the NTG. The administration of sodium nitroprusside, an agent to which the animals showed no tolerance, did not induce HO-1 or P450 depletion as judged by SDS-PAGE in combination with Western-blotting. These results suggest that P450-dependent drug metabolism may be drastically affected after continuous organic nitrate administration.     

Escape from tolerance of organic nitrate by induction of cytochrome P450.

The mechanism of organic nitrate tolerance is poorly defined. We studied the rat P450-catalyzed conversion of organic nitrate to nitric oxide (NO) by purified P450 isoforms relationship between P450 expression and nitrate tolerance following continuous infusion of organic nitrates in rats. The hypotensive effect of an nitroglycerin (NTG) bolus injection was abolished in rats that had been previously provided a continuous 48 h infusion of NTG. This effect was accompanied by a gradual but marked decrease in plasma and urinary nitrate levels following a peak at 18-24 h. Nitrate tolerance was reversible; the decline in the hypotensive effect and P450 levels observed after 2 d of continuous infusion was followed by restoration to control levels 2 d after cessation of the infusion. Similarly, the hypotensive action disappeared in P450-depleted, and -inhibited rats. At 48 h after infusion, NTG-induced NO generation of the vessels increased in acetone (a P450 inducer) -pretreated rats. The appearance and disappearance of P450 paralleled the conversion of organic nitrates to NO. Our observations indicate that nitrate tolerance is in large part the result of decreased P450 expression and activity. Interventions that maintain or increase P450 activity may be a strategy to provide relief from ischemic conditions in humans.     

Nitroglycerin reduces myocardial oxygen consumption during exercise despite vascular tolerance

The long-term benefits of nitroglycerin (NTG) therapy are limited by the development of vascular tolerance and endothelial dysfunction in conductance coronary arteries. We have determined whether nitrate tolerance extends to NTG effects on myocardial O2 consumption (MV(O2)) and the ability of endogenous nitric oxide (NO) to modulate MV(O2) during exercise. In chronically instrumented dogs (n = 8), hemodynamic and MV(O2) responses to treadmill exercise were measured before, during tolerance (3 and 7 days of NTG delivery), and 7 days after NTG withdrawal. Acute NTG delivery caused a parallel downward shift of the MV(O2)-triple product (TP) relations and reversed the disproportionate increases in MV(O2) caused by the blockade of NO formation. After 7 days of continuous transdermal NTG delivery, vascular tolerance was displayed as a >75% reduction of coronary blood flow (CBF) responses to NTG boluses. Despite vascular nitrate tolerance, MV(O2)-TP relations were shifted downward compared with pre-NTG exercise. Seven days after NTG withdrawal, vascular responses to boluses of NTG had recovered from tolerance, and MV(O2)-TP relations during exercise were back to pre-NTG level. At that time, blockade of NO formation failed to alter MV(O2)-TP relations. Thus NTG caused a sustained reduction of cardiac MV(O2), independent of metabolic demand during exercise, despite tolerance of the coronary microcirculation. NTG-induced vascular tolerance and MV(O2) reductions were reversible by NTG withdrawal, but endogenous NO-dependent modulation of O2 consumption was severely impaired.     

Evidence of enhanced non-enzymatic generation of nitric oxide on the skin surface of acupuncture points: An innovative approach in humans.

The present study quantified total nitrate and nitrite (NOx-) collected from the skin surface along acupuncture points (acupoints) and determined whether non-enzymatic reduction of nitrate by bacteria is involved in chemical generation of nitric oxide (NO) on acupoints. A small plastic tube (0.5 x 7 cm) cut in half lengthwise was taped to the forearm or leg in 50 healthy volunteers. NO-collecting solutions with NO-scavenging compounds, hemoglobin or 2-phenyl-4,4,5,5-tetramethylimidazoline-1-oxyl 3-oxide, was placed inside the tubing attached to the skin surface for 20 min. The concentrations of NOx- in the collected samples were quantified by using chemiluminescence. NOx- concentration was significantly enhanced in four acupoints on the pericardium meridian and in two acupoints on the bladder meridian compared with those collected on non-meridian control areas. The time intervals of NOx- levels were significantly higher at the first 20 min of acupoint collection, but the concentrations were similar among the study groups collected at 20-40, 40-60, and 60-80 min. NOx- concentrations and numbers of bacteria colonies detected on the skin surface were markedly reduced by pretreatment of skin with sodium hypochlorite compared to water treatment. This is the first evidence showing that NO has been successfully quantified on skin acupoints by a non-invasive device in humans. We conclude that NO is physiologically released from the skin surface with a higher level at acupoints, and that the non-enzymatic reduction of nitrate by bacteria is involved in chemical generation of NO on skin acupoints in addition to l-arginine-derived NO synthesis.     

