Modulation of brain serotonin by benzyl butyl phthalate in Fundulus heteroclitus (mummichog).

Endocrine-disrupting chemicals have been known to alter important animal behaviors by modulating serotonin (5-hydroxytryptamine, 5-HT) and dopamine. F. heteroclitus (mummichog) brain serotonin and dopamine levels were quantified by enzyme-linked immunosorbent assay (ELISA) following a 28-day exposure regimen involving daily doses of either 0.1 mg l-1 benzyl butyl phthalate (BBP) dissolved in acetone or acetone alone (0.1 mg l-1). No differences in mean brain mass or total protein homogenate were induced by exposure to the acetone vehicle or BBP in acetone. The acetone vehicle had no effect on dopamine, serotonin, or tyrosine hydroxylase levels, but acetone did decrease tryptophan hydroxylase levels (p = 0.011). Exposure to BBP in acetone decreased dopamine (p = 0.024), increased serotonin (p < 0.001), reduced tryptophan hydroxylase as compared to the acetone vehicle alone (p < 0.001), and had no significant effect on tyrosine hydroxylase levels. This study is the first to report modulation of F. heteroclitus brain serotonin and its enzyme tryptophan hydroxylase following sub-lethal exposure to BBP in an acetone vehicle. In addition, modulation of brain dopamine in F. heteroclitus, sans simultaneous modulation of tyrosine hydroxylase, was also observed. These findings support the use of F. heteroclitus for assessing sub-lethal BBP exposure.

Microglia and inflammatory mechanisms in the clearance of amyloid beta peptide.

There is now abundant evidence that brain microglia, when activated, have the lineage, receptors, and synthetic capacity to participate in both potentially neurotoxic inflammatory responses and potentially beneficial phagocytic responses. Amyloid beta peptide (Abeta) forms highly insoluble, beta-pleated aggregates that are widely deposited in the Alzheimer's disease (AD) cortex and limbic system. Aggregated Abeta also activates the classical and alternative complement cascades. These properties make Abeta an excellent target for microglial phagocytosis, a view supported by multiple reports, through well established mechanisms of phagocyte clearance.

Supraspinal cholecystokinin may drive tonic descending facilitation mechanisms to maintain neuropathic pain in the rat.

Complete or partial spinal section at T(8) has been shown to block tactile allodynia but not thermal hyperalgesia following L(5)/L(6) spinal nerve ligation (SNL), suggesting the supraspinal integration of allodynia in neuropathic pain. In the present study, the possibility of mediation of nerve injury-associated pain through tonic activity of descending nociceptive facilitation arising from the rostroventromedial medulla (RVM) was investigated. Specifically, the actions of brainstem cholecystokinin and the possible importance of sustained afferent input from injured nerve fibers were determined using pharmacological and physiological approaches in rats with SNL. Lidocaine given bilaterally into the RVM blocked tactile allodynia and thermal hyperalgesia in SNL rats and was inactive in sham-operated rats. Bilateral injection of L365,260 (CCK(B) receptor antagonist) into the RVM also reversed both tactile allodynia and thermal hyperalgesia. Microinjection of CCK-8 (s) into the RVM of naive rats produced a robust tactile allodynic effect and a more modest hyperalgesia. CCK immunoreactivity was not significantly different between SNL and sham-operated rats. The anti-nociceptive effect of morphine given into the ventrolateral periaqueductal gray region (PAG) was substantially reduced by SNL. The injection of L365,260 into the RVM or of bupivacaine at the site of nerve injury restored the potency and efficacy of PAG morphine in SNL rats. These results suggest that changes in supraspinal processing are likely to contribute to the observed poor efficacy of opioids in clinical states of neuropathic pain. These data also indicate that the activation of descending nociceptive facilitatory pathways is important in the maintenance of neuropathic pain, appears to be dependent on CCK release, and may be driven from sustained afferent input from injured nerves to brainstem sites. Collectively, these data support the hypothesis that abnormal tonic activity of descending facilitation mechanisms may underlie chronic pain from peripheral nerve injury.

delta-Opioid receptor agonists produce antinociception and [35S]GTPgammaS binding in mu receptor knockout mice.

