Effects of morphine and naloxone on the responses to noxious stimulation of neurones in the nucleus reticularis paragigantocellularis

Interactive Mechanisms of Supraspinal Sites of Opioid Analgesic Action: A Festschrift to Dr. Gavril W. Pasternak

Almost a half century of research has elaborated the discoveries of the central mechanisms governing the analgesic responses of opiates, including their receptors, endogenous peptides, genes and their putative spinal and supraspinal sites of action. One of the central tenets of "gate-control theories of pain" was the activation of descending supraspinal sites by opiate drugs and opioid peptides thereby controlling further noxious input. This review in the Special Issue dedicated to the research of Dr. Gavril Pasternak indicates his contributions to the understanding of supraspinal mediation of opioid analgesic action within the context of the large body of work over this period. This review will examine (a) the relevant supraspinal sites mediating opioid analgesia, (b) the opioid receptor subtypes and opioid peptides involved, (c) supraspinal site analgesic interactions and their underlying neurophysiology, (d) molecular (particularly AS) tools identifying opioid receptor actions, and (e) relevant physiological variables affecting site-specific opioid analgesia. This review will build on classic initial studies, specify the contributions that Gavril Pasternak and his colleagues did in this specific area, and follow through with studies up to the present.

Effects of 5-hydroxytryptamine applied into nucleus raphe magnus on nociceptive thresholds and neuronal firing rate

The effect of iontophoretically applied 5-hydroxytryptamine on neurones in nucleus raphe magnus, and the effect of microinjection of 5-hydroxytryptamine into nucleus raphe magnus on nociceptive thresholds were examined in the rat. Iontophoretically applied 5-hydroxytryptamine excited 66% and inhibited 6% of the neurones encountered in the nucleus raphe magnus. The excitatory response to 5-hydroxytryptamine was reduced by the putative serotonergic antagonist cinanserin in 21 of 24 cases. In 12 of these neurones the responses to iontophoretically applied glutamate were also examined. In 11 of the 12 studies the responses to glutamate were reduced by cinanserin. Microinjection of 5 microg of 5-hydroxytryptamine into the nucleus raphe magnus produced analgesia as assessed by the tail-flick response to noxious heat stimulation, but no analgesia as assessed by the paw withdrawal response to pressure. Microinjection of 5 microg of 5-hydroxytryptamine into the adjacent nucleus reticularis paragigantocellularis had no analgesic effect in either test. These results indicate that 5-hydroxytryptamine mainly excites neurones in nucleus raphe magnus and that 5-hydroxytryptamine has an action on neurones in nucleus raphe magnus which modulate the nociceptive threshold.

The function of alpha-2-adrenoceptors in the rat locus coeruleus is preserved in the chronic constriction injury model of neuropathic pain

RATIONALE

Peripheral neuropathic pain is a chronic condition that may produce plastic changes in several brain regions. The noradrenergic locus coeruleus (LC) is a crucial component of ascending and descending pain pathways, both of which are frequently compromised after nerve injury.

OBJECTIVES

The objective of the study was to examine whether chronic constriction injury (CCI), a model of neuropathic pain, alters noradrenergic activity in the rat LC.

METHODS

Activity in the LC was assessed by electrophysiology and microdialysis, while protein expression was monitored in western blots and by immunohistochemistry.

RESULTS

The pain threshold had dropped in injured rats 7 days after inducing neuropathy. While alpha-2-adrenoceptors mediate activity in the LC and in its terminal areas, no alterations in either spontaneous neuronal activity or extracellular noradrenaline levels were observed following CCI. Moreover, alpha-2-adrenoceptor activity in the LC of CCI rats remained unchanged after systemic administration of UK14,304, RX821002 or desipramine. Accordingly, extracellular noradrenaline levels in the LC were similar in CCI and control animals following local administration of clonidine or RX821002. In addition, there were no changes in the expression of the alpha-2-adrenoceptors, Gαi/z subunits or the regulators of G-protein signaling. However, pERK1/2 (phosphorylated extracellular signal-regulated kinases 1/2) expression augmented in the spinal cord, paragigantocellularis nucleus (PGi) and dorsal raphe nucleus (DRN) following CCI.

CONCLUSIONS

Neuropathic pain is not accompanied by modifications in tonic LC activity after the onset of pain. This may indicate that the signals from the PGi and DRN, the excitatory and inhibitory afferents of the LC, cancel one another out.

