Hindlimb paralytic effects of arginine vasopressin and related peptides following spinal subarachnoid injection in the rat

Intrathecal (IT) injection of arginine vasopressin (AVP) in rats caused a transient (<30 min), dose-related paralysis of the hindlimbs, loss of hindlimb and tail nociceptive responsiveness, and increased mean arterial pressure. Motor dysfunction was produced with comparable potency by lysine vasopressin (LVP) and arginine vasotocin (AVT); oxytocin (OXY) was approximately 1000 times less potent. Paralysis induced by these peptides was selectively blocked following IT pretreatment with 0.5 nmoles of the vasopressin V₁ receptor antagonist [1-(β-mercapto-β,β-cyclopentamethylene propioinic acid), 2-(O-methyl)tyrosine] Arg⁸-vasopressin (d(CH₂)₅[Tyr(Me²)]AVP). Pressor and antinociceptive responses to AVP were also blocked by this compound. However, at higher doses (2–5 nmoles, IT), d(CH₂)₅[Tyr(Me²)]AVP produced hindlimb paralysis, antinociception, and pressor responses by itself. In contrast to the fiber degeneration, cell loss, and necrosis found in lumbosacral cords of rats persistently paralyzed by other peptides (dynorphin A, somatostatin, and ICI 174864), neuropathological changes were not evident in spinal cords of rats transiently paralyzed by IT AVP. These results indicate that AVP-related peptides affected diverse spinal cord functions through interactions with a V₁-like receptor. The similar pattern of cardiovascular and antinociceptive responses to other peptides (dynorphin A, somatostatin, and ICI 174864), which also caused hindlimb paralysis, suggests that the former responses may actually reflect the nonselective consequences of a peptide-induced disruption of spinal cord function, rather than specific shared pharmacological effects.     

Chimeric peptide of Met-enkephalin and FMRFa induces antinociception and attenuates development of tolerance to morphine antinociception.

A synthetic chimeric peptide of Met-enkephalin and FMRFamide (YGGFMKKKFMRFa), based on MERF was synthesized. This peptide was tested for possible antinociceptive effects using the tail flick test in mice. The effect of the chimeric peptide on morphine antinociception and development of tolerance to the antinociceptive action of morphine was also investigated. The chimeric peptide produced significant, dose-dependent antinociception (40, 60 and 90 mg/kg) in the tail flick test. Pretreatment with naloxone (5 mg/kg, IP) significantly attenuated the antinociceptive effect induced by the chimeric peptide (90 mg/kg, IP), indicating involvement of an opioidergic mechanism. In combination experiments with morphine, the antinociceptive dose of the chimeric peptide (60 mg/kg, IP) potentiated morphine (7 mg/kg, IP) antinociception. A low dose of the chimeric peptide (10 mg/kg, IP), that did not produce significant antinociception on its own, also potentiated morphine antinociception. In the tolerance studies, male albino mice received twice daily injections of morphine (20 mg/kg, IP) followed by either saline (0.1 ml) or chimeric peptide (80 mg/kg, IP) for a period of 4 days. A control group received twice daily injections of saline (0.1 ml) for the same period. When tested on Day 5, tolerance to antinociceptive action of morphine (15 mg/kg, IP) was evidenced by decreased response in chronic morphine plus saline treated mice compared to control group. Concurrent administration of chimeric peptide (80 mg/kg, IP) with morphine significantly attenuated the development of tolerance to the antinociceptive action of morphine. The preliminary results of this study demonstrate that peripherally administered chimeric peptide can produce dose dependent, naloxone reversible, antinociception; potentiate morphine antinociception and attenuate morphine tolerance, indicating a possible role of these type of amphiactive sequences in antinociception and its modulation. These chimeric peptides may also prove to be useful tools for further ascertaining the role of FMRFa family of peptides in mechanisms leading to opiate tolerance and dependence.     

Behavioral profile of the TRH analogue RX77368 in developing rats

The behavioral effects of the TRH analogue RX77368, dimethyl proline-TRH (3, 10 and 30 mg/kg IP), in 5-, 10- and 20-day-old rat pups were investigated. The peptide induced shaking behavior and increased locomotion as early as 5 days after birth. At 20 days RX77368 also produced rearing, stereotyped mounting and grooming (mainly licking and chewing of the forepaws). Additionally, RX77368 produced hypothermia and antinociception in the infant rats. These responses, which were generally, although not always, comparable with those found in adults, agree with biochemical studies showing high levels of TRH receptors in the brain and spinal cord in the first three weeks following birth.     

