Vasopressin and oxytocin in the rat spinal cord: distribution and origins in comparison to [Met]enkephalin, dynorphin and related opioids and their irresponsiveness to stimuli modulating neurohypophyseal secretion

Sex Difference of Angiotensin IV-, LVV-Hemorphin 7-, and Oxytocin-Induced Antiallodynia at the Spinal Level in Mice With Neuropathic Pain

BACKGROUND

We demonstrated previously that angiotensin IV (Ang IV) and LVV-hemorphin 7 (LVV-H7) act through the blockade of insulin-regulated aminopeptidase to decrease oxytocin degradation, thereby causing antihyperalgesia at the spinal level in rats. We determined that intrathecal oxytocin can induce significant antihyperalgesia in male rats with inflammation but not in female rats. Thus, we speculate that Ang IV, LVV-H7, and oxytocin can induce antiallodynia, which could be of great therapeutic potential. Because the antihyperalgesia by using these peptides was with sex difference, their possible antiallodynia was examined in male and female mice for comparison. We investigated whether Ang IV, LVV-H7, and oxytocin produce antiallodynia at the spinal level in mice and whether this antiallodynia differs between the sexes.

METHODS

Partial sciatic nerve ligation surgery was performed on adult male and female C57BL/6 mice from the same litter (25-30 g). The effects of intrathecal injections of Ang IV (25.8 nmol), LVV-H7 (27.2 nmol), and oxytocin (0.125 or 1.25 nmol) were assessed through the von Frey test 3 days after partial sciatic nerve ligation.

RESULTS

Intrathecal injection of Ang IV, LVV-H7, and oxytocin all produced a potent antiallodynia in male mice. However, these antiallodynia effects were either extremely weak or absent in female mice at the same dose.

CONCLUSIONS

Intrathecal Ang IV, LVV-H7, and oxytocin can all cause significant antiallodynia in male mice. The Ang IV-, LVV-H7-, and oxytocin-induced antiallodynia effects differed between the sexes at the spinal level in mice.

Oxytocin in the periaqueductal gray participates in pain modulation in the rat by influencing endogenous opiate peptides

Periaqueductal gray (PAG) plays a very important role in pain modulation through endogenous opiate peptides including leucine-enkephalin (L-Ek), methionine-enkephalin (M-Ek), β-endorphin (β-Ep) and dynorphin A(1-13) (DynA(1-13)). Our pervious study has demonstrated that intra-PAG injection of oxytocin (OXT) increases the pain threshold, and local administration of OXT receptor antagonist decreases the pain threshold, in which the antinociceptive role of OXT can be reversed by pre-PAG administration of OXT receptor antagonist. The experiment was designed to investigate the effect of OXT on endogenous opiate peptides in the rat PAG during the pain process. The results showed that (1) the concentrations of OXT, L-Ek, M-Ek and β-Ep, not DynA(1-13) in the PAG perfusion liquid were increased after the pain stimulation; (2) the concentrations of L-Ek, M-Ek and β-Ep, not DynA(1-13) in the PAG perfusion liquid were decreased by the OXT receptor antagonist; (3) the increased pain threshold induced by the OXT was attenuated by naloxone, an opiate receptor antagonist; and (4) the concentrations of L-Ek, M-Ek and β-Ep, not DynA(1-13) in the PAG perfusion liquid were increased by exogenous OXT administration. The data suggested that OXT in the PAG could influence the L-Ek, M-Ek and β-Ep rather than DynA(1-13) to participate in pain modulation, i.e. OXT in the PAG participate in pain modulation by influencing the L-Ek, M-Ek and β-Ep rather than DynA(1-13).

REVIEW: Oxytocin: Crossing the bridge between basic science and pharmacotherapy

Is oxytocin the hormone of happiness? Probably not. However, this small nine amino acid peptide is involved in a wide variety of physiological and pathological functions such as sexual activity, penile erection, ejaculation, pregnancy, uterus contraction, milk ejection, maternal behavior, osteoporosis, diabetes, cancer, social bonding, and stress, which makes oxytocin and its receptor potential candidates as targets for drug therapy. In this review, we address the issues of drug design and specificity and focus our discussion on recent findings on oxytocin and its heterotrimeric G protein‐coupled receptor OTR. In this regard, we will highlight the following topics: (i) the role of oxytocin in behavior and affectivity, (ii) the relationship between oxytocin and stress with emphasis on the hypothalamo–pituitary–adrenal axis, (iii) the involvement of oxytocin in pain regulation and nociception, (iv) the specific action mechanisms of oxytocin on intracellular Ca²⁺ in the hypothalamo neurohypophysial system (HNS) cell bodies, (v) newly generated transgenic rats tagged by a visible fluorescent protein to study the physiology of vasopressin and oxytocin, and (vi) the action of the neurohypophysial hormone outside the central nervous system, including the myometrium, heart and peripheral nervous system. As a short nine amino acid peptide, closely related to its partner peptide vasopressin, oxytocin appears to be ideal for the design of agonists and antagonists of its receptor. In addition, not only the hormone itself and its binding to OTR, but also its synthesis, storage and release can be endogenously and exogenously regulated to counteract pathophysiological states. Understanding the fundamental physiopharmacology of the effects of oxytocin is an important and necessary approach for developing a potential pharmacotherapy.

Effects of centrally administered vasopressin on orofacial pain perception in rats

Vasopressin (AVP) appears in the cerebrospinal fluid and plays an important role in nociceptive modulation in the central nervous system. The effect of increased concentration of AVP in the cerebrospinal fluid on the excitability of the hypoglossal nerve nucleus was investigated. The experiments were carried out on rats under chloralose anesthesia. Amplitudes of the retractory evoked tongue jerks (ETJ) of the outstretched tongue during the perfusion of cerebral ventricles with solutions containing AVP or its antagonists and also opioid and serotonin antagonists were recorded. Perfusion of the ventricles with AVP in 100 microM concentration suppressed the ETJ amplitude to 66 +/- 3.83%, and in 200 microM concentration, to 53 +/- 3.18% of the control. V1 vasopressin receptor antagonist, d(CH2)5,Tyr(Me)AVP, blocked the suppressive effect caused by cerebral ventricle perfusion with AVP from 64 +/- 4.11% to 83 +/- 1.58%, whereas V2 vasopressin receptor antagonist, d(CH2)5[Ile2, Ile4]AVP, did not block the antinociceptive effect of AVP. Analgesic effect of AVP was also inhibited by opioid and serotonin receptor antagonists, naloxone and methysergide, respectively. Naloxone blocked the suppressive effect of 100 microM AVP from 64 +/- 5.63% to 92 +/- 3.70% and methysergide from 65 +/- 3.62% to 80 +/- 2.72% of the control. The results indicate that exogenous AVP plays an antinociceptive role in the brain of rats penetrating the lining of the cerebral ventricles into the cerebrospinal fluid and exerting a modulating effect on the tongue motor center situated near III and IV cerebral ventricle. V1 vasopressin receptor, but not V2 vasopressin receptor, is involved in this activity in the CNS. The antinociception of AVP seems to be mediated by opioid and serotonergic pathways.