Vitamin E deficiency accelerates nitrate tolerance via a decrease in cardiac P450 expression and increased oxidative stress

Organic nitrates, such as nitroglycerin (NTG), have been used to relieve the symptoms of angina pectoris. However, their biochemical mechanisms of action, particularly in relation to the development of tolerance, are incompletely defined. It has been reported that supplemental antioxidants such as vitamin E attenuate the development of nitrate tolerance. Therefore, we examined the role of vitamin E in the regulation of nitrate tolerance. Continuous NTG infusion induced nitrate tolerance in rats after 48 h, and vitamin E concentrations decreased in a time-dependent manner in tissues and plasma. Vitamin E supplementation (0.5 g/kg diet) maintained higher concentrations of vitamin E during NTG infusion. The onset and extent of the tolerance, estimated by the decrease in blood pressure following NTG bolus injection during the infusion of NTG, were accentuated in the vitamin E-deficient group. Vitamin E supplementation inhibited nitrate tolerance 48 h after NTG infusion. Cardiac P450 expression (CYP1A2) assessed by immunoblotting, markedly decreased 48 h after NTG administration in control rats. The supplementation of vitamin E significantly attenuated the decrease in P450. Treatment of NTG enhanced vascular superoxide production (L-012 chemiluminescence, DHE fluorescence). The peak of lipid peroxidation and free radical generation in the heart was reached before tolerance developed. In contrast, vitamin E-deficient hearts had lower P450 expression and higher free radical generation than control hearts. To evaluate other vitamin E-inhibitable mechanisms of nitrate tolerance, we studied the NO-cGMP pathway. NTG markedly reduced the vasodilator-stimulated phosphoprotein (VASP) serine 239 phosphorylation (specific substrate of cGMP-activated protein kinase I; cGK-I) in tolerant hearts. Vitamin E inhibited the depletion of pVASP. In conclusion, because continuous NTG infusion causes vitamin E depletion as well as nitrate tolerance, vitamin E deficiency may further accelerate nitrate tolerance via an increase in oxidative stress, the reduced bioconversion because of decreased P450 expression, and impairment of the NO/cGMP pathway in tolerant heart tissues.     

Exhaled NO is reduced at an early stage of hypoxia-induced pulmonary hypertension in newborn piglets

Altered nitric oxide (NO) production could contribute to the pathogenesis of hypoxia-induced pulmonary hypertension. To determine whether parameters of lung NO are altered at an early stage of hypoxia-induced pulmonary hypertension, newborn piglets were exposed to room air (control, n = 21) or 10% O(2) (hypoxia, n = 19) for 3-4 days. Some lungs were isolated and perfused for measurement of exhaled NO output and the perfusate accumulation of nitrite and nitrate (NOx-), the stable metabolites of NO. Pulmonary arteries (20-600-microm diameter) and their accompanying airways were dissected from other lungs and incubated for NOx- determination. Abundances of the nitric oxide synthase (NOS) isoforms endothelial NOS and neural NOS were assessed in homogenates of PAs and airways. The perfusate NOx- accumulation was similar, whereas exhaled NO output was lower for isolated lungs of hypoxic, compared with control, piglets. The incubation solution NOx- did not differ between pulmonary arteries (PAs) of the two groups but was lower for airways of hypoxic, compared with control, piglets. Abundances of both eNOS and nNOS proteins were similar for PA homogenates from the two groups of piglets but were increased in airway homogenates of hypoxic compared with controls. The NO pathway is altered in airways, but not in PAs, at an early stage of hypoxia-induced pulmonary hypertension in newborn piglets.     

