Beta-receptor involvement in locus coeruleus-induced inhibition of spinal trigeminal nucleus neurons: Microiontophoretic and HRP studies

Microiontophoretic and HRP studies were performed on cats anesthetized with alpha-chloralose to determine whether or not the locus coeruleus (LC)- and noradrenaline (NA)-induced inhibition of relay neurons in the subnucleus oralis of the spinal trigeminal nucleus (STN) is mediated by beta-adrenergic receptors. The inhibition of orthodromic spike generation upon intracranial trigeminal nerve stimulation by LC conditioning stimulation and microiontophoretically applied NA (100-200 nA) was antagonized during microiontophoretic application of sotalol, a beta-adrenergic antagonist, but not affected by phentolamine, an alpha-adrenergic antagonist. When HRP at doses of 300-500 nA was applied for 5-15 min to the immediate vicinity of the STN relay or interneuron, which was electrophysiologically identified by stimulating the ipsilateral trigeminal nerve and contralateral medial lemniscus, the injection site was localized to an area 0.3 mm in diameter and HRP-reactive cells were found in the ipsilateral LC, dorsal raphe nucleus and periaqueductal gray ventral to the aqueduct. These results strongly suggest that NA released from the nerve terminals of LC cells inhibits transmission in the STN relay neuron via beta-adrenergic receptors.     

Noradrenaline-mediated inhibition by locus coeruleus of spinal trigeminal neurons

Inhibitory effects of conditioning stimulation of the locus coeruleus (LC) on the neuron activity in spinal trigeminal nucleus (STN) were investigated in gallamine-immobilized cats. Field potentials of STN and spike potentials of single relay neurons in STN were orthodromically elicited by ipsilateral alveolar nerve stimulation and antidromically by stimulation of contralateral medial lemniscus. Conditioning stimuli were applied to LC and sensory cortex (SC) at various C-T intervals.

In tracking experiments near the LC region, conditioning stimulation of LC itself produced the most pronounced decrease in amplitude of the STN field potentials. Orthodromic spikes of STN single neurons were significantly reduced by conditioning stimulation of LC as well as SC. In reserpine-treated animals, however, conditioning stimulation of LC failed to produce a decrease in the number of orthodromic spikes, while the inhibitory effect of SC conditioning stimulation remained unaffected. Under these circumstances, intravenous L-dopa and intraventricular noradrenaline reproduced an inhibitory effect of LC conditioning stimulation on orthodromic spike generation, while such an effect was not seen with either dopamine or serotonin. Antidromic spike was unaltered by any of these treatments. Histochemically, catecholamine fluorescence in LC was entirely eliminated after reserpine-treatment, but was restored after L-dopa injection. These results strongly suggest that noradrenaline released from the terminals of neurons originating in LC produces an inhibition of transmission in the STN relay neurons.     

Feedback loop between locus coeruleus and spinal trigeminal nucleus neurons responding to tooth pulp stimulation in the rat

IGARASHI, S., M. SASA AND S. TAKAORI. Feedback loop between locus coeruleus and spinal trigeminal nucleusneurons responding to tooth pulp stimulation in the rat. BRAIN RES. BULL. 4(1) 75–83, 1979.—Studies were performed to elucidate reciprocal relationships between locus coeruleus (LC) and spinal trigeminal nucleus (STN) neurons responding to tooth pulp (TP) stimulation using rats anesthetized with α-chloralose. LC conditioning stimulation inhibited STN field potential as well as orthodromic spike generation of STN neurons produced by ipsilateral TP stimulation, confirming the previous findings in cats that LC neurons played an inhibitory role in the orthodromic transmission in STN neurons. Forty-one out of 56 LC neurons were activated by ipsilateral TP stimulation and 12 neurons by stimulation of both ipsi- and contralateral TP. STN stimulation usually excited LC neurons with a significantly shorter latency than did TP stimulation, including three LC neurons with a latency of less than 2.0 msec. These results indicate the existence of input from TP to LC neurons via multisynapses. In addition, neurons antidromically activated by STN stimulation were found in LC. It is highly probable, therefore, that there is a feedback loop between LC and STN, which might control input from TP to STN.     

Golgi studies in the substantia gelatinosa neurons in the spinal trigeminal nucleus.