Effect of intrathecal and intravenous administration of oxytocin on amplitude of the reflex-evoked muscle action potential after electrical stimulation of the tooth pulp in anesthetized dogs

OBJECTIVE

To determine whether intrathecal (IT) or IV administration of oxytocin will diminish amplitude of the reflex-evoked muscle action potential (REMP) in the digastricus muscle during electrical stimulation of the tooth pulp in anesthetized dogs, thus suggesting an analgesic effect for oxytocin.

ANIMALS

6 male Beagles that were 2 to 6 years old.

PROCEDURE

Dogs were used in a crossover design with at least a 5-day washout period between treatments. Each dog received morphine, saline (0.9% NaCl) solution, and oxytocin by both the IT and IV routes of administration. Noninvasive dental dolorimetry was used to assess changes in pain threshold following administration of treatments. Effectiveness of analgesia was determined on the basis of change in REMP amplitude in the digastricus muscle.

RESULTS

Morphine administered IV significantly inhibited REMP amplitude, compared with IV administration of saline solution or oxytocin. There was not a significant change in REMP amplitude between saline solution and oxytocin administered IV. Intrathecal administration of morphine significantly inhibited REMP amplitude, compared with IT administration of saline solution or oxytocin. Intrathecal administration of oxytocin significantly increased REMP amplitude, compared with IT administration of saline solution or morphine.

CONCLUSIONS AND CLINICAL RELEVANCE

Although IV administration of oxytocin did not have an effect on REMP amplitude, compared with IV administration of saline solution, IT administration of oxytocin had the opposite effect of morphine and increased REMP amplitude of the digastricus muscle. These data do not support the use of oxytocin as an analgesic agent in dogs.

Descending control of pain

Upon receipt in the dorsal horn (DH) of the spinal cord, nociceptive (pain-signalling) information from the viscera, skin and other organs is subject to extensive processing by a diversity of mechanisms, certain of which enhance, and certain of which inhibit, its transfer to higher centres. In this regard, a network of descending pathways projecting from cerebral structures to the DH plays a complex and crucial role. Specific centrifugal pathways either suppress (descending inhibition) or potentiate (descending facilitation) passage of nociceptive messages to the brain. Engagement of descending inhibition by the opioid analgesic, morphine, fulfils an important role in its pain-relieving properties, while induction of analgesia by the adrenergic agonist, clonidine, reflects actions at alpha(2)-adrenoceptors (alpha(2)-ARs) in the DH normally recruited by descending pathways. However, opioids and adrenergic agents exploit but a tiny fraction of the vast panoply of mechanisms now known to be involved in the induction and/or expression of descending controls. For example, no drug interfering with descending facilitation is currently available for clinical use. The present review focuses on: (1) the organisation of descending pathways and their pathophysiological significance; (2) the role of individual transmitters and specific receptor types in the modulation and expression of mechanisms of descending inhibition and facilitation and (3) the advantages and limitations of established and innovative analgesic strategies which act by manipulation of descending controls. Knowledge of descending pathways has increased exponentially in recent years, so this is an opportune moment to survey their operation and therapeutic relevance to the improved management of pain.

Microinjection of arginine vasopressin into the central nucleus of amygdala suppressed nociceptive jaw opening reflex in freely moving rats

This study was performed to examine the antinociceptive effect after microinjection of arginine vasopressin (AVP) into the central nucleus of amygdala. We recorded the jaw opening reflex in freely moving rats. After injection of 0.2 or 0.4 nM AVP into the central nucleus of amygdala, digastric electromyogram (dEMG) was suppressed to 55 +/- 5% or 88 +/- 3 of the control. Artificial cerebrospinal fluid had no effects on the basal dEMG activity. V(1) vasopressin receptor antagonist blocked the suppressive effect produced by microinjection of 0.4 nM AVP from 53 +/- 3 to 81 +/- 3% of the control. However, V(2) vasopressin receptor antagonist did not affect changes in dEMG. We observed dEMG activity after intracerebroventricular injection of naloxone, methysergide, or phentolamine. All drugs did not affect the basal dEMG activity at our dose. Naloxone blocked the suppressive effect of 0.4 nM AVP from 42 +/- 4 to 79 +/- 5% of the control. Methysergide also inhibited the suppression of dEMG from 44 +/- 3 to 83 +/- 6% of the control. However, phentolamine, an alpha-adrenergic receptor antagonist, did not affect the suppression of dEMG. These results indicate AVP in the central nucleus of amygdala has potent analgesic effects in the orofacial area. The antinociception of central AVP seems to be mediated by opioid and serotonergic pathways.

Neuropeptide expression in rat paraventricular hypothalamic neurons that project to the spinal cord

The paraventricular hypothalamic nucleus (PVH) exerts many of its regulatory functions through projections to spinal cord neurons that control autonomic and sensory functions. By using in situ hybridization histochemistry in combination with retrograde tract tracing, we analyzed the peptide expression among neurons in the rat PVH that send axons to the spinal cord. Projection neurons were labeled by immunohistochemical detection of retrogradely transported cholera toxin subunit B, and radiolabeled long riboprobes were used to identify neurons containing dynorphin, enkephalin, or oxytocin mRNA. Of the spinally projecting neurons in the PVH, approximately 40% expressed dynorphin mRNA, 40% expressed oxytocin mRNA, and 20% expressed enkephalin mRNA. Taken together with our previous findings on the distribution of vasopressin-expressing neurons in the PVH (Hallbeck and Blomqvist [1999] J. Comp. Neurol. 411:201-211), the results demonstrated that the different PVH subdivisions display distinct peptide expression patterns among the spinal cord-projecting neurons. Thus, the lateral parvocellular subdivision contained large numbers of spinal cord-projecting neurons that express any of the four investigated peptides, whereas the ventral part of the medial parvocellular subdivision displayed a strong preponderance for dynorphin- and vasopressin-expressing cells. The dorsal parvocellular subdivision almost exclusively contained dynorphin- and oxytocin-expressing spinal cord-projecting neurons. This parcellation of the peptide-expressing neurons suggested a functional diversity among the spinal cord-projecting subdivisions of the PVH that provide an anatomic basis for its various and distinct influences on autonomic and sensory processing at the spinal level.