强啡肽对脊髓原生型与诱生型一氧化氮合成酶活性,分布和基因表达的影响

蛛网膜下腔注射强啡肽Ａ１－１７引起剂量依赖性后肢和尾部瘫痪及甩尾甩足抑制。脊髓背角（侧）ＮＭＤＡ受体和ＮＯＳ／ＮＯ功能活性下降可能与Ｄｙｎ镇痛作用有关,脊髓腹角（）ＮＭＤＡ受体－Ｃａ＾２＋－ＮＯＳ／ＮＯ通路过度激活及ｃ－ｆｏｓ高表达可能与Ｄｙｎ致脊髓损伤作用有关。     

Sevoflurane suppresses noxious stimulus-evoked expression of Fos-like immunoreactivity in the rat spinal cord via activation of endogenous opioid systems

We investigated the antagonism of sevoflurane antinociception by opioid antagonists in the rat formalin test. Formalin injection into the hindpaw of the rat induces the nocifensive flinching behavior and the expression of Fos-like immunoreactivity (Fos-LI) in the spinal cord. Sevoflurane significantly suppressed the flinching behavior and decreased the number of Fos-LI neurons in the dorsal horn of spinal cord compared with the control group. Moreover, pretreatment with intraperitoneal naloxone plus naltrexone antagonized the suppression of flinching behavior and the decrease of the number of Fos-LI neurons produced by 3% sevoflurane. Intraperitoneal opioid antagonists themselves had no effects on both the behavior response and the expression of Fos-LI induced by formalin injection. This study supports the hypothesis that sevoflurane suppresses the nociceptive response, at least in part, by activating endogenous opioid systems.     

Interactions of substance P antagonists with serotonin in the mouse spinal cord

Administered intrathecally (IT) to mice, the putative substance P antagonist [D-Pro2,D-Trp7,9-substance P (DPDT) blocked substance P- and serotonin-induced reciprocal hindlimb scratching with ID50 values of 4.6 (2.9-6.9) and 3.0 (1.9-4.8) micrograms, respectively. The duration of this antagonistic effect was 90-120 min. In contrast, DPDT did not block bombesin-, somatostatin-, glycine- or glutamate-induced scratching. These data indicate that DPDT is an effective antagonist of serotonin-induced behaviors in the mouse spinal cord. Phenoxybenzamine (IT) also blocked substance P- and serotonin-induced scratching. Its onset of action was more rapid for serotonin than for DPDT implying differences in agonist-induced receptor activation. Methysergide (IT) blocked serotonin-induced scratching [ID50 = 0.7 (0.3-1.5) micrograms], but not substance P-induced scratching. Similar to DPDT, [D-Arg1,D-Trp7,9,Leu11]-substance P, [des-Arg1,D-Pro2, D-Trp7,9]-substance P(2-11) and [D-Pro4,D-Trp7,9]-substance P(4-11) blocked substance P and serotonin-induced scratching. In contrast, [D-Pro2,D-Phe7,D-Trp9]-substance P and [D-Pro4,D-Trp7,9,10]-substance P(4-11) blocked only substance P-induced scratching. Thus, some, but not all putative substance P antagonists may also be behavioral antagonists of serotonin in the mouse spinal cord.     

Involvement of kappa/dynorphin system in the development of tolerance to nicotine-induced antinociception

