Sympathetic purinergic vasoconstriction and thermosensitivity in a canine cutaneous vein

In canine cutaneous veins, cooling augments the contractile responses evoked by sympathetic nerve stimulation despite a cooling-induced reduction in the release of norepinephrine. With exogenous norepinephrine, the increased responsiveness observed during cooling results from enhanced sensitivity of the postjunctional alpha-2 adrenoceptors. The present experiments were performed to analyze the mechanism of the increased neurogenic response during cooling. Rings of canine saphenous vein were suspended for isometric tension recording in organ chambers filled with modified Krebs-Ringer bicarbonate solution, gassed with 95% O2-5% CO2. Cooling (from 37-24 degrees C) increased the contractile response evoked by nerve stimulation under control conditions, after alpha-1 adrenergic blockade with prazosin, alpha-2 adrenergic blockade with rauwolscine or the combination of both antagonists. The influence of cooling to enhance the neurogenic response was inhibited only by combined alpha adrenergic and purinergic-receptor blockade (alpha,beta-methylene ATP). Electrical stimulation failed to evoke a contractile response (either at 37 or 24 degrees C) in the presence of tetrodotoxin or after acute sympathetic denervation with 6-hydroxydopamine. alpha,beta-Methylene ATP abolished the contractile response evoked by ATP but did not affect the concentration-effect curves to alpha-1 (phenylephrine) or alpha-2 (UK 14,304) adrenergic stimulation. Cooling augmented the contractile responses evoked by ATP. The results suggest that ATP released from sympathetic neurons in the vessel wall contributes to the cooling-induced augmentation of contractile responses to sympathetic nerve stimulation in canine cutaneous veins. This may explain the increased prominence of purinergic mechanisms in cutaneous blood vessels.     

Role of calcitonin gene-related peptide-containing nerves in the vascular adrenergic neurotransmission.

The role of calcitonin gene-related peptide (CGRP)-containing nerves in adrenergic vasoconstrictor response to periarterial nerve stimulation (PNS) was investigated in mesenteric vascular beds isolated from rats, which were perfused with Krebs' solution (5 ml/min). In perfused mesenteric vascular beds, PNS (1-12 Hz, for 30 sec) caused a frequency-dependent increase in the perfusion pressure, which was prevented by 50 nM prazosin and abolished by 300 nM tetrodotoxin and 5 microM guanethidine. Bolus infusion of norepinephrine (NE, 0.5 and 1 nmol) also produced a pressor response which was blocked by 50 nM prazosin. In the preparation treated with 500 nM capsaicin for 20 min, pressor responses to PNS of 1 to 8 Hz were potentiated significantly. The pressor responses to NE infusion also were enhanced in both the preparations treated with and without capsaicin. In the capsaicin-untreated preparation contracted by 7 mM methoxamine in the presence of 5 microM guanethidine, PNS (1-12 Hz) caused a frequency-dependent vasodilation, which was abolished by 300 nM tetrodotoxin. However, no vasodilator response to PNS was observed in the preparation treated with capsaicin. In the contracted preparation, bolus infusion of rat CGRP (10 and 100 pmol) produced a marked long-lasting vasodilation which mimicked the PNS-evoked vasodilation, whereas neither bolus infusion of substance P (1 and 10 nmol), neurokinin A (1 and 10 nmol) nor neurokinin B (1 and 10 nmol) produced relaxation. In the preparation labeled with [3H]NE, the PNS (4 Hz)-evoked 3H release was not altered after capsaicin treatment, whereas the pressor response to PNS was potentiated significantly.(ABSTRACT TRUNCATED AT 250 WORDS)     

Alpha blocking action of the antihypertensive agent, prazosin.

The vasodilatory and alpha adrenergic blocking properties of prazosin were studied in anesthetized rats and compared with the direct-acting vasodilator, diazoside. The hypotensive activity of diazoxide was unimpaired after ganglion blockade with pentolinium or alpha adrenoreceptor blockade with phentolamine; diazoxide also significantly attenuated angiotensin II pressor responses. In contrast, the hypotensive action of prazosin was completely abolished, over a 10(4)-fold dose range, after ganglion or alpha adrenoreceptor blockade, and this agent failed, even in maximal hypotensive doses, to attenuate angiotensin II pressor responses. In addition, prazosin was shown to possess potent alpha adrenoreceptor blocking properties, significantly attenuating norepinephrine pressor responses and causing reversal of epinephrine pressor responses. These studies in the rat indicate that the hypotensive action of prazosin is not due to a direct relaxant effect upon vascular smooth muscle, but is attributable to alpha adrenoreceptor blockade.     

