Tachykinins enhance the depression of spinal nociceptive neurons caused by cutaneously applied vibration in the cat

The present investigation was prompted by previous studies in our laboratory which have indicated that tachykinins enhance depressant effects of purines and that the purine adenosine mediates a vibration-induced depression of nociceptive dorsal horn neurons. Extracellular recordings were made from single nociceptive neurons in the lower lumbar segments of anaesthetized cats. Vibration (80 Hz; 2.5-3.5 s every 20-25 s) was applied to the hindlimb using a feedback-controlled mechanical stimulator. The tachykinins physalaemin, substance P and neurokinin A were administered by iontophoresis. Physalaemin was tested on vibration-induced responses of 29 neurons; each neuron was excited by this tachykinin. To control for possible changes in the response to vibration caused by the excitation per se, statistical comparisons were made of the vibration-induced responses during excitation by tachykinins and during excitation by glutamate. In 16 cases the magnitude of the vibration-induced depression was significantly greater during the excitation caused by physalaemin. With the remaining neurons the response to vibration failed to differ during the excitation by physalaemin compared with the excitation by glutamate. In four of the 16 cases subthreshold applications of vibration caused depression after administration of physalaemin. The P1-purinergic (adenosine) antagonist, caffeine, was administered in three cases where vibration caused depression only with application of physalaemin. In each of these cases the depression was reversibly blocked by caffeine (10 or 40 mg kg-1 i.v.). The magnitude of vibration-induced depression was significantly increased during excitation by neurokinin A (5/14 neurons) or by substance P (1/9 neurons). From the results of the present study we suggest that tachykinins enhance the vibration-induced depression. This enhancement may be due to enhanced depression by adenosine.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of adenosine 5'-monophosphate and adenosine 5'-triphosphate on functionally identified units in the cat spinal dorsal horn. Evidence for a differential effect of adenosine 5'-triphosphate on nociceptive vs non-nociceptive units

A study was done of the effects of iontophoretic application of adenosine 5'-monophosphate (AMP) and adenosine 5'-triphosphate (ATP) on functionally identified neurones in the spinal dorsal horn of the cat. AMP depressed nearly two-thirds of the 32 neurones tested regardless of functional type; the remainder were unaffected. ATP, on the other hand, had three types of effect: depression, excitation and a biphasic effect which consisted of excitation followed by depression. A significant difference was found when a comparison was made of the frequency of occurrence of each of these three types of effect in the samples of non-nociceptive (n = 18) and of wide dynamic range neurones (n = 42): of non-nociceptive neurones 61% were excited, 11% were depressed, 6% had a biphasic response and 22% were unaffected; of wide dynamic range neurones 45% had a biphasic response, 19% were depressed, 14% were excited and 21% were unaffected (chi 2 = 16.2, P less than 0.005). The depressant effects of both AMP and ATP and the depressant phase of the biphasic effect of ATP seem to be mediated through activation of P1-purinergic receptors because these effects were blocked by theophylline, a P1-purinergic antagonist [Burnstock (1978) In Cell Membrane Receptors for Drugs and Hormones: A Multidisciplinary Approach, pp. 107-118]. Thus the biphasic effect appears to consist of excitatory and depressant responses in the same neurone. The differential effects of ATP on non-nociceptive vs wide dynamic-range neurones are similar to the differential effects on these neurones observed during activation of low-threshold primary afferents. This similarity, together with evidence that ATP can be released from primary afferent neurones [Holton and Holton (1954) J. Physiol., Lond. 126, 124-140; Holton (1959) J. Physiol., Lond. 145, 494-504], prompts us to suggest that ATP may be a chemical mediator of effects of low-threshold primary afferent inputs in the spinal dorsal horn.     