We examined the effects of [D-Pen(2),D-Pen(5)]enkephalin (DPDPE), [D-Ala(2),Glu(4)]deltorphin (DELT), and (+)-4-[(alphaR)-alpha((2S, 5R)-4-Allyl-2,5-dimethyl-1-piperazinyl)-3-methoxybenzyl]-N, N-diethylbenzamide (SNC80) on [35S]GTPgammaS binding in brain membranes prepared from micro-opioid receptor knockout (-/-) mice. The potency and maximal response (E(max)) of these agonists were unchanged compared to control mice. In contrast, while the potency of [D-Pen(2),pCl-Phe(4),D-Pen(5)]enkephalin (pCl-DPDPE) was not significantly different, the E(max) was reduced as compared to controls. In the tail-flick test, intracerebroventricular (i.c.v.) or intrathecal (i.th.) DELT produced antinociceptive effects in -/- mice with potency that did not differ significantly from controls. In contrast, the antinociceptive potency of i.c.v. and i.th. DPDPE was displaced to the right by 4- and 9-fold in -/- compared to control mice, respectively. Reduced DPDPE antinociceptive potency in -/- mice, taken together with reduced DPDPE- and pCl-DPDPE- stimulated G protein activity in membranes prepared from -/- mice, demonstrate that these agonists require mu-opioid receptors for full activity. However, because DELT mediated G protein activation and antinociception were both comparable between -/- and wild type mice, we conclude that the mu-opioid receptor is not a critical component of delta-opioid receptor function.

Selective opioid delta agonists elicit antinociceptive supraspinal/spinal synergy in the rat.

A multiplicative antinociceptive interaction of morphine activity at supraspinal and spinal sites has been clearly established and is thought to be responsible, in part, for the clinical utility of this compound in normal dose-ranges. While synergistic actions of mu-opioid receptor agonists have been shown, it is unclear whether a similar interaction exists for opioid agonists acting via delta-opioid receptors. Responses to acute nociception were determined with the 52 degrees C hot plate, 52 degrees C warm-water tail-flick and the Hargreaves paw-withdrawal tests. The peptidic opioid delta(1) agonist [D-Pen(2),D-Pen(5)]enkephalin (DPDPE) or delta(2) agonist [D-Ala(2),Glu(4)]deltorphin (DELT) were given into the rostral-ventral medulla (RVM), intrathecally (i.th.) or simultaneously into both the RVM and i.th. (1:1 fixed ratio). Both of the opioid delta agonists produced dose-dependent antinociception in all tests. With the exception of DPDPE in the hot plate test, isobolographic analysis revealed that the supraspinal/spinal antinociceptive interaction for both DPDPE and DELT were synergistic in all nociceptive tests. These data suggest that opioid delta agonists exert a multiplicative antinociceptive interaction between supraspinal and spinal sites to acute noxious stimuli and suggest possibility that compounds acting through delta-opioid receptors may have sufficient potency for eventual clinical application.

Lesions of the dorsolateral funiculus block supraspinal opioid delta receptor mediated antinociception in the rat.

Previous experiments have demonstrated that [D-Ala(2), Glu(4)]deltorphin (DELT) produces delta-receptor mediated antinociceptive effects when microinjected into the rat lateral ventricle and ventral medial medullary reticular formation (MRF), but not in the periaqueductal grey region (PAG). The present experiments were undertaken to further characterize the role of delta opioid agonists microinjected into the MRF and to explore the possibility of a descending pain modulatory system which might be linked to supraspinal delta opioid receptors. Rats received formalin into the dorsum of the right hindpaw and flinching responses were recorded. DELT given intracerebroventricularly (i.c.v.), intrathecally (i.th.) or into the MRF before formalin produced a dose-dependent and delta opioid receptor-mediated attenuation of both the first and second phases of the formalin-induced foot flinch response. DELT given i.c.v., i.th., or into the MRF also blocked formalin-induced increase in Fos-like immunoreactivity (FLI) in the dorsal horn of lumbar spinal cord ipsilateral to the formalin injection. Unilateral lesioning of the ipsilateral dorsolateral funiculus (DLF) did not alter nociceptive responses to formalin alone, but blocked the antinociceptive effect of DELT administered into the MRF; DELT was fully active in sham-DLF lesioned rats. Additionally, rats with DLF lesions did not show decreases in formalin-induced FLI in the ipsilateral lumbar spinal cord after injection of DELT into the MRF. These data suggest that delta opioid receptors in the MRF may be involved in activation of a descending inhibitory pain pathway projecting through the DLF to modulate tonic nociceptive input at the spinal level.