Effect of cooling on alpha-1 and alpha-2 adrenergic responses in canine saphenous and femoral veins

Experiments were designed to determine the effects of cooling on alpha-1 and alpha-2 adrenergic responses in isolated canine veins. Rings of saphenous and femoral veins were suspended for isometric tension recording in modified Krebs-Ringer bicarbonate solution, gassed with 95% O2 and 5% CO2. Cooling (from 37-24 degrees C) augmented contractions to norepinephrine in saphenous but caused depression in femoral veins. Cooling (to 24 degrees C) had no effect on alpha-1 adrenergic responses evoked by phenylephrine in saphenous veins but caused depression in femoral veins. Alpha-2 adrenergic responses produced by UK 14,304 were augmented by cooling in the saphenous but were virtually abolished by cooling in femoral veins. Cooling decreased the dissociation constant (i.e., increased affinity) of corynanthine for alpha-1 adrenoceptors in saphenous and femoral veins (approximately 3-fold), and the dissociation constant of rauwolscine for alpha-2 adrenoceptors in saphenous veins (approximately 7.5-fold). The influence of cooling on alpha adrenoceptor responsiveness was analyzed using computer-generated receptor-models. The results suggest that the differential sensitivity of cutaneous and deep blood vessels to cooling results from differences in efficiency of alpha-1 and alpha-2 adrenoceptor response coupling. In the saphenous vein, there is a large alpha-1 adrenoceptor reserve which buffers the alpha-1 adrenergic response from the inhibitory influence of cooling. This coupled with a cooling-induced increase in alpha-2 adrenoceptor affinity ensures that cooling augments the response to norepinephrine. In the femoral vein, there is no alpha-1 adrenoceptor reserve and cooling therefore depresses alpha-1 adrenergic responses.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nonadrenergic nature of prazosin-resistant, sympathetic contraction in the dog mesenteric artery

Electrical transmural stimulation of the isolated dog mesenteric artery produced a contractile response which was abolished by guanethidine and 6-hydroxydopamine but not by prazosin. Approximately 60% of the response seen with a frequency of 3 Hz remained after the treatment with prazosin. The prazosin-resistant contraction induced by electrical transmural stimulation was potentiated by other alpha adrenoceptor antagonists (phentolamine, phenoxybenzamine, tolazoline and DG-5128). Alpha-2 adrenoceptor agonists (including norepinephrine) attenuated the prazosin-resistant contraction and this attenuation was antagonized by the alpha antagonists mentioned above. Cocaine slightly inhibited the prazosin-resistant contraction, whereas this drug markedly augmented the contractile response to electrical stimulation before treatment with prazosin. In reserpine-treated mesenteric arteries also, electrical transmural stimulation produced a contraction and this was neither suppressed nor potentiated by prazosin and other alpha antagonists but was attenuated by alpha-2 agonists. Guanethidine and 6-hydroxydopamine abolished the prazosin-resistant contraction in reserpine-treated arteries. Nicotine, but not tyramine, also produced such prazosin-resistant contraction in reserpine-treated and untreated arteries. Exogenous norepinephrine produced a concentration-dependent contraction in reserpine-treated and untreated arteries and the responses were competitively antagonized by prazosin. These results indicate that the prazosin-resistant contractions of the dog mesenteric artery induced by electrical transmural stimulation and nicotine are sympathetic in origin but not adrenergic in nature. Such prazosin- resistant contraction was observed in the dog mesenteric vein but not in carotid and femoral arteries, thereby suggesting that the nonadrenergic component may play an important role in the regulation of visceral blood flow.     

