Intrathecal neurokinin A facilitates the spinal nociceptive flexor reflex evoked by thermal and mechanical stimuli and synergistically interacts with substance P.

The neuropeptide neurokinin A was injected intrathecally and its effect on the spinal nociceptive flexor reflex was examined. The reflex, which was evoked by electrical, thermal or mechanical stimulation of the foot and was recorded from the ipsilateral hamstring muscles, was substantially facilitated by 7 pmol intrathecally injected neurokinin A. The facilitatory effect of neurokinin A to thermal stimulation was, however, significantly stronger than to electrical or mechanical stimuli. Furthermore, co-administration of neurokinin A with substance P induced a significant synergistic facilitation of the reflex. It is suggested that neurokinin A, like substance P, may be released in association with activation of polymodal C-nociceptors.     

Intrathecal vasoactive intestinal polypeptide modulates spinal reflex excitability primarily to cutaneous thermal stimuli in rats

The effect of intrathecally (i.t.) injected vasoactive intestinal polypeptide (VIP) on spinal nocifensive flexor reflex excitability was examined in decerebrate, spinalized, unanesthetized rats. The hamstring reflex was evoked by intense cutaneous mechanical or thermal stimulation of the ipsilateral foot. I.t. VIP increased the excitability of the spinal cord to thermal much more than to mechanical stimuli. It is suggested that this neuropeptide is released by thermosensitive cutaneous afferents that respond poorly to mechanical stimuli.     

Intrathecal galanin at low doses increases spinal reflex excitability in rats more to thermal than mechanical stimuli

Summary The neuropeptide galanin (GAL) was injected intrathecally (i.t.) in decerebrate, spinalized, unanesthetized rats and its effect on the nocifensive flexor reflex was examined. The reflex, which was evoked by intense mechanical or thermal stimulation of the foot, was recorded from the ipsilateral hamstring muscles. I.t. GAL increased reflex excitability significantly more to thermal than to mechanical stimuli. It is suggested that GAL, which is present in sensory fibers that innervate the skin, is released by the central terminals of cutaneous afferents that are much more sensitive to thermal than to mechanical stimuli.     

On the role of NK-2 tachykinin receptors in the mediation of spinal reflex excitability in the rat.

The effects of intrathecal administration of neurokinin A, substance P and [Tyr5, D-Trp6,8,9 Arg10]neurokinin A-(4-10) (Men 10207), a specific NK-2 receptor antagonist, on the spinal nociceptive flexor reflex were studied in decerebrate, spinalized, unanesthetized rats. Intrathecal neurokinin A and substance P facilitate the flexor reflex in a similar manner. The reflex facilitation to intrathecal neurokinin A, but not substance P, is dose-dependently blocked by pretreatment with Men 10207. The NK-2 receptor antagonist by itself facilitates the flexor reflex with a potency about 10 times less than that of neurokinin A, indicating a partial agonistic property. Reversible depression of the flexor reflex, which is not due to nonspecific spinal blockade, is observed after 700 pmol Men 10207. Further increasing the dose of Men 10207 to 7 nmol for 20 s at an intensity that activates unmyelinated (C) fibers stimulation of peripheral nerves at 1 Hz for 20 s at an intensity that activates unmyelinated (C) fibers facilitates the ipsilateral flexor reflex. The duration of the facilitation after conditioning stimulation of the cutaneous sural nerve is several minutes and about 1 h after conditioning stimulation of the gastrocnemius muscle nerves. Pretreatment with Men 10207 (70-700 pmol) has no effect on facilitation by the sural nerve conditioning stimulation, but effectively blocks the long-term reflex facilitation to the gastrocnemius nerve stimulation. The present results indicate a distinct role for NK-2 tachykinin receptors in mediation of spinal reflex excitability in the rat. Neurokinin A may be involved in the long-term increase of spinal reflex excitability after activation of unmyelinated fibers innervating muscle.     