Sympathetic nervous system contributes to the age-related impairment of flow-mediated dilation of the superficial femoral artery

The physiological aging process is associated with endothelial dysfunction, as assessed by flow-mediated dilation (FMD). Aging is also characterized by increased sympathetic tone. Therefore, the aim of the present study is to assess whether acute changes in sympathetic activity alter FMD in the leg. For this purpose, the FMD of the superficial femoral artery was determined in 10 healthy young (22 +/- 1 yr) and 8 healthy older (69 +/- 1 yr) men in three different conditions: 1) at baseline, 2) during reduction of sympathetic activity, and 3) during sympathetic stimulation. Reduction of sympathetic activity was achieved by performing a maximal cycling exercise, leading to postexercise attenuation of the sympathetic responsiveness in the exercised limb. A cold pressor test was used to increase sympathetic activity. Nitroglycerin (NTG) was used to assess endothelium-independent vasodilation in all three conditions. Our results showed that, in older men, the FMD and NTG responses were significantly lower compared with young men (P = 0.001 and P = 0.02, respectively). In older men, sympathetic activity significantly affected the FMD response [repeated-measures (RM) ANOVA: P = 0.01], with a negative correlation between the level of sympathetic activity and FMD (R = -0.41, P = 0.049). This was not the case for NTG responses (ANOVA; P = 0.48). FMD and NTG responses in young men did not differ among the three conditions (RM-ANOVA: P = 0.32 and P = 0.31, respectively). In conclusion, in older men, FMD of the femoral artery is impaired. Local attenuation of the sympathetic responsiveness partly restores the FMD in these subjects. In contrast, in young subjects, acute modulation of the sympathetic nervous system activity does not alter flow-mediated vasodilation in the leg.     

Reactive oxygen species stimulate central and peripheral sympathetic nervous system activity

Recent studies have implicated reactive oxygen species (ROS) in the pathogenesis of hypertension and activation of the sympathetic nervous system (SNS). Because nitric oxide (NO) exerts a tonic inhibition of central SNS activity, increased production of ROS could enhance inactivation of NO and result in activation of the SNS. To test the hypothesis that ROS may modulate SNS activity, we infused Tempol (4-hydroxy-2,2,6,6-tetramethyl piperidinoxyl), a superoxide dismutase mimetic, or vehicle either intravenously (250 microg x kg(-1) x min(-1)) or in the lateral ventricle (50 microg x kg body wt(-1) x min(-1)), and we determined the effects on blood pressure (BP), norepinephrine (NE) secretion from the posterior hypothalamus (PH) measured by the microdialysis technique, renal sympathetic nerve activity (RSNA) measured by direct microneurography, the abundance of neuronal NO synthase (nNOS)-mRNA in the PH, paraventricular nuclei (PVN), and locus coeruleus (LC) measured by RT-PCR, and the secretion of nitrate/nitrite (NO(x)) in the dialysate collected from the PH of Sprague-Dawley rats. Tempol reduced BP whether infused intravenously or intracerebroventricularly. Tempol reduced NE secretion from the PH and RSNA when infused intracerebroventricularly but raised NE secretion from the PH and RSNA when infused intravenously. The effects of intravenous Tempol on SNS activity were blunted or abolished by sinoaortic denervation. Tempol increased the abundance of nNOS in the PH, PVN, and LC when infused intracerebroventricularly, but it decreased the abundance of nNOS when infused intravenously. When given intracerebroventricularly, Tempol also reduced the concentration of NO(x) in the dialysate collected from the PH. Pretreatment with N(omega)-nitro-l-arginine methyl ester did not abolish the effects of intracerebral Tempol on BP, heart rate, NE secretion from the PH, and RSNA suggesting that the effects of Tempol on SNS activity may be in part dependent and in part independent of NO. In all, these studies support the notion that ROS may raise BP via activation of the SNS. This activation may be mediated in part by downregulation of nNOS and NO production, in part by mechanisms independent of NO. The discrepancy in results between intracerebroventricular and intravenous infusion of Tempol can be best explained by direct inhibitory actions on SNS activity when given intracerebral. By contrast, Tempol may exert direct vasodilation of the peripheral circulation and reflex activation of the SNS when given intravenously.     

Effects of S-nitroso-N-acetyl-penicillamine administration on glucose tolerance and plasma levels of insulin and glucagon in the dog.