Central neural regulation of penile erection

Penile erection is caused by a change of the activity of efferent autonomic pathways to the erectile tissues and of somatic pathways to the perineal striated muscles. The spinal cord contains the cell bodies of autonomic and somatic motoneurons that innervate the peripheral targets. The sympathetic outflow is mainly antierectile, the sacral parasympathetic outflow is proerectile, and the pudendal outflow, through contraction of the perineal striated muscles, enhances an erection already present. The shift from flaccidity to erection suggests relations among these neuronal populations in response to a variety of informations. Spinal neurons controlling erection are activated by information from peripheral and supraspinal origin. Both peripheral and supraspinal information is capable of eliciting erection, or modulating or inhibiting an erection already present. One can hypothesize a spinal network consisting of primary afferents from the genitals, spinal interneurons and sympathetic, parasympathetic and somatic nuclei. This system is capable of integrating information from the periphery and eliciting reflexive erections. The same spinal network, eventually including different populations of spinal interneurons, would be the recipient of supraspinal information. Premotor neurons that project directly onto spinal sympathetic, parasympathetic or somatic motoneurons, are present in the medulla, pons and diencephalon. Several of these premotor neurons may in turn be activated by sensory information from the genitals. Aminergic and peptidergic descending pathways in the vicinity of spinal neurons, exert complex effects on the spinal network that control penile erection. This is caused by the potential interaction of a great variety of receptors and receptor subtypes present in the spinal cord. Brainstem and hypothalamic nuclei (among the latter, the paraventricular nucleus and the medial preoptic area) may not necessarily reach spinal neurons directly. However they are prone to regulate penile erection in more integrated and coordinated responses of the body, such as those occurring during sexual behavior. Finally, the central and spinal role of regulatory peptides (oxytocin, melanocortins, endorphins) has only recently been elucidated.

Central administration of cocaine-amphetamine-regulated transcript activates hypothalamic neuroendocrine neurons in the rat

We have recently shown that intracerebroventricular (i.c.v.) administration of the hypothalamic neuropeptide cocaine-amphetamine-regulated transcript (CART) inhibits food intake and induces the expression of c-fos in several nuclei involved in the regulation of food intake. A high number of CART-induced c-Fos-positive nuclei in the paraventricular nucleus of the hypothalamus prompted us to examine the effect of i.c.v. recombinant CART-(42-89) on activation of CRH-, oxytocin-, and vasopressin-synthesizing neuroendocrine cells in the paraventricular nucleus (PVN). In addition, plasma levels of glucose were examined after central administration of CART-(42-89). Seventy-six male Wistar rats were fitted with i.c.v. cannulas and singly housed under 12-h light, 12-h dark conditions. One week postsurgery the animals were injected i.c.v. in the morning with 0.5 microg recombinant CART-(42-89) or saline. Trunk blood was collected by decapitation at 0 (baseline), 10, 20, 40, 60, 120, or 240 min. CART caused a strong increase in circulating corticosterone that was significantly different from saline at 20, 40, 60, and 120 min postinjection (P<0.05). Furthermore, CART caused a transient rise in plasma oxytocin levels (P<0.05 at 10 and 20 min postinjection), whereas plasma vasopressin levels were unaffected by i.c.v. CART. Animals injected i.c.v. with CART showed a rise in blood glucose levels 10 min postinjection (P<0.05). To examine whether the stimulatory effect of i.c.v. CART on corticosterone and oxytocin secretion is caused by activation of paraventricular nucleus/supraoptic nucleus (PVN/SON) neuroendocrine neurons, we used c-Fos as a marker of neuronal activity. Animals injected with CART showed a strong increase in c-Fos-immunoreactive nuclei in the PVN. Double immunohistochemistry revealed that a high (89+/-0.4%) number of CRH-immunoreactive neurons in the PVN contained c-Fos after CART i.c.v.. c-Fos expression was also observed in oxytocinergic cells (in both magnocellular and parvicellular PVN neurons as well as in the supraoptic nuclei) 120 min after CART administration, whereas none of the vasopressinergic neurons contained c-Fos. Triple immunofluorescence microscopy revealed that CART-immunoreactive fibers closely apposed c-Fos-positive CRH neurons, suggestive of a direct action of CART on PVN CRH neurons. In summary, i.c.v. CART activates central CRH neurons as well as both magnocellular (presumably neurohypophysial) and parvicellular (presumably descending) oxytocinergic neurons of the PVN. The effect of CART on CRH neurons most likely leads to corticosterone secretion from the adrenal gland, which may contribute to the inhibitory effects of CART on feeding behavior.

Vasopressin acting at V1-type receptors produces membrane depolarization in neonatal rat spinal lateral column neurons

Vasopressin-immunoreactive fibers have been visualized in the area of spinal lateral horn cells, including spinal sympathetic preganglionic neurons. The presence and nature of vasopressin receptors on neurons in this area were addressed using whole-cell patch-clamp techniques in transverse spinal cord slice preparations from neonatal rat. Bath applications of Arg8-vasopressin (VP) induced a slow-onset membrane depolarization accompanied by spike discharges and membrane oscillations. In voltage-clamp, applications of VP induced a reversible, tetrodotoxin-resistant and dose-dependent inward current in 90% of tested cells. This effect was blocked by a V1 receptor antagonist [D-(CH2)5 Tyr (Me)-VP], whereas a V2 receptor agonist [desamino-(D-Arg8)-vasopressin] was ineffective. Furthermore the applications of oxytocin produced significantly smaller depolarizations when compared with VP suggesting that, at least in the neonatal lateral horn cells, vasopressin rather than oxytocin is more effective ligand. Both the amplitude and duration of the VP effect were enhanced after intracellular dialysis with GTP-gamma-S, a non-hydrolyzable GTP analogue, whereas the inward current was significantly reduced after intracellular dialysis with GDP-beta-S, a stable analogue of GDP that competitively inhibits G-proteins. The observation that the VP-induced net inward current reversed at a potential close to the equilibrium for potassium ions and was associated with a decrease in membrane conductance in a majority of tested cells suggest mediation through closure of a leak potassium conductance. These data indicate that SPNs and other lateral horn cells possess functional G-protein-coupled V1-type vasopressin receptors that, in adult spinal cord, may contribute to CNS regulation of autonomic nervous system function.

