Sympathetic vascular control of the pig nasal mucosa (III): co-release of noradrenaline and neuropeptide Y

The overflows of noradrenaline (NA) and neuropeptide Y like immunoreactivity (NPYLI) and vascular responses upon sympathetic nerve stimulation were analysed in the nasal mucosa of pentobarbital anaesthetized pigs. In controls, a frequency-dependent increase in NA overflow was observed whereas detectable release of NPY-LI occurred only at 6.9 Hz. Parallel decreases in blood flow in the sphenopalatine artery and vein and in nasal mucosa volume (reflecting blood volume in the venous sinusoids) were observed. The laser Doppler flowmeter signal (reflecting superficial blood flow) increased upon low and decreased upon high frequency stimulation. Twenty-four hours after reserpine pretreatment and preganglionic decentralization, the NA overflow was abolished while a frequency-dependent release of NPY-LI occurred. Forty, 60 and 80% of the vasoconstrictor responses then remained upon stimulation with a single impulse, 0.59 and 6.9 Hz, respectively. Both the vasoconstriction and NPY-LI overflow, however, were subjected to fatigue upon repeated stimulation. In reserpinized animals release of NPY-LI and vasoconstrictor responses were larger upon stimulation with irregular bursts at 0.59 Hz compared to effects seen at stimulation with continuous impulses. Pre-treatment with the a-adrenoceptor antagonist phenoxybenzamine or the monoamine reuptake inhibitor, desipramine, enhanced NA overflow by 2–3 and 1.5 times at 0.59 and 6.9 Hz, respectively. Phenoxybenzamine significantly reduced the nerve-evoked vascular responses while the release of NPY-LI at 6.9 Hz was increased. Desipramine increased the functional responses but reduced the NPY-LI overflow. During tachyphylaxis to the vasoconstrictor effects of the stable adenosine 5′-triphosphate (ATP) analogue α-β-methylene ATP (mATP) in controls, the vasoconstrictor responses as well as the NA and NPY-LI overflow to nerve stimulation were unmodified. In reserpinized animals, however, the vascular responses and the overflow of NPY-LI were reduced after mATP tachyphylaxis. These data show that both NA and NPY are released upon sympathetic nerve stimulation in the nasal mucosa in vivo and this release seems to be regulated via prejunctional a-adrenoceptors. The lack of effect of mATP tachyphylaxis under control conditions makes it less likely that ATP serves as a major mediator of the large nonadrenergic vasoconstrictor component.     

Possible involvement of neuropeptide Y in sympathetic vascular control of canine skeletal muscle

Sympathetic nerve stimulation (2 min, 2 and 10 Hz) increased perfusion pressure in the blood perfused canine gracilis muscle in situ after pretreatment with atropine, desipramine and beta-adrenoceptor antagonists. This vasoconstriction was accompanied by clear-cut increases in the overflow of endogenous noradrenaline (NA) at both frequencies and, at 10 Hz but not at 2 Hz, also of neuropeptide Y-like immunoreactivity (NPY-LI). The irreversible alpha-adrenoceptor antagonist phenoxybenzamine enhanced the nerve stimulation induced overflows of NA and NPY-LI five- to eightfold and threefold, respectively. The fractional overflows of NA and NPY-LI per nerve impulse were similar in response to the high-frequency stimulation, indicating equimolar release in relation to the tissue contents of the respective neurotransmitter. The maximal vasoconstrictor response elicited by 10 Hz was reduced by about 50% following a dose of phenoxybenzamine which abolished the effect of exogenous NA and the remaining response was more long-lasting. Local i.a. infusion of NPY evoked long-lasting vasoconstriction in the presence of phenoxybenzamine, while the stable adenosine 5(1)-triphosphate (ATP) analogue alpha-beta-methylene ATP was without vascular effects. Locally infused NPY reduced the nerve stimulation evoked NA overflow by 31% (P less than 0.01) at 1 microM in arterial plasma, suggesting prejunctional inhibition of NA release. In conclusion, NPY-LI is released from the canine gracilis muscle upon sympathetic nerve stimulation at high frequencies. There is nerve stimulation evoked vasoconstriction, which is resistant to alpha-adrenoceptor blockade. This may in part be mediated by NPY released together with NA from the sympathetic vascular nerves.     

The role of ATP in non-adrenergic sympathetic vascular control of the nasal mucosa in anaesthetized cats and dogs.