Discharge activities of neurons in the nucleus paragigantocellularis during the development of morphine tolerance and dependence: a single unit study in chronically implanted rats

The nucleus paragigantocellularis (PGi) has been proposed to play a role in opiate dependence/withdrawal. In the present study, we examined the discharge activity of PGi neurons before and after the development of morphine tolerance/dependence in rats. A multi-wire electrode was chronically implanted in the PGi, which allowed us to monitor the effects of both acute and chronic morphine treatments on the activity of PGi neurons recorded from the same site. We found that acute morphine excited, inhibited or had no effect on 36%, 35% or 29% of PGi neurons (N=556), respectively. After 3 days of continuous morphine infusion, which led to morphine tolerance/dependence, the firing rates of both excitatory and inhibitory PGi neurons returned to pre-morphine treatment levels, indicating that the PGi neurons developed tolerance to both excitatory and inhibitory effects of morphine. Naltrexone-precipitated withdrawal from chronic morphine treatment also induced heterogeneous responses in the PGi. On a site-by-site basis, most of the sites that showed excitatory response to acute morphine exhibited inhibitory response during withdrawal, and all the sites that showed inhibitory response to acute morphine exhibited excitatory response during withdrawal. Correlation analysis further quantitatively showed that PGi neurons' responses to acute morphine and that during withdrawal were inversely correlated with a correlation coefficient of 0.73, suggesting that adaptations in the PGi during the development of morphine dependence share common neural mechanisms with the acute effect of morphine. These results provide new insights into the role of the PGi in the development of morphine tolerance/dependence.

Select spinal lesions reveal multiple ascending pathways in the rat conveying input from the male genitalia

The specific white matter location of all the spinal pathways conveying penile input to the rostral medulla is not known. Our previous studies using rats demonstrated the loss of low but not high threshold penile inputs to medullary reticular formation (MRF) neurons after acute and chronic dorsal column (DC) lesions of the T8 spinal cord and loss of all penile inputs after lesioning the dorsal three-fifths of the cord. In the present study, select T8 lesions were made and terminal electrophysiological recordings were performed 45-60 days later in a limited portion of the nucleus reticularis gigantocellularis (Gi) and Gi pars alpha. Lesions included subtotal dorsal hemisections that spared only the lateral half of the dorsal portion of the lateral funiculus on one side, dorsal and over-dorsal hemisections, and subtotal transections that spared predominantly just the ventromedial white matter. Electrophysiological data for 448 single unit recordings obtained from 32 urethane-anaesthetized rats, when analysed in groups based upon histological lesion reconstructions, revealed (1) ascending bilateral projections in the dorsal, dorsolateral and ventrolateral white matter of the spinal cord conveying information from the male external genitalia to MRF, and (2) ascending bilateral projections in the ventrolateral white matter conveying information from the pelvic visceral organs (bladder, descending colon, urethra) to MRF. Multiple spinal pathways from the penis to the MRF may correspond to different functions, including those processing affective/pleasure/motivational, nociception, and mating-specific (such as for erection and ejaculation) inputs.

Excitatory amino acid receptors are involved in morphine-induced synchronous oscillatory discharges in the locus coeruleus of rats

Our previous studies demonstrated that morphine not only decreases the firing rate of locus coeruleus neurons, but that it induces synchronous oscillatory discharges in the locus coeruleus. In the present study, we examined the role of excitatory amino acid input in the mechanisms of the morphine-induced synchronous oscillation in the locus coeruleus. Using a multiple-electrode recording technique, locus coeruleus neuronal activities were recorded under halothane anesthesia in adult Sprague-Dawley rats. Among 175 locus coeruleus neurons recorded after intracerebroventricular (i.c.v.) injection of morphine (26 nmol), 88 of them exhibited both decreased firing rates and synchronous oscillatory discharges. The morphine-induced oscillation and synchrony were reversed by i.c.v. injection of the non-selective excitatory amino acid receptor antagonist kynurenic acid, the selective NMDA receptor antagonist DL-2-amino-5-phosphonopentanoic acid (AP-5), or the non-NMDA receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX), but not saline vehicle. These results suggest that excitatory amino acid input contributes to the morphine-induced synchronous oscillatory activity in the locus coeruleus. The results also provide us a pharmacology tool to study the influence of blockade of the locus coeruleus synchrony on neurotransmitter release and synaptic plasticity in the locus coeruleus target areas.

Fos and FRA protein expression in rat nucleus paragigantocellularis lateralis during different space flight conditions

The nucleus paragigantocellularis lateralis (LPGi) exerts a prominent excitatory influence over locus coeruleus (LC) neurons, which respond to gravity signals. We investigated whether adult albino rats exposed to different gravitational fields during the NASA Neurolab Mission (STS-90) showed changes in Fos and Fos-related antigen (FRA) protein expression in the LPGi and related cardiovascular, vasomotor, and respiratory areas. Fos and FRA proteins are induced rapidly by external stimuli and return to basal levels within hours (Fos) or days (FRA) after stimulation. Exposure to a light pulse (LP) 1 h prior to sacrifice led to increased Fos expression in subjects maintained for 2 weeks in constant gravity (either at approximately 0 or 1 G). Within 24 h of a gravitational change (launch or landing), the Fos response to LP was abolished. A significant Fos response was also induced by gravitational stimuli during landing, but not during launch. FRA responses to LP showed a mirror image pattern, with significant responses 24 h after launch and landing, but no responses after 2 weeks at approximately 0 or 1 G. There were no direct FRA responses to gravity changes. The juxtafacial and retrofacial parts of the LPGi, which integrate somatosensory/acoustic and autonomic signals, respectively, also showed gravity-related increases in LP-induced FRA expression 24 h after launch and landing. The neighboring nucleus ambiguus (Amb) showed completely different patterns of Fos and FRA expression, demonstrating the anatomical specificity of these results. Immediate early gene expression in the LPGi and related cardiovascular vasomotor and ventral respiratory areas may be directly regulated by excitatory afferents from vestibular gravity receptors. These structures could play an important role in shaping cardiovascular and respiratory function during adaptation to altered gravitational environments encountered during space flight and after return to earth.