Tramadol and its enantiomers differentially suppress c-fos-like immunoreactivity in rat brain and spinal cord following acute noxious stimulus.

Tramadol hydrochloride, (1RS,2RS)-2-[(dimethylamino)methyl]-1-(3-methoxyphenyl)-cyclohexanol hydrochloride, is an orally-active, centrally-acting analgesic with a putative dual mechanism of action, including an opioid and non-opioid component. The analgesic properties of tramadol and the possible co-existence of dual mechanisms has been postulated to be due to complementary and interactive pharmacologies of its enantiomers. We examined the ability of tramadol, its enantiomers, and morphine as reference to suppress c-fos-like immunoreactivity (c-fos-ir) in rat spinal cord and brain regions following a noxious stimulus (i.p. administration of 3.5% acetic acid). c-fos-ir was measured by immunocytochemistry and the stained cells in each region were counted 2 h after the acetic-acid injection (2:25 h after tramadol or morphine). Equi-analgesic doses of s.c. morphine (10 mg/kg) or tramadol (30 mg/kg) significantly suppressed c-fos-ir in all areas examined, except dorsal central gray of the spinal cord. The enantiomers of tramadol had distinctive patterns of suppression, neither one suppressed c-fos-ir in all of the regions, and hence neither one alone accounted for the suppression produced by the racemate. These findings support differential and complementary effects of tramadol enantiomers in sub-populations of spinal and supraspinal nociceptive neurons, consistent with the proposed antinociceptive interaction between the enantiomers.

Opioid antagonists and antisera to endogenous opioids increase the nociceptive response to formalin: demonstration of an opioid kappa and delta inhibitory tone.

The present experiments explored the role of endogenous opioids in the behavioral response to a formalin-induced nociceptive stimulus in the rat. Flinching was taken as a measure of the intensity of the nociceptive stimulus after the administration of formalin into the dorsal surface of the paw of control animals, or in animals receiving i.p. administration of receptor-selective doses of opioid antagonists including naloxone, naltrindole (delta opioid antagonist), nor-binaltorphimine (kappa opioid antagonist) or beta-funaltrexamine (mu opioid antagonist). Additionally, antisera to [Leu5]enkephalin, [Met5]enkephalin and dynorphin A (1-13) (dynorphin) were administered intrathecally before formalin to explore the contribution of endogenous opioids in modulation of the flinching response. Formalin-induced flinching was increased significantly by naloxone, and receptor selective doses of naltrindole and nor-binaltorphimine, but not beta-funaltrexamine. Additionally, antisera to [Leu5]enkephalin and dynorphin also resulted in a significant increase in formalin-induced flinching, whereas antisera to [Met5]enkephalin had no effect. On the basis of significant increases in formalin-induced flinching produced by 1) receptor-selective doses of delta and kappa, but not mu, opioid antagonists and 2) antisera to [Leu5]enkephalin and dynorphin A, but not [Met5]enkephalin, these data suggest the presence of an opioid inhibitory tone which acts to limit the intensity of the pain signal. This tone appears to be mediated via activation of delta and kappa receptors, possibly by a [Leu5]enkephalin- and dynorphin-like substance, respectively.