1. In anaesthetized cats and dogs, local intra-arterial injection of noradrenaline and alpha, beta-methylene adenosine 5'-triphosphate (mATP) reduced both nasal arterial blood flow and nasal mucosal volume (a measure of capacitance vessel function). The responses to mATP were not modified by pretreatment with the adrenoceptor antagonists phentolamine and propranolol or the purinoceptor antagonist suramin. The vascular effects of noradrenaline were not altered by suramin, but were virtually abolished by adrenoceptor antagonists. 2. After adrenoceptor blockade, frequency-dependent reductions in nasal arterial blood flow with sympathetic nerve stimulation were reduced by 25 and 39% in cats and dogs, respectively; whereas the volume response was reduced by 56% in cats and 54% in dogs. The remaining non-adrenergic sympathetic nerve-evoked vascular responses were not influenced by suramin. 3. During desensitization to mATP induced by local intra-arterial infusion for 5 min, the remaining non-adrenergic nasal blood flow and volume responses to sympathetic nerve stimulation were reduced in the dog but not in the cat. 4. It is suggested that both adrenergic and non-adrenergic mechanisms are involved in the sympathetic control of the nasal mucosa vascular bed of both species. Since desensitization to mATP markedly reduces the remaining non-adrenergic nasal vasoconstriction evoked by sympathetic nerve stimulation in the dog, ATP is a possible sympathetic mediator in the nasal vascular bed in this species.     

Release and vasoconstrictor effects of neuropeptide Y in relation to non-adrenergic sympathetic control of renal blood flow in the pig

The possible involvement of neuropeptide Y (NPY) in sympathetic control of renal blood flow was investigated in the pig in vivo. Exogenous NPY caused renal vasoconstriction with a threshold effect at an arterial plasma concentration of 164 pmol 6(-1). Stimulation of the renal nerves (0.59, 2 and 10 Hz) in control animals evoked rapid and frequency-dependent reduction in renal blood flow and overflow of NPY-like immunoreactivity (NPY-LI) and noradrenaline (NA) from the kidney, suggesting co-release from sympathetic nerves. Following the administration of the alpha- and beta-adrenoceptor antagonists phenoxybenzamine and propranolol, the vasoconstrictor response to exogenous NA was reduced by 98%, whereas that of NPY was unaltered. The response to nerve stimulation with 0.59 Hz was abolished, whereas relatively slowly developing reductions in renal blood flow by 7 and 28% were obtained upon stimulation with 2 and 10 Hz respectively. The nerve stimulation-evoked overflow of NA at 0.59 and 2 Hz, but not at 10 Hz and not that of NPY-LI, was enhanced after adrenoceptor blockade. Twenty-four hours after reserpine treatment (1 mg kg-1 i.v.) the contents of NPY-LI and NA in the renal cortex were reduced by 80 and 98% respectively. Sectioning of the renal nerves largely prevented the reserpine-induced depletion of NPY-LI, but not that of NA. Nerve stimulation of the denervated kidney with 2 and 10 Hz 24 h after reserpine treatment evoked slowly developing and long-lasting reductions in renal blood flow by 6 and 52% respectively. These responses were associated with overflow of NPY-LI, which was similar to and threefold higher than that observed in controls at 2 and 10 Hz respectively, while no detectable overflow of NA occurred. Repeated stimulation with 10 Hz resulted in a progressive fatigue of the vasoconstrictor response and the associated overflow of NPY-LI, giving a high correlation (r = 0.86, P less than 0.001) between the two parameters. It is concluded that NPY is a potent constrictor of the renal vascular bed. Furthermore, although NA is the likely transmitter mediating most of the responses to low to moderate nerve activation under control conditions, the data suggest that NPY may mediate the non-adrenergic reductions in renal blood flow evoked by high-frequency sympathetic nerve stimulation after reserpine treatment.     