This Golgi study identifies three neuronal cell types in the substantia gelatinosa (SG) layer of the spinal trigeminal nucleus. The SG neurons are distinguished from each other based on: (1) dendritic branching pattern, (2) denritic spine distribution, (3) geometric shape of the denritic tree, (4) laminar distribution of the dendrites, (5) axonal branching pattern and (6) laminar distribution of the axonal arbor. The islet cell is found in small clusters and its dendrites and axonal arbor are confined within the SG layer. Its dendrites span the full width of the SG layer and extend up to 500 mum in the long axis of the layer. Dendritic spines are generally sparse with small clusters of spines found on the higher order dendritic branches. The islet cell axon extends for at least 1 mm in the long axis of the layer. Each of its collaterals divide every 50-100 mum with one branch doubling back in the direction of the cell body and the other branch continuing on in the direction of its parent. In this manner each islet cell generates a profuse axonal plexus in the SG layer. The stalked cell is found individually within the SG layer. Its cell body is usually found in the inner half of the SG layer and its sinuous dendrites cross the SG layer and enter the marginal layer. The stalked cell dendrites emit numerous fine stalk-like branches and dentritic spines. Its axon emits branches in the SG and marginal layers. The spiny cell is found singly between groups of islet cells. Its extensive dendritic tree spans up to 500 mum rostrocaudally and mediolaterally crossing into both the marginal and magnocellular layers. Spiny cells have evenly distributed dendritic spines along their dendrites in the SG layer. The spiny cell axon sends branches into all three layers of nucleus caudalis. Numerous branches enter the outer 300 mum of the magnocellular layer where they undergo further branching with some branches returning in recurrent fashion toward the SG layer. The three neuronal cell types of the SG layer satisfy all of the morphological criteria for Golgi type II interneurons. Their highly branched axons generate many collaterals within the confines of their dendritic trees and do not project out of nucleus caudalis. The SG neurons are considered to be inhibitory interneurons interposed between V nerve primary afferent axons which arborize in the SG layer and second order neurons of nucleus caudalis.     

Effects of serotonin and morphine on spontaneous and evoked firing of nociceptive neurons in the trigeminal spinal nucleus of rats

Spontaneously firing neurons that were responsive to noxious face pinch or noxious heat were studied in the trigeminal spinal nucleus of the rat brain. These eurons responded with either an increase or decrease in firing rate. In these neurons serotonin (5-hydroxytryptamine; 5-HT) apparently acts through two mechanisms to attenuate the response to a noxious stimulus. One mechanism is mimicked by morphine; these two drugs block the response to the noxious stimuli without having a consistent effect on spontaneous firing. The effects of the two drugs were somewhat selective depending on the noxious stimulus used and the effect of the noxious stimulus; morphine and 5-HT were more effective in blocking the increase in firing rate evoked by the face pinch but 5-HT and morphine were more effective in blocking the decrease in firing rate evoked by the noxious heat stimulus. Interestingly, the direction of the response to a particular noxious stimulus frequently predicted whether or not both morphine and 5-HT would act on the same or different neurons. A second mechanism by which 5-HT, but not morphine, acted was to change the spontaneous firing in a direction opposite that evoked by the noxious stimulus. This type of effect apparently modulated the response to a noxious stimulus by changing the spontaneous firing rate such that a noxious stimulus had to be more intense before it could significantly alter the neuronal firing in the opposite direction. Morphine occasionally produced a change in firing pattern in neurons; this effect remains to be documented more extensively.     

Physiological properties of sensory neurons of the interstitial nucleus in the spinal trigeminal tract

Neurons were recorded from the interstitial nucleus of the spinal trigeminal tract. They were all nociceptive specific and some projected to the parabrachial area. These data suggest that this nucleus can be regarded as a rostral extension of lamina I of trigeminal subnucleus caudalis.     

Synapse development within the spinal trigeminal nucleus

Pars interpolaris of the spinal trigeminal nucleus of kittens has been studied with the electron microscope at birth and at several subsequent ages during the first month of life. Attention has been given to ultrastructural maturational changes that occur in this neuropil, especially events in synaptogenesis. The results of this investigation include the following observations: (1) the neuropil, even at the earliest ages studied (three-hour-old kittens), is strikingly mature, necessitating a quantitative assessment in order to determine subtle developmental changes in synaptic patterns; (2) the number of axoaxonic contacts at birth are few, and their emergence is essentially a postnatal phenomenon; (3) it appears that the immature Gray type II or symmetrical synapse possesses distinct cleft material and dense, parallel membrane specializations. Synaptic vesicle accumulation at this contact appears to occur after the membrane specializations have formed. A previous study by Kerr26 has shown a reduced potential for primary afferent reorganization with the spinal trigeminal nucleus when kittens are subjected to trigeminal rhizotomy after three days of age. Our observations on the development of axoaxonic synaptic arrangements in the neonatal period may provide an explanation for these earlier results.     