Release, spread and persistence of immunoreactive neurokinin A in the dorsal horn of the cat following noxious cutaneous stimulation. Studies with antibody microprobes

In barbiturate anaesthetized spinal cats antibody microprobes were used to examine release of immunoreactive neurokinin A following cutaneous thermal and mechanical stimulation. In the absence of peripheral stimuli, microprobes detected a diffuse basal presence of immunoreactive neurokinin A. Noxious mechanical and to a lesser extent noxious thermal stimuli increased the levels of immunoreactive neurokinin A diffusely throughout the dorsal horn which, in many cases, spread into the adjacent white matter. These diffuse stimulus-evoked increases contrast with previous experiments where the same stimuli produced discrete focal increases in levels of immunoreactive substance P. Evidence was obtained that released immunoreactive neurokinin A persisted in the spinal cord for at least 30 min beyond the period of stimulation. Neurokinin A needs consideration as the agent responsible for the long-lasting increases in excitability of some spinal neurons found by several laboratories to follow a brief input from unmyelinated primary afferents.     

Effects of intranigral substance P and neurokinin A on striatal dopamine release--I. Interactions with substance P antagonists.

The functional role of striatonigral neurokinins were studied by analysing the effects of intranigral injections of substance P and neurokinin A on the extracellular level of dopamine and dihydroxyphenylacetic acid in the striatum, as measured by in vivo microdialysis in rats. Two substance P antagonists, substance P D-Pro2 D-Trp7,9 and substance P D-Arg1 D-Trp7,9 Leu11 were tested and analysed for their ability to block the neurokinin effects. Unilateral injections of substance P (0.00007-7.0 nmol injected in 0.2 microliter) as well as neurokinin A (0.009-9.0 nmol) into the substantia nigra, pars reticulata of halothane anaesthetized rats produced long-lasting increases in ipsilateral striatal dopamine and dihydroxyphenylacetic acid levels. The dose-response relationship for substance P on dopamine was biphasic, with maximal effects occurring after the middle dose (0.007-0.07 nmol). The dose-response relationship for neurokinin A was monophasic. Intranigral injections of substance P D-Pro2 D-Trp7,9 (0.07-0.7 nmol) or substance P D-Arg1 D-Trp7,9 Leu11 (0.07-0.7 nmol) produced a decrease in striatal dopamine, but an increase in striatal dihydroxyphenylacetic acid. At a low dose (0.07 nmol) substance P D-Pro2 D-Trp7,9 enhanced the dopamine increase produced by intranigral substance P (0.07 nmol) or neurokinin A (0.09), while at a high dose (0.7 nmol) it blocked both substance P and neurokinin A effects. Both doses of substance P D-Arg1 D-Trp7,9 Leu11 (0.07 and 0.7 nmol) blocked the substance P- but not the neurokinin A-induced increase in striatal dopamine. Immunohistochemical analysis revealed that high doses of substance P (7.0 nmol) and neurokinin A (0.9 and 9.0 nmol), as well as substance P D-Pro2 D-Trp7,9 and substance P D-Arg1 D-Trp7,9 Leu11 (0.07 and 0.7 nmol), induced a restricted loss of tyrosine hydroxylase in dendrites and cells, and neuropeptide K in terminals, at the site of injection. Further analysis shows that co-administration of substance P (0.07 nmol) or neurokinin A (0.09 nmol) did not modify the extent of the depletion of both immunoreactivities induced by substance P D-Arg1 D-Trp7,9 Leu11 (0.7 nmol). The extent of the effect produced by substance P D-Arg1 D-Trp7,9 Leu11 (0.7 nmol) was, however, smaller than the spread of intranigral injection of [125I]Bolton-Hunter-labelled substance P D-Arg1 D-Trp7,9 Leu11, and it is suggested that the "neurotoxic" effects of the substance P antagonists are not primarily involved in their abilities to inhibit striatal dopamine release and block the stimulation of dopamine after intranigral substance P and neurokinin A.(ABSTRACT TRUNCATED AT 400 WORDS)     

Tachykinins and calcitonin gene-related peptide as co-transmitters in local motor responses produced by sensory nerve activation in the guinea-pig isolated renal pelvis.