Selective blockade by nicergoline of vascular responses elicited by stimulation of alpha 1A-adrenoceptor subtype in the rat

The alpha 1-adrenergic blocking activity of nicergoline was re-examined in rats, with a particular emphasis on alpha 1-adrenoceptor subtypes. In pithed rats, nicergoline and prazosin infused at a single small dose (0.5 microgram/kg/min i.v.) produced a substantial and identical shift to the right of the control dose pressor response curve to the specific alpha 1-agonist cirazoline (ED50 = 4.0 +/- 0.1, 4.0 +/- 0.1 and 0.9 +/- 0.01 microgram/kg i.v. for nicergoline, prazosin and vehicle respectively). In the isolated perfused mesenteric vascular bed, nicergoline strongly inhibited the pressor responses elicited by cirazoline, with approximately 40-fold higher potency (pA2 = 11.1 +/- 0.3) than prazosin (pA2 = 9.5 +/- 0.3). Conversely, nicergoline was 20-fold less potent than prazosin to antagonize the contractile effects of cirazoline in isolated endothelium-denuded aorta (pA2 = 8.6 +/- 0.2 and 9.9 +/- 0.2 for nicergoline and prazosin respectively). Pretreatment of mesenteric vascular beds with chloroethylclonidine did not significantly modify nicergoline antagonistic potency (pA2 = 10.6 +/- 0.2). Nicergoline displaced [3H]-prazosin bound to rat forebrain membranes pretreated with chloroethylclonidine (pKi = 9.9 +/- 0.2) at concentrations 60-fold lower than in rat liver membranes (pKi = 8.1 +/- 0.2). Finally, of the nicergoline metabolites studied, lumilysergol acted as a modest alpha 1 antagonist (bromonicotinic acid was devoid of alpha 1 antagonist activity). In conclusion, nicergoline is a potent and selective alpha 1A-adrenoceptor subtype antagonist, an alpha 1-adrenoceptor subtype which is mainly represented in resistance arteries.     

Effect of cooling on the responses of human saphenous vein to fentanyl, remifentanil and sufentanil

We studied the vasodilatory effects of fentanyl, remifentanil and sufentanil on the human saphenous vein strips at 37, 32 and 28 degrees C. Fentanyl produced concentration-dependent relaxation of human saphenous vein strips precontracted with 5-hydroxytryptamine (5-HT) at every temperature studied. Compared with vein strips at 37 degrees C, relaxant responses to each one concentration of fentanyl were significantly reduced at 32 and 28 degrees C. Remifentanil relaxed vein strips in a concentration-dependent way and the relaxation for all concentrations were significantly greater at 32 and 28 degrees C compared with 37 degrees C. Sufentanil produced concentration-dependent relaxation in saphenous vein strips precontracted with 5-HT. These relaxant responses were similar at 32 degrees C compared with 37 degrees C. When bath temperature was lowered from 37 to 28 degrees C, the relaxant responses to sufentanil were significantly reduced. In summary, the present study suggests that cooling reduces the relaxation caused by fentanyl and sufentanil on human saphenous veins but augments the relaxation with remifentanil. The augmented vasodilatory effect of remifentanil with cooling may be useful on systemic vascular resistance and organ preservation under hypothermic conditions like cardiopulmonary bypass surgery.     

Synergism between neuropeptide Y and norepinephrine highlights sympathetic cotransmission: studies in rat arterial mesenteric bed with neuropeptide Y, analogs, and BIBP 3226.

Although abundant literature supports the notion that neuropeptide Y (NPY) synergizes in vivo and in vitro, the vasomotor activity elicited by norepinephrine (NE), the converse interaction (i.e., the adrenergic modulation of the NPY vasomotor response) has been less characterized. To assess whether NE synergizes the vasomotor effect of NPY, the rat arterial mesenteric bed was chosen as a model experimental system. Mesenteries were precontracted with NE and few minutes later were perfused with exogenous NPY. Under these conditions, NPY contracted the arterial mesenteric bed with an EC50 value of 0.72 +/- 0.06 nM. NPY was unable to contract this vascular territory without an agonist-induced precontraction. Other agonists, such as endothelin-1, a synthetic analog of prostaglandin F2alpha, or 5-hydroxytryptamine, also were effective primers because in their presence, NPY was a potent vasoconstrictor. In contrast, mesenteries precontracted with KCl failed to evidence the NPY-induced rise in perfusion pressure. Two structural analogs of NPY, PYY and [Leu31, Pro34]NPY, mimicked the activity of NPY. The NPY fragment 13-36 did not elicit such a response. All NPY analogs exhibited less efficacy and potency relative to NPY. The NPY- and related structural analog-induced vasoconstriction was competitively and reversibly antagonized by BIBP 3226; the pA2 of the NPY interaction was 7.0. The application of 0.1 to 1 microM BIBP 3226 or 0.1 to 10 nM prazosin at the peak of the NPY vasomotor response elicited a gradual blockade of the vasoconstriction. Although BIBP 3226 blocked the increase in perfusion pressure elicited by NPY, leaving unaffected the NE-induced tone, 10 nM prazosin blocked the full response, including the NE-induced component. Tissue preincubation with 200 nM nifedipine abolished the NPY-induced vasoconstriction; likewise, the acute application of 10 to 100 nM nifedipine blocked gradually the maximal NPY-induced contraction. Removal of the mesenteric endothelial layer increased the potency of NPY by 2-fold; it also slightly potentiated the antagonist activity of BIBP 3226. The synergism between NPY and NE backs the principle of sympathetic cotransmission.     