Neuropeptide Y and differential sympathetic control of splenic blood flow and capacitance function in the pig and dog

The roles of different mediators in the sympathetic regulation of the pig and dog spleens were investigated using a preparation with intact vascular perfusion in vivo. Sympathetic nerve stimulation caused overflow of neuropeptide Y-like immunoreactivity (NPY-LI) and noradrenaline (NA), arterial vasoconstriction, increase in venous blood flow and haematocrit. The dog spleen responded to single impulse stimulation, whereas more prolonged stimulation was required to elicit vascular responses in the pig spleen. Furthermore, the maximal splenic capacitance response was about 10 times larger in the dog than in the pig. After depletion of neuronal NA content by reserpine combined with preganglionic denervation, about 70% of the splenic arterial vasoconstrictor responses in the dog and pig still remained at 5 Hz stimulation. Fifty per cent of the capacitance response evoked by nerve stimulation still remained in the pig while in the dog spleen the capacitance response was virtually abolished after reserpine. The stimulation-evoked overflow of NPY-LI in pig spleen was increased several fold after reserpine treatment as compared to controls reaching levels in the venous effluent where exogenous NPY evokes vasoconstriction. In the dog spleen, overflow of NPY-LI was only observed after reserpine. Administration of NA caused arterial vasoconstriction with an initial increase in venous blood flow while NPY mainly reduced arterial blood flow. It is concluded that NA is involved in both the splenic arterial vasoconstriction and the capacitance responses while a non-adrenergic splenic vasoconstriction at least in the pig may be mediated by NPY.     

Guanethidine-sensitive release of neuropeptide Y-like immunoreactivity in the cat spleen by sympathetic nerve stimulation

Splenic nerve stimulation (10 Hz for 2 min) caused a perfusion-pressure increase, a volume reduction and an increase in the output of neuropeptide Y-like immunoreactivity (NPY-LI) from the isolated blood-perfused cat spleen. Gel-filtration HPLC analysis revealed that plasma NPY-LI collected during nerve stimulation was similar to the NPY-LI in the spleen and synthetic porcine NPY. Combined propranolol and phenoxybenzamine pretreatment enhanced NPY output upon nerve stimulation by about 60%. Forty percent of the perfusion-pressure increase and 25% of the volume reduction seen during control stimulations remained after adrenoceptor blockade. Guanethidine abolished the release of NPY-LI, the perfusion-pressure increase and the volume reduction normally seen upon splenic nerve stimulation. Infusion of synthetic porcine NPY caused a long-lasting increase in perfusion pressure and a relatively moderate volume reduction. Noradrenaline (NA) both increased perfusion pressure and induced a marked volume reduction. The NPY effects were resistant to adrenoceptor antagonists in doses which abolished the NA response. In conclusion, the present data show that NPY-LI is released upon sympathetic nerve stimulation by a guanethidine-sensitive mechanism. Furthermore, the sympathetic response is partially resistant to adrenoceptor antagonists and NPY has powerful vasoconstrictor effects. This provides further evidence for a role of NPY in sympathetic vascular control.     

Time-dependent effects of ischaemia on neuropeptide Y mechanisms in pig renal vascular control in vivo

We have investigated the effects of ischaemia on neuropeptide Y (NPY) mechanisms involved in sympathetic vascular control of the pig kidney in vivo. Reperfusion after 2 h of renal ischaemia was associated with local overflow of noradrenaline (NA) but not of NPY-like immunoreactivity (-LI). Renal sympathetic nerve stimulation 10 min into reperfusion evoked markedly reduced vasoconstrictor effects and significantly less overflow of NA (reduced by 70% from the pre-ischaemic conditions), whereas NPY-LI overflow was unaltered. Renal vasoconstrictor responses to exogenous peptide YY (PYY), phenylephrine and angiotensin II were strongly attenuated after this ischaemic period, while vasoconstriction to α,β-methylene ATP was maintained to a larger extent. The renal vascular responses and NA overflow had become partially normalized within a 2 h recovery period. In contrast, the renal vasoconstrictor response and the overflow of NPY-LI upon sympathetic nerve stimulation were enhanced after 15 min of renal ischaemia. In parallel, the PYY-evoked renal vasoconstriction was selectively and markedly prolonged after the 15 min of ischaemia. In the presence of the NPY Y₁ receptor antagonist BIBP 3226, the augmented vascular response to nerve stimulation was significantly attenuated. We conclude that reperfusion after 2 h of renal ischaemia is associated with local overflow of NA, whereas the sympathetic nerve-evoked release of NA and the reactivity of the renal vasculature to vasoconstrictor stimuli are reversibly reduced. Furthermore, possibly due to an impaired local degradation, the role of neurogenically released NPY in renal sympathetic vasoconstriction is enhanced after short-term (15 min) ischaemia compared with control conditions.     