Vasopressin's depolarizing action on neonatal rat spinal lateral horn neurons may involve multiple conductances

Vasopressin-immunoreactive fibers have been visualized in the area of spinal lateral horn cells, including spinal sympathetic preganglionic neurons (SPNs). The presence and nature of vasopressin receptors on 125 neurons in this area were addressed using whole-cell patch-clamp techniques in transverse spinal cord slice preparations from neonatal rat (11-21 days). Local pressure applications of Arg-vasopressin (AVP, 1 microM) induced a slow-onset membrane depolarization accompanied by spike discharges and membrane oscillations. In voltage-clamp, applications of AVP (10 nM-1 microM) induced a reversible, tetrodotoxin-resistant and dose-dependent inward current in 90% of tested cells. This effect was blocked by a V1 receptor antagonist [D-(CH2)5 Tyr (Me)-AVP], whereas a V2 receptor agonist [desamino-(D-Arg8)-vasopressin] was ineffective. Both the amplitude and duration of the AVP effect were significantly modified after intracellular dialysis of non-hydrolysable G-protein modulators. I-V relationships, examined in 75 cells, suggested two conductances. In 36 cells the net AVP current reversed approximately -102 mV, was associated with a decrease in membrane conductance and yielded linear I-V plots, suggesting mediation through closure of a resting potassium conductance. In a further 26 cells the I-V lines remained almost parallel in the voltage range used in this study (-130 to -40 mV), while the membrane conductance was decreased in a majority of these cells. In the remaining 13 cells the net AVP current was estimated to reverse approximately -30 mV and was associated with a small increase in membrane conductance, suggesting mediation through opening of a nonselective cationic conductance. These data indicate that the majority of SPNs and other lateral horn cells possess functional G-protein-coupled V1-type vasopressin receptors in the neonatal spinal cord. In the adult spinal cord, some of these receptors are likely to participate in CNS regulation of autonomic nervous system function.

CNS location of uterine-related neurons revealed by trans-synaptic tracing with pseudorabies virus and their relation to estrogen receptor-immunoreactive neurons

Retrograde, transneuronal tracing with Bartha's strain of pseudorabies virus was used in rats to identify spinal cord, brainstem and hypothalamic loci of uterine-related neurons that could function in the regulation of uterine activity. Based on the premise that estrogen might influence such uterine-related neurons, the existence of estrogen receptors in neurons in these same loci was examined. Viral injections were made into the uterine cervix, body and cervical end of the uterine horns, and the rats allowed to survive for four to six days. After four days, mainly the spinal cord, medulla and pons contained virus-infected neurons. After longer survival times, progressively higher levels of the neuraxis contained viral-labeled neurons, so that by six days hypothalamic uterine-related neurons were identified. First-order virus-infected neurons were visualized by immunohistochemistry in the pelvic paracervical parasympathetic ganglia and in inferior mesenteric sympathetic ganglia. Preganglionic and putative interneurons were labeled in the lumbosacral spinal cord and thoracic spinal cord mainly in the lateral horn area (sacral parasympathetic nucleus and intermediolateral nucleus), lateral aspect of the dorsal horn, intermediate gray, lamina X and dorsal gray commissural area. In the brainstem, labeling was most evident and consistent in the nucleus tractus solitarius, ventrolateral medulla, raphe magnus and pallidus nuclei, parapyramidal area, A5 cell group, Barrington's nucleus of the pons and periaqueductal gray of the midbrain. In the hypothalamus, virus-infected neurons were most marked in the paraventricular nucleus, with fewer in the medial preoptic area and ventromedial hypothalamic nucleus. Estrogen receptor-immunoreactive neurons were most often present among the virus-labeled uterine-related neurons of the spinal cord, nucleus tractus solitarius, ventrolateral medulla, periaqueductal gray, medial preoptic area and ventromedial hypothalamic nucleus. These results identify a multisynaptic pathway of neurons whose eventual output is involved in uterine functions, whose distribution is similar to that revealed by pseudorabies virus tracing from other visceral organs, and which are often mixed among estrogen-responsive neurons.

Direct link from the suprachiasmatic nucleus to hypothalamic neurons projecting to the spinal cord: a combined tracing study using cholera toxin subunit B and Phaseolus vulgaris-leucoagglutinin

By combining retrograde and anterograde tracing, evidence for a bineuronal connection from the suprachiasmatic nucleus (SCN) to the intermediolateral cell column in the spinal cord (IML) was obtained. The retrograde tracer cholera toxin subunit B (ChB) was pressure-injected into the spinal cord and the anterograde tracer Phaseolus vulgaris-leucoagglutinin (PHA-L) was iontophoretically injected into the SCN. The two tracers were visualized simultaneously by a double immunohistochemical procedure. In the hypothalamus, ChB injections gave rise to retrogradely labeled cell bodies in the paraventricular nucleus, retrochiasmatic area, perifornical region, lateral hypothalamic area, and the posterior hypothalamic area. The SCN were found to project to all of these areas. Furthermore, spinal-projecting neurons were found in the brain stem, but no efferents from the SCN were observed to innervate these areas. In the most sparsely innervated areas, the lateral hypothalamic area and the perifornical region, only occasionally a PHA-L fiber in close apposition to a ChB-ir cell body was observed. This was also the case in the retrochiasmatic area and posterior hypothalamic area, although these areas received a moderate number-immunoreactive (ir) PHA-L-ir fibers. The highest number of closely apposed PHA-L-ir fibers and ChB-ir cell bodies was observed in the dorsal parvicellular and in the ventral division of the medial parvicellular paraventricular nucleus, which were also the areas receiving the densest input from the SCN. By anterograde tracing from the paraventricular nucleus of the hypothalamus, the exact topography of the terminal field formed by descending paraventricular neurons was established. Thus, it was confirmed that the paraventricular nucleus of the hypothalamus predominantly innervates the IML. The present study suggests the existence of a bineuronal link between the SCN and the IML, possibly involved in transmission of circadian signals from the endogenous clock to the pineal gland and other organs receiving sympathetic afferents.

Identification of hypothalamic vasopressin and oxytocin neurons activated during the exercise pressor reflex in cats

Blood pressure and heart rate reflexly increase during static muscle contraction in anesthetized cats. Previous studies have demonstrated that vasopressin (AVP) and oxytocin (OT) may act as neuromodulators to regulate cardiovascular responses elicited by contraction of skeletal muscle. In this study, we tested the hypothesis that neurons containing AVP and OT in the paraventricular nucleus (PVN) and the supraoptic nucleus (SON) of the hypothalamus are activated during static muscle contraction. A laminectomy was performed to expose the spinal cord and the peripheral cut ends of L7 and S1 ventral roots were stimulated electrically to induce muscle contraction. Hypothalamic neurons activated during the muscle contraction were identified by Fos-like immunoreactivity (FLI). Static muscle contraction significantly increased FLI in the PVN and SON, compared with sham-operated cats. Double-staining of neurons in the PVN for AVP and OT showed that 22 +/- 4% of the AVP and 26 +/- 3% of the OT neurons in the PVN expressed FLI. In contrast, only 4 +/- 1% of the AVP and 3 +/- 1% of the OT neurons in the PVN were labeled with FLI in sham-operated animals. These results indicate that neurons in the PVN and SON of the hypothalamus were activated during static muscle contraction. Furthermore, as FLI was present in AVP and OT neurons, this suggests these neurons may constitute a part of the neural pathway involved in cardiovascular regulation during static muscle contraction.