Renal periarterial nerve stimulation-induced vasoconstriction at low frequencies is primarily due to release of a purinergic transmitter in the rat

In the isolated rat kidney, the vasoconstrictor response elicited by periarterial nerve stimulation at low frequencies (2 Hz) is resistant to alpha adrenergic receptor blockade. It has been proposed that in some blood vessels ATP is coreleased with norepinephrine during nerve stimulation to activate P2-purinergic receptors and is responsible for the component of the vasoconstrictor response that is resistant to alpha adrenergic receptor blockade. To assess the contribution of a purinergic transmitter in the vasoconstriction elicited by periarterial nerve stimulation in the isolated Tyrodes-perfused rat kidney, fractional overflow of [3H]norepinephrine and vasoconstrictor responses to renal nerve stimulation were examined after alpha adrenergic receptor blockade and/or P2-purinergic receptor desensitization. The alpha-1 adrenergic receptor antagonists prazosin (0.1-1.0 microM) and corynanthine (0.1-1.0 microM) and the nonselective alpha adrenergic receptor antagonist phentolamine (0.1-1.0 microM) did not significantly reduce vasoconstrictor responses elicited by low frequency (0.5-4 Hz) but attenuated the responses to high-frequency (6-10 Hz) periarterial nerve stimulation. At low-frequency renal nerve stimulation, selective P2-purinergic receptor desensitization abolished the vasoconstriction at 0.5 Hz and dramatically attenuated the responses up to 4 Hz. In the presence of prazosin, the component of the vasoconstrictor response that was resistant to alpha adrenergic receptor blockade at all frequencies of renal nerve stimulation was abolished after treatment with alpha, beta-methylene ATP. On the other hand, in the isolated perfused rabbit kidney, prazosin (1.0 microM) alone reduced dramatically the vasoconstrictor responses to periarterial nerve stimulation over the same frequencies used in the rat.(ABSTRACT TRUNCATED AT 250 WORDS)     

Postsynaptic alpha adrenoceptors in baboon cerebral and mesenteric arteries

Postsynaptic alpha adrenergic mechanisms were compared in cerebral and mesenteric arteries isolated from the baboon. The contractile response to norepinephrine (NE) of the cerebral artery was potent and similar to that of the mesenteric artery. The EC50 was 3.1 (2.0-5.0) X 10(-7) M for the cerebral artery and 2.6 (1.5-4.8) X 10(-7) M for the mesenteric artery. The maximum contraction expressed as a force developed/cross-sectional area did not differ between the two arteries, whereas that expressed as percentage of 30 mM KCl-induced contraction in the cerebral artery (118 +/- 9%) was less than in the mesenteric artery (145 +/- 6%). Phenylephrine produced a contraction in a manner similar to NE, although the EC50 values in both arteries were 2 to 3 times as large as those for NE. Clonidine produced a moderate contraction in the mesenteric artery (35 +/- 8% of the KCl-induced contraction) but no contraction in the cerebral artery. NE-induced contraction in the cerebral artery was inhibited more prominently by prazosin, a selective alpha-1 adrenoceptor antagonist, than that in the mesenteric artery; the pA2 value for prazosin in the cerebral artery was higher (9.70) than that in the mesenteric artery (8.95). In contrast, there was no difference in pA2 values for either phentolamine or yohimbine between the two arteries. Clonidine-induced contraction in the mesenteric artery was attenuated by prazosin rather than yohimbine at the same concentration used. Thus, it may be concluded that contractile processes related to postsynaptic alpha-1 adrenoceptor stimulation are predominantly operative in baboon cerebral and mesenteric arteries, the cerebral artery being more susceptible to the inhibitory effect of prazosin.     