Morphological characterization of substance P receptor-immunoreactive neurons in the rat spinal cord and trigeminal nucleus caudalis

Although there is considerable evidence that primary afferent-derived substance P contributes to the transmission of nociceptive messages at the spinal cord level, the population of neurons that expresses the substance P receptor, and thus are likely to respond to substance P, has not been completely characterized. To address this question, we used an antibody directed against the C-terminal portion of the rat substance P receptor to examine the cellular distribution of the receptor in spinal cord neurons. In a previous study, we reported that the substance P receptor decorates almost the entire dendritic and somatic surface of a subpopulation of spinal cord neurons. In the present study we have taken advantage of this labeling pattern to identify morphologically distinct subpopulations of substance P receptorimmunoreactive neurons throughout the rostral-caudal extent of the spinal cord. We observed a dense population of fusiform substance P receptor-immunoreactive neurons in lamina I at all segmental levels. Despite having the highest concentration of substance P terminals, the substantia gelatinosa (lamina II) contained almost no substance P receptor-immunoreactive neurons. Several distinct populations of substance P receptor-immunoreactive neurons were located in laminae III-V; many of these had a large, dorsally directed dendritic arbor that traversed the substantia gelatinosa to reach the marginal layer. Extensive labeling was also found in neurons of the intermediolateral cell column. In the ventral horn, we found that labeling was associated with clusters of motoneurons, notably those in Onuf's nucleus in the sacral spinal cord. Finally, we found no evidence that primary afferent fibers express the substance P receptor. These results indicate that relatively few, but morphologically distinct, subclasses of spinal cord neurons express the substance P receptor. The majority, but not all, of these neurons are located in regions that contain neurons that respond to noxious stimulation. © 1995 Wiley-Liss, Inc.     

Differential action of amitriptyline on neurons in the trigeminal nucleus.

We studied the effect of amitriptyline (AMI) on neurons in the spinal trigeminal nucleus caudalis in cats anesthetized with alpha-chloralose. The IV injection of 1.0 to 4.0 mg/kg AMI had a differential effect on the inhibitory mechanisms controlling the responses of these neurons. AMI significantly enhanced the segmental inhibition (SI) of wide dynamic range (WDR) neurons but had little or no effect on low-threshold mechanoceptive neurons. AMI also facilitated the SI of some nociceptive specific (NS) neurons and the periventricular inhibition of some WDR and NS neurons, but these effects were not statistically significant. Our observations suggest that AMI exerts its antineuralgic effect by enhancing the ability of SI to prevent excessive firing of WDR neurons. This supports the notion that neuropathic pain is caused by dysfunction of inhibitory mechanisms in the CNS.     

Nitric oxide synthase inhibition lowers activity of neurons with meningeal input in the rat spinal trigeminal nucleus

Nitric oxide is thought to control transmitter release and neuronal activity in the spinal dorsal horn and the spinal trigeminal nucleus, where nociceptive information from extra- and intracranial tissues is processed. Extracellular impulse activity was recorded from neurons in the rat spinal trigeminal nucleus with afferent input from the cranial dura mater. In contrast to the inactive isomer D-NAME, infusion of the nitric oxide synthase inhibitor L-NAME (20 mg/kg) significantly reduced neuronal activity and increased systemic blood pressure. It is concluded that nitric oxide production contributes to the ongoing activity of sensitized neurons in the spinal trigeminal nucleus. The results suggest that nitric oxide may be involved in the generation and maintenance of primary headaches such as migraine.     