Spinal control of penile erection

Smooth muscle relaxation of penile arteries, the corpus cavernosum, and the corpus spongiosum, leading to penile erection, results from parasympathetic neural pathway activation and, likely, simultaneous inhibition of sympathetic outflow. Proerectile parasympathetic outflow is reflexively activated by sensory information of peripheral origin, conveyed by the dorsal penile nerve, and reflexive erections are supported by an intraspinal circuitry. Supraspinal influences modulate the reflex. Information integrated at or originating from supraspinal structures may also elicit penile erection. Several neurotransmitters are involved in either the modulation of the spinal reflex or the mediation of supraspinal influences. Spinal cord injury differently alters reflexive penile erection or erection from a central origin, depending on the neurologic level of injury.

Spinal release of immunoreactive dynorphin A(1-8) with the development of peripheral inflammation in the rat

Microprobes bearing immobilised antibodies to dynorphin A(1-8) were used to study the basal and evoked release of this prodynorphin derived peptide in the spinal cord of urethane anaesthetised normal rats and those with a peripheral inflammation. In the absence of any active peripheral stimulus the antibody microprobes detected immunoreactive (ir)-dynorphin A(1-8) in two areas (lamina I and laminae IV-V) in the dorsal horn of the spinal cord of normal rats. With the development of unilateral ankle inflammation over 3 to 5 days following subcutaneous injections of Freund's complete adjuvant, a basal presence of ir-dynorphin A(1-8) was found in both the dorsal and ventral horn regions of both sides of the spinal cord. Lateral compression of the ankles of the normal animals did not release ir-dynorphin A(1-8) during the period of stimulation, but this neuropeptide was detected in increased amounts in the ventral horn following the stimulus. By contrast, compression of inflamed ankles produced elevated levels of ir-dynorphin A(1-8) during the period of stimulus application at three major sites in the ipsilateral spinal grey matter. The largest peak was in the deep dorsal horn/upper ventral horn (laminae VI-VII), with further sites of significant release in the mid dorsal horn (laminae II-V) and the lower ventral horn. The observation that ir-dynorphin A(1-8) is physiologically released in the ventral and deep dorsal in addition to the superficial dorsal horn of the rat suggests an involvement of dynorphins in several aspects of spinal function.

Autonomic areas of rat brain exhibit increased Fos-like immunoreactivity during opiate withdrawal in rats

We sought to identify the brain areas that might contribute to the increased autonomic activity seen during morphine withdrawal by mapping neuronal expression of c-fos protein (Fos) and Fos-related antigens. Rats were implanted with morphine pellets or placebo pellets over a 5 day regimen and injected on day 6 with either saline or naltrexone (100 mg/kg). After a standard PAP immunocytochemical protocol, Fos-like immunoreactivity (Fos-LIR) was observed in medullary nuclei including the NTS (nucleus of the solitary tract), caudal (CVL) and rostral ventrolateral medulla (RVL). Although some Fos-LIR was seen in these areas in control rats (either morphine-implanted, saline injected, or placebo-implanted, saline or naltrexone injected), a significantly higher number of Fos-LIR-positive cells in NTS, CVL and RVL were seen after morphine withdrawal. Large numbers of Fos-like immunoreactive cells were also seen in the A5 area, the parabrachial nuclei of the pons and the locus coeruleus. Increased Fos-LIR was also detected in the paraventricular nucleus of the hypothalamus and the amygdala of morphine withdrawn rats. The Fos-LIR was co-localized with tyrosine hydroxylase immunoreactivity in many of the cells in caudal and rostral ventrolateral medulla, A5 and locus coeruleus. These data support the conclusion that autonomic areas in brain and noradrenergic/adrenergic cells in these areas are activated during morphine withdrawal and may contribute to the autonomic symptoms of opiate withdrawal.

Characterization of intrathecal vasopressin-induced antinociception, scratching behavior, and motor suppression

Intrathecal (IT) administration of vasopressin produces antinociception, scratching behavior, and motor suppression. The present experiments characterized these effects with regards to the following: 1) VP receptor specificity, 2) possible involvement of endogenous opiates, 3) possible involvement of seizure activity, and 4) whether the antinociception is due to direct actions of VP at the spinal cord. These studies showed that IT administration of a V1-specific vasopressin antagonist completely blocked the antinociception, scratching behavior, and motor suppression produced by 25 ng IT vasopressin. Furthermore, IT administration of the vasopressin metabolite, [pGlu4,Cyt6]AVP(4-9), produced none of the effects produced by vasopressin. Systemic administration of the opiate antagonists naloxone (1 mg/kg IP) and naltrexone (10 mg/kg IP) had no significant effect on the antinociception produced by IT vasopressin, whereas naltrexone potentiated the scratching behavior. Neither the IT vasopressin-induced antinociception nor scratching behavior was affected by pretreatment with the anticonvulsant sodium valproate. In addition, IT vasopressin inhibited the tail flick reflex in rats with transected spinal cords, demonstrating direct spinal effects of vasopressin. In conclusion, IT administration of vasopressin produces antinociception, scratching behavior, and motor suppression via activation of VP-specific receptors in the spinal cord.

Unmyelinated primary afferent fiber stimulation depletes dynorphin A (1-8) immunoreactivity in rat ventral horn

The present study demonstrates many dynorphin (DYN)-immunoreactive fibers and presumed presynaptic terminals in rat lumbar ventral horn. The fibers and terminals seem to arise largely from DYN-containing intrinsic neurons in the dorsal horn. The majority of the presumed terminals closely surround a subpopulation of motoneurons that tend to be located in flexor motoneuron columns. Acute C fiber, but not A fiber, primary afferent stimulation depletes the ventral horn DYN immunostaining. We interpret these findings to indicate that the spinal DYN neurons are well positioned to serve both as modulators of nociceptive input and as interneurons in motor reflexes. We further hypothesize that the depletion of DYN-immunoreactivity that follows either acute C fiber stimulation or intense nociceptive stimuli may be the trigger for the upregulation in spinal cord DYN that occurs in models of chronic pain states.