The aim of the present study was to explore the possible role of kappa/dynorphin system in the development of tolerance to nicotine antinociception in mice. First, we observed that kappa-opioid receptor (KOP-r) participates in the acute spinal antinociception produced by nicotine (3 and 5 mg/kg, s.c.) since the pre-treatment with the selective kappa antagonist nor-binaltorphimine (3 mg/kg, i.p.) attenuated this response in the tail-immersion test but not in the hot-plate test nor in locomotor responses. Possible changes in the expression of KOP-r were investigated in tolerant mice to nicotine antinociception by using autoradiography of [³H]CI-977 binding. The density of KOP-r decreased in the spinal cord of tolerant mice. In addition, bi-directional cross-tolerance between nicotine (3 and 5 mg/kg, s.c.) and the selective kappa agonist U50,488H (10 mg/kg, s.c.) was found in the tail-immersion test. Recent evidences indicate that an up-regulation of dynorphin levels in the spinal cord and subsequent activation of NMDA receptors participate in the development of tolerance to opioid and cannabinoid antinociception. In this study, dynorphin content in the lumbar spinal cord was similar in control and nicotine tolerant mice. Furthermore, the administration of the NMDA antagonist MK-801 (0.03 and 0.01 mg/kg, i.p.) before each daily nicotine injection did not modify the development of nicotine tolerance. In summary, these data indicate that KOP-r is directly involved in the development of tolerance to nicotine antinociception by a mechanism independent from dynorphin and NMDA receptors.     

Partly shared spinal cord networks for locomotion and scratching

Animals produce a variety of behaviors using a limited number of muscles and motor neurons. Rhythmic behaviors are often generated in basic form by networks of neurons within the central nervous system, or central pattern generators (CPGs). It is known from several invertebrates that different rhythmic behaviors involving the same muscles and motor neurons can be generated by a single CPG, multiple separate CPGs, or partly overlapping CPGs. Much less is known about how vertebrates generate multiple, rhythmic behaviors involving the same muscles. The spinal cord of limbed vertebrates contains CPGs for locomotion and multiple forms of scratching. We investigated the extent of sharing of CPGs for hind limb locomotion and for scratching. We used the spinal cord of adult red-eared turtles. Animals were immobilized to remove movement-related sensory feedback and were spinally transected to remove input from the brain. We took two approaches. First, we monitored individual spinal cord interneurons (i.e., neurons that are in between sensory neurons and motor neurons) during generation of each kind of rhythmic output of motor neurons (i.e., each motor pattern). Many spinal cord interneurons were rhythmically activated during the motor patterns for forward swimming and all three forms of scratching. Some of these scratch/swim interneurons had physiological and morphological properties consistent with their playing a role in the generation of motor patterns for all of these rhythmic behaviors. Other spinal cord interneurons, however, were rhythmically activated during scratching motor patterns but inhibited during swimming motor patterns. Thus, locomotion and scratching may be generated by partly shared spinal cord CPGs. Second, we delivered swim-evoking and scratch-evoking stimuli simultaneously and monitored the resulting motor patterns. Simultaneous stimulation could cause interactions of scratch inputs with subthreshold swim inputs to produce normal swimming, acceleration of the swimming rhythm, scratch-swim hybrid cycles, or complete cessation of the rhythm. The type of effect obtained depended on the level of swim-evoking stimulation. These effects suggest that swim-evoking and scratch-evoking inputs can interact strongly in the spinal cord to modify the rhythm and pattern of motor output. Collectively, the single-neuron recordings and the results of simultaneous stimulation suggest that important elements of the generation of rhythms and patterns are shared between locomotion and scratching in limbed vertebrates.     

Effects of naltrexone and CCK on estrous behavior and food intake in Syrian hamsters

Food deprivation inhibits estrous behavior in several species of rodents, but little is known about the neurotransmitter systems mediating this phenomenon. We determined whether partial blockade of opioid receptors by continuous infusion of naltrexone and/or acute peripheral injection of cholecystokinin (CCK) administration would overcome the suppressive effects of food deprivation on estrous behavior in Syrian hamsters. Contrary to expectation, naltrexone produced a slight suppression of estrous behavior, and systemic CCK administration had no effect. This dose of naltrexone was sufficient to reduce in vivo binding of [(3)H]naloxone in the brain, and both compounds affected other parameters such as food intake and body weight gain. Thus, the doses of CCK and naltrexone that were used were physiologically effective. These findings suggest that neither peripheral CCK nor opioid systems are likely to play a major role in the suppression of hamster estrous behavior by food deprivation.     