Phenotype and function of somatic primary afferent nociceptive neurones with C-, Adelta- or Aalpha/beta-fibres

Nociceptive dorsal root ganglion (DRG) neurones have fibres that conduct in the C, Adelta and Aalpha/beta conduction velocity range. The properties of nociceptive compared with non-nociceptive somatic afferent dorsal root ganglion neurones appear to fall into two patterns, A and B. Pattern A properties of nociceptive neurones, the more common type, include longer action potential duration and slower maximum rate of fibre firing, as well as a greater expression of substance P and calcitonin gene-related peptide immunoreactivity. The values of pattern A properties appear to be graded according to the conduction velocity group (C, Adelta or Aalpha/beta) of the fibres. The most pronounced forms of A-type properties are expressed by nociceptive neurones with C-fibres, and these become less pronounced in nociceptive neurones with Adelta-fibres and least pronounced in those with Aalpha/beta fibres (C > Adelta > Aalpha/beta). Some of these properties are also expressed in a less extreme but similarly graded manner through C, Adelta and Aalpha/beta groups of non-nociceptive low threshold mechanoreceptive (LTM) neurone. The less common pattern B properties of nociceptive neurones have similar values in C-, Adelta- and Aalpha/beta-fibre nociceptive neurones but these clearly differ from LTM units with C-, Adelta- and Aalpha/beta-fibre conduction velocities. These features of nociceptive neurones include consistently larger action potential overshoots and longer after-hyperpolarisation durations in nociceptive than in LTM neurones.     

Vasopressin release induced by intracranial injection of tachykinins is due to activation of central neurokinin-3 receptors

The present study investigated the effect on vasopressin release of the intracerebroventricular injection of tachykinins in rats. The selective neurokinin (NK)-3 receptor agonists [MePhe7]neurokinin B and [Asp5,6MePhe8]substance P(5-11) evoked vasopressin release. Also eledoisin, physalaemin and kassinin, which show good affinity for central NK-3 receptors, released vasopressin. On the other hand, neurokinin A, substance P and the selective NK-1 agonist [Pro9,Met(O2)11]substance P were devoid of activity. At doses releasing vasopressin, central injection of NK-3 selective agonists and of the natural tachykinins never produced hypotension. Present results indicate that activation of central NK-3 receptors is involved in vasopressin release induced by tachykinins, and rule out the possibility that the effect might be consequent to hypotension due to passage of tachykinins into the peripheral circulation.     

The excitatory action of the newly-discovered mammalian tachykinins, neurokinin alpha and neurokinin beta, on neurons of the isolated spinal cord of the newborn rat

The actions of two new mammalian tachykinins, neurokinin alpha and neurokinin beta, were examined using the isolated spinal cords of newborn rats. Depolarizing responses of spinal motoneurons were recorded extracellularly from the lumbar ventral root during application of neurokinin alpha or neurokinin beta at concentrations ranging from 3 X 10(-8) M to 10(-6) M. The potencies of various tachykinins in depolarizing the motoneurons showed the following order: physalaemin greater than neurokinin beta divided by kassinin divided by substance P greater than neurokinin alpha. When the synaptic transmission in the spinal cord was blocked by tetrodotoxin, the depolarizing action of neurokinin alpha and neurokinin beta was markedly reduced but not completely abolished. The depolarizing action of neurokinin alpha and neurokinin beta was depressed by a substance P antagonist, [D-Arg1, D-Pro2, D-Trp7,9, Leu11]SP. The possibility that neurokinin alpha and neurokinin beta act as neurotransmitters in the mammalian spinal cord is discussed.     

Anatomy of primary afferents and projection neurones in the rat spinal dorsal horn with particular emphasis on substance P and the neurokinin 1 receptor