Electrical field stimulation of circular muscle strips from the guinea-pig isolated renal pelvis produces a frequency-dependent positive inotropic effect of the spontaneous contractions which is unaffected by atropine and guanethidine and abolished by tetrodotoxin or in vitro capsaicin desensitization. Omega conotoxin fraction GVIA markedly inhibited the response to low frequencies of stimulation but had only a partial or minor inhibitory effect at higher frequencies. Tachykinins produce a concentration-dependent positive inotropic effect, neurokinin A being more potent than substance P. On the other hand, rat alpha calcitonin gene-related peptide (CGRP) inhibited spontaneous contractions of the renal pelvis. MEN 10,376 a neurokinin A (4-10) analog, antagonized the positive inotropism produced by neurokinin A, without affecting the response to KCl, and suppressed the positive inotropic response produced by electrical field stimulation. In the presence of MEN 10,376, a negative inotropic response was produced by electrical field stimulation which was antagonized by the C-terminal fragment (8-37) of human alpha calcitonin gene-related peptide (hCGRP). hCGRP (8-37) antagonized the negative inotropic effect of exogenously administered CGRP without affecting inhibition by isoprenaline. Application of capsaicin (10 microM) produced a marked increase in the outflow of substance P-, neurokinin A- and CGRP-like immunoreactivities from the superfused guinea-pig renal pelvis. Substance P-, neurokinin A- and CGRP-like immunoreactivities were also detected in tissue extracts of the renal pelvis by radioimmunoassay. These experiments indicate that peptide release from peripheral endings of capsaicin-sensitive primary afferents represents the major type of nerve-mediated response affecting motility of the guinea-pig isolated renal pelvis. Tachykinins and CGRP act as physiological antagonists and the excitatory action of tachykinins prevails over the inhibitory action of CGRP. Local modulation of renal pelvis motility by sensory nerves could facilitate removal of irritants present in the urine, protecting the kidney during obstruction and ureteral antiperistalsis.     

Spinal substance P and N-methyl-D-aspartate receptors are coactivated in the induction of central sensitization of the nociceptive flexor reflex.

We have studied the effects and interactions of the neurokinin-1 receptor antagonist CP-96,345 and the N-methyl-D-aspartate receptor/channel blocker MK-801, both applied intravenously, on the flexor reflex and on the facilitation of the flexor reflex by conditioning stimulation of cutaneous C-afferents in decerebrate, spinalized, unanesthetized rats. The flexor reflex was evoked by subcutaneous electrical stimuli applied to the sural nerve innervation area 1/min at an intensity that activated C-fibers and was recorded as electromyogram from the ipsilateral hamstring muscles. The magnitude of the baseline flexor reflex was usually highly stable in the course of the experiments without experimental manipulations. The same stimulus was used as a conditioning train (0.9 Hz, 20 shocks) and caused a brief facilitation of the flexor reflex, which was maximal 0.5 and 1 min after stimulation (255.1 +/- 23.6% over baseline). During the course of the conditioning stimulus train, the reflex magnitude was gradually increased (wind-up). MK-801 (0.1 and 0.5 mg/kg) consistently depressed the polysynaptic flexor reflex. At a dose of 0.5 mg/kg, but not 0.1 mg/kg, MK-801 reduced the wind-up and blocked the facilitation of the flexor reflex induced by the conditioning stimulus by 90%. The facilitatory effect of 7 pmol intrathecal substance P was also partially reduced by MK-801. CP 96,345 (1 and 3 mg/kg) did not depress the flexor reflex, but dose-dependently antagonized reflex facilitation by the conditioning stimulus train, similarly to its antagonism of intrathecally applied 7 pmol substance P-induced facilitation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Tachykinins stimulate acid and pepsinogen secretion in the isolated porcine stomach.

The precise role of tachykinins in regulation of acid and pepsinogen secretion has not been established. Tachykininergic effects on acid and pepsinogen secretion could be mediated either directly in the proximal stomach or through other indirect mechanisms, i.e. gastrin secretion. We studied the effects of the two tachykinins, substance P and neurokinin A, and of capsaicin, on acid and pepsinogen output, in isolated porcine non-antral stomach preparation. The release of substance P and neurokinin A was studied during electrical stimulation of the vagal nerves, and during capsaicin infusion. Substance P infusion (10-8 M) increased acid secretion from 30 +/- 8 to 68 +/- 17 fmol min-1 (n=6, P < 0.05) and pepsinogen output from 46 +/- 12 to 160 +/- 47 units of pepsin min-1 (n=9, P < 0.05). Neurokinin A also stimulated both acid and pepsinogen secretion, while capsaicin had no effect on either parameter. Electrical stimulation of the vagal nerves increased the release of both peptides. We conclude that tachykinins may be involved in regulation of acid and pepsinogen secretion.     

Effects of intranigral substance P and neurokinin A on striatal dopamine release--II. Interactions with bicuculline and naloxone.