Effects of acute and chronic morphine and narcotic antagonists on brain energy metabolism

Morphine sulphate (4 mg/kg to 32 mg/kg) produced a dose-dependent decrease in brain malate as antinociception increased. Decreased brain malate persisted 72 hours after implantation of morphine pellets by which time mice had become tolerant to antinociception. This finding suggests that malate decrease, unlike changes of other metabolites in other studies, might not be simply a result of general metabolic changes. Malate change as well as antinociception was prevented by prior injection of naloxone (3.0 mg/kg) or naltrexone (0.6 mg/kg) in acute experiments. Malate decrease in pelleted mice was no longer present if withdrawal was produced by naloxone or naltrexone in mice implanted with morphine pellets for 72 hours. Brain P-creatine was elevated in all mice implanted with morphine pellets even after withdrawal, thus, apparently, representing a more generalized effect than malate change.     

Spinal actions of GR73632, a novel tachykinin NK1 receptor agonist.

Behavioral characterization of GR73632, a newly synthesized tachykinin NK1 receptor agonist, was examined in mice. Intrathecal (IT) injection of GR73632 in the spinal subarachnoid space of mice elicited a dose-dependent behavioral syndrome, consisting of scratching, biting and licking. The time course of the response to GR73632 was almost similar to that of substance P. GR73632 evoked much more licking and biting than did substance P, that in turn caused less scratching. GR73632 was approximately 200-fold more potent than substance P in inducing the characteristic behavioral response. The GR73632-induced behavioral response was inhibited by IT co-administration of CP-96,345, a non-peptide NK1 receptor antagonist, but not its inactive enantiomer CP-96,344. CP-96,345, co-injected IT with substance P, also inhibited the behavioral response to substance P. These results demonstrate that the scratching, biting and licking response induced by IT GR73632 may be mediated by the NK1 receptor in the spinal cord. These findings suggest that GR73632 may be useful as a tachykinin NK1 receptor agonist and also for evaluating spinal pharmacological activities of NK1 receptor antagonists.     

Effects of methylnaltrexone on morphine-induced cough suppression in guinea pigs

We administered methylnaltrexone, a peripheral opioid receptor antagonist, to guinea pigs previously injected with morphine sulfate to determine whether the compound could block opioid-induced cough suppression without blocking antinociception. The effects of methylnaltrexone (2.0, 1.6, 0.8 mg/kg) and of naltrexone (0.32, 0.16, 0.02 and 0.01 mg/kg) were compared in animals who had been injected with morphine sulfate (8.1 mg/kg). At 2.0 mg/kg methylnaltrexone, number of coughs returned to baseline value and nociception remained unaffected. At the two higher doses of naltrexone (0.32 and 0.16 mg/kg), morphine-induced antitussive effect was blocked, but antinociception was reversed. Our results suggested that methylnaltrexone possesses opioid antagonist activity in receptors peripheral to the blood-brain barrier. Its peripheral activity makes methylnaltrexone a clinically interesting agent for maintaining the cough reflex in those who must take opioids for analgesia.     

Potentiation of opioid analgesia by cocaine: the role of spinal and supraspinal receptors.

These studies examined the effect of cocaine on the analgesia produced by systemically and centrally administered opioid agonists. Cocaine (50 mg/kg, s.c.) increased the analgesic potency of systemic, ICV and IT morphine; and the ICV and IT analgesic effects of the delta selective peptide, [D-Pen2,D-Pen5]enkephalin (DPDPE). Cocaine also increased the analgesic potency of the mu selective ligand [D-Ala2,NMePhe4,Gly-ol5]enkephalin (DAGO) administered ICV. However, cocaine did not alter the ED50 for IT DAGO. GC-MS studies indicated that brain cocaine concentration was approximately 3.0 micrograms/g wet weight 45 min following s.c. administration. These results suggest that cocaine-induced increases in opioid analgesic potency are mediated at brain mu and delta receptors and spinal mu receptors. Furthermore, there might be functional differences between spinal and supraspinal sites at which DAGO produces analgesia.     