The dorsal horn of the spinal cord plays an important role in transmitting information from nociceptive primary afferent neurones to the brain; however, our knowledge of its neuronal and synaptic organisation is still limited. Nociceptive afferents terminate mainly in laminae I and II and some of these contain substance P. Many projection neurones are located in lamina I and these send axons to various parts of the brain, including the caudal ventrolateral medulla (CVLM), parabrachial area, periaqueductal grey matter and thalamus. The neurokinin 1 (NK1) receptor on which substance P acts is expressed by certain neurones in the dorsal horn, including approximately 80 % of lamina I projection neurones. There is also a population of large NK1 receptor-immunoreactive neurones with cell bodies in laminae III and IV which project to the CVLM and parabrachial area. It has been shown that the lamina III/IV NK1 receptor-immunoreactive projection neurones are densely and selectively innervated by substance P-containing primary afferent neurones, and there is evidence that these afferents also target lamina I projection neurones with the receptor. Both types of neurone are innervated by descending serotoninergic axons from the medullary raphe nuclei. The lamina III/IV neurones also receive numerous synapses from axons of local inhibitory interneurones which contain GABA and neuropeptide Y, and again this input shows some specificity since post-synaptic dorsal column neurones which also have cell bodies in laminae III and IV receive few contacts from neuropeptide Y-containing axons. These observations indicate that there are specific patterns of synaptic connectivity within the spinal dorsal horn.     

Substance P (NK1) and somatostatin (sst2A) receptor immunoreactivity in NTS-projecting rat dorsal horn neurones activated by nociceptive afferent input

Spinal neurones that receive inputs from primary afferent fibres and have axons projecting supraspinally to the medulla oblongata may represent a pathway through which nociceptive and non-nociceptive peripheral stimuli are able to modulate cardiorespiratory reflexes. Expression of the neurokinin-1 (NK1) receptor is believed to be an indicator of lamina I cells that receive nociceptive inputs from substance P releasing afferents, and similarly, sst2_A receptor expression may be a marker for neurones receiving somatostatinergic inputs. In this study, immunoreactivity for these two receptors was investigated in rat spinal neurones retrogradely labelled by injections of cholera toxin B or Fluorogold into the nucleus of the solitary tract (NTS). In addition, nociceptive activation of these labelled cells was studied by immunodetection of Fos protein in response to cutaneous and visceral noxious chemical stimuli. NK1 and sst2_A receptors in lamina I were localised to mainly separate populations of retrogradely labelled cells with fusiform, flattened and pyramidal morphologies. Examples of projection neurones expressing both receptors were, however observed. With visceral stimulation, many retrogradely labelled cells expressing c-fos were immunoreactive for the NK1 receptor, and a smaller population was sst2_A positive. In contrast, with cutaneous stimulation, only NK1 positive retrogradely labelled cells showed c-fos expression. These data provide evidence that lamina I neurones receiving noxious cutaneous and visceral stimuli via NK1 receptor activation project to NTS and so may be involved in coordinating nociceptive and cardiorespiratory responses. Moreover, a subpopulation of projection neurones that respond to visceral stimuli may receive somatostatinergic inputs of peripheral, local or supraspinal origins.     

The effects of microiontophoretically applied capsaicin and substance P on single neurones in the rat and cat brain

Microiontophoretically applied capsaicin (10–480 nA) excited neurones in trigeminal nucleus caudalis (ntV) or potentiated their amino acid-induced excitation (20 of 23 neurones); inhibited one neurone; and had no effect on 2 neurones. Substance P (SP) excited 8 of 9 ntV neurones, and of these 8 neurones 6 were excited, one was depressed, and one was unaffected by capsaicin. Of 13 cerebellar neurones, 5 were depressed by capsaicin and 8 were unaffected. SP excited 3 of 5 cerebellar neurones. It is concluded that the excitatory action of capsaicin in ntV may be due to release of SP from neuronal structures and that the lack of excitatory effects seen in the cerebellum may reflect the absence of SP-containing neurones in this structure [2].     

Distribution of neurokinin B in rat spinal cord and peripheral tissues: comparison with neurokinin A and substance P and effects of neonatal capsaicin treatment.