Central analgesic mechanisms: a review of opioid receptor physiopharmacology and related antinociceptive systems

Clinical applications of these principles, based on the increased understanding of central analgetic mechanisms, are already being undertaken. Not only does the use of intrathecal and epidural opioids have the potential to decrease pain and related morbidity after surgical procedures, but there is at least one study that demonstrates a significant reduction in both major morbidity and mortality in high-risk surgical patients in whom epidural anesthesia and analgesia were used. These principles are also useful for the management of patients undergoing cardiac surgery. Currently, high-dose narcotic anesthesia is the technique of choice for such patients because of the greater hemodynamic stability this anesthetic technique provides. However, breakthrough hypertension and tachycardia still occur, and prolonged postoperative ventilation is a necessary consequence due to the high doses of narcotics that are required. In one study of patients undergoing coronary artery surgery, preoperative administration of clonidine, 5 micrograms/kg, orally, was demonstrated to decrease fentanyl requirements by 45% (110 to 61 micrograms/kg) while producing a similar degree of hemodynamic stability as seen with high-dose fentanyl. Extubation times were not compared, but the significantly lower dosage of fentanyl in the clonidine-treated group would be expected to lead to an earlier extubation. Whether similar potentiation of narcotic effects would be seen with dexmedetomidine, which may also prevent narcotic-induced rigidity, has not been determined, but the clinical application of such synergistic and complementary agents is another consequence of the greater understanding of central analgesic mechanisms, and augurs well for the future.

Spinal arginine vasopressin elevates renal nerve activity in the rat

Abstract Intrathecal injections of arginine vasopressin increased activity recorded from multifiber renal nerve bundles of anesthetized rats by 47 + 14%. This response was significantly attenuated following perfusion of the intrathecal space with a vasopressin antagonist, d(CH(2))(5)Tyr(Me)AVP. It is unlikely that vasopressin leaked to the periphery as iv administration of 10 pmol vasopressin decreased renal nerve activity by 9 + 1%. Electrical stimulation of the paraventricular nucleus (three stimuli at 20 to 100 muA, 100 or 200 Hz) caused a biphasic excitatory response with the peaks of increased renal nerve activity occurring between 50 to 100 and 100 to 200 ms after stimulation. Intrathecal application of the vasopressin antagonist prior to repeating the stimulation of the paraventricular nucleus attenuated the second excitatory response without affecting the first excitatory episode. In animals in which the stimulating electrode was located adjacent to, but not within, the paraventricular nucleus, a monophasic excitatory response (at between 100 to 150 ms after the stimulation) was observed. This response was not attenuated by the intrathecal antagonist. These results are consistent with earlier studies which suggested that arginine vasopressin may function as a mediator of synaptic transmission at spinal levels in pathways influencing kidney function.

Induction of the gene encoding pro-dynorphin by experimentally induced arthritis enhances staining for dynorphin in the spinal cord of rats

The response of dynorphinergic neurons in the lumbosacral spinal cord of the rat to chronic arthritic inflammation was studied by the combined use of biochemical and immunohistochemical procedures. In polyarthritic rats, in which all four limbs showed a swelling, inflammation and hyperalgesia, a pronounced elevation was seen in the level of messenger ribonucleic acid encoding prodynorphin (pro-enkephalin B) in the lumbosacral spinal cord. In addition, the levels of immunoreactive dynorphin A1-17, a primary gene product of this precursor, were greatly increased. This activation was reflected in a striking intensification of the immunohistochemical staining of both dynorphin and alpha/beta-neo-endorphin, a further major product of pro-dynorphin. In control animals perikarya were stained exceedingly rarely and encountered only in laminae I and II. Stained fibres and varicosities were seen throughout the dorsal and ventral gray matter, being most concentrated in laminae I, II, IV and V of the dorsal horn and dorsolateral to the central canal. In polyarthritic rats, fibres and varicosities were much more intensely stained throughout the cord, particularly in laminae I/II, IV and V and dorsolateral to the central canal. Many strongly-stained perikarya could be seen: these comprised many small diameter cells in laminae I and II, and some large diameter marginal neurons and large diameter cells, heterogenous in appearance, in the deeper laminae IV and V. Monolaterally inflamed rats injected in the right hind-paw showed pathological changes only in this limb. Correspondingly, in unilateral inflammation, an elevation in immunoreactive dynorphin was seen exclusively in the right dorsal horn and the above-described intensification of staining for dynorphin and neo-endorphin was seen only in this quadrant. This reveals the neuroanatomical specificity of the response. Thus, in the lumbosacral cord of the rat, pro-dynorphin neurons are most preponderant in laminae I, II, IV and V. A pronounced intensification of the immunohistochemical staining of these neurons is seen in chronic arthritis. Furthermore, there is a parallel elevation in the levels of messenger ribonucleic acid encoding pro-dynorphin and of its primary products dynorphin and neo-endorphin. These findings demonstrate an enhancement in the functional activity of spinal cord localized dynorphin neurons in the response to chronic arthritic inflammation.

Antinociception vs motor effects of intrathecal vasopressin as measured by four pain tests

The effects of intrathecal (i.t.) vasopressin (VP) on nociception were quantitatively tested in rats using 4 pain tests: tail flick, tail shock vocalization, hot plate, and formalin. In addition, motor effects of VP were examined qualitatively. I.t. VP produced a prolonged antinociception lasting at least 40 min on the tail flick (2.5 and 25 ng) and formalin (25 ng) tests, and a brief antinociception lasting less than 20 min on the tail shock (25 ng) and hot plate (25 ng) tests. Those rats not responding to the pain tests showed no signs of perceiving the pain stimulus, such as orientation to the stimulus or vocalization. In addition, i.t. VP produced scratching bouts (2.5 and 25 ng) and suppressed hindbody motor function (25 ng). The motor inhibitory effects of VP, although severe in some rats, were brief, lasting less than 15 min. In conclusion, i.t. VP produces antinociception in addition to its motor effects, and these properties appear to be due to separate mechanisms.