It has been suggested that nitric oxide (NO, nitrogen monoxide) is a regulator of carbohydrate metabolism in skeletal muscle. The present study was undertaken to investigate the acute effects of the nitric oxide donor S-nitroso-N-acetylpenicillamine (SNAP) on blood glucose levels and on the gluco-regulatory hormones insulin and glucagon in healthy dogs. The acute effects of SNAP on mean arterial pressure and heart rate were also investigated. The drug was administered intravenously and the pre- and postprandial blood glucose, plasma insulin, and glucagon concentrations were determined at half-hour time intervals postadministration after a glucose challenge. The plasma nitrate and nitrite concentrations were measured and taken as the biochemical markers of in vivo NO formation. The oral glucose tolerance test revealed an impaired glucose tolerance in SNAP-treated dogs as reflected by the area under the glucose curve, 1150.50 +/- 63.00 mmol x 150 min and 1355.25 +/- 102.01 mmol/L x 150 min in dogs treated with 10 and 20 mg/kg of SNAP, respectively, compared with 860.25 +/- 60.68 mmol/L x 150 min in captopril-treated controls (P < 0.05). The 2-h blood glucose concentration in dogs treated with 20 mg/kg body wt of SNAP was 9.17 +/- 1.10 mmol/L compared with 5.59 +/- 0.26 mmol/L for captopril-treated controls (P = 0.015). The oral glucose tolerance test also confirmed an impaired insulin secretion in the SNAP-treated dogs. While the plasma insulin concentration increased gradually in the captopril-treated controls to a peak value of 39.50 +/- 2.55 microIU/ml, 1.5 h after a glucose challenge there was a decrease in the plasma insulin concentration in SNAP-treated dogs to a low value of 20.67 +/- 0.88 microIU/ml (P = 0.006). In contrast, there were no significant differences in plasma glucagon concentration in SNAP-treated dogs and captopril-treated dogs at any time points. Using the Griess reaction, we found that there was a 27-95% increase in plasma nitrate/nitrite concentration on administration of SNAP. The sustained hyperglycemic effect observed in SNAP-treated dogs was accompanied by a marginal decrease in the mean arterial blood pressure and a significant increase in heart rate (P < 0.05). We conclude that acute administration of SNAP in the oral glucose tolerance test releases NO that modulates the parameters of carbohydrate metabolism.     

High constitutional nitrate status in young cattle.

Nitrate or nitrite can be ingested or endogenously produced from nitric oxide. They can cause intoxication and are of general concern for health because they relate to various diseases. Our goal was to study ontogenetic and nutritional effects on the nitrate+nitrite (NOx-) status in cattle, particularly calves. NOx- concentration in blood plasma, cerebrospinal fluid, saliva, and urine was measured based on nitrate conversion by added nitrate reductase to nitrite, which was then determined by the Griess reaction. Concentrations of nitrate were the result of the difference between NOx- and nitrite values. Nitrate in blood plasma, saliva and urine was > or =97% and in cerebrospinal fluid of calves was approximately 35% of NOx-. Preprandial plasma NOx- in calves born after shortened or normal lengths of pregnancy (277 and 290 days) was 470 and 830 micromol/l, respectively, decreased within 4-7 days to 40-60 micromol/l, remained in this range up to 4 months, was < or =5 micromol/l in heifers and no longer measurable in 3-8-year-old cows. Cerebrospinal NOx- in 8-day-old calves was 14 micromol/l and approximately 11-fold lower than in blood plasma. Salivary NOx- decreased postnatally from 600 to 200 micromol/l at 2 days and to 25 micromol/l at 4 weeks. Urinary NOx- excretion decreased from 125 or 16 micromol/l per kg x 24 h in 5-day-old calves to 45 or 8 micromol/kg x 24 h between 10 and 115 days of life and was undetectable in urine of heifers and cows. Feeding neonatal calves no or variable amounts of colostrum, delaying colostrum intake by 24 h after birth or feeding at different feeding intensity had no effect on the NOx- status. In conclusion, the high plasma, salivary and urinary NOx- concentrations especially in newborn calves, ingesting but insignificant amounts of nitrite or nitrate, indicated marked endogenous formation of nitrate, which decreased with age. The high nitrate status may contribute to enhanced susceptibility of young calves to exogenous nitrite+nitrite ingestion.     