Sciatic and vagal sensory inputs converge onto non-baroreceptive neurones of the rostral ventrolateral medulla

Previous data suggested that somatic and vagal sensory afferent inputs may converge in the rostral ventrolateral medulla oblongata (RVLM). The aim of the present study was to establish the existence of convergence between inputs mediated via the cervical vagus and contralateral sciatic nerves using in vivo intracellular recordings. The majority of RVLM neurones that received input from the vagus or the sciatic nerves also responded to stimulation of the other nerve. In 72% of the neurones the response was excitation or inhibition to stimulation of both nerves, respectively. The most frequent response type was a short excitation in response to stimulation of both nerves. Only 8% of the neurones exhibited a visible response to stimulation of the aortic depressor nerve. The results provided experimental evidence that non-baroreceptive neurones of the RVLM are involved in coordination of somatic and visceral sensory inputs.

A mouse genetic locus with death clock and life clock features

A senility syndrome, with weight loss and priapism, occurs in CBAT6/T6 mice, an exceptionally long-lived strain. Instead of dying at the expected time, these mice get senile weight loss and priapism and go on living. We have postulated that a mutant death clock kills the wrong neurons. Crosses with the NZW and C57BL/6 strains show causation by a single genetic locus (Priap1), with a pronounced gene dosage effect on timing. We report here that various cancers were the cause of death in 31 of 32 NZW mice, compared to only five of 22 CBAT6/T6 mice, a highly significant difference (P<0.001). The longevity of (CBAT6/T6xNZW)F1 hybrids, and the segregation of longevity with priapism and senile weight loss in (CBAT6/T6xNZW) F2 hybrids, indicates that Priap1, or a linked gene, inhibits the cancers that usually shorten the lives of NZW mice. If a timer gene is involved, the cancer resistance action could be because the locus impedes the normal mid-life regression of anti-cancer defence. The priapism suggests loss of the medullary reticular formation neurons which normally inhibit male spinal sexual reflexes. In this region of the medulla there are also the respiratory and cardiac control centres, where apoptotic neuron destruction by the wild-type locus could govern maximal life-span. The CBAT6/T6 locus may be a mutant life-stage control clock. Its discovery could be the revelation of a new, major class of aetiology of disease.

Occurrence of morphine tolerance and dependence in the nucleus paragigantocellularis neurons

The occurrence of morphine tolerance and dependence in the nucleus paragigantocellularis neurons was investigated. The spontaneous activity was recorded from the nucleus paragigantocellularis neurons of urethane-anesthetized rats, using single unit recording. Morphine microinjected (20 mg/ml, 120-200 nl) into the nucleus paragigantocellularis of control rats had both excitatory and inhibitory effects. These effects were reversed by microinjection of naloxone, revealing the possible involvement of mu receptors. Morphine microinjected into morphine-dependent rats failed to change the spontaneous activity of the nucleus paragigantocellularis neurons that accounts for the occurrence of tolerance to morphine in these neurons. Microinjection of naloxone (25 mg/ml, 120-200 nl) in control rats had no effect on the spontaneous firing rate of the nucleus paragigantocellularis neurons but in morphine-dependent rats, either alone or after morphine microinjection, naloxone increased neuronal activity significantly, indicating the occurrence of dependence on morphine in the nucleus paragigantocellularis neurons. These data show that the nucleus paragigantocellularis neurons may play a role in physical dependence on morphine. This conclusion is consistent with the finding, that activation of the nucleus paragigantocellularis by electrical stimulation in morphine-naive rats can elicit behaviors similar to those observed during naloxone-precipitated morphine withdrawal.

Some proposals regarding the organization of the central nervous system control of penile erection

Recent research on the central nervous control of penile erection is discussed. A framework for this control is based upon principles put forward by Frank Beach regarding the neuroendocrine regulation of male copulatory behavior. The current discussion is focused primarily on a subset, penile erection. The spinal cord contains all the necessary components for the production of penile erection. This requires a multisegmental coordination among penile vasodilator and vasoconstrictor autonomic neurons, pudendal motoneurons responsible for penile rigidity and autonomic neurons which control extra-penile blood flow. Genital sensory stimulation can activate this spinal network. The spinal cord is also under excitatory and inhibitory control from supraspinal sites. Penile erection can be driven by supraspinal input alone and supraspinal control can inhibit the erectile effects of genital stimulation.An important aspect of the CNS control of penile erection is that there are extensive interconnections between most of the brain sites identified to date. Most of the pathways are characterized by reciprocal connections. A large number of the CNS sites also receive genital sensory information. Thus, descending control may itself be modulated by ascending sensory pathways which relay information from the genitalia. This raises the possibility that penile erection may involve a positive feedback system. Receptors for gonadal hormones have been identified throughout the neuraxis. However, strong evidence for the control of male sexual function by gonadal hormones has been identified only for forebrain sites. The functional role of brainstem and spinal gonadal hormone receptors has not yet been clarified.