Immobilization stress affects oxytocin and vasopressin levels in hypothalamic and extrahypothalamic sites

Oxytocin (OT) and vasopressin (VP) have been localized in various sites within the central nervous system outside the classic hypothalamo-neurohypophyseal axis. This study investigated the effect of immobilization stress on the levels of OT and VP in the hypothalamus, pons-medulla, and the cervical, thoracic, and lumbosacral segments of the spinal cord. Male Long Evans rats were immobilized for 1 min and sacrificed by guillotine. The tissues were dissected out and homogenized in 0.1 N HCl. The hormone content was determined by radioimmunoassay (RIA) in Sep-pak extracted samples. The data show a decrease in OT content of 33.6% (P less than 0.02) and 42.4% (P less than 0.01) in the hypothalamus and pons-medulla, respectively. In the spinal cord, however, OT levels were increased by 39.1% (not significant), 51.1% (P less than 0.05), and 87.6% (P less than 0.001) in the cervical, thoracic, and lumbosacral segments respectively. The VP content of the hypothalamus and pons-medulla did not change. However, in the spinal cord, the VP content was also increased by 101.4% (P less than 0.01) and by 143.7% (P less than 0.01) in the cervical and lumbosacral segments. The levels of VP in the thoracic segment did not change. The data demonstrate that stress can alter hypothalamic and extra-hypothalamic levels of OT as well as spinal cord levels of VP. The exact physiological effects of these changes, particularly within the spinal cord, remain to be elucidated.

Neurochemical organization of the hypothalamic projection to the spinal cord in the rat

The hypothalamus provides a major projection to the spinal cord that innervates primarily lamina I of the dorsal horn and the sympathetic and parasympathetic preganglionic cell columns. We have examined the chemical organization of the neurons that contribute to this pathway by using combined retrograde transport of fluorescent dyes and immunohistochemistry for 15 different putative neurotransmitters or their synthetic enzymes. Our results demonstrate that 5 cytoarchitectonically distinct cell groups in the hypothalamus contribute to the spinal projection and that each has its own predominant chemical types. In the paraventricular nucleus, substantial numbers of hypothalamo-spinal neurons stain with antisera against arginine vasopressin (25-35%), oxytocin (20-25%), and met-enkephalin (10%). About 25% of the neurons with spinal projections in the retrochiasmatic area stain with an antiserum against alpha-melanocyte-stimulating hormone. Nearly 100% of the hypothalamo-spinal neurons in the tuberal lateral hypothalamic area stain with this same antiserum, but these cells do not stain for other proopiomelanocortin-derived peptides, and so probably contain a cross-reacting peptide. This population must be distinguished from an adjacent cell group, in the perifornical region, where many spinal projection neurons stain with antisera against dynorphin (25%) or atrial natriuretic peptide (20%). Finally, in the dorsal hypothalamic area as many as 55-75% of the neurons with spinal projections are dopaminergic, on the basis of their staining with an antiserum against tyrosine hydroxylase. These 5 neurochemically distinct projections from the hypothalamus to the spinal cord are discussed in the context of their possible functional significance.

Dehydration reduces kappa-opiate receptor binding in the neurohypophysis of the rat

Quantitative autoradiography was used to examine the effects of dehydration on kappa-opiate receptor binding in the neural lobe of the pituitary in rats. Dehydration was produced by 5 days of water deprivation or ingestion of 2% saline. Brattleboro rats homozygous for diabetes insipidus were used as a model of chronically disturbed water balance. Slide-mounted pituitary sections were incubated with [3H]bremazocine using kappa-receptor-selective assay conditions. Binding in the neural lobe was quantified by densitometry of film autoradiographs. Specific [3H]bremazocine binding in neural lobe sections of control rats was 45.4 fmol/mg wet weight. In contrast, binding in neural lobe sections of water-deprived, saline-treated, and water-sated homozygous Brattleboro rats was lower by 50%, 35% and 37%, respectively. We suggest that chronic dehydration elevates levels of endogenous neurohypophyseal dynorphin and produces a down-regulation of kappa-opiate receptors in the neurohypophysis, a change in affinity of the receptors for kappa-agonists, or both.

Distribution of the C-terminal glycopeptide of the vasopressin prohormone in rat brain: an immunocytochemical study

The distribution of the C-terminal glycopeptide of the vasopressin prohormone was mapped in rat brain by an immunocytochemical method using antibodies to the sheep glycopeptide. The antibodies did not react with vasopressin, oxytocin or their related neurophysins. Stained neural perikarya were observed in the hypothalamus (suprachiasmatic, paraventricular, and supraoptic nuclei) and in the bed nucleus of the stria terminalis. Fibres were detected in the hypothalamus and in extrahypothalamic regions (the frontal cortex, the lateral septum, the bed nucleus of the stria terminalis, the medial nuclei of the thalamus, the lateral habenula, the amygdala, the mesencephalic central gray, the raphe nucleus of the solitary tract and the cervical spinal cord). The distribution of glycopeptide immunoreactive cells was generally similar in young rats (8 weeks old) to the distribution in older rats (13 weeks old) except in the bed nucleus of the stria terminalis where stained neurons were relatively sparse or absent in the younger animals. Similarly, in the young rats the density of fibres containing the glycopeptide was reduced in territories innervated by the bed nucleus. In both young and old rats the neuronal distribution of the glycopeptide was identical to the distribution of vasopressin, which suggests that the glycopeptide and vasopressin are co-transported from the sites of biosynthesis to the sites of release.

Atrial natriuretic polypeptide in spinal cord and autonomic ganglia

Using a radioimmunoassay for alpha-rat atrial natriuretic polypeptide (alpha-rANP), tissue levels of alpha-rANP-like immunoreactivity (-LI) in the rat spinal cord and autonomic ganglia were investigated. The alpha-rANP-LI level was higher in the more caudal parts of the spinal cord and the highest in the sacral spinal cord. alpha-rANP-LI was also detected in the superior cervical and coeliac ganglia. Gel permeation chromatographic analysis showed that the major peak of alpha-rANP-LI in the spinal cord was a low molecular weight form co-eluted with synthetic alpha-rANP. Reverse-phase high performance liquid chromatographic analysis revealed that alpha-rANP-LI with a low molecular weight in the spinal cord consisted of several components, two major components of which co-migrated with synthetic alpha-rANP (4-28) and alpha-rANP (5-28), whereas little immunoreactivity was eluted at the position of alpha-rANP. These findings suggest the involvement of ANP in the function of the spinal cord and autonomic nervous system.

Electric footshocks differentially affect plasma and spinal cord vasopressin and oxytocin levels

Rats exposed for three minutes to repeated electric footshocks showed an approximate 10-fold increase of basal plasma vasopressin (AVP) and oxytocin (OXT) levels. In contrast, spinal AVP and OXT contents measured in the same rats remained unchanged when compared to undisturbed controls. This observation suggests that spinal AVP and OXT do not play a major role in the short-term adaptation of the organism to stress.