Frequency- and reserpine-dependent chemical coding of sympathetic transmission: differential release of noradrenaline and neuropeptide Y from pig spleen

The importance of impulse pattern and stimulation frequency for the release of noradrenaline (NA) and the coexisting peptide neuropeptide Y (NPY) in relation to vasoconstriction (perfusion-pressure increase) was studied in the blood-perfused pig spleen in vivo. Splenic nerve stimulation with intermittent bursts at high frequency (20 Hz) caused a several-fold larger release of NPY-like immunoreactivity (-LI) in relation to NA than a continuous stimulation at a low frequency (2 Hz), giving the same total number of impulses. alpha-Adrenoceptor blockade by phentolamine enhanced markedly both NA and NPY release, especially at low stimulation frequency, suggesting prejunctional adrenergic inhibition of release. Addition of propranolol unmasked a large remaining perfusion-pressure response to nerve stimulation. Reserpine treatment reduced the NA content of the spleen as well as the stimulation-evoked NA release by greater than 90%. However, the perfusion-pressure increase in response to nerve stimulation was well maintained. A marked increase in the stimulation-evoked release of NPY-LI occurred after reserpine. Adrenoceptor blockade after reserpine treatment reduced only slightly the perfusion-pressure response in parallel with a decline in NPY output. NPY caused an adrenoceptor-resistant perfusion-pressure increase at plasma concentrations that were in the same range as the maximal increase during nerve stimulations. In conclusion, the present data suggest a frequency-dependent, chemical coding of sympathetic transmission with preferential release of the classical transmitter NA at low, continuous frequencies and release of NPY, mainly at high frequencies. Reserpine treatment enhances markedly NPY release, which may explain why the functional response is largely intact in spite of adrenoceptor blockade and marked NA depletion.     

Pancreatic polypeptide family (APP,BPP, NPY and PYY) in relation to sympathetic vasoconstriction resistant to α-adrenoceptor blockade

Electrical stimulation of the cat cervical sympathetic trunk caused submandibular salivary secretion and vasoconstriction simultaneously with a contraction of the nictitating membrane. Following α- and β-adrenoceptor blockade by phentolamine or phenoxybenzamine combined with propranolol, the salivary response and the nictitating membrane contraction upon sympathetic stimulation were almost abolished. A considerable vasoconstrictor response (up to 40% of control) however still remained in the submandibular gland. This yasoconstriction, which persisted after α-adrenoceptor blockade, was rather slow in onset and had a long duration without any poststimulatory hyperemia. Local intra-arterial infusions of noradrenaline caused submandibular vasoconstriction, salivary secretion and nictitating membrane contraction. The blood flow response to exogenous noradrenaline did, however, not mimic the effects of sympathetic nerve stimulation with regard to vascular escape. Whereas the vascular escape after nerve stimulation was followed by a prolonged vasoconstriction with a gradual decline, the escape after noradrenaline infusions was accompanied by a normalization of blood flow. Local intra-arterial infusions of pancreatic polypeptide (PP)-related peptides caused a slowly developing vasoconstriction with a long duration in the submandibular gland, but no salivary secretion or contraction of the nictitating membrane. The relative molar potencies as vasoconstrictory agents were about PYY: 1, neuropeptide Y (NPY): 5, avian and bovine pancreatic polypeptid 100. The vasoconstrictor effects of PP-related peptides were resistant to α-adrenoceptor blockade and present also in sympathectomized animals, suggesting a direct action on vascular smooth muscle. Combined local infusions of noradrenaline and NPY caused a vascular response in the submandibular salivary gland which was similar to that seen upon sympathetic nerve stimulation. PYY and NPY caused increase in systemic arterial blood pressure upon systemic administration which indicates general vasoconstrictor actions. This effect was accompanied by a transient bradycardia which was due to inhibition of sympathetic tone, since it was absent in animals treated with propranolol. In conclusion, the present findings illustrate the differential sensitivity to α-adrenoceptor antagonists of the submandibular vasoconstriction and salivation as well as smooth muscle contraction of the nictitating membrane induced by sympathetic nerve stimulation. This remaining vasoconstriction may be explained by release of a nonadrenergic, PP-related transmitter such as NPY which may be present together with noradrenaline in the vascular nerves. Release of an additional vasoconstrictory factor may also account for the finding that infusions of noradrenaline do not mimic the vascular effects of sympathetic nerve stimulation in vivo.     