Different sensitivities to alpha1 adrenoceptor blockade on periarterial sympathetic nerve-induced constriction by low and high frequencies in canine isolated splenic arteries

The periarterial nerve electrical stimulation at 4 and 10 Hz induced a monophasic vasoconstriction of the canine splenic artery in a pulse number-related manner (1-30 pulses). The responses at 4 Hz were not significantly affected by 0.1 microM prazosin, but abolished by 1 microM alpha, beta-methylene ATP. Prazosin (0.1 microM) partially but significantly inhibited responses at 10 Hz, and the remaining responses were blocked by 1 microM alpha, beta-methylene ATP. It indicates that the monophasic vasoconstrictor response to short pulses of stimulation at a low frequency is mediated by P2X-receptors, whereas the response at a high frequency may be due to activation of not only P2X-receptors but also alpha1 adrenoceptors.     

Differential inhibitory effect of neomycin on contractile responses of various canine arteries.

The influence of neomycin on vascular smooth muscle contractile responses was examined in different isolated arterial preparations of the dog. Prior exposure (5 minutes) to 7 mM neomycin decreased contractile responses elicited with norepinephrine (NE, 0.6 muM) or KC1 (K-+, 80 nM) in helical strips of canine aortae (Ao) and femoral (F), carotid (Cd), renal (R), superior mesenteric (Sm), terminal mesenteric (Tm) and coronary (Cr) arteries. Addition of neomycin subsequent to NE-induced contractile responses depressed tension responses of the F, Cd, R, Sm and Tm arteries but had little or no effect on the Ao. However, after contractions had been elicited with K-+, neomycin had no effect on tension responses of the Ao, F, Cd, R or Sm arteries but depressed contractions of the Cr and Tm arterial strips. Preincubation with neomycin (0.7-3.5 mM) produced a concentration-related inhibition of contractile responses elicited in Tm arterial strips by addition of calcium ions (Ca-++; 1.6 mM) to a Ca-++-free depolarizing solution; conversely, subsequent addition of neomycin had no effect on maintained Ca-++ contractures. In constant flow-perfused terminal mesenteric arterial branches, neomycin (0.5-4.0 mM) produced a concentration-related antagonism of pressor responses elicited with NE (1-8 mug) or K-+ (40 mM). The inhibitory action of neomycin on K-+-induced pressor responses was inversely related to the Ca-++ concentration of the perfusion fluid. However, inhibition of NE pressor responses by neomycin did not appear to be related to the Ca-++ concentration. The differential inhibitory action of neomycin on contractions induced by NE and K-+ in various canine arteries suggests that different vascular beds vary in the manner in which Ca-++ is bound and subsequently utilized by stimulatory agents to elicit tension changes.     

Neuronal nitric-oxide synthase inhibition facilitates adrenergic neurotransmission in rat mesenteric resistance arteries

The effects of nonselective nitric-oxide synthase (NOS) inhibitors [N-omega-nitro-L-arginine methyl ester (L-NAME) and N-omega-nitro-L-arginine (L-NNA)] and specific neuronal NOS (nNOS) inhibitor [vinyl-L-N-5-(1-imino-3-butenyl)-L-ornithine (L-VNIO)] on adrenergic nerve-mediated vasoconstriction were studied in rat perfused mesenteric vascular beds without endothelium. Perfusion of L-NAME, L-NNA, or l-VNIO markedly augmented vasoconstrictor responses to periarterial nerve stimulation (PNS; 2-8 Hz) without affecting vasoconstriction induced by exogenously injected norepinephrine (NE). Addition of L-arginine, a precursor for the synthesis of nitric oxide (NO), reversed the augmentation of the PNS response by l-NAME. The PNS (8 Hz)-evoked NE release in the perfusate was increased by L-NAME perfusion. In preparations treated with capsaicin [a depleter of calcitonin gene-related peptide (CGRP)-containing nerves], L-NAME did not augment vasoconstrictor responses to PNS or NE injection. Combined perfusion of CGRP(8-37) (a CGRP receptor antagonist) and L-NAME induced additive augmentation of the vasoconstrictor response to PNS but did not affect the response to NE injection. In preparations with active tone produced by methoxamine and in the presence of guanethidine, L-NAME perfusion did not affect the vasodilator response induced by PNS. Immunostaining of the mesenteric artery showed the presence of nNOS-like immunopositive nerve fibers, which were absent in arteries pretreated with capsaicin. These findings suggest that NO, which is released from perivascular capsaicin-sensitive nerves, presynaptically inhibits neurogenic NE release to modulate adrenergic neurotransmission.     