Co-localization of fixative-modified glutamate and glutaminase in neurons of the spinal trigeminal nucleus of the rat: an immunohistochemical and immunoradiochemical analysis

The spinal trigeminal nucleus (STN) is involved in processing orofacial sensory information, including tactile, thermal and nociceptive input, and relaying this information to higher brain centers, such as the thalamus. Very little information is available regarding the major excitatory neurotransmitters of this nucleus. The amino acid glutamate has been proposed as a major excitatory neurotransmitter in the central nervous system. In the present study, a novel monoclonal antibody, specific for fixative-modified glutamate, was utilized in conjunction with polyclonal antisera against glutaminase and aspartate aminotransferase (AATase) in an attempt to identify and map the locations of possible glutamatergic neurons in the STN. Co-localization experiments were performed by radiolabeling our monoclonal antibody and using this antibody in conjunction with the polyclonal antisera against glutaminase and AATase to evaluate the possible coexistence of glutamate with glutaminase or AATase in STN neurons. In all three subnuclei of the STN, immunohistochemically labeled neuronal profiles were observed with both of the polyclonal antisera and with the monoclonal antibody. Subnucleus caudalis contained the greatest number of labeled profiles per coronal section followed by subnucleus interpolaris and subnucleus oralis. The number and the distribution of immunoreactive profiles observed after the use of the glutaminase antiserum was comparable to that obtained with the monoclonal antibody. Co-localization experiments demonstrated that all glutaminase-like immunoreactive neurons also contained fixative-modified glutamate-like immunoradioactivity. These results suggest that glutamatergic neurons are present in the spinal trigeminal nucleus. The AATase antiserum labeled more neuronal profiles in each of the three subnuclei than did the glutaminase antiserum or the monoclonal antibody. In addition, co-localization experiments indicated that glutamate-like immunoreactivity was present in only two-thirds of AATase-like immunoreactive neuronal profiles. These findings suggest that glutaminase may be a more reliable marker of glutamatergic function than AATase.     

Association of serotonin-like immunoreactive axons with nociceptive projection neurons in the caudal spinal trigeminal nucleus of the rat

Serotoninergic projections to the spinal dorsal horn are implicated in the modulation of nociceptive transmission. However, morphological evidence indicating that serotoninergic projection fibers make synapses on nociceptive neurons in the medullary dorsal horn is still meager. Thus, we examined whether axonal varicosities with serotonin (5-HT)-like immunoreactivity (5-HT-LI) might make synapses on nociceptive projection neurons in the caudal spinal trigeminal nucleus (Vc) of the rat. Projection neurons were retrogradely labeled with tetramethylrhodamine-dextran amine (TMR-DA) or wheat germ agglutinin-horseradish peroxidase (WGA-HRP) that was injected into the parabrachial or thalamic region. Vc neurons in which c-fos protein-like immunoreactivity (Fos-LI) was induced by subcutaneous injection of formalin into the lip were considered nociceptive. Vc neurons in direct contact with axonal varicosities that bind isolectin I-B4 were also considered nociceptive. Triple labeling for 5-HT, TMR-DA, and Fos as well as that for 5-HT, TMR-DA, and I-B4 were done by using the immunofluorescence and fluorescence histochemical techniques. Confocal laser-scanning microscopy revealed that axonal varicosities with 5-HT-LI were in close apposition to TMR-DA-labeled neurons showing Fos-LI in lamina I and the outer part of lamina II (lamina IIo), and that both axonal varicosities with 5-HT-LI and those binding I-B4 were in close apposition to single neuronal profiles labeled with TMR-DA. The presumed nociceptive neuronal profiles in close apposition to axon terminals with 5-HT-LI were mainly those of laminae I and II neurons as well as dendrites of lamina III neurons. Electron microscopy confirmed that axon terminals with 5-HT-LI and those with I-B4 binding activity in laminae I and II made synapses on somatic and dendritic profiles that were labeled with WGA-HRP. The results indicate that serotoninergic neurons project directly on nociceptive projection neurons in the Vc. J. Comp. Neurol. 384:127-141, 1997. © 1997 Wiley-Liss, Inc.     

Substance P receptor-like immunoreactive neurons in the caudal spinal trigeminal nucleus send axons to the gelatinosus thalamic nucleus in the rat.

By means of substance P receptor (SPR) immunofluorescence histochemistry combined with Fluoro-Gold (FG) fluorescent retrograde labeling, SPR-like immunoreactive neurons in the caudal spinal trigeminal nucleus of the rat were observed to send their axons to the gelatinosus thalamic nucleus with a clear ipsilateral dominance. FG/SPR double-labeled neurons were distributed mainly in the ventral part of lamina I at the rostral level of the caudal spinal trigeminal nucleus. The percentages of FG/SPR-LI neurons in the total number of SPR-LI neurons and FG-labeled neurons are 10.5% and 31.1%, respectively. The present results suggest that trigemino-gelatinosus thalamic projection neurons with SPR-LI in the caudal spinal trigeminal nucleus might receive SP-containing, nociceptive primary afferent fibers from the orofacial region and transmit nociception to the gelatinosus thalamic nucleus.     