Morphine tolerance and dependence in the nucleus paragigantocellularis: single unit recording study in vivo

In this study, a single unit activity was recorded in the nucleus paragigantocellularis (PGi), located in the rostral ventrolateral medulla of anesthetized, morphine-dependent rats. The spontaneous activity of PGi neurons was significantly decreased by administration of morphine (10 mg/kg; i.p.) in sham-operated, control and morphine-dependent rats. However, in PGi neurons of morphine-dependent rats, the firing rate decreased significantly less than those of sham-operated and control ones. There was also significant enhancement of spontaneous activity of PGi neurons for 30 min following administration of naloxone (2 mg/kg; s.c.) in morphine-dependent rats as an opiate withdrawal-induced activation of PGi neurons. The results indicated the occurrence of morphine tolerance and dependence in the PGi and/or elsewhere which appeared in PGi unit activity. The findings are consistent with the hypothesis that during morphine withdrawal, there is an increase in unit activity of the PGi afferents to the nucleus locus coeruleus (LC) or an increased release of excitatory transmitter from their nerve terminals in the LC.

Response of locus coeruleus neurons to footshock stimulation is mediated by neurons in the rostral ventral medulla

While it is well documented that locus coeruleus neurons are potently activated by foot-pinch or sciatic nerve stimulation, little is known about the circuit producing this sensory response. Previous work in our laboratory has identified the medullary nucleus paragigantocellularis as a major excitatory afferent to the locus coeruleus. Here, we use local microinjections into the paragigantocellularis to test whether this nucleus is a link in the pathway mediating the activation of locus coeruleus neurons by subcutaneous footpad stimulation, or footshock, in anesthetized rats. Lidocaine HCl microinjected into the paragigantocellularis reversibly attenuated footshock-evoked activation of 50 out of 56 locus coeruleus cells, with responses in 20 cells completely blocked. Microinjections of GABA into the paragigantocellularis reduced the footshock-evoked responses of 17 out of 27 locus coeruleus cells (seven complete blocks); microinjections of the GABAB agonist baclofen had no effect (0 out of 11 cells blocked). Microinjections of a synaptic decoupling cocktail of manganese and cadmium also attenuated locus coeruleus activation in eight out of nine cells with two complete blocks. With each agent, the most effective injection placement for complete blockade of responses was the ventromedial paragigantocellularis; injections bordering this region attenuated responses, while those outside of the paragigantocellularis (dorsal medullary reticular formation, nucleus tractus solitarius, or facial nucleus), or vehicle injections, were ineffective. These results are consistent with previous findings that pharmacologic blockade of paragigantocellularis-evoked locus coeruleus activity also blocks footshock-evoked responses of locus coeruleus neurons [Ennis and Aston-Jones (1988) J. Neurosci. 8, 3644-3657], and support the view that this somatosensory response, and perhaps other sensory-evoked responses of locus coeruleus neurons, involve the nucleus paragigantocellularis.

Brainstem afferents to the rostral (juxtafacial) nucleus paragigantocellularis: integration of exteroceptive and interoceptive sensory inputs in the ventral tegmentum

The rostral pole of the nucleus paragigantocellularis (PGi), termed juxtafacial PGi, lies medially adjacent to the facial nucleus and lateral to the pyramidal tract and the nucleus gigantocellularis pars alpha in the caudal ventral pons. This narrow region of the ventral pontine reticular formation is an afferent to the nucleus locus coeruleus, and contains neurons which have been implicated in pain processing, cardiovascular regulation, respiratory control and arousal. Here, we studied brainstem afferents to the juxtafacial PGi using retrograde transport of wheat germ agglutinin-conjugated horseradish peroxidase (WGA-HRP) or of a colloidal gold-protein complex. Anterograde transport of WGA-HRP, or of Phaseolus vulgaris leucoagglutinin (PHA-L), was used to confirm and further detail innervation patterns in the juxtafacial PGi. Results revealed that the juxtafacial PGi receives inputs from a variety of nuclei involved in somatosensory, auditory and autonomic function. Retrograde labeling was prominent in the dorsal column nuclei, the inferior colliculus and the paralemniscal zone of the midbrain, as previously reported in other species. We also found afferents to the juxtafacial PGi that were not previously described, including the paramedian reticular formation and the paraolivary reticular formation. Afferents were also identified from the retrofacial PGi, the caudal medullary reticular formation and the dorsal periaqueductal gray, structures implicated in autonomic and pain regulation. These results indicate that inputs to this subregion of the PGi is distinct from that to the more caudal parts of the PGi, and support the view that the juxtafacial PGi may function in the integration and coordination of polymodal (somatic and visceral) sensory events.