The functional roles of striatonigral neurokinins were studied by analysing the effects of intranigral injections of substance P and neurokinin A on the extracellular levels of dopamine and dihydroxyphenylacetic acid in the striatum, as measured by in vivo microdialysis in rats. An opioid antagonist, naloxone, and a GABAergic antagonist, bicuculline, were tested and analysed for their ability to modify the neurokinin effects. Unilateral injections of substance P (0.07 nmol) or neurokinin A (0.09 nmol) into the substantia nigra, pars reticulata of halothane anaesthetized rats produced long-lasting increases in ipsilateral striatal dopamine and dihydroxyphenylacetic acid levels. Intranigral injections of naloxone (30 and 300 nmol) produced short-lasting decreases in striatal dopamine, concomitant with an increase in dihydroxyphenylacetic acid. Intranigral injections of 7.0 nmol bicuculline produced an increase, while 70 nmol produced a decrease in striatal dopamine, however, both doses produced an increase in dihydroxyphenylacetic acid. When co-administered intranigrally, the high dose of naloxone (300 nmol) completely blocked the dopamine stimulation of substance P (0.07 nmol), but only moderately inhibited that of neurokinin A (0.09 nmol). The high dose of bicuculline (70 nmol) completely blocked the dopamine stimulation of neurokinin A, but only moderately inhibited that of substance P. Naloxone (30 and 300 nmol) enhanced the dihydroxyphenylacetic acid response to substance P, while bicuculline (70 nmol) inhibited the dihydroxyphenylacetic acid response to neurokinin A. These findings complement and extend the findings in the preceding paper, demonstrating that intranigral substance P and neurokinin A stimulate striatal dopamine via different neuronal mechanisms. We suggest that opioid drugs have a greater influence over substance P while GABAergic drugs have a greater influence over neurokinin A.     

Intrathecal galanin potentiates the spinal analgesic effect of morphine: electrophysiological and behavioural studies.

The interaction between intrathecally (i.t.) applied galanin (GAL) and morphine was examined in electrophysiological and behavioural experiments. The physiological experiments were performed on decerebrate, spinalized, unanesthetized rats where the effects of i.t. GAL and morphine on the hamstring flexor reflex were studied. In the behavioural experiments sensitivity to noxious thermal stimulation was assessed on the hot plate test in rats injected with GAL and morphine via chronically implanted i.t. catheters. GAL at 100 ng in 10 microliters, which by itself has no depressive effect, potentiated the depressive effect of morphine on the flexor reflex. In the behavioral study the same dose of GAL potentiated the antinociceptive effect of morphine on the hot plate test without having an analgesic effect by itself. It is suggested that GAL may enhance the analgesic effect of opiates in the spinal cord.     

Substance P and neurokinin A regulate by different mechanisms dopamine release from dendrites and nerve terminals of the nigrostriatal dopaminergic neurons

Numerous striatal neurons innervating the substantia nigra contain substance P and/or neurokinin A. In contrast to substance P or neurokinin A, little neurokinin B is found in the substantia nigra. This led us to compare the effects of nigral application of these tachykinins on the release of dopamine from dendrites and nerve terminals of nigrostriatal dopaminergic neurons. Experiments were made in halothane-anesthetized cats implanted with one push-pull cannula in the substantia nigra and another in the ipsilateral caudate nucleus [3H]Tyrosine was delivered continuously to each push-pull cannula and the release of newly synthesized [3H]dopamine measured in the superfusate. Unlike substance P or neurokinin A, neurokinin B (10(-8) M) applied for 30 min into the pars compacta of the substantia nigra was without effect on the release of [3H]dopamine from nerve terminals or dendrites. When either substance P (10(-8) M) or neurokinin A (10(-8) M) was applied into the pars compacta, the release of [3H]dopamine from nerve terminals was enhanced. While neurokinin A also stimulated the dendritic release of [3H]dopamine, this was reduced by substance P. At a lower concentration (10(-9) M), neurokinin A induced similar effects to those observed at 10(-8) M whereas substance P (10(-9) M) stimulated moderately [3H]dopamine release from nerve terminals but did not affect the dendritic release of the [3H]amine. When superfused into the pars reticulata, substance P (10(-8) M) still stimulated [3H]dopamine release from nerve terminals but not from dendrites while neurokinin A (10(-8) M) was without effect either in the caudate nucleus or the substantia nigra. Additional experiments were made to determine whether or not substance P (10(-8) M) or neurokinin A (10(-8) M) act directly on nigral dopaminergic neurons when applied into the pars compacta. The effects of substance P on [3H]dopamine release from nerve terminals and dendrites were prevented when 2-amino-6-trifluoromethoxy benzothiazole (10(-5) M), an antagonist of glutamatergic transmission, was applied continuously into the caudate nucleus. In contrast, the stimulatory effects of neurokinin A on [3H]dopamine release from nerve terminals and dendrites were insensitive to 2-amino-6-trifluoromethoxy benzothiazole (10(-5) M). These results suggest that neurokinin A, but not substance P, acts directly on dopaminergic cells. In the light of previous observations, we propose that the effects of substance P on dopaminergic transmission are mediated by a nigro-thalamo-cortico-striatal loop.(ABSTRACT TRUNCATED AT 400 WORDS)     