Substance P antagonist-induced spinal cord vasoconstriction: Effects of thyrotropin-releasing hormone and substance P agonists

Local spinal cord vasomotor effects of 3 substance P (SP) antagonists were studied in the rat following intrathecal (IT) administration. Each SP antagonist (3.3 nmol) increased spinal cord vascular resistance and reduced blood flow. A LH-RH antagonist analog (10 nmol) of similar molecular weight and which also contained multiple D-Trp residues did not cause spinal cord vasoconstriction. The vasoconstrictor action of the SP antagonist, [D-Arg¹, D-Pro², D-Trp^7,9, Leu¹¹]-SP ([D-Arg]-SP) was unaffected by pretreatment with a stable SP receptor agonist (5 nmol IT). Given evidence for a cerebral vasodilator action of TRH agonists, the effects of TRH (IV) and a stable TRH analog (MK-771, IT) on [D-Arg]-SP-induced vasoconstriction were also assessed. Neither TRH nor MK-771 prevented the [D-Arg]-SP-induced vasoconstriction. However, TRH (IV) but not MK-771 (IT) partially opposed [D-Arg]-SP-induced reduction in thoracic spinal cord blood flow. Thus, SP antagonists cause spinal cord vasoconstriction by a non-SP receptor mediated phenomenon. In addition, the attenuation of SP-antagonist-induced neuropathological changes previously reported with IV. TRH administration is likely due to less severe consequences of vasoconstriction in the presence of a higher initial baseline blood flow rather than direct prevention of the vasoconstriction.     

Both shared and specialized spinal circuitry for scratching and swimming in turtles

In principle, nervous systems could generate a behavior either via neurons that are relatively specialized for producing one behavior or via multifunctional neurons that are shared among multiple, diverse behaviors. I recorded extracellularly from individual turtle spinal cord neurons while evoking hindlimb scratching, swimming, and withdrawal motor patterns. The majority of spinal neurons recorded were activated during both scratching and swimming motor patterns, consistent with the existence of shared circuitry for these types of limb movements. These neurons tended to have a similar degree of rhythmic modulation of their firing rate and a similar phase preference within the hip flexor activity cycle during scratching and swimming motor patterns. In addition, a substantial minority of neurons were activated during scratching motor patterns but silenced during swimming motor patterns. This raises the possibility that inhibitory interactions between some scratching and swimming neural circuitry play a role in motor pattern selection. These scratch-specialized neurons were also less likely than the putative shared neurons to be activated during withdrawal motor patterns. Thus, these neurons may represent two separate classes, one of which is used generally for hindlimb motor control and the other of which is relatively specialized for a subset of hindlimb movement types.     

Physiological Function of Gastrin-Releasing Peptide and Neuromedin B Receptors in Regulating Itch Scratching Behavior in the Spinal Cord of Mice

Pruritus (itch) is a severe side effect associated with the use of drugs as well as hepatic and hematological disorders. Previous studies in rodents suggest that bombesin receptor subtypes i.e. receptors for gastrin-releasing peptide (GRPr) and neuromedin B (NMBr) differentially regulate itch scratching. However, to what degree spinal GRPr and NMBr regulate scratching evoked by intrathecally administered bombesin-related peptides is not known. The first aim of this study was to pharmacologically compare the dose-response curves for scratching induced by intrathecally administered bombesin-related peptides versus morphine, which is known to elicit itch in humans. The second aim was to determine if spinal GRPr and NMBr selectively or generally mediate scratching behavior. Mice received intrathecal injection of bombesin (0.01–0.3 nmol), GRP (0.01–0.3nmol), NMB (0.1–1nmol) or morphine (0.3–3 nmol) and were observed for one hour for scratching activity. Bombesin elicited most profound scratching over one hour followed by GRP and NMB, whereas morphine failed to evoke scratching response indicating the insensitivity of mouse models to intrathecal opioid-induced itch. Intrathecal pretreatment with GRPr antagonist RC-3095 (0.03–0.1 nmol) produced a parallel rightward shift in the dose response curve of GRP-induced scratching but not NMB-induced scratching. Similarly, PD168368 (1–3 nmol) only attenuated NMB but not GRP-induced scratching. Individual or co-administration of RC-3095 and PD168368 failed to alter bombesin-evoked scratching. A higher dose of RC-3095 (0.3 nmol) generally suppressed scratching induced by all three peptides but also compromised motor function in the rotarod test. Together, these data indicate that spinal GRPr and NMBr independently drive itch neurotransmission in mice and may not mediate bombesin-induced scratching. GRPr antagonists at functionally receptor-selective doses only block spinal GRP-elicited scratching but the suppression of scratching at higher doses is confounded by motor impairment.     