In the present study, highly specific radioimmunoassays were developed and used to measure neurokinin B, neurokinin A and substance P in the rat spinal cord and various peripheral tissues. The results are as follows. (1) Neurokinin B and neurokinin A were distributed all along the rostrocaudal axis of the spinal cord, as is substance P, and were more concentrated in the dorsal than in the ventral region. (2) Substance P was more abundant in the central and peripheral nervous tissues than neurokinin A, while in certain peripheral organs, neurokinin A was more abundant than substance P. In the spinal cord, neurokinin B concentrations were lower than those of the other two tachykinins. (3) In contrast to neurokinin A and substance P, neurokinin B was not detected in any of the peripheral tissues examined. (4) Capsaicin treatment reduced by half neurokinin A and substance P concentrations in the dorsal region of the spinal cord, the dorsal root ganglia and the sciatic nerve, but was without effect on neurokinin B concentrations in the spinal cord. Neurokinin A, like substance P, may therefore have an important function in the transmission of sensory information, particularly in nociceptive transmission from the periphery to the spinal cord and in peripheral neurogenic inflammation. In contrast, since neurokinin B was not found in the sensory neurons, it is not likely to have these functions, but may perhaps control them.     

The tachykinins neurokinin A and physalaemin stimulate murine thymocyte proliferation

The tachykinins constitute a family of neuropeptides that are released from sensory neurons, mediating a variety of responses termed neurogenic inflammation. The present study investigates the possibility that tachykinins are also involved in immune-regulatory mechanisms. The mammalian tachykinins neurokinin A (NKA), neurokinin B, neuropeptide K and substance P, as well as the nonmammalian tachykinin physalaemin (PHY) and eledoisin, were analysed in 10-pM to 1.0 microM concentrations for regulatory influences in several lymphocyte proliferation assays. NKA, and to a lesser extent PHY, but none of the other tachykinins tested, displayed a stimulatory action in murine thymocyte cultures, utilised as an interleukin-1 (IL-1) bioassay. The effect was apparent only at a concentration of 0.1 microM or higher. No further stimulatory effect of the tachykinins could be observed in thymocyte cultures already suboptimally stimulated to proliferation by addition of IL-1. The tachykinins had no effect in direct and co-mitogenic T and B lymphocyte proliferation assays with rat spleen cells, in a thymocyte growth peptide assay with mouse thymic lymphoblasts or in an interleukin-2 (IL-2) bioassay with IL-2-dependent rat splenoblasts. Our findings indicate that NKA and PHY can act as immune regulators. The results are relevant for the understanding of the interaction between the nervous and the immune system, and are of particular interest in view of the inflammatory actions of both tachykinins and IL-1.     

Fibroblast growth factor-2 acutely influences the impulse activity of rat dorsal horn neurones

The neurotrophic and neuroprotective actions of fibroblast growth factor-2 (FGF-2) are well-established. The signal cascade mediating these effects includes steps that are likely to influence also the electrical properties of neurones. However, the possibility that FGF-2 may acutely affect the processing of neuronal impulse activity is largely unexplored. In the present study the impulse activity of single dorsal horn neurones was recorded in the rat during ionophoretical administration of FGF-2 close to the neurones. Before and during FGF-2 ionophoresis the receptive field of each cell was tested with defined mechanical stimuli. At a concentration of 10 nM in the ionophoresis pipette, FGF-2 reduced the responses of the cells to mechanical stimulation. There was no preferential action of FGF-2 on a particular functional type of dorsal horn neurone; both non-nociceptive and nociceptive cells exhibited a reduced mechanical responsiveness. The background (ongoing) activity was also depressed in most neurones. The results of the study show that in addition to neurotrophic and neuroprotective actions FGF-2 has an acute inhibitory influence on the impulse activity of spinal sensory neurones. This depression of neuronal activity could add to the neuroprotective action of FGF-2 by counteracting glutamate excitotoxicity following a central nervous trauma.     

Actions of neuropeptide K and calcitonin gene-related peptide on inferior mesenteric ganglion cells--tachykinin interactions with non-cholinergic potentials evoked by ureteric nerve stimulation

Neuropeptide K (NPK) induced a slow depolarization in principal ganglion cells of the guinea pig inferior mesenteric ganglion (IMG) in vitro. This effect was due to a postsynaptic action and prevented by pre-exposure of the IMG to neurokinin A (NKA) or substance P (SP). The non-cholinergic slow postsynaptic excitatory potential (s-EPSP) evoked by ureteric nerve stimulation was depressed during NPK, SP or NKA application. Calcitonin gene-related peptide (CGRP) applied in concentrations up to 10 microM had no effect on the membrane potential in 90% of IMG cells nor did it influence the s-EPSP. We suggest that NPK may depolarize IMG neurones via similar mechanisms/in a similar fashion, to other tachykinins and that the s-EPSP, induced by stimulation of the afferent ureteric nerve fibres, is mediated by a tachykinin whereas there is little indication/evidence for an involvement of CGRP.     