Involvement of substance P and calcitonin gene-related peptide in development and maintenance of neuropathic pain from spinal nerve injury model of rat

Recently, it has been suggested that uninjured primary sensory neurons contribute to neuropathic pain induced by peripheral nerve injury. However, there is lack of evidences of roles of normal pain transmitting substances such as substance P and calcitonin gene-related peptide (CGRP) in neuropathic pain. Whether substance P and CGRP have a role in spinal nerve-injured neuropathic pain model was tested. Male rats were subjected to L5 and L6 spinal nerve transection (SNT), and mechanical hyperalgesia was evaluated by measuring paw withdrawal threshold (PWT). SNT induced a persistent PWT decrease, a sign of neuropathic pain. Lidocaine was soaked on spinal nerves or intrathecally injected 10 min before SNT to block neuronal discharges caused by the injury, and L703,606 (NK1 receptor antagonist) and CGRP8-37 (CGRP receptor antagonist) were intrathecally injected into the rats to block actions of substance P and CGRP released from central nerve terminals in the spinal cord by injury discharges. The treatments with lidocaine, L703,606 and CGRP8-37 delayed the onset of neuropathic pain by 1-4 days, compared with the saline-treated rats. After neuropathic pain was established, intrathecal injections of L703,606 and CGRP8-37 significantly mitigated mechanical hyperalgesia for 20 min. These results suggest that substance P and CGRP are involved in the development and maintenance of neuropathic pain and that these peptides from the central terminals of intact sensory neurons contribute to the maintenance of peripheral nerve injury-induced neuropathic pain.     

Release of sensory neuropeptides in the spinal cord: studies with calcitonin gene-related peptide and galanin

In anaesthetized cats, antibody microprobes were used to investigate the release of immunoreactive calcitonin gene-related peptide and galanin in the lower lumbar spinal cord. In the absence of applied stimulation, a basal release of both peptides was detected at the level of the substantia gelatinosa. This release of calcitonin gene-related peptide was not altered by innocuous thermal cutaneous stimulation nor by electrical stimulation of low-threshold myelinated primary afferent fibres, but was increased by noxious thermal or noxious mechanical cutaneous stimuli and by electrical stimulation of unmyelinated primary afferents. A simultaneous release of both calcitonin gene-related peptide and substance P was detected in the substantia gelatinosa region by the use of pairs of microprobes. In contrast, none of the peripheral stimulation procedures increased intraspinal galanin release. The results suggest that the spinal transmission of nociceptive information may involve the simultaneous release and action of several neuropeptides within the superficial layers of the dorsal horn.     

Somatostatin and calcitonin gene-related peptide synergistically modulate spinal sensory and reflex mechanisms in the rat: behavioral and electrophysiological studies

Using behavioral and electrophysiological techniques evidence was obtained that somatostatin (SOM) and calcitonin gene-related peptide (CGRP) synergistically increase spinal cord excitability. In the behavioral experiments 1 microgram SOM or 1 microgram SOM + 20 ng CGRP injected intrathecally (i.t.) elicited a biting/scratching response lasting about 20 min. One microgram SOM combined with 200 ng, 2 micrograms or 20 micrograms CGRP caused an increase in the duration of this response. CGRP by itself (20 micrograms i.t.) had no effect. In the physiological experiments 10 ng SOM or 100 ng CGRP i.t. caused a brief facilitation of the hamstring flexion reflex (1-5 min) whereas 10 ng SOM + 100 ng CGRP synergistically facilitated the reflex for 40-75 min. The results are qualitatively similar to those obtained with substance P + CGRP and further strengthen the role of SOM in sensory transmission involving C-afferents.     