Norepinephrine and adenosine triphosphate release in different ratio from guinea pig vas deferens by high potassium chloride, ouabain and monensin

Release of norepinephrine (NE) and ATP from the guinea pig vas deferens evoked by ouabain in combination with monensin or by high KCl was measured by a high-pressure liquid chromatography-ECD and luciferin-luciferase assay, respectively. Ouabain (10-100 microM) induced a concentration-dependent liberation of NE, which was enhanced by 10 microM monensin, a Na+-ionophore. The marked NE release elicited by the combined administration of both the drugs was unaffected by Ca++-removal but was reduced by lowering Na+ from the medium. This NE release in the Ca++-free medium was diminished markedly after treatment with 6-hydroxydopamine or reserpine and in low-temperature (25 degrees C) medium. This release was also decreased by ruthenium red (10-30 microM), an uptake inhibitor of Ca++ to mitochondria, and carbonyl cyanide-m-chlorophenyl hydrazone (10 microM), a metabolic inhibitor. On the other hand, 100 mM KCl caused a moderate, extracellular Ca++-dependent release of NE. ATP-outflow from the tissue evoked by 100 microM ouabain plus 10 microM monensin was almost unaltered by Ca++-removal but was inhibited by 6-hydroxydopamine or prazosin (0.3 microM), whereas release induced by high KCl was reduced by 6-hydroxydopamine and Ca++-free medium but was unaffected by prazosin. ATP/NE ratios at respective maximum effluxes evoked by 100 mM KCl and ouabain plus monensin were 6.59 and 0.22, respectively. These findings suggest that there may be more than one site of corelease for NE and ATP. Ouabain plus monensin seems to produce an extracellular Ca++-independent neuronal release of NE and ATP from the cytoplasmic and vesicular storage sites which predominantly release NE.(ABSTRACT TRUNCATED AT 250 WORDS)     

Influence of TMB-8 and thapsigargin on vasoconstrictor responses in the pulmonary vascular bed of the cat

The effects of 8-(diethylamino)octyl-3,4,5-trimethoxybenzoate hydrochloride (TMB-8), a protein kinase C (PKC) inhibitor, and thapsigargin, a CaATPase inhibitor, on pressor responses were studied in the pulmonary vascular bed of the intact-chest anesthetized cat. Under conditions of constant lobar blood flow in the cat, injections of the angiotensin peptides (ANG II), norepinephrine (NE), serotonin (5-HT), Bay K 8644, and the thromboxane A2 mimic U46619 into the lobar arterial perfusion circuit caused dose-related increases in lobar arterial pressure and responses were reproducible with respect to time. Intravenous infusion of TMB-8 at 1.0 mug . kg reduced the pressor response to the ANG II and to NE. However, TMB-8 did not alter pressor responses to 5-HT, U46619, or Bay K 8644. In a separate series of experiments, the effects of thapsigargin were investigated and intravenous infusion of the CaATPase inhibitor at 1.0 mug . kg also reduced pressor responses to the ANG II and to NE but did not alter pressor responses to 5-HT, U46619, and Bay K 8644. The data provide support for the hypothesis that vasoconstrictor responses to ANG II and NE in the pulmonary vascular bed are mediated in part by the activation of protein kinase C (PKC) and sarcoplasmic reticulum CaATPase-sensitive mechanisms in the cat. The present data suggest that pulmonary pressor responses to U46619, 5-HT, and Bay K 8644 are not mediated by PKC or CaATPase activation in the pulmonary vascular bed of the cat.     