Thalamic NMDA receptors and nociceptive sensory synaptic transmission

The responses of single thalamic neurones to noxious thermal stimulation were recorded in anaesthetized rats. The selective (NMDA) receptor antagonist, 3-((±)-2-carboxypiperazin-4-yl)propyl-1-phosphonate (CPP), antagonised nociceptive responses when ejected iontophoretically with currents which produced selective antagonism at NMDA receptors. In contrast, the non-NMDA excitatory amino acid receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) had little or no effect on nociceptive responses, although it was able to reduce responses to non-nociceptive mechanoreceptor input. These results show that there is substantial NMDA receptor involvement in thalamic nociceptive responses, and that the contribution of CNQX-sensitive non-NMDA receptors to these responses is not extensive. Furthermore, it appears that nociceptive and non-nociceptive input to the thalamus have distinct synaptic pharmacologies.     

Effects of glutamate, substance P and eledoisin-related peptide on solitary tract neurones involved in respiration and respiratory reflexes

Recent studies have implicated glutamate and substance P in synaptic transmission in the nuclei tractus solitarii and in central regulation of cardiorespiratory functions. Consequently, in chloralose-anaesthetized cats that were artificially ventilated, we examined the effects of the microiontophoretic application of both chemicals (and the substance P homologue, eledoisin-related peptide) on single neurones of the nuclei tractus solitarii implicated in the control of respiration and respiratory tract reflexes. These neurones were functionally identified as either respiratory neurones or presumed reflex interneurones, and showed functional properties comparable to those previously documented for each of these two types. The iontophoretic application of glutamate produced an excitation of rapid onset in 23 or 25 reflex interneurones tested, but the respiratory neurones showed a differential sensitivity: one type (n = 32) was "glutamate-sensitive" and showed rapid excitation with glutamate applications of less than 30 nA, the other type of respiratory neurone (n = 26) was termed "glutamate-insensitive" since it either showed excitation only with applications of 60 nA or more or showed no response even with currents up to 94 nA. Each neurone studied was clearly of one type or the other. Glutamate could increase the number of spikes per rhythmic burst and the burst duration of respiratory neurones, it facilitated evoked activity in the reflex interneurones and in those respiratory neurones having a superior laryngeal nerve or vagus nerve afferent input, and the magnitude of the excitatory responses to glutamate varied directly with the amount of ejecting current. Substance P and eledoisin-related peptide also had excitatory effects on respiratory neurones and reflex interneurones, but compared with glutamate-induced effects the excitation was slower in onset and more prolonged in after-discharge. Both rhythmic and evoked activity could be facilitated, and the magnitude of the effect varied directly with the magnitude of the ejecting current. In showing that both glutamate and substance P (and its analogue, eledoisin-related peptide) have excitatory effects on the activity of respiratory neurones and reflex interneurones, this study provides evidence suggesting that these neurones have receptors for these neural chemicals, supportive of a role for each chemical in the regulation of respiration and respiratory tract reflexes.     

Two major tachykinins, substance P and substance K, are localized to distinct subsets of amacrine cells in the anuran retina

Tachykinins are known to be major excitatory neuromodulators in neural systems, including the retina of many vertebrate species. Among them substance P has been detected in several species, including anurans. However, none of the other major tachykinins has been sought for in the anuran retina. The aim of this study was to identify another major tachykinin, substance K (neurokinin A) in the frog retina and compare its distribution to that of substance P. Since one of the synthetic pathways of the above mentioned tachykinins make it possible to produce both peptides from one large precursor RNA, we also investigated possible colocalization with double-label immunocytochemistry. Our results show that both substance P and substance K are localized to wide-field amacrine cells in the retina of a terrestrial frog (Pelobates fuscus). Preabsorption and double-label studies provided evidence that the populations of substance P- and substance K-immunoreactive cells are clearly distinct and their dendritic arbor do not overlap in the inner plexiform layer of the retina. These findings provide evidence for the presence of (i) a novel anatomically/neurochemically identifiable amacrine cell type and (ii) predict distinct synthetic pathways for substance P and substance K in the anuran retina.     