Inhibition of noxious stimulus-induced spinal prostaglandin E2 release by flurbiprofen enantiomers: a microdialysis study

Peripheral noxious stimuli have been shown to induce prostaglandin (PG) E2 release at the site of inflammation and in the spinal cord. The antiinflammatory and antinociceptive effects of cyclooxygenase-inhibiting drugs are thought to depend on the inhibition of PG synthesis. R-Flurbiprofen, however, does not inhibit cyclooxygenase activity in vitro but still produces antinociceptive effects. To find out whether R-flurbiprofen acts via inhibition of spinal PG release, concentrations of PGE2 and flurbiprofen in spinal cord tissue were assessed by microdialysis. The catheter was transversally implanted through the dorsal horns of the spinal cord at level L4. R- and S-flurbiprofen (9 and 27 mg kg(-1), respectively) were administered intravenously 10-15 min before subcutaneous injection of formalin into the dorsal surface of one hindpaw. Flurbiprofen was rapidly distributed into the spinal cord with maximal concentrations after 30-45 min. Baseline PGE2 dialysate concentrations were 100.6 +/- 6.4 pg ml(-1) (mean +/- SEM). After formalin injection they rose about threefold with a maximum of 299.4 +/- 68.4 pg ml(-1) at 7.5 min. After approximately 1 h PGE2 levels returned to baseline. Both flurbiprofen enantiomers completely prevented the formalin-induced increase of spinal PGE2 release and reduced PGE2 concentrations below basal levels. S- and R-flurbiprofen at 9 mg kg(-1) produced a minimum of 15.8 +/- 5.2 and 27.7 +/- 14.9 pg ml(-1), respectively, and 27 mg kg(-1) S- and R-flurbiprofen resulted in 11.7 +/- 1.7 and 9.3 +/- 4.7 pg ml(-1), respectively. PGE2 levels remained at the minimum up to the end of the observation period at 5 h. When 27 mg kg(-1) R-flurbiprofen was injected intravenously without subsequent formalin challenge, baseline immunoreactive PGE2 concentrations were not affected. S-Flurbiprofen (27 mg kg(-1)), however, led to a moderate reduction (approximately 40%). The data suggest that antinociception produced by R-flurbiprofen is mediated at least in part by inhibition of stimulated spinal PGE2 release and support the current view that increased spinal PGE2 release significantly contributes to nociceptive processing.     

Drinking,but not feeding,is opiate-sensitive in hamsters

The long-lasting opiate antagonist, naltrexone (NTX), was examined for its effects on various types of consummatory behavior in male golden hamsters and rats. Rat, but not hamster, 24 hr food and water intakes were significantly decreased by four daily NTX (10.0 mg/kg) injections. Hamsters displayed a minimal night to day feeding ratio compared to rats. hamsters increased food intake following insulin (50 U/kg) administration, but not after 24 hr food deprivation (FD) or 2-deoxy-D-glucose (2-DG; 800 mg/kg) injections. NTX (1.0 and 10 mg/kg) had no effect on feeding, but markedly attenuated hamster drinking induced by 48 hr water deprivation or hypertonic saline injection. Dexamethasone (DEX), a glucocorticoid which depletes pituitary β-endorphin and produces anorexia in rats, had no effect on daily hamster intake. Since the normal feeding profile of the hamster is similar to that of naloxone and DEX-treated rats, hamsters appear to lack an opiate-sensitive feeding system. In contrast, stimulated drinking behavior of hamsters operates through an opiate-sensitive mechanism. Thus, there are marked species differences concerning the involvement of endogenous opioids is consummatory behavior.     

Effect of arginine vasopressin in the nucleus raphe magnus on antinociception in the rat

Previous work has shown that arginine vasopressin (AVP) regulates antinociception through brain nuclei rather than the spinal cord and peripheral organs. The present study investigated the nociceptive effect of AVP in the nucleus raphe magnus (NRM) of the rat. Microinjection of AVP into the NRM increased pain threshold in a dose-dependent manner, while local administration of AVP-receptor antagonist-d(CH2)5Tyr(Et)DAVP decreased the pain threshold. Pain stimulation elevated AVP concentration in the NRM perfuse liquid. NRM pretreatment with AVP-receptor antagonist completely reversed AVP's effect on pain threshold in the NRM. The data suggest that AVP in the NRM is involved in antinociception.