Effect of systemic morphine on neurons in the lateral reticular nucleus area of the rat

The present study is undertaken to investigate the effect of systemic morphine on neurons in the lateral reticular nucleus (LRN) using extracellular recording techniques. The spontaneous activities of 64 neurons in the LRN area were tested with morphine (3-5 mg/kg, IV). Morphine excited 23 and inhibited 28 neurons tested, and 13 neurons were not affected. Of the 28 neurons inhibited, 20 were identified as nociceptive and the remaining 6 were nonnociceptive. Of the 23 neurons excited by morphine, 18 were nociceptive and 5 were nonociceptive. Systemic naloxone (0.3-0.5 mg/kg) significantly reversed the morphine effect in 15 out of 19 neurons excited and 19 out of 20 neurons inhibited by morphine. Thirteen out of 64 neurons were further identified as reticulospinal neurons, of which four were excited and four were inhibited by morphine. The remaining five were not affected. The results demonstrate that a similar proportion of neurons in the LRN area were either excited or inhibited by systemic morphine, and the majority of them are nociceptive neurons. It is suggested that different types of neurons in the LRN area may have different functions in morphine analgesia.

Activation of locus coeruleus neurons by nucleus paragigantocellularis or noxious sensory stimulation is mediated by intracoerulear excitatory amino acid neurotransmission

The nucleus paragigantocellularis (PGi), located in the rostral ventrolateral medulla, is one of two major afferents to the nucleus locus coeruleus (LC). Electrical stimulation of PGi exerts a robust, predominantly excitatory influence on LC neurons that is blocked by intracerebroventricular (i.c.v.) administration of the broad spectrum excitatory amino acid (EAA) antagonists kynurenic acid (KYN) or gamma-D-glutamylglycine (DGG), but not by the selective N-methyl-D-aspartate (NMDA) receptor antagonist 2-amino-7-phosphonoheptanoate (AP7). I.c.v. injection of KYN or DGG also blocked activation of LC neurons evoked by noxious somatosensory stimuli. These results indicate that activation of LC neurons by PGi and noxious stimuli may be mediated by an EAA acting at a non-NMDA receptor in LC. In the present study, microiontophoretic techniques were used to determine the sensitivity of LC neurons in vivo to the selective EAA receptor agonists kainate (KA), NMDA and quisqualate (QUIS). Microinfusion and microiontophoresis were also used to determine whether direct application of KYN, the preferential non-NMDA receptor antagonist 6-cyano-7-nitroquinoxaline-2,3 dione (CNQX) or the selective NMDA receptor antagonist 2-amino-5-phosphonovalerate (AP5) onto LC neurons blocked excitation elicited by stimulation of PGi or the sciatic nerve. The results demonstrated that individual LC neurons were robustly activated by direct application of KA, NMDA and QUIS. Iontophoretically applied KYN reduced or completely antagonized responses evoked by all 3 agonists. In contrast, iontophoretically applied AP5 strongly attenuated NMDA-evoked excitation, while KA-and QUIS-evoked responses were not affected by this agent. Furthermore, direct application of KYN or the specific non-NMDA receptor antagonist, CNQX, onto LC neurons substantially attenuated or completely blocked synaptic activation produced by PGi or sciatic nerve stimulation in nearly every LC neuron tested. Microinfusion of the selective NMDA receptor antagonist AP5 had no effect on sciatic nerve-evoked responses. These results confirm our hypothesis that activation of LC neurons from PGi is mediated by an EAA operating primarily at a non-NMDA receptor subtype on LC neurons. Furthermore, these findings provide additional support for the hypothesis that this pathway mediates at least some sensory-evoked responses of LC neurons.

Lesions of the nucleus paragigantocellularis: effects on mating behavior in male rats

We evaluated the effects of bilateral radio-frequency lesions of the paragigantocellular (PGi) reticular nucleus in the ventral medulla on male rat copulatory behavior. In Experiment 1, sexually naive male rats with such lesions were more likely than sham-operated controls to copulate to ejaculation during their first exposure to an estrous female. Additionally, among the rats that copulated to ejaculation, those with lesions demonstrated a reduction in mount frequency (MF), intromission frequency (IF), and ejaculation latency (EL), and an increase in copulatory efficiency (CE). In Expt. 2, sexually experienced male rats were allowed to mate to sexual exhaustion. Males with PGi lesions showed an increased latency to sexual exhaustion and an increased number of ejaculations prior to exhaustion. Additionally, rats with PGi lesions displayed reductions in IF, EL, and post-ejaculatory interval (PEI) as they approached sexual exhaustion. Our results provide further evidence that the PGi is a supraspinal locus of descending inhibitory influence on spinal nuclei mediating ejaculatory reflexes in the male rat.