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.     

Substance P acts by releasing 5-hydroxytryptamine from enteric neurons in the stomach of the rainbow trout, Salmo gairdneri

The effect and mode of action of substance P was studied in a perfused stomach preparation and on isolated strip preparations of the stomach wall from the rainbow trout, Salmo gairdneri. Substance P was excitatory on the stomach muscle wall in a dose-dependent manner. Two other tachykinins, physalaemin and eledoisin, excited the preparations in a similar manner and in the same dose range. The effect of substance P was not antagonized by the substance P analogues [D-Pro2, D-Phe7, D-Trp9]substance P and [D-Pro2, D-Trp7,9]substance P (both 10(-5) M). Tetrodotoxin reduced or abolished the effect of substance P, while no reduction of the response was obtained after atropine, chlorisondamine or phentolamine (all 10(-6) M). 5-Hydroxytryptamine excited the stomach and this effect was not antagonized by tetrodotoxin, suggesting that the action of 5-hydroxytryptamine was direct on the smooth muscle. The 5-hydroxytryptamine antagonist methysergide, in a concentration which selectively blocked the response to 5-hydroxytryptamine, also blocked the response to substance P (10(-9)-10(-8) M). The outflow of 5-[3H]hydroxytryptamine from a preloaded perfused stomach was clearly increased by substance P, and this release was blocked by tetrodotoxin. Immunohistochemistry revealed the presence of nerve fibres and ganglion cells showing 5-hydroxytryptamine-like immunoreactivity in the myenteric plexus and smooth muscle layers of the stomach wall. The immunoreactive cells and nerve fibres were particularly abundant in the pyloric part of the stomach. It is concluded that the main effect of substance P on the stomach wall of the rainbow trout is indirect, via activation of a non-adrenergic, non-cholinergic neuron. The results are compatible with the view that this neuron exerts its action by release of 5-hydroxytryptamine. Supramaximal concentrations (greater than or equal to 10(-7) M) of substance P may in addition have a direct effect on the gastric smooth muscle.     

Activation of neurokinin NK(2) receptors by tachykinin peptides causes contraction of uterus in pregnant women near term

The aim of this study was firstly to elucidate whether the mammalian tachykinins substance P (SP), neurokinin A (NKA) and neurokinin B (NKB)-regulated contractility of myometrium obtained from near-term pregnant women, and secondly to investigate the receptor subtype(s) responsible. In the presence of peptidase inhibitors, i.e. thiorphan (3 micromol/l; endopeptidase 24.11 inhibitor), captopril (10 micromol/l; angiotensin converting enzyme inhibitor) and bestatin (10 micromol/l; aminopeptidase inhibitor); all three mammalian tachykinins elicited concentration-related contractions of isolated myometrial preparations. The rank order of agonist potency of the mammalian tachykinins in the presence of the peptidase inhibitors was NKA > SP = NKB, indicating that the contractile effects were mediated by activation of an NK(2) receptor. The NK(2) receptor-selective agonist, [Lys(5), MeLeu(9), Nle(10)]NKA(4-10), produced concentration-related contractile responses, while the respective NK(1) and NK(3) receptor-selective agonists, [Sar(9), Met(O(2))(11)]SP and [N-MePhe(7)]NKB, had no effect either in the absence or presence of the peptidase inhibitors. The NK(2) receptor-selective antagonist, SR48968, produced concentration-related rightward shift in the log concentration curve to [Lys(5), MeLeu(9), Nle(10)]NKA(4-10). This study shows that tachykinins elicit contractile effects on human myometrium obtained from pregnant women near term, and that these effects are mediated by an NK(2) receptor. An excitatory effect of the tachykinins on these preparations could indicate a physiological role for these peptides in enhancing contractility of the uterus in women at term.     