The increase in morphine antinociceptive potency produced by carrageenan-induced hindpaw inflammation is blocked by naltrindole, a selective delta-opioid antagonist.

Carrageenan-induced inflammation of the rat hindpaw has been used as a model for persistent pain of inflammatory origin. The induction of inflammation resulting from carrageenan injection in the rat hindpaw has been shown to elicit an increase in the antinociceptive potency of morphine, an effect postulated to be related to reduced levels of spinal cholecystokinin (CCK). Recent findings have related the anti-opioid effect of CCK to a decrease in activation of delta-opioid receptors. For this reason, we have examined the effects of the delta-opioid antagonist naltrindole (NTI) on the modulation of morphine antinociceptive potency resulting from carrageenan-induced inflammation. Rats with carrageenan-induced hindpaw inflammation received several doses of morphine in the absence or presence of NTI and were tested in the hot plate (HP) and tail flick (TF) tests. These results were compared to those of non-carrageenan injected rats. Morphine was significantly more potent in inflamed, than in control, rats in both tests. While NTI did not affect morphine antinociceptive potency in control rats in either test, this opioid delta antagonist blocked the increase in morphine potency resulting from carrageenan inflammation in nearly every case. The blockade of the enhancement of morphine potency was such that the effect of a given dose of morphine was similar in control rats and carrageenan-injected rats with NTI. We suggest that carrageenan-induced inflammation may alter endogenous enkephalin levels, perhaps by a decrease in CCK availability. The enhancement of morphine antinociceptive potency may result from the well-established synergism seen following the activation of opioid delta receptors by enkephalins.

Naltrindole, an opioid delta antagonist, blocks the enhancement of morphine-antinociception induced by a CCKB antagonist in the rat.

CCK has been shown to inhibit morphine antinociception, while antagonists of CCK receptors enhance morphine antinociceptive potency. These observations have led to the suggestion that CCK may function as an endogenous anti-opioid. Here, the involvement of the CCKB receptor in modulating the antinociceptive effects of morphine has been investigated by examination of the effects of a CCKB antagonist in the absence or presence of naltrindole, an opioid delta receptor antagonist. Intrathecal (i.th.) or subcutaneous (s.c.) L365,260 (a CCKB antagonist) did not produce any antinociceptive actions alone in either the rat tail-flick or hot-plate tests. L365,260 pretreatment enhanced the morphine antinociceptive response after either i.th. or s.c. administration. Naltrindole did not produce any antinociceptive effect alone and did not antagonize the antinociceptive actions of morphine after either i.th. or s.c. administration. However, naltrindole blocked the enhancement of morphine antinociception produced by L365,260 when evaluated by either route. These data suggest a tonic inhibition of enkephalin release by CCK via CCKB receptors. The subsequent enhancement of morphine antinociceptive potency may reflect the well-known modulation of morphine by enkephalins acting at opioid delta receptors.

Chronic exposure to low doses of MPTP. I. Cognitive deficits in motor asymptomatic monkeys.

Cognitive deficits which may occur following chronic low-dose exposure to 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) were studied in monkeys who remained motor asymptomatic for parkinsonism throughout the study. The tasks used to assess cognitive functioning are those which have proved in the past to be sensitive to disruption of frontal cortical and or striatal integrity (delayed response and delayed alternation) or sensitive to inferior temporal lobe dysfunction (visual pattern discrimination). Since Parkinson's disease patients have been described as exhibiting frontal signs, we were interested to examine whether MPTP-treated monkeys might exhibit deficits on frontally-mediated tasks, without the confound of motor disturbances. We found that macaque nemistrina monkeys exposed to cumulative doses of 14.94-75.42 mg of MPTP over periods ranging from 5 to 13 months never developed parkinsonian motor signs. However, all 4 animals examined showed significant post-MPTP deficits in delayed response and delayed alternation performance, while visual pattern discrimination performance remained intact. These animals also developed other behavioral problems including irritability and decreased attentiveness. These results show that MPTP can cause specific cognitive deficits independent of the motor deficits which can be produced by this toxin.