Tachykinin-like immunoreactivity in the mammalian urinary bladder: correlation with the functions of the capsaicin-sensitive sensory nerves

The tachykinin-like immunoreactivity of the urinary bladder has been measured in various species by means of an antiserum (K12) having negligible cross-reactivity with substance P. The rank order for bladder content of tachykinin-like immunoreactivity was guinea-pig greater than mice greater than rat, similar to that found for substance P-like immunoreactivity. In all three species, both substance P- and tachykinin-like immunoreactivities were depleted by systemic capsaicin desensitization. The time course for depletion of substance P- and tachykinin-like immunoreactivities of the rat bladder following extrinsic denervation was almost superimposable. At reverse phase high pressure liquid chromatography, the major constituent of tachykinin-like immunoreactivity of the rat bladder co-eluted with neurokinin A. In vitro, the contractile response of the rat bladder to capsaicin (1 microM) was directly proportional to bladder tachykinin-like immunoreactivity while the response to field stimulation was not. In vivo, the volume threshold for reflex micturition was inversely proportional to bladder tachykinin-like immunoreactivity while amplitude of micturition contraction was not. Similar correlations were found in a previous study for substance P-like immunoreactivity. The contractile response to capsaicin or neurokinin A of the rat isolated bladder were significantly reduced by incubation with phenoxybenzamine at a concentration reported to produce a selective alkylation of neurokinin-2 receptors, while the response to substance P or KCl was unaffected. These findings indicate that multiple neurokinins co-exist in those bladder sensory nerves which are capsaicin-sensitive in adult rats. Both substance P- and tachykinin-like immunoreactivities in the rat bladder appear to be good functional markers of the sensory and "efferent" functions mediated by capsaicin-sensitive nerves, consistent with the hypothesis of a transmitter role for the corresponding peptides.     

Intrathecal substance P-induced thermal hyperalgesia and spinal release of prostaglandin E2 and amino acids

Substance P is an important neuromediator in spinal synaptic transmission, particularly in processing nociceptive afferent information. The effects of substance P are mediated by activation of the neurokinin 1 receptor. Evidence has suggested that excitatory amino acids such as glutamate, and prostaglandins including prostaglandin E2 are involved in the enhanced spinal excitability and hyperalgesia produced by spinal substance P. In the present study, we have demonstrated that intrathecal injection of substance P (20 nmol) in rats chronically implanted with intrathecal dialysis catheters induced a decrease in thermal paw withdrawal latency (before: 10.4+/-0.3 s; after 7.6+/-0.6 s), which was accompanied by an increase in prostaglandin E2 (362+/-37% of baseline), glutamate (267+/-84%) and taurine (279+/-57%), but not glycine, glutamine, serine or asparagine. Intrathecal injection of artificial cerebrospinal fluid had no effect upon the behavior or release. Substance P-induced thermal hyperalgesia and prostaglandin E2 release were significantly attenuated by a selective neurokinin 1 receptor antagonist RP67580, but not by an enantiomer RP68651. However, substance P-induced release of glutamate and taurine was not reduced by treatment with RP67580. SR140333, another neurokinin 1 receptor antagonist, displayed the same effects as RP67580 (i.e. block of thermal hyperalgesia and prostaglandin E2 release, but not release of amino acids). These results provide direct evidence suggesting that the spinal substance P-induced thermal hyperalgesia is mediated by an increase in spinal prostaglandin E2 via activation of the neurokinin 1 receptor. These findings define an important linkage between small afferents, sensory neurotransmitter release and spinal prostanoids in the cascade of spinally-mediated hyperalgesia. The evoked release of glutamate is apparently not a result of activation of neurokinin 1 receptors. Accordingly, consistent with other pharmacological data, acute spinal glutamate release does not contribute to the hyperalgesia induced by activation of spinal neurokinin 1 receptors.     

Resiniferatoxin-, capsaicin- and CGRP-evoked porcine coronary vasodilatation is independent of EDRF mechanisms but antagonized by CGRP(8-37).