Decrease of nitric oxide (NO)-cGMP-dependent vasodilatation in the vessels of lesser circulation in endothelial dysfunction

Inducible NO-synthase inhibitor aminoguanidine (AG) was used for investigation into enhanced nitric oxide (NO) production influence on elevated pressure in the pulmonary circulation (pulmonary hypertension, PH) under endothelial dysfunction. PH was simulated by subcutaneous injection of 60 mg/kg MCT to Wistar rats. Experimental groups were given AG in drinking water (15 mg/(kg x day)), and control groups were given drinking water. Rate of nitrite/nitrate excretion (RENOx) with urine was measured. The RENOx was elevated since second week as long as through the PH development. Chronic AG administration led to RENOx and soluble guanylate cyclase (sGC) NO-dependent activity restoration, and also it led to partial restoration of the right ventricular pressure. AG administration restored the perfusion pressure responses of isolated pulmonary arteries to acetylcholine. These results suggest that chronic inducible NO-synthase inhibition restores the impaired endothelium-dependent and sGC-dependent relaxation of pulmonary artery in MC-induced PH.     

Clinical and biological investigation of NO

Furchgott et al. demonstrated in 1980 that relaxation of arterial smooth muscle cells in response to acetylcholine is dependent on the integrity of endothelium. They named the factor responsible of this intercellular relationship EDRF (Endothelium Derived Relaxing Factor), which was identified 7 years latter as nitric oxide (NO), a free radical gas. In vessels, NO is generated locally by the endothelial NO synthase and its effect is mainly paracrine (relaxation of the underlying smooth muscle cells, and inhibition of platelet aggregation). The in vivo half-life of NO is short, and the assessment of its production is thus difficult. Invasive and non invasive techniques are now available to explore the variations of arterial diameter or flow. Furchgott's pioneering work anticipated the whole pathophysiology of endothelial-dependent relaxation. Indeed, numerous diseases, in particular atherosclerosis, are accompanied by abnormalities of endothelial-dependent vasodilation ("endothelial dysfunction"). Whereas acetylcholine (or serotonin) infused in a normal artery elicits a vasodilation, in contrast, it promotes a vasoconstriction in an atheromatous artery, as a consequence of a decrease in NO bioavailability. This defect in NO favors arterial spasm, interaction between platelets and arterial wall and thrombosis, and thus probably cardiovascular events. NO cannot be measured directly in humans, except in exhaled NO. In vivo, NO is rapidly oxidized in nitrite (NO2-) and in nitrate (NO3-), the summation being NOx. We shall detail the limitations of this measurement as a biochemical index of NO production from "endothelial" origin.     

Cardiac sympathetic afferent stimulation impairs baroreflex control of renal sympathetic nerve activity in rats

It is well known that cardiac sympathetic afferent reflexes contribute to increases in sympathetic outflow and that sympathetic activity can antagonize arterial baroreflex function. In this study, we tested the hypothesis that in normal rats, chemical and electrical stimulation of cardiac sympathetic afferents results in a decrease in the arterial baroreflex function by increasing sympathetic nerve activity. Under alpha-chloralose (40 mg/kg) and urethane (800 mg/kg i.p.) anesthesia, renal sympathetic nerve activity, mean arterial pressure, and heart rate were recorded. The arterial baroreceptor reflex was evaluated by infusion of nitroglycerin (25 microg i.v.) and phenylephrine (10 microg i.v.). Left ventricular epicardial application of capsaicin (0.4 microg in 2 microl) blunted arterial baroreflex function by 46% (maximum slope 3.5 +/- 0.3 to 1.9 +/- 0.2%/mmHg, P < 0.01). When the central end of the left cardiac sympathetic nerve was electrically stimulated (7 V, 1 ms, 20 Hz), the sensitivity of the arterial baroreflex was similarly decreased by 42% (maximum slope 3.2 +/- 0.3 to 1.9 +/- 0.4%/mmHg; P < 0.05). Pretreatment with intracerebroventricular injection of losartan (500 nmol in 1 microl of artificial cerebrospinal fluid) completely prevented the impairment of arterial baroreflex function induced by electrical stimulation of the central end of the left cardiac sympathetic nerve (maximum slope 3.6 +/- 0.4 to 3.1 +/- 0.5%/mmHg). These results suggest that the both chemical and electrical stimulation of the cardiac sympathetic afferents reduces arterial baroreflex sensitivity and the impairment of arterial baroreflex function induced by cardiac sympathetic afferent stimulation is mediated by central angiotensin type 1 receptors.     