Determination of molecular size of alpha-1 and alpha-2 adrenoceptors in rat mesenteric artery by radiation inactivation

Radiation inactivation of alpha-1 and alpha-2 adrenoceptors in the purified plasma membranes of rat mesenteric artery has been performed with high energy electrons at -45 to -55 degrees C. Alpha-1 and alpha-2 adrenoceptor inactivation was monitored with [3H] prazosin and [3H]yohimbine binding, respectively. Internal endogenous and external standards of known molecular weight were used in these studies to determine the molecular size. The average value of D37 for the [3H]prazosin binding site was 6.75 +/- 0.62 Mrad (n = 4) with an estimated molecular size of 122,921 +/- 11,329 Daltons. However, the average value of D37 for the [3H] yohimbine binding site was higher (D37 = 10.05 +/- 0.91 Mrad) and accordingly the molecular size of this binding site was less than the [3H]prazosin binding sites (molecular weight = 82,540 +/- 7478 Daltons; n = 4). Irradiation did not change the dissociation constant of either radioligand, suggesting that the loss of the radioligand binding sites after radiation is due to receptor protein inactivation. These results confirm our earlier finding that [3H]prazosin and [3H]yohimbine bind to two distinct sites in the plasma membranes of rat mesenteric artery. Whether both of these sites are the subunits of a common macromolecule of alpha adrenoceptor on vascular smooth muscle in rat mesenteric artery cannot be concluded from these results. This report is the first one in the literature on the molecular size of alpha-1 and alpha-2 binding sites in vascular smooth muscle.     

Phenylpropanolamine constricts mouse and human blood vessels by preferentially activating alpha2-adrenoceptors

Phenylpropanolamine (dl-norephedrine) was one of the most widely used therapeutic agents to act on the sympathetic nervous system. Because of concerns regarding incidents of stroke, its use as a nasal decongestant was discontinued. Although considered an alpha1-adrenergic agonist, the vascular adrenergic pharmacology of phenylpropanolamine was not fully characterized. Unlike most other circulations, the vasculature of the nasal mucosa is highly enriched with constrictor alpha2-adrenoceptors. Therefore, experiments were performed to determine whether phenylpropanolamine activates vascular alpha2-adrenoceptors. Mouse tail and mesenteric small arteries and human small dermal veins were isolated and analyzed in a perfusion myograph. The selective alpha1-adrenergic agonist phenylephrine caused constriction of tail and mesenteric arteries and human veins. The selective alpha2-adrenergic agonist UK14,304 [5-bromo-N-(4,5-dihydro-1H-imidazol-2-yl)-6-quinoxalinamine] caused constriction in tail arteries and in human veins, but not mesenteric arteries. The lack of constriction to UK14,304 was also observed in endothelium-denuded mesenteric arteries. Phenylpropanolamine constricted both types of artery but was 62-fold more potent in tail arteries. In mesenteric arteries, constriction to phenylpropanolamine was not affected by the selective alpha2-adrenergic antagonist, rauwolscine (10(-7) M) but was abolished by the selective alpha1-adrenergic antagonist, prazosin (3 x 10(-7) M). In contrast, constriction to phenylpropanolamine in tail arteries and in human veins was inhibited by rauwolscine but not prazosin. Therefore, phenylpropanolamine is a preferential alpha2-adrenergic agonist. At low concentrations, it constricts blood vessels that express functional alpha2-adrenoceptors, whereas at much higher concentrations, phenylpropanolamine also activates vascular alpha1-adrenoceptors. This action likely contributed to phenylpropanolamine's therapeutic activity, namely constriction of the nasal vasculature.     