Morphine microinjected into the nucleus raphe magnus does not block the activity of spinal trigeminal nucleus oralis convergent neurons in the rat

This study investigated the effects of morphine microinjection into the nucleus raphe magnus (RMg) on electrically evoked C-fiber activities of convergent neurons in the spinal trigeminal nucleus oralis (Sp5O), in halothane-anesthetized rats. Although the neurons could be depressed by systemic morphine (6 mg/kg, i.v.) in a naloxone-reversible fashion, morphine microinjected into the RMg (2.5 μg or 5 μg) neither depressed their C-fiber-evoked responses, nor the diffuse noxious inhibitory controls acting on them. It is concluded that the RMg is not involved in reinforcing descending inhibitory controls that are tonic or triggered by noxious stimuli acting on Sp5O convergent neurons.     

Effects of L-threo-DOPS, a noradrenaline precursor, on the long-term potentiation in the rat hippocampal mossy fiber-CA3 region.

The effects of L-threo-3,4-dihydroxyphenylserine (L-threo-DOPS), a synthetic precursor of norepinephrine (NE), on the long-term potentiation (LTP) in the hippocampal mossy fiber-CA3 system was examined in urethane-anesthetized rats, the objective being to determine whether or not this drug acts as NE on the LTP. L-threo-DOPS may be effective for treating some type of mental disorders, including dementia. The LTP, induced in CA3 by tetanic stimulation (100 Hz for 1 s) applied to the mossy fiber persisted for more than 4 h. When L-threo-DOPS (50 and 150 micrograms) was injected into the lateral ventricle 30 min prior to the tetanic stimulation, there were no significant alterations in the LTP. However, in animals treated with reserpine (5 mg/kg i.p.) 24 h before the experiment, LTP was not induced with tetanic stimulation alone yet was obtained when tetanic stimulation was preceded by L-threo-DOPS (50 and 150 micrograms) applied to the ventricle. The LTP obtained by L-threo-DOPS in the reserpine-treated animal was inhibited by pretreatment with benserazide and was completely blocked by the simultaneous administration of sotalol. These results suggest that NE converted from L-threo-DOPS plays an important role in inducing LTP in the mossy fiber-CA3 system in the animals deficient in catecholamines.     

Opioid peptide immunoreactivity in spinal and trigeminal dorsal horn neurons projecting to the parabrachial nucleus in the rat

The parabrachial nucleus (PB) is the major relay for ascending visceral afferent information from the nucleus of the solitary tract to the forebrain. We have recently found that PB in the rat also receives a substantial afferent projection from neurons in the marginal zone of the entire length of the spinal and trigeminal dorsal horn. Immunoreactive perikarya stained with antisera against several neuropeptides--including dynorphin, enkephalins, and substance P--have been identified in the marginal zone. We therefore investigated the chemical specificity of the spinoparabrachial projection by combining fluorescent retrograde tracing with immunofluorescence for substance P, dynorphin A1-17, met-enkephalin, and two enkephalin precursor fragments (proenkephalin 192-203 and peptide E). Following PB injections of fluorescent dyes, about half of the retrogradely labeled neurons in the marginal zone stained with antisera against either dynorphin or enkephalin series peptides. Elution-restaining experiments indicated that the dynorphin- and enkephalin-immunoreactivities were contained within separate populations of marginal zone neurons. We could not identify any substance P-immunoreactive perikarya in the marginal zone, but substance P-immunoreactive fibers were seen in close apposition to retrogradely labeled, opioid-immunoreactive cell bodies and dendrites. These results indicate that the dynorphin- and enkephalin-immunoreactive perikarya in the marginal zone of the dorsal horn represent independent neuronal populations. These opioid-immunoreactive neurons, which are believed to have extensive local collateral connections, are the main source of a long ascending projection to the parabrachial nucleus in the rat. Furthermore, opioid neurons in the marginal zone may receive substance P-immunoreactive primary sensory afferents.