Neuropeptide Y may mediate effects of sympathetic nerve stimulations on colonic motility and blood flow in the cat

The present study investigated sympathetic mechanisms involved in the regulation of colonic motility and blood flow in the cat. Infusion of neuropeptide Y (NPY) close i.a. produced an inhibition of colonic motility and a vasoconstriction of long duration but no post-infusion vasodilatation. In contrast to NPY, porcine pancreatic polypeptide did not evoke any vascular or motility response. On a molar basis, NPY was 25 times more potent than noradrenaline in producing 50% reduction of the colonic blood flow. These vascular and motility effects of NPY were resistant to guanethidine, phentolamine, phenoxybenzamine and propranolol. Thus, the action of NPY on vascular and colonic smooth muscle did not seem to be mediated via adrenergic receptors. Noradrenaline administered close i.a. produced inhibition of colonic motility, and vasoconstriction followed by a rapid vasodilatation. These effects were completely blocked by combined alpha- and beta-adrenoceptor blockade. Electrical stimulation of the splanchnic and lumbar colonic nerves produced an overall inhibition of colonic motility, and vasoconstriction of the proximal and distal colon, respectively, with a rapid post-stimulatory vasodilatation. After combined alpha- and beta-adrenoceptor blockade the inhibitory effect of the nerve stimulations on colonic motility partly remained together with a marked vasoconstriction, which was most pronounced upon lumbar colonic nerve stimulation. All vascular effects of sympathetic nerve stimulation were eradicated by guanethidine, which also abolished the inhibitory motility response to splanchnic nerve stimulation. However, lumbar colonic nerve stimulation elicited a colonic contraction, possibly due to stimulation of afferent C-fibres. The present findings indicate the existence of a sympathetic nonadrenergic neuronal mechanism mediating vasoconstriction and inhibition of colonic motility in the cat. Thus, NPY may be released from noradrenergic neurons to act on colonic smooth muscle and vessels.     

Neuropeptide Y and sympathetic control of heart contractility and coronary vascular tone

The effects of neuropeptide Y (NPY) on contractility of the spontaneously beating guinea-pig atrium and transmural nerve stimulation (TNS)-induced efflux of tritium-noradrenaline (3H-NA) were studied in vitro. NPY induced a moderate positive chronotropic and inotropic atrial response, which was resistant to metoprolol. TNS at 2 Hz for 2 s caused an increase in rate and contractile force. These effects were significantly reduced by NPY. NPY also reduced the TNS induced (2 Hz for 20 s), fractional [3H]NA release by 40% without affecting the contractile response. The contractile effects of exogenous NA on the guinea-pig atrium were not affected by NPY. NPY caused a long-lasting increase in coronary perfusion pressure, and also, in high doses, an inhibition of ventricular contractility in the isolated, perfused guinea-pig heart. The perfusion pressure increase to NPY, which most likely reflects coronary vasoconstriction, was resistant to alpha- and beta-adrenoceptor blockade but sensitive to the calcium antagonist nifedipine. A 50% reduction of the vascular NPY response occurred at 10(-9) M nifedipine, which did not influence cardiac contractility per se or the contractile effects of NA. NPY did not modify the increase in ventricular contractility induced by NA. Noradrenaline did not influence coronary perfusion pressure after beta-blockade. Since NPY is present together with NA in cardiac nerves, it may be suggested that NPY is involved in the regulation of NA release as well as the sympathetic control of atrial contractility and coronary blood flow.     

Renal sympathetic nerve activation in relation to reserpine-induced depletion of neuropeptide Y in the kidney of the rat

The effect of reserpine treatment on renal sympathetic nerve activity and tissue levels of neuropeptide Y (NPY)-like immunoreactivity (LI) and noradrenaline (NA) were studied in rats. Injection of reserpine (1 mg kg-1 i.v.) caused a clear-cut (about 50%) increase in rectified activity of the post-ganglionic sympathetic nerves to the kidney within 15 min in chloralose-anaesthetized rats compared to a saline-treated control group. This increase in nerve activity was still maintained 120 min after the reserpine injection. The renal nerve activation was accompanied by a progressive fall in mean arterial blood pressure and an initial tachycardia. In a separate group of conscious rats, the levels of NPY-LI (1.3 +/- 0.06 pmol g-1) and NA (1.6 +/- 0.07 nmol g-1) in the kidney were significantly reduced (by 74 and 83%, respectively) 24 h after reserpine treatment (1 mg kg-1 i.v.). The reserpine-induced depletion of NPY-LI, but not that of NA, was inhibited by pretreatment with the ganglionic blocking agent chlorisondamine or the alpha 2-adrenoceptor agonist clonidine, both of which are known to decrease renal sympathetic nerve activity. The tissue content of NPY-LI in the right atrium (16.3 +/- 0.7 pmol g-1) was not reduced by reserpine. Arterial plasma NPY-LI in the rat was high (222 +/- 5 pmol l-1), and this value did not change after pretreatment with reserpine, chlorisondamine or clonidine, indicating that, in the rat, circulating NPY-LI is not a good indicator of sympatho-adrenal activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of cervical sympathetic nerve stimulation and neuropeptide Y (NPY) on cranial blood flow in the cat