Interleukin-1beta and neurogenic control of blood pressure in normal rats and rats with chronic renal failure

Increased sympathetic nervous system (SNS) activity plays a role in the genesis of hypertension in rats with chronic renal failure (CRF). The rise in central SNS activity is mitigated by increased local expression of neuronal nitric oxide synthase (NOS) mRNA and NO(2)/NO(3) production. Because interleukin (IL)-1beta may activate nitric oxide in the brain, we have tested the hypothesis that IL-1beta may modulate the activity of the SNS via regulation of the local expression of neuronal NOS (nNOS) in the brain of CRF and control rats. To this end, we first found that administration of IL-1beta in the lateral ventricle of control and CRF rats decreased blood pressure and norepinephrine (NE) secretion from the posterior hypothalamus (PH) and increased NOS mRNA expression. Second, we observed that an acute or chronic injection of an IL-1beta-specific antibody in the lateral ventricle raised blood pressure and NE secretion from the PH and decreased NOS mRNA abundance in the PH of control and CRF rats. Finally, we measured the IL-1beta mRNA abundance in the PH, locus coeruleus, and paraventricular nuclei of CRF and control rats by RT-PCR and found it to be greater in CRF rats than in control rats. In conclusion, these studies have shown that IL-1beta modulates the activity of the SNS in the central nervous system and that this modulation is mediated by increased local expression of nNOS mRNA.     

Atrial natriuretic peptide (ANP) does not inhibit the basal vascular tone present in the in situ blood-perfused dog gracilis muscle

This study evaluated the effects of rat ANP(5-28) infusion into the blood-perfused dog gracilis muscle at concentrations ranging from 30 to 10,000 pg/ml. The vasculature of gracilis muscles from anesthetized beagle dogs was isolated and pump-perfused at constant flow with blood utilizing an extracorporeal circuit. Maximal vasodilatory capacity was determined by adenosine injection. ANP was infused into the arterial circuit to produce increasing arterial blood concentrations. Each infusion lasted 10 min. Systemic arterial pressure, central venous pressure, cardiac output and heart rate did not change during ANP infusion into the gracilis vasculature. ANP at arterial blood concentrations up to 10,000 pg/ml did not produce significant vasodilation although the vasculature showed pronounced vasodilation in response to adenosine. In vitro experiments showed that ANP had much less vasorelaxant activity in dog femoral artery and saphenous vein than in rabbit aorta. Therefore, rat ANP(5-28) at concentrations within and well above physiological and pharmacological ranges does not inhibit the basal vascular tone present in the innervated, blood-perfused dog gracilis muscle in situ.     

Nitric oxide inhibition of renal vasoconstrictor responses to sympathetic cotransmitters in the pig in vivo.

The object of the present study was to investigate the involvement of nitric oxide (NO) in the regulation of renal vasoconstrictor responses to sympathetic nerve activation, and each of the known sympathetic cotransmitters separately, in the pig in vivo. Renal vasoconstrictor responses were elicited by sympathetic nerve stimulation, the alpha(1)-adrenoceptor agonist phenylephrine (10 nmol kg(-1), injected iv), neuropeptide Y (NPY, 120 pmol kg(-1), iv) acting on the NPY Y(1) receptor, and the stable ATP-analogue alpha,beta-methylene ATP (mATP, 10 nmol kg(-1)) presumably acting on the P2X(1) purinoceptor. Infusion of the NO-donor sodium nitroprusside, at a dose (0.1 mg kg(-1) h(-1), iv) that elevated renal blood flow (by 14 +/- 7%) and lowered mean arterial pressure (by 30 +/- 5%), inhibited renal vasoconstrictor responses to sympathetic nerve stimulation, phenylephrine, and NPY, but not to mATP. In contrast, injection of the NO synthase inhibitor Nomega-nitro-l-arginine methyl ester, at a dose (10 mg kg(-1), iv) that lowered renal blood flow (by 47 +/- 4%) and elevated mean arterial pressure (by 28 +/- 8%), potentiated the renal vasoconstriction evoked by sympathetic nerve stimulation, phenylephrine, and NPY, but not mATP. It is concluded that endogenous NO may function as an inhibitory modulator of vasoconstrictor responses to the sympathetic cotransmitters norepinephrine and NPY. In contrast, NO seems not to modify vasoconstrictor responses to the sympathetic cotransmitter ATP, a discrepancy that may be due to differences in the types of receptors and intracellular effector mechanisms.     