A quantitative analysis of the interrelationships between subpopulations of rat sensory neurons containing arginine vasopressin or oxytocin and those containing substance P, fluoride-resistant acid phosphatase or neurofilament protein

In rat L5 dorsal root ganglia 50% of neurons contained arginine vasopressin-like immunoreactivity and 38% oxytocin-like immunoreactivity, the oxytocin entirely coexisting with the arginine vasopressin. Staining of alternate mirror-image sections with RT97 (an antibody to neurofilament protein, and a marker for large light neurons) and with arginine vasopressin antiserum showed that the two were entirely complementary, thus establishing arginine vasopressin as a marker for all small dark neurons. Mirror-image staining also showed that neurons containing substance P-like immunoreactivity and those containing fluoride-resistant acid phosphatase activity were each contained within the arginine vasopressin-positive population. Arginine vasopressin-like immunoreactivity was axonally transported in the dorsal root and (in greater quantity) in sciatic nerve. Arginine vasopressin-like immunoreactivity was present also in laminae I and II of the dorsal horn of the spinal cord and this reactivity was absent in animals which had been treated neonatally with capsaicin, suggesting that it was contained in primary afferent terminals. These results are discussed in terms of their implications for the classification of primary afferent neurons and of a possible physiological role for arginine vasopressin in these neurons.

Oxytocin inhibits ACTH and peripheral catecholamine secretion in the urethane-anesthetized rat

Oxytocin (OT) generally has a stimulatory effect on ACTH secretion both in vitro and in vivo. As part of a study of ACTH-releasing factors in hypophysial portal blood, the effects of i.v. OT administration on plasma ACTH levels were tested in urethane-anesthetized rats. Surprisingly, i.v. injection of 10 micrograms OT lowered plasma ACTH levels by about 35% (P less than 0.01). It was reasoned that this paradoxical inhibition of ACTH secretion by OT might be mediated by inhibition of the unusually high rate of peripheral catecholamine secretion in this model. Measurement of plasma catecholamines before and after i.v. administration of 10 micrograms OT revealed a 53% inhibition of EPI (P less than 0.01) and 43% inhibition of NE (P less than 0.05). Administration of the beta-adrenergic antagonist propranolol (400 micrograms) 15 min before the beginning of the experiment completely blocked the inhibitory effects of OT on ACTH secretion and in fact unmasked the stimulatory effects of OT normally seen in conscious animals and in vitro. Superfused bisected adrenal glands exposed to 10(-6) M OT for 10 min secreted more than 30% less EPI and NE than control adrenals suggesting that the inhibition of EPI and NE secretion by OT in vivo occurs, at least in part, directly at the level of the adrenal. The data support the hypothesis that peripheral catecholamines may at times be directly involved in the control of ACTH secretion and also suggest that OT, which has recently been identified in the adrenal medulla, may have important paracrine functions in the regulation of adrenal catecholamine secretion.

In vivo biosynthesis and transport of oxytocin, vasopressin and neurophysin from the hypothalamus to the spinal cord

The biosynthesis of oxytocin, vasopressin and their associated neurophysins were studied in the projection from the paraventricular nucleus of the hypothalamus to the spinal cord in individual freely-moving adult male rats. Neuropeptide biosynthesis was studied in vivo by the delivery of [35S]cysteine through stereotaxically implanted indwelling cannulae using an osmotic minipump delivery system. Following the appropriate chase times, the neural lobe and spinal cord segments T1-T4 and T12-L2 were removed from fresh tissue; in addition, the nucleus of the solitary tract was punched from frozen coronal sections. The radiolabeled peptides were purified from the tissue homogenates by sequential linear and exponential gradient elution from reverse-phase high performance liquid chromatography columns. This approach has allowed us to purify radiolabeled oxytocin and vasopressin from both the upper and lower spinal cord. However, the kinetics of oxytocin and vasopressin biosynthesis appeared to be remarkably different, as judged by their differential labeling with different pulse and chase times. Additionally, the use of different chase periods following the pulse of radiolabel has allowed us to determine that oxytocin reaches the spinal cord via the fast component of axonal transport (greater than 8 mm h-1). Using immunoprecipitation and purification by high performance liquid chromatography, we were also able to purify radiolabeled neurophysins from spinal cord tissue homogenates. These results lend further support to a role for oxytocin and vasopressin in the modulation of autonomic nervous system function and to the role of the paraventricular nucleus as an integration center for endocrine and autonomic function.

Spinal cord dynorphin may modulate nociception via a kappa-opioid receptor in chronic arthritic rats

Inoculation of rats with Mycobacterium butyricum produced an arthritis of the limbs which revealed an enhanced sensitivity to noxious mechanical pressure (hyperalgesia). Arthritic rats displayed a pronounced rise in immunoreactive dynorphin in lumbo-sacral spinal cord which correlated both with the intensity and time-course of this hyperalgesia. MR-2266, a relatively preferential antagonist at the chi-opioid receptor (at which dynorphin is considered to act) potentiated this hyperalgesia. In contrast, MR 2267 (its inactive stereo-isomer) was ineffective. Further, naloxone (a weak chi-antagonist), and ICI 154,129 (a preferential delta-antagonist) were, in each case, inactive. The data demonstrate a pronounced response of spinal dynorphin to chronic arthritic pain in the rat. In addition, they raise the possibility of a function of spinal DYN, via a chi-receptor, in the modulation of chronic arthritic pain.

Localization of chromatographically characterized oxytocin and arginine-vasopressin to sensory neurones in the rat

Following treatment with colchicine 50-60% of all neurones in rat trigeminal and L5 spinal ganglia showed oxytocin (OXT)- and arginine-vasopressin (AVP)-like immunoreactivity. Further, OXT and AVP, together with their associated neurophysins, could be isolated from trigeminal ganglia by reversed-phase high-performance liquid chromatography followed by radioimmunoassay.

Vasopressin and oxytocin in the rat spinal cord: analysis of their role in the control of nociception

Lesions of the hypothalamic paraventricular nucleus depleted immunoreactive (ir)-vasopressin (VP) and -oxytocin (OT) from rat spinal cord but failed to modify nociceptive thresholds. Further, intrathecal introduction of VP and OT into the cord failed either to influence nociceptive thresholds or to modify the antinociceptive action of morphine. However, doses of VP as low as 20 ng caused, in contrast to OT, a hind-limb muscular flaccidity and respiratory disturbances. Rats suffering from chronic arthritis did not, finally, reveal any alterations in levels or ir-VP or ir-OT in the spinal cord. Is is concluded that spinal pools of VP and OT are derived from the paraventricular nucleus and do not play a major role in nociceptive processes in the spinal cord. A role of spinal VP in motor and, possibly autonomic control is, nevertheless, indicated.