Effects of cervical sympathetic nerve stimulation (SNS) at 10 Hz and intravenous infusion of neuropeptide Y (NPY), 10 and 100 pmol x kg body wt-1 x min-1 for 5 min, on regional blood flow in the cat were investigated with radioactive microspheres. Sympathetic nerve stimulation caused significant reductions in blood flows in the facial tissues including the eye. Alpha-adrenoceptor blockade with phenoxybenzamine and combined beta- and alpha-adrenoceptor blockade with propranolol and phenoxybenzamine abolished the effects of sympathetic nerve stimulation in most facial tissues except in the tongue, upper eyelid and masseter muscle. In most cranial tissues, neuropeptide Y reduced regional blood flow and increased vascular resistance. No effect of neuropeptide Y on vascular resistance was observed in the choroid. In the present study, evidence for a non-adrenergic component in sympathetic vasoconstriction was found in the tongue, upper eyelid and masseter muscle but not in the majority of feline facial tissues. Neuropeptide Y was a potent vasoconstrictor in many cranial tissues, while in parts of the uvea, the effects of neuropeptide Y were less pronounced.     

Sympathetic vascular control of the pig nasal mucosa: (I) increased resistance and capacitance vessel responses upon stimulation with irregular bursts compared to continuous impulses

An in vivo model is described in which pentobarbital anaesthetized pigs were used to study the sympathetic nervous control of the nasal mucosal vascular bed. Changes in blood flow in the sphenopalatine artery (representing nasal blood flow) and in the volume of the nasal cavity (mainly reflecting blood content in venous sinusoids), upon electrical stimulation of the cervical sympathetic trunk, were recorded simultaneously. Single impulses (15V, 5 ms) reduced both the arterial flow and the volume of the nasal mucosa. The effects of nerve stimulation with a continuous train of impulses at 0.59, 2 and 6.9 Hz were compared with those caused by stimulation with the irregular bursting pattern, triggered by recorded human sympathetic vasoconstrictor nerve activity, with the same average frequencies. Both types of stimulation reduced nasal blood flow and volume, but the responses were significantly larger with burst stimulation at 0.59 Hz. The volume reduction was already maximal at 0.59 Hz while the blood flow response increased further higher frequencies. Local intra-arterial pretreatment with the α-adrenoceptor antagonist phenoxybenzamine significantly attenuated the flow and volume responses to single impulses, while clear-cut reductions in blood flow (by 40%) and volume (by 80%) remained, upon stimulation, at 6.9 Hz. Noradrenaline given intra-arterially caused a dose-dependent reduction in nasal blood flow and volume. The noradrenaline effects were blocked by phenoxybenzamine treatment. The results show that the pig nasal mucosa represents a model where both blood flow and volume changes can be studied in parallel in vivo. Furthermore, stimulation with the firing pattern of human vasoconstrictor nerves, i.e. irregular bursts, causes larger vascular responses in the pig nasal mucosa compared to a continuous stimulation. The large residual vascular responses to sympathetic nerve stimulation at high frequency after a-adrenoceptor blockage may be mediated by some other non-adrenergic transmitter substance(s).     