Direct and indirect actions of morphine on medullary neurons that modulate nociception

The rostral ventromedial medulla is part of a neural network through which systemically administered morphine produces antinociception. Two physiologically characterized classes of presumed nociceptive modulating neurons that respond differentially to systemically administered morphine have been identified in this region: the firing of "on-cells" is depressed, whereas "off-cells" become continuously active. On-cells have been proposed to permit or facilitate, and off-cells to inhibit, nociceptive transmission. Because local application of morphine in the rostral ventromedial medulla itself is sufficient to produce antinociception, it is important to determine whether systemically administered morphine exerts its effects on neurons in this region by a direct action. Thus, activity of physiologically characterized neurons was studied before, during and after ionotophoretic administration of morphine. As with systemic administration, iontophoretic application of morphine depresses the activity of on-cells, an effect that is reversed by iontophoretic as well as by systemic administration of naloxone. In contrast, no reliable changes in the firing of off-cells are produced by iontophoretic administration of morphine. Cells of a third class, "neutral cells", are not affected by systemic morphine administration, nor do they respond to iontophoretic application of the drug. The present experiments demonstrate that direct opioid responsiveness in the rostral ventromedial medulla is limited to a single physiologically characterized class of presumed nociceptive modulatory neuron, the on-cell. This implies that the antinociceptive effect exerted by systemically administered morphine involves at least two components within the rostral ventromedial medulla: a direct inhibition of on-cells, and an indirect activation of off-cells. Each of these actions is likely to have a net hypoalgesic effect.

Paragigantocellularis stimulation induces beta-adrenergic hippocampal potentiation

The nucleus paragigantocellularis (PGi) is the major excitatory glutamatergic input to the locus coeruleus (LC). Glutamate activation of the LC has previously been shown to produce beta-adrenergic-dependent potentiation of the perforant path- (PP) evoked population spike in the dentate gyrus (DG). The present study asks if electrical stimulation of the PGi, by activating the LC endogenously, can produce a parallel beta-receptor-dependent potentiation of the PP-evoked population spike. An optimal interstimulus interval (ISI) was determined for PGi-PP stimulation in urethane-anesthetized rats and propranolol was used to assess the role of noradrenergic beta-receptors. PGi stimulation potentiated the PP-evoked population spike at an optimal ISI of 30 ms. The population synaptic response slope and spike latency were not affected. Propranolol blocked the PGi-induced potentiation, as would be expected for beta-receptor-dependent modulation. The parallels between PGi- and LC-induced effects on the PP-evoked population spike suggest PGi stimulation offers an alternate method of LC activation for studies of LC's role in behavior.

The identification of a brainstem site controlling spinal sexual reflexes in male rats

It has long been assumed that the brainstem exerts a tonic descending inhibitory influence on spinal sexual reflexes, but the source of this inhibition is unknown. Sexual responses (penile erection and ejaculatory movements) were elicited in anesthetized male rats using urethral stimuli. Using brainstem transections and electrolytic and neurotoxic lesions, we have identified a group of neurons in the paragigantocellular reticular nucleus in the ventral medulla which mediates this descending inhibition. Correlative neuroanatomical studies indicate that the inhibition is mediated via a direct projection to pelvic efferent neurons and interneurons. These results promise new approaches to the treatment of human sexual disorders.

Diverse afferents converge on the nucleus paragigantocellularis in the rat ventrolateral medulla: retrograde and anterograde tracing studies

The nucleus paragigantocellularis in the ventrolateral medulla has been implicated in cardiovascular, pain, and analgesic functions; and it has also been found to be a major afferent to the pontine nucleus locus coeruleus. In the present study, afferents to the nucleus paragigantocellularis were identified in the rat by means of the retrograde tracers wheat germ agglutinin-conjugated horseradish peroxidase or Fluoro-Gold. Projections to the nucleus paragigantocellularis arise from a wide variety of nuclei with autonomic, visceral, and sensory-related functions. Major afferents with consistent and robust retrograde labeling include most laminae of the spinal cord, the caudal lateral medulla, the contralateral paragigantocellularis, the nucleus of the solitary tract, the A1 area, the lateral parabrachialis, the Kölliker-Fuse nucleus, the periaqueductal gray, and a preoculomotor nucleus in the ventral central gray, the supraoculomotor nucleus. Other notable afferents, seen only after large caudal injections into the nucleus paragigantocellularis, include the lateral hypothalamus, the paraventricular nucleus of the hypothalamus, and the medial prefrontal cortex. Minor afferents include the gigantocellular nucleus, the area postrema, the caudal raphe groups, the inferior colliculus, the A5 area, and the locus coeruleus. The projection from the supraoculomotor nucleus, not previously reported as an afferent to the ventrolateral medulla, was confirmed with anterograde tracing by means of Phaseolus vulgaris-leucoagglutinin. Iontophoretic deposits of Phaseolus vulgaris-leucoagglutinin into the nucleus of the solitary tract (commissuralis level) or into the periaqueductal gray also yielded terminal fiber labeling in the nucleus paragigantocellularis. Fibers from the supraoculomotor nucleus and the nucleus of the solitary tract were densest in the lateral aspect of the nucleus paragigantocellularis (corresponding to the rostroventrolateral reticular nucleus), while fibers from the periaqueductal gray were more medially located. Previous studies have defined inputs to the rostral ventrolateral medulla from the cochlear nucleus as well as from the colliculi. In the present study, deposits of wheat germ agglutinin-conjugated horseradish peroxidase or Phaseolus vulgaris-leucoagglutinin into the cochlear nucleus or the superior colliculus yielded only sparse anterograde labeling in the nucleus paragigantocellularis, but heavily labeled adjacent areas. The inferior collicular injections yielded strong but restricted anterograde labeling in the rostromedial paragigantocellularis, medial to the facial nucleus. These results indicate that the paragigantocellularis area receives inputs from diverse brain structures. Neurons in the nucleus paragigantocellularis afferent to the locus coeruleus, being distributed throughout this region, may provide a channel where several types of information are integrated and transmitted to the extensive locus coeruleus noradrenergic efferent network...