The effect of prior hypothermia on the physiological response to norepinephrine

OBJECTIVE: this study determines the effect of prior hypothermia on the cardiovascular responses to norepinephrine (NE) after rewarming. METHODS: the experiment was a 2x2 controlled design with four groups of feline animals. The two variables were the presence or absence of previous cooling, and the use or non-use of NE after rewarming. During the 'cooling' phase, animals were either cooled using an external arterial-venous femoral shunt to 30 degrees C or maintained at 37 degrees C. After 'rewarming' animals were stratified to receive either NE at rates to deliver 0.2, 1.0 or 5 microg/kg per h or normal saline infusions. Animals were instrumented to measure mean arterial pressure (MAP) and cardiac output (CO) and systemic vascular resistance (SVR) was calculated. RESULTS: there were no differences between groups at baseline and low dose NE (0.2 microg/kg per min). At 1.0 microg/kg per min, NE caused a significant increase in CO (P<0.01) and no effect of MAP or SVR in the rewarmed animals when compared with normothermic controls. In rewarmed animals 5.0 microg/kg per min NE caused a significant increase in CO (P<0.01) and no effect on MAP or SVR. In normothermic controls there was a significant increase in SVR (P=0.02) and MAP (P=0.05) and no effect on CO. CONCLUSION: this study shows that the effect of prior hypothermia on cardiovascular responses to moderate and high doses of NE is an improved CO with no affect on SVR and MAP. This could alter the clinical utility of NE in this situation.     

Prazosin selectively antagonizes norepinephrine contractions at low-affinity, non-alpha adrenoceptor sites (extraceptors) in arterial muscle

The characteristics of a low-affinity site activated by norepinephrine (NE), which is demonstrable in arterial smooth muscle pretreated with phenoxybenzamine (PBZ) to alkylate most alpha adrenoceptors were studied. Treatment with PBZ resulted in biphasic dose-response curves to NE. The initial phase associated with concentrations of NE up to 10(-5) M was due to its action in tissues where alpha adrenoceptors have been reduced to a number that would not support a maximum contraction. The second phase occurred with higher doses of NE. We postulate that this latter PBZ-resistant phase or contraction, which can represent more than 60% of the control maximal response, occurs at low-affinity sites for NE "extraceptors" distinct from alpha adrenoceptors in arterial smooth muscle. These residual responses to NE after PBZ treatment were inhibited selectively by prazosin and protected by prazosin from further inhibition by additional doses of PBZ. Effects due to prazosin at low-affinity sites were observed only with doses in excess of those required to competitively inhibit responses through alpha adrenoceptors in smooth muscle. The response to NE occurring through PBZ-resistant adrenoceptors was not dependent on the presence of the endothelium. This low-affinity site for NE was also evident after alkylation of alpha adrenoceptors with other irreversibly acting antagonists (e.g., benextramine and dibenamine). These observations are discussed in relation to the suggestion for a new adrenoceptor, the gamma-adrenoceptor. Differences and similarities of the extraceptor with this proposed adrenoceptor are discussed. Both sites have a high threshold to NE, and both may be influenced by prazosin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Differential antagonism of alpha-1 and alpha-2 adrenoceptor-mediated pressor responses by urotensin I, a selective mesenteric vasodilator peptide

In order to characterize the hemodynamic actions of urotensin I, a vasodilator peptide with selectivity for the mesenteric vascular bed, we studied its hypotensive effects and interference with alpha-1 and alpha-2 adrenergic vasoconstrictor responses in the rat. After i.v. administration in anesthetized rats, urotensin I (0.06-6 nmol/kg) produced a dose-dependent lowering of arterial blood pressure. At hypotensive doses, urotensin I was about 3 times more potent in antagonizing systemic pressor responses to the selective alpha-1 adrenoceptor agonist, phenylephrine, than responses to the nonselective adrenoceptor agonist, norepinephrine. Additional studies were performed on the blood-perfused mesenteric bed of the anesthetized rat and on the isolated rat superior mesenteric artery, using as tools phenylephrine, norepinephrine and the relatively selective alpha-2 adrenoceptor agonist, alpha-methylnorepinephrine. The selectivity of the three agonists for vascular alpha-1 and alpha-2 adrenoceptors in the blood-perfused mesenteric bed was confirmed using prazosin and yohimbine as selective antagonists of alpha-1 and alpha-2 adrenoceptors, respectively. Urotensin I diminished the maximum increase in perfusion pressure and shifted the log dose-response curves to the right for all three agonists. A marked selectivity of urotensin I for alpha-1 adrenoceptor-mediated responses was observed: IC30 values of the peptide for pressor responses to phenylephrine, norepinephrine and alpha-methylnorepinephrine were 0.05, 0.83 and greater than 6 nmol/kg, respectively. A less pronounced selectivity of urotensin I for alpha-1 adrenoceptor-mediated contractions could be demonstrated in isolated strips of the superior mesenteric artery of the rat.(ABSTRACT TRUNCATED AT 250 WORDS)