Prejunctional beta 2-adrenoreceptor blockade reduces nerve stimulation evoked release of endogenous noradrenaline in skeletal muscle in situ

Prejunctional beta-adrenoceptor-mediated modulation of endogenous noradrenaline (NA) overflow elicited by sympathetic nerve stimulation was studied in blood-perfused canine gracilis muscle in situ. An attempt was made to subclassify these beta-adrenoceptors by comparing the effects of beta 1-selective (metoprolol) and non-selective (propranolol) beta-adrenoceptor blockade. Animals were pre-treated with desipramine and phenoxybenzamine in order to counteract possible influences of neuronal uptake and stimulation-evoked changes in vascular resistance on the diffusion of NA into the blood stream. Metoprolol did not decrease stimulation-evoked NA overflow, as compared with control experiments (-10 and -8%, respectively). However, propranolol reduced stimulation-evoked NA overflow by 30% in metoprolol pre-treated animals (P less than 0.05 vs. control experiments). Both antagonists elevated basal perfusion pressure, suggesting that vascular post-junctional beta 1- as well as beta 2-adrenoceptors are present. Propranolol increased stimulation-evoked vasoconstriction in metoprolol pre-treated animals, indicating that neuronally released NA may activate postjunctional beta 2-adrenoceptors under these experimental conditions. In conclusion, our findings suggest that NA release can be enhanced by activation of prejunctional beta 2-adrenoceptors in vivo.     

Transmitter characteristics of cutaneous,renal and skeletal muscle small arteries in the rat

Aim: We studied transmitter characteristics of proximal and distal arteries supplying skin (saphenous artery and its medial tarsal branch), kidneys (terminal branches of renal artery and interlobar arteries) and skeletal muscle (proximal and distal sections of external sural artery). Methods: Artery segments were mounted in an isometric myograph and intramural nerves were activated by electrical field stimulation. Adrenergic and purinergic components of the neurogenic response were blocked using phenoxybenzamine and α,β‐methylene adenosine triphosphate (mATP), respectively. Results: Arteries from skin or kidney developed rapid and prominent neurogenic contractile responses, with half‐maximal amplitude reached within 5–15 s; responses in proximal vessels were greater than in distal vessels. Arteries from skeletal muscle responded to sympathetic stimulation with a moderate contraction developing over 1 min or more, the response of distal segments was greater than that of proximal segments. In skeletal muscle vessels the sympathetically evoked contraction was completely blocked by phenoxybenzamine, whereas in skin and renal vessels it was the combined effect of noradrenaline and adenosine triphosphate (ATP). Given alone, mATP did not change the magnitude of the response to nerve stimulation, but increased its latency and also potentiated the response to exogenous noradrenaline. In all vascular beds, distal vessels were more sensitive to noradrenaline and mATP. Conclusion: It thus appears that the noradrenaline/ATP ratio of the sympathetic vasoconstrictor response differs between vascular beds in a way that is consistent with known differences in the selective regulation of regional vascular resistance by the sympathetic nervous system.     

Sympathetic vascular control of the pig nasal mucosa: (I). Increased resistance and capacitance vessel responses upon stimulation with irregular bursts compared to continuous impulses

An in vivo model is described in which pentobarbital anaesthetized pigs were used to study the sympathetic nervous control of the nasal mucosal vascular bed. Changes in blood flow in the sphenopalatine artery (representing nasal blood flow) and in the volume of the nasal cavity (mainly reflecting blood content in venous sinusoids), upon electrical stimulation of the cervical sympathetic trunk, were recorded simultaneously. Single impulses (15V, 5 ms) reduced both the arterial flow and the volume of the nasal mucosa. The effects of nerve stimulation with a continuous train of impulses at 0.59, 2 and 6.9 Hz were compared with those caused by stimulation with the irregular bursting pattern, triggered by recorded human sympathetic vasoconstrictor nerve activity, with the same average frequencies. Both types of stimulation reduced nasal blood flow and volume, but the responses were significantly larger with burst stimulation at 0.59 Hz. The volume reduction was already maximal at 0.59 Hz while the blood flow response increased further higher frequencies. Local intra-arterial pretreatment with the alpha-adrenoceptor antagonist phenoxybenzamine significantly attenuated the flow and volume responses to single impulses, while clear-cut reductions in blood flow (by 40%) and volume (by 80%) remained, upon stimulation, at 6.9 Hz. Noradrenaline given intra-arterially caused a dose-dependent reduction in nasal blood flow and volume. The noradrenaline effects were blocked by phenoxybenzamine treatment. The results show that the pig nasal mucosa represents a model where both blood flow and volume changes can be studied in parallel in vivo.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mechanisms underlying changes in the contents of neuropeptide Y in cardiovascular nerves and adrenal gland induced by sympatholytic drugs