In the present study the effects of activation of capsaicin-sensitive C-fibre afferents by resiniferatoxin and capsaicin as well as the effects of the co-stored peptides calcitonin gene-related peptide substance P and neurokinin A on porcine coronary vascular tone in vitro was investigated. Resiniferatoxin, capsaicin, calcitonin gene-related peptide and neurokinin A all evoked a sustained, concentration-dependent vasodilatation of potassium (60 mM)-precontracted arteries. Substance P also caused vasodilatation of the precontracted arteries but this effect was transient and tachyphylaxis developed rapidly upon repeated administration. Incubation with the calcitonin gene-related peptide fragment (8-37) did not influence the vascular tone per se but markedly attenuated the dilatory effect of calcitonin gene-related peptide and totally abolished the vasodilatation induced by resiniferatoxin and capsaicin while leaving the effect of neurokinin A and substance P unaltered. Incubation with methylene blue, an inhibitor of endothelium-derived relaxing factor mechanisms, which completely blocked the substance P-evoked vasodilatation, as well as substance P-tachyphylaxis, did not influence the vasodilator response to resiniferatoxin, capsaicin or calcitonin gene-related peptide. The neurokinin A-evoked vasodilatation was most likely mediated through activation of neurokinin 1-receptors since it remained unchanged in the presence of the neurokinin 2-receptor antagonist dactinomycin and (Nle10)-neurokinin A (4-10), which selectively activates neurokinin 2-receptors, had only a minor dilatory effect on the precontracted arteries.(ABSTRACT TRUNCATED AT 250 WORDS)     

Neural substrates for reflex salivation induced by taste, mechanical, and thermal stimulation of the oral region in decerebrate rats

In order to investigate the neural mechanisms of reflex salivary secretion, experiments were carried out on anesthetized, decerebrate rats from which the volumes of submandibular salivary secretion and the efferent discharges in the preganglionic parasymapathetic fibers innervating the submandibular gland were recorded. Salivary secretion was induced by either infusing a taste solution, or an aliquot of hot water (45-55 degrees C) into the oral cavity, or by pinching the frontal parts of the oral region with a pair of forceps. The reflex salivation induced by noxious thermal and mechanical stimuli was markedly reduced by lesioning either the caudal (VC), or the interpolar (VI) trigeminal sensory nuclei. Taste-elicited salivary secretion was significantly reduced by lesioning the nucleus of the tractus solitarius (NTS). Of 43 preganglionic parasympathetic fibers sampled, 27 responded to both noxious mechanical and thermal stimulation of the oral region, and to electrical stimulation of the VC. Ten fibers responded only to taste stimulation and to electrical stimulation of the NTS. The remaining 6 fibers responded to both taste and noxious thermal stimulation of the oral region. These fibers responded well to NTS stimulation, but gave only a slight response to VC stimulation. These results suggest that two distinct neural pathways exist which mediate reflex salivation in the lower brain stem of the rat, i.e., the taste pathway via the NTS and the nociceptive pathway via the trigeminal sensory nuclei.     

Multiple tachykinin pools in sensory nerve fibres in the rabbit iris

A population of sensory nerve fibres in the rabbit iris is known to contain calcitonin gene-related peptide and tachykinins, such as substance P and neurokinin A. In the presence of atropine and guanethidine, the isolated iris sphincter responded to electrical stimulation with a contraction that could be abolished by tachykinin antagonists. Capsaicin, known to release tachykinins from sensory fibres, evoked a long-lasting tachykinin-mediated contraction of the iris sphincter. Repeated application of capsaicin led to tachyphylaxis, possibly reflecting depletion of releasable neuronal stores of tachykinins. At this stage, electrical stimulation failed to elicit contraction. The capacity of capsaicin to release neuropeptides from sensory fibres was confirmed by determination of substance P- and calcitonin gene-related peptide-like immunoreactivity in the incubation medium and in the iris tissue. The concentrations of substance P and calcitonin gene-related peptide in the iris after capsaicin exposure were reduced by about 25%. Like capsaicin, bradykinin evoked a tachykinin-mediated contraction and tachyphylaxis. However, after development of tachyphylaxis to bradykinin, electrical stimulation or exposure to capsaicin still evoked tachykinin-mediated contraction, albeit a reduced one compared with the response before bradykinin. Hence, capsaicin completely depletes tachykinin stores releasable by prolonged electrical stimulation, whereas bradykinin exhausts only a sequestered pool. The possibility that tachykinins occur in several releasable pools in sensory nerves was investigated in yet another way: the iris sphincter muscle was stimulated electrically once every 2.5 min over several hours. The contractile response diminished gradually.(ABSTRACT TRUNCATED AT 250 WORDS)