Putative nociceptive modulating neurons in the rostral ventromedial medulla of the rat: firing of on- and off-cells is related to nociceptive responsiveness

In the unstimulated, lightly anesthetized rat, both on- and off-cells exhibit alternating periods of silence and activity lasting from several seconds to a few minutes. In the preceding paper, we showed that the active periods of all cells of the same class are always in phase, whereas the firing of cells of different classes is invariably out of phase. Thus, the pattern of firing of any single on- or off-cell provides a useful indication of the excitability of all on- and off-cells in the rostral ventromedial medulla (RVM). In this study, we measured the latency of the tail flick response (TF) at set intervals while recording from TF-related neurons in RVM, and were able to demonstrate a significant relationship between the spontaneous firing of both on- and off-cells and the latency of the TF response. If noxious heat is applied at a time when an off-cell is spontaneously active (or an on-cell is silent), the TF latency is longer than if the TF trial falls during a period in which the off-cell is silent (or the on-cell is active). This correlation between on- and off-cell firing and changes in TF latency is consistent with a nociceptive modulatory role for either or both cell classes. These findings support the hypothesis that off-cells inhibit and on-cells facilitate spinal nociceptive transmission and reflexes.

Morphine increases 5-HT metabolism in the nucleus raphe magnus: an in vivo study in freely moving rats using 5-hydroxyindole electrochemical detection

The purpose of this study was to evaluate in freely moving animals the effect of morphine on the 5-hydroxyindole oxidation current recorded in the nucleus raphe magnus (NRM) which is the origin of serotonergic control systems modulating the transmission of noxious inputs at the spinal level. A current recorded at 270-290 mV (peak 3), characteristic of 5-hydroxyindoleacetic acid (5-HIAA), was measured with treated multi-fiber carbon electrodes, using differential pulse (DPV) or differential normal pulse (DNPV) voltammetry. In control rats the amplitude of the peak remains constant for many hours. Morphine (10 mg/kg i.p.) caused a very significant increase which plateaued between 60 and 80 min (mean increase: 142 +/- 7% of control values); recovery was complete by about 3 h. Simultaneous injection of naloxone (1 mg/kg i.p.) completely abolished the effect of morphine. The peak 3 augmentation was still observed (151 +/- 5%) in rats pretreated with the xanthine oxidase inhibitor, allopurinol (12 mg/kg i.p.), but did not occur when animals were given an anaesthetic dose (450 mg/kg i.p.) of chloral hydrate. It is concluded that morphine clearly increases the metabolism of serotonin (5-HT) in the NRM, and one could speculate that the increase in 5-HIAA results from 5-HT release. Such a release could be due either to 5-HT terminals originating in the periaqueductal gray, or to somato-dendritic mechanisms. Thus the question remains as to the relationship between the activation of 5-HT metabolism in the NRM and previous neurochemical evidence for morphine-induced augmentation of 5-HT metabolism within the terminal area of serotonergic raphe-spinal pathways.

Two physiologically distinct populations of neurons in the ventrolateral medulla innervate the locus coeruleus

Recent anatomic studies indicate that the nucleus paragigantocellularis (PGi), located in the rostral ventrolateral medulla, strongly innervates the locus coeruleus (LC) while no such input derives from the more caudally located lateral reticular nucleus (LRN). In the present study, focal electrical stimulation of the LC was used to antidromically activate neurons in the ventrolateral medulla. A substantial number of PGi neurons were antidromically driven from the ipsilateral LC, while antidromic activation was virtually absent in LRN. Furthermore, several physiologic properties of antidromically driven cells in PGi define two populations within this group of neurons afferent to LC. These findings provide physiologic confirmation of an anatomically identified input to LC.

The brain nucleus locus coeruleus: restricted afferent control of a broad efferent network

Dense, focal injections of wheat germ agglutinin conjugated-horseradish peroxidase in the locus coeruleus of rats labeled afferent neurons in unexpectedly few brain regions. Major inputs emanate from only two nuclei--the paragigantocellularis and the prepositus hypoglossi, both in the rostral medulla. The dorsal cap of the paraventricular hypothalamic nucleus and the spinal intermediate gray are possible minor afferents to locus coeruleus. Other areas reported to project to locus coeruleus (for example, amygdala, nucleus tractus solitarius, and spinal dorsal horn) did not exhibit consistent retrograde labeling. Anterograde tracing and electrophysiologic experiments confirmed the absence of input to locus coeruleus from these areas, which instead terminate in targets adjacent to locus coeruleus. These findings redefine the anatomic organization of the locus coeruleus, and have implications for hypotheses concerning the functions of this noradrenergic brain nucleus.