Neuropeptide Y (NPY) is a recently isolated vasoactive peptide, which is present, together with catecholamines, in sympathetic nerves and in the adrenal medulla. In the present study, we report that pretreatment with sympatholytic agents influences the tissue levels of NPY-like immunoreactivity (NPY-LI) in the guinea-pig. Thus, 24 h after reserpine not only noradrenaline (NA), but also NPY-LI, was depleted in the heart, spleen and the adrenal gland. The levels of NPY-LI in the vas deferens and stellate ganglia, however, were unaffected by reserpine in spite of marked depletions of NA. The reserpine-induced depletion of NPY-LI was probably caused by enhanced nerve-impulse flow and subsequent release from cardiovascular nerves in excess of resupply, since it could be prevented by the ganglionic-blocking agent chlorisondamine. Long-term (6 days) treatment with chlorisondamine reduced the levels of NPY-LI in the stellate ganglion. Short-term treatment (48 h) with guanethidine partially prevented the reserpine-induced depletion of NPY-LI, probably due to inhibition of NPY release. Long-term guanethidine treatment depleted not only NA, but also NPY-LI from the spleen. Pretreatment with the alpha-receptor antagonist phenoxybenzamine did not influence the NA levels but reduced the content of NPY-LI in the spleen via a mechanism that was dependent on intact ganglionic transmission. Since NPY has several cardiovascular actions, changes in NPY mechanisms may contribute to the pharmacological and therapeutical effects of sympatholytic agents.     

Transmitter characteristics of cutaneous,renal and skeletal muscle small arteries in the rat

AIM: We studied transmitter characteristics of proximal and distal arteries supplying skin (saphenous artery and its medial tarsal branch), kidneys (terminal branches of renal artery and interlobar arteries) and skeletal muscle (proximal and distal sections of external sural artery). METHODS: Artery segments were mounted in an isometric myograph and intramural nerves were activated by electrical field stimulation. Adrenergic and purinergic components of the neurogenic response were blocked using phenoxybenzamine and alpha,beta-methylene adenosine triphosphate (mATP), respectively. RESULTS: Arteries from skin or kidney developed rapid and prominent neurogenic contractile responses, with half-maximal amplitude reached within 5-15 s; responses in proximal vessels were greater than in distal vessels. Arteries from skeletal muscle responded to sympathetic stimulation with a moderate contraction developing over 1 min or more, the response of distal segments was greater than that of proximal segments. In skeletal muscle vessels the sympathetically evoked contraction was completely blocked by phenoxybenzamine, whereas in skin and renal vessels it was the combined effect of noradrenaline and adenosine triphosphate (ATP). Given alone, mATP did not change the magnitude of the response to nerve stimulation, but increased its latency and also potentiated the response to exogenous noradrenaline. In all vascular beds, distal vessels were more sensitive to noradrenaline and mATP. CONCLUSION: It thus appears that the noradrenaline/ATP ratio of the sympathetic vasoconstrictor response differs between vascular beds in a way that is consistent with known differences in the selective regulation of regional vascular resistance by the sympathetic nervous system.     

Neuropeptide Y (NPY) induced inhibition of preganglionic nerve stimulation evoked release of adrenalin and noradrenaline in the pithed rat

NPY, a peptide with 36 amino acid residues, is co-stored together with noradrenaline (NA) in cardiac and sympathetic perivascular nerves as well as with adrenalin (A) in adrenal chromaffin cells. NPY is released together with NA from sympathetic nerves and with A from the adrenal glands and appears to be involved in the control of sympathetic neurotransmission. The aim of the present study was to analyse the effect of NPY on the preganglionic nerve stimulation (PNS) evoked increases in plasma A and NA concentrations in pithed rats. In the first part of the study (I) only one PSN period (2 Hz for 45 s) was performed in each rat and the control group was compared to the NPY treated group. In the second part of the study (II) two PNS periods (1 Hz for 45 s) were performed in each rat, which either received saline or NPY before the second PNS. Thus, interindividual changes between the responses to the first and second PNS in control and NPY rats could be compared. In both study I and II, systemic infusion of NPY (2 micrograms kg-1 min-1 i.v.) significantly reduced the PNS-induced increase in plasma A by 26% and 42%, respectively (P less than 0.05). However, the increase in plasma NA elicited by PNS was significantly reduced only in study II by 23% (P less than 0.05). Infusion of NPY did not affect basal heart rate in either of the studies, but significantly increased basal blood pressure by about 10 mmHg. The blood pressure responses to PNS were significantly greater in NPY treated rats.(ABSTRACT TRUNCATED AT 250 WORDS)