Receptive field organisation and electrophysiological responses of spinal cord thermoreactive neurones in the rat

Summary Receptive fields and electrophysiological responses of seventy-three thermoreactive neurones were studied. The receptive fields were 1 to 10 mm wide and 1 to 15 mm long, for the warm thermoreactive neurones and 5 to 15 mm wide and 2 to 31 mm long for cold thermoreactive neurones. The receptive fields of 5 units excited by warming and heating were 5 to 11 mm wide and 3 to 16 mm long. Six units excited by warming and light mechanical stimulation had receptive fields about 1 to 7 mm wide and 1 to 10 mm long. Those of 3 units excited by cooling and light mechanical stimulation were 3 to 10 mm wide and 3 to 15 mm long. Seven bimodal units had receptive fields that were 2 to 30 mm wide and long. The receptive fields were on the ipsilateral scrotal and or inguinal and perineal skin. Only 1 unit had a bilateral receptive field. Seven dorsal horn neurones showed convergence of warm sensitive and nociceptive afferents. Also, 2 units had convergent inputs from cold sensitive and nociceptive afferents. The noxious mechanical excitatory receptive fields were separate and located on the ipsilateral and contralateral toes, the penis or ipsilateral testicle. The thermal excitatory receptive fields of these units were 15 to 17 mm wide and 20 to 21 mm long. The warm and cold-reactive neurones discharged more with the rise and fall in skin temperature, respectively. Five warm-reactive neurones showed bursting activity. The locations of the thermoreactive neurones studied were similar to those reported earlier. It is concluded that dorsal horn thermoreactive neurones, have mainly ipsilateral receptive fields. Secondly, convergence of temperature sensitive and nociceptive afferents occur in the dorsal horn of the rat.     

Purine-induced depression of dorsal horn neurons in the cat spinal cord: enhancement by tachykinins

The neurokinins, physalaemin, substance P, neurokinin A and bradykinin, were tested on the responses of single spinal neurons to the purines, adenosine 5'-triphosphate (ATP) and adenosine 5'-monophosphate and to GABA. Experiments were done on anaesthetized cats, recording extracellularly from functionally identified sensory neurons in the lumbar dorsal horn. All compounds were administered by iontophoresis. Neurokinins caused a slow, prolonged excitation which outlasted the period of application. Physalaemin was tested on responses to ATP in 24 units. In each case application of ATP caused either depression, excitation or a biphasic response when the application was not pre-conditioned by ejection of physalaemin. For 11 units, with ATP applications subthreshold to alter the on-going firing rate, such applications caused depression when they were preceded by administration of physalaemin. Three units were tested with ATP applications which caused the excitatory response; when the applications of ATP were preceded by ejection of physalaemin, there was then a depressant component in the response. In these 14 cases, the magnitude of the depression or of the depressant component of the response, was measured using currents which failed to produce depression in the absence of physalaemin ejection; the mean magnitude of this depression was 34.7 +/- 1.6% (+/- S.E.M.). With the 10 remaining units, responses to ATP were unaffected by application of physalaemin. The early components of the biphasic and excitatory responses were unaffected by physalaemin and hence it appeared to have a differential effect, enhancing only the depressant effects of ATP. The enhancement of depression was reversible, lasting up to 30 min following a single ejection. Neither control current nor glutamate mimicked the effect of physalaemin in the responses to application of ATP. The depressant response to adenosine 5'-monophosphate was also enhanced by physalaemin: ejections of adenosine 5'-monophosphate subthreshold to affect the on-going firing rate caused depression after physalaemin application in 3 of 8 units (average depression: 35.0 +/- 3.3%). On the other hand, depression induced by GABA was unaffected by physalaemin in every case (n = 8); in 4 of these cases GABA was tested on units for which purine-induced depression was enhanced by physalaemin. Thus, physalaemin preferentially affected depressant responses to ATP and to adenosine 5'-monophosphate.(ABSTRACT TRUNCATED AT 400 WORDS)