Nitric oxide modulates sympathoexcitatory cardiac-cardiovascular reflexes elicited by bradykinin

A number of studies have demonstrated an important role for nitric oxide (NO) in central and peripheral neural modulation of sympathetic activity. To assess the interaction and integrative effects of NO release and sympathetic reflex actions, we investigated the influence of inhibition of NO on cardiac-cardiovascular reflexes. In anesthetized, sinoaortic-denervated and vagotomized cats, transient reflex increases in arterial blood pressure (BP) were induced by application of bradykinin (BK, 0.1-10 microg/ml) to the epicardial surface of the heart. The nonspecific NO synthase (NOS) inhibitor NG-monomethyl-L-arginine (L-NMMA, 10 mg/kg iv) was then administered and stimulation was repeated. L-NMMA increased baseline mean arterial pressure (MAP) from 129 +/- 8 to 152 +/- 9 mmHg and enhanced the change in MAP in response to BK from 32 +/- 3 to 39 +/- 5 mmHg (n = 9, P < 0.05). Pulse pressure was significantly enhanced during the reflex response from 6 +/- 4 to 27 +/- 6 mmHg after L-NMMA injection due to relatively greater potentiation of the rise in systolic BP. Both the increase in baseline BP and the enhanced pressor reflex were reversed by L-arginine (30 mg/kg iv). Because L-NMMA can inhibit both brain and endothelial NOS, the effects of 7-nitroindazole (7-NI, 25 mg/kg ip), a selective brain NOS inhibitor, on the BK-induced cardiac-cardiovascular pressor reflex also were examined. In contrast to L-NMMA, we observed significant reduction of the pressor response to BK from 37 +/- 5 to 18 +/- 3 mmHg 30 min after the administration of 7-NI (n = 9, P < 0.05), an effect that was reversed by L-arginine (300 mg/kg iv, n = 7). In a vehicle control group for 7-NI (10 ml of peanut oil ip), the pressor response to BK remained unchanged (n = 6, P > 0.05). In conclusion, neuronal NOS facilitates, whereas endothelial NOS modulates, the excitatory cardiovascular reflex elicited by chemical stimulation of sympathetic cardiac afferents.     

Effect of adenosine and glucagon on hepatic blood volume responses to sympathetic nerves

Hepatic blood volume responses were studied in cats using in vivo plethysmography. The maximal response (Rmax) to sympathetic nerve stimulation and to infusions of norepinephrine into the hepatic artery or portal vein was similar (12-14 mL expelled per liver in 2.9-kg cats; average liver weight, 76.8 +/- 6.8 g). The ED50 for norepinephrine intraportal (0.44 +/- 0.13) and intrahepatic arterial infusions (0.33 +/- 0.08 micrograms.kg-1.min-1) were similar indicating equal access of both blood supplies to the capacitance vessels. Adenosine (2.0 mg.kg-1.min-1) did not cause significant volume changes but produced a mild (27%) suppression of Rmax due to nerve stimulation with no change in the frequency (3.4 Hz) needed to produce 50% of Rmax. Rmax tended (not statistically significant) to decrease during glucagon (1.0 micrograms.kg-1.min-1) infusion but the nerve frequency needed to produce 50% of Rmax rose to 5.6 Hz. Thus both adenosine and glucagon produced modulation of sympathetic nerve-induced capacitance responses without having significant effects on basal blood volume. Adenosine, by virtue of its marked effects on arterial resistance vessels (at substantially lower doses than those used here) and the relative lack of effect on venous capacitance vessels, may be useful for producing clinical afterload reduction without venous pooling.