Noxious stimuli and Met-enkephalin release from nucleus reticularis gigantocellularis

The nucleus reticularis gigantocellularis of the rat medulla oblongata was perfused in situ, and effects of noxious stimuli on the release of immunoreactive Met-enkephalin were examined. Formalin-induced and thermal but not mechanical stimuli increased the "tonic" release of immunoreactive Met-enkephalin from this nucleus. No "phasic" increase was observed following the three forms of stimulation. A topical application of dibucaine abolished the formalin-induced increase in the release of immunoreactive Met-enkephalin. Therefore, the possibility that persistent noxious stimuli may activate the Met-enkephalin-containing fibers in the nucleus reticularis gigantocellularis has to be given consideration.

The neural basis of footshock analgesia: the effect of periaqueductal gray lesions and decerebration

Previous studies have demonstrated that brief front paw shock and brief hind paw shock produce potent opiate and non-opiate analgesia, respectively. Front paw footshock-induced analgesia (FSIA) and hind paw FSIA are similar in that each is mediated by a medullospinal pathway. A question which arises is whether these opiate and non-opiate descending pathways are activated in direct response to afferent information from the spinal cord or whether indirect activation via more rostral centers is required. The first experiment examined the effect of lesions of the rostral periaqueductal gray (PAG) and caudal PAG on front paw (opiate) FSIA and hind paw (non-opiate) FSIA. In no case did PAG lesions markedly reduce the magnitude of these pain inhibitory states. Since this result raised the possibility that rostral centers may not have any major involvement in the production of these phenomena, the second experiment examined the effect of decerebration on front paw FSIA and hind paw FSIA. Decerebration effect on hind paw FSIA and, at most, produced only a very modest decrease in front paw FSIA. The fact that potent and prolonged analgesia can still be elicited after decerebration clearly demonstrates that limbic, cortical, thalamic, and rostral midbrain structures are not critical to the production of these pain inhibitory effects. Thus this work provides the first demonstration of opiate and non-opiate analgesia systems within the caudal brainstem and spinal cord which can be activated by environmental stimuli.

The neural basis of footshock analgesia: the role of specific ventral medullary nuclei

Previous studies have demonstrated that brief front paw shock produces opiate analgesia while brief hind paw shock produces non-opiate analgesia in rats. Additionally, front paw shock and hind paw shock can produce an opiate-mediated classically conditioned analgesia; that is, when shock is delivered to an animal, environmental cues become associated with this stimulus such that these cues become capable of producing potent opiate analgesia in the absence of shock. Investigations of the neural bases of these phenomena have revealed that front paw shock and classical conditioning lead to activation of supraspinal sites which mediate analgesia via descending pathways lying solely within the dorsolateral funiculus (DLF) of the spinal cord. Hind paw footshock induced analgesia (FSIA) is also mediated by a descending DLF pathway but is unlike front paw FSIA or classically conditioned analgesia in that it involves intraspinal pathways as well. The aim of the present series of experiments was to identify the supraspinal origin of the centrifugal DLF pathway mediating front paw (opiate) FSIA, hind paw (non-opiate) FSIA, and classically conditioned (opiate) analgesia. These studies examined the effect of electrolytic lesions of the nucleus raphe magnus (NRM), nucleus reticularis paragigantocellularis (PGC), and combined lesions of these two areas (nucleus raphe alatus, NRA) on these environmentally-induced analgesias. The results of this work indicate that the NRA is the origin of the spinal cord DLF pathway mediating front paw (opiate) FSIA and classically conditioned (opiate) analgesia. Hind paw (non-opiate) FSIA is also mediated, in part, by the NRA but must involve another, yet unidentified, brainstem site(s) as well.

Microinjection of morphine into nucleus reticularis paragigantocellularis of the rat suppresses spontaneous activity of nucleus raphe magnus neurons

Microinjection of morphine into nucleus reticularis paragigantocellularis of anesthetized rats had differential effects on spontaneous firing of neurons in nucleus raphe magnus (NRM) depending upon the dose of morphine administered. Microinjection of 1 microgram of morphine, a dose which has reliable antinociceptive effects in awake animals, had predominantly suppressive effects on NRM spontaneous firing. Microinjection of 0.35 micrograms of morphine, a dose which has small and unreliable antinociceptive effects in awake animals, had little effect on the activity of NRM cells.

Endogenous opiates: 1981

This paper is the fourth of an annual series reviewing the research concerning the endogenous opiate peptides. This installment covers only work published during 1981 and attempts to provide a comprehensive, but not exhaustive, survey of the area. Previous papers in the series have dealt with research done before 1981. Topics concerning endogenous opiates reviewed here include a delineation of their receptors, their distribution, their precursors and degradation, behavioral effects resulting from their administration, their possible involvement in physiological responses, and their interactions with other peptides and hormones. Due to the burgeoning literature in this field, the comprehensive nature of this review in the future will be limited to considerations of behavioral phenomena related to the endogenous opiates.